THE ENVIRONMENTAL TECHNOLOGY VERIFICATION
PROGRAM
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ETV Joint Verification Statement
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U.S. Environmental Protection Agency Pjjlfjruf rprilODJ^ Wll Ji
TECHNOLOGY TYPE: ON-BOARD EMISSIONS MONITOR
APPLICATION: MEASURING VEHICLE EXHAUST EMISSIONS
TECHNOLOGY NAME: REMOTE (Real-world Emissions Monitoring On-board
Testing Equipment) On-board Emissions Monitor
COMPANY: Clean Air Technologies International Inc.
ADDRESS: 819 East Ferry Street PHONE: 1-716-893-5800
Buffalo, NY 14211 FAX: 1-716-893-0547
WEB SITE: http://www.cleanairt.com
E-MAIL: info@cleanairt.com
The U.S. Environmental Protection Agency (EPA) supports the Environmental Technology Verification (ETV)
Program to facilitate the deployment of innovative or improved environmental technologies through
performance verification and dissemination of information. The goal of the ETV Program is to further
environmental protection by substantially accelerating the acceptance and use of improved and cost-effective
technologies. ETV seeks to achieve this goal by providing high-quality, peer-reviewed data on technology
performance to those involved in the design, distribution, financing, permitting, purchase, and use of
environmental technologies.
ETV works in partnership with recognized standards and testing organizations, with stakeholder groups
(consisting of buyers, vendor organizations, and permitters), and with individual technology developers. The
program evaluates the performance of innovative technologies by developing test plans that are responsive to the
needs of stakeholders, conducting field or laboratory tests (as appropriate), collecting and analyzing data, and
preparing peer-reviewed reports. All evaluations are conducted in accordance with rigorous quality assurance
(QA) protocols to ensure that data of known and adequate quality are generated and that the results are
defensible.
The Advanced Monitoring Systems (AMS) Center, one of seven technology areas under ETV, is operated by
Battelle in cooperation with EPA's National Exposure Research Laboratory. The AMS Center has recently
evaluated the performance of an on-board emissions monitor used to measure vehicle exhaust emissions. This
verification statement provides a summary of the test results for the Real-world Emissions Monitoring On-board
Testing Equipment (REMOTE) on-board emissions monitor (OEM).
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VERIFICATION TEST DESCRIPTION
The verification was based on evaluating the performance of the REMOTE OEM under realistic operating
conditions. Duplicate REMOTE OEMs were operated side-by-side throughout all portions of the verification test,
which was conducted between May 7 and May 10, 2001, to estimate measurement precision. (A delay by the
OEM vendor postponed preparation of this report until early 2003.) Overall accuracy (bias and precision) of the
REMOTE OEM relative to emission measurements made by standard emission test equipment with a chassis
dynamometer was assessed in three test vehicles: Chevrolet Cavalier (1998, 2.2 L, 4 cylinder, 22,697 miles);
Chevrolet Tahoe (1997, 5.7 L, 8 cylinder, 63,857 miles); and Ford Taurus (1998, 3.0 L, 6 cylinder, 33,981 miles).
Reliability and ease of use also were assessed. Two REMOTE OEMs (OEM A and B) were operated on two test
cycles: the Federal Test Procedure (FTP) and the US06 cycle. In phase one of testing, three dynamometer test
cycles were conducted with each of the three vehicles, to test whether interactions between vehicle type and test
cycle have an impact on observed bias and precision. Four additional US06 cycles were performed on the
Cavalier. Three of these were conducted at 30, 75, and 100°F, respectively, to assess the effect of temperature on
OEM performance. The fourth US06 cycle was performed at 100°F with the Cavalier's air conditioner operating
at maximum capacity to assess whether using vehicle accessories influences the performance of the REMOTE
OEM. For all of the dynamometer test cycles, vehicle emissions were measured using flame ionization detection
(FID) for hydrocarbons (HC), non-dispersive infrared spectroscopy for carbon monoxide (CO) and carbon
dioxide (C02), and chemiluminescence for nitrogen oxides (NOx). In phase two of testing, the duplicate
REMOTE OEMs were installed in each test vehicle, and each vehicle was driven for approximately 15 minutes
over each of two routes: one that was predominantly stop-and-go traffic and one that was predominantly
sustained high-speed traffic. Second-by-second on-road data for HC, CO, NOx, and C02 were collected by the
duplicate REMOTE OEMs and used to visually compare the response of the REMOTE OEMs.
QA oversight of verification testing was provided by Battelle. Battelle QA staff conducted a technical systems
audit, a performance evaluation audit, and a data quality audit of 10% of the test data.
TECHNOLOGY DESCRIPTION
The following description of the REMOTE OEM was provided by the vendor and does not represent verified
information.
The REMOTE OEM is capable of measuring exhaust emissions from electronically controlled light-duty
passenger vehicles and light trucks of model year 1996 and newer with on-board diagnostics (OBD) ports. The
REMOTE OEM, using infrared techniques to measure CO, C02, and HC and electrochemical techniques to
measure NOx, is designed to provide real-time on-road emissions measurements and to derive test- and bag-
averaged emissions during standard vehicle test cycles, as used in vehicle dynamometer testing. The REMOTE
OEM provides second-by-second total HC, CO, C02, NOx, and 02 readings and total mass emissions summaries
for individual test cycles. It includes a touch-screen computer and comes standard in a powder-coated aluminum
housing.
The REMOTE OEM is installed in the passenger seat of the vehicle and connects to the vehicle in three locations.
The cigarette lighter provides the power in the majority of installations (auxiliary battery optional), the OBD port
under the dashboard provides the engine data stream, and the sample exhaust probe is inserted into the tailpipe.
VERIFICATION OF PERFORMANCE
Bias: Table 1 shows the results from the bias calculations. Considering all test data combined, the REMOTE
OEM exhibited biases ranging between 34.8 and -11.2%. Considering all test data organized by test vehicle and
test cycle, the REMOTE OEM exhibited biases for NOx and CO ranging between -0.14 and 21.3% for OEM A
and between -1.56 and 16.5% for OEM B. Biases for HC and C02 ranged between 8.09 and 63.9% for OEM A
and between 9.53 and 44.7 % for OEM B.
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Table 1. Percent Bias Values and Confidence Intervals for REMOTE OEM
Bias
Pooling
OEM A
OEM B
HC
CO
NOx
co2
HC
CO
NOx
co2
Total Test
% Bias
34.8
-7.95
-11.2
16.5
21.5
-2.07
1.96
22.2
±
9.56
1.80
3.35
2.50
4.82
2.84
3.90
3.60
Cavalier
% Bias
63.9
-0.14
-1.93
29.5
24.9
5.40
16.5
44.7
±
15.8
1.19
5.33
3.39
3.56
2.98
6.01
4.11
Tahoe
% Bias
11.2
-12.9
-10.3
8.09
20.1
-7.79
-3.04
9.53
±
2.22
2.09
1.46
0.73
4.97
3.12
1.64
0.70
Taurus
% Bias
29.4
-10.8
-21.3
11.8
19.4
-3.80
-7.58
12.3
±
2.42
1.05
1.42
0.39
6.12
1.94
1.32
0.34
FTP cycles
% Bias
53.9
-7.47
-18.1
19.2
20.6
-1.56
-4.57
25.2
±
12.8
1.40
2.05
3.29
3.48
2.63
1.98
3.78
US06 cycles
% Bias
15.8
-8.42
-4.23
13.7
22.4
-2.57
8.48
19.2
±
2.62
2.22
4.07
1.39
6.11
3.19
5.06
3.57
Note: Bold rows show results by vehicle.
Unit-to-Unit Precision: Table 2 shows the results from the precision calculations. In nearly all cases,
coefficients of variation (CVs) of the duplicate OEMs for all the emissions measured from all vehicles were less
than 5%. The largest CV was reported for HC during the Cavalier test at 8.97 ± 11.6% over a tested range of 0.05
to 0.47 grams per mile (g/mi). The smallest CV was seen for CO during the Cavalier test at 1.11 ± 1.43% over a
tested range of 0.70 to 12.0 (g/mi).
Reliability and Ease of Use: All data were collected as expected, and the REMOTE OEMs had no downtime
during the tests. The REMOTE OEMs were installed in the vehicles with no difficulty for the on-road testing.
Operation over a temperature range of 30 to 100°F had no adverse effect on OEM reliability, and operation over
this range showed no consistent effect of temperature on OEM bias for any of the measured species.
Other Unit-to-Reference Method Comparisons: The second-by-second data for the reference method and the
REMOTE OEM illustrate close agreement. A time delay between the reference monitors and the REMOTE OEM
was due to the different lag times in sampling by the reference monitors.
The linear regression of OEM and FTP bag results shows that, except for the OEM A HC results (r2 of 0.54),
both OEM A and OEM B had coefficients of determination greater than 0.86 for all four emitted species. The
slopes of the linear regressions for OEM A and OEM B relative to the FTP bag results were between 0.97 and
1.03 for C02 over a tested range of 300 to 620 (g/mi). The slopes were between 0.95 and 1.05 for CO over a
tested range
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Table 2. Unit-to-Unit Precision Results and Confidence Intervals for REMOTE OEM
Precision
Pooling
HC
CO
NOx
co2
Total Test
%CV
6.04
2.54
4.03
3.17
±
2.66
1.12
1.78
1.40
Cavalier
%CV
8.97
1.11
4.73
4.89
±
11.6
1.43
6.10
6.30
Taurus
%CV
4.77
2.32
4.59
1.99
±
6.15
2.99
5.92
2.57
Tahoe
%CV
2.50
3.57
2.29
1.50
±
3.23
4.60
2.96
1.93
FTP Cycles
%CV
7.90
2.05
4.4
3.71
±
6.44
1.67
3.58
3.02
US06 Cycles
%CV
4.77
2.32
4.59
1.99
±
2.65
2.40
2.95
2.05
of 0 to 13 (g/mi) and between 0.92 and 1.03 for NOx over a tested range of 0 to 1.4 (g/mi). However, the slopes
of the linear regressions for OEM A and OEM B were between 0.62 and 0.79 for HC over a tested range of 0 to
1 (g/mi). The HC results may be because of the different analytical techniques used (i.e., infrared absorption in
the OEM measurements, FID in the reference measurements).
signed bv Gabor J. Kovacs 7/16/03
Gabor J. Kovacs Date
Vice President
Environmental Sector
Battelle
signed bv Gary J. Foley 9/4/03
Gary J. Foley Date
Director
National Exposure Research Laboratory
Office of Research and Development
U.S. Environmental Protection Agency
NOTICE: ETV verifications are based on an evaluation of technology performance under specific, predetermined
criteria and the appropriate quality assurance procedures. EPA and Battelle make no expressed or implied
warranties as to the performance of the technology and do not certify that a technology will always operate as
verified. The end user is solely responsible for complying with any and all applicable federal, state, and local
requirements. Mention of commercial product names does not imply endorsement.
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