tCDsrA UNITED STATES ENVIRONMENTAL PROTECTION AGENCY
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n,' V Washington, D.C. 20460 f
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ENVIRONMENTAL TECHNOLOGY VERIFICATION PROGRAM
VERIFICATION STATEMENT
TECHNOLOGY TYPE: GROUND WATER SAMPLING TECHNOLOGIES
APPLICATION: NARROW-BORE WELL WATER SAMPLING
TECHNOLOGY NAME: GW1400 Series Pneumatic Bladder Pump
COMPANY: Geoprobe Systems Inc.
ADDRESS: 601 N. Broadway PHONE: (800) 436-7762
Salina, KS 67401 FAX: (785) 825-2097
WEBSITE: www.geoprobe.com
EMAIL: info@geoprobe.com
PROGRAM DESCRIPTION
The U.S. Environmental Protection Agency (EPA) has created the Environmental Technology
Verification Program (ETV) 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.
ETV works in partnership with recognized standards and testing organizations and stakeholder groups
consisting of regulators, buyers, and vendor organizations, with the full participation of 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 protocols to ensure that data of known and
adequate quality are generated and that the results are defensible.
Verification of contaminated site characterization and monitoring technologies is carried out within the
Advanced Monitoring Systems (AMS) Center, one of seven ETV verification centers. Sandia National
Laboratories, a Department of Energy laboratory, is one of the verification testing organizations within
this ETV Center. Sandia collaborated with personnel from the US Geological Survey and Tyndall Air
Force Base to conduct a verification study of ground-water sampling technologies for deployment in
narrow-bore, direct-push wells at contaminated sites with potential ground-water contamination. This
verification statement provides a summary of the results from a verification test of the GW1400 Series
Pneumatic Bladder Pump manufactured by Geoprobe Systems Inc.
EPA-VS-SCM-57
The accompanying notice is an integral part of this verification statement.
August 2003
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DEMONSTRATION DESCRIPTION
The performance of two ground-water sampling technologies was evaluated at the US Geological Survey
Hydrological Instrumentation Facility at the NASA Stennis Space Center in southwestern Mississippi
and at Tyndall Air Force Base near Panama City, Florida. Each technology was independently evaluated
to assess its performance in the collection of inorganic cations, commonly encountered in ground-water,
as well as volatile organic compound (VOC) contaminated ground-water.
The verification test, conducted over a one-week interval in February 2003, incorporated the use of a 5-
inch diameter, 100-foot standpipe at the USGS facility. The standpipe, serving as an "above-ground"
well, was filled with tap water spiked with various concentration levels of five target inorganic cations
(calcium, iron, magnesium, potassium and sodium) and six volatile organic compounds. Target VOC
compounds (vinyl chloride, methyl-tertiary butyl ether, cis-l,2-dichloroethene, benzene, trichloroethene
and ethyl benzene) were chosen to represent the range of VOC volatility likely to be encountered in
normal sampler use. Target cation concentrations were in the range of 5 to 100 mg/L and VOC
concentrations were in the range of 50 to 100 |ag/L. Water sampling ports along the exterior of the
standpipe were used to collect reference samples at the same time that ground-water sampling
technologies collected samples from the interior of the pipe. Trials were carried out at two different
inorganic cation concentrations, a single VOC concentration, and sampler depths ranging from 17 to 76
feet. An unspiked, tap-water, blank sampling trial was also included in the test matrix. A total of 48
cation and 24 VOC samples were collected with the sample count equally split between vendor and
reference sampling methods.
The standpipe trials were supplemented with additional trials at six, 1-inch internal-diameter, direct-push-
installed wells at Tyndall Air Force Base. Sampling at narrow-bore, direct-push wells provided an
opportunity to observe the operation of the sampling system under typical field-use conditions. A simple
reference sampler was deployed along side the vendor technology such that co-located, simultaneous
samples could be collected from each well. Principal contaminants at the Tyndall monitoring wells
included trichloroethene and its degradation products as well as hydrocarbon contaminants such as
benzene and ethyl benzene. Ground-water VOC concentrations ranged from low |Jg/L to low mg/L
levels. A total of 96 ground-water samples were collected, with the sample count equally split between
vendor and reference methods.
All technology and reference samples were analyzed by an offsite laboratory utilizing EPA SW-846
Standard Methods 301 OA (Acid Digestion of Aqueous Samples and Extracts For Total Metals by FLAA
or ICP Spectrometry) and 6010B (Inductively Coupled Plasma Atomic Emission Spectrometry) for
inorganic cation analysis and EPA SW-846 Standard Method 8260B (Volatile Organic Compounds by
Gas Chromatography/Mass Spectroscopy) for VOC analysis. The overall performance of the ground-
water sampling technologies was assessed by evaluating sampler precision and comparability with
reference samples. Other logistical aspects of field deployment and potential applications of the
technology were also considered in the evaluation.
Details of the demonstration, including an evaluation of the sampler's performance, may be found in the
report entitled Environmental Technology Verification Report: Geoprobe Systems, Pneumatic Bladder
Pump, GW1400 Series, EPA Report Number EPA/600/R-03/085.
TECHNOLOGY DESCRIPTION
The GW1400 Series is a narrow-diameter (23.8-inch length x 0.5-inch outside diameter) bladder pump
suitable for deployment in direct-push-installed ground water wells. The pump consists of an internal,
flexible and inert bladder that is positioned within a rigid stainless steel tube. The bladder's internal
volume can be reduced by applying an external force via air pressure in order to collapse the bladder. The
bladder is equipped with one-way inlet and outlet check valves and passively fills with water when the
EPA-VS-SCM-57
The accompanying notice is an integral part of this verification statement.
August 2003
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pump is at depth in the well as a result of the hydrostatic pressure exerted by the surrounding water column.
Following the bladder fill cycle, a source of compressed air at the surface is used to pressurize the region
between the bladder and the outer rigid tube. The bladder volume is reduced and the water within the
bladder is pushed toward the surface. The pumping sequence consists of repeated fill-compress cycles that
are regulated by an adjustable pneumatic controller located at the well head between a source of
compressed air and the pump. The narrow-diameter sampling pump with an inert bladder design offers
the advantage of minimizing sample turbulence, which can result in loss of VOCs in the sample, as well as
eliminating contact of the water with an air vacuum and further potential VOC losses.
Pump accessories include a pneumatic controller, a source of compressed gas (typically nitrogen) or an air
compressor and power source. The pump utilizes a concentric tubing configuration for air pressure
connection and water transport to the surface and various tubing materials are available that can be matched
to the sampling application. The nominal flow rate of the pump measured at a depth of 35 feet below the
surface with a 32-foot water column above the pump was approximately 75 mL/min. Under these typical
sampling conditions, the flow range of the pump is well-suited for sampling applications that incorporate
low-flow sampling protocols.
Costs for the pump and accessories are as follows: pump, $700; pneumatic controller $1300; compressor,
$250; AC generator $2000. Concentric tubing sets are priced as follows: HDPE (outer) /FEP-Teflon
(inner), $114 per 50-foot roll; FEP/FEP $396 per 50-foot roll.
VERIFICATION OF PERFORMANCE
The following performance characteristics of the GW1400 Series Pneumatic Bladder Pump were
observed:
Precision: The precision of the sampler was determined through the collection of a series of replicate
samples from a number of standpipe trials that included known concentrations of inorganic cations and
VOCs. Sampler depths ranged from 17 to 76 feet. Sampler precision, represented by the percent relative
standard deviation, for all target cation compounds at all concentrations and sampling depths evaluated
in this study ranged from 0.0 to 2.8 percent with a median value of 0.6 percent. Precision for VOCs at a
single concentration and multiple sampler depths ranged from 0.3 to 2.8 percent with a median value of
1.3 percent. Pump precision measured in the Tyndall field trials was similar to that observed in the
standpipe trials for the target cations. For VOC compounds, Tyndall monitoring-well field trials
revealed considerably more variability in the replicate samples from the pump and co-located reference
sampler.
Comparability with a Reference: Pneumatic bladder pump results from the standpipe trials were
compared with results obtained from co-located reference port samples collected simultaneously. Both
bladder pump and reference samples were analyzed at an off-site laboratory using standard EPA methods
for inorganic cations and VOCs. Sampler comparability is expressed as percent difference relative to the
reference data. Sampler differences for all target cations compounds at all concentrations and sampler
depths in this study ranged from -14.8 to 6.5 percent with a median percent difference of-1.0. Sampler
differences for all VOC compounds at all sampling depths ranged from -5.6 to 0.9 percent with a median
value of-2.3 percent.
Two statistical tests, the F-ratio test and the t-test for two sample means, were used to assess whether the
observed differences at the standpipe between the pneumatic bladder pump and reference port sample
precision and mean pump and reference target compound concentrations were statistically significant. In
general, the tests show that the observed differences between the bladder pump and reference samples
with regard to both precision and accuracy can be attributed to random variation. Thus, no statistically
significant bias exists between the results from the bladder pump and the reference port samples.
EPA-VS-SCM-57
The accompanying notice is an integral part of this verification statement.
August 2003
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The percent difference values for the pump in comparison with the reference method for target cations at
Tyndall monitoring wells ranged from -9.7 to 53.5 with a median value of 3.5. Comparability results for
VOCs were considerably more variable with percent differences ranging from -68.7 to 571 percent with
a median value of 8.4. Some of the larger percent difference values encountered are attributable to
measurements of VOC concentrations near the approximate 5 |a,g/L method detection limit where small
absolute differences between methods can result in relative large percent difference values. The
controlled aspects of the standpipe tests should be considered in combination with the Tyndall field tests
for a comprehensive understanding of pump performance.
Versatility: Sampler versatility is the consistency with which it performed with various target
compounds, concentration levels, and sampling depths. The pneumatic bladder pump performance did
not vary with changes in compounds or concentration levels. Deployment of the pump at depths in
excess of 50 feet may result in flow rates that are deemed unacceptable for some sampling applications.
The small surface area of the pump inlet filter can result in clogging when sampling under turbid ground
water conditions. In general, the Geoprobe pneumatic bladder pump is regarded as a versatile
technology and applicable for sampling the types of inorganic and VOC contaminants from narrow-
diameter direct push wells.
Logistical Requirements: The sampler can be deployed and operated in the field by one person. Several
hours of training are adequate to become proficient in the use of the system. The system includes a
surface-located pneumatic controller and requires either a source of compressed gas or a portable air
compressor and associated gasoline-powered generator or line source. The bladder pump can be used as
a dedicated sampler or as a portable sampler; however, pump decontamination is required when moving
from well to well.
Overall Evaluation: The results of this verification test show that the Geoprobe pneumatic bladder pump
and associated accessories can be used to collect inorganic cation- and VOC-contaminated water samples
from monitoring wells in such a way that sampling and analysis results are statistically comparable to
reference samples. The system is specifically designed for use in narrow-bore (0.5-inch minimum
internal-diameter) wells. Furthermore, the pump is compatible with sampling programs that incorporate
low-volume purge methodologies.
As with any technology selection, the user must determine if this technology is appropriate for the
application and the project data quality objectives. For more information on this and other verified
technologies visit the ETV web site at http://www.epa.gov/etv.
Gary J. Foley, Ph D
Director
National Exposure Research Laboratory
Office of Research and Development
Margie Tatro
Director
Energy and Transportation Security Center
Sandia National Laboratories
EPA-VS-SCM-57
The accompanying notice is an integral part of this verification statement.
August 2003
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