CHP
SSBS COMBINED HEAT AND
~ POWER PARTNERSHIP
Combined Heat and Power
Energy Savings and Energy Reliability for
Wastewater Treatment Facilities
Combined heat and power (CHP),
also known as cogeneration, can be
an excellent solution for controlling
energy costs while improving the
reliability of power and thermal energy
supplies for your wastewater treatment
facility (WWTF). With a well-designed
CHP system, your facility can:
Produce power at a cost below retail
electricity
Reduce operating costs by displacing
purchased fuels for thermal needs.
Ensure the availability of reliable
heat and electricity supply
Increase energy efficiency, reduce
greenhouse gas emissions, and
generate renewable power.
How Is CHP Used at
WWTFs?
CHP is the production of both power and
heat from a single fuel source. CHP is a
reliable, cost-effective option for WWTFs
that have, or are planning to install,
anaerobic digesters. The biogas flow from
the digester can be used as "free" fuel to
.generate electricity and power in a CHP
system using a turbine, microturbine, fuel
cell, or reciprocating engine. The thermal
Engineering Rules of
Thumb for Considering
CHP at a WWTF
Atypical WWTF processes 100 gallons
per day of wastewater for every person
served.
Approximately 1.0 cubic foot (ft3) of
digester gas can be produced by an
anaerobic digester per person per day.
This volume of gas can provide
approximately 2.2 watts of power
generation.
The heating value of the biogas
produced by anaerobic digesters is
approximately 600 British thermal units
per cubic foot (Btu/ft3).
For each 4.5 million gallons per day
processed by a WWTF with anaerobic
digestion, the generated biogas can
produce approximately 100 kilowatts
(kW) of electricity and 12.5 million Btu
(MMBtu) of thermal energy.
energy produced by the CHP system is
then typically used to meet digester heat
loads and for space heating. By making
use of the waste heat from onsite
electricity production, CHP increases fuel
efficiency and decreases energy costs.
For detailed information on the opportunities for CHP at WWTFs, see the CHP Partnership's report,
The Opportunities for and Benefits of Combined Heat and Power at Wastewater Treatment Facilities.1
1 Available at http:llwww.epa.govlchplmarketsjwastcwater.htni,.
-------�
Where Does CHP Have the Best
Technical and Economic Fit?
CHP has the greatest technical and economic
potential at WWTFs that have anaerobic digesters
and influent flow rates greater than 5 million gallons
per day (MGD). Anaerobic digestion continuously
produces biogas that contains approximately 60
percent methane. The biogas generated from each 4.5
MGD of influent flow generates approximately 100
kW of electricity and 12.5 MMBtu of thermal energy
in a CHP system. The electricity and heat can be
used for a variety of purposes:
To sell back to the grid as green power.
To operate pumps and blowers used throughout
the treatment process.
To maintain optimal digester temperatures, dry
the biosolids, and provide space heating for the
WWTF.
A variety of CHP technologies can be used at
WWTFs. Reciprocating engines are the most widely
used CHP systems and can be employed at facilities
with any influent flow rate. Microturbine and fuel cell
CHP systems up to approximately 1 megawatt (MW)
can be employed at facilities with influent flow rates
less than 50 MGD. Combustion turbine CHP systems
greater than 1 MW are an option for facilities with
influent flow rates greater than 50 MGD.
What Can CHP Do for You?
Reduce Energy Costs
A well-designed CHP system can be an attractive
investment for your WWTF. A CHP system allows
your facility to generate both electric and thermal
energy on site, offsetting the costs of grid power and
purchased fuel.
A market analysis developed by EPA's CHP
Partnership2 estimates the net cost to generate power
for three representative CHP systems at a WWTF.
Depending on the WWTF, costs can range from:
3 cents per kilowatt-hour (kWh) to 6.5
cents/kWh for a 126 kW microturbine.
9.1 cents/kWh to 10.2 cents/kWh for a 300 kW
fuel cell.
0.1 cents/kWh to 3.8 cents/kWh for a 1 MW
reciprocating engine.
Although the economics of CHP at WWTFs are
often attractive, in states where electricity prices are
low, burning biogas directly in boilers for onsite
heating needs might be more economical.
Ensure the Availability of Heat and Electricity
Supply
CHP systems provide critical power and thermal
reliability for WWTFs by producing power and heat
24 hours per day, 7 days per week. CHP integrates
seamlessly into existing heating and electrical systems
and provides a steady supply of hot water or steam. A
CHP system can also be configured to provide backup
power in the event of a utility outage so operations
can continue during a blackout or catastrophic event.
Typical CHP System Configuration at WWTFs
r >
Water
Heat Recovery
v J
Unit
Hot Exhaust
Gases
| Anaerobic j
Digester
^ Biogas J
Engine
Turbine
Microturbine
Fuel Cell
Generator
Electricity
2 available at http://www.epa.gov/chp/markets/wastewater.html
-------�
Increase Energy Efficiency, Reduce Greenhouse
Gas Emissions, and Generate Renewable Power
With CHP, improved efficiency means that your
facility uses less fuel; therefore, operating and
maintenance costs are reduced, while environmental
performance is improved. The power and heat
produced on site by the CHP system displaces
purchases of electricity and fuel for boilers. The same
reductions in purchased electricity that result in
energy cost savings also reduce the environmental
impact of WWTF operations by reducing air
pollution.
On a national scale, if all WWTFs that operate
anaerobic digesters and have influent flow rates
greater than 5 MGD were to install CHP,
approximately 340 MW of clean electricity could be
generated, offsetting 2.3 million metric tons of
carbon dioxide (CO-,) emissions annually. These
emission reductions are equivalent to removing
approximately 430,000 cars from the road.
Additionally, because the biogas produced by
WWTFs is considered renewable by most state
renewable portfolio standards and third-party green
power certification programs, the environmental
attributes of electricity generated by CHP systems at
WWTFs can be sold as renewable energy certificates
(RECs). The monetary value of the REC sale may be
used to defray the capital costs of the CHP system to
further improve project economics.
How Is CHP Being Used at U.S. WWTFs?
As of September 2007, wastewater treatment CHP systems were in place at 79 sites in 24 states, representing
223 MW of electric capacity. Of the existing CHP systems in the wastewater treatment sector, the majority use
reciprocating engines. The mix of technologies used for CHP also includes microturbines, fuel cells, and turbine
installations.
The following case studies provide examples of recent successful CHP installations at WWTFs.
City of Albert Lea Wastewater Treatment
Facility, Minnesota
In the summer of 2003, the city of Albert Lea, Minnesota,
installed a 120 kW CHP system at its WWTF. The CHP
system integrates four 30 kW microturbines (manufactured
by Capstone Turbine Corporation, a CHP Partnership
Partner) and utilizes the recovered heat (28 MMBtu per
day) from the turbines to maintain proper operating
temperature of the anaerobic digester and provide a
portion of the facility's space heating requirements.
With funding from the Minnesota Department of
Commerce's Conservation Improvement Program and the
local utility, the CHP system provides 120 kW of backup
power to operate critical systems during a utility power
outage. The CHP system also saves the WWTF 800,000
kWh/year, or 25 percent of its energy use. The system has
a payback period of approximately 4 to 6 years.
In addition to representing a successful partnership
between municipal, utility, and state entities, the
project successfully integrates a CHP system utilizing
a renewable fuel, generates energy and cost savings
for the municipality, and results in reduced air
emissions for local citizens.
Palmdale Water Reclamation Plant,
California
In 2004, the Los Angeles County Sanitation District
(LACSD) began operating a 250 kW fuel cell CHP
system at the Palmdale Water Reclamation Plant. The
fuel cell was manufactured by FuelCell Energy, a CHP
Partnership Partner. With the CHP system, 70 to 80
percent of the digester gas produced by the facility's
anaerobic digesters is utilized in the fuel cell. The
system produces 225 kW for use on site, while waste
heat from the fuel cell exhaust is used to maintain
proper temperature for digester operation.
LACSD chose the use of biogas coupled with CHP to
conserve fossil fuel, reduce air emissions, and save
money. The CHP system reduces annual C02 and
nitrogen oxide emissions by 778 tons and 0.58 tons,
respectively, and saves LACSD approximately
$227,000 per year in energy costs.
-------�
What Resources Are Available?
Is My Facility a Good Candidate
for CHP?
• Do you have an influent flow rate greater than 5
MGD?
• Do you pay more than $0.06/kWh for electricity?
• Is reliable, high-quality power and thermal
energy important to you?
• Is it important to reduce energy costs and
increase the overall energy efficiency of your
wastewater treatment process?
• Do you want to increase your facility's
environmental performance?
If the answer is "yes" to two or more of these
questions, CHP can benefit your facility.
CHP technologies are flexible, providing a wide
range of sizing options. The right CHP system for
your WWTF will be determined through
consultations and analyses, which will include a
site-specific evaluation of your facility's electricity
and thermal loads.
Technical Assistance
The CHP Partnership has developed services and
tools to assist those considering implementing CHP
at their facilities. Visit the Streamlining Project
Development pages of the Partnership's Web site at
www.epa.gov/chp/proiect-development/index.html to
learn more about the CHP project development
process, whom to involve on your CHP project
team, typical options for system financing, and other
services EPA provides.
Project Resources
Take advantage of the Partnership's up-to-date lists
of state and federal incentives (e.g., rebates, tax
credits, environmental revenue streams) for CHP,
along with lists of regulatory rules and rates that are
advantageous to clean distributed generation. This
information is updated monthly at www.epa.gov/
chp/funding/index .html.
Pubiic Recognition
Through the ENERGY STAR CHP Awards, EPA
recognizes highly efficient CHP projects that achieve
fuel and emission savings over comparable state-of-
the-art separate heat and power. The Partnership
accepts Award applications continuously and
presents these awards at key events. For more
information on applying for an ENERGY STAR
CHP Award for your WWTF, visit www.epa.gov/
chplpublic-recognitionlindex.html.
What's the Next Step?
EPA is available to answer your questions and
provide specific technical support for your project.
For information on how EPA can support your
evaluation and implementation of CHP, contact
Neeharika Naik-Dhungel at (202) 343-9553 or
e-mail her at naik-dhungel.neeharika@epa.gov.
About the EPA CHP Partnership
The CHP Partnership is a voluntary program ^
designed to foster cost-effective CHP projects.
Through the Partnership, EPA engages energy &ERA combined^heatand
users, the CHP industry, state and local
governments, and other stakeholders in cooperative relationships to
expand the use of CHP Information about the Partnership's services and
program offerings is available on its Web site: www.epa.gov/chp.
CHP
Last updated March 5, 2008
-------� |