ETV Joint Verification Statement Chemiluminescent Ozone Analyzer Jsc Optec Ltd.

THE ENVIRONMENTAL TECHNOLOGY VERIFICATION
PROGRAM
SERA ElV
U.S. Environmental Protection Agency
Baireiie
The Business of Innovation
ETV Joint Verification Statement

TECHNOLOGY TYPE: CHEMILUMINESCENT OZONE ANALYZER
APPLICATION: MEASURING OZONE IN AMBIENT AIR
TECHNOLOGY NAME: 3.02 P-A
COMPANY: JSC OPTEC Ltd.
ADDRESS: 1985 West Henderson Road PHONE: (614) 477-1020
Columbus, Ohio 43220 FAX: (614) 486-2693
WEB SITE: www.optec-corp.com
E-MAIL: mkozliner@gmail.com
The U.S. Environmental Protection Agency (EPA) has established 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 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. Information and ETV documents are available at
www.epa.gov/etv.
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 five verification centers under ETV, is
operated by Battelle in cooperation with EPA's National Exposure Research Laboratory. The AMS
Center evaluated the performance of a chemiluminescent ozone analyzer, a continuous monitor for
determining ozone in air. This verification statement provides a summary of the test results for the JSC
Optec Ltd. 3.02 P-A ozone analyzer.

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VERIFICATION TEST DESCRIPTION
The objective of this verification test was to evaluate the 3.02 P-A performance for determining ozone
in air in part by comparing it to the response of the ultraviolet (UV)-absorption Federal Equivalent
Method (FEM) for ozone. The specific commercial FEM monitor used in this test was the Thermo
Environmental Model 49 C (FEM EQOA-880-047). The verification test was conducted between
June 13 and June 28, 2007 at Battelle laboratories located in Columbus, Ohio.
The response of the 3.02 P-A to ozone in ambient air and at low (< 5%) and high (~ 80%) relative
humidity (RH) in clean air was used to evaluate for accuracy, linearity, interference effects,
comparability to the FEM, data completeness, and operational factors. Two 3.02 P-A instruments
were operated, one with no additional equipment and per the manufacturer's recommendations, and
the other with a Nafion humidity equilibration tube added to the monitor's inlet. Results from the first
unit are the primary results of this verification. The Nafion tube was added to the second unit to assess
the impact of humidity and humidity control on the 3.02 P-A response. Both 3.02 P-A units relied
entirely on their internal automated calibration systems, as specified by the vendor.
Accuracy was calculated from the response of the 3.02 P-A with respect to different levels of ozone
challenges, established either by a known ozone source or by FEM response. Linearity was assessed by
a linear regression analysis using the FEM reading as the independent variable and the response of the
3.02 P-A as the dependent variable. Interferences tested were naphthalene, o-nitrophenol, and p-
tolualdehyde, each at approximately 6 to 15 parts per billion by volume (ppbv) in both dry and
humidified air; mercury vapor at 630 nanograms per cubic meter (ng/m3) in dry air and 54 ng/m3 in
humidified air; nitrogen dioxide (NO2) at up to 200 ppbv in humidified air; and a 17-component mix of
volatile organic compounds at up to 593 ppbv total concentration in humidified air. Interference effects
were calculated in terms of the ratio of the 3.02 P-A response to the actual concentration of the
interferent. Comparability was assessed by comparing the 3.02 P-A response to that of the FEM during
generation of ozone in photochemical chamber tests at 80% RH, and in ambient ozone monitoring. Data
completeness was assessed as the percentage of maximum data return achieved by the 3.02 P-A over the
test period. Operational factors were evaluated by means of observations during testing and records of
needed maintenance, vendor activities, and expendables use.
QA oversight of verification testing was provided by Battelle and EPA. Battelle QA staff conducted a
technical systems audit, a performance evaluation audit, and a data quality audit of 10% of the test
data. EPA QA staff also conducted an on-site technical systems audit. This verification statement, the
full report on which it is based, and the test/QA plan for this verification test are all available at
www. epa. gov/etv/centers/center 1 .html.
TECHNOLOGY DESCRIPTION
The following description of the 3.02 P-A was provided by the vendor and does not represent verified
information.
The 3.02 P-A chemiluminescent ozone analyzer combines a solid phase chemiluminescence approach
with menu-driven software with diagnostic functions. It is designed to measure ozone concentrations in
ambient air.
The Model 3.02 P-A is designed to have the following features:
- Automatic continuous measurements
- Automatic internal calibration

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- High sensitivity
- Fast response time
- Linearity
- Menu driven software
- Digital display
- Electronic data output
The 3.02 P-A detects ambient ozone by means of its chemical reaction with a solid-phase reactant of
proprietary composition, resulting in the emission of light with peak intensity near 560 nm wavelength.
The emitted light is detected by a photomultiplier tube, and converted to a digital signal that is linearly
proportional to the gaseous ozone concentration. An internal pump draws sample air through two
alternate flow paths: in the measurement path sample air passes directly into contact with the solid-
phase reactant, whereas in the zeroing path ozone in the sample air is removed by a selective scrubber
element before the air contacts the reactant. The 3.02 P-A thus measures ozone by comparison of the
signals from these two paths. An internal ozone generator (UV lamp) provides a calibration mixture to
the 3.02 P-A at 10-minute intervals, and the internal software automatically adjusts instrument
response with each calibration. The measured ozone concentration is displayed on the front panel of
the 3.02 P-A and can be transmitted via analog outputs. The estimated price of the base model analyzer
is $5,000.
VERIFICATION RESULTS
The addition of the Nafion humidity equilibration tube to the inlet of one unit of the 3.02 P-A reduced
the performance of that unit in nearly all performance measures. The performance of the 3.02 P-A unit
operated normally is summarized below.
Accuracy: The accuracy of the Optec 3.02 P-A ozone analyzer was assessed in terms of percent
recovery (%R). The 3.02 P-A averaged a %R of 85.4 to 107.7% at concentrations of 98 to 289 parts
ppbv when ozone was delivered to the analyzer in dry air directly from a calibration source. When
ozone was added to clean air in the test chamber in stepwise concentrations of 51 to 257 ppbv at high
humidity (~ 80% RH), the average %R was 93.2 to 110%. In the corresponding chamber test at
concentrations of 69 to 260 ppbv in dry test conditions (< 5% RH), the average %R of the 3.02 P-A was
83.4 to 88.3%.
Linearity: Linearity was evaluated in terms of slope, intercept, and coefficient of determination (r2).
The linearity of the 3.02 P-A under ~ 80% RH test conditions showed a slope of 0.914, an intercept of
6.2 ppbv, and an r2 value of 0.998 over a concentration range of 51 to 257 ppbv. The linearity of the
3.02 P-A in < 5% RH conditions showed a slope of 0.838, an intercept of 1.0 ppbv, and an r2 value of
0.999 over a concentration range of 69 to 260 ppbv.
Interference Effects: None of the interferents tested caused any response on the 3.02 P-A. As a result,
all interferent response ratios were zero.
Comparability: Comparability was evaluated in terms of the slope, intercept, and r2 of a linear
regression of 3.02 P-A readings against FEM readings. The comparison between the 3.02 P-A and FEM
during the photochemical ozone test with high precursor concentrations resulted in a slope of 0.815, an
intercept of 4.1 ppbv, and an r2 value of 0.999 over an ozone concentration range of 20 to 130 ppbv.
The same comparison in the photochemical test with lower precursor concentrations resulted in a slope
of 0.941, an intercept of -1.2 ppbv, and an r2 value of 0.997 over an ozone concentration range of 20 to
80 ppbv. The comparison of the 3.02 P-A and FEM readings over the four day ambient monitoring

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period resulted in a slope of 0.998, an intercept of 0.19 ppbv, and an r2 value of 0.995 over an ozone
concentration range of 3 to 80 ppbv. The average relative percent difference of the 3.02 P-A with
respect to the FEM in these three comparisons was -14.2%, -8.0%, and 0.3%, respectively.
Data Completeness: Data completeness for the 3.02 P-A was 100%, based on its operation over a total
of 6.07 test days during a 16 day operational period. Considering only those 6.07 days on which the
3.02 P-A was tested, there were 4.6 days of ambient monitoring, 0.27 days spent in calibration/
zeroing/other instrument checks, and 1.2 days total spent conducting measurements in the environmental
chamber. Both 3.02 P-A units also operated without problems throughout the 16-day period in which
those 6 test days occurred.
Operational Factors: The Optec 3.02 P-A was operated on a 220 V to 120 V converter during testing.
When the 3.02 P-A was turned on, it took approximately 1 hour for the 3.02 P-A to stabilize and it then
remained functional throughout the entire 16-day test period. No repair was needed during the test and
the need for vendor assistance was minimal. The analyzer calibrated itself internally every ten minutes.
The ozone measurements were displayed on the front panel in parts per million. An operating manual
was provided and although translated from Russian to English, the manual was somewhat difficult to
understand. The monitor includes an audible alarm which sounds when ozone readings exceed the
maximum full scale value (i.e., above about 250 ppbv).
Signed by Martin E. Toomaiian 03/06/08 Signed by Sally Gutierrez 04/15/08
Martin E. Toomajian Date Sally Gutierrez Date
Manager Director
Chemical, Environmental, and National Risk Management Research Laboratory
Materials Operations Office of Research and Development
Battelle 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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