EPA 600/R-11/018 | April 2011 | www.epa.gov/ord
United States
Environmental Protection
Agency
CS Unitec ETR180 Circular
Sander for Radiological
Decontamination
TECHNOLOGY EVALUATION REPORT
Office of Research and Development
National Homeland Security Research Center
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*»EPA
United States
Environmental Protection
Agency
Office of Research and
Development
Washington, D.C. 20460
EPA 600-R-11-018
February 2011
www.epa.gov/nhsrc
Technology Evaluation Report
CS Unitec ETR180 Circular
Sander for Radiological
Decontamination
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EPA 600-R-11-018
February 2011
Technology Evaluation Report
CS Unitec ETR 180 Circular Sander
for Radiological Decontamination
John Drake
Task Order Project Officer
National Homeland Security Research Center
Office of Research and Development
U.S. Environmental Protection Agency
26 Martin Luther King Drive
Cincinnati, OH 45268
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Disclaimer
The U.S. Environmental Protection Agency (EPA), through its Office of Research and
Development's National Homeland Security Research Center, funded and managed this
technology evaluation through a Blanket Purchase Agreement under General Services
Administration contract number GS23F0011L-3 with Battelle. This report has been peer
and administratively reviewed and has been approved for publication as an EPA
document. Mention of trade names or commercial products does not constitute
endorsement or recommendation for use of a specific product.
Questions concerning this document or its application should be addressed to:
John Drake
National Homeland Security Research Center
Office of Research and Development
U.S. Environmental Protection Agency
26 West Martin Luther King Dr.
Cincinnati, OH 45268
513-569-7164
drake.john@epa.gov
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Foreword
The Environmental Protection Agency (EPA) holds responsibilities associated with
homeland security events: EPA is the primary federal agency responsible for
decontamination following a chemical, biological, and/or radiological (CBR) attack. The
National Homeland Security Research Center (NHSRC) was established to conduct
research and deliver scientific products that improve the capability of the Agency to carry
out these responsibilities.
An important goal of NHSRC's research is to develop and deliver information on
decontamination methods and technologies to clean up CBR contamination. When
directing such a recovery operation, EPA and other stakeholders must identify and
implement decontamination technologies that are appropriate for the given situation. The
NHSRC has created the Technology Testing and Evaluation Program (TTEP) in an effort
to provide reliable information regarding the performance of homeland security related
technologies. TTEP provides independent, quality assured performance information that
is useful to decision makers in purchasing or applying the tested technologies. TTEP
provides potential users with unbiased, third-party information that can supplement
vendor-provided information. Stakeholder involvement ensures that user needs and
perspectives are incorporated into the test design so that useful performance information
is produced for each of the tested technologies. The technology categories of interest
include detection and monitoring, water treatment, air purification, decontamination, and
computer modeling tools for use by those responsible for protecting buildings, drinking
water supplies and infrastructure, and for decontaminating structures and the outdoor
environment. Additionally, environmental persistence information is also important for
containment and decontamination decisions.
NHSRC is pleased to make this publication available to assist the response community to
prepare for and recover from disasters involving CBR contamination. This research is
intended to move EPA one step closer to achieving its homeland security goals and its
overall mission of protecting human health and the environment while providing
sustainable solutions to our environmental problems.
Jonathan G. Herrmann, Director
National Homeland Security Research Center
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Acknowledgments
Contributions of the following individuals and organizations to the development of this document
are gratefully acknowledged.
United States Environmental Protection Agency (EPA)
John Drake
Emily Snyder
Sang Don Lee
Lukas Oudejans
David Musick
Kathy Hall
Eletha Brady-Roberts
Jim Mitchell
University of Tennessee
Dr. Howard Hall
United States Department of Energy's Idaho National Laboratories
Battelle Memorial Institute
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Contents
Disclaimer i
Foreword ii
Acknowledgments iii
Abbreviations/Acronyms vi
Executive Summary vii
1.0 Introduction 1
2.0 Technology Description 3
3.0 Experimental Details 4
3.1 Experiment Preparation 4
3.1.1 Concrete Coupons 4
3.1.2 Coupon Contamination 4
3.1.3 Measurement of Activity on Coupon Surface 5
3.1.4 Surface Construction Using Test Stand 6
3.2 Evaluation Procedures 6
4.0 Quality Assurance/Quality Control 8
4.1 Intrinsic Germanium Detector 8
4.2 Audits 9
4.2.1 Performance Evaluation Audit 9
4.2.2 Technical Systems Audit 9
4.2.3 Data Quality Audit 10
4.3 QA/QC Reporting 10
5.0 Evaluation Results 11
5.1 Decontamination Efficacy 11
5.2 Deployment and Operational Factors 13
6.0 Performance Summary 15
6.1 Decontamination Efficacy 15
6.2 Deployment and Operational Factors 15
7.0 References 16
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Figures
Figure 2-1. CS Unitec ETR180 (left) and sanding disk (right) 3
Figure 3-1. Demonstration of contaminant application technique 5
Figure 3-2. Containment tent: outer view (left) and inner view with test stand containing
contaminated coupons (right) 6
Figure 5-1. Test coupon surfaces before (left) and after (right) sanding with the
ETR180 13
Tables
Table 3-1. Characteristics of Portland Cement Clinker Used to Make Concrete
Coupons 4
Table 4-1. Calibration Results - Difference from Th-228 Calibration Energies 8
Table 4-2. NIST-Traceable Eu-152 Activity Standard Check 9
Table 5-1. Decontamination Efficacy Results 13
Table 5-2. Operational Factors Gathered from the Evaluation 14
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Abbreviations/Acronyms
ANSI American National Standards Institute
ASTM American Society for Testing and Materials
BQ Becquerel
Cs cesium
cfm cubic feet per minute
cm centimeters
cm2 square centimeters
DARPA Defense Advanced Research Projects Agency
DF decontamination factor
DHS U.S. Department of Homeland Security
DOD Department of Defense
EPA U.S. Environmental Protection Agency
ETR180 CS Unitec ETR180
Eu europium
HEPA High Efficiency Particle Air
IEEE Institute of Electrical and Electronics Engineers
INL Idaho National Laboratory
keV kilo electron volts
kg kilogram
mg milligram
mL milliliter
L liter
m meter
m2 square meters
|iCi microCurie
NHSRC National Homeland Security Research Center
NIST National Institute of Standards and Technology
ORD Office of Research and Development
%R percent removal
RH relative humidity
PE performance evaluation
QA quality assurance
QC quality control
QMP quality management plan
RDD radiological dispersion device
RML Radiological Measurement Laboratory
RSD relative standard deviation
TSA technical systems audit
TTEP Technology Testing and Evaluation Program
Th thorium
V volt
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Executive Summary
The U.S. Environmental Protection Agency's (EPA) National Homeland Security
Research Center (NHSRC) is helping to protect human health and the environment from
adverse impacts resulting from acts of terror by carrying out performance tests on
homeland security technologies. Through its Technology Testing and Evaluation
Program (TTEP), NHSRC evaluated the performance of the CS Unitec ETR180
(hereafter referred to as the ETR180) and its ability to remove radioactive cesium (Cs)-
137 from the surface of unpainted concrete.
Experimental Procedures. The ETR180 is a lightweight disk sander with a dust hood
and configuration that allows sanding all the way to a wall edge. Bound Cs can be
removed from a surface by sanding away the surface layer. Eight 15 centimeter (cm) x 15
cm unpainted concrete coupons were contaminated with approximately 1 microCurie
(|iCi) of Cs-137 per coupon and allowed to age for seven days. The amount of
contamination deposited on each coupon was measured using gamma spectroscopy. The
eight contaminated coupons were placed in a test stand (along with one uncontaminated
blank coupon) that was designed to hold nine concrete coupons in a vertical orientation to
simulate the wall of a building. Each coupon was sanded with the ETR180, and the
decontamination efficacy was determined by calculating both a decontamination factor
(DF) and percent removal (%R). Important deployment and operational factors were also
documented and reported.
Results. The decontamination efficacy attained by the ETR180 was evaluated for each
concrete coupon used during the evaluation. When the decontamination efficacy metrics
(%R and DF) of the eight contaminated coupons were averaged together, the average %R
for the ETR180 was 54 ± 10% and the average DF was 2.3 ± 0.7. Hypothesis testing was
performed to determine if there were significant differences between the %R values
determined for the coupons in each row (top, middle, and bottom) of the test stand. No
differences were found.
Following the manufacturer's recommendations, the ETR180 was used with 24 grit
sanding disks. The ETR180 could decontaminate a vertical surface at a rate of
approximately 1.4 square meters (m2) per hour with minimal surface destruction and
minimal secondary waste. The texture of the coupon surface may be important to the
efficacy of the ETR180 and similar radiological decontamination technologies. It was
observed that because sanding disks do not cut into concrete surfaces, uneven concrete
surfaces may prevent the sanding disk from reaching some areas of the concrete surfaces.
A very limited evaluation of cross-contamination was performed. During an actual
decontamination of a vertical surface, the higher elevation surfaces would likely be
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decontaminated first, possibly exposing the lower elevation surfaces to secondary
contamination. To simulate an actual scenario, one uncontaminated coupon was placed
in the bottom row of the test stand and decontaminated using the ETR180 in the same
way as the other coupons. Following decontamination, this uncontaminated coupon did
not exhibit measurable activity, suggesting that cross contamination was minimal.
Overall, the vacuum shroud was effective at containing the secondary waste. There was
very little dust visible during the evaluation and very little remaining on the floor in front
of the test stand following the evaluation. In addition, the radiological control technicians
did not find any measurable airborne contamination through analysis of air filters
sampled near the test stand. The dust collected by the vacuum was not analyzed for
gamma radiation.
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1.0 Introduction
The U.S. Environmental Protection Agency's (EPA) National Homeland Security
Research Center (NHSRC) is helping to protect human health and the environment from
adverse effects resulting from acts of terror. NHSRC is emphasizing decontamination
and consequence management, water infrastructure protection, and threat and
consequence assessment. In doing so, NHRSC is working to develop tools and
information that will improve the ability of operational personnel to detect the intentional
introduction of chemical, biological, or radiological contaminants on or into buildings or
water systems, to contain or mitigate these contaminants, to decontaminate affected
buildings and/or water systems, and to dispose of contaminated materials resulting from
clean-ups.
NHSRC, through its Technology Testing and Evaluation Program (TTEP), works in
partnership with recognized testing organizations; stakeholder groups consisting of
buyers, vendor organizations, and permitters; and through the participation of individual
technology developers in carrying out performance tests on homeland security
technologies. The program evaluates the performance of homeland security technologies
by developing evaluation plans that are responsive to the needs of stakeholders,
conducting tests, 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 high quality are generated and that the results are
defensible. TTEP provides high-quality information that is useful to decision makers in
purchasing or applying the evaluated technologies and in planning clean-up operations.
TTEP provides potential users with unbiased, third-party information that can supplement
vendor-provided information. Stakeholder involvement ensures that user needs and
perspectives are incorporated into the evaluation design so that useful performance
information is produced for each of the evaluated technologies.
Under TTEP, NHSRC evaluated the performance of the CS Unitec (Norwalk, CT)
ETR180 (hereafter referred to as the ETR180) in removing radioactive isotope cesium
(Cs)-137 from concrete. A peer-reviewed test/QA plan was developed according to the
requirements of the quality management plan (QMP) for TTEP. The evaluation generated
the following performance information:
Decontamination efficacy, defined as the extent of radionuclide removal following
use of the ETR180, and the possibility of cross-contamination.
Deployment and operational factors, including the approximate rate of surface area
decontamination, applicability to irregular surfaces, skilled labor requirement, utility
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requirements, portability, secondary waste management, and technology cost.
This evaluation took place from August 11, 2009 until October 13, 2009. All of the
experimental work took place in a radiological contamination area at the U.S. Department
of Energy's Idaho National Laboratory (INL). This report describes the quantitative
results and qualitative observations gathered during the evaluation of the ETR180. The
contractor, Battelle, and EPA were responsible for QA oversight. The Battelle QA
Manager conducted a technical systems audit (TSA) during the evaluation as well as a
data quality audit of the evaluation data.
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2.0 Technology Description
The following description of the ETR180 is based on information provided by the vendor
and was not verified during this evaluation.
ETR180 is a lightweight (3 kilogram, kg) circular sander with a variable speed motor, a
dust shroud, and a configuration to allow sanding all the way to a wall edge. The ETR180
is powered by standard 110 volt (V) electricity; according to vendor specifications, it
operates at approximately 1,450 revolutions per minute. The handle can be adjusted for
right- and left-handed operators. The dust shroud allows dust extraction over the bnish
rim and through the punched sanding disk and base plate. The ETR180 comes with a
centering tool for attaching the sanding disks, which are centered for balanced and
smooth operation. The largest sanding disk the unit can use is 18 centimeters (cm) in
diameter. During this evaluation, the ETR180 was used with 24 grit sanding disks
provided by the vendor. Several different disks of varying coarseness (grit density) were
evaluated during dry runs. A blue dye was applied to the coupon surface and allowed to
dry, after which the ETR180 was used with each disk. The 24 grit disks were chosen as
being aggressive enough to effectively clean the surface while being only minimally
destructive. Figure 2-1 shows the ETR180 being applied to a coupon surface during the
dry run using a 24 grit sanding disk.
In order to minimize the secondary waste produced during sanding, the ETR180 was
connected to a high efficiency particulate air (HEPA) vacuum (C83985-01, Minuteman,
Addison, IL) with a flow rate of 95 cubic feet per minute (cfm). CS Unitec did not
provide the vacuum, but approved of its use during this evaluation.
Figure 2-1. CS Unitec ETR180 (left) and sanding disk (right)
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3.0 Experimental Details
3.1 Experiment Preparation
3.1.1 Concrete Coupons
The concrete coupons were prepared from a single batch of concrete made from Type II
Portland cement. The ready-mix company (Burns Brothers Redi-Mix, Idaho Falls, ID)
that supplied the concrete for this evaluation provided the data which describe the cement
clinker used in the concrete mix. For Type II Portland cement, the American Society for
Testing and Materials (ASTM) Standard C 150-71 specifies that tricalcium aluminate
accounts for less than 8% of the overall cement clinker (by weight). The cement clinker
used for the concrete coupons was 4.5% tricalcium aluminate (Table 3-1). For Type I
Portland cement the tricalcium aluminate content should be less than 15%. Because Type
I and II Portland cements differ only in tricalcium aluminate content, the cement used
during this evaluation meets the specifications for both Type I and II Portland cements.
Table 3-1. Characteristics of Portland Cement Clinker
Used to Make Concrete Coupons
Cement Constituent Percent of Mixture
Tricalcium Silicate 57.6
Dicalcium Silicate 21.1
Tricalcium Aluminate 4.5
Tetracalcium Aluminoferrite 8.7
Minor Constituents 8.1
The wet concrete was poured into 0.9 meter (m) square plywood forms with the exposed
surface "floated" to allow the smaller aggregate and cement paste to float to the top, and
the concrete was then cured for 21 days. Following curing, the squares were cut to the
desired size with a laser-guided rock saw. For this evaluation, the "floated" surface of the
concrete coupons was used. The coupons were approximately 4 cm thick, 15 cm x 15 cm
square, and had a surface finish that was consistent across all the coupons. The concrete
was representative of exterior concrete commonly found in urban environments in the
United States as shown by INL under a previous project sponsored by the U.S.
Department of Defense (DOD), Defense Advanced Research Projects Agency (DARPA)
and U.S. Department of Homeland Security (DHS).2
3.1.2 Coupon Contamination
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Eight coupons were contaminated by spiking individually with 2.5 milliliters (mL) of
aqueous solution that contained 0.26 milligrams (mg)/liter (L) Cs-137 as a solution of
cesium chloride, corresponding to an activity level of approximately 1 microCurie (|iCi)
over the 225 square centimeters (cm2) surface. Application of the Cs-137 in an aqueous
solution was justified because even if Cs-137 were dispersed in a particle form following
a radiological dispersion device (RDD) or "dirty bomb" event, morning dew or rainfall
would likely occur before the surfaces could be decontaminated. In addition, from an
experimental standpoint, it is much easier to apply liquids, rather than dry particles,
homogeneously across the surface of the concrete coupons. The liquid spike was
delivered to each coupon using an aerosolization technique developed by INL (under a
DARPA/DHS project4) and described in detail in the test/QA plan. The coupons were
then allowed to age for seven days.
The aerosol delivery device was constructed of two syringes. The plunger and needle
were removed from the first syringe and discarded. Then, a compressed air line was
attached to the rear of the syringe. The second syringe contained the contaminant solution
and was equipped with a 27 gauge needle, which penetrated through the plastic housing
near the tip of the first syringe. Compressed air flowing at a rate of approximately 1 - 2 L
per minute created a turbulent flow through the first syringe. When the contaminant
solution in the second syringe was introduced, the solution became nebulized by the
turbulent air flow. A fine aerosol was ejected from the tip of the first syringe, creating a
controlled and uniform spray of fine liqui d droplets onto the coupon surface. The
contaminant spray was applied all the way to the edges of the coupon, which were taped
(after having previously been sealed with polyester resin) to ensure that the contaminant
was applied only to the surfaces of the coupons. The photographs in Figure 3-1 show this
procedure being performed using a nonradioactive, nonhazardous aqueous dye to
demonstrate that the 2.5 mL of contaminant solution is effectively distributed across the
surface of the coupon.
Figure 3-1. Demonstration of contaminant application technique.
3.1.3 Measurement of Activity on Coupon Surface
Gamma radiation from the surface of each concrete coupon was measured to quantify
contamination levels both before and after evaluation of the ETR180. These
measurements were made using an intrinsic, high purity germanium detector (Canberra
LEGe Model GL 2825R/S, Meriden, CT). After being placed in the detector, each
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coupon was measured until the average activity level of Cs-137 from the surface
stabilized to a relative standard deviation of less than 2%. Gamma-ray spectra acquired
from Cs-137 contaminated coupons were analyzed using INL Radiological Measurement
Laboratory (RML) data acquisition and spectral analysis programs. Radionuclide
activities on coupons were calculated based on efficiency, emission probability, and half-
life values. Decay corrections were made based on the date and the duration of the
counting period. Full RML gamma counting QA/quality control (QC), as described in
the test/QA plan, was employed and certified results were provided.
3.1.4 Surface Construction Using Test Stand
To evaluate the decontamination technologies on vertical surfaces (simulating walls), a
stainless steel test stand was fabricated that held three rows of three concrete coupons.
The test stand, approximately 9 feet (ft) x 9 ft, was erected within a containment tent. The
concrete coupons were placed into holders so their surfaces extended just beyond the
surface of the stainless steel face of the test stand. Eight of the nine coupons placed in the
test stand were contaminated with Cs-137, which has a half-life of 30 years. One
uncontaminated coupon was placed in the bottom row of the test stand and
decontaminated using the ETR180 in the same way as the other coupons. This coupon
was placed on the test stand to observe possible secondary contamination caused by the
decontamination process being conducted higher on the wall. Figure 3-2 shows the
containment tent and the test stand loaded with the concrete coupons.
Figure 3-2. Containment tent: outer view (left) and inner view with test stand
containing contaminated coupons (right).
3.2 Evaluation Procedures
The containment tent consisted of two rooms. One room contained the test stand to hold
the contaminated coupons; the other room (the shorter part of the tent as shown in Figure
3-2) held the vacuum. An opening in the tent wall between the two rooms was just large
enough to allow the vacuum hose connected to the ETR180 to pass through. The tent
opening was taped closed around the hose prior to the start of the evaluation.
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The nine concrete coupons in the test stand were sanded using the ETR180 starting with
the top row and working from left to right, then proceeding to the middle and bottom
rows. The coupons were sanded in this manner to simulate an approach that would likely
be taken in an actual decontamination event, where higher wall surfaces would be
decontaminated first because of the possibility of secondary contamination lower on the
wall. The ETR180 was connected to the vacuum and used at full power for one minute on
each coupon. The temperature and relative humidity (RH) were recorded before (21.1°C,
32% RH) and after (21.4°C, 32% RH) the approximately one hour test. These conditions
did not vary significantly in the room where the evaluation was performed.
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4.0 Quality Assurance/Quality Control
QA/QC procedures were performed in accordance with the program QMP and the
test/QA plan for this evaluation.
4.1 Intrinsic Germanium Detector
The germanium detector was calibrated once each week. The calibration was performed
in accordance with standardized procedures from the American National Standards
Institute (ANSI) and the Institute of Electrical and Electronics Engineers (IEEE).3 In
brief, detector energy was calibrated using thorium (Th)-228 daughter gamma rays at
238.6, 583.2, 860.6, 1620.7, and 2614.5 kilo electron volts (keV). This calibration was
performed three times during the overall project and documented by the RML. Table 4-1
gives the difference between the known energy levels and those measured following
calibration. The energies were compared to the previous 30 calibrations to confirm that
the results were within three standard deviations of the previous calibration results. All
the calibrations fell within this requirement.
Table 4-1. Calibration Results - Difference from Th-228 Calibration Energies
Calibration Energy Levels (keV)
Date
Energy 1
238.632
Energy 2
583.191
Energy 3
860.564
Energy 4
1620.735
Energy 5
2614.533
8-25-2009
-0.005
0.014
-0.031
-0.199
0.031
9-21-2009
-0.003
0.009
-0.040
-0.125
0.015
10-13-2009
-0.003
0.008
-0.011
-0.180
0.020
Gamma ray counting was continued on each coupon until the activity level of Cs-137 on
the surface had a relative standard deviation (RSD) of less than 2%. This RSD occurred
within the initial 1 hour of counting for all the coupons measured during this evaluation.
The final activity assigned to each coupon was a compilation of information obtained
from all components of the electronic assemblage that comprise the "gamma counter,"
including the raw data and the spectral analysis described in Section 3.1.3. Final spectra
and all data that comprise the spectra were sent to a data analyst who independently
confirmed the "activity" number arrived at by the spectroscopist. When both the
spectroscopist and an expert data analyst independently arrived at the same value the data
were considered certified. This process defines the full gamma counting QA process for
certified results.
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The background activity of the concrete coupons was determined by analyzing nine
arbitrarily selected coupons from the stock of concrete coupons used for this evaluation.
The ambient activity level of these coupons was measured for at least two hours. No
activity was detected above the minimum detectable level of 2xl0"4 |iCi on these
coupons. Because the background activity was not detectable (and the detectable level
was more than 2,500 times lower than the post-decontamination activity levels), no
background subtraction was required.
Throughout the evaluation, a second measurement was taken on 10 coupons in order to
provide duplicate measurements to evaluate the repeatability of the instrument. Half of
the duplicate measurements were performed after contamination prior to application of
the decontamination technology and half were performed after decontamination. Five of
the duplicate pairs showed no difference in activity levels between the two
measurements; the other five duplicate pairs had a difference of 2% between the two
measurements, within the acceptable difference of 5%.
4.2 Audits
4.2.1 Performance Evaluation Audit
RML performed regular checks of the accuracy of the Th-228 daughter calibration
standards (during the time when the detector was in use) by measuring the activity of a
National Institute of Standards and Technology (NIST)-traceable europium (Eu)-152
standard (in units of Becquerel, BQ) and comparing it to the accepted NIST value.
Results within 7% of the NIST value are considered to be within acceptable limits. The
Eu-152 activity comparison is a routine QC activity performed by INL, but for the
purposes of this evaluation serves as the performance evaluation (PE) audit, an audit that
confirms the accuracy of the calibration standards used for the instrumentation critical to
the results of an evaluation. Table 4-2 gives the results of each of the audits applicable to
the duration of the evaluation. All results are below the acceptable difference of 7%.
Table 4-2. NIST-Traceable Eu-152 Activity Standard Check
Relative
NIST Activity
INL RML
Percent
Date
(BQ)
Result (BQ)
Difference
8-18-2009
124,600
122,400
2%
9-10-2009
124,600
122,600
2%
10-12-2009
124,600
122,300
2%
4.2.2 Technical Systems A udit
A TSA was conducted during testing at INL to ensure that the evaluation was performed
in accordance with the test/QA plan and the TTEP QMP. As part of the audit, the actual
evaluation procedures were compared with those specified in the test/QA plan and the
data acquisition and handling procedures were reviewed. No significant adverse findings
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were noted in this audit. The records concerning the TSA are stored indefinitely with the
Battelle QA Manager.
4.2.3 Data Quality Audit
The Battelle QA Manager verified all of the raw data acquired during the evaluation and
transcribed into spreadsheets for use in the final report. The data were traced from the
initial raw data collection, through reduction and statistical analysis, to final reporting, to
ensure the integrity of the reported results.
4.3 QA/QC Reporting
Each assessment and audit was documented in accordance with the test/QA plan and the
QMP. The Battelle QA Manager prepared the draft assessment report and sent it to the
Test Coordinator and Battelle TTEP Program Manager for review and approval. The
Battelle QA Manager then sent the final assessment report to the EPA QA Manager and
Battelle staff.
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5.0 Evaluation Results
5.1 Decontamination Efficacy
The decontamination efficacy of the ETR180 was measured for each contaminated
coupon in terms of percent removal (%R) and decontamination factor (DF). Both of these
measurements provide a means of representing the extent of decontamination
accomplished by a technology. The %R gives the extent of removal as a percent relative
to the activity and the DF is the ratio of the initial activity to the final activity or the
factor by which the activity was decreased. These terms are defined by the following
equations:
%R = (1-Af/Ao) x 100% and DF = A0/Af
where A0 is the radiological activity from the surface of the coupon before application of
the ETR180 and Af is radiological activity from the surface of the coupon after treatment.
While the DFs are reported, the narrative describing the results focuses on the %R.
Table 5-1 gives the %R and DF for the ETR180. All coupons were oriented vertically.
The target activity for each of the contaminated coupons (pre-decontamination) was
within the acceptable range of 1 |iCi ± 0.5 |iCi. The overall average (plus or minus one
standard deviation) of the contaminated coupons was 1.15 |iCi ± 0.07 |iCi, a variability of
6%. The post-decontamination coupon activities were less than the pre-decontamination
activities showing an overall reduction in activity. The %R averaged 54 ± 10% and the
DF averaged 2.3 ± 0.7. Overall, the %R ranged from 42% to 74% and the DF ranged
from 1.7 to 3.9. The coupons with the %R values of 61% and 74% were notably higher
than the %R values for the other six coupons, which all fell within the range of 42% to
53%. There was no obvious reason for these larger %R values.
Paired t-tests were performed at a 95% confidence interval to determine whether location
(top, middle, or bottom) on the test stand affected the decontamination efficacy. While
the average %R for the top row (47% ± 5%) of coupons was slightly lower than the
middle (58% ± 14%) and bottom (57% ± 6%) rows, no significant difference between
any of the rows was found. The bottom middle coupon was not contaminated to test the
possibility of cross-contamination. Activity of the uncontaminated coupon was measured
after the ETR180 had been used on all nine coupons. No activity was detected on the
uncontaminated coupon, suggesting that cross-contamination resulting from ETR180
sanding was minimal.
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Table 5-1. Decontamination Efficacy Results
Coupon
Location in
Pre-Decon Activity
Post-Decon Activity
Test Stand
pCi / Coupon
nCi / Coupon
%R
DF
Top left
1.12
0.53
53
2.1
Top middle
1.21
0.71
42
1.7
Top right
1.21
0.64
47
1.9
Center left
1.06
0.53
50
2.0
Center middle
1.12
0.57
50
2.0
Center right
1.13
0.29
74
3.9
Bottom left
1.09
0.52
52
2.1
Bottom right
1.25
0.48
61
2.6
Average
1.15
0.53
54
2.3
Std. Dev
0.07
0.12
10
0.7
5.2 Deployment and Operational Factors
A number of operational factors were documented by the ETR180 operator. One of the
factors was damage to the surface of the concrete coupons. Figure 5-1 shows photographs
of an uncontaminated coupon before and after sanding with the ETR180. The slight pink
color is due to a dye that was applied to the surface of the noncontaminated coupon for
illustrative purposes. The coupon on the right still has all of the obvious surface
characteristics (discolorations, etc.) visible on the coupon on the left. However, a very
thin layer of the surface (referred to as the "cream" of the concrete) has been removed as
a result of sanding with the ETR180 making those characteristics more pronounced on
the right coupon. The ETR180 operator referred to the condition of the right coupon as
looking "polished." It is clear from these photographs that a small amount of the surface
was removed, but not enough to significantly change the look of the coupon.
Figure 5-1. Test coupons before (left) and
after (right) sanding with the ETR180.
Another important factor to consider is the personal protection of the technology
operators. During this evaluation, the radiological control technicians required the
operators to wear full anti-contamination personal protective equipment that included a
full face respirator with supplied air. This level of personal protection was required by
the INL RCTs because of the likelihood of airborne radiological contamination due to the
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act of sanding. However, each situation will need to be considered independently by
local RCTs to determine the proper level of personal protection.
Table 5-2 summarizes qualitative and quantitative practical information gained by the
operator during the evaluation of the ETR180. All of the operational information was
gathered during use of ETR180 on the concrete coupons inserted into the test stand.
Some of the information given in Table 5-2 could differ if the ETR180 were applied to a
larger surface or to a surface that was smoother or more rough and jagged than the
concrete coupons used during this evaluation.
Table 5-2. Operational Factors Gathered from the Evaluation
Parameter
Description/Information
Decontamination
rate
Technology Preparation: 15 minutes to attach sanding disk, vacuum shroud, and
vacuum to the ETR180.
Application: One minute per concrete coupon used during this evaluation corresponds
to an application rate of 1.4 m2/hour; less or more time per coupon may result in
different levels of radiological decontamination.
Applicability to
irregular surfaces
Application to irregular surfaces could be problematic for sanding disk technologies
like the ETR180 because the rotating disk does not cut into the surface of the
concrete: therefore, irregular coupon surfaces may prevent the sanding disk from
reaching some areas of the coupons.
Skilled labor
requirement
The rotating sanding disk is an extremely basic technology requiring minimal
training. Adequate training would likely include a few minutes of orientation so the
operator is familiar with the power switches on the vacuum and the ETR180. The
ETR180 centering tool was helpful in attaching the sanding disks.
The ETR180 weighs 3 kg. The operator during this evaluation experienced a
significant level of exertion as he completed the evaluation. The weight of the
ETR180, in combination with the additional weight and awkwardness of the attached
HEPA vacuum hose, increased the level of effort required to use the ETR180 when
standing on a ladder holding the ETR180 at a level equivalent to the operator's chest.
These factors will exclude some people from operating the ETR180. However, most
people who are used to performing physical labor should not have any problem
operating the ETR180.
Utilities
requirement
110V power for both the ETR180 and an applicable vacuum.
Extent of portability
The limiting factors of portability for the ETR180 will include the availability of
power and the ability to connect to the vacuum by staying close enough to the
vacuum or by having vacuum hosing of adequate length.
Sanding media
A new sanding disk was used after treating every 5 concrete coupons. The 24 grit
surface became smoother after each successive sanding.
Secondary waste
management
The vacuum shroud was effective at containing the secondary waste. There was very
little dust visible during the evaluation and very little remaining on the floor in front
of the test stand following the evaluation. In addition, the radiological control
technicians did not find any measurable airborne contamination during the evaluation.
The dust collected by the vacuum was not analyzed for gamma radiation, but given
the decrease in activity on the coupons, the waste would have had measurable
activity.
Surface damage
Operator described surface as being "polished." See description and photograph in
text.
Cost
The cost of ETR 180 is $389 and replacement disks are less than $5 each.
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6.0 Performance Summary
This section presents the findings from the evaluation of the ETR180 for each
performance parameter evaluated.
6.1 Decontamination Efficacy
The decontamination efficacy (in terms of %R) attained by the ETR180 was evaluated
for each concrete coupon used during the evaluation. When the decontamination efficacy
metrics (%R and DF) of the eight contaminated coupons were averaged together, the
average %R for the ETR180 was 54 ± 10% and the average DF was 2.3 ± 0.7. Hypothesis
testing was performed to determine if there were significant differences between the %R
values determined for the coupons in each row (top, middle, and bottom) of the test stand.
No differences were found.
6.2 Deployment and Operational Factors
Following the manufacturer's recommendations, the ETR180 was used with 24 grit
sanding disks. The ETR180 could decontaminate a vertical surface at a rate of
approximately 1.4 m2 per hour with minimal surface destruction and minimal secondary
waste. The texture of the coupon surface may be important to the efficacy of the ETR180
and similar radiological decontamination technologies. Battelle observed that because
sanding disks do not cut into concrete surfaces, uneven concrete surfaces may prevent the
sanding disk from reaching some areas of the concrete surfaces.
A limited evaluation of cross-contamination was performed. During an actual
decontamination of a vertical surface, the higher elevation surfaces would likely be
decontaminated first, possibly exposing the lower elevation surfaces to secondary
contamination. To simulate an actual scenario, one uncontaminated coupon was placed
in the bottom row of the test stand and decontaminated using the ETR180 in the same
way as the other coupons. Following decontamination, this uncontaminated coupon did
not exhibit measurable activity, suggesting that cross contamination was minimal.
Overall, the vacuum shroud was effective at containing the secondary waste. There was
very little dust visible during the evaluation and very little remaining on the floor in front
of the test stand following the evaluation. In addition, the radiological control technicians
did not find any measurable airborne contamination through analysis of air filters
sampled near the test stand. The dust collected by the vacuum was not analyzed for
gamma radiation.
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7.0 References
1. ASTM Standard C 150-07, "Standard Specification for Portland Cement." ASTM
International, West Conshohocken, PA, www.astm.org. 2007,
2. Radionuclide Detection and Decontamination Program. Broad Agency
Announcement 03-013, U.S. Department of Defense (DOD) Defense Advanced
Research Projects Agency (DARPA) and the U.S. Department of Homeland Security,
classified program.
3. Calibration and Use of Germanium Spectrometers for the Measurement of Gamma
Emission Rates of Radionuclides. American National Standards Institute. ANSI
N42.14-1999. IEEE New York, NY (Rev. 2004).
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United States
Environmental Protection
Agency
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