ALTERNATIVE FUEL INFRASTRUCTURE
lr CORRIDOR COALITION
MEDIUM- AND HEAVY-DUTY ALTERNATIVE FUEL INFRASTRUCTURE
^''^^SSSS^STRATEGIC DEVELOPMENT/PLAN
MARCH 2020
CALSTART
48 S. Chester Ave., Pasadena, CA
Primary Authors: Alycia Gilde, Jonathan Norris, Campbell Scott
Kasey Okazaki, and Jonathan Gordon
Disclaimer: This document captures a snapshot in time and should be considered as an initial,
possible framework for medium and heavy-duty alternative fuel infrastructure investments. The
West Coast Collaborative believes that the infrastructure development project proposals listed
in this document cover a small percentage of the demand for medium and heavy-duty
alternative fuel infrastructure on the West Coast, and it welcomes feedback on additional
infrastructure needs not reflected in this document.
www.westcoastcollaborative.org
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WEST COAST COLLABORATIVE
A public-private partnership to reduce diesel emissions
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This Medium and Heavy-Duty Alternative Fuel Infrastructure Strategic Development Plan was commissioned by the
West Coast Collaborative Alternative Fuel Infrastructure Corridor Coalition (WCC AFICC). This document was
prepared by CALSTART for the purposes of identifying potential diesel emission reduction strategies in California,
Oregon, and Washington. This document captures a snapshot in time and should be considered as an initial, possible
framework for medium and heavy-duty (MHD) alternative fuel infrastructure investments, not a prescriptive list of
specific projects that must be endorsed for funding, or implementation. The information and recommendations
presented herein do not represent the views of any individual WCC AFICC Steering Team Member, WCC AFICC
Workgroup Member, or other WCC Partners.
WCC AFICC Steering Team Member Organizations
California Air Pollution Control Officers Association
California Air Resources Board
California Association of Councils of Government
California Department of Transportation
California Energy Commission
California Environmental Protection Agency
California Governor's Office of Business and Economic Development
California Public Utilities Commission
CALSTART
Columbia-Willamette Clean Cities Coalition
Discovery Institute: West Coast Corridor Coalition
Oregon Department of Energy
Oregon Department of Environmental Quality
Oregon Department of Transportation
Oregon Metro
Port of Portland
Port of Seattle
Port of Tacoma
Puget Sound Clean Air Agency
Puget Sound Regional Council
Rogue Valley Clean Cities Coalition
Ross Strategic: Pacific Coast Collaborative
United States Department of Energy, National Energy Technology Laboratory
United States Department of Energy, Vehicle Technologies Office
United States Department of Energy, National Renewable Energy Laboratory
United States Department of Transportation, Federal Highway Administration
United States Department of Transportation, Volpe National Transportation Systems Center
United States Environmental Protection Agency, Region 9
United States Environmental Protection Agency, Region 10
Washington State Department of Commerce
Washington State Department of Ecology
Washington State Department of Transportation
Western Washington Clean Cities Coalition
Guidance for Submitting Additional Infrastructure Project Proposals After Release of this Plan
This plan contains MHD alternative fuel infrastructure project proposals submitted by fleets and fuel providers who
participated in the 2016-2019 WCC AFICC alternative fuel infrastructure needs assessment for MHD fleet operations
in California, Oregon, and Washington. Following publication of this report, the WCC intends to create an AFICC
submission form on its website to solicit additional MHD alternative fuel infrastructure project proposals from
partners seeking funding assistance and partnerships to support implementation elsewhere in the WCC states and
territories, including: Alaska, Arizona, California, Hawaii, Idaho, Nevada, Oregon, Washington, Tribal Lands, and the
U.S. Pacific Islands: American Samoa, Guam, and Northern Mariana Islands (www.westcoastcollaborative.org).
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Table of Contents
I. LIST OF ACRONYMS 1
II. EXECUTIVE SUMMARY 3
III. INTRODUCTION 25
What is AFICC 26
Mission Statement 26
Partnership Objectives 26
Partnership Roadmap 27
IV. MEDIUM- AND HEAVY-DUTY ALTERNATIVE FUEL VEHICLE TRENDS 29
Alternative Fuel Trends 29
Designation and Cost of Alternative Fuel Corridors 29
Federal Policy Landscape 36
Current Federal Government Activities 38
Opportunities to Meet Alternative Fuel Goals 38
California Policy Landscape 38
Current California Government Activities 41
Opportunities to Meet Alternative Fuel Goals 41
Oregon Policy Landscape 42
Current Oregon Government Activities 44
Opportunities to Meet Alternative Fuel Goals 44
Washington Policy Landscape 44
Current Washington Government Activities 46
Opportunities to Meet Alternative Fuel Goals 47
Barriers, Solutions, and Drivers of Alternative Fuel 48
Electric Charging 49
Hydrogen 53
CNG, LNG, and LPG 55
Environmental Benefits and Environmental Justice 58
Workforce Development Considerations 60
V. UNDERSTANDING ALTERNATIVE FUEL INFRASTRUCTURE NEEDS 62
Stakeholder Engagement and Industry Outreach 62
Champion Groups 62
Workgroup Webinar Sessions 65
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VI. ALTERNATIVE FUEL INFRASTRUCTURE PROJECT READINESS CRITERIA 70
VII. FLEET AND FUEL PROVIDER SURVEY RESULTS 75
Survey Results In and Of Themselves Are Incomplete: Refer to Sections IX and VIII for Full and
Final Results and Takeaways 75
Fleet Survey Results - Key Takeaways 76
Respondent Profiles 76
Fuel Type Preferences and Fuel Demand 76
Funding Needs 76
Infrastructure Projects Underway 76
Infrastructure Project Proposals 77
Fuel Provider Survey Results - Key Takeaways 77
Respondent Profiles 77
Alternative Fuel Infrastructure Development Plans 77
Average Annual Fuel Demand Required for Station Development 77
Funding Needs for Station Development 77
Infrastructure Projects Underway 78
Infrastructure Project Proposals 78
VIII. CONCLUSIONS AND RECOMMENDATIONS 79
A Note Regarding Section IX: List of Project Proposals and Readiness for Funding 79
Conclusions 79
Recommendations for AFICC Partners 82
IX. LIST OF PROJECT PROPOSALS AND READINESS FOR FUNDING 86
Proposal Listings by State 87
California Only 87
Oregon Only 95
Washington Only 99
Proposal Listings by Fuel Type 102
Electric Vehicle Charging 102
Hydrogen 108
Liquefied Petroleum Gas (Propane) 110
Compressed Natural Gas Ill
Liquefied Natural Gas 114
Other Fuel Types 115
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Proposal Readiness Listing by State 116
California 117
Oregon 119
Washington 121
Proposal Readiness Listing by Fuel Type 122
Electric Vehicle Charging 122
Hydrogen 124
Liquefied Petroleum Gas (Propane) 125
Compressed Natural Gas 126
Liquefied Natural Gas 127
Other Fuel Types 128
Existing and Proposed Infrastructure Maps 129
X. APPENDIX A: ADDITIONAL INFRASTRUCTURE SITE MAPS 138
XI. APPENDIX B: ENVIRONMENTAL JUSTICE CONSIDERATION TABLES 144
XII. APPENDIX C: FLEET AND FUEL PROVIDER SURVEY RESULTS 149
Fleet Survey Results 149
Fuel Provider Survey Results 166
XIII. APPENDIX D: Endnotes 185
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I. LIST OF ACRONYMS
AFICC Alternative Fuel Infrastructure Corridor Coalition
AFV Alternative Fuel Vehicle; includes: BEVs, FCEVs, NGVs, PHEVs and propane vehicles
AQIP California Air Resources Board Air Quality Improvement Program
AQMD Air Quality Management District
ARFVTP California Energy Commission Alternative and Renewable Fuel and Vehicle Technology
Program, now known as the Clean Transportation Program
BEV Battery-Electric Vehicle
CALeVIP California Energy Commission Electric Vehicle Infrastructure Project
Caltrans California Department of Transportation
CAPEX Capital Expense
CARB California Air Resources Board
CNG Compressed Natural Gas
CEC California Energy Commission
CPUC California Public Utilities Commission
DGE Diesel Gallon Equivalent1
DOE United States Department of Energy
EPA United States Environmental Protection Agency
EV Electric Vehicle
EVSE Electric Vehicle Supply Equipment
FAST Fixing America's Surface Transportation
FCEV Fuel Cell Electric Vehicle
FHWA United States Department of Transportation, Federal Highway Administration
gal Gallons
GHG Greenhouse Gas
GVWR Gross Vehicle Weight Rating
1 Some survey and outreach participants reported fuel volumes for CNG and LNG in gasoline gallon equivalent
(GGE). Throughout this strategic plan, wherever outreach participants reported volumes in GGE, those values were
multiplied by 1.13 to derive a volume in diesel gallon equivalent (DGE), per:
https://afdc.energy.gov/fuels/equivalencv methodology.html
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H2 Hydrogen
HVIP CARB Hybrid and Zero-Emission Truck and Bus Voucher Incentive Project
IOU Investor Owned Utility
kg Kilogram
kWh Kilowatt-Hour
lbs Pounds
LNG Liquefied Natural Gas
LPG Liquefied Petroleum Gas/Propane
MHDV Medium-and Heavy-Duty Vehicle
MOU Memorandum of Understanding
MSRC Mobile Source Air Pollution Reduction Review Committee
MW Megawatt
NAAQS National Ambient Air Quality Standards
NGV Natural Gas Vehicle; vehicles powered by CNG or LNG
NREL National Renewable Energy Laboratory
ODOT Oregon Department of Transportation
OEM Original Equipment Manufacturer
PEV Plug-In Electric Vehicle; includes: BEVs and PHEVs
PHEV Plug-in Hybrid Electric Vehicle
PUD Public Utility District
RNG Renewable Natural Gas
SB Senate Bill
SCAQMD South Coast Air Quality Management District
SELP State Energy Loan Program
US DOT United States Department of Transportation
VTO United States Department of Energy, Vehicle Technologies Office
WCC West Coast Collaborative
WSDOT Washington State Department of Transportation
ZEV Zero Emission Vehicle, includes: BEVs, FCEVs and PHEVs
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II. EXECUTIVE SUMMARY
This document presents the Strategic Development Plan of the West Coast Collaborative Alternative Fuel
Infrastructure Corridor Coalition (WCC AFICC) for medium and heavy-duty (MHD) alternative fuel
infrastructure in California, Oregon, and Washington. The West Coast Collaborative (WCC) is a United
States Environmental Protection Agency (EPA) led public-private partnership including representatives
from federal, state, local, and tribal governments, as well as the private sector, academia, and
environmental groups, all with a stated goal to reduce diesel emissions. In 2017, the WCC formed the
Alternative Fuel Infrastructure Corridor Coalition (AFICC), a partnership committed to accelerating the
modernization of West Coast transportation corridors by deploying alternative fuel infrastructure for
medium- and heavy-duty vehicles (MHDVs). Consistent with the United States Department of
Transportation Federal Highway Administration's (FHWA's) Alternative Fuel Corridor Program; the fuels
covered under this effort include plug-in electric vehicle charging (EV), hydrogen (H2), propane (LPG), and
compressed and liquefied natural gas (CNG and LNG). Since its formation, the AFICC has focused its efforts
on evaluating regional priorities within West Coast states for MHD alternative fuel infrastructure,
understanding MHD infrastructure investment needs, and identifying projects suitable for funding when
it is available to support MHD alternative fuel corridor development.
To help states and industry partners improve coordination and prioritization for infrastructure
development, this strategic plan provides important context for policies and programs aimed at
supporting deployment of alternative fuels in the three West Coast states. Secondly, AFICC's engagement
process to collect feedback on infrastructure needs is carefully described and shares best practices and
methods to evaluate infrastructure projects depending on maturity and development readiness. Lastly,
recommendations are provided to help AFICC partners meet MHD alternative fuel infrastructure
expansion goals on the West Coast. This strategic plan is intended as a living document to highlight the
strong evidence of projects in need of funding, and ways the Coalition can continue to advance solutions
for MHD alternative fuel transportation corridors. California, Oregon, and Washington State Departments
of Transportation and Metropolitan/Regional Transportation Planning Organizations (MPOs/RTPOs) are
encouraged to use this Strategic Development Plan to help advance MHD alternative fuel infrastructure
development and implementation in their jurisdictions. The WCC also encourages other regions of the
U.S. to replicate this project by developing their own partnerships to assess local demand for MHD
alternative fuel infrastructure development.
As the market for alternative fuel vehicles (AFVs) grows, so does the need for alternative fuel
infrastructure, and vice versa. Currently, diesel-fueled vehicles make up the majority of MHDVs on the
road in the United States. However, market forces and state policies, such as mandates to drastically
reduce mobile source emissions for purposes of National Ambient Air Quality Standards (NAAQS)
attainment, toxic air contaminant exposure reduction, and climate change mitigation are increasing
demand for MHD AFVs. This projected increase in demand, and the goals to reduce emissions from
transportation on the West Coast, serve as key drivers for the WCC AFICC's efforts to understand MHD
alternative fuel infrastructure investment needs in California, Oregon, and Washington.
CALSTART, a national clean transportation non-profit organization, was selected through a competitive
solicitation to facilitate the WCC AFICC and assist the Coalition in conducting a regional infrastructure
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needs assessment and drafting a strategic plan outlining near-term development opportunities along
West Coast corridors. There are six core AFICC objectives to advance a strategy and effort to expand
alternative fuel corridors in California, Oregon, and Washington:
1. Convene a stakeholder coalition focused on MHD alternative fuel infrastructure development.
2. Conduct stakeholder workgroups and targeted outreach to identify a subset of desired and/or
unfunded MHD alternative fuel stations.
3. Synthesize stakeholder input into a plan document.
4. Provide a platform for sharing MHD alternative fuel infrastructure investment needs.
5. Use the plan as the basis for joint applications to competitive funding programs.
6. Obtain funding assistance to help implement MHD alternative fuel infrastructure in California,
Oregon, and Washington.
The efforts presented in this strategic plan represent those conducted to meet objectives (1), (2), (3) and
(4) in preparation for pursuing objectives (5) and (6).
To start the strategic planning process, AFICC facilitated numerous workgroup sessions for WCC Partners
and other stakeholders in California, Oregon, and Washington. Through these workgroup sessions, AFICC
collected feedback on which research questions would help to identify viable MHD alternative fuel
infrastructure projects for development. These workgroup sessions were attended by stakeholders with
varying perspectives, including but not limited to federal, state, and local government agencies, private
sector entities such as fleets, infrastructure providers, original equipment manufacturers (OEMs), Clean
Cities Coalitions, utilities, port authorities, and environmental groups. With the feedback obtained from
these sessions, AFICC started its next step in conducting an infrastructure needs assessment.
AFICC developed project readiness criteria which served as guiding considerations for evaluating
infrastructure project proposals. The readiness criteria helped AFICC develop two surveys to obtain
information on infrastructure needs from fleets and fuel providers. Both surveys sought to understand
MHD alternative fuel infrastructure needs, required funding for MHD infrastructure development, and
proposals on where to locate infrastructure that benefit MHD fleets most. Once developed, AFICC
distributed the surveys to a wide audience using the combined networks of WCC partners.
The surveys yielded responses from 26 fleets and 31 fuel providers from organizations in all three states.
This included responses from MHD fleets across a variety of vocations, including but not limited to food
and beverage distribution, drayage, transit, cargo handling, and school districts. Along with MHD
infrastructure project proposals received through responses to these two surveys, the AFICC received
additional proposals through follow-up outreach to various partners outside of the surveys. These two
methods yielded a handful of important takeaways, as described below.
There is significant and proven demand for MHD alternative fuel infrastructure in all three West Coast
states: California, Oregon, and Washington.
First, the surveys found that all fleet respondents are interested in procuring MHD AFVs within the next
five years, creating an increased demand for MHD alternative fueling stations throughout the West Coast.
Fleets expressed interest in all alternative fuel types in the AFICC purview, with electricity being the most
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popular choice with 81% of respondents stating an interest in procuring MHD plug-in electric vehicles
(PEVs).
Fuel providers also shared similar interest and plans to develop MHD alternative fuel infrastructure
throughout the West Coast. Most fuel providers surveyed stated plans to develop MHD alternative fuel
infrastructure in California within the next three to five years. Of those planned projects, most were EV
charging stations, followed by CNG, H2, LPG, and LNG. The assessment received a lower response in
developing MHD alternative fuel stations in Oregon and Washington, with most fuel providers stating that
they did not have current plans to build infrastructure in those states. Those that do have plans, however,
are most interested in building EV charging stations.
Combined, the survey respondents and outreach participants proposed 147 alternative fuel infrastructure
projects on the West Coast: 67 in California, 57 in Oregon, and 23 in Washington. Project proposals were
received for all five fuel types within the AFICC planning scope: 62 EV charging stations, 36 CNG stations,
23 H2 stations, 13 LPG stations, and 7 LNG stations. Some participants also proposed technologies outside
the AFICC planning scope: 5 catenary electric infrastructure projects; and, 1 liquid biofuel station.
Fleets and fuel providers alike have a significant need for funding assistance to develop both new MHD
alternative fuel infrastructure and to expand existing alternative fuel infrastructure projects.
Most fleet survey respondents required funding support to purchase and install new MHD alternative fuel
infrastructure: 73% of fleet respondents require funding support to justify the decision to install
infrastructure, 8% stated that they do not need funding support, and 19% stated that they do not know if
they need funding support. Likewise, most fleet respondents currently developing alternative fuel
infrastructure have a need for additional funding support: 68% of fleet respondents indicated they need
additional funding for current projects to support a variety of uses, including but not limited to the
following examples: purchasing equipment and materials, adding gas compression capacity, and
expanding project scope.
Regarding funding needs, CALSTART solicited information via fleet and fuel provider surveys as well as
additional outreach via phone calls. When asked what percentage of the total capital expense (CAPEX) of
installing an alternative fueling station must be covered for them to consider development, 28% of these
combined outreach participants' infrastructure proposals stated that at least 50% of the CAPEX must be
covered by external funding, followed by 14% of proposals that said 70% of CAPEX should be covered, and
then a tie between 30% and 80% of CAPEX at 9% of proposals each. Less than 1% of proposals stated that
100% of the CAPEX must be covered by funding, and nearly 22% of proposals did not list a minimum
funding need amount. The remaining ~17% of proposals stated other funding amounts needed at lower
frequencies than those listed above. Effectively, 77% of all proposals would be viable for development
with external funding assistance up to 80% of project CAPEX.
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MHD alternative fuel infrastructure development is already underway in many locations throughout
West Coast states, and many of those projects require additional funding support.
When surveyed, 65% of fleet respondents had MHD alternative fuel projects underway with varying fuel
types, fleet sizes, locations, and timelines. Of those projects listed, 65% are EV projects, 26% are CNG
stations, and a smaller share are LNG and H2 projects, at 9% and 4% respectively. 22% of fleet survey
respondents with projects underway stated that they were for other fuel types, including renewable
diesel. Most projects underway are private access stations and are likely located within the respondents'
facilities. These existing projects may well serve as starting points for MHD alternative fuel infrastructure
expansion on the West Coast, but given their private nature, more public and limited access stations
would be needed to expand MHD AFV corridor fueling.
Survey respondents and other partners provided 147 specific proposals for MHD alternative fuel
infrastructure placement. These proposals only represent a small portion of MHD alternative fuel
infrastructure development needs on the West Coast as of December 2019.
As stated in an earlier takeaway, survey respondents and other partners provided 147 unique proposals
for alternative fuel infrastructure development in California, Oregon, and Washington. This represents the
number of proposals made to the AFICC as of December 2019 and does not fully capture all the MHD
alternative fuel infrastructure development needs on the West Coast.
The West Coast Collaborative believes that the infrastructure development project proposals listed in this
document, captured through responses to surveys and other targeted outreach, only cover a small
percentage of the full need for comprehensive MHD alternative fuel infrastructure access on the West
Coast, and it welcomes feedback on additional infrastructure needs not reflected in this document.
Table 1 shows all project proposals by fuel type and state.
Table 1 Project Proposal Numbers by Fuel Type and State
EV
H2
LPG
CNG
LNG
Other"
Totals
California
34
6
6
16
0
5
67
Oregon
15
14
5
17
5
1
57
Washington
13
3
2
3
2
0
23
Totals
62
23
13
36
7
6
147
Table 4 through Table 6 below show each proposal per state. Additionally, Figure 1 shows all proposed
sites mapped by their locations. All but 20 proposals were evaluated based on a standard set of criteria
" This column includes 5 catenary electric infrastructure projects proposed in California, and 1 liquid biofuel station
proposed in Redmond, Oregon. Per Section 1413 of the Fixing America's Surface Transportation (FAST) Act, these
technologies are outside the scope of this plan (see Section IV, Federal Policy Landscape), and were note evaluated.
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to vet projects for development readiness.1" These project proposals were evaluated on the readiness
criteria outlined in Section VI. Subsequently, each project was grouped into one of three readiness
categories based on those evaluations. The readiness categories are defined below. The cut-offs between
each of these three readiness categories were made quantitatively based on the results from evaluations
using the readiness criteria defined in Section VI, Table 15.
1. Advanced Site: Advanced Sites are the project proposals deemed most ready for development.
These sites have a high degree of readiness for funding and development. For example, this could
be a proposal that includes a location which is highly specific (e.g. a street address, city, and state),
a clear estimate of annual fuel throughput, a location near a major west coast corridor, and a
clearly defined CAPEX estimate.
2. Emerging Site: Emerging Sites are the second to most ready for development, behind Advanced
Sites. These sites are considered less ready for funding and development than Advanced Sites,
but more so than Potential Sites. These proposals were often deemed less ready than Advanced
Sites due to a lack of information about project scope. For example, this could be a proposed site
with demonstrated demand for fuel but lacking a specific location (e.g. proposing a county instead
of a cross street or address).
3. Potential Site: Potential Sites are the proposals deemed least ready for development. The reasons
for the lower readiness category vary across proposals, but often the project scope for these
proposals is vague or is lacking responses to multiple readiness criteria metrics. For example, this
could be a proposed site with a vague location (e.g. proposing location on a certain highway near
a city, but with no address or cross street), and not many associated details (e.g. no listing for
annual throughput or number of vehicles that the station is expected to support, no response on
the amount of funding needed, and no listing for estimated CAPEX).
111 20 of the 147 proposed projects were not evaluated: 6 proposals were outside the technological scope of this plan,
and 14 proposals did not contain enough information to properly evaluate them.
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Estimated cost to build the 141 proposed stations for targeted alternative fuel technologies is
$373,600,000.IV
This plan includes 141 proposed stations of various size, throughput, and level of construction for targeted
alternative fuel technologies.IV Based on CALSTART's estimates, it would cost approximately $373,600,000
to fund the development of all 141 sites, assuming they were newly constructed, capable of
accommodating MHD AFVs, and had average throughput and size levels. Again, these 141 sites do not
represent the total need on the West Coast, therefore $373,600,000 does not represent the total funding
amount needed to provide comprehensive MHD alternative fuel infrastructure access in California,
Oregon, and Washington.
Table 2 Estimated Funding Needed to Build Proposed Infrastructure Projects in the AFICC Planv vl
Number of Sites
Average
Fueling
Proposed by
Average Assumptions for Each
Estimated
Total Cost
Type
Outreach
Participants
Station
CAPEX Per
Station
EV
62
750kW-lMW Peak Capacity
$2,000,000
$124,000,000
H2
23
1,000-4,800 kg/Day
$6,000,000
$138,000,000
LPG
13
1,000 gallons/Day
$1,700,000
$22,100,000
CNG
36
1,695-2,260 DGE/Day
$2,000,000
$72,000,000
LNG
7
1,695-2,260 DGE/Day
$2,500,000
$17,500,000
Total
141
$373,600,000
Table 3 Estimated Funding Needed to Build Proposed Infrastructure Projects by State
State
Number of Stations by Fuel Type
Total Cost
EV
H2
LPG
CNG
LNG
California
34
6
6
16
0
$146,200,000
Oregon
15
14
5
17
5
$169,000,000
Washington
13
3
2
3
2
$58,400,000
Total
62
23
13
36
7
$373,600,000
lv Cost estimate does not include catenary electric, or liquid biofuel proposals (6 projects omitted).
v CAPEX estimate does not represent the total funding needed to deploy comprehensive MHD alternative fueling
infrastructure in California, Oregon, and Washington; only includes proposals obtained through AFICC outreach.
Vl Table does not include catenary electric, or liquid biofuel infrastructure proposals (6 projects omitted) as these
technologies are outside the AFICC planning scope.
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Based on the results of AFICC's outreach and surveying efforts, CALSTART offers the following
recommendations to advance the Coalition's goals in meeting objectives (5) and (6) listed above:
1. State Plans -Take the learnings from this plan document and develop targeted MHD alternative fuel
infrastructure investment plans per state.
2. Alternative Fuel Policy - Examine, in more detail, the state-level policy barriers to alternative fuel
infrastructure deployment and develop policies that support accelerated MHD infrastructure project
implementation.
3. Communication and Outreach - Share this strategic plan document throughout the WCC and with
partners around the nation.
4. Public Funding Assistance - WCC partners are well positioned to both fundraise for MHD alternative
fuel infrastructure development and to petition for increased public funding support.
5. Implementation - All parties interested in developing alternative fuel infrastructure are encouraged
to leverage the information gathered through this effort for purposes of implementing the projects
listed within this plan.
6. Workforce Development - Consider workforce development opportunities which are likely to arise as
a result of MHD alternative fuel infrastructure development on the West Coast.
7. Environmental Justice - MHD infrastructure development in environmental justice communities
should be prioritized where there is synergy with alternative fuel demand.
8. Sustained Partnership - The partnerships formed between WCC AFICC partners should be sustained,
and other geographic regions are encouraged to replicate the WCC AFICC through similar regional
partnerships across the United States.
By following through with these recommendations, the WCC AFICC can work toward achieving its stated
goal of deploying alternative fuel infrastructure for MHD vehicles and equipment along the West Coast of
the United States.
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Figure 1 All Proposed MHD Alternative Fuel Infrastructure Sites
Sites
a Proposed Sites, Electric
* Proposed Sites, Hydrogen
* Proposed Sites, CNG
Proposed Sites, LNG
* Proposed Sites, LPG
Portland
San Francisco
Basemap
Major US Highways
I I States Boundaries of the United States
250
500 km
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Table 4 Proposed Alternative Fuel Infrastructure Projects by Readiness Category - Californiav"
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput / # of Vehicles
the Station Would Serve
Reported
CAPEX
Estimate
Funding
Needed(%
of CAPEX)
Readiness
Category
CA-1
EV
CA
Banta
1-5 & 1-205
750 kW minimum (1 MW
ideal)
$2,017,499
(Reported)
50%
Advanced
CA-2
EV
CA
Barstow
1-15 & 1-40
750 kW minimum (1 MW
ideal)
$2,017,499
50%
Advanced
CA-3
EV
CA
Blythe
1-10 & CA-78
750 kW minimum (1 MW
ideal)
$2,017,499
50%
Advanced
CA-4
EV
CA
Fresno
CA-99 & CA-41
750 kW minimum (1 MW
ideal)
$2,017,499
50%
Advanced
CA-5
EV
CA
Hamburg
Farms
1-5 & CA-165
750 kW minimum (1 MW
ideal)
$2,017,499
50%
Advanced
CA-6
EV
CA
Long Beach
301
Mediterranean
Way, Long Beach
CA
50 vehicles
Not reported by
participant; See
Table 7 for
estimated average
CAPEX
30%
Advanced
CA-7
EV
CA
Long Beach
Port of Long
Beach Terminal
N/A
$2,250,000
90%
Advanced
CA-8
EV
CA
National City
1-5 & CA-54
200 truck trips a day
Not reported by
participant; See
Table 7 for
estimated average
CAPEX
N/A
Advanced
CA-9
EV
CA
Red Bluff
1-5 & CA-3 6
6 vehicles
$100,000
50%
Advanced
CA-10
EV
CA
Redding
1-5 & CA-44
6 vehicles
$100,000
50%
Advanced
CA-11
EV
CA
Sacramento
1-80 & US-50
750 kW minimum (1 MW
ideal)
$2,017,499
50%
Advanced
v" The proposals marked "Unevaluated" did not contain enough data to properly evaluate them.
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Reported CAPEX
Estimate
Funding
Needed (%
Of CAPEX)
Readiness
Category
CA-12
EV
CA
San
Bernardino
1535 West 4th
St San
Bernardino, CA
92411
7 electric hostlers, 2
electric service trucks, 1
hybrid RTG, 1 electric
side loader, 1 electric
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
Advanced
drayage truck
CA-13
EV
CA
San Diego
1-5 & 1-8
200 truck trips a day
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Advanced
CA-14
EV
CA
Weaverville
CA-299 & CA-44
6 vehicles
$100,000
50%
Advanced
CA-15
EV
CA
Williams
1-5 & CA-20
750 kW minimum (1 MW
ideal)
$2,017,499
50%
Advanced
CA-16
EV
CA
Willow Creek
CA-299 & CA-96
6 vehicles
$100,000
50%
Advanced
CA-17
EV
CA
Willows
1-5 & CA-162
6 vehicles
$100,000
50%
Advanced
CA-18
H2
CA
Long Beach
1926 East Pacific
Coast Highway
547,500 kg (12 vehicles)
(assuming 365 days)
$10,000,000
80-85%
Advanced
CA-19
H2
CA
Ontario
4325 East Guasti
Road
547,500 kg (12 vehicles)
(assuming 365 days)
$10,000,000
80-85%
Advanced
CA-20
H2
CA
Redding
1-5 & CA-44
365,000 kg (assuming
365 days)
$4,000,000
30-100%
Advanced
CA-21
LPG
CA
Corona
CA-91 & 1-15
200,000 Gallons (50-60
vehicles)
$110,000
30-40%
Advanced
CA-22
LPG
CA
Duarte
1-605 & 1-210
200,000 Gallons (50-60
vehicles)
$110,000
30-40%
Advanced
CA-23
LPG
CA
Hawthorne
N/A
200,000 Gallons (50-60
vehicles)
$110,000
30-40%
Advanced
CA-24
LPG
CA
Norwalk
1-605 & 1-105
200,000 Gallons (50-60
vehicles)
$110,000
30-40%
Advanced
12 |
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Reported CAPEX
Estimate
Funding
Needed (%
of CAPEX)
Readiness
Category
CA-25
LPG
CA
Ontario
1-10 & 1-15
200,000 Gallons (50-60
vehicles)
$110,000
30-40%
Advanced
CA-26
LPG
CA
Sherman
Oaks
US-101 & 1-405
200,000 Gallons (50-60
vehicles)
$110,000
30-40%
Advanced
CA-27
CNG
CA
Bellflower
15330 Woodruff
Ave., Bellflower,
CA 90706
791,000 DGE
$2,750,000
20%
Advanced
CA-28
CNG
CA
Gardena
14800 South
Spring St.,
Gardena CA
90248
60 CNG tractors
$4,000,000
80%
Advanced
CA-29
CNG
CA
Lost Hills
1-5 & CA-46
339,000 DGE (8-10
vehicles)
Not reported by
participant; See Table 7
for estimated average
CAPEX
40-60%
Advanced
CA-30
CNG
CA
Lost Hills
1-5 & CA-46
N/A
$1,000,000
N/A
Advanced
CA-31
CNG
CA
Near
Kettleman
City
1-5 & CA-41
N/A
$1,000,000
N/A
Advanced
CA-32
CNG
CA
Tehachapi
CA-58 & CA-58B
339,000 DGE (8-10
vehicles)
N/A
40-60%
Advanced
CA-33
EV
CA
Bakersfield
N/A
70 vehicles
N/A
0%
Emerging
CA-34
EV
CA
Barstow
2825 W. Main
St. Barstow, CA
92311
N/A
N/A
50%
Emerging
13 |
-------�
Number
Fuel Type
Proposed
State
Proposed City
or County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
CA-35
EV
CA
Los Angeles /
Hobart
4000 East Sheila
St Los Angeles,
CA 90023
10 electric hostlers,
1 electric service
truck
N/A
50%
Emerging
CA-36
EV
CA
Stockton
6450 South
Austin Rd.
Stockton, CA
95215
6 electric hostlers, 1
hybrid RTG
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
CA-37
CNG
CA
Barstow
1-15 & Lenwood
Road
339,000 DGE (8-10
vehicles)
Not reported by
participant; See Table
7 for estimated
average CAPEX
40-60%
Emerging
CA-38
CNG
CA
Coachella
1-10 & Dillon
Road
339,000 DGE (8-10
vehicles)
Not reported by
participant; See Table
7 for estimated
average CAPEX
40-60%
Emerging
CA-39
CNG
CA
Near
Bakersfield
1-5 & CA-119
N/A
$1,000,000
N/A
Emerging
CA-40
CNG
CA
Riverside
County
N/A
225 vehicles
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
CA-41
CNG
CA
Riverside
County
N/A
225 vehicles
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
CA-42
CNG
CA
San Bernardino
County
N/A
225 vehicles
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
CA-43
CNG
CA
San Bernardino
County
N/A
225 vehicles
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
CA-44
CNG
CA
San Bernardino
County
N/A
225 vehicles
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
14 |
-------�
Number
Fuel Type
Proposed
State
Proposed City
or County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
CA-45
CNG
CA
San Bernardino
County
N/A
225 vehicles
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Emerging
CA-46
EV
CA
Bakersfield
Bakersfield, CA
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
Potential
CA-47
EV
CA
Between Los
Angeles &
Santa Barbara
US-101
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-48
EV
CA
Between
Sacramento &
San Francisco
1-80
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-49
EV
CA
Grapevine
1-5 &
Edmonston
Pumping Plant
Road
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
Potential
CA-50
EV
CA
Inland Empire
1-15
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-51
EV
CA
Inland Empire
Warehouse
Districts Around
Inland Empire
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-52
EV
CA
Long Beach
Port of Long
Beach
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-53
EV
CA
Long Beach
Port of Long
Beach Terminal
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
Potential
15 |
-------�
Estimated Annual
Funding
Needed
(% of
CAPEX)
Number
Fuel Type
Proposed
State
Proposed City
or County
Proposed
Address or
Interchange
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Reported CAPEX
Estimate
Readiness
Category
Not reported by
CA-54
EV
CA
Los Angeles
1-10
N/A
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-55
EV
CA
Los Angeles
Warehouse
Districts Around
Los Angeles
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
CA-56
EV
CA
Los Angeles
Port of Los
Angeles
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
Potential
Not reported by
CA-57
EV
CA
Near Coalinga
1-5 & CA-198
N/A
participant; See Table
7 for estimated
average CAPEX
N/A
Potential
Not reported by
CA-58
EV
CA
Near Los Banos
1-5 & CA-152
N/A
participant; See Table
7 for estimated
average CAPEX
N/A
Potential
Not reported by
CA-59
H2
CA
Long Beach
1-710 & 1-405
N/A
participant; See Table
7 for estimated
average CAPEX
20%
Potential
Not reported by
CA-60
CNG
CA
Bakersfield
Bakersfield, CA
N/A
participant; See Table
7 for estimated
average CAPEX
N/A
Potential
Not reported by
CA-61
H2
CA
Sacramento
N/A
N/A
participant; See Table
7 for estimated
average CAPEX
N/A
Unevaluated
Not reported by
CA-62
H2
CA
Sacramento
N/A
N/A
participant; See Table
7 for estimated
average CAPEX
N/A
Unevaluated
CA-63
Catenary
Electric
CA
Between East
Los Angeles
and Riverside
CA-60 (East LA
to Riverside)
6000 trucks per day
per direction
$5-8.7M /Mile
0%
Unevaluated
16 |
-------�
Number
Fuel Type
Proposed
State
Proposed City
or County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
CA-64
Catenary
Electric
CA
Between Los
Angeles and
Las Vegas
1-15 Los Angeles
to Las Vegas
6000 trucks per day
per direction
$5-8.7M /Mile
0%
Unevaluated
CA-65
Catenary
Electric
CA
Between
Mettler and
Sacramento
CA-99 (Mettler
to Sacramento)
6000 trucks per day
per direction
$5-8.7M /Mile
0%
Unevaluated
CA-66
Catenary
Electric
CA
Between San
Diego and
Redding
1-5 (San Diego to
Redding)
6000 trucks per day
per direction
$5-8.7M /Mile
0%
Unevaluated
CA-67
Catenary
Electric
CA
Los Angeles
County
1-710
14,000 trucks per
day and direction
$8.7M/Mile
0%
Unevaluated
17 |
-------�
Table 5 Proposed Alternative Fuel Infrastructure Projects by Readiness Category - Oregon"
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
OR-1
EV
OR
Bend
US-20 & US-
97
750 kW minimum (1
MW ideal)
$2,017,499
50%
Advanced
OR-2
EV
OR
Bend
US-97 & US-
20
500 vehicles @
350kW
$100,000
70%
Advanced
OR-3
EV
OR
Boardman
1-84 & South
Main Street
500 vehicles @
350kW
$100,000
70%
Advanced
OR-4
EV
OR
Eugene
1-5 &OR-126
500 vehicles @
350kW
$100,000
70%
Advanced
OR-5
EV
OR
La Grande
1-84 & OR-82
500 vehicles @
350kW
$100,000
70%
Advanced
OR-6
EV
OR
Medford
1-5 & OR-62
500 vehicles @
350kW
$100,000
70%
Advanced
OR-7
EV
OR
Ontario
1-84 & US-30
500 vehicles @
350kW
$100,000
70%
Advanced
OR-8
EV
OR
Pendleton
1-84 & US-395
500 vehicles @
350kW
$100,000
70%
Advanced
OR-9
EV
OR
Portland
1-84 & 1-205
30 vehicles
$2,000,000
50%
Advanced
OR-IO
EV
OR
Portland
1-5 & 1-405
500 vehicles @
350kW
$100,000
70%
Advanced
OR-11
EV
OR
Salem
1-5 & OR-22
500 vehicles @
350kW
$100,000
70%
Advanced
OR-12
EV
OR
The Dalles
1-84 & US-197
500 vehicles @
350kW
$100,000
70%
Advanced
Vl" The proposals marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
18 | P a g e
-------�
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
OR-13
H2
OR
Eugene
1-5 & 1-105
365,000 kg/year
$4,000,000
30-
100%
Advanced
OR-14
H2
OR
Grants Pass
1-5 & CA-99
365,000 kg/year
$4,000,000
30-
100%
Advanced
OR-15
H2
OR
Portland
1-5 & 1-84
365,000 kg/year
$4,000,000
30-
100%
Advanced
OR-16
LPG
OR
Boardman
1-84 & South
Main Street
3000 DGE/Hour
$100,000
50-60%
Advanced
OR-17
LPG
OR
Ontario
1-84 & US-30
3000 DGE/Hour
$100,000
50-60%
Advanced
OR-18
LPG
OR
Pendleton
1-84 & US-395
3000 DGE/Hour
$100,000
50-60%
Advanced
OR-19
LPG
OR
Roseburg
1-5 & SE Oak
Avenue
3000 DGE/Hour
$100,000
50-60%
Advanced
OR-20
LPG
OR
The Dalles
1-84 & US-197
3000 DGE/Hour
$100,000
50-60%
Advanced
OR-21
CNG
OR
Bend
US-97 & US-
20
500 DGE/Hour
$1,500,000
70%
Advanced
OR-22
CNG
OR
Boardman
1-84 & South
Main Street
500 DGE/Hour
$1,500,000
70%
Advanced
OR-23
CNG
OR
La Grande
1-84 & OR-82
500 DGE/Hour
$1,500,000
70%
Advanced
OR-24
CNG
OR
Ontario
1-84 & US-30
500 DGE/Hour
$1,500,000
70%
Advanced
OR-25
CNG
OR
Pendleton
1-84 & US-395
500 DGE/Hour
$1,500,000
70%
Advanced
OR-26
CNG
OR
Portland
1-205 & Sandy
Boulevard
40 vehicles
$1,000,000
50-70%
Advanced
OR-27
CNG
OR
The Dalles
1-84 & US-197
500 DGE/Hour
$1,500,000
70%
Advanced
OR-28
CNG
OR
Umatilla
1-82 & US-730
30 vehicles
Not reported by
participant; See Table 7
for estimated average
CAPEX
70%
Advanced
OR-29
CNG
OR
Woodburn
OR-214 & 1-5
40 vehicles
$1,000,000
50-70%
Advanced
19 |
-------�
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
OR-30
LNG
OR
Eugene
1-5 & OR-58
5 vehicles
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Advanced
OR-31
LNG
OR
Portland
N/A
7,352 DGE (5
vehicles)/year
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Advanced
OR-32
LNG
OR
Portland
1-205 & 1-84
5 vehicles
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Advanced
OR-33
H2
OR
Bend
US-97 & US-
20
222,650 kg/year
$4,000,000
80%
Emerging
OR-34
H2
OR
Boardman
1-84 & South
Main Street
222,650 kg/year
$4,000,000
80%
Emerging
OR-35
H2
OR
Eugene
1-5 &OR-126
222,650 kg/year
(assuming 365 days)
$4,000,000
80%
Emerging
OR-36
H2
OR
La Grande
1-84 & OR-82
222,650 kg/year
$4,000,000
80%
Emerging
OR-37
H2
OR
Medford
1-5 & OR-62
222,650 kg/year
$4,000,000
80%
Emerging
OR-38
H2
OR
Ontario
1-84 & US-30
222,650 kg/year
$4,000,000
80%
Emerging
OR-39
H2
OR
Pendleton
1-84 & US-395
222,650 kg/year
$4,000,000
80%
Emerging
OR-40
H2
OR
Portland
1-5 & 1-405
222,650 kg/year
$4,000,000
80%
Emerging
OR-41
H2
OR
Salem
1-5 & OR-22
222,650 kg/year
$4,000,000
80%
Emerging
OR-42
H2
OR
The Dalles
1-84 & US-197
222,650 kg/year
$4,000,000
80%
Emerging
OR-43
CNG
OR
Baker City
N/A
30 vehicles
Not reported by
participant; See Table 7
for estimated average
CAPEX
70%
Emerging
OR-44
CNG
OR
Portland
1-5 & 1-405
500 DGE/Hour
$1,500,000
70%
Emerging
OR-45
CNG
OR
Salem
1-5 & OR-22
500 DGE/Hour
$1,500,000
70%
Emerging
20 |
-------�
Proposed
Address or
Interchange
Estimated Annual
Funding
Number
Fuel
Proposed
Proposed City or
Fuel Throughput / #
Reported CAPEX
Needed
Readiness
Type
State
County
of Vehicles the
Station Would Serve
Estimate
(% of
CAPEX)
Category
Not reported by
OR-46
LNG
OR
Hermiston
1-82 & 1-84
5 vehicles
participant; See Table 7
for estimated average
CAPEX
N/A
Emerging
Not reported by
OR-47
CNG
OR
Medford
N/A
30 vehicles
participant; See Table 7
for estimated average
CAPEX
70%
Potential
OR-48
EV
OR
Eugene
3500 E17th
Ave Eugene
OR 97403
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
Not reported by
OR-49
EV
OR
Hood River County
N/A
N/A
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
Not reported by
OR-50
EV
OR
Josephine County
N/A
N/A
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
Not reported by
OR-51
H2
OR
Portland
N/A
N/A
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
OR-52
CNG
OR
Eugene
3500 E17th
Ave Eugene
OR 97403
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
Not reported by
OR-53
CNG
OR
Eugene/Portland
1-5 Corridor
N/A
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
Not reported by
OR-54
CNG
OR
Portland
N/A
N/A
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
Not reported by
OR-55
CNG
OR
SE Portland
1-5 Corridor
33,900 DGE
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
21 |
-------�
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would Serve
Reported CAPEX
Estimate
Funding
Needed
(% of
CAPEX)
Readiness
Category
OR-56
LNG
OR
Eugene
3500 E17th
Ave Eugene
OR 97403
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
OR-57
Biofu
el
OR
Redmond
N/A
3-5 million gallons
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
Unevaluated
22 |
-------�
Table 6 Proposed Alternative Fuel Infrastructure Projects by Readiness Category - Washington1*
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would Serve
Reported CAPEX
Estimate
Funding
Needed (%
of CAPEX)
Readiness
Category
WA-1
EV
WA
Bellevue
1-405 & 1-5
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-2
EV
WA
Ellensburg
Main and
Washington
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-3
EV
WA
Kennewick
1-82 & US-395
750 kW minimum (1
MW ideal)
$2,017,499
50%
Advanced
WA-4
EV
WA
Olympia
Capital &
Jefferson
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-5
EV
WA
Spokane
Division &
Mission
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-6
EV
WA
Tacoma
Market &
Pacific Avenue
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-7
EV
WA
Yakima
Yakima & 4th
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-8
EV
WA
Yakima
Nob Hill & 1st
200 vehicles
Not reported by participant-
See Table 7 for estimated
average CAPEX
60-80%
Advanced
WA-9
H2
WA
Seattle
1-5 & 1-90
365,000 kg (assuming
365 days)
$4,000,000
30-100%
Advanced
WA-10
H2
WA
Tacoma
Tacoma
10,000 kg/day with
electrolyzer
production
$90,000,000x
10%
Advanced
WA-11
H2
WA
Tacoma
1-5 & WA-7
365,000 kg (assuming
365 days)
$4,000,000
30-100%
Advanced
lx The proposals marked "Unevaluated" did not contain enough data for evaluation.
x This proposal is for a 35 MW electrolysis station with an expected capacity of 10,000 kg/day. A hydrogen fueling station may or may not be included in the
project. CAPEX includes but is not limited to an electrolyzer, electrical connections to substations, transportation infrastructure, liquefaction, and storage.
23 | P a g e
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would Serve
Reported CAPEX
Estimate
Funding
Needed (%
of CAPEX)
Readiness
Category
WA-12
LPG
WA
Ellensburg
1-90 & 1-82
360,000 gallons
$1,700,000
25-50%
Advanced
WA-13
LPG
WA
Ritzville
1-90 & WA-261
360,000 gallons
$1,700,000
25-50%
Advanced
WA-14
EV
WA
Everett
Cedar and
Wentworth
N/A
MHD station not reported
by participant; See Table 7
for estimated average
CAPEX
0%
Emerging
WA-15
EV
WA
Everett
Cedar and
Pacific
N/A
MHD station not reported
by participant; See Table 7
for estimated average
CAPEX
0%
Emerging
WA-16
EV
WA
Everett
Cedar and
Pacific
10 buses, 5 small
vehicles
$292,000
50%
Emerging
WA-17
EV
WA
Seattle
Port of Seattle
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
Potential
WA-18
EV
WA
Tacoma
Tacoma
15 vehicles
$500,000
100%
Potential
WA-19
LNG
WA
Seattle
N/A
7,352 DGE (5
vehicles)
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
Potential
WA-20
LNG
WA
Spokane
N/A
7,352 DGE (5
vehicles)
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
Potential
WA-21
CNG
WA
Clark County
1-5 Corridor
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
Unevaluated
WA-22
CNG
WA
Vancouver
1-5 Corridor
113,000 DGE
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
Unevaluated
WA-23
CNG
WA
Washington
State
1-5 Corridor
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
Unevaluated
24 |
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III. INTRODUCTION
Transportation corridors are vital to the nation's economic growth and prosperity and are responsible for
the movement of goods and people. Interstate 5 (1-5), stretching 1,400 miles from the borders of Canada
to Mexico, is one of the most critical freight corridors in the United States. Running directly through the
states of California, Oregon and Washington, 1-5 serves as an international trade corridor supporting
multiple industries such as import and export trade and agriculture. Connecting to major routes such I-
90, 1-84, 1-80, 1-505, 1-15, and 1-405, 1-5 provides fundamental access to interstates, state highways, and
local roads enabling a crucial transportation network for major supply chains and goods movement.
Trucks and other medium and heavy-duty vehicles that consume diesel fuel also generate significant
emissions of harmful air pollution that is detrimental to public health. Though our economy depends on
transportation corridors, the vehicles that traverse these roads represent 29% of the nation's greenhouse
gas (GHG) emissions.1 While it is difficult to estimate the average number of trucks that travel along the
whole of the 1-5 on a daily basis, the California Department of Transportation (Caltrans) tracks the number
of vehicles that travel on the 1-5 at certain sections of the highway, as well as the percentage of those
vehicles that are trucks. As an illustrative example, in 2017 the highest volume of trucks traveling on any
section of the 1-5 was one near the junction of 1-205 in San Joaquin County at 40,128 trucks per day (26.4%
of all daily vehicle volume). Other sections of the 1-5 see different truck volumes and percentages, like the
1-580 junction in San Joaquin County, which had the highest truck percentage of total vehicle volume in
California at 49.6% of all vehicles per day (9,424 trucks per day).xl As population continues to increase (est.
30% by 2050) so will the number of trucks and buses that depend on our nation's corridors.
Advancing the development of alternative fuel infrastructure along 1-5 and other connecting routes will
increase the adoption of clean vehicles and equipment. Alternative fuel corridors are an effective
coordinating strategy to grow the clean vehicle marketplace, reduce energy dependence, improve air
quality, and increase economic and environmental sustainability of the U.S. transportation system. By
working across state boundaries, industries, and technologies, alternative fuel corridors can help states
meet critical air quality requirements, diversify energy systems, and increase access to diverse fueling
options for vehicle and equipment owners.
The West Coast Collaborative (WCC), a United States Environmental Protection Agency (EPA)-led public-
private partnership between leaders from federal, state, local and tribal governments, the private sector,
academia and environmental groups committed to reducing diesel emissions, have developed a regional
initiative entitled, the Alternative Fuel Infrastructure Corridor Coalition (AFICC). AFICC is an important
multi-state, multi-stakeholder initiative that seeks to advance station development for medium- and
heavy-duty alternative fuel vehicles along the 1-5 and other major connecting routes in California, Oregon,
and Washington. The coalition seeks to build upon the United States Department of Transportation
Federal Highway Administration's (FHWA) national program to designate alternative fuel corridors by
filling in infrastructure gaps and expanding corridors to enable electric vehicle charging, hydrogen,
propane, and natural gas fuel deployment.
Xl Direct consultation with Caltrans.
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Policies and partnerships in the three West Coast states have seen great success with the build-out of
electric corridors for passenger vehicles. FHWA has designated 1-5 as "Corridor-Ready" for light-duty
electric vehicle (EV) charging with numerous EV chargers across the region. Though, there have been
many efforts to incentivize infrastructure for light-duty EVs, more policies and incentives are needed to
advance alternative fuel infrastructure for medium- and heavy-duty vehicles. AFICC serves as a convening
platform to identify infrastructure projects that need funding and partnership assistance to be
implemented. In doing so, the Coalition supports other efforts seeking to expand alternative fuel corridors
that promote clean vehicle and equipment adoption/"
What is AFICC
In 2017, EPA leadership of the West Coast Collaborative organized a Steering Team to help develop the
mission, goals and objectives of the Alternative Fuel Infrastructure Corridor Coalition (AFICC). A meeting
was held with the Steering Team in April 2017 to review a draft organizational charter that outlined a
proposed plan to carry out the process of stakeholder engagement, outreach, industry feedback on
infrastructure needs, plan development and partner action-setting. Members of the Steering Team
included EPA, FHWA, U.S. DOT Volpe Center, state transportation, energy and environment offices, port
authorities, industry associations, Clean Cities Coalitions and utilities. EPA held calls with the Steering
Team to collect feedback and finalize the AFICC organizational charter and work plan.
EPA brought on contractor, CALSTART, a national clean transportation non-profit organization to help
facilitate and implement AFICC objectives in May 2018. CALSTART has led some of the nation's largest
emission reduction programs including clean corridor initiatives to advance alternative fuel vehicle
adoption. As the stakeholder engagement process began, AFICC's membership quickly grew as members
of the Steering Team assisted with identifying other critical partners that could provide value and help
inform the infrastructure planning process. To capture the unique needs, priorities and concerns of each
state, Champion Groups were established to ensure that communication and feedback was given regularly
respective to each state's interests and needs. CALSTART worked with EPA and the Champion Groups for
California, Oregon, and Washington to grow AFICC's membership to over 200 public and private partners.
Mission Statement
The mission of the West Coast Collaborative Alternative Fuel Infrastructure Corridor Coalition (WCC
AFICC) is to accelerate the modernization of West Coast transportation corridors by deploying alternative
fuel infrastructure for medium- and heavy-duty vehicles (MHDVs) in synergy with other investments.
Public-private collaboration to plan projects, leverage funding, and construct modernized corridors with
alternative fuel infrastructure will create jobs, increase domestic fuel supply diversity, reduce emissions,
improve public health and support more robust MHD fleet operations.
Partnership Objectives
Coalition partners work together to evaluate regional priorities, infrastructure needs and available
funding to support MHD alternative fuel corridor development. As a result of this innovative partnership
x" The West Coast Collaborative Alternative Fuel Infrastructure Corridor Coalition is not to be confused with the West
Coast Clean Transit Corridor Initiative: a study led by nine electric utilities on the West Coast, and on which CALSTART
is also a contractor, to determine how best to equip Interstate 5 with sufficient electric charging infrastructure for
medium- and heavy-duty battery-electric trucks.
26 I F
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and the subsequent build out of alternative fuel corridors, AFICC seeks to help advance deployment of
alternative fuel vehicles. MHDV fleets and the communities they serve will then be able to experience the
many benefits of alternative fuel vehicle operation. The AFICC's specific objectives are to:
1. Convene a stakeholder coalition focused on MHD alternative fuel infrastructure development.
2. Conduct stakeholder workgroups and targeted outreach to identify desired/unfunded MHD
alternative fuel stations.
3. Synthesize stakeholder input into a plan document.
4. Provide a platform for sharing MHD alternative fuel infrastructure investment needs.
5. Use the plan as the basis for joint applications to competitive funding programs.
6. Obtain funding assistance to help implement infrastructure in California, Oregon, and Washington
(i.e., electric vehicle charging, hydrogen, propane, and natural gas fueling for public and private MHD
fleets).
Partnership Roadmap
To accomplish the AFICC objectives, EPA and CALSTART developed a Partnership Roadmap to help define
the process for identifying infrastructure needs to advance West Coast MHD alternative fuel corridors.
The AFICC Partnership Roadmap outlines the steps taken to develop a process framework, execute
meaningful stakeholder engagement, assess infrastructure needs, and produce this strategic
development plan. Figure 2 below provides an overview of the Roadmap.
Figure 2: AFICC Partnership Roadmap
Present Outcomes to
AFICC Partnership Roadmap Partners^^^
Draft Stiatcgic Plan
• Include Themes & Priorities
• Outline Strategy & Actions
• Provide Re-commendations
• Estimate Project Costs 8. ID Funds
Conduct Infrastructure Needs Assessment
• Establish Project Criteria
• Survey Distribution (Fleets & Fuel Suppliers
« Collect and Evaluate Feedback
• Determine Readiness & Map Station Locations
jr
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Y Facilitate ~
Workgroup Sessions
[CA, OR & WA]
Collect Feedback, Compile
^ Info. & Research Q's^^
Establish Framework
» Define Workgroup Discussion Objectives
• ID Key Stakeholders
• ID Coalition-Supporting Resources
• ID Direct Outcomes
-------�
The following document presents AFICC's strategic development plan, which describes the important
learnings from the process carried out under the AFICC Partnership Roadmap, a prioritization of MHDV
infrastructure projects seeking funding for development, and partner recommendations to advance West
Coast alternative fuel corridors. It is the hope of AFICC and its partners to utilize the plan in leveraging
available public and private funding assistance to implement the highlighted projects. This plan is intended
to serve as a tool and living document for the West Coast Collaborative and AFICC members to support
ongoing interstate coordination, partnership development, and prioritization of programs and incentives
to increase infrastructure development and growth of alternative fuel corridors. California, Oregon, and
Washington State Transportation Agencies and Regional Metropolitan Planning Organizations are
encouraged to use the Strategic Development Plan to help advance alternative fuel infrastructure
development by supporting implementation of cited project opportunities located within their respective
jurisdictions.
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IV. MEDIUM-AND HEAVY-DUTY ALTERNATIVE FUEL VEHICLE TRENDS
Alternative Fuel Trends
There is an increase in the adoption of alternative fuel vehicles for personal and commercial use in the
United States, with myriad factors driving the demand for these vehicles. On the consumer side, drivers
and fleet managers recognize that with some initial investment, there can be significant cost savings when
switching to alternative fuels. Faced with challenging emission reduction mandates, public agencies are
implementing various policies and incentive programs to encourage consumers to adopt cleaner vehicles.
For all parties, there is the recognition that traditional fuels will become less available and more expensive
over time, motivating many to begin the proactive switch to alternative fuels.
Despite interest in the advancement of alternative fuels, there are still barriers that persist and make the
transition difficult for some. For instance, the higher upfront cost of both vehicles and infrastructure has
been prohibitive for many interested in adopting new fueling types. Public agencies have responded with
incentives and rebates to remedy this challenge, but these inducements have had a limited impact to
date, largely due to their limited scope and available resources. Another barrier is a lack of infrastructure
for refueling vehicles. Many fleet managers are wary of transitioning to alternative fuels without abundant
fueling access across their commonly used routes. A lack of knowledge of available technologies and
operational cost savings is another factor that impedes potential adopters.
Although these barriers are currently inhibiting some growth in the alternative fuel market, most are
surmountable with time and sustained effort. Both government and industry have introduced and
encouraged alternative fuel vehicles in California, Oregon, and Washington, causing the West Coast to be
home to many early adopters of these new technologies. With this preface, the following sections discuss
public sector activities, and policy needs to support alternative fuel deployment on the West Coast.
Designation and Cost of Alternative Fuel Corridors
Under Section 1413 of the Fixing America's Surface Transportation (FAST) Act, the Federal Highway
Administration (FHWA) is required to designate corridors as "signage ready" or "signage pending" for
alternative fuels annually through 2020.2 Figure 3 through Figure 7 are snapshots of the FHWA corridor
designations for the fuels and states that are covered in this report. The solid colored lines represent those
corridors that are designated as "signage ready" and the dotted lines represent corridors that are
designated as "signage pending." "Signage pending" corridors do not have sufficient alternative fuel
stations to meet required mileage between stations as stated by the FHWA, whereas "signage ready"
corridors do. The mileage between station requirements are defined in Section VI. Corridors with boxing
or circling around them indicate that the corridor has sufficient infrastructure to be designated as corridor
"signage ready" but has not yet been nominated for consideration by FHWA.
Please note that the FHWA's corridor designation program counts stations that service light-duty vehicles
along with medium- and heavy-duty vehicles, and as of publication of this strategic development plan the
FHWA's corridor maps do not offer an apparent method for disaggregating light-duty accessible stations
from medium-duty and heavy-duty accessible stations. Therefore, it should be assumed that Figure 3
through Figure 7 all show fueling stations that may service light-duty, medium-duty, and/or heavy-duty
vehicles. It is likely for some of the fuels, particularly with electric and hydrogen, that the majority of the
29 I F
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sites are light-duty and not capable of accommodating medium- and heavy-duty vehicles. Despite this,
the FHWA's corridor designation program and its associated maps offer a valuable approach that may be
followed with a focus on identifying gaps in alternative fuel infrastructure for medium- and heavy-duty
vehicles along major West Coast corridors. Thus, CALSTART shows snapshots of FHWA's maps for each
alternative fuel type below as an example and reference for methods in determining alternative fuel
infrastructure completeness along corridors.
30 I F
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Figure 3: Snapshot of Electric Corridor Designations3 "1"
Kelewna
Nalfcimo'
ViGtona
MedBIT
O1 About I Content ¦ Legend
Legend
Electric Stations (09/05/2018)
•
Alternative Fuel Corridora (09/10/201S)
Corri dor Ready
Corridor Pending
Potential Electric Corridors - Areas with enough
stations to nominate new corridors or where a
single station would lead to an extension of an
existing corridor or a new corridor,
b
National Highway Network
Interrrates
X"'https://www.arcgis.com/home/webmap/viewer.html?webmap=376dedd75b8347b8936abd70703cdb69&extent
=-158,6002,16.7349.-56.1198.56,6162
31 | P a g e
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Figure 4: Snapshot of Hydrogen Corridor Designation
4, XIV
Vancouve?
Nanaimo
Victoria
Seatjtte
r
Olympic
Spofearre"x
KM
SaJ^rri
viecHoid
v 1C
-------�
Figure 5: Snapshot of LPG Corridor Designation5,1™
WMtttef
+ ^ Kelj^na
^ m *¦ .^ancjteiy^-r *
Nafwmo «
• • •
w
[O] V^ona ^ 1
' KfflTffavick
,
Por:ffrnl
S
Salfcn
m
J
III
'V •
$e£tafd
-Bone
O I ii
Legend
" Fropane Stations (09/05/2018)
/ Carson Qly
Alternative Fuet Corridors
. simKjfeto. (09/10/2018)
JJV
San i nfonf c.o.. Corridor Ready
!&fWO!
Fiesno
Corridor Pending
Potentia l Propane Corridors - Areas
with enough stations to nominate new
corridors or where a single station
. would lead to an extension of an
exigtinq corridor or a new corridor.
San JJiego.
Tijuana MwK"1 National Highway Network
Irnerrzsnes
50 lOOmi
xv Readers should assume that this map shows light-duty only stations along with MHD-accessible stations. The cited
source did not offer a method to disaggregate light-duty only stations from MHD- accessible stations.
33 | P a g e
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Figure 6: Snapshot of CIMG Corridor Designation6,xvl
0 Aboiit I I 'Content ¦ Legend
Legend
Compressed Natural Gas Stations
(09/05/2018)
Alternative Fuel Corridors (09/10/2018)
Corridor Reedy
Corridor Pending
Potential Compressed Natural Gas
Corridors - Areas with enough stations to
nominate new corridors or where a single
station would lead to an extension of an
existing corridor or a new corridor.
b
National Highway Network
Interstates
XVI Readers should assume that this map shows light-duty CNG stations along with MHD-accessible stations. The cited
source did not offer a method to disaggregate light-duty only stations from MHD- accessible stations. All depicted
stations likely MHD-accessible given the prevalence of CNG fueling for MHDVs versus LDVs.
34 | P a g e
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Figure 7: Snapshot of LNG Corridor Designation7,1™"
¦ VjflCQUVGf
Nanairno
X
Victoria
Keiowna
Sppkarrr-
0 About [3 Content
Legend
LNG Stations (09/05/2018}
4
Alternative Fuel Corridors {09/10/2018)
Corridor Ready
Corridor Pending
Potential LNG Corridors - Areas with enough
stations to nominate new corridors or where a
single station would lead to an extension of an
existing corridor or a new corridor.
b
National Highway Network
Interstages
xv" Readers should assume that this map shows light-duty LNG stations along with MHD-accessible stations. The
cited source did not offer a method to disaggregate light-duty accessible LNG stations from MHD-accessible stations.
All depicted stations likely MHD accessible given the prevalence of LNG fueling for MHDVs versus LDVs.
35 | P a g e
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Because this plan is aimed at highlighting MHD alternative fueling infrastructure needs, it is important to
consider the cost of outfitting corridors with infrastructure by fuel type. CALSTART took survey responses,
reached out to partners, and read available reports to estimate the costs of an average MHD fueling
station for each fuel type. The data collected had varying levels of capacity, year built, and other factors,
so CAPEX can vary greatly. Finally, these CAPEX estimates only factor in capital costs (construction,
permitting, equipment, etc.) and not operational costs. Accordingly, the CAPEX estimate per station
provided below are approximate. Also be aware that the stations included here are not truly
representative of the total investment needed for comprehensive MHD alternative fuel infrastructure
access on the West Coast.
Table 7 Estimated Funding Needed to Build Proposed Infrastructure Projects in This AFICC Effort XVMi
-------�
Fixing America's Surface Transportation (FAST) Act, Section 1413: Section 1413 of the FAST Act, enacted
in 2015 requires the designation of national electric vehicle (EV) charging, hydrogen, propane, and natural
gas fueling corridors (also defines the technological scope of this plan). This designation includes the
identification of near and long-term needs for future alternative fuel infrastructure along interstate and
major state highway corridors. Section 1413 also directs the Secretary of Transportation to update and
re-designate corridors annually after establishment of the Act due to the continuously changing state of
alternative fuel vehicle and infrastructure technology. For a highway segment to be designated as
"Signage Ready", maximum distance between stations is as follows: 50 miles for electric, 100 miles for
hydrogen, 150 miles for propane, 150 miles for CNG, and 200 miles for LNG. In addition, the stations must
be within five miles of the designated highway corridor segment.8
EPA Diesel Emissions Reduction Act Program:' The Diesel Emissions Reduction Act (DERA) is part of the
Energy Policy Act of 2005 and was reauthorized in 2010. The aim of the bill is to reduce diesel emissions
by appropriating EPA funding assistance to replace, repower, and/or retrofit heavy-duty diesel engines.
This bill has had a profound effect, allowing tens of thousands of diesel engines to be cleaned up,
generating public health benefits nationwide. Furthermore, the DERA-related funding opportunities have
led to the creation of several regional clean diesel collaboratives, including the West Coast Collaborative.10
These Collaboratives, facilitated by EPA's regional offices, have laid the foundation for partnerships
between vehicle owners, government, and environmental advocates that help further reduce diesel
emissions beyond the scope of federally funded projects.
EPA Ports Initiative:11 This initiative works in collaboration with the port industry, communities, and all
levels of government to improve environmental performance and increase economic prosperity. This
effort helps people living and working near ports across the country breathe cleaner air and live better
lives. The program is designed to encourage retrofit, repower, or replacement of legacy heavy-duty diesel
engines with lower emitting technologies, operational best practices, and partnership development.
Funding provided by the EPA's National Clean Diesel Campaign aims to offset the cost of the technology
and increase adoption rates at ports to compliment exist DERA program efforts in the goods movement
sector.
U.S. Department of Energy Clean Cities Program:1' Founded in 1993 by the U.S. Department of Energy
(DOE) Vehicle Technologies Office (VTO), Clean Cities aims to advance affordable, domestic transportation
fuels, along with more efficient mobility systems and other fuel-saving technologies and practices. There
are nearly 100 local coalitions across the nation comprised of 15,000 stakeholders, including businesses,
government agencies, fuel providers, fleets and other stakeholders. At the local level, coalitions leverage
the resources of DOE and their national labs to create networks of local stakeholders and provide technical
assistance to fleets implementing alternative and renewable fuels and other emerging transportation
technologies.
U.S. Department of Energy Zero-Emission Cargo Transportation Demonstration and SuperTruck
Programs:13 DOE recognizes the need for funding in the heavy-duty space. It demonstrates zero-emission
vehicles through the Zero-Emission Cargo Transportation Demonstration, which aims to accelerate the
introduction of electric trucks into the market. There is also the SuperTruck Initiative, which aims to
increase Class 8 tractor trailer fuel efficiency by 50%.
37 I F
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U.S. Department of Energy Hydrogen and Fuel Cells Program:14 This program conducts research and
development in hydrogen production, delivery, storage, and fuel cells, as well as activities in technology
validation, manufacturing, systems analysis and integration, safety, codes and standards, and education.
Current Federal Government Activities
The federal government is implementing various programs to support the deployment of alternative fuel
vehicles and infrastructure, however, as this strategic plan outlines, additional funding is required to
support infrastructure development for medium- and heavy-duty vehicles. This is seen as a necessity to
the industry as expansion of zero- and near-zero emission alternative fuel vehicles in commercial fleet
applications is not possible without the development of infrastructure to support them.
Opportunities to Meet Alternative Fuel Goals
Federal funding assistance is needed to incentivize the purchase and operation of commercially available
medium- and heavy-duty alternative fuel vehicles, as well as to support infrastructure development along
transportation corridors. Research, development, and demonstration funding will also help to
commercialize high-efficiency and low emission vehicle technologies, helping build a more robust clean
transportation industry in the U.S.
California Policy Landscape
California has several statutes, programs, and initiatives supporting alternative fuel deployment. Many
related policies in California are comprehensive in that they cover vehicles, fueling infrastructure, and fuel
production.
Senate Bill 32:15 The California Global Warming Solutions Act of 2006, requires greenhouse gas (GHG)
emission reduction to 40% below 1990 levels by 2030. Under this statute, the California Air Resources
Board (CARB) is directed to develop and implement the GHG emission reduction strategies required to
achieve the 2030 mitigation mandate.
Senate Bill 350:l ! The Clean Energy and Pollution Reduction Act established clean energy, clean air, and
GHG reduction goals, including reducing GHG to 40% below 1990 levels by 2030 and to 80% below 1990
levels by 2050. Under this bill, agencies including the: California Public Utilities Commission (CPUC),
California Energy Commission (CEC), and CARB are working with stakeholders to support transportation
electrification. In doing so, the CPUC is actively working with investor owned electric utilities (lOUs) to
develop and implement programs and investments to accelerate transportation electrification
throughout the state. The CPUC approved several California lOUs to operate an electric vehicle
infrastructure rebate program for a total of $786 million in funding.
Senate Bill 1383:17 This bill codified CARB's Short-Lived Climate Pollutants (SLCP) Strategy and prescribed
related pollution reduction goals. This includes reducing methane emission by 40% below 2013 levels by
2030. To support this goal, the bill allows for an increase in the production and use of in-state biomethane
for electricity and transportation sectors and for the development of at least 5 dairy biomethane pilot
projects.
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Assembly Bill 784:18 This bill would exempt certain public agencies in the state from paying taxes on the
purchase of specified zero-emission technology transit buses.
Assembly Bill 2061:19 This bill allows for zero and near-zero emission heavy-duty trucks to exceed
California's weight limits by 2,000 pounds due to the extra weight associated with alternative fuel systems
(e.g., powertrain and fuel storage components). With this additional weight limit, many heavy-duty
alternative fuel vehicles can now weigh up to 82,000 pounds.
California Executive Order N-19-19:20 Signed on September 20, 2019, EO N-19-19 requires California state
agencies to enhance their efforts in reducing GHG emissions and mitigating the impacts of climate change
while focusing on economic growth. This executive order requires multiple actions from several agencies.
First, it requires the Department of Finance to create a Climate Investment Framework by leveraging the
state's $700 billion investment portfolio. The purpose of this Framework is to set a strategy for investing
the state's pension funds into companies and industry sectors that have growth potential based on
reducing carbon emissions. Second, the EO requires the State Transportation Agency to leverage
California's more than $5 billion in annual transportation spending to reduce fuel consumption and GHG
emissions associated with the transportation sector, working to meet the objectives of the state's Climate
Change Scoping Plan. Third, the EO requires the Department of General Services to minimize its fleets'
carbon footprints. Finally, the EO requires CARB to accelerate efforts toward the state's goal of five million
zero-emission vehicles (ZEV) sales by 2030 through new strategies for increasing demand for such vehicles
and incentivizing ZEV production.
California Executive Order B-48-18:1 Signed on January 26, 2018, EO B-48-18 commits California to a goal
of five million ZEVs on the road by 2030, and 250,000 vehicles charging stations and 200 hydrogen
refueling stations by 2025. The order also states the ways in which all State entities should collaborate
with stakeholders to aid in the implementation of this order. This includes updating the 2016 ZEV Action
plan, recommending actions to create jobs and boost economy through ZEV infrastructure development,
recommend ways to expand infrastructure through Low Carbon Fuel Standards Program, etc.
California Climate Change Scoping Plan:22 California Assembly Bill 32 (AB 32), passed in 2006, required
CARB to develop a Scoping Plan which would outline the approach that the state would take to reduce
GHGs to 1990 levels by 2020. With the passage of Senate Bill 32 (SB 32), the Scoping Plan updated in 2016
to include a 2030 GHG emissions reduction goal of 40% below 1990 levels. Additionally, AB 197 was passed
alongside SB 32 providing additional direction on community health protection within the Scoping Plan.
Thus, CARB updated the current version of the Climate Change Scoping Plan in 2017, which describes the
state's strategy for achieving its 2030 target for GHG emission reductions, including emissions reductions
in the transportation sector, which constitutes approximately 41% of current carbon emissions in
California.
CARB Three Year Heavy-Duty Investment Strategy:23 Identifies three MHD beachhead pathways to target
for future investment in alternative fuels for the state of California: Zero-Emission, Low NOx, and
Efficiencies. The idea behind these beachheads is that the advancements in these areas will support the
development of other, emerging technologies that overlap with existing technologies and therefore have
a "multiplier" effect upon the industry and alternative fuel development.
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CARB Low Carbon Fuel Standard (LCFS):24 Aims to reduce the carbon intensity (CI) of transportation fuels
by 10% by 2020, and 20% by 2030, and encourage the production of cleaner fuels. In this program,
transportation fuels with a higher CI level than a CARB-designated cap generate deficits for the
organization that produced them, and fuels with a lower CI level than a CARB-designated cap generate
credits for the organization that produced them. Fuel providers must comply with the fuel CI caps, and if
they cannot do so using internally produced fuel products, they can purchase credits on the market from
other LCFS market participants.
CARB Innovative Clean Transit Rule: Requires that mass transit agencies in California will only be permitted
to purchase buses that are fully electric by 2029. As part of the rule, state transit agencies will have
benchmarks to reach sooner than 2029. By 2023 and 2026, one quarter and half of new buses must be
electric, respectively.
CARB Advanced Clean Truck Regulation: This regulation has been proposed and will be subject to change
until CARB's Board makes a final decision (expected in 2020). This regulation focuses on manufacturers of
Class 2b-8 vehicles with combustion engines, requiring increasing percentages of their annual California
truck sales from the model years 2024 to 2030 to be zero-emission capable vehicles (i.e., plug-in hybrid,
battery-electric, and fuel cell electric).
CARB Hybrid and Zero Emission Truck and Bus Voucher Incentive Project (HVIP):25 Offers point-of-sale
incentives for zero- and near-zero emission trucks and buses, allowing for a streamlined incentive process
that benefits adopters of clean technology. At the time of writing this plan, HVIP has deployed more than
4,000 MHDVs, helping to grow the MHD advanced powertrain market by 30%. lOUs such as Pacific Gas &
Electric, Southern California Edison, and San Diego Gas and Electric are coordinating closely with the
administrators of HVIP on infrastructure incentives for MHD plug-in electric vehicles.
CARB Clean Off-Road Equipment (CORE) Voucher Incentive Project: Similar to the HVIP model, this
program offers point-of-sale incentives for zero-emission medium- and heavy-duty off-road equipment
used by the goods movement industry. Launched in 2020, CORE provides $44 million in incentives for
equipment across various functions including; cargo handling equipment, yard tractors, transport
refrigeration units, rail car movers, airport cargo loaders among others. Additional incentives are available
for infrastructure and for users operating in disadvantaged communities.
Volkswagen NOx Mitigation Trust Fund:26 The funds from the Volkswagen Light-Duty Diesel Settlement
will provide $423 million in funding assistance for various engine replacement, zero emission vehicle
deployment and ZEV infrastructure development projects that will reduce NOx emissions throughout
California. The fund aims to provide a "balanced approach" by committing funding to cost-effective,
cleaner combustion technologies (e.g., low NOx powertrains) and zero-emission technologies to reach
longer term emission reduction goals. Funding will support deployment of MHD alternative fuel vehicles
and light-duty ZEV infrastructure.
CEC Clean Transportation Program:- In 2007, the California Legislature passed Assembly Bill 118 which
created the CEC's Clean Transportation Program (formerly known as the Alternative and Renewable Fuel
and Vehicle Technology Program or ARFVTP). In 2013, this program was reauthorized through 2023 by
the passage of Assembly Bill 8. The CEC has provided nearly $830 million for fuel production,
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infrastructure, vehicles, and other related needs for a wide variety of alternative fuels throughout
California. For FY 2019-2020, over $95 million was allocated for investment under this program.
CEC Electric Vehicle Supply Equipment Rebates:28 There are multiple rebate programs available to
incentivize the cost of electric vehicle supply equipment (EVSE). A major program, the California Electric
Vehicle Infrastructure Project (CALeVIP) under the CEC's Clean Transportation Program, offers incentives
for the purchase and installation of electric vehicle charging infrastructure at publicly accessible sites in
several regions throughout California. CALeVIP works with local partners to develop and implement EV
charger incentive projects that meet regional needs for Level 2 chargers and direct-current fast chargers.
This statewide project aims to provide a streamlined process for getting chargers installed and fill gaps in
charging availability.
CDFA Dairy Digester Research and Development Program:29 This program, administered by the California
Department of Food and Agriculture (CDFA), provides financial assistance for the installation of anaerobic
digesters at California dairies. This technology converts manure and other organic waste into biomethane,
a renewable transportation fuel that can be used in CNG and LNG powered vehicles.
Current California Government Activities
Under Assembly Bill 2127 (2017), the CEC must publish a statewide assessment of the EVSE infrastructure
required to accommodate anticipated increases in charging demand to achieve the goal of at least five
million ZEVs by 2030. Executive Order B-48-18, directs the state to add 250,000 EVSE and 200 hydrogen
stations by 2025, primarily for light-duty vehicles. The CPUC has approved or is in the process of approving
approximately $2 billion for EVSE investment, and the VW settlement funds will also provide financial
support for ZEV deployment and related infrastructure development. It is widely acknowledged that the
state will need additional funding assistance to accomplish its existing ZEV deployment goals.
Opportunities to Meet Alternative Fuel Goals
California is advancing alternative fuel technology through a suite of legislation, regulations, funding
programs, and thoughtful coordination between stakeholders. CARB has produced foundational plans
that seek to coordinate these efforts, including CARB's Three Year Heavy-Duty Investment Strategy and
the Climate Change Scoping Plan. Through these plans, incentive programs such as HVIP and CORE were
developed to help propel new technologies into the market and help existing technologies further
penetrate the market. CARB is also consulting with other state agencies, air districts, utilities and ports to
evaluate ways to coordinate across funding programs and investment needs for MHD vehicles and
infrastructure through a working group called the California Funders Forum. In addition, through the MHD
Infrastructure Working Group, stakeholders are working together to evaluate infrastructure needs across
the state to advance clean transportation and to be better prepared for zero-emission transportation.
California has shown how coordinated policy and funding can help quickly accelerate alternative fuel
vehicle adoption. Although great progress has been made, significant, additional, and sustained funding
assistance is needed to build on this momentum and achieve transformative change within California's
transportation sector.
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Oregon Policy Landscape
Oregon has several policies and programs that encourage the development of alternative fuel stations
and the deployment of low and zero emission vehicles. Additional funding is required to advance the
medium- and heavy-duty alternative fuel vehicle market and support corridor growth within the state.
Senate Bill 1044:30 Aims to promote ZEV adoption by requiring certain state fleet purchases and leases to
be ZEVs. In addition, this bill provides funding for school bus fleets to deploy EV charging infrastructure.
Senate Bill 583 and Oregon Energy Incentive Program:31 Passed in 2013, this bill created "eligibility for
alternative fuel vehicles used in business activities to receive tax credits under the Oregon Energy
Incentive Program beginning January 1, 2015". Eligible vehicles would receive a 35% credit on the
incremental cost between a conventional vehicle and an EV. Despite this tax credit, the number of
applications from businesses for EVs has been low thus far. This is likely due to a lack of knowledge of low
operating costs of EVs and the cost of the EVs being larger upfront compared to conventional vehicles
despite the tax credit. Although this program is beneficial for the promotion of EVs, the rebate may need
to be larger to have greater impact on purchasing. As of December 2019, this program was no longer
running.
Senate Bill 98:'• This bill allows natural gas utilities to rate base incentives for renewable natural gas (RNG).
It also sets voluntary RNG portfolio goals to support a smooth transition to a low carbon energy economy.
For example, the suggested renewable portfolio target for gas purchased by natural gas utilities for
distribution to retail customers reaches as high as 30% by 2050.
Senate Bill 1547: " This bill mandates that electric utilities eliminate coal-based electricity generation by
2026. This is significant in the alternative fuel sector because it reduces emissions associated with EV
charging by enabling renewable energy production.
House Bill 3543 and the Oregon Global Warming Commission:'"1 Introduced the goal of reducing GHG
levels to 75% below 1990 levels by 2050 and created the Oregon Global Warming Commission. This
advisory group, consisting of 25 appointed members, develops long-term policy recommendations for the
State of Oregon to combat and adapt to global warming.
House Bill 2017:35 Created a transportation fuel tax that funds a variety of initiatives, including additional
funding for transit agencies to deploy low to zero emission buses. This policy has supported increased
adoption of alternative fuel buses in Oregon.
House Bill 2007:"' In addition to allocating funds received under the Volkswagen Diesel Settlement, HB
2007 established deadlines after which older-model MHD diesel engines cannot be titled or registered in
Clackamas, Multnomah and Washington counties. The phase-out deadlines occur in 2023, 2025 & 2029.
Criteria for certified diesel retrofits will be established prior to these deadlines to allow for regulated
parties to comply with the new titling and registration rules. The Oregon Department of Environmental
Quality (ODEQ) will also establish minimum standards for both on road and off-road diesel engines used
on certain public improvement contracts.
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ODEQ Clean Fuels Program:37 The Oregon Clean Fuels program, analogous to California's Low Carbon Fuel
Standard, is designed to reduce the average carbon intensity of Oregon's transportation fuels by 10% over
a 10-year period. As of December 2019, the program had approximately 160 regulated parties who were
registered importers of conventional and alternative fuels. Deficits and credits are generated based on
the carbon intensity of fuel imports to the state. A Credit Clearance Market provides an opportunity for
regulated parties to comply with the standard if they cannot generate enough credits during the year.
Additionally, owners of EV charging infrastructure can earn clean fuel credits, incentivizing the adoption
of MHD electric vehicles. The program incentivizes and promotes alternative fuel usage in all
transportation sectors statewide in order to reduce GHG emissions.
Executive Order No. 17-21, Accelerating Zero Emission Vehicle Adoption in Oregon to Reduce Greenhouse
Gas Emissions and Address Climate Change:38 Issued in November 2017, this EO focuses on accelerating
ZEV adoption, and proposes a strategy to triple ZEVs in the state by 2020. The group tasked with
implementing EO No. 17-21 is The ZEV Interagency Working Group (ZEViWG), a team of Oregon state
agencies, including the: Department of Transportation, Department of Environmental Quality, Public
Utility Commission, Department of Administrative Services, and Department of Energy. Another
organization contributing to this effort is the Oregon Electric Vehicle Collaborative, headed-up by Oregon
Solutions.39
Volkswagen NOx Mitigation Plan:40 Oregon will reduce diesel emissions from at least 450 school buses
over the next three years and is on track to meet that goal at an estimated of cost $18-22M. HB 2007
directed Oregon to spend the remainder of the $72.9M on a new Clean Diesel Initiative grant program to
reduce diesel emissions from trucks and equipment with a preference for projects in the greater Portland
Metropolitan area.
Multi-State Zero Emission Vehicle (ZEV) Task Force:41 Oregon, along with California, Connecticut,
Maryland, Massachusetts, New Jersey, New York, Rhode Island, and Vermont, signed a memorandum of
understanding (MOU) to promote and advance strategies to increase ZEV adoption. Through a ZEV
Program Implementation Task Force, the states are seeking to deploy at least 3.3 million ZEVs with
adequate fueling infrastructure in participating states by 2025. Oregon is a participant in the Multi-State
ZEV Action Plan to implement this MOU 42 Additionally, the Multi-State ZEV Task Force created the
International ZEV Task Force, and Oregon will be hosting its annual conference in Portland in 2020.
Oregon's Clean Car Standards:43 As of December 2019, Oregon is one of eleven states that have adopted
both California's Low Emission Vehicle Program and ZEV mandate. The Low Emission Vehicle program
requires new light-duty vehicles to meet certain emissions performance requirements for GHGs, criteria
pollutants, and air toxics. The ZEV mandate requires automobile manufacturers to provide a certain
number of new ZEVs (battery electric, fuel cell electric and plug-in hybrid electric) for sale within the state.
While focused on light-duty vehicles, these standards indicate the state's continued commitment to
transportation electrification.
West Coast Electric Highway:44 Oregon is actively working to enhance its portion of the West Coast Electric
Highway by recapitalizing it to provide dual-protocol DC Fast Charging, including SAE CCS Combo and
CHAdeMO compatible DC Fast Charging infrastructure. Each of the 44 sites along Oregon's West Coast
Electric Highway segment will be upgraded in this way. The State of Oregon committed over $4 million to
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this effort in 2019, with the Oregon Transportation Commission approving $3.5 million in federal funding
for this work and HB 5050, Section 63 (adopted in 2019) authorizing the Oregon Department of
Transportation to use $650,000 as match funding for the same effort.45
Current Oregon Government Activities
Currently, Oregon is dedicated to both transportation electrification and expanding RNG development
and use. Oregon's commitment to transportation electrification is indicated through its Clean Car
Standards, EO No. 17-21, existence oftheZEV Interagency Working Group, participation in the Multi-State
ZEV Task Force, enhancements of the West Coast Electric Highway, and the Oregon Clean Fuels Program.
Additionally, there are several ratepayer-funded pilots and programs underway to develop EV charging
infrastructure. Examples of these projects are listed later in this strategic plan: an EV charging station in
Josephine County, OR and an EV charging station in Hood River County, OR. Regarding natural gas
expansion, one example is the Oregon Biogas/Renewable Natural Gas Inventory (SB 334), which requires
development of a detailed RNG feedstock inventory, air pollution improvement estimates for RNG use,
and an Advisory Committee to provide input on ways to develop more RNG opportunities in the state.
Additionally, AFICC member Columbia Willamette Clean Cities Coalition has the goal of delivering the
infrastructure to increase CNG and Propane on major Interstate corridors, particularly 1-5 and 1-84, as well
as state highway corridors (e.g., OR 26, 30, 101, 97).
Opportunities to Meet Alternative Fuel Goals
FHWA has already designated much of the 1-5 corridor in Oregon as signage ready for CNG with a small
area between Oregon and California that is currently signage pending. However, stakeholders have noted
that there is a need for policies and incentives to facilitate the development and deployment of RNG
supply for new and existing CNG stations. For example, existing policy prevents Oregon utilities from
making ratepayer-funded capital investments in RNG infrastructure, which includes extension of
pipelines, or connection points for RNG producers. To encourage RNG production, Oregon has the option
of mandating the source separation of wastes (such as food wastes) for RNG production. Additionally,
financial incentives for natural gas fueling infrastructure may encourage investment in this alternative fuel
technology. In addition to natural gas, Oregon may continue to deepen its commitment to transportation
electrification. By leveraging the current EV charging pilots and programs that exist in the state, Oregon
can further develop needed EV charging infrastructure. Some stakeholders in Oregon have also suggested
that the development of a GHG cap-and-trade program similar to California's Climate Investments
Program would help support such efforts.46
Washington Policy Landscape
The State of Washington has shown legislative commitment to increasing the use of alternative fuels.
Historically, there has been a greater emphasis on electric vehicles compared to other alternative fuels.
Like Oregon, Washington has shown significant interest in RNG, however, state legislation has focused on
the production of RNG rather than its use in the transportation sector.
GHG Emission Reduction Targets:47 Washington has set statewide GHG emission reduction targets that
will likely encourage alternative fuel production and deployment in the state. Washington's existing GHG
emission reduction targets include:
By 2020, reduce statewide GHG emissions to 1990 levels;
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By 2035, reduce statewide GHG emissions 25% below 1990 levels; and
By 2050, reduce statewide GHG emissions to 50% below 1990 levels.
Senate Bill 5588:4S Authorizes Public Utility Districts (PUDs) to produce, distribute, and sell renewable
hydrogen.
Senate Bill 5116:49 Requires electric utilities to eliminate coal generation and pay off remaining
construction costs from coal plants by 2025, to become "GHG neutral" by 2030, and to provide 100%
carbon free power by 2045.
House Bill No. 2580:'° Accomplished the following:
1. Restored lapsed tax incentives for anaerobic biomethane digester projects and expanded types
of eligible projects and the total incentive value per project;
2. Called for a study to quantify near-term opportunities, identified uses by state agencies, and
evaluated RNG portfolio standard policy options; and,
3. Called for work with the Washington Utilities and Transportation Commission (UTC), energy
utilities, developers and other stakeholders on gas pipeline quality standards.
House Bill 1512:51 Authorized municipal utilities and PUDs to create and implement transportation
electrification plans aimed at offering programs that promote related services and incentives.
House Bill 2042:52 Enabled the following programs:
1. Alternative Fuel Commercial Vehicle Tax Credit:53 Tax credits are available to businesses that
purchase new alternative fuel commercial vehicles. The tax credit applies to vehicles primarily
powered by natural gas, propane, hydrogen, dimethyl ether, or electricity. The tax credit may
cover up to 50% of the incremental cost and is based on the gross vehicle weight rating (GVWR)
of the vehicles. See below for the maximum credit values:
Table 9: Washington State Alternative Fuel Commercial Vehicle Tax Credit Structure
GVWR
Max Credit Values: January 1, 2018 to January 1, 2021
Up to 14,000 pounds (lbs.)
$25,000
14,001 to 26,500 lbs.
$50,000
Over 26,500 lbs.
$100,000
2. Clean Alternative Fuel Charging and Refueling Infrastructure Program:The EV Charging
Infrastructure pilot program was made subject to appropriations through the 2023-25 biennium.
It was expanded to include the opportunity for bidders to propose hydrogen fueling station
infrastructure that can address an existing gap in the state's low-carbon transportation
infrastructure and meet other program evaluation criteria.
3. Electric Vehicle Battery and Hydrogen Fuel Cell, Infrastructure, and Zero-Emission Bus Retail Sales
and Use Tax Exemption:55 The EV battery and infrastructure retail sales and use tax exemption
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was extended to apply to batteries sold as a component of an electric bus at the time of the
vehicle's sale and to the sale of zero-emission buses. It was also extended to apply to hydrogen
fuel cells, hydrogen fueling stations, and renewable hydrogen production facilities.
4. Leasehold Excise Tax Exemption for Electric Vehicle Infrastructure, Hydrogen Fueling Stations,
and Renewable Hydrogen Production Facilities:56 The leasehold excise tax exemption for EV
infrastructure was expanded to include public lands used for hydrogen fueling stations and
renewable hydrogen production facilities, and the expiration date was extended to June 30, 2025.
5. Green Transportation Capital Grant Program for Public Agencies:57 Subject to amounts
appropriated for this specific purpose through the 2023-25 biennium, the Washington State
Department of Transportation's (WSDOT's) Public Transportation Division is required to establish
a green transportation capital grant program to aid transit authorities in funding cost-effective
capital projects such as the electrification of fleets (battery and fuel cell), modification or
replacement of capital facilities to facilitate electric and hydrogen fueling, and upgrades to
electrical transmission and distribution systems.
Clean Truck Program:58 Starting in January 2019, The Northwest Seaport Alliance, a marine cargo
operating partnership of the Ports of Tacoma and Seattle, required all heavy-duty drayage trucks serving
port terminals to be powered by a model year 2007, or newer engine (with some exceptions).
Plug-in Electric Vehicle (PEV) Promotion and Infrastructure Development:59 Washington mandates that
regional planning organizations with more than one million residents must promote and invest in PEV use
and EV charging using federal or private funding. Some efforts related to this planning mandate include:
1) developing plans outlining how state, regional, and local governments can construct EV charging
locations to ensure that this infrastructure can be supported by the existing electrical distribution grid; 2)
supporting public education and training programs on PEVs; 3) developing an implementation plan for
counties with a population greater than 500,000 to have 10% of public and private parking spaces ready
for PEV charging; and 4) developing model ordinances and guidance for local governments for site
assessment and installing PEV infrastructure.
Volkswagen NOx Mitigation Plan:60 The State of Washington is also focused on building charging
infrastructure for both light-duty and heavy-duty EVs. For example, the Washington State Department of
Ecology (WSDOE) will partner with WSDOT to use 15% of Washington's Volkswagen Mitigation Trust Fund
allocation to create, operate, and maintain additional light-duty EV charging infrastructure. Although the
plan does not provide funding for heavy-duty EV charging infrastructure, it provides funding for a variety
of heavy-duty vehicles, including school buses, transit buses, freight trucks, and drayage trucks in order
to accelerate vehicle adoption and reduce emissions.
Current Washington Government Activities
In Washington, transportation electrification has been an important priority. Although there has been
recent legislation to promote RNG production, much of this resource is exported to other states for
transportation fuel use as opposed to being used in Washington for that purpose.
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The Washington Governor's Office is currently working to introduce legislation aimed at creating a state
program similar to California's Low Carbon Fuel Standard (LCFS) and Oregon's Clean Fuel Program.
Additionally, some policymakers have identified a cap and trade program as an important priority for
advancing clean transportation in Washington as well.
Opportunities to Meet Alternative Fuel Goals
Many Washington stakeholders are working to develop a low carbon fuel program to complement existing
State efforts to support alternative fuel deployment. Given that Seattle and Tacoma are major port cities
and goods movement hubs, Washington has an opportunity to significantly reduce emissions by
developing RNG and ZEV technologies in the state to support the transition of heavy-duty truck fueling
from diesel to lower emission alternative fuels.
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Barriers, Solutions, and Drivers of Alternative Fuel
Development of alternative fuels included in this report face a variety of barriers related to infrastructure,
the cost of technology, information gaps, and regulations. This section reviews the barriers, potential
solutions, and the drivers propelling alternative fuel adoption. To start, Table 10 shows a brief overview
of these barriers.
Table 10: Overview of Barriers by Alternative Fuel
Infrastructure
Technology Cost
Information Gap
Incentives / Regulations
EV
• Cost of
• Higher price
• Investor risk
• Little financial incentive
installation
of vehicle
perception
to be first investor
• Lead time
• Battery
• End-user
• Lack of inter-state
• Demand charges
replacement
awareness of
coordination
• Availability of
expense
technology and
• Unmet goals and
chargers
• Battery
incentives
expectations
• Duration of
capacity drain
• Training and
charging
• Reduced
education for
• Non-universal
range
municipal staff
chargers
H2
• Lead time
• Higher vehicle
• Lack of public
• Little financial incentive
• Expensive initial
cost
awareness
to be first investor
investment
• Maintenance
• Investor risk
• Lack of inter-state
• Expensive fuel
and
perception
coordination
cost
replacement
• Insecurity in fuel
costs
supply and
demand
• Limited number
of fueling stations
CNG
• Cost of
• Higher price
• Investor risk
• Lack of inter-state
LNG
installation
of vehicle
perception
coordination
LPGXX
• Lead time
• Reduced
• End-user
• Push towards zero-
• Price and timeline
range
awareness of
emission technologies
of maintenance
technology and
facility
incentives
• Misinformation
of first-
generation
vehicles
• Lack of inter-
state
coordination
xx Many barriers are common across these fuels.
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Electric Charging
As the only non-liquid or gaseous fuel in this plan's purview, battery electric vehicles (BEVs) face a variety
of unique barriers. The table below examines the major barriers with regard to infrastructure, technology
cost, information gaps, incentives, and regulations.
Table 11: Electric Barriers and Solutions
Barrier
Description
Solutions
Infrastructure
Cost of
Installation
Not including the EVSE unit, Level 2
installation averages $3000 and Level 3
installation averages $21,000, although
these costs may vary on a case-by-case
basis.61
Rebates and incentives
are available per state,
utility, air district, and
city.
Level 3 (DC Fast Charging) material and
installation costs can vary from $14,000
to $91,000.62
Lead Time
The lead time required for labor and to
obtain city permits can significantly delay
EV infrastructure installations.
City streamlining of
permits and beginning
infrastructure discussion
early in project process.
Demand
Charges
Demand charges state that after a
specified amount of energy consumption
is surpassed by a ratepayer, the energy
provider will charge a much higher fee for
all additional consumption in the
remaining month.63
Utilities can create
commercial EV rates that
account for massive
energy demand by BEV
fleets.™1
XXI Southern California Edison has an EV charging rate for commercial vehicles. Pacific Gas & Electric Company and
San Diego Gas & Electric are both in the process of developing similar rate structures.
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Barrier
Description
Solutions
Infrastructure
Availability
of Chargers
Charging stations along
corridors are often not
designed to accommodate
MHDVs.
Early consideration of charging
requirements with respect to space
and supply can help account for
this barrier.
For private fleets considering
BEV adoption, the amount of
space required for EVSE acts as
a barrier.
For growing fleets, it is important
to take scaling into account.
Duration of
Charging
The length of time required for
charging is a barrier to mass EV
adoption.
Technological improvements in
battery capacity, DC Fast Chargers,
and pairing charging stations with
truck stops can help avoid this
barrier.
For MHDVs on routes requiring
recharging, long charge times
may make BEVs inefficient.
Non-
Universal
Chargers
There are a variety of different
EV charging adapters as well as
different payment methods
based on the EVSE provider.
Facilitating discussion among EVSE
providers and automakers can help
streamline this process and create
consensus about charging
standards.
Technology inconsistency may
complicate EV charging
corridors that do not comply
easily with all vehicles.
Some companies may see benefits
to keeping their own systems in
place which would further
complicate these discussions.
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Barrier
Description
Solutions
Technology
Cost
Battery Replacement
Expense
A major concern about
adopting BEVs is the
formidable price of
replacing a battery.
Long-term warranties,
renting/leasing, battery
repurposing, and battery
exchange programs all
address this barrier.
Battery Capacity
Drain
Battery capacity reduces
over time which can
prohibit a BEV from
meeting its required duty
cycle.
Purchasing a battery with a
larger initial capacity than
required can ensure the BEV
meets duty cycle
requirements even after
capacity drain.
Proper maintenance of the
battery may also slow its
degradation.
Reduced Range
BEVs have a reduced range
compared to conventional
vehicles due to battery
limitations, energy
demands of duty cycle and
creature comforts.
Planning before purchase to
ensure that the BEVs range
can meet its required duty
cycle can address this issue.
Investor Risk
Perception
Lack of adequate
information available to
investors on costs, pricing,
operational benefits,
competition, secondary
market applications and
other factors stalls
investment.
Connecting industry,
government, end-users, and
investors to build a shared
understanding of EV market
dynamics can help spur
investor confidence.
Previously missed EV
adoption goals created
chilling effect in the
marketplace.
Effectively presenting total
cost of ownership (TCO)
comparisons across
vocations and duty cycles.
Higher Price of
Vehicle
EVs usually have an up-
front cost higher than
conventional vehicles due
to the high price of the
battery.
Due to economies of scale
for battery production, EV
prices are dropping.
Incentive programs help
address incremental
purchase cost.
Lower fuel costs can result
in a lower TCO for EVs.
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Barrier
Description
Solutions
Information
Gap
End-user
Awareness of
Technology and
Incentives
Manufacturers, dealers, and end-
users are not always aware of the
incentives or technologies
available to them.
Stakeholder education
campaigns that raise
awareness of available
incentives can significantly
accelerate market growth.
Fleet owners may not be aware of
potential savings through lower
charging rates and low carbon fuel
credits.
Training and
Education for
Staff
Lack of education and training on
charging, maintenance, and other
operational best practices may
result in negative BEV experiences
that discourage further adoption.
Ensuring that operators and
staff are properly trained can
significantly boost
effectiveness of BEV
deployment.
Little Financial
Incentive to be
First Investor
The current market does not
create additional benefit for initial
investors. As a result, investors
may wait until the market is more
established and still reap similar
results, which slows market near-
term acceleration.
Creating regulations that
incentivize primary
investment in infrastructure
and deployment can help
spur EV market acceleration.
Incentives/
Regulations
Lack of Inter-
State
Coordination
A lack of inter-state coordination
about fueling infrastructure plans
and locations may act as a barrier
to projects that otherwise could
be co-funded through
partnerships.
Facilitated discussion
between state and local
governments, fleet owners,
and fueling infrastructure
companies could help align
future plans and spur growth
(e.g., WCCAFICC).
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Hydrogen
Hydrogen is a promising and emerging ZEV infrastructure technology, however the current open retail
stations on the West Coast region are all in California and primarily service the light-duty fuel cell electric
vehicle (FCEV) market. This section describes the barriers to development of MHD hydrogen stations, and
potential solutions to those barriers.
Table 12: Hydrogen Barriers and Solutions
Barrier
Description
Solutions
Infrastructure
Lead Time,
Station Codes,
Permitting, and
Site Assessment
The average reported time for a
station to achieve open-retail
status is 18 months, subject to
station codes, permitting, and
site assessments.64
California agencies are
seeking to streamline the
station development process,
which could have significant
impacts in accelerating the
deployment timeline.
Expensive Initial
Investment
The cost to build hydrogen
fueling stations remains a
significant barrier (average of
~$4 million/MHD station).
Additional funding and
incentives may be necessary
to propel the hydrogen
infrastructure market to
commercial scale.
Despite its funding and
incentives, California is falling
behind on its 200-station goal by
2025.65
Coordination and investment
in hydrogen infrastructure
outside of California may
both accelerate vehicle
adoption and decrease fuel
prices.
Expensive Fuel
Cost
The average price for open retail
hydrogen fuel is $13.99/kg (as of
December 2019).66
Currently, manufacturers
include 3 years of fuel with
light-duty FCEV purchases in
California.
Because FCEVs are significantly
more energy efficient than
conventional vehicles, price
parity is expected to occur when
hydrogen is priced at $8/kg
assuming $3.50/gasoline
gallon.67
Building more hydrogen fuel
production facilities both in
and outside of California can
help lower costs.
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Barrier
Description
Solutions
Infrastructure
Insecurity in
Fuel Supply and
Demand
Dependence on limited
hydrogen supply chains and
increasing demand have
created instances of fuel
shortages at stations.
FCEV automakers have quickly
responded in instances of fuel
shortages to offer FCEV
customers free rental programs.
A lack of consumer-
confidence may act as a
barrier to FCEV adoption.
Additional production and
distribution chains are necessary
to resolve this barrier.68
Technology Cost
Maintenance
and
Replacement
Costs
Because there are few
FCEVs on the road,
maintenance and
replacement of parts,
including the fuel cell stack,
can be slow and expensive.
As more FCEVs get on the road,
manufacturers will be more
inclined to train technicians and
have parts ready to handle
maintenance and replacement.
Higher Vehicle
Cost
FCEVs are significantly more
expensive than
conventional internal
combustion engine
vehicles, posing a barrier to
purchase.
Incentives help subsidize the
higher costs, however additional
funding for vehicles and
infrastructure is necessary to
reach commercial scale.
Leasing may provide a successful
alternative ownership option for
encouraging FCEV adoption.
Information Gap
Lack of Public
Awareness
FCEV and hydrogen
technologies are largely
unknown to the general
public.
Awareness and education
campaigns, ride and drive
events, community rideshare
programs, and other campaigns
can help promote FCEV and
hydrogen awareness.
Investors may also
experience an information
gap on the emerging
market and California's
consistent financial support.
Fleet owners in California
and Oregon may also be
unaware of potential
savings through low carbon
fuel credits.
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CNG, LNG, and IPG
CNG, LNG, and LPG face similar barriers, solutions, and drivers.xx" As such, they are combined in this
section. Barriers that only affect one of each these fuel types are specified.
Table 13: CNG, LNG, and LPG Barriers and Solutions
Barrier
Description
Solutions
Infrastructure
Cost of
Installation
Costs of installation vary
widely with CNG stations
ranging from $1 to $4
million with fast-fill
dispensers.
Various incentives are available
per state, utility, air district, and
city.
Slow-fill LNG stations
averaging $2.5 million
Small propane station
averages around
$65,000.69,70 Larger stations
can cost up to $2 million.
Varying costs and site
conditions can act as
barriers to constructing
infrastructure.
Fleet partnerships on shared
station development can increase
throughput and reduce costs,
especially for CNG users
considering slow and fast-fill
stations.
Lead Time
The lead time required for
labor and obtaining city
permits can significantly
delay infrastructure
installations.
Streamlining local permitting
processes and beginning
infrastructure consultations with
relevant authorities early in the
station development process.
Price of and
Timeline of
Maintenance
Facility
CNG and LNG maintenance
facilities must be upgraded
for compliance, which
generally costs $45,000 -
$100,000.
This process can take 12 to
24 months.71
Advanced planning can help
prepare for the capital and
timeline. Additional incentives
may still be necessary.
xx" LNG faces a few unique barriers associated with cryogenic fuel storage and transportation, as well as siting and
permitting for large-scale bunkering facilities which can require specialized infrastructure and comes with
associated costs.
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Barrier
Description
Solutions
Technology
Cost
Higher price
of Vehicle
Heavy-duty CNG trucks can carry a 40
to 80% price premium over diesel
alternatives.72
Despite higher premiums,
heavy-duty trucks can save
~$30,000 per year in fuel and
maintenance costs in some
applications.73
Incentive programs can help
lower premiums and speed up
ROI.
Reduced
Range
LNG contains about 60% as much
energy per gallon compared to diesel,
and CNG contains less.74
Lower fuel prices for all three
alternative fuels compared to
diesel or gas make them more
cost-effective.
Propane also has a lower fuel
economy than diesel.75
Low carbon fuel programs
help further reduce consumer
cost for these fuels.
Information
Gap
Investor Risk
Perception
Existing gas and diesel infrastructure
to compete with, low fuel utilization
relative to fixed costs, and lack of
knowledge of future incentive
funding all act as investment barriers.
Connecting industry,
government, end-users, and
investors to discuss the
changing market can help spur
investor confidence.
Making government
intentions for funding more
transparent may also help
reduce the perception of risk.
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Barrier
Description
Solutions
Information
Gap
End-User
Awareness of
Technology and
Incentives
Manufacturers, dealers, and
end-users are not always
aware of the incentives or
technologies available to them.
Confusion about future zero-
emission mandates also act as
a barrier.
Education campaigns to
connect stakeholders and
make them aware of available
incentives can significantly
accelerate market growth.
Misinformation of
First-Generation
Vehicles
The original generation of CNG
vehicles were underpowered
and some could not meet their
required duty cycles, creating
long-lasting doubt in the
technology that still harms the
industry.
While CNG technology
improved greatly, additional
awareness campaigns are
necessary to inform end-users
about modern CNG
capabilities.
Lack of Inter-State
Coordination
A lack of inter-state
coordination about fueling
infrastructure plans and
locations may act as a barrier
to projects that otherwise
could be co-funded through
partnerships.
Facilitated discussion
between state and local
governments, fleet owners,
and fueling infrastructure
companies could help align
future plans and spur growth
(e.g., WCCAFICC).
Incentives/
Regulations
Push Towards
Zero-emission
Technology
The push for ZEVs threatens
both the consumer market and
potential funding for CNG,
LNG, and propane vehicles.
ZEV technologies do not
currently have the capability
to meet all required duty
cycles for MHD fleet
applications.
CNG, LNG, and propane can
be promoted as critical
intermediaries. Some fuel
functions, like LNG carriers,
may prove dominant over
other fuel types.
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Environmental Benefits and Environmental Justice
EPA defines Environmental Justice (EJ) as the fair treatment and meaningful involvement of all people
regardless of race, color, national origin, or income with respect to the development, implementation and
enforcement of environmental laws, regulations and policies.76 Promoting the expansion and
development of alternative fuel corridors provides an important opportunity to reduce the impact of
harmful emissions from vehicles and equipment that frequent our interstates, state highways, and freight
hubs situated in and near communities overburdened with air pollution and other environmental impacts.
Each of the West Coast states participating in the AFICC partnership have goals to promote EJ within their
respective state programs. For instance, and relevant to transportation, the State of California through
Senate Bill 350, the Clean Energy and Pollution Reduction Act, directs state agencies to conduct research
to evaluate the barriers to ZEV adoption within Disadvantaged Communities (DACs). Likewise, Assembly
Bill 1550 requires that 25% of the Greenhouse Gas Reduction Fund (GGRF) is spent on projects within
DACs. Under these statutes, multiple California state agencies are collaborating on evaluating best
practices and strategies to educate and inform DACs about the benefits of advanced vehicle technologies,
incentives available to support deployment, and partnership development opportunities to implement
emission reduction programs and strategies.
The environmental benefits of alternative fuel vehicle technologies are significant, specifically emissions
reductions. While, due to a lack of data on potential conventional vehicle replacement levels, it is difficult
to quantify the potential emissions reductions that may result from deployment of the infrastructure
proposed in this strategic plan, it is important to take note of these environmental benefits in general.
DOE reports that each of the alternative fuels in this plan's purview can contribute to emissions reductions
when used in vehicles. Both BEVs and FCEVs have zero tailpipe emissions, virtually eliminating on-road
hydrocarbon, oxides of nitrogen, carbon monoxide, particulate matter, and air toxics. GHG emissions from
ZEV operation are also significantly lower than conventional internal combustion engine vehicles, but the
scale of lifecycle GHG benefit generated by ZEVs varies greatly depending on the energy sources used to
charge/fuel them. Typically, renewable feedstocks for ZEV fuel will generate the greatest emission
benefits (e.g., solar, wind, organic waste, hydroelectric, etc.).77,78 Argonne National Laboratory's
Greenhouse Gases, Regulated Emissions, and Energy Use in Transportation (GREET) model estimates that,
on a life-cycle basis, GHG emissions are reduced by approximately 13% when propane is used to fuel
vehicles compared to conventional diesel fuel.79 Likewise, natural gas vehicles are lower-carbon fuels
compared to diesel, and their use can also result in significant reductions of hydrocarbons, carbon
monoxide, oxides of nitrogen, and GHG emissions.80 Such emissions reductions will improve air quality,
and in turn, lead to better health outcomes in EJ communities.
There are also economic incentives for deploying alternative fuel technology in EJ communities. Many
programs have additional funding provided for grantees located in EJ communities. In addition, there are
other financial incentives for investments in EJ zones or similar areas more generally. For example,
Opportunity Zones, from the Tax Cuts and Jobs Act, allow any corporation or individual with capital gains
in one of these zones to qualify for some tax benefits. This flexibility could allow for a variety of investors
to benefit from alternative fuel infrastructure investment in undercapitalized communities as defined by
U.S. DOT.
EPA's Regional Diesel Collaboratives, including the West Coast Collaborative (WCC), provide an important
mechanism for communities to participate with other stakeholders in developing and implementing
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programs, policies and strategies to reduce diesel emissions. Through AFICC, the WCC can engage EJ
communities and groups within their respective states to participate in planning activities to support
infrastructure development of alternative fuels that will enable the adoption of clean vehicles and
equipment that operate within and near impacted communities. As an important next step in promoting
and further supporting the development of the proposed sites in this strategic plan, AFICC should evaluate
ways to encourage EJ community and environmental group feedback and participation. Community
members that live within the locations that are targeted for a proposed alternative fuel site can be
important ambassadors and champions for project implementation.
The following are best practices and strategies to promote EJ and community involvement for the
development and expansion of alternative fuel corridors:
¦ State transportation agencies and regional MPOs may evaluate commercial vehicle traffic volumes
and locations to help prioritize advancement of alternative fuel infrastructure in environmental justice
and disadvantaged communities.
¦ Use community-based approaches for stakeholder involvement such as community facilitated
engagement, or collaborative governance.
¦ Apply diverse communication tools to reach and engage with environmental justice communities.
¦ Conduct research and needs assessments to understand priorities within EJ communities to
determine the best way to engage and support alternative fuel infrastructure development.
¦ Evaluate commercial vehicle activity within communities and identify industry partners to target and
collaborate with on infrastructure development.
¦ Provide access to online tools (websites, apps, and webinars) for communities to better understand
technologies and the benefits, strategies to support emission reductions, and access to information
on funding resources to support development and implementation.
¦ Make online and printed collateral on alternative fuels, funding programs, partnership opportunities
and outreach events available in multiple languages. Be familiar with the diversity of languages spoken
within a respective EJ community.
¦ Provide opportunities for communities to comment on and have a voice in planning activities within
their area.
¦ Engage schools to support awareness building campaigns, educate a child and you'll educate the
parent.
¦ Provide grants to help build the capacity of EJ or community groups to support the promotion of clean
transportation programs.
In Appendix B, CALSTART evaluates projects proposed in this strategic plan that are located within
environmental justice or disadvantaged communities to help AFICC partners understand how the
proposed projects can serve as important emission reduction solutions for air quality improvement and
public health protection.
California has developed a comprehensive and detailed environmental justice zone mapping tool that
incorporates pollutants, adverse environmental conditions, socioeconomic factors and prevalence of
certain health conditions. This tool, CalEnviroScreen 3.0, is the California Environmental Protection
Agency's (CalEPA) preferred tool for administering environmental justice grants and is used to identify
disadvantaged communities in California, as well as for data tracking pursuant to relevant laws and
regulations in the state.81 Given the significance this tool has for California's policy decisions, CALSTART
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used the CalEnviroScreen 3.0 tool to approximate EJ community status for California infrastructure sites
proposed in this plan. CalEnviroScreen 3.0, developed by CalEPA's Office of Environmental Health Hazard
Assessment (OEHHA), works by scoring locations on 19 indicators, 12 pollution indicators and 7 population
characteristics. The individual scores for each of these 19 indicators are weighted and added together to
derive a final percentile score.xxl" It is important to note that defining EJ communities varies state by state,
but for consistency CALSTART considered 80th percentile and above to be the threshold for a "Yes"
designation in the table shown in Appendix B. This table lists the infrastructure project proposals
evaluated in this plan document with a designation regarding potential EJ community classification, using
the process described above.
For Oregon and Washington, CALSTART used the EPA's environmental justice (EJ) mapping and screening
tool called EJSCREEN, which is based on nationally consistent data that combines environmental and
demographic factors in its maps. Specifically, CALSTART evaluated sites on the following variables through
a comparison to each respective state (as opposed to the US as a whole): NATA Diesel PM, Ozone, and
PM 2.5. CALSTART considered 80th percentile and above on these measures to be the threshold for a "Yes"
designation in the table in Appendix B, as described in the paragraph above.XXIV
Workforce Development Considerations
As fleets continue their transition from conventionally fueled vehicles to alternative fuel vehicles (AFVs),
the demand for training and workforce development associated with AFV operation and maintenance is
expected to increase. In a 2014 study conducted by the California Community Colleges Chancellor's Office,
along with the California Energy Commission and the Centers of Excellence, it was estimated that fleets,
dealerships, and auto shops in California expected a 13-14% increase in the combined number of workers
in five occupations key to those businesses (from 58,900 in 2014 to 67,100 in 2015). Those five
occupations were as follows: automotive service technicians and mechanics, automotive master
mechanics, bus and truck mechanics, first-line supervisors, and fleet managers. Given the expected
growth in these occupations and given the differences between conventional vehicle technology and AFV
technologies, expanded and additional training will be required to support increased adoption of AFVs
across the West Coast.82
The California study focused only on occupations required to operate, service, and maintain AFVs. In
addition to the expected growth in those occupations, additional training will be required for workers
focused on alternative fuel infrastructure development. As AFVs are deployed, new fueling and charging
infrastructure needed to support them will be installed, requiring workers in fields including, but not
limited to design and engineering, manufacturing, construction, commissioning, maintenance, sales, etc.
While some alternative fuel infrastructure operates in similar ways to conventional fueling infrastructure,
additional training on the following topics may be required for workers focused on the installation and
operation of such infrastructure: safety, fuel science, high voltage electronics, etc.
Currently, there are a few programs across the West Coast that offer training on AFVs and supporting
technology. Sunline Transit Agency hosts a Center of Excellence in Zero Emission Technology, focused on
XXI" For more details on CalEnviroScreen 3.0, visit this link: https://oehha.ca.gov/calenviroscreen/calenviroscreen-
faqs
xxw pue t0 the state-level differences in defining EJ communities, CALSTART cannot guarantee that each site with a
"Yes" designation is, in fact, located within an EJ community, but this represents CALSTART's best judgement on the
topic.
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providing training on zero-emission buses.83 Los Angeles Metro and the County of Los Angeles now
provide a Transportation School, preparing youth in the county for careers in transportation.84 The
National Alternative Fuels Training Consortium, organized by West Virginia University but national in
scope, offers courses on a wide range of AFV- and infrastructure-related topics at training centers hosted
at El Camino College, Fresno City College, Rio Hondo College, and Yuba College in California.85 The
International Brotherhood of Electrical Workers offers training and certification on EV charging
infrastructure work.86 The Southern California Regional Transit Training Consortium offers some training
on battery-electric transit buses. According to the 2014 study mentioned above, eight community colleges
in California offer approved alternative fuels training programs while 25 offer alternative fuels
coursework. Additionally, private for-profit institutions like Universal Technical Institute (UTI) also offer
certificates and degree programs on related topics.82 Finally, training is also often provided to fleets by
AFV manufacturers.
While some training programs exist, expanded training will be required to develop a national workforce
skilled in AFV infrastructure installation, service, and maintenance. As stated previously, the primary focus
of this document is to highlight the demand for alternative fuel infrastructure on the West Coast, along
with funding needs to spur development of that infrastructure. Development of this infrastructure, and
the associated deployment of AFVs, will increase demand for a workforce skilled and trained on
alternative fuels. Thus, opportunities to leverage alternative fuel infrastructure development in building
workforce capacity should be considered. If and when funding becomes available to develop alternative
fuel infrastructure projects listed in later sections of this document, a portion of that funding may be well-
suited for expanded workforce development programs, and as demonstrated by the existing programs
above, such training can come from a variety of educational institutions, government agencies, and
private organizations.
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V. UNDERSTANDING ALTERNATIVE FUEL INFRASTRUCTURE NEEDS
Given the current and anticipated trends in alternative fuel vehicle adoption, AFICC sought to better
understand the need for medium and heavy-duty (MHD) alternative fuel infrastructure across the three-
state West Coast region of California, Oregon, and Washington. This section describes the outreach
conducted to understand those needs and to identify funding prioritization for prospective infrastructure
projects on the West Coast.
Stakeholder Engagement and Industry Outreach
Stakeholder engagement and industry outreach was critical to help realize the goals and objectives of
AFICC. By building a diverse and multi-disciplinary coalition of stakeholders across the three West Coast
states, AFICC was able to collect important feedback from partners on regional priorities, collaboration
strategies and opportunities to advance alternative fuel corridors. Throughout the project, the AFICC
conducted stakeholder outreach using different methods to understand infrastructure needs in the
region. Working through its Champion Groups, AFICC collected feedback on state goals related to MHDV
technology advancement and the various programs and policies to help support consumer adoption.
AFICC worked closely with the Champion Groups to help devise a broader stakeholder engagement and
industry outreach program that would include a series of webinars featuring government and industry
leaders sharing perspectives on state priorities, the availability of alternative fuel technologies, and
infrastructure investment needs.
AFICC stakeholders include federal, state and local governments, industry associations, fleets, port
authorities, fueling providers, vehicle and equipment manufacturers, Clean Cities Coalitions, utilities and
environmental organizations. The stakeholder engagement program used email, newsletter, telephone,
and in-person outreach to help raise awareness regarding the Champion Group meetings and the webinar
workgroup sessions. The Steering Team also facilitated several teleconferences and in-person meetings
with stakeholders to obtain specific information on existing funding programs, MHDV technology
advancement objectives, and alternative fuel infrastructure investment needs.
In this section, a detailed overview is provided on AFICC's Stakeholder Engagement Program and the
process used to collect feedback from Coalition members. This section also includes an overview of the
learnings from the California, Oregon, and Washington Champion Group meetings and AFICC's webinar
workgroup sessions.
Champion Groups
AFICC held nine Champion Group meetings with each state throughout the stakeholder engagement
process. During the Champion Group meetings, the following topics were covered:
1. Current alternative fuel technologies and infrastructure projects and deployments in each state;
2. Concerns and thoughts from fleets regarding adopting alternative fuel technologies;
3. Current incentives that are available for each state;
4. Applications for deployment of alternative fuel vehicles and infrastructure in the region; and
5. Goals and hopes for this collaborative effort.
Following each webinar, the Champion Groups would discuss the progress of the project, learnings from
the webinar sessions, and feedback on topics to cover/include in subsequent workgroup webinars and
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Champion Group meetings. Figure 8 provides an example of the stakeholder engagement carried out for
the Washington Champion Group and the webinar series for Washington stakeholders. All AFICC partners
were invited to partake in all webinar sessions regardless of their geographic location.
Figure 8: AFICC Workgroup Roadmap
Alternative Fuel Infrastructure Corridor Coalition (AFICC)
2018 Washington Workgroup Roadmap
Webinar Sessions
Session #1
M/HD Alternative Fuel
Landscape and Opportunities
Friday Sept. 21, 2018
10:30 a.m.-12:00 p.m. PT
Session #2
Natural Gas & Propane
Technologies Thursday,
Nov 1, 2018
2:30 - 4:00 p.m. PT
Session #3
Mug-In Electric Si Hydrogen
Fuel Cell Technologies
Tuesday Nov. 6r 2018
10:30 a.m. -12:00 p.m. PT
Session #4
M/HD Alternative Fuel1
Infrastructure Needs
Monday Dec. 10r 2018
1:00- 2:30 p.m. PT
Partners provide an update on alternative fuel
activities & opportunities to promote emission
reductions, advance clean techs, &.
transportation sustainability through
alternative fuel com dors.
Technology manufacturers and fueling infrastructure
providers provide information on the Latest emerging
technologies, operational suitability, infrastructure
considerations, St fleet best practices. These sessions
are open to CA, OR and WA partners.
Partners provide input on critical gaps &
infrastructure needs along key corridors &
evaluate actions and funding opportunities to
support partnership, coordination & project
implementation.
fl? $L Sk I &% S3-
WEST COAST COLLABORATIVE
A pufcJ ic pritdtc pjrlP4fship fao 'educe dieicl omvoii
The following are key takeaways from the Champion Group meetings.
California Champion Group
1. The California Public Utilities Commission has approved $2 billion for EVSE investment by Investor
Owned Utilities (lOUs). Utilities are looking into specialized rates for MHD EVs to combat demand
charges and make fleet electrification more cost effective.
2. California's Volkswagen NOx mitigation funds will support ZEV deployment and related
infrastructure development.
3. California's ZEV Executive Order directs the state to implement 250,000 additional light-duty EVSE
and 200 hydrogen stations by 2025. The California Governor's Office of Business and Economic
Development is actively coordinating MHD hydrogen infrastructure deployment activities in
partnership with organizations including, but not limited to the following: Nikola, Toyota, the
California Fuel Cell Partnership, and the California Hydrogen Business Council.
4. California is looking into additional highway segments for the next round of FHWA Alternative
Fuel Corridor nominations.
5. Freight also flows east-to-west, future engagement with Arizona and Nevada will be useful to
expand MHD alternative fuel corridors.
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6. Ports of Long Beach and Los Angeles are seeking to electrify their operations, which will require
significant charging and/or hydrogen fueling capacity. The port authorities are actively working
with their tenants to electrify equipment in all feasible applications.
7. When moving towards alternative fuel technologies, community involvement will be imperative,
and the Assembly Bill 617 advisory committees can help to guide deployment in this regard.
Oregon Champion Group
1. There is a large existing natural gas network with landfill RNG access. Oregon is interested in
expanding public access to natural gas fueling infrastructure using in-state RNG supplies.
2. According to Oregon truckers, there is not a huge incentive for moving to alternative fuels. Many
members of the Oregon Trucking Association have indicated that they do not want to adopt
technologies beyond clean diesel.
3. There is a technology readiness gap because many MHD ZEV products will not be commercially
available in the near-term, so most MHDVs will continue to run on clean diesel powertrains. Fleets
need more specifics on the operational capabilities of MHD ZEVs.
4. Oregon wants to increase their connections with California and Washington. This coalition is a
good way of growing relations throughout the region.
5. Oregon supports near-term heavy-duty alternative fuel deployment goals for local applications,
like last-mile delivery. Oregon Metro has developed a regional freight strategy including
sustainability goals for multi-modal goods movement.87
6. For fleets to adopt alternative fuel technologies at a large scale, differential vehicle weight and
size issues need to be resolved.
7. To support more alternative fuel deployment, more incentives need to be available for adoption
of these technologies.
Washington Champion Group
1. Pacific Coast Collaborative is working along the same track with light-duty electrification
infrastructure and there is much to learn from this effort.
2. Puget Sound Clean Air Agency is looking into changing urban delivery and goods movement supply
chains to accommodate alternative fuel technologies. Infrastructure is needed to prepare for a
large increase in alternative fuel vehicles in urbanized areas like the Puget Sound region.
3. Private business fleets should be part of this effort to educate them on heavy-duty freight
planning work and strategies to advance their fleet sustainability goals.
4. Washington is working on a techno-economic assessment of RNG production and natural gas
pipeline injection of RNG.
5. Washington wants to address municipal concerns with infrastructure development obligations.
6. Washington has completed corridor designations both internally, and in collaboration with
neighboring states. It was difficult to complete a tri-state designation that included both California
and Oregon. California is a large state with many ongoing alternative fuel efforts, and that made
it difficult to collect needed information in the timeframe needed to compose the designation
nominations.
7. Fleets want electric buses, but the manufacturers cannot make them fast enough. There is a
manufacturer capacity problem in creating these buses. That makes it difficult to set accurate and
timely schedules for related infrastructure investments.
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Workgroup Webinar Sessions
To better understand the needs of Oregon and Washington, AFICC hosted a workgroup webinar series to
gain an understanding of the states' alternative fuel landscape, the availability of alternative fuel
technologies, and infrastructure needs to advance MHD AFVs.xxv For Oregon and Washington, there were
a total of six webinars; Oregon and Washington each kicked off their webinar series with a "Medium- and
Heavy-Duty Alternative Fuel Landscape" webinar. After each of those webinars, the coalition hosted two
technology webinars to educate participants on the current medium- and heavy-duty alternative fuel
technologies. This included a "Natural Gas and Propane Technologies & Infrastructure" webinar and a
"Plug-In Electric and Hydrogen Fuel Cell Technologies & Infrastructure" webinar. After the technology
webinars, Washington and Oregon each had a final webinar on the "Medium- and Heavy-Duty Alternative
Fuel Infrastructure Needs" for each state. The goal of this series was to learn about current alternative
fuel projects in the region and identify opportunities for synergy of new alternative fuel infrastructure
investments.
For each webinar hosted by the Coalition, targeted outreach was used to increase interest and guarantee
that desired stakeholders were able to participate in the webinar series. Various forms of communication
were used to gain interest and ensure that relevant individuals participated in the event, such as calls,
personal emails, and WCC email newsletter announcements. The Steering Team also asked the Champion
Groups to invite relevant parties to attend the webinars.
Session 1: Medium- and Heavy-Duty Alternative Fuel Landscape and Opportunities in Oregon
The first session in the AFICC webinar series was entitled, "Medium- and Heavy-Duty Alternative Fuel
Landscape in Oregon". The goal of this webinar was to learn from Oregon partners about the activities
they were conducting to promote emissions reductions, advance clean technologies and transportation
sustainability throughout the state. Discussion leaders included: Federal Highway Administration, Oregon
Department of Transportation, Oregon Trucking Association, Oregon Department of Energy, Oregon
Metro, and Rogue Valley Metropolitan Planning Organization. During this webinar, the coalition
established a shared understanding of Oregon's alternative fuel goals, and progress to date.
Key takeaways from this webinar included:
1. Oregon has a great opportunity to designate many of its highways as Alternative Fuel Corridors
for plug-in electric, hydrogen, propane, and natural gas technologies.
2. Oregon has worked extensively to support the development of the West Coast Electric Highway
(a light-duty electric corridor) and can apply learnings from this work to medium- and heavy-duty
alternative fuel infrastructure deployment efforts in the state.
3. Oregon has a large amount of RNG production potential that can be allocated to transportation
fuel applications.
4. Oregon is developing a regional strategy to support RNG production and distribution.
5. Oregon Metro has a regional freight policy and action plan that emphasizes the need to deploy
low and zero-emission goods movement technologies.
xxv Webinar recordings and presentation slides are available at:
https://westcoastcollaborative.org/workgroup/wkgrp-fuels.htm
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Session 2: Medium- and Heavy-Duty Alternative Fuel Landscape and Opportunities in Washington
The second session in the AFICC webinar series was entitled, "Medium- and Heavy-Duty Alternative Fuel
Landscape and Opportunities in Washington". The goal of this webinar was to learn from Washington
partners about the activities they were conducting to promote emissions reductions, advance clean
technologies and transportation sustainability throughout the state. Discussion leaders included: Federal
Highway Administration, Washington Department of Transportation, Puget Sound Regional Council, Puget
Sound Clean Air Agency, and Washington State University.
Key takeaways from this webinar included:
1. Washington has a great opportunity to designate many of its highways as Alternative Fuel
Corridors for plug-in electric, hydrogen, propane, and natural gas technologies.
2. Washington worked extensively to support implementation of the West Coast Electric Highway
and will use that experience to examine electrification of its goods movement and public transit
systems as well.
3. Puget Sound Regional Council presented its four-part GHG mitigation strategy with vehicle
technology advancement being a key component.
4. Washington recently conducted an RNG development study and is exploring state policy options
to address the study's recommendations.
5. Participants talked about their interest in increasing RNG, as well as the funding sources needed
to support deployment of RNG and other alternative fuel technologies.
Session 3: Natural Gas and Propane Technologies and Infrastructure
After the initial Washington and Oregon webinars, the coalition hosted two technology webinars for all
interested WCC partners. The first technology webinar was entitled, "Natural Gas and Propane
Technologies & Infrastructure". The goal of this webinar was to learn from vehicle manufacturers, fuel
suppliers, and fleets about the benefits, applications, and business case for natural gas and propane
technologies. Discussion leaders for this webinar included: Trillium-Love's, Ruan Transportation
Management Systems, Western Propane Gas Association, ROUSH Clean Tech, City of Vancouver-
Washington, and National Renewable Energy Laboratory (NREL).
Key Takeaways from this webinar included:
1. Natural gas technology is attractive, reliable, and clean compared to liquid, petroleum-based
technologies. There are currently incentives for natural gas deployment, and fleets can work with
fueling providers to develop refueling infrastructure.
2. Ruan presented its case study on how to implement RNG technology in heavy-duty trucking
operations. They also shared the key stakeholders needed to successfully develop an RNG station.
3. MHD propane vehicles are safe and reliable. They have been particularly successful in school bus
and emergency response applications, and the fueling infrastructure is relatively affordable.
4. The City of Vancouver, Washington presented a case study on propane technology adoption.
There are many different fleet applications for propane, the return on investment is strong, and
it is relatively easy to transition from diesel.
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5. When compared to diesel, propane generally generates operational cost savings. However, there
are currently limitations for Class 8 propane vehicle availability.
Session 4: Plug-In Electric & Hydrogen Fuel Cell Technologies & Infrastructure
After the Natural Gas and Propane Webinar, the coalition hosted a session entitled, "Plug-In Electric &
Hydrogen Fuel Cell Technologies & Infrastructure". The goal of this webinar was to learn from vehicle
manufacturers, fuel suppliers, and fleets about the benefits, applications, and business case for plug-in
electric and hydrogen fuel cell technologies. Discussion leaders for this webinar included: Chanje,
GreenPower Motor Company, Hydrogenics, and Ballard Power Systems.
Key Takeaways from this webinar included:
1. Fleets are placing large orders for medium-duty battery-electric vehicles (e.g., delivery vans).
There are few barriers to electrifying this application for small-scale deployments. However,
charging infrastructure planning and investment are key constraints for large-scale, fleetwide
deployments.
2. Many GreenPower fleet customers have been able to utilize existing charging infrastructure,
which has made their transition from diesel to battery-electric technology easier.
3. There are many applications for MHD FCEVs in goods movement and other commercial transport
applications. Moving to hydrogen technology is an easy fit for many MHD fleets from an
operations perspective (e.g., short refueling time, range, and equipment performance).
4. Hydrogen fuel can be created onsite using natural gas steam reforming, or water electrolysis.
5. FCEV incremental cost, and hydrogen fueling infrastructure planning and investment are the
primary barriers to fleet adoption of these technologies.
Session 5: MHD Alternative Fuel Infrastructure Needs & Opportunities in Washington
The final session in the Washington webinar series was entitled, "Medium- and Heavy-Duty Alternative
Infrastructure Needs & Opportunities in Washington". The goal of this webinar was for ports, fleets,
industry associations, and state agencies to provide input on infrastructure needs and opportunities to
advance medium- and heavy-duty alternative fuel corridors in Washington. Discussion leaders included
the following: Port of Tacoma, Northwest Seaport Alliance, Port of Seattle, National Association of Truck
Stop Operators, Washington Trucking Association, King County Department of Transportation, and
Washington State Energy Office.
Key Takeaways from this webinar included the following:
1. NREL's Station Locator allows users to locate gaps in alternative fuel corridor designations as well
as existing alternative fuel stations.88
2. Many ports are introducing alternative fuel technologies into parts of their marine, cargo
handling, and airport operations.
3. Some ports are working on sustainability strategies that include ambitious emission reduction
targets.
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4. Truck stops are starting to deploy alternative fuel infrastructure, but there is a need for more
federal and state funding and policy assistance to support these efforts.
5. Washington truckers are struggling to move to alternative fuels because there is a lot of
uncertainty on which direction the industry will move. They need certainty in which technology
to adopt into their operations (i.e., choosing a fleet technology transition pathway among electric,
hydrogen, propane, and natural gas).
6. King County Metro provides a helpful case study for deploying battery-electric transit buses and
scaling up charging infrastructure to meet operational needs.
7. Washington continues its work on RNG production and future policy considerations.
Session 6: MHD Alternative Fuel Infrastructure Needs & Opportunities in Oregon
The last session in the Oregon webinar series was entitled, "Medium- and Heavy-Duty Alternative
Infrastructure Needs & Opportunities in Oregon". The goal of this webinar was for ports, fleets, industry
associations, and state agencies to provide input on infrastructure needs and opportunities to advance
medium- and heavy-duty alternative fuel corridors in Oregon. Discussion leaders included: U.S.
Department of Transportation - Volpe Center, National Association of Truck Stop Operators, Columbia
Willamette Clean Cities Coalition, Oregon Department of Energy, and the Port of Portland.
Key takeaways from this webinar included the following:
1. NREL's Station Locator allows users to locate gaps in alternative fuel corridor designations as well
as existing alternative fuel stations.89
2. Port of Portland working to convert some of its operations to alternative fuel technologies.
3. Policy reform and funding support are needed to help implement alternative fuel infrastructure,
and if federal leadership is lacking, then the states need to pick up the slack.
4. Columbia Willamette Clean Cities Coalition is working on a large-scale natural gas and propane
infrastructure project to deploy stations along major interstate and highway corridors.
5. Oregon is continuing their work on RNG production, and these efforts need to be expanded to
include RNG fueling infrastructure.
From the last two webinars and targeted outreach, the AFICC Steering Team aimed to gather the
information shown in Table 14 regarding potential alternative fuel infrastructure projects on the West
Coast.
Table 14: Information Gathered from Outreach
Project Description
Infrastructure Needs
Project Location
Station Type
Distance to Nearest Corridor
Number of Dispensers/ Chargers
Project Partners
Estimated Fuel/ Energy Use
Fleet Vocation
Equipment Costs
Vehicle Technology/ Fuel Type
Development Costs
Number of Vehicles
Operational Costs
Project Timeline
Construction Schedule
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The Steering Team chose the information in Table 14 to learn more about infrastructure projects
throughout the region, and if there were projects that needed funding assistance to complete
development. CALSTART then worked to obtain this information and collected data on many potential
alternative fuel infrastructure project proposals.
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¥1. ALTERNATIVE FUEL INFRASTRUCTURE PROJECT READINESS CRITERIA
After conducting outreach to AFICC partners across the three West Coast states, CALSTART sought to
obtain deeper insights from fueling infrastructure providers to develop a standard approach for evaluating
potential projects on measures of readiness. The Champion meetings, webinars, and targeted outreach
helped set the stage for further analysis into infrastructure funding needs throughout the region and
developing these readiness criteria was deemed a logical next step for that analysis. The purpose of this
exercise was to develop a set of readiness criteria that CALSTART could use to adequately vet and
categorize the alternative fuel infrastructure project proposals it would receive during the AFICC planning
process. As described in the following sections, CALSTART developed and distributed surveys to fleets and
fuel providers to obtain infrastructure project proposals for which survey respondents wished to receive
funding. With the expectation of receiving numerous proposals through these surveys, CALSTART
developed the criteria to prioritize those project proposals that appear to be most ready for funding.
Importantly, it is CALSTART's view that while some projects would be more ready for funding than others,
all project proposals should be considered.
To develop this set of criteria, CALSTART contacted multiple fuel providers and developers to gain their
insights into what should be considered when determining the readiness of an infrastructure project for
development. This targeted outreach included discussions and meetings with specific stakeholders to
learn more about their role in alternative fuel infrastructure development and how infrastructure is
deployed. Operating under the notion that any future funding for projects will likely be allocated based
on a competitive application process, CALSTART sought to work with fuel provider partners to develop
criteria that would serve as a basis for evaluating projects under this notion. The list of organizations which
CALSTART spoke to on this matter is as follows:
1. EV: CALSTART Internal Experts, ChargePoint;
2. H2: Trillium-Love's, Hydrogenics, Mitsui, First Element;
3. LPG: Columbia-Willamette Clean Cities Coalition; and,
4. CNG and LNG: Trillium, a Love's Company;
From these discussions and its own research, CALSTART put together the following criteria to be
considered when examining infrastructure projects. The remainder of this section explains these criteria
and how they were used to evaluate projects on their readiness for development and funding.
1. Fuel type must be one of the following: EV, H2, LPG, CNG, LNG
2. Estimate number of anchor fleet vehicles (for fleet-proposed projects) / Estimated annual fuel
throughput (for fuel provider-proposed projects)
3. Strategic location
a. Distance from a major corridor
b. Distance from the closest station of the same fuel type
4. Cost share
5. Defined scope and budget
6. Medium-and heavy-duty vehicle accessibility
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First, as a requirement, any projects considered in this plan must include one of the alternative fuel types
in the project's purview. Fuels included in this list are plug-in electric, hydrogen, liquefied petroleum gas
(propane), compressed natural gas, and liquefied natural gas.
Second, to justify the development of any medium- and heavy-duty accessible station, demand for the
fuel provided by that station must be guaranteed. Based on CALSTART's conversations with the partners
mentioned above, having an anchorfleet is critical for an applicant, and more vehicles committed to using
the station are better as they spread out risk. Having fleets committed to using the station being
developed proves demand for that fuel. CALSTART identified optimal minimum annual fuel throughput
amounts for MHDV accessible stations, listed below:
1. EV: 50 kilowatt charger minimum50™1
2. H2: 30,000 kilograms per year
3. LPG: 165,000 gallons per year
4. CNG: 220,000 DGE per year
5. LNG: 220,000 DGE per year
Third, as this plan seeks to identify gaps in corridor-specific fueling needs for alternative fuel vehicles, it is
important that infrastructure projects be strategically located to support completion of any signage
pending/incomplete corridors as designated by FHWA. For this criterion, CALSTART determined that two
criteria are important: 1) the distance from the fueling station to the nearest corridor, and 2) the distance
from the fueling station to the closest fueling station of the same fuel type. FHWA has set the following
requirements for alternative fuel corridors as it relates to these distances:
1. EV: Within five miles from a highway, 50 miles between stations
2. H2: Within five miles from a highway, 100 miles between stations
3. LPG: Within five miles from a highway, 150 miles between stations
4. CNG: Within five miles from a highway, 150 miles between stations
5. LNG: Within five miles from a highway, 200 miles between stations
For purposes of considering readiness categories, CALSTART considers the mileage requirements listed
above as optimal. Mileage from a corridor and mileage between stations which are under the optimal
distance thresholds are considered more ready than mileage that is above the optimal distance
thresholds.
Fourth, another important criterion is cost share. Based upon survey results, which are discussed in more
detail below, CALSTART determined that a cost share requirement would be ideal for alternative fuel
infrastructure projects considered as part of this effort. While no minimum cost share threshold has been
defined for this readiness evaluation system, proposals that report lower funding needs (in percentage of
CAPEX) are categorized as more ready than those which have higher funding needs.
XXVI The minimum kilowatt charging capacity for MHD capable electric vehicle charging stations will impact the time
required to charge a vehicle of that size. Higher power levels will lower charging durations and make for a more
seamless charging experience for fleets. The 50 kW minimum is determined from a Penske fleet case study in which
50-150 kW fast chargers were installed (https://blog.gopenske.com/lease/penske-truck-leasing-opens-high-speed-
commercial-electric-truck-chargers-in-southern-california/)
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Fifth, regarding project scope and budget, those suggested projects which have a clearly defined scope
and budget are categorized as more ready than those that have not provided these details. Scope and
budget include, but are not limited to, the capacity and throughput of the station, where the station will
be located, what fuels it will include, the size of the station, which fleets are expected to use it, and a
budget estimate for developing the station. The project may either be a new fueling station development
or the addition of capacity at an existing alternative fuel station; both were considered.
Finally, all stations - public, private, and limited access - must be capable of accommodating a medium-
duty vehicle at minimum. As the focus of this effort is to fill alternative fuel infrastructure gaps for MHDVs,
this is considered a requirement. Additionally, as there is a projected need for heavy-duty vehicle
accessible alternative fueling stations, any project capable of fueling up to Class 8 vehicles (i.e., >33,000
lbs GVWR) are considered more ideal than those that are not.
Table 15 below shows all current readiness criteria with descriptions of how each criterion was used to
evaluate project proposals.
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Table 15: Project Readiness Criteria
Weights
Metric
Fuel Type
Evaluation Type
Evaluation System Description
Requirement
Fuel type
All fuel types
Requirement
Fuel type(s) must be chosen from this list: EV, H2, LPG, CNG, LNG
30% (for fleets
only)
Number of anchor fleet vehicles
(fleet-proposed projects only)
All fuel types
Minimum Requirement,
1 Through 10
At least 1 anchor fleet is required, more vehicles are valued higher than less
30% (for fuel
providers only)
Proven demand for fuel (fuel-
provider proposed projects only)
EV
Minimum Requirement,
1 Through 10
50 kW charger minimum, higher power rating correlates to a higher readiness category
H2
Minimum Requirement,
1 Through 10
30,000 kg per year minimum, more demand correlates to a higher readiness category
LPG
Minimum Requirement,
1 Through 10
165,000 gallons per year minimum, more demand correlates to a higher readiness category
CNG
Minimum Requirement,
1 Through 10
220,000 diesel gallon equivalent per year minimum, more demand correlates to a higher readiness category
LNG
Minimum Requirement,
1 Through 10
220,000 diesel gallon equivalent per year minimum, more demand correlates to a higher readiness category
20%
Strategic location
All fuel types
Optimal Requirement, 1
Through 10
Optimal distance from highway: five miles maximum. Shorter distance is categorized as more ready higher than
farther distance.
20%
Strategic location
All fuel types
Optimal Requirement, 1
Through 10
Optimal distance between stations: Optimal amounts are categorized as more ready. Shorter distances are better
than farther distances.
EV
Optimal Requirement, 1
Through 10
EV - 50 miles
H2
Optimal Requirement, 1
Through 10
Hydrogen -100 miles
LPG
Optimal Requirement, 1
Through 10
Propane -150 miles
CNG
Optimal Requirement, 1
Through 10
CNG-150 miles
LNG
Optimal Requirement, 1
Through 10
LNG-200 miles
15%
Cost share
All fuel types
1 Through 10
Projects that share more cost are categorized as more ready higher than those that share less cost.
15%
Scope and budget defined
All fuel types
Requirement, 1
Through 10
Scope and budget required in application. Projects with more details provided on scope and budget will be
categorized as more ready.
Requirement
Medium-and heavy-duty vehicle
accessible
All fuel types
Requirement
All stations must be at least Class 5 vehicle accessible, and ideally, they should be up to Class 8 accessible.
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After being evaluated on the metrics listed in Table 15, each project was grouped into one of three
readiness categories based on those evaluations. Those readiness categories are defined below. It is
important to note that cut-offs between each of these three readiness categories were made
quantitatively based on the results from evaluations using the readiness criteria mentioned above, but
they do not sort the proposals into equal thirds. See ranges of resulting scores for proposals across fuel
types on each readiness category in Table 16. The cutoffs between readiness categories were applied after
scoring all of the proposals, not before scoring, and therefore the resulting minimum and maximum scores
per readiness category vary by fuel type. Because the richness and the amount of information contained
in each proposal varied so much, it was not ideal to assign readiness category cutoff scores that would be
uniform across all fuel types. Instead, CALSTART assessed the readiness of proposals by fuel type and used
its discretion to determine cutoffs between readiness categories based on both quantitative and
qualitative measures.
1. Advanced Site: Advanced Sites are the project proposals deemed most ready for development.
Based on the readiness criteria in Table 15 these sites have a high degree of readiness for funding
and development, and a high degree of viability in meeting WCC AFICC's goals for alternative fuel
infrastructure development. For example, this could be a proposal that includes a location which
is highly specific (e.g. a street address, city, and state), a clear estimated annual fuel throughput,
a location near a major west coast corridor, and a defined CAPEX estimate.
2. Emerging Site: Emerging Sites are the second to most ready for development, behind Advanced
Sites. These sites are considered less ready for funding and development than Advanced Sites but
more so than Potential Sites. These proposals were often deemed less ready than Advanced Sites
due to a lack of information about project scope. For example, this could be a proposed site with
demonstrated demand for fuel but lacking a specific location (proposing a county instead of a
cross street or address).
3. Potential Site: Potential Sites are the proposals deemed least ready for development. Based on
the readiness criteria in Table 15, these sites have a low degree of readiness for funding and
development. The reasons for the lower readiness category vary across proposals, but often the
project scope for these proposals is vague or is lacking responses to multiple readiness criteria
metrics. For example, this could be a proposed site with a vague location (e.g. proposing location
on a certain highway near a city, but with no address or cross street), and not many associated
details (e.g. no listing for annual throughput or number of vehicles that the station is expected to
support, no response on the amount of funding assistance needed, and no CAPEX estimate
reported).
Table 16 Range of Resulting Scores for Readiness Category by Fuel Type
EV
H2
LPG
CNG
LNG
Advanced
48.5-62
57.5-59
50.5 -63.5
45-68
42-44
Emerging
30.5-42.5
38
N/A
35-41.5
26
Potential
20-27.5
32
N/A
16.5 - 21
12-20
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VII. FLEET AND FUEL PROVIDER SURVEY RESULTS
After speaking with fuel provider partners about what criteria would be best for evaluating infrastructure
projects, AFICC needed to obtain information on proposed and potential alternative fuel infrastructure
developments on the West Coast. To do this, CALSTART developed and administered two surveys. One
survey was administered to fleets and equipment users operating in a variety of vocations within the three
states. The purpose of this survey was to evaluate both the demand for alternative fuel infrastructure on
the West Coast, as well as the funding resources needed to support such projects.
The second survey was administered to fuel providers and infrastructure developers supporting the West
Coast states. Similar to the fleet survey, its purpose was to understand where fuel providers see needs
and opportunities for alternative fuel infrastructure development, and to understand the funding and
throughput required to justify station development. Both surveys were developed using SurveyMonkey,
and with the help of AFICC partners, CALSTART administered both surveys to a broad audience using email
announcements and one-on-one targeted outreach. The targeted stakeholders included participants from
the webinar series and stakeholders that were suggested by the Champion Groups. It was imperative that
West Coast Ports complete the surveys and that the Clean Cities Coalitions distribute the survey to fleets
in their regions. From this outreach effort, CALSTART received numerous responses for both the fleet
survey and the fueling provider survey.
Survey Results In and Of Themselves Are Incomplete: Refer to Sections IX and ¥111 for Full and
Final Results and Takeaways
While these surveys yielded many of the proposed infrastructure projects that are listed in Section IX,
CALSTART also conducted targeted outreach to various partners which yielded additional project
proposals and information included in this plan. As a result of the added non-survey outreach efforts,
some of the survey results do not match the final results represented in the full project listings shown in
Section IX. For example, the surveys asked respondents to explain how much funding would be needed
to justify infrastructure project development in terms of a minimum percentage of the total CAPEX for a
given project. The responses to this question differ from the same information provided in the final list of
project proposals because the survey asked for this information under the assumption that the
infrastructure project would be at a minimum level of fuel throughput and scale, whereas actual project
proposals vary in scope and scale. Also, the inclusion of more proposals solicited through non-survey
forms of outreach cause final statistics and related percentages to shift, differing from those shown via
survey results alone. Differences of this sort exist between the survey results and the final list of project
proposals which include survey results and other outreach results combined. For complete results, refer
to the project listings in Section IX as well as the Conclusions and Recommendations listed in Section VIII.
This section shows results from the surveys alone and does not include additional insights yielded from
other forms of outreach.
The remainder of this section focuses only on the key findings from both surveys. For more detailed survey
results, and to see the associated figures and tables, view Appendix C.
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Fleet Survey Results - Key Takeawaysxxv"
Respondent Profiles
In total, 26 organizations responded to the fleet survey representing all three West Coast states.
Respondents varied widely in the vocations they represented, including the following: drayage, transit
refuse, school districts, food and beverage distribution, locomotive services, cargo handling, construction,
regional government, air quality inspection and monitoring, road maintenance, airport shuttle services,
marine cargo handling, utilities, and municipal street sweeping.
Fuel Type Preferences and Fuel Demand
Most of the vehicles currently operated by fleet respondents are gasoline or diesel at an average of 608
and 541 vehicles per respondent, respectively. CNG is the next in line at 38 vehicles per respondent, LNG
at 9, LPG at 4, EV at 20, and H2 at less than one (0.27) on average. When asked what alternative fuel type
they are most interested in adding to their fleets in the next three-to-five years, most said EVs, followed
by CNG, H2, LNG, and LPG.
When asked to estimate the average annual fuel demand required for each alternative fuel type, fleet
responses averaged out to the following amounts: 416,875 DGE of CNG per year, 54,542 DGE of LNG per
year, 1,556 gallons of LPG per year, 2.14 MW of EV charging capacity. Respondents did not provide
responses for annual H2 fuel demand.
Funding Needs
Most fleet respondents (69%) stated that they will need funding support to purchase alternative fuel
vehicles or equipment, while 15% said that they would not need funding, and 15% said that they did not
know if funding would be need. Likewise, 73% of fleet respondents stated that they would need funding
to purchase alternative fuel infrastructure, with 19% stating that they did not know if funding would be
needed, and 8% stating that they would not need funding for infrastructure.
When asked how much funding would be needed to cover the cost of purchasing alternative fuel vehicles
and infrastructure, 23% of fleets said that at least 50% of the total cost of an alternative fuel vehicle would
need to be covered by funding assistance to justify the purchase. Similarly, 27% of fleets stated that 50%
of CAPEX for developing alternative fuel infrastructure would need to be covered to justify the
development. The second ranked answer to that question was 100% of CAPEX, with 23% of fleets
responding with that answer.
Infrastructure Projects Underway
When asked whether fleets currently have alternative fuel infrastructure projects underway, a majority
of respondents reported that they do (65%), while 27% do not, and 8% did not know if they had projects
underway. Of those respondents that report having projects currently underway, 65% of them report
having EV projects, 26% report CNG projects, 9% report LNG projects, 4% report H2 projects, none
reported LPG projects, and 22% report having other projects underway including RNG or renewable diesel.
Of those respondents that do not have projects underway, 68% of them stated that funding support is
xxv" As stated above, this survey was administered before additional outreach was conducted which yielded
additional information, and therefore the survey results in and of themselves are not a complete representation of
the full results of this effort. Please refer to Sections VIII and IX for full and final results.
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needed, 14% stated that no funding support is needed, and 18% stated that they did not know if funding
support is needed.
Infrastructure Project Proposals
Fleets provided numerous infrastructure project proposals for which they would like to be considered for
funding. Those listings are included in Section IX.
Fuel Provider Survey Results - Key Takeawaysxxvl"
Respondent Profiles
In total, 31 fuel provider organizations responded to the survey, many of which operate in more than one
West Coast state. Those organizations span all three states, with 66% of them operating in California, 63%
of them operating in Washington, and 46% of them operating in Oregon.
Alternative Fuel Infrastructure Development Plans
When asked what plans each fuel provider respondent had to develop alternative fuel infrastructure in
the three West Coast states within the next three to five years, respondents gave answers that varied by
fuel type and by state. In California, 40% of respondents plan to develop EV stations, 23% plan to develop
CNG stations, 17% plan to develop H2 stations, 9% plan to develop LPG stations, 6% plan to develop LNG
stations, and 34% report having no plans to develop alternative fuel infrastructure in California within the
next three-to-five years. In Oregon, 20% plan to develop EV stations, 20% plan to develop CNG stations,
12% plan to develop H2 stations, 8% plan to develop LNG stations, 8% plan to develop LPG stations, and
64% report having no plans to develop alternative fuel infrastructure in Oregon within the next three-to-
five years. In Washington, 29% plan to develop EV stations, 17% plan to develop LPG stations, 17% plan
to develop CNG stations, 13% plan to develop H2 stations, 8% plan to develop LNG stations, and 46%
report having no plans to develop alternative fuel infrastructure in Washington within the next three-to-
five years.
Average Annual Fuel Demand Required for Station Development
When asked to describe the average annual fuel demand required to justify the development of a station
that is on the lowest end of project size and scope, fuel providers gave the following responses: On
average, respondents report that 249,333 DGE of CNG is required per year, 67,500 gallons of LPG is
required per year, 30,000 kg of H2 is required per year, and 2 MW of EV charging capacity is required. No
responses were given for LNG stations.
Funding Needs for Station Development
Like fleets, fuel providers were asked to state what minimum level of funding assistance needed as the
percentage of a station's total CAPEX to justify development. Twenty-five percent (25%) of respondents
stated that at least 50% of station development CAPEX would need to be covered by funding assistance
for them to justify implementation. The remaining responses to this question varied evenly, as 8% of
respondents selected each of the following funding amount answer options: 0%, 20%, 30%, 40%, 60%,
XXVI" As stated above, this survey was administered before additional outreach was conducted which
yielded additional information, and therefore the survey results in and of themselves are not a complete
representation of the full results of this effort. Please refer to Sections VIII and IX for full and final results.
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80%, 100%. Seventeen percent (17%) of respondents said that they did not know how much funding would
be required to justify development of a station.
Infrastructure Projects Underway
When asked what infrastructure projects fuel providers currently have underway, they gave the following
responses. In California, 21% of respondents report having CNG stations underway, 21% report having EV
stations underway, 7% report having LPG stations underway, 7% report having H2 stations underway, 0%
report having LNG stations underway, and 50% report that they have no alternative fuel station projects
underway. In Oregon, 14% of respondents report having either CNG or LPG stations underway, and 7%
report having either LNG, H2, or EV stations underway. 71% report that they have no alternative fuel
station projects underway in Oregon. In Washington, 14% of respondents report having EV stations
underway, 7% report having either CNG, LNG, LPG, or H2 projects underway, and 64% report that they
have no alternative fuel station projects underway. Please note that respondents were able to select
multiple answer choices in these survey questions, so percentages need not add to 100%.
Of those respondents that did report having alternative fuel infrastructure projects underway in
California, 43% report that they do not need funding support, 36% report that they do not know if they
need funding support, and 21% report that they do need funding support. In Oregon, 67% report that they
do not need funding support, 25% report that they do not know if they need funding support, and 8%
report that they do need funding support. In Washington 58% report that they do not need funding
support, 25% report that they do need funding support, and 17% report that they do not know if they
need funding support.
Infrastructure Project Proposals
Fuel providers provided numerous infrastructure project proposals for which they would like to be
considered for funding. Those listings are included in Section IX.
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VIII. CONCLUSIONS AND RECOMMENDATIONS
A Note Regarding Section IX: List of Project Proposals and Readiness for Funding
Section IX includes a full listing of the alternative fuel infrastructure development projects proposed by
survey and other outreach participants. The section also includes an assessment of each proposal's
readiness for funding by the authors of this strategic plan, as well as maps showing the locations of each
proposed project. Due to the length of Section IX, the authors of this document chose to place it behind
the Conclusions and Recommendations section in order to maintain a steady flow throughout this
document. As much of the Conclusions and Recommendations section relies upon the details in Section
IX, the authors remind the reader to view it and see detailed descriptions of all 147 infrastructure
proposals gathered through this effort.
Conclusions
The goal of the strategic development plan was to identify and prioritize a subset of alternative fuel
infrastructure projects that may fill network gaps needed to enable adoption of alternative fuel medium-
and heavy-duty vehicles (MHDVs) in California, Oregon, and Washington. After multiple years of research,
stakeholder engagement, workgroup sessions, and industry surveying, AFICC has developed four main
conclusions regarding alternative fuel infrastructure along the West Coast.
There is significant and proven demand for alternative fuel infrastructure in all three West Coast states:
California, Oregon, and Washington.
First, CALSTART's surveying efforts found that all fleet respondents are interested in procuring alternative
fuel vehicles within the next five years. This will increase the demand for alternative fueling stations
throughout the West Coast. While fleet respondents showed interest in all alternative fuel types covered
in this effort's purview, electricity was the most popular choice with 81% of respondents stating an
interest in procuring EVs.
Likewise, fuel providers shared similar interests and plans to develop alternative fuel infrastructure
throughout the West Coast. Most fuel provider survey respondents stated plans to develop alternative
fuel infrastructure in California within the next three to five years. Of those planned projects, most were
electric vehicle (EV) charging stations, followed closely by compressed natural gas (CNG) fueling stations,
and less so for hydrogen (H2), propane (LPG), and liquefied natural gas (LNG). Fuel providers did not
express as much interest in developing stations in Oregon and Washington, with most stating that they
do not have current plans to build alternative fuel infrastructure in those states. Those that do, however,
are most interested in building EV stations.
As shown in Table 17, fleet and fuel provider respondents proposed 147 alternative fuel infrastructure
projects for the West Coast states: 67 in California, 57 in Oregon, and 23 in Washington. Project proposals
were received for all 5 fuel types within the AFICC planning scope: 62 EV charging stations, 36 CNG
stations, 23 H2 stations, 13 LPG stations, and 7 LNG stations. Some participants also proposed
technologies outside the AFICC planning scope: catenary electric infrastructure projects, five in total; and,
one proposed liquid biofuel station. All stations varied in terms of size, scope, cost, and readiness.
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Table 17 Project Proposals by Fuel Type and State
EV
H2
LPG
CNG
LNG
Otherxxlx
Totals
California
34
6
6
16
0
5
67
Oregon
15
14
5
17
5
1
57
Washington
13
3
2
3
2
0
23
Totals
62
23
13
36
7
6
147
Fleets and fuel providers alike have a significant need for funding assistance to develop both new
alternative fuel infrastructure in West Coast states, and to expand current alternative fuel
infrastructure projects.
Most fleet respondents stated that funding support is needed to purchase and install alternative fuel
infrastructure: 73% of fleet respondents have a need for funding support to justify the decision to install
such infrastructure, 8% stated that they do not need funding support, and 19% stated that they do not
know if they need funding support. Likewise, most fleet respondents that are currently developing
alternative fuel infrastructure have a need for additional funding support: 68% of respondents said that
their current projects could use additional funding for a variety of uses, including but not limited to
purchasing equipment and materials, adding gas compression capacity, and expanding project scope.
Regarding funding needs, CALSTART solicited information via fleet and fuel provider surveys as well as
additional outreach via phone calls. When asked what percentage of the total capital expense (CAPEX) of
installing an alternative fueling station must be covered for them to consider development, 28% of these
combined outreach participants' infrastructure proposals stated that at least 50% of the CAPEX must be
covered by external funding, followed by 14% of proposals that said 70% of CAPEX should be covered, and
then a tie between 30% and 80% of CAPEX at 9% of proposals each. Less than 1% of proposals stated that
100% of the CAPEX must be covered by funding, and nearly 22% of proposals did not list a minimum
funding need amount. The remaining ~17% of proposals stated other funding amounts needed at lower
frequencies than those listed above. Effectively, about 77% of all proposals received through all channels
of AFICC outreach would be viable for development with external funding assistance up to 80% of project
CAPEX.
Alternative fuel infrastructure development is already underway in many locations throughout West
Coast states, and many projects require support.
Most fleets surveyed stated that they currently have alternative fuel infrastructure projects underway:
65% of respondents fall into this category with projects that range in fuel type, fleet size, location and
timeline. Of the projects underway, 65% are EV projects, 26% are CNG projects, and a smaller share are
LNG and H2 projects. Most projects are private access stations, likely located in our respondents' own
facilities. These existing projects may well serve as starting points for alternative fuel infrastructure
expansion on the West Coast, but given their private nature, more public and limited access stations
would be needed to expand corridor fueling for MHD AFVs.
xxix Qne participant in the outreach process proposed a liquid biofuel station in Redmond, Oregon. Other participants
proposed five catenary electric truck infrastructure projects.
80 I F
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Survey respondents and other partners provided 147 specific proposals for alternative fuel
infrastructure placement. These proposals likely represent only a portion of alternative fuel
infrastructure development needs on the West Coast as of December 2019.
The contents of this plan detail 147 specific proposals for new and expanded alternative fuel infrastructure
along the west coast. This represents the number of proposals made to the AFICC as of December 2019.
To see all 147 proposals, along with maps of how they contribute to filling-in current gaps for alternative
fuel infrastructure on major West Coast corridors, see Section IX of this plan.
As stated at the beginning of the document, the West Coast Collaborative believes that the infrastructure
development project proposals listed in this document, captured through responses to surveys and other
targeted outreach, only cover a small percentage of the full need for MHD alternative fuel infrastructure
on the West Coast, and it welcomes feedback on additional infrastructure needs not reflected in this
document.
CALSTART evaluated 127 of the 147 proposals on the criteria mentioned in Section VI of this strategic plan;
all projects were evaluated and then grouped into three categories based on their readiness level. Table
18 and Table 19 show summaries of readiness category results by state and fuel type, respectively. Please
note that twenty (20) proposals were unevaluated; five (5) of which were catenary electric truck
infrastructure proposals that was out of scope for this plan, one (1) was a biofuel station proposal which
was out of scope, and the remaining 14 did not contain enough information to properly evaluate them.
Table 18 Summary of Readiness Categories by State
California
Oregon
Washington
Totals
Advanced
32
32
13
77
Emerging
13
14
3
30
Potential
15
1
4
20
Unevaluated
7
10
3
20
Totals
67
57
23
147
Table 19 Summary of Readiness Categories by Fuel Type
EV
H2
LPG
CNG
LNG
Catenary Electric
Otherxxx
Totals
Advanced
37
9
13
15
3
0
0
77
Emerging
7
10
0
12
1
0
0
30
Potential
15
1
0
2
2
0
0
20
Unevaluated
3
3
0
7
1
5
1
20
Totals
62
23
13
36
7
5
1
147
xxx Qne survey respondent proposed a liquid biofuel station.
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Estimated funding needed to build the 141 proposed stations for targeted alternative fuel technologies
is $373,600,000.XXXI
The contents of this plan detail 141 proposed stations of various size, throughput, and level of
construction for the targeted alternative fuel technologies (i.e., EV, H2, LPG, CNG and LNG).XX)
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Take the learnings from this plan document and develop targeted investment plans per state.
Knowing several locations where alternative fuel infrastructure is needed in each state, AFICC partners
are well positioned to start a process of developing more targeted investment plans for each state. With
67 proposed stations in California, 57 in Oregon, and 23 in Washington, partners now have a starting point
in the effort of filling alternative fuel infrastructure gaps in each state. Further, it is important to note that
the 147 projects listed in this plan are only those suggested by survey respondents and outreach
participants, and do not reflect an exhaustive list of infrastructure needs across West Coast states. It is
highly likely that other fleets and fuel providers who did not participate in this effort also have an interest
in adopting MHD alternative fuel vehicles, and therefore have a need for MHD-accessible alternative fuel
infrastructure. Partners within the WCC, via the AFICC, may now take the learnings from this document
and start to develop strategies for filling infrastructure gaps in each of their states.
Examine, in more detail, the policy barriers to alternative fuel infrastructure development, and develop
policies that support accelerated MHD infrastructure implementation in California, Oregon, and
Washington.
As mentioned previously in this plan, while each state has existing policies to incentivize and advance
alternative fuel vehicle adoption and alternative fuel infrastructure development, it may not be sufficient
to meet future demand for these technologies. In some cases, state policies are a barrier to alternative
fuel deployment, and in other cases the lack of state policies and incentives are barriers. All three states
have varying approaches to reducing transportation emissions and encouraging alternative fuels. In all
states, however, there is a need to increase funding specifically for MHD alternative fuel infrastructure
development. AFICC partners are well positioned to support the development of such policies, using the
findings from this plan as a basis for championing such work.
Share the information in this strategic plan document with partners external and tangential to the West
Coast Collaborative.
AFICC partners have an extensive stakeholder base spanning multiple commercial vocations. Among the
AFICC's ranks are Clean Cities Coalitions, fleets, original equipment manufacturers, fuel and infrastructure
providers, government agencies, trade associations, ports, and more. Spreading the learnings from this
effort would send two primary signals to partners who are external and tangential to the AFICC: 1)
significant demand for MHD alternative fuel infrastructure exists,XXXIV and 2) funding support is needed to
meet that demand. One barrier that persists within the issue of alternative fuel vehicles and infrastructure
is the chicken and egg problem: fleets are hesitant to purchase alternative fuel vehicles for lack of
infrastructure, and fuel providers are hesitant to develop alternative fuel infrastructure for lack of fleet
users. By spreading the word that demand for both vehicles and infrastructure exists, the AFICC may serve
to alleviate some concerns that both fleets and fuel providers may have with respect to infrastructure.
XXXIV As highlighted previously in the strategic plan, the 147 proposed infrastructure projects reported by
participants of this plan's study efforts likely represent only a small fraction of the total need for alternative fuel
infrastructure and associated funding assistance throughout the West Coast.
83 I F
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West Coast Collaborative Partners are well positioned to both fundraise for MHD alternative fuel
infrastructure development and to petition for increased public funding support.
As mentioned in the recommendation to develop more supportive policies, AFICC partners are well
positioned to leverage their networks in also petitioning for increased alternative fuel infrastructure
development funding support. With this document serving as a partial basis for demonstrating MHD
alternative fuel infrastructure demand, and that funding is required to meet related public policy goals on
the West Coast, AFICC partners may work with policymakers to develop federal, state and/or local funding
mechanisms. As a next step in this process, it will be valuable to assess how much funding may be needed
by state and by fuel type.
This effort sought out to identify the need for MHD alternative fuel infrastructure in California, Oregon,
and Washington, and to identify potential projects to develop such infrastructure. After three years of
research and outreach, the WCC AFICC with support from CALSTART has identified 147 proposed MHD
alternative fuel infrastructure projects across all three states and all five fuel types in this plan's purview.
The demand for MHD infrastructure is clear, as is the need for increased funding to support infrastructure
development. The AFICC is well positioned to take these findings and champion programs to start the
development of these projects and others that may also need funding and support.
All parties interested in developing alternative fuel infrastructure are encouraged to leverage the
partnership contacts gathered through this effort for purposes of implementing the projects listed
within this plan.
Through the research conducted to develop this strategic plan, CALSTART and other AFICC partners
collected a significant database of stakeholder contact information. From fleets to fuel providers to
government agencies, the contact information of partners interested in carrying forward such
infrastructure development is on hand and ready to be leveraged if and when funding for MHD station
development becomes available. The AFICC aims to accelerate MHD-accessible alternative fuel
infrastructure development for both the projects listed in this document and any other MHD alternative
fuel infrastructure projects on the West Coast that support the WCC's mission to reduce diesel emissions.
As a next step in acting upon the findings of this plan, CALSTART encourages WCC partners and other
interested stakeholders to build capacity for project development through strategic partnerships,
including but not limited to the contacts made through this effort. California, Oregon and Washington
State Transportation Agencies and Regional Metropolitan Planning Organizations are encouraged to use
the Strategic Development Plan to help advance MHD infrastructure development and support
implementation of the projects identified in this document.
Infrastructure development in environmental Justice communities should be prioritized where there is
synergy with alternative fuel demand.
As described in previous sections, promoting environmental justice and community involvement with the
development and expansion of alternative fuel corridors are important to build support and inclusiveness
for project initiatives that can benefit impacted communities. AFICC partners should evaluate
opportunities to engage through tools and resources to build meaningful partnerships with communities
84 I
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to understand needs and collaborate on programs that improve air quality and public health. Raising
awareness on the benefits of alternative fuel technologies is important to help build acceptance, buy-in
and encourage communities to collaborate with industry to advance solutions that are better for business
and the environment. By engaging communities with alternative fuel corridor development where there
is synergy with alternative fuel demand, AFICC partners will be enhancing long-term program
sustainability.
Consider workforce development opportunities which are likely to arise as a result of MHD alternative
fuel infrastructure development on the West Coast.
As highlighted in this plan, an opportunity exists to leverage the trends toward MHD alternative fuel
vehicle adoption and infrastructure deployment for purposes of workforce development. Partners acting
to develop MHD infrastructure should consider the workforce implications of such development and
should highlight it in applications for funding.
The partnerships formed between West Coast Collaborative Alternative Fuel Infrastructure Corridor
Coalition partners should be sustained and leveraged for ongoing coordination on corridor planning,
and other geographic regions are encouraged to replicate the WCC AFICC through similar regional
partnerships across the United States.
To continue the meaningful partnership developed through AFICC, the West Coast Collaborative should:
discuss opportunities to continue coordination, identify funding sources to support proposed project
sites, help encourage projects for further development, leverage partnership opportunities along
corridors exploring similar fuels, and have an entity that is responsible for ongoing follow up and status
review of projects proposed under this plan to ensure long-term implementation success. As an example,
CALSTART has established a Funders Forum, bringing together key funding agencies across California, and
an Infrastructure Working Group, bringing together key infrastructure partners across California, for
ongoing coordination on various topics including alternative fuel infrastructure corridor planning. Similar
working groups may benefit stakeholders in Oregon and Washington and would serve the west coast as a
whole as stakeholders strive to build-out alternative fuel corridors in the region. The information provided
in this strategic plan offers a robust starting point which stakeholders in all three states may use to form
tighter partnerships centered around alternative fuel corridors, and through continued collaborative
efforts partners may build upon the results herein and advance the goals of the West Coast Collaborative.
As stated multiple times in this document, the authors believe that the 147 proposals herein represent a
small fraction of the total need across the West Coast. As such, the WCC intends to create a web-based
submission form on its website (www.westcoastcollaborative.org) to solicit additional MHD alternative
fuel infrastructure proposals from partners seeking incentives and partnerships to support
implementation. Additionally, other regions of the United States are encouraged to visit the link above to
learn more about the WCC AFICC and use it as a model for similar regional partnership formations across
the United States.
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IX. LIST OF PROJECT PROPOSALS AND READINESS FOR FUNDING
CALSTART took the survey results it received from both fleets and fuel providers and evaluated the
projects using the readiness criteria described in Section VI above. In total, survey respondents and other
partners provided 147 project proposals. All 147 projects vary by fuel type, location, capacity, and
maturity. While some projects are already underway and could use additional funding, other projects have
not started and only capture respondents' needs and recommendations for future alternative fuel
infrastructure.500™
The following lists present each project that was provided to CALSTART through its survey efforts, along
with its readiness categories based on the criteria described in Section VI above. To adequately validate
the infrastructure development project proposals received, CALSTART determined it was best to assess
the proposals in two ways. First, all project proposals are listed with no readiness category whatsoever.
The purpose for this is to highlight the large number of alternative fuel infrastructure project proposals
which represent significant demand for investment. Naturally, some project proposals are more mature
than others, but projects which are less mature are still viable for funding to support the WCC AFICC's
objective to build a robust network of MHD alternative fuel infrastructure along the West Coast.
Therefore, to not discount any project proposals, CALSTART first lists all proposals with no evaluation.
Second, to assess project readiness and neat-term viability, CALSTART developed a standard set of
readiness criteria by which it measured each proposal on its readiness to start development if funding
were to become available, as well as its viability in meeting the need for MHD alternative fuel
infrastructure in West Coast states. The proposals are bundled into three categories based on the
evaluation criteria listed in Section VI: Advanced Site, Emerging Site, and Potential Site. For a description
of these three categories, revisit Section VI. For more detail, the proposals are also disaggregated and
listed by fuel type and by state.
Table 22 shows all 147 project proposals by fuel type and state.
Table 22 Project Proposal Numbers by Fuel Type and State
EV
H2
LPG
CNG
LNG
Otherxxxvl
Totals
California
34
6
6
16
0
5
67
Oregon
15
14
5
17
5
1
57
Washington
13
3
2
3
2
0
23
Totals
62
23
13
36
7
6
147
xxxv The West Coast Collaborative believes that the infrastructure development project proposals listed in this
document only cover a small percentage of the demand for MHD alternative fuel infrastructure on the West Coast,
and it welcomes feedback on additional infrastructure needs not reflected in this document.
XXXVI This column includes: 5 catenary electric infrastructure projects proposed in California, and 1 liquid biofuel
station proposed in Redmond, Oregon. These proposals were not evaluated as they are outside the technological
scope of this plan.
86 I F
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Proposal Listings by State
California Only
The following table shows all of the proposed projects within the State of California.
Table 23 California Proposed Alternative Fuel Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed City
or County
Proposed Address
or Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Public,
Private, or
Limited
Access
Reported
CAPEX Estimate
Funding
Needed
(Percentage of
CAPEX)
1
EV
CA
Bakersfield
N/A
70 vehicles
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
0%
2
EV
CA
Bakersfield
Bakersfield, CA
N/A
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
3
EV
CA
Banta
1-5 / 1-205
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
4
EV
CA
Barstow
2825 W. Main St.
Barstow, CA
92311
N/A
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
5
EV
CA
Barstow
1-15 / 1-40
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
6
EV
CA
Between Los
Angeles &
Santa Barbara
US-101
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
7
EV
CA
Between
Sacramento &
San Francisco
1-80
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
8
EV
CA
Blythe
1-10 / CA-78
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
9
EV
CA
Fresno
CA-99 / CA-41
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
87 |
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Number
Fuel
Type
Proposed
State
Proposed City
or County
Proposed Address
or Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Public,
Private, or
Limited
Access
Reported
CAPEX Estimate
Funding
Needed
(Percentage of
CAPEX)
10
EV
CA
Grapevine
1-5 & Edmonston
Pumping Plant
Road
N/A
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
11
EV
CA
Hamburg
Farms
1-5 / CA-165
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
12
EV
CA
Inland Empire
1-15
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
13
EV
CA
Inland Empire
Warehouse
Districts Around
Inland Empire
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
14
EV
CA
Long Beach
Port of Long
Beach
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
15
EV
CA
Long Beach
301
Mediterranean
Way, Long Beach
CA
50 vehicles
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
30%
16
EV
CA
Long Beach
Port of Long
Beach Terminal
N/A
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
17
EV
CA
Long Beach
Port of Long
Beach Terminal
N/A
Limited
Access
$2,250,000
90%
18
EV
CA
Los Angeles
1-10
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
19
EV
CA
Los Angeles
Warehouse
Districts Around
Los Angeles
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
88 |
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Number
Fuel
Type
Proposed
State
Proposed City
or County
Proposed Address
or Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Public,
Private, or
Limited
Access
Reported
CAPEX Estimate
Funding
Needed
(Percentage of
CAPEX)
20
EV
CA
Los Angeles
Port of Los
Angeles
N/A
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
21
EV
CA
Los Angeles /
Hobart
4000 East Sheila St
Los Angeles, CA
90023
10 electric hostlers,
1 electric service
truck
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
50%
22
EV
CA
National City
1-5 & CA-54
200 truck trips a day
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
23
EV
CA
Near Coalinga
1-5 & CA-198
N/A
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
24
EV
CA
Near Los Banos
1-5 & CA-152
N/A
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
25
EV
CA
Red Bluff
1-5 & CA-36
6 vehicles
Public
$100,000
50%
26
EV
CA
Redding
1-5 & CA-44
6 vehicles
Public
$100,000
50%
27
EV
CA
Sacramento
1-80 / US-50
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
89 |
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated
Annual Fuel
Throughput/#
of Vehicles the
Station Would
Serve
Public,
Private,
or
Limited
Access
Reported CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
28
EV
CA
San
Bernardino
1535 West 4th
St San
Bernardino, CA
92411
7 electric
hostlers, 2
electric service
trucks, 1 hybrid
RTG, 1 electric
side loader, 1
electric drayage
truck
Private
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
29
EV
CA
San Diego
1-5 & 1-8
200 truck trips
a day
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
30
EV
CA
Stockton
6450 South
Austin Rd.
Stockton, CA
95215
6 electric
hostlers, 1
hybrid RTG
Private
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
31
EV
CA
Weaverville
CA-299 & CA-
44
6 vehicles
Public
$100,000
50%
32
EV
CA
Williams
1-5 / CA-20
750 kW
minimum (1
MW ideal)
Public
$2,017,499
50%
33
EV
CA
Willow
Creek
CA-299 & CA-
96
6 vehicles
Public
$100,000
50%
34
EV
CA
Willows
1-5 & CA-162
6 vehicles
Public
$100,000
50%
35
H2
CA
Long Beach
1-710 & 1-405
N/A
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
20%
36
H2
CA
Long Beach
1926 East
Pacific Coast
Highway
547,500
kg/year(12
vehicles)
Private
$10,000,000
80-85%
90 |
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Estimated
Public,
Private,
or
Limited
Access
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Annual Fuel
Throughput/#
of Vehicles the
Station Would
Serve
Reported CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
4325 East
Guasti Road
547,500
37
H2
CA
Ontario
kg/year(12
vehicles)
Public
$10,000,000
80-85%
38
H2
CA
Redding
1-5 & CA-44
365,000
kg/year
Public
$4,000,000
30-100%
39
H2
CA
Sacramento
N/A
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
40
H2
CA
Sacramento
N/A
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
41
LPG
CA
Corona
CA-91 & 1-15
200,000 Gallons
(50-60 vehicles)
Public
$110,000
30-40%
42
LPG
CA
Duarte
1-605 & 1-210
200,000 Gallons
(50-60 vehicles)
Public
$110,000
30-40%
43
LPG
CA
Hawthorne
N/A
200,000 Gallons
(50-60 vehicles)
Public
$110,000
30-40%
44
LPG
CA
Norwalk
1-605 & 1-105
200,000 Gallons
(50-60 vehicles)
Public
$110,000
30-40%
45
LPG
CA
Ontario
1-10 & 1-15
200,000 Gallons
(50-60 vehicles)
Public
$110,000
30-40%
46
LPG
CA
Sherman
Oaks
US-101 & 1-405
200,000 Gallons
(50-60 vehicles)
Public
$110,000
30-40%
47
CNG
CA
Bakersfield
Bakersfield, CA
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
48
CNG
CA
Barstow
1-15 & Lenwood
Road
339,000 DGE
(8-10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
91 |
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated
Annual Fuel
Throughput/#
of Vehicles the
Station Would
Serve
Public,
Private,
or
Limited
Access
Reported CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
49
CNG
CA
Bellflower
15330
Woodruff Ave.,
Bellflower, CA
90706
791,000 DGE
Public
and 35
Limited
Access
$2,750,000
20%
50
CNG
CA
Coachella
1-10 & Dillon
Road
339,000 DGE
(8-10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
51
CNG
CA
Gardena
14800 South
Spring St.,
Gardena CA
90248
60 CNG tractors
Public
and
Private
$4,000,000
80%
52
CNG
CA
Lost Hills
1-5 & CA-46
N/A
Public
$1,000,000
N/A
53
CNG
CA
Lost Hills
1-5 & CA-46
339,000 DGE
(8-10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
54
CNG
CA
Near
Bakersfield
1-5 & CA-119
N/A
Public
$1,000,000
N/A
55
CNG
CA
Near
Kettleman
City
1-5 & CA-41
N/A
Public
$1,000,000
N/A
56
CNG
CA
Riverside
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
57
CNG
CA
Riverside
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
58
CNG
CA
San
Bernardino
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
92 |
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated
Annual Fuel
Throughput/#
of Vehicles the
Station Would
Serve
Public,
Private,
or
Limited
Access
Reported CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
59
CNG
CA
San
Bernardino
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
County
60
CNG
CA
San
Bernardino
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
County
61
CNG
CA
San
Bernardino
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
County
62
CNG
CA
Tehachapi
CA-58 & CA-
58B
339,000 DGE
(8-10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
Between
63
Catenary
Electric
CA
East Los
Angeles
and
Riverside
CA-60 (East LA
to Riverside)
6000 trucks per
day per
direction
Public
$5-8.7m /Mile
0%
64
Catenary
Electric
CA
Between
Los Angeles
and Las
Vegas
1-15 Los
Angeles to Las
Vegas
6000 trucks per
day per
direction
Public
$5-8.7m /Mile
0%
65
Catenary
Electric
CA
Between
Mettler and
Sacramento
CA-99 (Mettler
to Sacramento)
6000 trucks per
day per
direction
Public
$5-8.7m /Mile
0%
66
Catenary
Electric
CA
Between
San Diego
and
Redding
1-5 (San Diego
to Redding)
6000 trucks per
day per
direction
Public
$5-8.7m /Mile
0%
93 |
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated
Annual Fuel
Throughput/#
of Vehicles the
Station Would
Serve
Public,
Private,
or
Limited
Access
Reported CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
67
Catenary
Electric
CA
1-710
1-710
14,000 trucks
per day and
direction
Public
$8.7m /mile
0%
94 |
-------�
Oregon Only
The following table shows all of the proposed projects within the State of Oregon.
Table 24 Oregon Proposed Alternative Fuel Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
1
EV
OR
Bend
US-20 / US-
97
750 kW minimum (1 MW
ideal)
Public
$2,017,499
50%
2
EV
OR
Bend
US-97 & US-
20
500 vehicles @ 350kW
Public
$100,000
70%
3
EV
OR
Boardman
1-84 & South
Main Street
500 vehicles @ 350kW
Public
$100,000
70%
4
EV
OR
Eugene
1-5 & OR-126
500 vehicles @ 350kW
Public
$100,000
70%
5
EV
OR
Eugene
3500 E17th
Ave Eugene
OR 97403
N/A
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
6
EV
OR
Hood River
County
N/A
N/A
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
7
EV
OR
Josephine
County
N/A
N/A
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
8
EV
OR
La Grande
1-84 & OR-82
500 vehicles @ 350kW
Public
$100,000
70%
9
EV
OR
Medford
1-5 & OR-62
500 vehicles @ 350kW
Public
$100,000
70%
10
EV
OR
Ontario
1-84 & US-30
500 vehicles @ 350kW
Public
$100,000
70%
11
EV
OR
Pendleton
1-84 & US-
395
500 vehicles @ 350kW
Public
$100,000
70%
12
EV
OR
Portland
1-84 & 1-205
30 vehicles
Public and
Private
$2,000,000
50%
13
EV
OR
Portland
1-5 & 1-405
500 vehicles @ 350kW
Public
$100,000
70%
14
EV
OR
Salem
1-5 & OR-22
500 vehicles @ 350kW
Public
$100,000
70%
95 |
-------�
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
15
EV
OR
The Dalles
1-84 & US-
197
500 vehicles @ 350kW
Public
$100,000
70%
16
H2
OR
Bend
US-97 & US-
20
222,650 kg/year
Public
$4,000,000
80%
17
H2
OR
Boardman
1-84 & South
Main Street
222,650 kg/year
Public
$4,000,000
80%
18
H2
OR
Eugene
1-5 & 1-105
365,000 kg
Public
$4,000,000
30-100%
19
H2
OR
Eugene
1-5 & OR-126
222,650 kg/year
Public
$4,000,000
80%
20
H2
OR
Grants Pass
1-5 & CA-99
365,000 kg
Public
$4,000,000
30-100%
21
H2
OR
La Grande
1-84 & OR-82
222,650 kg/year
Public
$4,000,000
80%
22
H2
OR
Medford
1-5 & OR-62
222,650 kg/year
Public
$4,000,000
80%
23
H2
OR
Ontario
1-84 & US-30
222,650 kg/year
Public
$4,000,000
80%
24
H2
OR
Pendleton
1-84 & US-
395
222,650 kg/year
Public
$4,000,000
80%
25
H2
OR
Portland
1-5 & 1-84
365,000 kg/year
Public
$4,000,000
30-100%
26
H2
OR
Portland
1-5 & 1-405
222,650 kg/year
(assuming 365 days)
Public
$4,000,000
80%
27
H2
OR
Portland
N/A
N/A
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
28
H2
OR
Salem
1-5 & OR-22
222,650 kg/year
Public
$4,000,000
80%
29
H2
OR
The Dalles
1-84 & US-
197
222,650 kg/year
Public
$4,000,000
80%
30
LPG
OR
Boardman
1-84 & South
Main Street
3000 DGE/Hour
Public
$100,000
50-60%
31
LPG
OR
Ontario
1-84 & US-30
3000 DGE/Hour
Public
$100,000
50-60%
32
LPG
OR
Pendleton
1-84 & US-
395
3000 DGE/Hour
Public
$100,000
50-60%
33
LPG
OR
Roseburg
1-5 & SE Oak
Avenue
3000 DGE/Hour
Public
$100,000
50-60%
96 |
-------�
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
34
LPG
OR
The Dalles
1-84 & US-
197
3000 DGE/Hour
Public
$100,000
50-60%
35
CNG
OR
Baker City
N/A
30 vehicles
Public
Not reported by
participant; See
Table 7 for estimated
average CAPEX
70%
36
CNG
OR
Bend
US-97 & US-
20
500 DGE/Hour
Public
$1,500,000
70%
37
CNG
OR
Boardman
1-84 & South
Main Street
500 DGE/Hour
Public
$1,500,000
70%
38
CNG
OR
Eugene
3500 E17th
Ave Eugene
OR 97403
N/A
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
39
CNG
OR
Eugene/Portland
1-5 Corridor
N/A
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
40
CNG
OR
La Grande
1-84 & OR-82
500 DGE/Hour
Public
$1,500,000
70%
41
CNG
OR
Medford
N/A
30 vehicles
Public
Not reported by
participant; See
Table 7 for estimated
average CAPEX
70%
42
CNG
OR
Ontario
1-84 & US-30
500 DGE/Hour
Public
$1,500,000
70%
43
CNG
OR
Pendleton
1-84 & US-
395
500 DGE/Hour
Public
$1,500,000
70%
44
CNG
OR
Portland
1-205 &
Sandy
Boulevard
40 vehicles
Public and
Private
$1,000,000
50-70%
45
CNG
OR
Portland
1-5 & 1-405
500 DGE/Hour
Public
$1,500,000
70%
46
CNG
OR
Portland
N/A
N/A
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
47
CNG
OR
Salem
1-5 & OR-22
500 DGE/Hour
Public
$1,500,000
70%
97 |
-------�
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
48
CNG
OR
SE Portland
1-5 Corridor
33,900 DGE
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
49
CNG
OR
The Dalles
1-84 & US-
197
500 DGE/Hour
Public
$1,500,000
70%
50
CNG
OR
Umatilla
1-82 & US-
730
30 vehicles
Public
Not reported by
participant; See
Table 7 for estimated
average CAPEX
70%
51
CNG
OR
Woodburn
OR-214& 1-5
40 vehicles
Private
$1,000,000
50-70%
52
LNG
OR
Eugene
1-5 & OR-58
5 vehicles
Public and
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
53
LNG
OR
Eugene
3500 E17th
Ave Eugene
OR 97403
N/A
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
54
LNG
OR
Hermiston
1-82 & 1-84
5 vehicles
Public and
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
55
LNG
OR
Portland
N/A
7,352 DGE (5
vehicles/year)
Public and
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
56
LNG
OR
Portland
1-205 & 1-84
5 vehicles
Public and
Private
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
57
Biofuel
OR
Redmond
N/A
3-5 Million Gallons
Not
Reported
Not reported by
participant; See
Table 7 for estimated
average CAPEX
N/A
98 |
-------�
Washington Only
The following table shows all of the proposed projects within the State of Washington.
Table 25 Washington Proposed Alternative Fuel Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
1
EV
WA
Bellevue
1-405 & 1-5
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
2
EV
WA
Ellensburg
Main and
Washington
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
3
EV
WA
Everett
Cedar and
Wentworth
N/A
Public
MHD station not
reported by
participant; See Table
7 for estimated
average CAPEX
0%
4
EV
WA
Everett
Cedar and
Pacific
N/A
Public
MHD station not
reported by
participant; See Table
7 for estimated
average CAPEX
0%
5
EV
WA
Everett
Cedar and
Pacific
10 buses, 5 small
vehicles
Public
$292,000
50%
6
EV
WA
Kennewick
1-82/ US-395
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
7
EV
WA
Olympia
Capital &
Jefferson
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
8
EV
WA
Seattle
Port of Seattle
N/A
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
99 |
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
9
EV
WA
Spokane
Division &
Mission
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
10
EV
WA
Tacoma
Tacoma
15 vehicles
Private
$500,000
100%
11
EV
WA
Tacoma
Market &
Pacific Avenue
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
12
EV
WA
Yakima
Yakima & 4th
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
13
EV
WA
Yakima
Nob Hill & 1st
200 vehicles
Public
Not reported by
participant; See Table
7 for estimated
average CAPEX
60-80%
14
H2
WA
Seattle
1-5 & 1-90
365,000 kg/year
Public
$4,000,000
30-100%
15
H2
WA
Tacoma
Tacoma
10,000 kg/day with
electrolyzer production
Public and
Private
$90,000,000XX)
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX Estimate
Funding
Needed
(Percentage
of CAPEX)
21
CNG
WA
Washington
State
1-5 Corridor
N/A
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
22
LNG
WA
Seattle
N/A
7,352 DGE (5 vehicles)
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
23
LNG
WA
Spokane
N/A
7,352 DGE (5 vehicles)
Public and
Private
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
101 | P a g e
-------�
Proposal Listings by Fuel Type
Electric Vehicle Charging
The following table shows all proposed EV projects.
Table 26 Proposed EV Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
EV-1
EV
CA
Bakersfield
N/A
70 vehicles
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
0%
EV-2
EV
CA
Bakersfield
Bakersfield, CA
N/A
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-3
EV
CA
Banta
1-5 / 1-205
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-4
EV
CA
Barstow
2825 W. Main
St. Barstow, CA
92311
N/A
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-5
EV
CA
Barstow
1-15 / 1-40
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-6
EV
CA
Between Los
Angeles &
Santa
Barbara
US-101
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-7
EV
CA
Between
Sacramento
& San
Francisco
1-80
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-8
EV
CA
Blythe
1-10 / CA-78
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
102 | P a g e
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
EV-9
EV
CA
Fresno
CA-99 / CA-41
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-10
EV
CA
Grapevine
1-5 &
Edmonston
Pumping Plant
Road
N/A
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-11
EV
CA
Hamburg
Farms
1-5 / CA-165
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-12
EV
CA
Inland
Empire
1-15
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-13
EV
CA
Inland
Empire
Warehouse
Districts Around
Inland Empire
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-14
EV
CA
Long Beach
Port of Long
Beach
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-15
EV
CA
Long Beach
301
Mediterranean
Way, Long
Beach CA
50 vehicles
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
30%
EV-16
EV
CA
Long Beach
Port of Long
Beach Terminal
N/A
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-17
EV
CA
Long Beach
Port of Long
Beach Terminal
N/A
Limited
Access
$2,250,000
90%
EV-18
EV
CA
Los Angeles
1-10
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
103 | P a g e
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
EV-19
EV
CA
Los Angeles
Warehouse
Districts Around
Los Angeles
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-20
EV
CA
Los Angeles
Port of Los
Angeles
N/A
Public and
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-21
EV
CA
Los Angeles
/ Hobart
4000 East Sheila
St Los Angeles,
CA 90023
10 electric hostlers, 1
electric service truck
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-22
EV
CA
National City
1-5 & CA-54
200 truck trips a day
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-23
EV
CA
Near
Coalinga
1-5 & CA-198
N/A
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-24
EV
CA
Near Los
Banos
1-5 & CA-152
N/A
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-25
EV
CA
Red Bluff
1-5 & CA-36
6 vehicles
Public
$100,000
50%
EV-26
EV
CA
Redding
1-5 & CA-44
6 vehicles
Public
$100,000
50%
EV-27
EV
CA
Sacramento
1-80 / US-50
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-28
EV
CA
San
Bernardino
1535 West 4th
St San
Bernardino, CA
92411
7 electric hostlers, 2
electric service trucks, 1
hybrid RTG, 1 electric
side loader, 1 electric
drayage truck
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
104 | P a g e
-------�
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
EV-29
EV
CA
San Diego
1-5 & 1-8
200 truck trips a day
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-30
EV
CA
Stockton
6450 South
Austin Rd.
Stockton, CA
95215
6 electric hostlers, 1
hybrid RTG
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
50%
EV-31
EV
CA
Weaverville
CA-299 & CA-44
6 vehicles
Public
$100,000
50%
EV-32
EV
CA
Williams
1-5 / CA-20
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-33
EV
CA
Willow
Creek
CA-299 & CA-96
6 vehicles
Public
$100,000
50%
EV-34
EV
CA
Willows
1-5 & CA-162
6 vehicles
Public
$100,000
50%
EV-35
EV
OR
Bend
US-20 / US-97
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-36
EV
OR
Bend
US-97 & US-20
500 vehicles @ 350kW
Public
$100,000
70%
EV-37
EV
OR
Boardman
1-84 & South
Main Street
500 vehicles @ 350kW
Public
$100,000
70%
EV-38
EV
OR
Eugene
1-5 &OR-126
500 vehicles @ 350kW
Public
$100,000
70%
EV-39
EV
OR
Eugene
3500 E 17th Ave
Eugene OR
97403
N/A
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-40
EV
OR
Hood River
County
N/A
N/A
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-41
EV
OR
Josephine
County
N/A
N/A
Private
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
EV-42
EV
OR
La Grande
1-84 & OR-82
500 vehicles @ 350kW
Public
$100,000
70%
105 | P a g e
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
EV-43
EV
OR
Medford
1-5 & OR-62
500 vehicles @ 350kW
Public
$100,000
70%
EV-44
EV
OR
Ontario
1-84 & US-30
500 vehicles @ 350kW
Public
$100,000
70%
EV-45
EV
OR
Pendleton
1-84 & US-395
500 vehicles @ 350kW
Public
$100,000
70%
EV-46
EV
OR
Portland
1-84 & 1-205
30 vehicles
Public and
Private
$2,000,000
50%
EV-47
EV
OR
Portland
1-5 & 1-405
500 vehicles @ 350kW
Public
$100,000
70%
EV-48
EV
OR
Salem
1-5 & OR-22
500 vehicles @ 350kW
Public
$100,000
70%
EV-49
EV
OR
The Dalles
1-84 & US-197
500 vehicles @ 350kW
Public
$100,000
70%
EV-50
EV
WA
Bellevue
1-405 & 1-5
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-51
EV
WA
Ellensburg
Main and
Washington
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-52
EV
WA
Everett
Cedar and
Wentworth
N/A
Public
MHD station not
reported by participant-
See Table 7 for estimated
average CAPEX
0%
EV-53
EV
WA
Everett
Cedar and
Pacific
N/A
Public
MHD station not
reported by participant-
See Table 7 for estimated
average CAPEX
0%
EV-54
EV
WA
Everett
Cedar and
Pacific
10 buses, 5 small
vehicles
Public
$292,000
50%
EV-55
EV
WA
Kennewick
1-82 / US-395
750 kW minimum (1
MW ideal)
Public
$2,017,499
50%
EV-56
EV
WA
Olympia
Capital &
Jefferson
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-57
EV
WA
Seattle
Port of Seattle
N/A
N/A
Not reported by
participant; See Table 7
for estimated average
CAPEX
N/A
106 | P a g e
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage
of CAPEX)
EV-58
EV
WA
Spokane
Division &
Mission
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-59
EV
WA
Tacoma
Tacoma
15 vehicles
Private
$500,000
100%
EV-60
EV
WA
Tacoma
Market &
Pacific Avenue
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-61
EV
WA
Yakima
Yakima & 4th
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
EV-62
EV
WA
Yakima
Nob Hill & 1st
200 vehicles
Public
Not reported by
participant; See Table 7
for estimated average
CAPEX
60-80%
107 | P a g e
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Hydrogen
The following table shows all proposed H2 projects.
Table 27 Proposed Hi Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage of
CAPEX)
H2-1
H2
CA
Long Beach
1-710 & 1-405
N/A
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
20%
H2-2
H2
CA
Long Beach
1926 East
Pacific Coast
Highway
547,500 kg/year (12
vehicles)
Private
$10,000,000
80-85%
H2-3
H2
CA
Ontario
4325 East
Guasti Road
547,500 kg/year (12
vehicles)
Public
$10,000,000
80-85%
H2-4
H2
CA
Redding
1-5 & CA-44
365,000 kg/year
Public
$4,000,000
30-100%
H2-5
H2
CA
Sacramento
N/A
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
H2-6
H2
CA
Sacramento
N/A
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
H2-7
H2
OR
Bend
US-97 & US-20
222,650 kg/year
Public
$4,000,000
80%
H2-8
H2
OR
Boardman
1-84 & South
Main Street
222,650 kg/year
Public
$4,000,000
80%
H2-9
H2
OR
Eugene
1-5 & 1-105
365,000 kg/year
Public
$4,000,000
30-100%
H2-10
H2
OR
Eugene
1-5 & OR-126
222,650 kg/year
Public
$4,000,000
80%
H2-11
H2
OR
Grants Pass
1-5 & CA-99
365,000 kg/year
Public
$4,000,000
30-100%
H2-12
H2
OR
La Grande
1-84 & OR-82
222,650 kg/year
Public
$4,000,000
80%
H2-13
H2
OR
Medford
1-5 & OR-62
222,650 kg/year
Public
$4,000,000
80%
H2-14
H2
OR
Ontario
1-84 & US-30
222,650 kg/year
Public
$4,000,000
80%
H2-15
H2
OR
Pendleton
1-84 & US-395
222,650 kg/year
Public
$4,000,000
80%
H2-16
H2
OR
Portland
1-5 & 1-84
365,000 kg/year
Public
$4,000,000
30-100%
H2-17
H2
OR
Portland
1-5 & 1-405
222,650 kg/year
Public
$4,000,000
80%
108 | P a g e
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Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual
Fuel Throughput / #
of Vehicles the
Station Would
Serve
Public,
Private, or
Limited
Access
Reported CAPEX
Estimate
Funding
Needed
(Percentage of
CAPEX)
H2-18
H2
OR
Portland
N/A
N/A
Not
Reported
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
H2-19
H2
OR
Salem
1-5 & OR-22
222,650 kg/year
Public
$4,000,000
80%
H2-20
H2
OR
The Dalles
1-84 & US-197
222,650 kg/year
Public
$4,000,000
80%
H2-21
H2
WA
Seattle
1-5 & 1-90
365,000 kg
Public
$4,000,000
30-100%
H2-22
H2
WA
Tacoma
Tacoma
10,000 kg/day with
electrolyzer
production
Public and
Private
$90,000,000XX)
-------�
Liquefied Petroleum Gas (Propane)
The following table shows all proposed LPG projects.
Table 28 Proposed LPG Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
LPG-1
LPG
CA
Corona
CA-91 & 1-15
200,000 Gallons (50-60
vehicles)
Public
$110,000
30-40%
LPG-2
LPG
CA
Duarte
1-605 & 1-210
200,000 Gallons (50-60
vehicles)
Public
$110,000
30-40%
LPG-3
LPG
CA
Hawthorne
N/A
200,000 Gallons (50-60
vehicles)
Public
$110,000
30-40%
LPG-4
LPG
CA
Norwalk
1-605 & 1-105
200,000 Gallons (50-60
vehicles)
Public
$110,000
30-40%
LPG-5
LPG
CA
Ontario
1-10 & 1-15
200,000 Gallons (50-60
vehicles)
Public
$110,000
30-40%
LPG-6
LPG
CA
Sherman
Oaks
US-101 & 1-405
200,000 Gallons (50-60
vehicles)
Public
$110,000
30-40%
LPG-7
LPG
OR
Boardman
1-84 & South
Main Street
3000 DGE/Hour
Public
$100,000
50-60%
LPG-8
LPG
OR
Ontario
1-84 & US-30
3000 DGE/Hour
Public
$100,000
50-60%
LPG-9
LPG
OR
Pendleton
1-84 & US-395
3000 DGE/Hour
Public
$100,000
50-60%
LPG-10
LPG
OR
Roseburg
1-5 & SE Oak
Avenue
3000 DGE/Hour
Public
$100,000
50-60%
LPG-11
LPG
OR
The Dalles
1-84 & US-197
3000 DGE/Hour
Public
$100,000
50-60%
LPG-12
LPG
WA
Ellensburg
1-90 & 1-82
360,000 Gallons
Public
$1,700,000
25-50%
LPG-13
LPG
WA
Ritzvil le
1-90 & WA-261
360,000 Gallons
Public
$1,700,000
25-50%
110 | P a g e
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Compressed Natural Gas
The following table shows all proposed CNG projects.
Table 29 Proposed CNG Infrastructure Projects (Readiness Categories not Shown)
Estimated Annual
Public,
Funding
Needed
(Percentage of
CAPEX)
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Fuel Throughput
/ # of Vehicles
the Station
Would Serve
Private,
or
Limited
Access
Reported CAPEX
Estimate
CNG-1
CNG
CA
Bakersfield
Bakersfield, CA
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
CNG-2
CNG
CA
Barstow
1-15 & Lenwood
Road
339,000 DGE (8-
10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
15330
Public
CNG-3
CNG
CA
Bellflower
Woodruff Ave.,
Bellflower, CA
90706
791,000 DGE
and 35
Limited
Access
$2,750,000
20%
CNG-4
CNG
CA
Coachella
1-10 & Dillon
Road
339,000 DGE (8-
10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
CNG-5
CNG
CA
Gardena
14800 South
Spring St.,
Gardena CA
90248
60 CNG tractors
Public
and
Private
$4,000,000
80%
CNG-6
CNG
CA
Lost Hills
1-5 & CA-46
N/A
Public
$1,000,000
N/A
CNG-7
CNG
CA
Lost Hills
1-5 & CA-46
339,000 DGE (8-
10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
CNG-8
CNG
CA
Near Bakersfield
1-5 & CA-119
N/A
Public
$1,000,000
N/A
CNG-9
CNG
CA
Near Kettleman
City
1-5 & CA-41
N/A
Public
$1,000,000
N/A
CNG-10
CNG
CA
Riverside County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
111 | P a g e
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Estimated Annual
Public,
Funding
Needed
(Percentage of
CAPEX)
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Fuel Throughput
/ # of Vehicles
the Station
Private,
or
Limited
Reported CAPEX
Estimate
Would Serve
Access
CNG-11
CNG
CA
Riverside County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
CNG-12
CNG
CA
San Bernardino
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
CNG-13
CNG
CA
San Bernardino
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
CNG-14
CNG
CA
San Bernardino
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
CNG-15
CNG
CA
San Bernardino
County
N/A
225 vehicles
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
50%
CNG-16
CNG
CA
Tehachapi
CA-58 & CA-58B
339,000 DGE (8-
10 vehicles)
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
40-60%
CNG-17
CNG
OR
Baker City
N/A
30 vehicles
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
70%
CNG-18
CNG
OR
Bend
97 & 20
500 DGE/Hour
Public
$1,500,000
70%
CNG-19
CNG
OR
Boardman
1-84 & South
Main Street
500 DGE/Hour
Public
$1,500,000
70%
CNG-20
CNG
OR
Eugene
3500 E 17th Ave
Eugene OR
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
97403
CNG-21
CNG
OR
Eugene/Portland
1-5 Corridor
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
CNG-22
CNG
OR
La Grande
1-84 & 82
500 DGE/Hour
Public
$1,500,000
70%
CNG-23
CNG
OR
Medford
N/A
30 vehicles
Public
N/A
70%
CNG-24
CNG
OR
Ontario
1-84 & US-30
500 DGE/Hour
Public
$1,500,000
70%
CNG-25
CNG
OR
Pendleton
1-84 & US-395
500 DGE/Hour
Public
$1,500,000
70%
112 | P a g e
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Estimated Annual
Public,
Funding
Needed
(Percentage of
CAPEX)
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed
Address or
Interchange
Fuel Throughput
/ # of Vehicles
the Station
Private,
or
Limited
Reported CAPEX
Estimate
Would Serve
Access
CNG-26
CNG
OR
Portland
1-205 & Sandy
Boulevard
40 vehicles
Public
and
Private
$1,000,000
50-70%
CNG-27
CNG
OR
Portland
1-5 & 1-405
500 DGE/Hour
Public
$1,500,000
70%
CNG-28
CNG
OR
Portland
N/A
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
CNG-29
CNG
OR
Salem
1-5 & OR-22
500 DGE/Hour
Public
$1,500,000
70%
CNG-30
CNG
OR
SE Portland
1-5 Corridor
33,900 DGE
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
CNG-31
CNG
OR
The Dalles
1-84 & US-197
500 DGE/Hour
Public
$1,500,000
70%
CNG-32
CNG
OR
Umatilla
1-82 & US-730
30 vehicles
Public
Not reported by participant-
See Table 7 for estimated
average CAPEX
70%
CNG-33
CNG
OR
Woodburn
OR-214& 1-5
40 vehicles
Private
$1,000,000
50-70%
CNG-34
CNG
WA
Clark County
1-5 Corridor
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
CNG-35
CNG
WA
Vancouver
1-5 Corridor
113,000 DGE
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
CNG-36
CNG
WA
Washington State
1-5 Corridor
N/A
N/A
Not reported by participant-
See Table 7 for estimated
average CAPEX
N/A
113 | P a g e
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Liquefied Natural Gas
The following table shows all proposed LNG projects.
Table 30 Proposed LNG Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX Estimate
Funding Needed
(Percentage of
CAPEX)
LNG-1
LNG
OR
Eugene
1-5 & OR-58
5 vehicles
Public and
Private
Not reported by
participant; See Table
7 for estimated
N/A
average CAPEX
LNG-2
LNG
OR
Eugene
3500 E17th
Ave Eugene OR
97403
N/A
N/A
Not reported by
participant; See Table
7 for estimated
average CAPEX
N/A
LNG-3
LNG
OR
Hermiston
1-82 & 1-84
5 vehicles
Public and
Private
Not reported by
participant; See Table
7 for estimated
N/A
average CAPEX
LNG-4
LNG
OR
Portland
N/A
7,352 DGE (5 vehicles)
Public and
Private
Not reported by
participant; See Table
7 for estimated
N/A
average CAPEX
LNG-5
LNG
OR
Portland
1-205 & 1-84
5 vehicles
Public and
Private
Not reported by
participant; See Table
7 for estimated
N/A
average CAPEX
LNG-6
LNG
WA
Seattle
N/A
7,352 DGE (5 vehicles)
Public and
Private
Not reported by
participant; See Table
7 for estimated
N/A
average CAPEX
LNG-7
LNG
WA
Spokane
N/A
7,352 DGE (5 vehicles)
Public and
Private
Not reported by
participant; See Table
7 for estimated
N/A
average CAPEX
114 | P a g e
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Other Fuel Types
The following table shows all proposed infrastructure projects for other fuel types.
Table 31 Other Proposed Infrastructure Projects (Readiness Categories not Shown)
Number
Fuel
Type
Proposed
State
Proposed
City or
County
Proposed
Address or
Interchange
Estimated Annual Fuel
Throughput/# of
Vehicles the Station
Would Serve
Public,
Private, or
Limited
Access
Reported
CAPEX
Estimate
Funding Needed
(Percentage of
CAPEX)
Biofuel-1
Biofuel
OR
Redmond
N/A
3-5 Million Gallons
Not
Reported
N/A
N/A
Catenary
Electric-1
Catenary
Electric
CA
Between
East Los
Angeles and
Riverside
CA-60 (East LA
to Riverside)
6000 trucks per day
per direction
Public
$5-8.7m
/Mile
0%
Catenary
Electric-2
Catenary
Electric
CA
Between
Los Angeles
and Las
Vegas
1-15 Los
Angeles to Las
Vegas
6000 trucks per day
per direction
Public
$5-8.7m
/Mile
0%
Catenary
Electric-3
Catenary
Electric
CA
Between
Mettler and
Sacramento
CA-99 (Mettler
to Sacramento)
6000 trucks per day
per direction
Public
$5-8.7m
/Mile
0%
Catenary
Electric-4
Catenary
Electric
CA
Between
San Diego
and
Redding
1-5 (San Diego
to Redding)
6000 trucks per day
per direction
Public
$5-8.7m
/Mile
0%
Catenary
Electric-5
Catenary
Electric
CA
1-710
1-710
14,000 trucks per day
and direction
Public
$8.7m/mile
0%
115 | P a g e
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Proposal Readiness Listing by State
All project proposals were evaluated by a common set of criteria (see Section VI). These projects were
then bundled into one of three categories based on their level of readiness for funding, of which the cut-
offs between them were qualitatively assessed. Table 32 and Table 33 show summaries of readiness
evaluation results by state and by fuel type, respectively. Table 34 through Table 36 show all readiness
listings by state, and Table 37 through Table 43 show all readiness listings by fuel type. Please note that
twenty (20) proposals were unevaluated; five (5) catenary electric infrastructure proposals that was out
of scope for this report, one (1) liquid biofuel station proposal which was out of scope, and the remaining
14 did not contain enough information to properly evaluate them.
Table 32 Proposal Readiness by State
California
Oregon
Washington
Totals
Advanced
32
32
13
77
Emerging
13
14
3
30
Potential
15
1
4
20
Unevaluated
7
10
3
20
Totals
67
57
23
147
Table 33 Proposal Readiness by Fuel Type
EV
H2
LPG
CNG
LNG
Catenary Electric
Otherxxxlx
Totals
Advanced
37
9
13
15
3
0
0
77
Emerging
7
10
0
12
1
0
0
30
Potential
15
1
0
2
2
0
0
20
Unevaluated
3
3
0
7
1
5
1
20
Totals
62
23
13
36
7
5
1
147
xxxix Qne stuc|y participant proposed a biofuel station.
116 I F
-------�
California
The following table shows all project proposals in California.
Table 34 California Proposed Infrastructure Project Readiness Listing -
Number
Fuel Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
CA-1
EV
CA
Banta
1-5 & 1-205
Advanced
CA-2
EV
CA
Barstow
1-15 & 1-40
Advanced
CA-3
EV
CA
Blythe
1-10 & CA-78
Advanced
CA-4
EV
CA
Fresno
CA-99 & CA-41
Advanced
CA-5
EV
CA
Hamburg Farms
1-5 & CA-165
Advanced
CA-6
EV
CA
Long Beach
301 Mediterranean
Way, Long Beach CA
Advanced
CA-7
EV
CA
Long Beach
Port of Long Beach
Terminal
Advanced
CA-8
EV
CA
National City
1-5 & CA-54
Advanced
CA-9
EV
CA
Red Bluff
1-5 & CA-3 6
Advanced
CA-10
EV
CA
Redding
1-5 & CA-44
Advanced
CA-11
EV
CA
Sacramento
1-80 & US-50
Advanced
CA-12
EV
CA
San Bernardino
1535 West 4th St San
Bernardino, CA 92411
Advanced
CA-13
EV
CA
San Diego
1-5 & 1-8
Advanced
CA-14
EV
CA
Weaverville
CA-299 & CA-44
Advanced
CA-15
EV
CA
Williams
1-5 & CA-20
Advanced
CA-16
EV
CA
Willow Creek
CA-299 & CA-96
Advanced
CA-17
EV
CA
Willows
1-5 & CA-162
Advanced
CA-18
H2
CA
Long Beach
1926 East Pacific Coast
Highway
Advanced
CA-19
H2
CA
Ontario
4325 East Guasti Road
Advanced
CA-20
H2
CA
Redding
1-5 & CA-44
Advanced
CA-21
LPG
CA
Corona
CA-91 & 1-15
Advanced
CA-22
LPG
CA
Duarte
1-605 & 1-210
Advanced
CA-23
LPG
CA
Hawthorne
N/A
Advanced
CA-24
LPG
CA
Norwalk
1-605 & 1-105
Advanced
CA-25
LPG
CA
Ontario
1-10 & 1-15
Advanced
CA-26
LPG
CA
Sherman Oaks
US-101 & 1-405
Advanced
CA-27
CNG
CA
Bellflower
15330 Woodruff Ave.,
Bellflower, CA 90706
Advanced
CA-28
CNG
CA
Gardena
14800 South Spring St.,
Gardena CA 90248
Advanced
CA-29
CNG
CA
Lost Hills
1-5 & CA-46
Advanced
CA-30
CNG
CA
Lost Hills
1-5 & CA-46
Advanced
XL This listing includes seven proposals which were unevaluated, five catenary electric proposals and two hydrogen
proposals. The catenary electric proposals were unevaluated as they were outside of the technological scope of this
plan. The hydrogen proposals were unevaluated due to a lack of information necessary to evaluate them.
117 I
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Number
Fuel Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
CA-31
CNG
CA
Near Kettleman City
1-5 & CA-41
Advanced
CA-32
CNG
CA
Tehachapi
CA-58 & CA-58B
Advanced
CA-33
EV
CA
Bakersfield
N/A
Emerging
CA-34
EV
CA
Barstow
2825 W. Main St.
Barstow, CA 92311
Emerging
CA-35
EV
CA
Los Angeles /
Hobart
4000 East Sheila St Los
Angeles, CA 90023
Emerging
CA-36
EV
CA
Stockton
6450 South Austin Rd.
Stockton, CA 95215
Emerging
CA-37
CNG
CA
Barstow
1-15 & Lenwood Road
Emerging
CA-38
CNG
CA
Coachella
1-10 & Dillon Road
Emerging
CA-39
CNG
CA
Near Bakersfield
1-5 & CA-119
Emerging
CA-40
CNG
CA
Riverside County
N/A
Emerging
CA-41
CNG
CA
Riverside County
N/A
Emerging
CA-42
CNG
CA
San Bernardino
County
N/A
Emerging
CA-43
CNG
CA
San Bernardino
County
N/A
Emerging
CA-44
CNG
CA
San Bernardino
County
N/A
Emerging
CA-45
CNG
CA
San Bernardino
County
N/A
Emerging
CA-46
EV
CA
Bakersfield
Bakersfield, CA
Potential
CA-47
EV
CA
Between Los
Angeles & Santa
Barbara
US-101
Potential
CA-48
EV
CA
Between
Sacramento & San
Francisco
1-80
Potential
CA-49
EV
CA
Grapevine
1-5 & Edmonston
Pumping Plant Road
Potential
CA-50
EV
CA
Inland Empire
1-15
Potential
CA-51
EV
CA
Inland Empire
Warehouse Districts
Around Inland Empire
Potential
CA-52
EV
CA
Long Beach
Port of Long Beach
Potential
CA-53
EV
CA
Long Beach
Port of Long Beach
Terminal
Potential
CA-54
EV
CA
Los Angeles
1-10
Potential
CA-55
EV
CA
Los Angeles
Warehouse Districts
Around Los Angeles
Potential
CA-56
EV
CA
Los Angeles
Port of Los Angeles
Potential
CA-57
EV
CA
Near Coalinga
1-5 & CA-198
Potential
CA-58
EV
CA
Near Los Banos
1-5 & CA-152
Potential
CA-59
H2
CA
Long Beach
1-710 & 1-405
Potential
118 I F
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Number
Fuel Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
CA-60
CNG
CA
Bakersfield
Bakersfield, CA
Potential
CA-61
H2
CA
Sacramento
N/A
Unevaluated
CA-62
H2
CA
Sacramento
N/A
Unevaluated
CA-63
Catenary
Electric
CA
Between East Los
Angeles and
Riverside
CA-60 (East LA to
Riverside)
Unevaluated
CA-64
Catenary
Electric
CA
Between Los
Angeles and Las
Vegas
1-15 Los Angeles to Las
Vegas
Unevaluated
CA-65
Catenary
Electric
CA
Between Mettler
and Sacramento
CA-99 (Mettler to
Sacramento)
Unevaluated
CA-66
Catenary
Electric
CA
Between San Diego
and Redding
1-5 (San Diego to
Redding)
Unevaluated
CA-67
Catenary
Electric
CA
Los Angeles County
1-710
Unevaluated
Oregon
The following table shows all project proposals in Oregon.
Table 35 Oregon Proposed Infrastructure Project Readiness Listing*11
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
OR-1
EV
OR
Bend
US-20 & US-97
Advanced
OR-2
EV
OR
Bend
US-97 & US-20
Advanced
OR-3
EV
OR
Boardman
1-84 & South Main Street
Advanced
OR-4
EV
OR
Eugene
1-5 &OR-126
Advanced
OR-5
EV
OR
La Grande
1-84 & OR-82
Advanced
OR-6
EV
OR
Medford
1-5 & OR-62
Advanced
OR-7
EV
OR
Ontario
1-84 & US-30
Advanced
OR-8
EV
OR
Pendleton
1-84 & US-395
Advanced
OR-9
EV
OR
Portland
1-84 & 1-205
Advanced
OR-10
EV
OR
Portland
1-5 & 1-405
Advanced
OR-11
EV
OR
Salem
1-5 & OR-22
Advanced
OR-12
EV
OR
The Dalles
1-84 & US-197
Advanced
OR-13
H2
OR
Eugene
1-5 & 1-105
Advanced
OR-14
H2
OR
Grants Pass
1-5 & CA-99
Advanced
OR-15
H2
OR
Portland
1-5 & 1-84
Advanced
OR-16
LPG
OR
Boardman
1-84 & South Main Street
Advanced
OR-17
LPG
OR
Ontario
1-84 & US-30
Advanced
OR-18
LPG
OR
Pendleton
1-84 & US-395
Advanced
OR-19
LPG
OR
Roseburg
1-5 & SE Oak Avenue
Advanced
XLI The proposals marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
119 I F
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Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
OR-20
LPG
OR
The Dalles
1-84 & US-197
Advanced
OR-21
CNG
OR
Bend
US-97 & US-20
Advanced
OR-22
CNG
OR
Boardman
1-84 & South Main Street
Advanced
OR-23
CNG
OR
La Grande
1-84 & OR-82
Advanced
OR-24
CNG
OR
Ontario
1-84 & US-30
Advanced
OR-25
CNG
OR
Pendleton
1-84 & US-395
Advanced
OR-26
CNG
OR
Portland
1-205 & Sandy Boulevard
Advanced
OR-27
CNG
OR
The Dalles
1-84 & US-197
Advanced
OR-28
CNG
OR
Umatilla
1-82 & US-730
Advanced
OR-29
CNG
OR
Woodburn
OR-214 & 1-5
Advanced
OR-30
LNG
OR
Eugene
1-5 & OR-58
Advanced
OR-31
LNG
OR
Portland
N/A
Advanced
OR-32
LNG
OR
Portland
1-205 & 1-84
Advanced
OR-33
H2
OR
Bend
US-97 & US-20
Emerging
OR-34
H2
OR
Boardman
1-84 & South Main Street
Emerging
OR-35
H2
OR
Eugene
1-5 &OR-126
Emerging
OR-36
H2
OR
La Grande
1-84 & OR-82
Emerging
OR-37
H2
OR
Medford
1-5 & OR-62
Emerging
OR-38
H2
OR
Ontario
1-84 & US-30
Emerging
OR-39
H2
OR
Pendleton
1-84 & US-395
Emerging
OR-40
H2
OR
Portland
1-5 & 1-405
Emerging
OR-41
H2
OR
Salem
1-5 & OR-22
Emerging
OR-42
H2
OR
The Dalles
1-84 & US-197
Emerging
OR-43
CNG
OR
Baker City
N/A
Emerging
OR-44
CNG
OR
Portland
1-5 & 1-405
Emerging
OR-45
CNG
OR
Salem
1-5 & OR-22
Emerging
OR-46
LNG
OR
Hermiston
1-82 & 1-84
Emerging
OR-47
CNG
OR
Medford
N/A
Potential
OR-48
EV
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
Unevaluated
OR-49
EV
OR
Hood River County
N/A
Unevaluated
OR-50
EV
OR
Josephine County
N/A
Unevaluated
OR-51
H2
OR
Portland
N/A
Unevaluated
OR-52
CNG
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
Unevaluated
OR-53
CNG
OR
Eugene/Portland
1-5 Corridor
Unevaluated
OR-54
CNG
OR
Portland
N/A
Unevaluated
OR-55
CNG
OR
SE Portland
1-5 Corridor
Unevaluated
OR-56
LNG
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
Unevaluated
OR-57
Biofuel
OR
Redmond
N/A
Unevaluated
120 I F
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Washington
The following table shows all project proposals in Washington.
Table 36 Washington Proposed Infrastructure Project Readiness Listing*1"
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
WA-1
EV
WA
Bellevue
1-405 & 1-5
Advanced
WA-2
EV
WA
Ellensburg
Main and Washington
Advanced
WA-3
EV
WA
Kennewick
1-82 & US-395
Advanced
WA-4
EV
WA
Olympia
Capital & Jefferson
Advanced
WA-5
EV
WA
Spokane
Division & Mission
Advanced
WA-6
EV
WA
Tacoma
Market & Pacific Avenue
Advanced
WA-7
EV
WA
Yakima
Yakima & 4th
Advanced
WA-8
EV
WA
Yakima
Nob Hill & 1st
Advanced
WA-9
H2
WA
Seattle
1-5 & 1-90
Advanced
WA-10XLI"
H2
WA
Tacoma
Tacoma
Advanced
WA-11
H2
WA
Tacoma
1-5 & WA-7
Advanced
WA-12
LPG
WA
Ellensburg
1-90 & 1-82
Advanced
WA-13
LPG
WA
Ritzvil le
1-90 & WA-261
Advanced
WA-14
EV
WA
Everett
Cedar and Wentworth
Emerging
WA-15
EV
WA
Everett
Cedar and Pacific
Emerging
WA-16
EV
WA
Everett
Cedar and Pacific
Emerging
WA-17
EV
WA
Seattle
Port of Seattle
Potential
WA-18
EV
WA
Tacoma
Tacoma
Potential
WA-19
LNG
WA
Seattle
N/A
Potential
WA-20
LNG
WA
Spokane
N/A
Potential
WA-21
CNG
WA
Clark County
1-5 Corridor
Unevaluated
WA-2 2
CNG
WA
Vancouver
1-5 Corridor
Unevaluated
WA-23
CNG
WA
Washington State
1-5 Corridor
Unevaluated
XL" The proposals marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
XLI" This proposal is for a 35 MW electrolysis station with an expected capacity of 10,000 kg/day. A hydrogen fueling
station may or may not be included in the project.
121 I F
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Proposal Readiness Listing by Fuel Type
Electric Vehicle Charging
The following table shows all EV project proposals.
Table 37 Proposed EV Infrastructure Project Readiness ListingXLIV
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
EV-1
EV
CA
Banta
1-5 & 1-205
Advanced
EV-2
EV
CA
Barstow
1-15 & 1-40
Advanced
EV-3
EV
CA
Blythe
1-10 & CA-78
Advanced
EV-4
EV
CA
Fresno
CA-99 & CA-41
Advanced
EV-5
EV
CA
Hamburg Farms
1-5 & CA-165
Advanced
EV-6
EV
CA
Long Beach
301 Mediterranean Way,
Long Beach CA
Advanced
EV-7
EV
CA
Long Beach
Port of Long Beach
Terminal
Advanced
EV-8
EV
CA
National City
1-5 & CA-54
Advanced
EV-9
EV
CA
Red Bluff
1-5 & CA-36
Advanced
EV-10
EV
CA
Redding
1-5 & CA-44
Advanced
EV-11
EV
CA
Sacramento
1-80 & US-50
Advanced
EV-12
EV
CA
San Bernardino
1535 West 4th St San
Bernardino, CA 92411
Advanced
EV-13
EV
CA
San Diego
1-5 & 1-8
Advanced
EV-14
EV
CA
Weaverville
CA-299 & CA-44
Advanced
EV-15
EV
CA
Williams
1-5 & CA-20
Advanced
EV-16
EV
CA
Willow Creek
CA-299 & CA-96
Advanced
EV-17
EV
CA
Willows
1-5 & CA-162
Advanced
EV-18
EV
OR
Bend
US-20 & US-97
Advanced
EV-19
EV
OR
Bend
US-97 & US-20
Advanced
EV-20
EV
OR
Boardman
1-84 & South Main Street
Advanced
EV-21
EV
OR
Eugene
1-5 &OR-126
Advanced
EV-22
EV
OR
La Grande
1-84 & OR-82
Advanced
EV-23
EV
OR
Medford
1-5 & OR-62
Advanced
EV-24
EV
OR
Ontario
1-84 & US-30
Advanced
EV-25
EV
OR
Pendleton
1-84 & US-395
Advanced
EV-26
EV
OR
Portland
1-84 & 1-205
Advanced
EV-27
EV
OR
Portland
1-5 & 1-405
Advanced
EV-28
EV
OR
Salem
1-5 & OR-22
Advanced
EV-29
EV
OR
The Dalles
1-84 & US-197
Advanced
EV-30
EV
WA
Bellevue
1-405 & 1-5
Advanced
EV-31
EV
WA
Ellensburg
Main and Washington
Advanced
XLIV The proposals marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
122 I F
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Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
EV-32
EV
WA
Kennewick
1-82 & US-395
Advanced
EV-33
EV
WA
Olympia
Capital & Jefferson
Advanced
EV-34
EV
WA
Spokane
Division & Mission
Advanced
EV-35
EV
WA
Tacoma
Market & Pacific Avenue
Advanced
EV-36
EV
WA
Yakima
Yakima & 4th
Advanced
EV-37
EV
WA
Yakima
Nob Hill & 1st
Advanced
EV-38
EV
CA
Bakersfield
N/A
Emerging
EV-39
EV
CA
Barstow
2825 W. Main St.
Barstow, CA 92311
Emerging
EV-40
EV
CA
Los Angeles / Hobart
4000 East Sheila St Los
Angeles, CA 90023
Emerging
EV-41
EV
CA
Stockton
6450 South Austin Rd.
Stockton, CA 95215
Emerging
EV-42
EV
WA
Everett
Cedar and Wentworth
Emerging
EV-43
EV
WA
Everett
Cedar and Pacific
Emerging
EV-44
EV
WA
Everett
Cedar and Pacific
Emerging
EV-45
EV
CA
Bakersfield
Bakersfield, CA
Potential
EV-46
EV
CA
Between Los Angeles
& Santa Barbara
US-101
Potential
EV-47
EV
CA
Between Sacramento
& San Francisco
1-80
Potential
EV-48
EV
CA
Grapevine
1-5 & Edmonston
Pumping Plant Road
Potential
EV-49
EV
CA
Inland Empire
1-15
Potential
EV-50
EV
CA
Inland Empire
Warehouse Districts
Around Inland Empire
Potential
EV-51
EV
CA
Long Beach
Port of Long Beach
Potential
EV-52
EV
CA
Long Beach
Port of Long Beach
Terminal
Potential
EV-53
EV
CA
Los Angeles
1-10
Potential
EV-54
EV
CA
Los Angeles
Warehouse Districts
Around Los Angeles
Potential
EV-55
EV
CA
Los Angeles
Port of Los Angeles
Potential
EV-56
EV
CA
Near Coalinga
1-5 & CA-198
Potential
EV-57
EV
CA
Near Los Banos
1-5 & CA-152
Potential
EV-58
EV
WA
Seattle
Port of Seattle
Potential
EV-59
EV
WA
Tacoma
Tacoma
Potential
EV-60
EV
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
Unevaluated
EV-61
EV
OR
Hood River County
N/A
Unevaluated
EV-62
EV
OR
Josephine County
N/A
Unevaluated
123 I F
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Hydrogen
The following table shows all H2 project proposals.
Table 38 Proposed H2 Infrastructure Project Readiness ListingXLV
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
H2-1
H2
CA
Long Beach
1926 East Pacific Coast
Highway
Advanced
H2-2
H2
CA
Ontario
4325 East Guasti Road
Advanced
H2-3
H2
CA
Redding
1-5 & CA-44
Advanced
H2-4
H2
OR
Eugene
1-5 & 1-105
Advanced
H2-5
H2
OR
Grants Pass
1-5 & CA-99
Advanced
H2-6
H2
OR
Portland
1-5 & 1-84
Advanced
H2-7
H2
WA
Seattle
1-5 & 1-90
Advanced
H2-8xlvi
H2
WA
Tacoma
Tacoma
Advanced
H2-9
H2
WA
Tacoma
1-5 & WA-7
Advanced
H2-10
H2
OR
Bend
US-97 & US-20
Emerging
H2-11
H2
OR
Boardman
1-84 & South Main Street
Emerging
H2-12
H2
OR
Eugene
1-5 & OR-126
Emerging
H2-13
H2
OR
La Grande
1-84 & OR-82
Emerging
H2-14
H2
OR
Medford
1-5 & OR-62
Emerging
H2-15
H2
OR
Ontario
1-84 & US-30
Emerging
H2-16
H2
OR
Pendleton
1-84 & US-395
Emerging
H2-17
H2
OR
Portland
1-5 & 1-405
Emerging
H2-18
H2
OR
Salem
1-5 & OR-22
Emerging
H2-19
H2
OR
The Dalles
1-84 & US-197
Emerging
H2-20
H2
CA
Long Beach
1-710 & 1-405
Potential
H2-21
H2
CA
Sacramento
N/A
Unevaluated
H2-22
H2
CA
Sacramento
N/A
Unevaluated
H2-23
H2
OR
Portland
N/A
Unevaluated
XLVThe proposals marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
XLVI This proposal is for a 35 MW electrolysis station with an expected capacity of 10,000 kg/day. A hydrogen fueling
station may or may not be included in the project.
124 I F
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Liquefied Petroleum Gas (Propane)
The following table shows all LPG project proposals.
Table 39 Proposed LPG Infrastructure Project Readiness Listing
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
LPG-1
LPG
CA
Corona
CA-91 & 1-15
Advanced
LPG-2
LPG
CA
Duarte
1-605 & 1-210
Advanced
LPG-3
LPG
CA
Hawthorne
N/A
Advanced
LPG-4
LPG
CA
Norwalk
1-605 & 1-105
Advanced
LPG-5
LPG
CA
Ontario
1-10 & 1-15
Advanced
LPG-6
LPG
CA
Sherman Oaks
US-101 & 1-405
Advanced
LPG-7
LPG
OR
Boardman
1-84 & South Main Street
Advanced
LPG-8
LPG
OR
Ontario
1-84 & US-30
Advanced
LPG-9
LPG
OR
Pendleton
1-84 & US-395
Advanced
LPG-10
LPG
OR
Roseburg
1-5 & SE Oak Avenue
Advanced
LPG-11
LPG
OR
The Dalles
1-84 & US-197
Advanced
LPG-12
LPG
WA
Ellensburg
1-90 & 1-82
Advanced
LPG-13
LPG
WA
Ritzvil le
1-90 & WA-261
Advanced
125 I F
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Compressed Natural Gas
The following table shows all CNG project proposals.
Table 40 Proposed CNG Infrastructure Project Readiness ListingXLV"
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
CNG-1
CNG
CA
Bellflower
15330 Woodruff Ave.,
Bellflower, CA 90706
Advanced
CNG-2
CNG
CA
Gardena
14800 South Spring St.,
Gardena CA 90248
Advanced
CNG-3
CNG
CA
Lost Hills
1-5 & CA-46
Advanced
CNG-4
CNG
CA
Lost Hills
1-5 & CA-46
Advanced
CNG-5
CNG
CA
Near Kettleman City
1-5 & CA-41
Advanced
CNG-6
CNG
CA
Tehachapi
CA-58 & CA-58B
Advanced
CNG-7
CNG
OR
Bend
US-97 & US-20
Advanced
CNG-8
CNG
OR
Boardman
1-84 & South Main Street
Advanced
CNG-9
CNG
OR
La Grande
1-84 & OR-82
Advanced
CNG-10
CNG
OR
Ontario
1-84 & US-30
Advanced
CNG-11
CNG
OR
Pendleton
1-84 & US-395
Advanced
CNG-12
CNG
OR
Portland
1-205 & Sandy Boulevard
Advanced
CNG-13
CNG
OR
The Dalles
1-84 & US-197
Advanced
CNG-14
CNG
OR
Umatilla
1-82 & US-730
Advanced
CNG-15
CNG
OR
Woodburn
OR-214 & 1-5
Advanced
CNG-16
CNG
CA
Barstow
1-15 & Lenwood Road
Emerging
CNG-17
CNG
CA
Coachella
1-10 & Dillon Road
Emerging
CNG-18
CNG
CA
Near Bakersfield
1-5 & CA-119
Emerging
CNG-19
CNG
CA
Riverside County
N/A
Emerging
CNG-20
CNG
CA
Riverside County
N/A
Emerging
CNG-21
CNG
CA
San Bernardino
County
N/A
Emerging
CNG-22
CNG
CA
San Bernardino
County
N/A
Emerging
CNG-23
CNG
CA
San Bernardino
County
N/A
Emerging
CNG-24
CNG
CA
San Bernardino
County
N/A
Emerging
CNG-25
CNG
OR
Baker City
N/A
Emerging
CNG-26
CNG
OR
Portland
1-5 & 1-405
Emerging
CNG-27
CNG
OR
Salem
1-5 & OR-22
Emerging
CNG-28
CNG
CA
Bakersfield
Bakersfield, CA
Potential
CNG-29
CNG
OR
Medford
N/A
Potential
CNG-30
CNG
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
Unevaluated
XLV" The proposals marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
126 I F
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Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
CNG-31
CNG
OR
Eugene/Portland
1-5 Corridor
Unevaluated
CNG-32
CNG
OR
Portland
N/A
Unevaluated
CNG-33
CNG
OR
SE Portland
1-5 Corridor
Unevaluated
CNG-34
CNG
WA
Clark County
1-5 Corridor
Unevaluated
CNG-35
CNG
WA
Vancouver
1-5 Corridor
Unevaluated
CNG-36
CNG
WA
Washington State
1-5 Corridor
Unevaluated
Liquefied Natural Gas
The following table shows all LNG project proposals.
Table 41 Proposed LNG Infrastructure Project Readiness Listing*"""
Number
Fuel
Type
Proposed
State
Proposed City or
County
Proposed Address or
Interchange
Readiness
Category
LNG-1
LNG
OR
Eugene
1-5 & OR-58
Advanced
LNG-2
LNG
OR
Portland
N/A
Advanced
LNG-3
LNG
OR
Portland
1-205 & 1-84
Advanced
LNG-4
LNG
OR
Hermiston
1-82 & 1-84
Emerging
LNG-5
LNG
WA
Seattle
N/A
Potential
LNG-6
LNG
WA
Spokane
N/A
Potential
LNG-7
LNG
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
Unevaluated
xlviii yhe pr0p0sa|s marked "Unevaluated" did not contain enough data to properly evaluate those proposals.
127 I F
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Other Fuel Types
Catenary Electric
The following table shows all Catenary Electric project proposals. As catenary electric projects are not
within the technological scope of this project, they were not included in the readiness evaluations.
Table 42 Proposed Catenary EV Infrastructure Project Readiness Listing
Number
Fuel Type
Proposed
State
Proposed City or
County
Proposed Address
or Interchange
Readiness
Category
Catenary Electric-1
Catenary
Electric
CA
Between East Los
Angeles and
Riverside
CA-60 (East LA to
Riverside)
Unevaluated
Catenary Electric-2
Catenary
Electric
CA
Between Los
Angeles and Las
Vegas
1-15 Los Angeles
to Las Vegas
Unevaluated
Catenary Electric-3
Catenary
Electric
CA
Between Mettler
and Sacramento
CA-99 (Mettler to
Sacramento)
Unevaluated
Catenary Electric-4
Catenary
Electric
CA
Between San
Diego and
Redding
1-5 (San Diego to
Redding)
Unevaluated
Catenary Electric-5
Catenary
Electric
CA
Los Angeles
County
1-710
Unevaluated
Liquid Biofuel
The following table shows one other project proposal received for a biofuel station. As biofuel projects
are not within the technological scope of this project, this one was not included in the readiness
evaluations.
Table 43 Proposed Liquid Biofuel Infrastructure Project Readiness Listing
Number
Fuel Type
Proposed
State
Proposed City or
County
Proposed Address
or Interchange
Readiness
Category
Biofuel-1
Biofuel
OR
Redmond
N/A
Unevaluated
128 I F
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Existing and Proposed Infrastructure Maps
Figure 9 shows all existing EV, H2, LPG, CNG, and LNG sites in California, Oregon, and Washington. It is
important to note that this map includes light-duty as well as MHD fueling stations. The FHWA Alternative
Fuel Corridor designation program served as the data source for existing alternative fuel station locations.
FHWA counts all existing stations regardless of its ability to service light-duty, medium-duty, or heavy-
duty vehicles. Further, at the time of writing this strategic development plan, the FHWA's corridor maps
do not offer an apparent method for disaggregating light-duty only stations from MHD-accessible stations.
Therefore, it could not be determined from these maps alone whether each given existing station services
light-duty, medium-duty, and/or heavy-duty vehicles. Given the current state of MHD alternative fuel
vehicle technology, however, it is likely that many EV and H2 stations shown are only accessible by light-
duty vehicles. Despite this, the FHWA's Alternative Fuel Corridor designation program and its associated
data on existing alternative fuel station locations provide a valuable starting point in assessing the gaps in
alternative fuel vehicle infrastructure on the West Coast. Further refining of these maps to show existing
stations which service only MHDVs is a needed next step to accurately assess these gaps, and to identify
how the infrastructure projects proposed in this strategic plan might fill-in those gaps.
129 I F
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Figure 9: Existing Alternative Fuel Stations in California, Oregon, and Washington*11*
Existing Sites
• Electric
• Hydrogen
• CNG
LPG
• LPG
Basemap
— Major US Highways
I I States Boundaries of the United States
Portland
San Francisco
Seattle
XLIX Readers should assume that this map shows light-duty only stations along with MHD-accessible stations. The
source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did not offer a method to
disaggregate light-duty only stations from MHD-accessible stations.
130 | P a g e
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The next map (Figure 10) shows the location of all the proposed alternative fuel stations.
Figure 10: Proposed MHD Alternative Fuel Stations in California, Oregon, and Washington
San Francisco
Sites
* Proposed Sites, Electric
a Proposed Sites, Hydrogen
* Proposed Sites, CNG
Proposed Sites, LNG
* Proposed Sites, LPG
„ ' -Ci
Portland
Ba semap
Major US Highways
I I States Boundaries of the United States
250
500 km
131 | P a g e
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The following map (Figure 11) shows existing and proposed electric charging stations. While many
proposed stations are in Seattle, San Francisco, and Los Angeles, several are located in northern California
along the 1-5 and away from major metro areas. Likewise, a couple stations are suggested in Washington
away from Seattle.
Figure 11: Existing arid Proposed Electric Charging Stations in California, Oregon, and Washington1
0 250 500 km
^¦ I
L Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
132 | P a g e
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Figure 12 shows existing and proposed Hydrogen stations.
Figure 12: Existing and Proposed H2 Fueling Stations in California, Oregon, and WashingtonLI
0 250 500 km
u Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
133 | P a g e
-------�
Figure 13 shows existing and proposed LPG stations. Most proposed stations are in the Los Angeles area
with one on 1-90 in Washington State.
Figure 13: Existing and Proposed LPG Fueling Stations in California, Oregon, and Washington1"
Sites
~ Existing Sites, LPG
a Proposed Sites, LPG
Ba semap
Major US Highways
I I States Boundaries of the United States
. ' ^
V
San Francisco
Seattle
Portland
250
BOO km
Ul Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
134 | P a g e
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Figure 14 shows existing and proposed CNG fueling stations in California, Oregon, and Washington.
Proposed sites are distributed throughout all three West Coast states, mostly near major cities.
Figure 14: Existing and Proposed CNG Fueling Stations in California, Oregon, and Washington1111
Sites
• Existing Sites, CNG
a Proposed Sites, CNG
Basemap
Major US Highways
[ I States Boundaries of the United States
San Francisco
»*»•-
„ ' "Q
Seattle
250
500 km
u" Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
135 | P a g e
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The following map (Figure 15) shows existing LNG sites along with LNG sites proposed by survey
respondents. Like CNG, most proposed sites are near major cities like Los Angeles and Portland, while a
few others are suggested to be located on corridors away from those hubs.
Figure 15: Existing and Proposed LNG Fueling Stations in California, Oregon, and WashingtonLIV
San Francisco
O.T3*-
Sites
Existing Sites, LNG
a Proposed Sites, LNG
Basemap
Major US Highways
I I States Boundaries of the United States
Portland
250
500 km
LIV Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
136 | P a g e
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Finally, the following figure shows two maps that demonstrate the overlap of proposed sites and areas
that disproportionately suffer from diesel emissions exposure (according to EPA's EJSCREEN tool). The
map on the left shows the proposed sites for this report and the map on the right shows a screenshot of
the EJSCREEN tool for National Air Toxics Assessment (NATA) Diesel PM (>5 ng/m3).
Figure 16: NATA Diesel PM Map for California, Oregon, and Washington
Los Angeles
Metro Area:
29 sites
Diego
[san Francisco
Sites
a Proposed Sites, Electric
* Proposed Sites, Hydrogen
a Proposed Sites, CNG
Proposed Sites, LNG
* Proposed Sites, LPG
„ ' ¦**
Ba semap
Major US Highways
~~ States Boundaries of the United States
500 km
137 | P a g e
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X. APPENDIX A: ADDITIONAL INFRASTRUCTURE SITE MAPS
Figure 17 California Existing Alternative Fuel Infrastructure Sites (All Fuels)LV
Existing Sites
> Electric
¦ Hydrogen
• CNG
LNG
¦ LPG
Basemap
Major US Highways
I I States Boundaries of the United States
250
500 km
~
LV Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
138 | P a g e
-------�
Figure 18 California Proposed
Alternative
Fuel
Infrastructure Sites (All Fuels, 147 Sites)
Sites
* Proposed Sites, Electric
* Proposed Sites, Hydrogen
* Proposed Sites, CNG
Proposed Sites, LNG
* Proposed Sites, LPG
Basemap
— Major US Highways
I I States Boundaries of the United States
San Francisco
0 250 500 km
^ 1
139 | P a g e
-------�
Figure 19 Oregon Existing Alternative Fuel Infrastructure Sites (All Fuels)LVI
Existing Sites
• Existing Sites, Electric
• Existing Sites, Hydrogen (N/A for OR)
• Existing Sites, CNG
Existing Sites, LNG
• Existing Sites, LPG
Basemap
Major US Highways
I I States Boundaries of the United States
c
LVI Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations..
140 | P a g e
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Sites
Proposed Sites, LNG
* Proposed Sites, Electric
a Proposed Sites, Hydrogen
a Proposed Sites, CNG
* Proposed Sites, LPG
Basemap
— Major US Highways
I I States Boundaries of the United States
Figure 20 Oregon Proposed Alternative Fuel Infrastructure Sites (All Fuels, 57 Sites)
141 | P a g e
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Figure 21 Washington Existing Alternative Fuel Infrastructure Sites (All Fuels)LVM
Existing Sites
• Electric
• Hydrogen
• CNG
LNG
• IPG
Basemap
Major US Highways
States Boundaries of the United States
LV" Readers should assume that the existing stations on this map include light-duty only stations along with MHD-
accessible stations. The source of the existing fueling station data (FHWA Alternative Fuel Corridor Designation) did
not offer a method to disaggregate light-duty only stations from MHD-accessible stations.
142 | P a g e
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Figure 22 Washington Proposed Alternative Fuel infrastructure Sites (All Fuels, 23 Sites)
Sites
a Proposed Sites, Electric
a Proposed Sites, Hydrogen
a Proposed Sites, CNG
Proposed Sites, LNG
* Proposed Sites, LPG
Basemap
Major US Highways
I I States Boundaries of the United States
~i ^ r
143
Page
-------�
XI.
APPENDIX B: ENVIRONMENTAL JUSTICE CONSIDERATION TABLES
CALSTART evaluated projects proposed in this strategic plan to identify if they may be located within
environmental justice (EJ) or disadvantaged communities. The aim of this is to help AFICC partners
understand how the proposed projects may serve as important emission reduction solutions for NAAQS
non-attainment areas, air quality improvement and public health benefits. For proposed California sites,
CALSTART used CalEnviroScreen 3.0 and its combined score on 19 total indicators. For Oregon and
Washington, the EPA's EJ mapping and screening tool called EJSCREEN was used. Specifically, CALSTART
considered NATA Diesel PM, Ozone, and PM 2.5. 80th percentile and above on these measures was the
threshold for a "Yes" designation in the table below. While the definitions of an EJ community vary from
state to state, CALSTART sought to approximate the potential EJ community status of each infrastructure
site proposed in this plan. Therefore, a "Yes" designation in the table below indicates high likelihood of
being located in an EJ community. Please note that due to the state-level differences in defining EJ
communities, CALSTART cannot guarantee that each site with a "Yes" designation is, in fact, located within
an EJ community, but this represents CALSTART's best judgement on the topic.
Table 44: Environmental Justice Zones for California (Listed Alphabetically by Location)
Fuel
Type
State
Location-City
Location-Address (or intersection)
80th Percentile
or Above in
CalEnviroScreen
3.0
EV
CA
Banta
1-5 / 1-205
Yes
EV
CA
Barstow
2825 W. Main St. Barstow, CA 92311
Yes
EV
CA
Barstow
1-15 / 1-40
Yes
EV
CA
Blythe
1-10 / HWY-78
No
EV
CA
Coalinga
1-5 & 198
Yes
EV
CA
Fresno
HWY-99 / HWY-41
Yes
EV
CA
Grapevine
1-5 & Edmonston Pumping Plant Road
No
EV
CA
Gustine
1-5 &152
Yes
EV
CA
Hamburg Farms
1-5 / HWY-165
Yes
EV
CA
Inland Empire
1-15
Yes
EV
CA
LA /Hobart
4000 East Sheila St Los Angeles, CA
90023
Yes
EV
CA
Long Beach
Port of LB
Yes
EV
CA
Long Beach
301 Mediterranean Way, Long Beach
CA
Yes
EV
CA
Long Beach
Port of Long Beach Terminal
Yes
EV
CA
Long Beach
Port of Long Beach Terminal
Yes
EV
CA
Los Angeles
1-10
Yes
EV
CA
Los Angeles
Port of LA
Yes
EV
CA
National City
15 & 54
Yes
EV
CA
Red Bluff
15 & 36
No
EV
CA
Redding
15 &44
No
144 I F
-------�
Fuel
Type
State
Location-City
Location-Address (or intersection)
80th Percentile
or Above in
CalEnviroScreen
3.0
EV
CA
Sacramento
1-80/1-50
Yes
EV
CA
San Bernardino
(demonstrating BYD)
1535 West 4th St San Bernardino, CA
92411
Yes
EV
CA
San Diego
I5& 18
No
EV
CA
Stockton
6450 South Austin Rd. Stockton, CA
95215
Yes
EV
CA
Weaverville
299 & 3
No
EV
CA
Williams
1-5 / HWY-20
No
EV
CA
Willow Creek
299 & 96
No
EV
CA
Willows
15 & 162
No
H2
CA
Long Beach
710 & 405
Yes
H2
CA
Long Beach
1926 east pacific coast highway
Yes
H2
CA
Ontario
4325 East Guasti Road
No
H2
CA
Redding
I5&44
No
LPG
CA
Corona
91/15
Yes
LPG
CA
Duarte
605/210
No
LPG
CA
Hawthorne
105/405
Yes
LPG
CA
Norwalk
605/105
Yes
LPG
CA
Ontario
10/15
Yes
LPG
CA
Sherman Oaks
101/405
No
CNG
CA
Bakersfield
1-5 & 119
No
CNG
CA
Barstow
1-15 & Lenwood Road
No
CNG
CA
Bellflower
15330 Woodruff Ave, Bellflower, CA
90706
Yes
CNG
CA
Coachella
1-10 and Dillon Road
No
CNG
CA
Gardena
14800 South Spring St Gardena CA
90248
Yes
CNG
CA
Kettleman City
1-5 &41
No
CNG
CA
Lost Hills
1-5 & 46
Yes
CNG
CA
Lost Hills
1-5 & 46
Yes
CNG
CA
Tehachapi
58&58B
No
145 I F
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Table 45: Environmental Justice Zones for Oregon
Fuel
Type
State
Location-
City
Location-Address (or
intersection)
80th
Percentile
or above in
NATA
Diesel PM
80th
Percentile
or above in
Ozone
80th
Percentile
or above
in 2.5PM
CNG
OR
Bend
97 & 20
No
Yes
No
EV
OR
Bend
97 & 20
No
Yes
No
EV
OR
Bend
HWY-20 / HWY-97
No
Yes
No
H2
OR
Bend
97 & 20
No
Yes
No
CNG
OR
Boardman
1-84 & South Main Street
No
Yes
Yes
H2
OR
Boardman
1-84 & South Main Street
No
Yes
Yes
LPG
OR
Boardman
1-84 & South Main Street
No
Yes
Yes
EV
OR
Boardman
1-84 & South Main Street
No
Yes
Yes
CNG
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
No
No
No
LNG
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
No
No
No
EV
OR
Eugene
3500 E 17th Ave Eugene
OR 97403
No
No
No
H2
OR
Eugene
1-5 & 126
No
No
No
EV
OR
Eugene
1-5 & 126
No
No
No
H2
OR
Eugene
15 &105
No
No
No
LNG
OR
Eugene
1-5 &H58
No
No
No
H2
OR
Grants
Pass
I5&99
No
No
No
LNG
OR
Hermiston
182 & 184
No
Yes
No
CNG
OR
La Grande
1-84 & 82
No
Yes
No
H2
OR
La Grande
1-84 & 82
No
Yes
No
EV
OR
La Grande
1-84 & 82
No
Yes
No
EV
OR
Medford
1-5 & 62
No
No
No
H2
OR
Medford
1-5 & 62
No
No
No
CNG
OR
Ontario
1-84 & 30
No
Yes
Yes
H2
OR
Ontario
1-84 & 30
No
Yes
Yes
LPG
OR
Ontario
1-84 & 30
No
Yes
Yes
EV
OR
Ontario
1-84 & 30
No
Yes
Yes
CNG
OR
Pendleton
1-84 & 395
No
Yes
No
H2
OR
Pendleton
1-84 & 395
No
Yes
No
LPG
OR
Pendleton
1-84 & 395
No
Yes
No
EV
OR
Pendleton
1-84 & 395
No
No
No
146 I F
-------�
Fuel Type
State
Location-
City
Location-Address (or
intersection)
80th
Percentile
or above in
NATA Diesel
PM
80th
Percentile
or above
in Ozone
80th
Percentile
or above
in 2.5PM
CNG
OR
Portland
205 and Sandy Boulevard
No
No
No
CNG
OR
Portland
1-5 & 405
No
No
No
H2
OR
Portland
1-5 & 405
Yes
No
Yes
EV
OR
Portland
1-5 & 405
Yes
No
Yes
H2
OR
Portland
15 &84
Yes
No
No
EV
OR
Portland
1-84 & 205
Yes
No
No
LNG
OR
Portland
1205 & 184
Yes
No
No
LPG
OR
Roseburg
1-5 & SE Oak Avenue
No
No
No
CNG
OR
Salem
1-5 & 22
No
Yes
No
H2
OR
Salem
1-5 & 22
No
No
No
EV
OR
Salem
1-5 & 22
No
No
No
CNG
OR
The Dalles
1-84 & 197
No
Yes
No
H2
OR
The Dalles
1-84 & 197
No
Yes
No
LPG
OR
The Dalles
1-84 & 197
No
Yes
No
EV
OR
The Dalles
1-84 & 197
No
Yes
No
CNG
OR
Umatilla
182 & 730
No
Yes
Yes
CNG
OR
Woodburn
214 and 1-5
No
Yes
Yes
147 I F
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Table 46 Environmental Justice Zones for Washington
Fuel
Type
Stat
e
Location-
City
Location-Address (or
intersection)
80th
Percentile
or above
in NATA
Diesel PM
80th
Percentile
or above in
Ozone
80th
Percentile
or above
in 2.5PM
EV
WA
Bellevue
405 & 15
Yes
No
No
LPG
WA
Ellensburg
1-90 & 82
No
Yes
No
EV
WA
Ellensburg
Main and Washington
No
Yes
No
EV
WA
Kennewic
k
1-82 / HWY-395
No
Yes
Yes
EV
WA
Olympia
Capital & Jefferson
No
No
No
EV
WA
Port of
Seattle
Port of Seattle
Yes
No
No
LPG
WA
Ritzville
1-90 &261
No
Yes
Yes
H2
WA
Seattle
15 & 90
Yes
No
No
EV
WA
Spokane
Division & Mission
No
Yes
Yes
H2
WA
Tacoma
15 &7
Yes
No
No
EV
WA
Tacoma
Market & Pacific Avenue
Yes
No
No
H2
WA
Tacoma
Tacoma
Yes
No
No
EV
WA
Tacoma
Tacoma
Yes
No
No
EV
WA
Yakima
Nob Hill & 1st
No
Yes
No
EV
WA
Yakima
Yakima & 4th
No
Yes
No
148 I F
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XII. APPENDIX C: FLEET AND FUEL PROVIDER SURVEY RESULTS
This section includes detailed fleet and fuel provider survey results. These surveys represent only one
form of soliciting project proposals and information for this strategic plan. In addition to these two
surveys, CALSTART yielded information through additional outreach via email and phone calls. As this
section does not include information from organizations that submitted project proposals through
outreach conducted outside of the surveys, it does not convey the full and final results or key findings for
this effort. For complete results, refer to the project listings in Section IX as well as the Conclusions and
Recommendations listed in Section VIII, both of which included key findings from the surveys and other
forms outreach combined.
Fleet Survey ResultsLVIM
In total, 26 organizations responded to the fleet survey, representing respondents from all three states
within the plan's purview. While respondents operated in all three states, California had the highest share
of respondents which operated within it.
Figure 23: States of Fleet Operation
States of Fleet Operation
52%
50%
£ 48%
£
CD
T3
o 46%
Q.
i/i
a>
en
*5 44%
a>
im.
(B
« 42%
40%
38%
50%
46%
42%
California
Oregon
State
Washington
Fleet Vocation: Respondents also operated within a wide range of MHD vocations, including drayage
trucking, transit buses, refuse haulers, school buses, food and beverage distribution, locomotive services,
cargo handling, construction, regional government, air quality inspection and monitoring, road
LVI" As stated above, this survey was administered before additional outreach was conducted which yielded
additional information, and therefore the survey results in and of themselves are not a complete representation of
the full results of this effort. Please refer to Sections VIII and IX for full and final results.
149 | P a g e
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maintenance, airport shuttle services, marine cargo handling, utility service fleets, and municipal street
sweeping.
Figure 24: Fleet Vocation
Fleet Vocation
Other (please specify)
Agriculture
Construction
Cargo Handling
Locomotive
Marine
c Shuttle Service
¦£ Towing
(0 ....
g Food or Beverage Distribution
> School Bus
Refuse
Transit
Parcel Delivery
Long-Haul Trucking
Drayage
Regional Shipping
0% 5% 10% 15% 20% 25% 30% 35% 40% 45%
Share of Respondents
0%
0%
0%
0%
0%
0%
0%
4%
4%
4%
4%
12%
12'
15%
38%
Vehicles/Equipment Currently Operating and Planning to Procure: Fleets were asked to describe how
many vehicles or off-road equipment that currently operate for each of the following fuel types: gasoline,
diesel, compressed natural gas (CNG), liquefied natural gas (LNG), liquefied petroleum gas (LPG),
hydrogen (H2), and electric vehicle charging (EV). Table 47 shows summary statistics for the aggregate
number of vehicles operated by all fleets per fuel type.
Table 47: Summary Statistics - Number of Vehicles Operated by Fleet per Fuel Type
Gasoline
Diesel
CNG
LNG
LPG
H2
EV
Average
608
541
38
9
4
0.27
20
Maximum
5000
8000
225
230
35
7
195
Minimum
0
0
0
0
0
0
0
Sum Across All
15,816
14,055
988
239
111
7
532
26 Respondents
for This Question
Some fleets included vehicles and off-road equipment that did not fit into any of the fuel types listed
above. For instance, one survey respondent had 312 E85 vehicles, and one more had 315 Flex Fuel E85
vehicles.
150 | P a g e
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When asked what alternative fuel vehicles and off-road equipment the respondents were interested in
adding to their fleets within the next three to five years, the most popular fuel type was EV, followed by
CNG, H2, LNG, and LPG. There were no fleets that stated that they were not interested in adding
alternative fuel vehicles to their fleet.
Figure 25: Alternative Fuel Procurement Interests
Alternative Fuel Vehicles and Equipment
Fleets are Interested in Procuring Within 5
Years
90%
80%
« 70%
c
-S 60%
C
I 50%
o
£ 30%
(0
" 20%
10%
0%
81%
38%
19%
12%
8%
1
1
1
0%
CNG
LNG LPG H2
Fuel Type
EV
i
No Interest
Funding Needs for Vehicles: When asked if they will need funding support to purchase alternative fuel
vehicles and off-road equipment, 69.2% respondents said "Yes", while 15.4% of respondents said "No"
and 15.4% of respondents said, "I don't know".
151 | P a g e
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Figure 26: Fleet Funding Needs for Alternative Fuel Vehicles
Will you need funding support to purchase
alternative fuel vehicles or equipment?
80%
70%
69%
60%
Q)
"D
O
CL
50%
a>
DC
«4—
o
0)
(TJ
-C
on
40%
30%
20%
10%
0%
-15%-
-15%-
Yes
No
Response
I do not know
152 | P a g e
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Anticipated Funding Needs for Infrastructure: In the same vein, when asked if they will need funding
support to purchase and install alternative fuel infrastructure, 73% of respondents said "Yes" while 8% of
respondents said "No" and 19% of respondents said, "I don't know".
Figure 27: Fleet Funding Needs for Alternative Fuel Infrastructure
Will you need funding support to purchase
and install alternative fuel infrastructure?
80%
70%
« 60%
4-1
| 50%
o
Q-
S 40%
cc
o
0) 30%
i—
(0
^ 20%
10%
0%
73%
19%
8%
Yes
No
Response
I don't know
153 | P a g e
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Cost Share Potential: CALSTART was interested to know what sort of cost share requirement would be
best suited for an alternative fuel infrastructure funding program. As such, CALSTART asked respondents
if funding were available to help them purchase an alternative fuel vehicle or off-road equipment unit,
what would be the minimum percentage of the total vehicle purchase price which funding must cover to
justify purchase of that vehicle. The answer with the most responses was 50%, while a sizeable number
of respondents also said 0%, 30%, 70%, 80%, and 100%.
Figure 28: Minimum Fleet Funding Needed for Alternative Fuel Vehicles
Minimum Percentage of Alternative Fuel
Vehicle Purchase Price Required to be
Covered by Funding
25%
20%
(A
c
0)
T3
§ 15%
Q.
10
-------�
Additionally, CALSTART asked respondents if funding were available to help them cover the capital
expenses for installing alternative fuel infrastructure, what would be the minimum percentage of the total
CAPEX which funding must cover to justify development. The two answer choices with the most responses
were 50% and 100%, with 27% and 23% of respondents, respectively.
Figure 29: Minimum Fleet Funding Needed for Alternative Fuel Infrastructure CAPEX
Minimum Percentage of Alternative Fuel
Vehicle Infrastructure CAPEX Cost
Required to be Covered by Funding
30%
25%
I 20%
C
O
® 15%
cc
«+-
o
£ 10%
fD
-C
to
5%
0%
27%
~8% S%~
I i - I
0%
-i— —i 1— —i 1— —r
-29%-
0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100%
Percent of CAPEX
155 | P a g e
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Proposed Infrastructure Locations & Privacy Preferences: In addition to funding needs, CALSTART was
interested in knowing where fleets think the best locations would be for alternative fuel infrastructure.
As such, CALSTART asked fleets where in California they will require fueling or charging stations within the
next three to five years, for each fuel type. Responses varied in how precise they were. While some
respondents went so far as to give latitude and longitude coordinates, many others simply named cities
or highways where they believe stations should be located. The following list describes the fleets' answers.
Table 48: Fleet Proposed Alternative Fuel Infrastructure Locations - California
CNG
LNG
LPG
H2
EV
Bakersfield
Gardena
1-5 Sacramento to
Mt. Shasta
Los Angeles County
Disadvantaged
Communities
Barstow
Gardena
HWY 299 Eureka
to Susanville
60 FWY in Riverside
County
San Bernardino
105 FWY
HWY 44 Eureka to
Susanville
15 FWY in Riverside
County
Commerce
605 FWY
10 FWY in San Bernardino
County
Stockton
91 FWY
210 FWY in San
Bernardino County
Cottonwood
Bellflower
215 FWY in San
Bernardino County
HWY 44 Eureka to
Susanville
15 FWY in San Bernardino
County
HWY 299 Eureka
Susanville
Long Beach
1-5 Sacramento to Mt.
Shasta
Long Beach
215 FWY in San
Bernardino County
210 FWY in San
Bernardino County
10 FWY in San Bernardino
County
15 FWY in Riverside
County
60 FWY in Riverside
County
Los Angeles County
Disadvantaged
Communities
Bakersfield
156 I F
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Respondents also suggested numerous station locations in Oregon. The following list shows their
responses.
Table 49: Fleet Proposed Alternative Fuel Infrastructure Locations - Oregon
CNG
LNG
LPG
H2
EV
1-205/ NE Sandy
Boulevard
1-5 North
Portland
1-5 / Roseburg
5 FWY
5 FWY
1-5 / Woodburn Exit
1-205 / 1-84 East
Portland
1-84/The Dalles
1-5 / Medford
Long
Beach
1-5 North Portland
1-82 / 1-84
Hermiston
1-84 / Boardman or
Port of Morrow
1-5 / Eugene
Airports
1-205 / 1-84 East
Portland
1-5 / H-58
Eugene
1-84 / Pendleton
1-5 / Salem
Portland
Eugene
1-82 / 1-84 Hermiston
US-26
1-84/Ontario
1-5 / Portland
Eugene
1-5 / H-58 Eugene
Hillsboro
1-84/The Dalles
1-84 Boardman
Hubbard
1-84 / Boardman or
Port of Morrow
Umatilla
US-97 / Bend
1-5 Medford
1-84 / Pendleton
Roseburg
1-84 / La Grande
1-5 / Salem
1-84/Ontario
Portland
1-5 / Portland
US-97/ Bend
1-84/ US-97/The
Dalles
1-84 / Boardman or
Port of Morrow
1-84 / Pendleton
1-84 / La Grande
1-84/Ontario
1-5 Eugene to
Portland
Eugene
Portland
157 I F
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Finally, the following list shows where respondents suggested station locations in Washington.
Table 50: Fleet Proposed Alternative Fuel Infrastructure Locations - Washington
CNG
LNG
H2
EV
Coordinates: 47.171882,
1-5 / H-2 Everett
5 FWY
1-5 / Exit 193 Northbound Everett
-122.486240
1-5 / H-2 Everett
1-5/H-599 Tukwila
Puget Sound
1-5 / H-599 Tukwila
1-90 Cle Elum
5 FWY
1-90 Cle Elum
1-90 Spokane
Spokane
1-90 Spokane
1-5 Canadian Border to Olympia
Tri-Cities
Puget Sound
Seattle
Spokane
Bellevue
Kennewick
Yakima
1-5 Clark County
Tacoma
Olympia
47.171432, -122.484975
1-5 / Exit 193 Northbound Everett
In addition to assessing where fleets need locations for alternative fuel infrastructure, CALSTART also
sought to understand the average daily distance traveled for their vehicles. Understanding this
information is important for knowing what locations are best suited for fueling stations. Table 51 shows
summary statistics for daily distance traveled by each fleet.
Table 51: Summary Statistics - Daily Distance Traveled by Fleets
Average
Maximum
Minimum
Distance (Miles)
102
250
0
Hours of Operation
11
24
0
158 I F
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CALSTART also sought to understand the fueling station privacy preferences by each fleet. Figure 30 shows
which alternative fueling station type each fleet would use. 92% of fleets would use a private station,
while 46% of fleets would use a public retail station and 42% of fleets would use a limited access station.
Figure 30: Station Type Preferences by Fleets
Alternative Fuel Station Type Preferences
100%
90%
80%
% 70%
Ol
c 60%
o
Q-
S 50%
cr
o
-------�
Figure 31 Annual Compressed Natural Gas Demanded by Fleet Respondents
o-
LU
C
_o
"ro
~ai
to
a;
h
5000000
4500000
4000000
3500000
3000000
2500000
2000000
1500000
1000000
500000
0
Annual Compressed Natural Gas Demanded by Fleet
Respondents
4400000
704000
m 376549.36
0 4576
0 0 124960 o g 72160 0 0 0 154000
6 7 8 9
Respondent
10
11
12
13
14
Figure 32 Annual Liquefied Natural Gas Demanded by Fleet Respondents
Annual Liquefied Natural Gas Demanded by Fleet
Respondents
440000
3
cr
LU
c
_o
"ro
"33
OJ
h
500000
450000
400000
350000
300000
250000
200000
150000
100000
50000
0
124960
35000
0
I
0
5 6 7
Respondent
10
11
160 | P a g e
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Figure 33 Annual Liquefied Petroleum Gas Demanded by Fleet Respondents
12000
10000
8000
CO
c
:§ 6000
ra
(J
4000
2000
0
Annual Liquefied Petroleum Gas Demanded by Fleet
Respondents
4000
10000
0
0
0
0
0
0
0
14
12
10
t/1
¦*r->
ro
8
(O
00
¦D
2
6
4
2
0
Respondent
Figure 34 Megawatt EV Charging Capacity Demanded by Fleet Respondents
Megawatt EV Charging Capacity Demanded by Fleet
Respondents
10
1.5
1.5
Respondent
Suggested Project Partners for Infrastructure Development: Having the right partners involved is also
important to any alternative fuel infrastructure development project. As such, when asked what project
partners are required for each fleet to have in order to install a fueling station, they provided a number
of answers. Here is a list of common partners that fleets listed as important partners to a project:
161 | P a g e
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Mobile Source Air Pollution Reduction Review Committee (MSRC), Air Quality Management District
(AQMD), Construction, Planning, Ports, State, Procurement/Sourcing, Landlord, Electrical Design,
Engineering, Real Estate, Engineering Construction Procurement, General Contractor, Consultants,
Original Equipment Manufacturers, City, and utilities.
Current Infrastructure Projects: In addition to future projects, several fleets already had alternative fuel
infrastructure development projects underway at the time of survey distribution. According to survey
results, 65% of fleet respondents were working on a project.
Figure 35: Current Alternative Fuel Infrastructure Projects by Fleets
Are you currently working on any
alternative fuel infrastructure development
projects for your fleet?
70%
60%
trt
I 50%
"O
g. 40%
i/t
Q)
t 30%
O
£
| 20%
10%
65%
77%
8%
Yes
No
Response
1 don't know
0%
162 | P a g e
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Of those that had an alternative fuel infrastructure project underway, the majority of them were electric
charging station projects, followed by CNG, LNG, and H2. Other responses included renewable natural gas
and renewable diesel projects.
Figure 36: Current Alternative Fuel Infrastructure Projects by Fleets per Fuel Type
Fuel Types Included in Alternative Fuel
Infrastructure Projects Underway
70% -| 65%
60%
I 50%
01
T3
g. 40%
a>
^ 30% -\ 26%-
a>
J; 20%
on
10%
0%
9%
4%
¦
0%
LNG
LPG
H2
Fuel Type
22%
I
CNG LNG LPG H2 EV Other (please
specify)
163 | P a g e
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Respondents which had alternative fuel infrastructure projects underway at the time of survey
distribution were asked to describe the details of their projects. Table 53 shows the range of projects that
are currently underway by fleets who responded to the survey.
Table 53: List of Current Alternative Fuel Infrastructure Projects Underway by Fleets
Fuel
Annual
Number of
Number of
Public
Located
Estimated
Type
Fueling
Vehicles/Equipment
Dispensers
or
in a
Completion
Capacity
Units it is Built to
Support
Private
Station?
DAC?
Year
Fleet
EV
6,000
45
45
Private
Yes
2028
Project 1
MWh
Fleet
EV
N/A
30
30
Limited
No
2019
Project 2
Access
Fleet
EV
N/A
3-5
2
Private
No
Ongoing
Project 3
Fleet
EV
N/A
10 buses
10
Private
Yes
N/A
Project 4
Fleet
EV
N/A
40
40
Private
N/A
2021
Project 5
Fleet
EV
N/A
8
8
Public
No
2019
Project 6
Fleet
EV
N/A
6
8
Private
Yes
2019
Project 7
Fleet
EV
N/A
4
N/A
Private
Yes
2021
Project 8
Fleet
EV
N/A
N/A
N/A
Private
Yes and
2022
Project 9
No
Fleet
EV
Varies by
Varies by site
Varies by
Private
Yes
Varies by
Project
site
site
site
10
Fleet
CNG
1,056,000
300 per day
3
Public
Yes
Operational
Project
DGE
today,
11
expansion
by 2019
Fleet
CNG
26,400
200
4
Private
Yes
2020
Project
DGE
12
Fleet
EV
N/A
10
10
Private
N/A
N/A
Project
13
Fleet
CNG
N/A
N/A
N/A
N/A
N/A
2021
Project
14
164 I F
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Current Project Funding Needs: Many respondents who stated that they are currently working on
alternative fuel infrastructure projects said that those projects could use funding support. As seen in
Figure 37 below, 68% of respondents said that their projects could use funding.
Figure 37: Fleet Funding Needs for Alternative Fuel Infrastructure Projects Currently Underway
Do Your Alternative Fuel Infrastructure
Projects Underway Require Funding
Support?
80%
70%
| 60%
c 50%
0
Q.
S 40%
C£
1 30%
w
£ 20%
10%
68%
18%
14%
Yes
No
Response
don't know
0%
Respondents stated various uses for this funding, including the following: adding time-fill stations, adding
gas compression capacity, installing power lines, paying for electric work, trenching, expanding a station
to retail, construction, design, and purchasing infrastructure, vehicles, equipment, or signage. Of these
uses, purchasing infrastructure and equipment had the most responses.
165 | P a g e
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Fuel Provider Survey Results11*
In total, 31 organizations responded to the fuel provider survey, and like the fleet survey this group
represents all three West Coast states.
Of all three states, California had the largest share of representation, followed by Washington then
Oregon.
Figure 38: Fuel Provider States of Operation
States of Operation
70%
60%
£ 50%
c
CD
"O
0 40%
Q.
to
01
CC
^ 30%
20%
10%
"55%-
0%
63%
California
Oregon
State
Washington
LIX As stated above, this survey was administered before additional outreach was conducted which yielded
additional information, and therefore the survey results in and of themselves are not a complete representation of
the full results of this effort. Please refer to Sections VIII and IX for full and final results.
166 | P a g e
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Alternative Fuel Station Development Plans: The survey started by asking fuel providers what fuel types
they plan to develop in California within the next three to five years. While all alternative fuel types were
represented, electric vehicle charging had the highest share of responses, followed by respondents with
no plans to develop in that time frame, CNG, H2, LPG, and then LNG.
Figure 39: Fuel Provider Plans to Develop Alternative Fuel Infrastructure in California Within Three-to-Five Years
Plans to Develop Alternative Fuel
Infrastructure in California within 3-5
Years
40%
9%
6%
_
m
CNG
LNG
LPG
H2
EV
No Plans
Fuel Type
167 | P a g e
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Respondents largely have no plans to develop alternative fuel stations in Oregon. However, those that do
plan on developing mostly EV charging and CNG stations, followed by H2, and then LNG and LPG.
Figure 40: Fuel Provider Plans to Develop Alternative Fuel Infrastructure in Oregon Within Three-to-Five Years
70%
60%
~ 50%
0)
TJ
| 40%
-------�
Like Oregon, most respondents do not have plans to develop alternative fuel stations in Washington. For
those that do, a majority plan to develop EV charging stations, followed by CNG, LPG, H2, and LNG stations.
Figure 41: Fuel Provider Plans to Develop Alternative Fuel Infrastructure in Washington Within
Three-to-Five Years
c.r\
-------�
Fuel providers also provided similar suggestions in the state of Oregon, although they provided
significantly fewer locations in this state.
Table 55: Fuel Provider Proposed Alternative Fuel Infrastructure Locations - Oregon
CNG
H2
EV
1-5
Fleet Depots
1-5
Metropolitan Areas
The following list describes the same suggestions for Washington.
Table 56: Fuel Provider Proposed Alternative Fuel Infrastructure Locations - Washington
CNG
LPG
H2
EV
Tacoma
1-90
Tacoma
1-5
Seattle
Seattle
Metropolitan Areas
Ports
Ports
Tacoma
1-5
Fleet Depots
Seattle
Ports
Projected Annual Fuel Demand. CAPEX. and Development Time Estimates: In addition to the optimal
locations for alternative fuel infrastructure, CALSTART also sought to understand what annual level of
demand is required to justify the development of a Class 8-accessible station for fuel providers. Table 57
summarizes statistics on this topic by fuel type.
Table 57: Annual Demand for Fuel Required to Justify Station Development per Fuel Type
CNG (DGE)
LNG (DGE)
LPG (Gal)
H2 (Kg)
EV (MW Capacity)
Average
249,333
No Answers
67,500
30,000
2
Maximum
352,000
No Answers
75,000
30,000
2
Minimum
88,000
No Answers
60,000
30,000
2
To see the distribution of responses by fuel type, see Figure 42 through Figure 45. As you will see in these
figures, only a handful of the total survey respondents shared responses to this question, and it varied by
fuel type.
170 I F
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Figure 42 Suggested Minimum Annual Level of CNG Demand Needed to Justify Station Development
Suggested Minimum Annual Level of CNG Demand Needed
to Justify Station Development
400000
350000
S 300000
03
>
=5 250000
O"
LU
g 200000
<3 150000
13
£ 100000
~
50000
0
352000
88000
308000
Respondent
Figure 43 Suggested Minimum Annual Level of LPG Demand Needed to Justify Station Development
Suggested Minimum Annual Level of LPG Demand Needed
to Justify Station Development
80000
70000
60000
50000
M 40000
75000
ra
13
30000
20000
10000
0
60000
1
Respondent
2
171 | P a g e
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Figure 44 Suggested Minimum Annual Level of Hydrogen Demand Needed to Justify Station Development
Suggested Minimum Annual Level of H2 Demand Needed
to Justify Station Development
35000
30000
30000
25000
E 20000
ra
ob
M 15000
10000
5000
0
1
Respondent
Figure 45 Suggested EV Megawatt Charging Capacity Needed to Justify Station Development
2.5
Suggested EV Megawatt Charging Capacity Needed to
Justify Station Development
ro
5
to
on
oj
1.5
0.5
Respondent
172 | P a g e
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Similarly, CALSTART asked fuel providers to describe their estimated CAPEX range for developing one
fueling station at the minimum level of annual demand they described in the table above. These results
represent estimates for stations that meet the minimum capacity requirements that fuel providers
suggested are needed to justify the business case for station development. The CAPEX of any fueling or
charging station will vary by size and scope. This is reflected in Section IX as the CAPEX estimates for
specific project proposals vary and differ from the average responses provided through surveys as shown
in Table 58.
Table 58: Estimated CAPEX per Station per Fuel Type via Survey Responses
CNG
LNG
LPG
H2
EV
Average
$1,125,000
$500,000
$285,000
$625,000
$50,000
Maximum
$2,000,000
$500,000
$500,000
$750,000
$50,000
Minimum
$500,000
$500,000
$70,000
$500,000
$50,000
When asked the projected timeline to develop one fueling station for each of the following fuel types, the
respondents gave numerous responses. Table 59 shows summary statistics across all responses per fuel
type.
Table 59: Estimated Development Timeline per Station per Fuel Type
CNG
LNG
LPG
H2
EV
Average
13.8 months
12 months
5.67 months
20 months
8.5 months
Maximum
24 months
12 months
12 months
24 months
12 months
Minimum
9 months
12 months
2 months
12 months
5 months
As with fleets, CALSTART asked fuel providers what partners are important to an infrastructure
development project. The three partners which were mentioned most, in order, were utilities,
engineering procurement and construction providers, and city permitting offices. Fuel providers also
mentioned the following partners less frequently: original equipment manufacturer, the state, operations
and maintenance contractors, project management organizations, modular fuel storage and dispensing
vehicle companies, companies providing rail access, software vendors, and hardware vendors.
173 I F
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Infrastructure Funding Needs: Fuel providers were asked, if funding were available to help them cover the
capital expenses for developing alternative fueling infrastructure, what is the minimum percentage of the
total capex that funding must cover for them to consider the development. 73% respondents stated that
>80% should be covered by funding assistance.
Figure 46: Minimum Fuel Provider Funding Needed for Alternative Fuel Infrastructure CAPEX
Minimum Percentage of Alternative Fuel
Vehicle Infrastructure CAPEX Required to
be Funded to Justify Station Development
c
C£.
H—
O
(D
i-
ro
-C
in
30%
25%
20%
15%
10%
5%
0%
-8%-
i
25%
-8% 8%-
0%
~i r
17%
8%
S Vn
0%
0%
J
0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% Do not
know
Percentage of CAPEX
174 | P a g e
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Infrastructure Projects Currently in Development and Funding Needs: When asked about current
alternative fuel infrastructure development projects in California, most respondents said there were none
in development, but those that did state projects were focused primarily on EV and CNG stations, followed
by LPG and H2 station development.
Figure 47: Current Fuel Provider Alternative Fuel Infrastructure Projects Underway - California
Alternative Fuel Infrastructure Projects
Underway in California
60% -|
50%
50%
i/i
4->
| 40%
C
O
Q.
® 30%
21% 21%
20%
10% -| 234 2^-
0%
0%
CNG LNG LPG H2 EV Not
Developing
Fuel Type
175 | P a g e
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Further, 43% of fuel providers who are currently developing projects in California do not need funding
support. 36% of fuel providers with projects under way stated that they did not know if they would need
funding support for those projects, and 21% said that they did need funding.
Figure 48: Fuel Provider Funding Needs for Current Projects Underway - California
Do any of your projects underway
in California require additional funding
support?
50%
45%
0 40%
£ 35%
"D
O 30%
a 25%
ce
*5 20%
-------�
Similarly, most respondents said that they are not developing projects in Oregon. Of those that do have
projects underway in Oregon, 14% are working on either CNG or LPG projects, and 7% are working on
either LNG, H2, or EV projects.
Figure 49: Current Fuel Provider Alternative Fuel Infrastructure Projects Underway - Oregon
80%
70%
£! 60%
c
01
c 50%
o
Q.
2 40%
ce
2 30%
i—
(0
5 20%
10%
0%
ng
177 | P a g e
Alternative Fuel Infrastructure Projects
Underway in Oregon
71%
~W%
7% 7% 7%
CNG LNG LPG H2 EV Not
Developi
Fuel Type
-------�
Most respondents that had projects underway in Oregon stated that they do not need additional funding,
25% stated that they do not know if funding is needed, and 8% stated that they could use additional
funding. Those that need funding would use it for the following purposes: fund expansion of project scope,
purchase construction materials, secure fuel storage and supply, purchase dispensertrucks, fund software
development and support.
Figure 50: Fuel Provider Funding Needs for Current Projects Underway - Oregon
Do any of your projects underway in
Oregon require additional funding
support?
80%
70%
% 60%
-------�
Again, in Washington, the majority of respondents stated that they are not currently developing
alternative fuel stations. Those that are focus mostly on EV charging, followed by a tie between CNG, LNG,
LPG, and H2.
Figure 51: Current Fuel Provider Alternative Fuel Infrastructure Projects Underway-Washington
70%
60%
I 50%
tu
"O
g. 40%
0>
^ 30%
-------�
While the majority of respondents who are developing projects in Washington stated that they do not
require additional funding, those that do listed a few uses for funding. Those uses are as follows: leasing
land, purchasing equipment, design, permitting, scope expansion, and purchasing materials.
Figure 52: Fuel Provider Funding Needs for Current Projects Underway - Washington
Do any of your projects underway in
Washington require additional funding
support?
70%
60%
I 50%
"O
g. 40%
iA
jl 20%
i/i
10%
58%
ZD/o
17%
0%
Yes
No
Response
I don't know
180 | P a g e
-------�
Table 60 shows the range of projects that are planned or currently underway in California by fuel providers
who responded to the survey.
Table 60: Current and Planned Alternative Fuel Infrastructure Projects by Fuel Providers - California
Fuel
Project
Public or
Station
Annual
Number of
Located
Type
Timeline
Private
Station?
Location
Fueling
Capacity
Dispensers
in a
DAC?
Fuel
EV
Nine
Private
Multiple
12.5 MW
1000
Some
Provider
months
locations
(across all
Project 1
(Complete
2020)
sites)
Fuel
RNG
N/A
Public
Multiple
N/A
N/A
Some
Provider
locations
Project 2
Fuel
CNG,
N/A
Public
Los Angeles
176,000
4
Yes
Provider
RNG
DGE
Project 3
Fuel
CNG
18 months
Public
N/A
264,000
2
Don't
Provider
DGE
Know
Project 4
Fuel
H2
60 months
Private
N/A
1,760,000
N/A
Don't
Provider
DGE
Know
Project 5
Fuel
EV
36 months
Public
Freight
"Several
N/A
Don't
Provider
Corridors
Thousand
Know
Project 6
Trucks"
Fuel
EV
N/A
Private
Port of San
N/A
30
Yes
Provider
Diego
Project 7
Fuel
EV
24 months
Private
35 W. Saint
N/A
2
No
Provider
Josephs St.,
Project 8
Arcadia, CA
Fuel
LPG
Complete
Public
Los Angeles
200,000
1
Don't
Provider
2021
County
Gallons
Know
Project 9
Fuel
CNG
12 months
Public
N/A
264,000
2
Don't
Provider
DGE
Know
Project 10
minimum
Fuel
LPG
Complete
Public
Orange
200,000
1
Don't
Provider
2021
County
gallons
Know
Project 11
Fuel
LPG
Complete
Public
Riverside
200,000
1
Don't
Provider
2021
County
gallons
Know
Project 12
Fuel
LPG
Complete
Public
San
200,000
1
Don't
Provider
2021
Bernardino
gallons
Know
Project 13
County
181 I F
-------�
Fuel
Project
Public or
Station
Annual
Number of
Located in
Type
Timeline
Private
Station?
Location
Fueling
Capacity
Dispensers
a DAC?
Fuel
RNG
N/A
Public
N/A
N/A
N/A
N/A
Provider
Project 14
Fuel
LPG
Complete
Public
405 /10 FWY
200,000
1
Don't
Provider
2021
gallons
Know
Project 15
Fuel
CNG
36 months
Private
Several
11,300,000
7-15
Don't
Provider
Locations:
DGE
Know
Project 16
Industrial and
Agricultural
Areas
182 I F
-------�
Table 61 shows the same results for projects planned or currently underway in Oregon.
Table 61: Current and Planned Alternative Fuel Infrastructure Projects by Fuel Providers - Oregon
Fuel
Project
Public or
Station
Annual
Number of
Located
Type
Timeline
Private
Station?
Location
Fueling
Capacity
Dispensers
in a
DAC?
Fuel
CNG,
24 months
Public
N/A
264,000
3
Don't
Provider
EV
DGE
Know
Project 1
minimum
Fuel
EV
36 months
Public
Freight
"Several
N/A
Don't
Provider
Corridor
thousand
Know
Project 2
trucks per
day"
Fuel
EV
Operational
Private
Transit
450 kW
1
Don't
Provider
03/2019
Depot
Know
Project 3
Fuel
EV
Operational
Private
Transit
100 kW
6
Don't
Provider
03/2019
Depot
Know
Project 4
Fuel
EV
Complete
Private
Transit
Varies by
100 (across
Don't
Provider
2022
Agencies
site
all sites)
Know
Project 5
Fuel
CNG
36 months
Private
Several
11,300,000
7-15
Don't
Provider
Locations:
DGE
Know
Project 6
Industrial
and
Agricultural
Areas
Fuel
CNG
12/2020
Private
SE Portland
26,400 DGE
2
Yes
Provider
Project 7
Fuel
Biofuel
6 months
Private
Redmond
3-5 million
5-7
Don't
Provider
gallons
Know
Project 8
183 I F
-------�
Table 62 shows projects planned or currently underway in Washington.
Table 62: Current and Planned Alternative Fuel Infrastructure Projects by Fuel Providers - Washington
Fuel
Type
Project
Timeline
Public or
Private
Station?
Station
Location
Annual
Fueling
Capacity
Number of
Dispensers
Located
in a
DAC?
Fuel
Provider
Project 1
H2
36 months
(Complete
2023)
Public
Tacoma
N/A
N/A
Yes
Fuel
Provider
Project 2
CNG,
EV
24 months
Public
N/A
264,000 DGE
minimum
3
Don't
Know
Fuel
Provider
Project 3
EV
36 months
Public
Freight
Corridor
"Several
thousand
trucks per
day"
N/A
Don't
Know
Fuel
Provider
Project 4
LPG
Open Now
Both
Multiple
locations
360,000
gallons
2
No
Fuel
Provider
Project 5
EV
36 months
(Complete
2023)
Public
Tacoma
N/A
N/A
Yes
Fuel
Provider
Project 6
H2
36 months
(Complete
2023)
Public
Tacoma
35,000 kg
N/A
Yes
Fuel
Provider
Project 7
LPG
3 months
Both
N/A
60,000
gallons
2
No
Fuel
Provider
8
EV
Complete
2021
Public
Tacoma
150
MWh/year
N/A
Yes
Fuel
Provider
Project 9
CNG
36 months
Private
Several
Locations:
Industrial
and
Agricultural
Areas
11,300,000
DGE
7-15
Don't
Know
Fuel
Provider
10
CNG
2020
Private
Vancouver
26,400 DGE
2
No
184 I F
-------�
XIII. APPENDIX D: Endnotes
1 United States Environmental Protection Agency, (n.d.). Sources of Greenhouse Gas Emissions. In United States
Environmental Protection Agency. Retrieved from https://www.epa.gov/ghgemissions/sources-
greenhouse-gas-emissions
2 U.S. Department of Transportation. (2019, October 8). Fixing America's Surface Transportation Act or "FAST Act".
In Federal Highway Administration. Retrieved from https://www.fhwa.dot.gov/fastact/section.cfm
3 U.S. Department of Transportation Federal Highway Administration. (2019, November 4). Electric Corridor Map.
In ArcGIS. Retrieved from
https://www.arcgis.com/home/webmap/viewer.html?webmap=376dedd75b8347b8936abd707
03cdb69&extent=-158.6002,16.7349,-56.1198,56.6162
4 U.S. Department of Transportation Federal Highway Administration. (2019, November 12). Hydrogen Corridor
Map. In ArcGIS. Retrieved from
https://www.arcgis.com/home/webmap/viewer.html?webmap=lce93c0d6a84479494d40513f7
43b403&extent=-158.6002,16.7349,-56.1198,56.6162
5 U.S. Department of Transportation Federal Highway Administration. (2019, November 4). Propane (LPG) Corridor
Map. In ArcGIS. Retrieved from
https://www.arcgis.com/home/webmap/viewer.html?webmap=2527f9038e7c4de09ebfabc78fb
57e85&extent=-158.6002,16.7349,-56.1198,56.6162
6 U.S. Department of Transportation Federal Highway Administration. (2019, November 4). Compressed Natural
Gas (CNG) Corridor Map. In ArcGIS. Retrieved from
https://www.arcgis.com/home/webmap/viewer.html?webmap=a86a599982d8486587863262a
460ccf9&extent=-158.6002,16.7349,-56.1198,56.6162
7 U.S. Department of Transportation Federal Highway Administration. (2019, November 12). Liquefied Natural Gas
(LNG) Corridor Map. In ArcGIS. Retrieved from
https://www.arcgis.com/home/webmap/viewer.html?webmap=ad0bll99f7494b29a2c31cd00a
420c29&extent=-158.6002,16.7349,-56.1198,56.616
8 U.S. Department of Transportation Federal Highway Administration. (2019, December 5). Fixing America's
Surface Transportation Act or "FAST Act". In U.S. Department of Transportation Federal Highway
Administration. Retrieved from https://www.fhwa.dot.gov/fastact/
9 United States Environmental Protection Agency, (n.d.). Clean Diesel and DERA Funding. In United States
Environmental Protection Agency. Retrieved from https://www.epa.gov/cleandiesel
10 West Coast Collaborative. (2019, December 9). West Coast Collaborative. In West Coast Collaborative. Retrieved
from https://www.westcoastcollaborative.org/https://ww2.arb.ca.gov/our-
work/programs/low-carbon-transportation-investments-and-air-qualitv-improvement-program/low-1
11 United States Environmental Protection Agency, (n.d.). Ports Initiative. In United States Environmental
Protection Agency. Retrieved from https://www.epa.gov/ports-initiative
12 U.S. Department of Energy, (n.d.). Clean Cities Coalition Network. In U.S. Department of Energy. Retrieved from
https://cleancities.energy.gov/
13 U.S. Department of Energy. (2016, August 16). Energy Department Announces $137 Million Investment in
Commercial and Passenger Vehicle Efficiency. In U.S. Department of Energy. Retrieved from
https://www.energv.gov/articles/energy-department-announces-137-million-investment-
commercial-and-passenger-vehicle
14 U.S. Department of Energy, (n.d.). Hydrogen & Fuel Cells Program. In U.S. Department of Energy.
Retrieved from https://www.hvdrogen.energy.gov/
15 California State Legislature. (2016, September 8). SB-32 California Global Warming Solutions Act of
2006: emissions limit. In California Legislative Information. Retrieved from
https://leginfo.legislature.ca.gov/faces/billNavClient.xhtml7bill id=201520160SB32
16 California State Legislature. (2015, October 7). SB-350 Clean Energy and Pollution Reduction Act of
2015. In California Legislative Information. Retrieved from
185 | P a g e
-------�
https://leginfo.legislature.ca.gov/faces/billNavClient.xhtml7bill id=201520160SB350
17
California State Legislature. (2016, September 19). SB-1383 Short-lived climate pollutants: methane emissions:
dairy and livestock: organic waste: landfills. In California Legislative Information. Retrieved from
https://leginfo.legislature.ca.gov/faces/billNavClient.xhtml7bill id=201520160SB1383
18 California State Legislature. (2019, October 9). AB-784 Sales and use taxes: exemption: California Hybrid
and Zero-Emission Truck and Bus Voucher Incentive Project: transit buses. In California
Legislative Information. Retrieved from
https://leginfo.legislature.ca.gov/faces/billTextClient.xhtml7bill id=201920200AB784
19 California State Legislature. (2018, September 20). AB-2061 Near-zero-emission and zero-emission
vehicles. In California Legislative Information. Retrieved from
https://leginfo.legislature.ca.gov/faces/billTextClient.xhtml7bill id=201720180AB2061
20 Newsom, G. (2019, September 20). Executive Order N-19-19. In Office of Governor Gavin Newsom. Retrieved
from https://www.gov.ca.gOv/wp-content/uploads/2019/09/9.20.19-Climate-EQ-N-19-19.pdf
21 Brown, E. (2018, January 26). Executive Order B-48-18. In Office of Governor Edmund Brown. Retrieved from
https://www.ca.gov/archive/gov39/2Q18/01/26/governor-brown-takes-action-to-increase-zero-emission-
vehicles-fund-new-climate-investments/index.html
22 California Air Resources Board. (2017, November). California's 2017 Climate Change Scoping Plan.
In California Air Resources Board. Retrieved from
https://ww3.arb.ca.gov/cc/scopingplan/scoping plan 2017.pdf
23 California Air Resources Board. (2019). Proposed Fiscal Year 2019-20 Funding Plan for Clean Transportation
Incentives for Low Carbon Transportation Investments and the Air Quality Improvement Program.
Sacramento, CA: California Air Resources Board. Retrieved from
https://ww2.arb.ca.gov/sites/default/files/2019-09/fvl920fundingplan.pdf
24 California Air Resources Board, (n.d.). Low Carbon Fuel Standard. In California Air Resources Board.
Retrieved from https://ww3.arb.ca.gov/fuels/lcfs/lcfs.htm
25 California Air Resources Board, (n.d.). California HVIP. In California HVIP. Retrieved from
https://www.californiahvip.org/
26 California Air Resources Board, (n.d.). Volkswagen Zero-Emission Vehicle (ZEV) Investment Commitment.
In California Air Resources Board. Retrieved from https://ww2.arb.ca.gov/our-
work/programs/volkswagen-zero-emission-vehicle-zev-investment-commitment
27 California Energy Commission, (n.d.). Clean Transportation Program. In California Energy Commission. Retrieved
from https://www.energy.ca.gov/programs-and-topics/programs/clean-
transportation-program
28 California Energy Commission, (n.d.). CALeVIP. In CALeVIP. Retrieved from https://calevip.org/
29 California Department of Food & Agriculture, (n.d.). Dairy Digester Research & Development Program.
In California Department of Food & Agriculture. Retrieved from
https://www.cdfa.ca.gov/oefi/ddrdp/
30 Senate Bill 1044, 80th Oregon Legislative Assembly, 2019 Regular Session. (OR. 2019). Retrieved from
https://olis.leg.state.or.us/liz/2019Rl/Downloads/MeasureDocument/SB1044/Enrolled
31 Senate Bill 583, 77th Oregon Legislative Assembly, 2013 Regular Session. (OR. 2013). Retrieved from
https://olis.leg.state.or.us/liz/2013Rl/Downloads/MeasureDocument/SB0583/Enrolled
32 Senate Bill 98, 80th Oregon Legislative Assembly, 2019 Regular Session. (OR. 2019). Retrieved from
https://olis.leg.state.or.us/liz/2019Rl/Downloads/MeasureDocument/SB98/lntroduced
33 Senate Bill 1547, 78th Oregon Legislative Assembly, 2016 Regular Session. (OR. 2016). Retrieved from
https://olis.leg.state.or.us/liz/2016Rl/Downloads/MeasureDocument/SB1547/Enrolled
34 House Bill 3543, 74th Oregon Legislative Assembly, 2007 Regular Session. (OR. 2007). Retrieved from
https://olis.leg.state.or.us/liz/2007Rl/Downloads/MeasureDocument/HB3543/Enrolled
35 House Bill 2017, 79th Oregon Legislative Assembly, 2017 Regular Session. (OR. 2017). Retrieved from
https://olis.leg.state.or.us/liz/2017Rl/Downloads/MeasureDocument/HB2017/Enrolled
36 House Bill 2007, 80th Oregon Legislative Assembly, 2019 Regular Session. (OR. 2019). Retrieved from
186 | P a g e
-------�
https://olis.leg.state.or.us/liz/2019Rl/Downloads/MeasureDocument/HB2007/Enrolled
37 State of Oregon Government, (n.d.). Oregon Clean Fuels Program. In State of Oregon Government.
Retrieved from https://www.oregon.gov/deq/aq/programs/Pages/Clean-Fuels.aspx
38 Brown, K. (2017, November 06). Executive Order No. 17-21: Accelerating Zero Emission Vehicle Adoption in
Oregon to Reduce Greenhouse Gas Emissions and Address Climate Change. In Office of the Governor:
State of Oregon. Retrieved from https://www.oregon.gov/gov/Documents/executive orders/eo 17-
21.pdf
39 Oregon Solutions, (n.d.). Oregon Electric Vehicle Collaborative. In Oregon Solutions. Retrieved from
https://orsolutions.org/osproiect/oregon-electric-vehicle-collaborative-summarv
40 Downing, K. (2017, December 15). VW Diesel Settlement: Oregon's Initial Environmental Mitigation Plan.
In State of Oregon Department of Environmental Quality. Retrieved from
https://www.oregon.gov/deq/FilterDocs/VWenviroMitPlanFS.pdf
41 Multi-State ZEV Task Force, (n.d.). About the ZEV Task Force. In Multi-State ZEV Task Force. Retrieved from
https://www.zevstates.us/
42 ZEV Task Force. (2018). Multi-State ZEV Action Plan: Accelerating the Adoption of Zero Emission Vehicles.
Boston, MA: NESCAUM. https://www.nescaum.org/documents/2018-zev-action-plan.pdf
43 State of Oregon Government, (n.d.). Oregon's Clean Car Standards. In State of Oregon Government.
Retrieved from https://www.oregon.gov/deq/aq/programs/Pages/ORLEV.aspx
44 Washington State Department of Transportation, (n.d.). West Coast Electric Highway. In West Coast Green
Highway. Retrieved from http://www.westcoastgreenhighwav.com/electrichighwav.htm
45 Oregon Transportation Commission. (2019, August 06). Agenda D - Allocation of Oregon's Federal-Aid Highway
Program Redistribution - Fiscal Year 2019. Retrieved from https://www.oregon.gov/ODOT/Get-
Involved/OTCSupportMaterials/Agenda D Federal-Aid Hwv Program Redistribution Ltr.pdf
46 California Climate Investments, (n.d.). Cap-and-Trade Dollars at Work. In California Climate Investments.
Retrieved from http://www.caclimateinvestments.ca.gov/
47 Washington Department of Ecology, (n.d.). Reducing Greenhouse Gases. In Washington Department of Ecology.
Retrieved from https://ecology.wa.gov/Air-Climate/Climate-change/Greenhouse-gases/Reducing-
greenhouse-gases
48 Substitute Senate Bill 5588, 66th Legislature, 2019 Regular Session. (WA. 2019). Retrieved from
http://lawfilesext.leg.wa.gov/biennium/2019-
20/Pdf/Bills/Senate%20Passed%20Legislature/5588-S.PL.pdf
49 Engrossed Second Substitute Senate Bill 5116, 66th Legislature, 2019 Regular Session. (WA. 2019). Retrieved from
http://lawfilesext.leg.wa.gov/biennium/2019-
20/Pdf/Bills/Senate%20Passed%20Legislature/5116-S2.PL.pdf
50 Engrossed Substitute House Bill 2580, 65th Legislature, 2018 Regular Session. (WA. 2018). Retrieved from
http://lawfilesext.leg.wa.gov/biennium/2017-
18/Pdf/Bills/House%20Passed%20Legislature/2580-S.PL.pdf
51 Substitute House Bill 1512, 66th Legislature, 2019 Regular Session. (WA. 2019). Retrieved from
http://lawfilesext.leg.wa.gov/biennium/2019-
20/Pdf/Bills/House%20Passed%20Legislature/1512-S.PL.pdf
52 Engrossed Second Substitute House Bill 2042, 66th Legislature, 2019 Regular Session. (WA. 2019). Retrieved from
http://lawfilesext.leg.wa.gov/biennium/2019-
20/Pdf/Bills/House%20Passed%20Legislature/2042-S2.PL.pdf
53 82 Revised Code of Washington § 16.0496, available at
https://app.leg.wa.gov/rcw/default.aspx?cite=82.16.0496
54 47 Revised Code of Washington § 04.350, available at
https://app.leg.wa.gov/RCW/default.aspx?cite=47.04.350
55 Washington State Department of Revenue. (2019, July 23). Special Notice: Tax exemptions on electric vehicle
infrastructure, electric vehicle batteries and fuel cells, and zero emission buses. In Washington State
Department of Revenue. Retrieved from
187 | P a g e
-------�
https://dor.wa.gov/sites/default/files/legacv/Docs/Pubs/SpecialNotices/2019/sn 19 ElectricVe
hicleBuses.pdf
56 Washington State Department of Revenue. (2019, July 23). Special Notice: Tax exemptions on electric vehicle
infrastructure, electric vehicle batteries and fuel cells, and zero emission buses. In Washington State
Department of Revenue. Retrieved from
https://dor.wa.gov/sites/default/files/legacv/Docs/Pubs/SpecialNotices/2019/sn 19 ElectricVe
hicleBuses.pdf
57 Washington State Department of Transportation. (2019). Public Transportation - Green Transportation Capital
Grant Notice of Funding Opportunity. In Washington State Department of Transportation. Retrieved from
https://www.wsdot.wa.gov/transit/grants/public-
transportation-green-transportation-capital-grant-notice-funding-opportunitv
58 The Northwest Seaport Alliance, (n.d.). Clean Truck Program Requirements. In The Northwest Seaport Alliance.
Retrieved from https://www.nwseaportalliance.com/trucks
59 47 Revised Code of Washington § 80.090, available at
https://app.leg.wa.gov/RCW/default.aspx?cite=47.80.090
60 Volkswagen Diesel Emissions Environmental Mitigation State and Indian Tribe Trusts, (n.d.). Washington.
In Volkswagen Diesel Emissions Environmental Mitigation Trust. Retrieved from
https://www.vwenvironmentalmitigationtrust.com/state-trust/washington
61 Smith, M., Castellano, J. (2015). Costs Associated with Non-Residential Electric Vehicle Supply Equipment:
Factors to consider in the implementation of electric vehicle charging stations. Washington, D.C.: U.S.
Department of Energy. Retrieved from
https://afdc.energv.g0v/files/u/publicati0n/evse cost report 2015.pdf
62 Smith, M., Castellano, J. (2015). Costs Associated with Non-Residential Electric Vehicle Supply Equipment:
Factors to consider in the implementation of electric vehicle charging stations. Washington, D.C.: U.S.
Department of Energy. Retrieved from
https://afdc.energv.g0v/files/u/publicati0n/evse cost report 2015.pdf
63 Northwestern Energy, (n.d.). Explanation of Demand Charges. In Northwestern Energy. Retrieved from
https://www.northwesternenergy.com/docs/default-source/documents/E-Programs/E-
demandcharges.pdf
64 California Air Resources Board. (2019, July). 2019 Annual Evaluation of Fuel Cell Electric Vehicle Deployment &
Hydrogen Fuel Station Network Development. In California Air Resources Board. Retrieved from
https://ww2.arb.ca.gov/sites/default/files/2019-07/AB8 report 2019 Final.pdf
65 Brown, E. (2018, January 26). Executive Order B-48-18. In Office of Governor Edmund Brown. Retrieved from
https://www.ca.gov/archive/gov39/2Q18/01/26/governor-brown-takes-action-to-increase-zero-emission-
vehicles-fund-new-climate-investments/index.html
66 California Fuel Cell Partnership, (n.d.). Cost to refill. In California Fuel Cell Partnership. Retrieved from
https://cafcp.org/content/cost-refill
67 California Fuel Cell Partnership, (n.d.). Cost to refill. In California Fuel Cell Partnership. Retrieved from
https://cafcp.org/content/cost-refill
68 Halvorson, B. (2019, June 6). Hydrogen supply pinch affects San Francisco fuel-cell drivers. In Green Car Reports.
Retrieved from https://www.greencarreports.com/news/1123449 hvdrogen-supplv-pinch-affects-san-
francisco-fuel-cell-drivers
69 Smith, M., Gonzales, J. (2014, September). Costs Associated with Compressed Natural Gas Vehicle Fueling
Infrastructure. In U.S. Department of Energy. Retrieved from
https://afdc.energv.g0v/files/u/publicati0n/cng infrastructure costs.pdf
70 U.S. Energy Information Administration. (2010, April). Annual Energy Outlook 2010. In U.S. Energy
Information Administration. Retrieved from
https://www.eia.gov/outlooks/archive/aeol0/pdf/0383(2010).pdf
188 I F
-------�
71 Kelly, K.; Melendez, M. (2017). Compressed Natural Gas Vehicle Maintenance Facility Modification
Handbook. Washington, D.C.: U.S. Department of Energy. Retrieved from
https://afdc.energv.g0v/files/u/publicati0n/cng maintenance facility mod.pdf
72 Dougherty, S.; Nigro, N. (2014). Alternative Fuel Vehicle & Fueling Infrastructure Deployment Barriers & the
Potential Role of Private Sector Financial Solutions. Washington, D.C.: U.S. Department of Energy.
Retrieved from
https://afdc.energy.gOv/files/u/publication/afv fueling infrastructure deployment barriers.pdf
73 Dougherty, S.; Nigro, N. (2014). Alternative Fuel Vehicle & Fueling Infrastructure Deployment Barriers & the
Potential Role of Private Sector Financial Solutions. Washington, D.C.: U.S. Department of Energy.
Retrieved from
https://afdc.energy.gOv/files/u/publication/afv fueling infrastructure deployment barriers.pdf
74 Swartz, N. (2000, May 1). Trucks: Fueling the Diesel vs. Natural Gas Debate. In Waste 360. Retrieved from
https://www.waste360.com/mag/waste trucks fueling diesel
75 Laughlin, M.; Burnham, A. (2014). Case Study - Propane School Bus Fleets. Washington, D.C.: U.S. Department of
Energy. Retrieved from https://afdc.energy.gov/files/u/publication/case-studv-propane-school-bus-
fleets.pdf
76 U.S. Environmental Protection Agency. (2020, February 14). Environmental Justice.
Retrieved from https://www.epa.gov/environmentaliustice
77 U.S. Department of Energy, (n.d.). Emissions from Hybrid and Plug-In Electric Vehicles
Retrieved from https://afdc.energy.gov/vehicles/electric_emissions.html
78 U.S. Department of Energy, (n.d.). Fuel Cell Electric Vehicle Emissions
Retrieved from https://afdc.energy.gov/vehicles/emissions_hydrogen.html
79 U.S. Department of Energy, (n.d.). Propane Vehicle Emissions.
Retrieved from https://afdc.energy.gov/vehicles/propane emissions.html
80 U.S. Department of Energy, (n.d.). Natural Gas Vehicle Emissions.
Retrieved from https://afdc.energy.gov/vehicles/natural gas emissions.html
81 California Office of Environmental Health Hazard Assessment. (2016, February 26). CalEnviroScreen FAQs.
In California Office of Environmental Health Hazard Assessment. Retrieved from
https://oehha.ca.gov/calenviroscreen/calenviroscreen-faqs
82 Coleman, L., Lindstrom, E., Milan, T., Lori, S. (2014). Alternative Fuels & Advanced Transportation
Technologies: Automotive Workforce Needs Assessment. Sacramento, CA: California Community
Colleges Chancellor's Office. Retrieved from http://coeccc.net/reports/31e4blle-47b9-4de9-
a2c6-657af5ffb2f6
83 SunLine Transit Agency, (n.d.). West Coast Center of Excellence in Zero Emission Technology. In SunLine
Transit Agency. Retrieved from https://www.sunline.org/alternative-fuels/west-coast-center-of-
excellence-in-zero-emission-technology
84 Ubaldo, J. (2018, June 18). Metro and L.A. County Partner on Transportation School to Create the Next
Generation of Workers. In The Source. Retrieved from https://thesource.metro.net/2018/06/18/metro-
and-l-a-countv-partner-on-transportation-school-to-create-the-next-generation-of-workers/
85 West Virginia University, (n.d.). National Alternative Fuels Training Consortium. In West Virginia
University. Retrieved from http://naftc.wvu.edu/
86 Chandler, S., Espino, J., O'Dea, J. (2017). Delivering Opportunity: How Electric Buses and Trucks Can Create Jobs
and Improve Public Health in California. Cambridge, MA: Union of Concerned Scientists. Retrieved from
https://www.ucsusa.org/sites/default/files/attach/2Q16/10/UCS-
Electric-Buses-Report.pdf
87 Oregon Metro. (2018). 2018 Regional Transportation Plan: Regional Freight Strategy. Portland, OR: Metro.
Retrieved from https://www.oregonmetro.gov/sites/default/files/2019/09/2Q/Regional-
Freight-Strategy-FINAL-091919.pdf
88 U.S. Department of Energy, (n.d.). Alternative Fueling Station Locator. In Alternative Fuels Data Center.
Retrieved from https://afdc.energy.gOv/stations/#/find/nearest
89 U.S. Department of Energy, (n.d.). Alternative Fueling Station Locator. In Alternative Fuels Data Center.
Retrieved from https://afdc.energy.gOv/stations/#/find/nearest
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