Oil Reservoir & Environmental Technologies
In situ Permeable Barrier for BTEX Remediation
Direct-push groundwater circulation wells (DP-GCW) are a promising technology for remediation of groundwater contaminated with dissolved hydrocarbons and chlorinated solvents. In these wells, groundwater is withdrawn from the formation at the bottom of the well, aerated and vapor stripped, and injected back into the formation at or above the water table. Previous field studies have shown that: (a)
can circulate significant volumes of groundwater; and (b)
can effectively remove volatile compouonds and add oxygen.
A system of
has been developed and field tested for remediation of volatile organics such as benzene, toluene, ethylbenzene, and xylenes (BTEX). The
were constructed with No. 20 slotted well screen (2.4
and natural sand pack extending from 1.5 to 8.2
below grade. Air is introduced at approximately 7.5
below grade via 0.6
tubing. Approximately 15% of the vertical length of the air supply tubing is wrapped in tangled mesh polypropylene geonet drainage fabric to provide surface area for biological growth and precipitation of oxidized iron. These materials were selected to allow rapid installation of the
direct-push Geoprobe® rods, greatly reducing well installation costs.
Laboratory testing of these sparged wells and computational fluid dynamics (CFD) modeling showed that these wells, although using only about 1
of air, could circulate about 1
of water through the surrounding aquifer. This flow was sufficient to capture all of a flowing contaminant if the wells are sufficiently close together (i.e. about 1 meter on center depending on the air flow rate supplied) in a line across the plume. The
work showed the details of this ability to capture and also showed that unforeseen heterogeneities in the aquifer, such as a gradient of permeability or a thin impermeable layer (such as a clay layer), did not prevent the system from working as intended.
The system was tested in a petroleum contaminated aquifer near Rocky Point,
The contaminant plume there is approximately 10
wide and contains up to 4
dissolved iron. An extensive pilot test was first performed to estimate the zone of influence for a single well. At this site an air injection rate of 1.2
resulted in a water flow rate of 1 to 2
based on bromide dilution tests in the
GCW increased the dissolved oxygen concentration in the discharge water to between 6 and 8
and reduced contaminant concentrations to less than 20
Monitoring results from a 73 day pilot test were then used to define the zone of influence for a single
and to design a full-scale barrier system.