The URL can be used to link to this page

Home My WebLink About4101_Guilford_HighPoint_MSWLF_Seaboard_SamplingRequest_FID1596058_20210809SEABOARD GROUP If AND THE CITY OF HIGH POINT August 16, 2021 Eric B. Aufderhaar, P.G., Environmental Program Consultant Jackie Drummond, Hydrogeologist North Carolina Department of Environmental Quality Division of Waste Management 1646 Mail Service Center Raleigh, North Carolina 27699-1646 Re: HydraSleeve Equivalency Demonstration Workplan Former Seaboard Chemical and Riverdale Drive Landfill Site Jamestown, Guilford County, North Carolina Dear Eric and Jackie: The Seaboard Group II and the City of High Point are proposing to evaluate an alternate groundwater sample collection method for the water quality monitoring events at the former Seaboard/Riverdale Drive Landfill Site. If approved by NCDEQ, this Equivalency Demonstration Workplan will be implemented during the fall 2021 water quality monitoring event at the Site with an evaluation provided following submittal of the Annual Water Quality Monitoring Report. HydraSleeve Sampling Device The HydraSleeve is a no -purge passive grab sampling device, meaning that it is used to collect groundwater samples directly from the screened interval of a well without having to purge the well prior to sample collection. As the groundwater at the Site contains high concentrations of contaminants, the elimination of purge water is a significant advantage over other sample collection methods. The HydraSleeve collects a sample from the screened section of the well only. It excludes water from any other part of the water column in the well through the use of a self-sealing check valve at the top of the sampler. No -purge sampling devices like the HydraSleeve collect formation - quality water under undisturbed, non- pumping natural flow conditions. It is a single -use disposable sampler that is not intended for reuse, so there are no decontamination requirements for the sampling device itself. The Hydra Sleeve sampling device is approved by Region IV EPA and is included in Section 3.6 of the EPA SESD Operating Procedure Manual. An excerpt from the Operating Procedure Manual discussing the use of HydraSleeve is attached to this Workplan. There are several videos available which demonstrate the use and application of the HydraSleeve sampling device. A few representative video links are provided below: How the HydraSleeve Works (52 sec): hLtps://www.youtube.com/watch?v=gV 2qCUoqDl Installing the HydraSleeve (5:33 min): https://www.youtube.com/watch?v=HwDYc5y9NDc Removing the HydraSleeve (7:28 min): hLtps://www.youtube.com/watch?v=rz9!pVgjjsE HydraSleeve Equivalency Demonstration Procedure There are currently twenty-five groundwater monitoring wells included in the annual water quality monitoring program at the Site. Based on preliminary conversations with NCDEQ staff, a total of ten monitoring wells have been selected for duplicate sampling during the fall 2021 monitoring event. The ten selected monitoring wells and relevant screened intervals and water quality information are provided below: Monitoring Well ID Well Screen Interval Total VOCs * 1,4-Dioxane MW-1 47' - 57' BQL BQL MW-12B 48' — 58' 125 ug/1 110 ug/1 MW-15A 19' — 34' 1,449 ug/l 1,100 ug/1 OW-DR2 176' — 186' 1,060 ug/1 280 ug/1 PW-3D 179' — 209' 76,030 ug/l 160 ug/1 PW-5D 272' — 282' 1,272 ug/1 460 ug/1 PW-10I 80' 100, 281 ug/1 250 ug/1 PW-131 235' — 250' 146 ug/1 68 ug/1 PW-16D 169' — 179' 68 ug/1 BQL W-4A 54' — 64' 344 ug/l 30 ug/l * October 2020 Analytical Data A Site Map showing the location of these ten monitoring wells is attached to this Workplan. The HydraSleeve samples will be collected a minimum of 2 days prior to the routine monitoring event which uses low -flow sampling procedures. This is to assure the well casing water is undisturbed at the time of both sample collection events. The HydraSleeve sampling devices will be installed and allowed to equilibrate for approximately two hours prior to retrieval of the sample. As with the routine monitoring event, the samples will be analyzed for VOCs by EPA Method 8270D and 1,4-dioxane by EPA Method 8270D SIM. In addition to the routine field measurements (pH, temperature, specific conductance, and dissolved oxygen), the turbidity of the sample will also be determined at the time of collection. Following receipt of the analytical data from the sampling events, the data from the HydraSleeve sampling will be compared to the data obtained during the routine annual monitoring event using low -flow procedures. This comparison will be provided separate from the Annual Water Quality Monitoring Report and will contain a summary of the work performed and a comparison of the data received for the wells in the demonstration. While an exact quantitative match is not anticipated, a qualitative approach to the evaluation of the data will be applied. The observed magnitude of contaminant concentration as well as the ratio of specific contaminants in a particular sample should indicate the equivalency of the sample collection methods. If there are any questions or comments regarding this Equivalency Demonstration Workplan, please contact the undersigned at 919/605-4719 Please direct any correspondence related to this matter to: Mr. Craig Coslett de maximis, inc. 1550 Pond Road, Suite 120 Allentown, PA 18104 Email: ccoslettkdemaximis.com. Respectfully, Seaboard Group II and City of High Point Gary D. Babb, P.G. Babb & Associates, P.A. Mr. Gary Babb, P.G. and Babb & Associates, P.A. 5506 Bradford Pear Ct Raleigh, NC 27606 Email: gdbabb@gmail.com Attachment: EPA SESD Operating Procedure Manual Excerpt Site Sample Location Map Cc: Mr. Craig Coslett de maximis, inc. 3.6.1 Minimum Purge Sampling COPY The pump or tubing inlet is deployed in the screened interval. A volume of water equal to the internal pump and tubing volume is pumped to flush the equipment. Sampling then proceeds immediately. While superficially similar to Low -Flow sampling, the results obtained in this method will be sensitive to the vertical pump or tubing inlet placement and are subject to the limitations described above. 3.6.2 Passive Diffusion Bags The no -purge Passive Diffusion Bag (PDB) typically consists of a sealed low -density polyethylene (LDPE) bag containing deionized water. They are deployed in the screened interval of a well and allowed to equilibrate, commonly for two weeks, prior to retrieval and decanting of the water into sample containers. Many volatile organic compounds will reach equilibrium across the LDPE material, including BTEX compounds and many chlorinated solvents. Compounds showing poor equilibration across LDPE include acetone, MTBE, MIBK, and styrene. PDBs have been constructed of other materials for sampling other analytes, but the vast majority of PDB samplers are of the LDPE material. Various vendors and the Interstate Technology and Regulatory Council (ITRC) can provide additional information on these devices. 3.6.3 HydraSleevesTM HydraSleeevesTM are no -purge grab sampling devices consisting of a closed -bottom sleeve of low -density polyethylene with a reed valve at the top. They are deployed in a collapsed state to the desired interval and fill themselves through the reed valve when pulled upward through the sampling interval. The following is a summary of their operation: Sampler placement — A reusable weight is attached to the bottom of the sampler or the sampler is clipped to a weighted line. The HydraSleeveTM is lowered on the weighted line and placed with the top of the sampler at the bottom of the desired sampling interval. In -situ water pressure keeps the reed valve closed, preventing water from entering the sampler. The well is allowed to return to equilibrium. Sample collection - The reed valve opens to allow filling when the sampler is moved upward faster than 1 foot per second, either in one continuous upward pull or by cycling the sampler up and down to sample a shorter interval. There is no change in water level and only minimal agitation during collection. Sample retrieval - When the flexible sleeve is full, the reed valve closes and the sampler can be recovered without entry of extraneous overlying fluids. Samples are removed by puncturing the sleeve with the pointed discharge tube and draining the contents into containers for sampling or field parameter measurements. SESD Operating Procedure Page 21 of 34 SESDPROC-301-R4 Groundwater Sampling Groundwater Sampling (301 )_AF.R4 Effective Date: April 26, 2017 Because the HydraSleeve" is retrieved before equilibration can occur and they are constructed of non -Teflon® materials, there may be issues with sorbtion of contaminants in the use of this sampler. 3.6.4 Snap Samplers The Snap Sampler is a patented no -purge groundwater sampling device that employs a double -end -opening bottle with "Snap" sealing end caps. The dedicated, device is deployed at the desired position in the screened interval with up to six Snap Samplers and six individual sampling bottles. The device is allowed to equilibrate in the screened interval and retrieved between 3 and 14 days after deployment. Longer deployments are possible to accommodate sampling schedules. To operate, Snap Samplers are loaded with Snap Sampler bottles and the "Snap" caps are set into an open position. Samplers are deployed downhole with an attachment/trigger line and left to equilibrate downhole. To collect samples, the Snap Sampler bottles seal under the water surface by pulling a mechanical trigger line, or using an electric or pneumatic trigger system. The trigger releases Teflon® "Snap Caps" that seal the double - ended bottles. The end caps are designed to seal the water sample within the bottles with no headspace vapor. After the closed vial is retrieved from the well, the bottles are prepared with standard septa screw caps and labeled for laboratory submittal. The manufacturer of the Snap Sampler provides considerable additional information on the validation and use of the device. 3.7 Equipment Considerations Equipment choices are dictated by the purging and sampling method used, the depth to water, the quantity of water to be pumped, and quality considerations. The advantages and disadvantages of various commonly used pumps are discussed in the sections below and summarized in Table 1, Purge and Sample Strategies with Equipment Considerations. Additional information on the use of individual pumps is available in SESD Operating Procedure for Pump Operation, SESDPROC-203. 3.7.1 Use of Peristaltic Pumps Peristaltic pumps are simple, inexpensive, and reliable equipment for purging and sampling where the limit of suction is not exceeded (approximately 25-30 vertical feet from the groundwater surface to the pump). When used for sampling, they should be equipped with new Teflon® tubing for each well. The flexible peristaltic pump -head tubing should also be changed between wells. Samples for organic analyses cannot be exposed to the flexible peristaltic pump -head tubing, both due to the risk that the tubing would sorb contaminants and the propensity of this tubing to contribute organic compounds to the sample. Samples can be collected without contact with the pump -head tubing by the use of vacuum transfer caps for SESD Operating Procedure Page 22 of 34 SESDPROC-301-R4 Groundwater Sampling Groundwater Sampling (301 )_AF.R4 Effective Date: April 26, 2017 . SW-2�/ SW-6LOCATED AT UPSTREAM PW-18 SIDE OF KIVETT DRIVE BRIDLE — -- - I I ----------- --- / OW -NISI I - j � RW-NIS 680. 0 I a MW 1 D+ —.BIB; � / - PW-19 RIVERDALE ORI VE LANDFILL 679'688. 2 � � .r � I I PW16D j PW-14D 677.76 623.19 � I r P 7I P1-141 r I PW-15D Pw-T5s . . 676.10 If I IT •I �� ;lI �� ; d � �� \\ ..., W—DRP-2 IT Ps_ D . . 6s.2/ j \ I - FORMER BURN �� i� ' �...�...�_ .. ..\ .'� i. / �� 679. 5 I II M W— 1 �I 111 PITS AREA 11 II 761.18 \ j \ �' f W— 131 679.30 OW R 2- � 3 � �/ `• MW-36,w72. -46 WAY OW-DR4e MW-3A RECOVER SE w i6 4 — I\ MW-3C W OR_-7 6678.55 ® CITY —51 .I � •.L.. - r. RW SISI IN RMITTENT/ _ I """-----��_ MAINTENANC - -- - GARAGE \� \ a W 3A '\--- MRF-1 SOIL SIDUE� W15 A� NND 7ao.1a \ ( a MW-15B \ MATERIAL \,I RECYCLING 21 \\ V FACILITY Y \ ;Aj .1%w-S�\-SW-3W LF�- RW-SIS2 R 1. \ T 9 ® I e\�\\664 47 I . y W4A� SW-5 q W - � INTERMITTENT _ TREAM 4.2 w_ 4 O \ \ eM \(�I - 9 �V A)so�1PER� W-20 oWasls2 W—/SD�80 �F 0 ' Pw sI OW-SF1 W-41 �I\ \ MRF-2 /� - � \_ 9 MW 8B 695.62 O I 70 10 HOUSE W-18 _ OF g V1 1 M 67 PRAR 9 w---�W-.r MW-7q 678. I: . P —10 D'' II 672.38 �W-26 _W-29 li 710 RIVERDALE DRIVE LANDFILL � I 720 111 FORMER SEABOARD II CHEMICAL CORPORA LION Q/ -- w-2 oJ�o RIVERDALE DRIVE ' SW—bRP-11 LOC TE _Tao /i/ DOWNSTREAM A �� lb PW12 EAST SIDE ONFLUENCE WI �� S —711 724.05 WASTEWATER O /,; TREATMENT _ ICHLAND CRE /T PLANT �j66 VAM W 6 SCALE IN FEET //r 696 74 I I I/ 0 75 150 300 oBASE MAP FROM BBL REMEDIAL INVESTIGATION LEGEND FIGURE o REPORT, MARCH 1999. g MONITORING WELL (SAPROLITE/PWR) OCTOBER 2020 GROUNDWATER POTENTIOMETRIC MAP N WELLS TO BE SAMPLED SHOWN ®RECOVERY WELL SAPROLTE SB ' GROUNDWATER AND SURFACE WATER SAMPLE LOCATIONS % N ENLARGED TYPE SURFACE WATER (MONITORING STATION FORMER SEABOARD CHEMICAL/RIVERDALE DRIVE LF Babb & Associates, P.A. JAMESTOWN, NORTH CAROLINA