DE19846804A1 - In situ ground water decontamination process operates without pumps and the associated energy costs - Google Patents

Abstract

A passive in-situ process cleans contaminated ground water in a zone (2) located between two water-impermeable sub-surface barriers (1). The barriers prevent the flow of ground water through the contaminated zone. One of the barriers has an opening which admits ground water (4), but contains a water-permeable plug of a material which filters or treats the contaminants, rendering them harmless.

Description

The invention relates to a method for the subsequent passive in-situ cleaning of contaminated groundwater within an impermeable barrier elements from the contaminated area separated from the natural groundwater flow.

Contaminated areas such as landfills, old deposits or industrial sites endanger the environment due to their pollutant potential. These are very common contaminated areas in the groundwater and pose a serious threat to groundwater quality. For this reason, such areas are separated water-impermeable barrier elements from the natural groundwater flow. Out The prior art offers a variety of options for executing such locks elements known. For example, diaphragm or sealing walls, narrow walls, Sheet piling, jet walls, bored pile walls or the like used for this become. The prerequisite for execution is always the existence of something serially impermeable barrier layer in the subsurface, which serves as an integration horizon for the Locking elements is used. This integration horizon is ideally a natural one dene layer, for example a clay layer, but it can also by techni cal means are produced, for example by a nozzle jet sole. Essential lich is that by enclosing the contaminated area a so-called Sealing pot is created, which is hydraulically removed from the natural groundwater flow separates.

On the one hand, rainwater infiltrates into the sealing pot and leads there to a reflection of the inner water level. On the other hand, there is a Water inflow into the sealing pot due to the always existing system tightness of the locking elements, which are never completely waterproof, but one (albeit very low) residual permeability. Because of this permanent The infiltration of water must be managed hydraulically. This is done by actively pumping the water out of wells or through the Detection and derivation in drainage. This prevents the inside of the Sealing pot water with the groundwater outside in Contact comes. It also prevents that the water level inside half of the sealing pot is higher than outside in natural groundwater and so that water flows from the inside of the sealing pot to the outside. If there is contamination inside the sealing pot, for example  a landfill, the contaminated water must be constantly in a separate be cleaned before it can be reintroduced into a receiving water can.

This prior art now has several disadvantages. Through the active hospitality the sealing pot is created by pumping out the water ongoing costs incurred over long periods of time. The captured contaminated what water must be cleaned with complex technology. This also causes high Costs. In addition, the technically recorded water goes to the local, natural Groundwater flow is lost and thus increased by its artificial discharge into an outflow the above-ground runoff. From an environmental point of view, that is Preservation of the natural groundwater flow is always preferable.

The invention now has various tasks. First, the discharge of Verun cleaning by the water flow from inside the sealing pot to the outside into the natural groundwater without the use of detection elements and Energy can be prevented. Second, a purification of the water that is in located inside the sealing pot, before it reaches the natural water electricity is supplied again. And thirdly, that should be inside the sealing pot water after its purification to the local, natural groundwater electricity can be supplied again.

The invention solves these problems by the characteristic features of the Pa tent Claims 1. Then at least one water-permeable opening in the Barrier elements introduced and at least one opening with a treatment filled with material that breaks down, filters or umwan the pollutants in the groundwater delt. According to the invention, it has been recognized that it is possible to constantly active Management of a contaminated area enclosed by barrier elements to be omitted if the locking elements that form the enclosure are opened with be provided with a treatment material that the Degrades, filters or converts pollutants in groundwater.

The sealing pot is always in a natural groundwater flow. This means that it is blown against from one side. On the opposite side  however, the groundwater flows out. This groundwater flow is now there used by that the locking elements or the surface of one of the Sperrele targeted non-contaminated area on the upstream side specifically for a water flow can be kept open or opened. Over this opening or this surface enters groundwater or rainwater into the sealing pot on. The water level inside the sealing pot rises compared to the outside natural groundwater level. Will a connection on the downstream side created the seal pot to the natural groundwater, arises accordingly According to the natural groundwater flow, a water flow to the downstream side of the sealing pot.

On the downstream side, the blocking elements are provided with openings into which a reactive, water-permeable treatment material is introduced, the the Verun contained in the water flowing from within the sealing pot removes, filters or converts cleaning. The flowing out from the inside, unclear Water flows through the treatment material and is therefore from Verunreini cleaned and then re-enters the local groundwater stream on.

The openings on the downstream side are dimensioned hydraulically so that a hy drastic gradient from inside the seal enclosure to the outside, however, there is no impermissibly high water build-up on the upstream side.

The treatment material is much more permeable to water than the material the blocking elements, so that all the water flowing out from the inside through the Treatment material flows. The treatment material is advantageously ent speaking of the contamination present in the groundwater. So can for example chlorinated hydrocarbons by reducing zero-valent iron be dismantled. Activated carbon has a high adsorption capacity for many organi pollutants. However, flu gas or zeolites conceivable. The combination with Mi is a particular advantage microorganisms that use the treatment material as a substrate.  

Advantageously, the treatment material in the opening in a container, for example, a basket, net or sack, which the Exchange of treatment material allowed. It is also possible to use the ratchet elements with several openings arranged one behind the other different treatment materials that break down different pollutants s to be filled. This is particularly advantageous since it is in contaminated groundwater usually several pollutants occur side by side.

There are a number of options for making the openings in the locking elements options. For example, such an opening can be made through a bore become. A more complex version is the opening as in-situ concrete work. Around the flow path and thus the dwell time of the contaminated Extending the groundwater in the treatment material can be done with the opening directions are provided, such as one or more partitions, the may be perforated at certain depth levels. The flow of the Opening can take place both horizontally and vertically.

It is particularly advantageous if an opening in the locking elements as a finished part can be installed, for example as a pipe with defined filter sections. To the end Exchange of the treatment material must ver the opening in the locking elements can be closed. For this purpose, it is advisable to fix the openings with devices conditions for closing such. B. to provide a slide. To the quality of the Groundwater control can be seen in the flow direction before and / or devices for removing and checking the openings after the openings Groundwater are installed, for example gauges or probes that characterize Record static parameters such as pH value or redox potential of the groundwater.

There are now several ways to teach the present invention advantageous to design and develop. For this purpose, on the one hand the claims 1 subordinate claims and on the other hand to the successor reference to two exemplary embodiments of the invention. In ver binding with the explanation of the preferred embodiments of the invention are generally preferred refinements and developments of the Teaching explained.  

Fig. 1 shows the initial state in cross section. A contaminated loading area 3 , for example a landfill, is cut off by water-impermeable barrier elements 1 , which bind into a barrier layer 10 , from the natural groundwater flow, which is divided into an upstream side 4 and an downstream side 5 by the sealing pot. Contaminated groundwater is located inside the sealing pot 2 . Since on the one hand the hydraulic permeability of the blocking elements 1 is small against the hydraulic permeability of the surrounding subsurface and the contaminated groundwater 2 is pumped out, the level of the inner water level 8 is lower than that of the outer water level 9 . Due to rainfall and inflows through the blocking elements 1 in the contaminated area 3 , the inner water level 8 increases and must be kept constantly by pumping 11 of the contaminated ground water 2 below the level of the outer water level 9 . The contaminated groundwater 2 is treated in a treatment plant and, for example, introduced into a sewage treatment plant.

Fig. 2a shows the initial state in plan. The contaminated area 3 is cut off from the natural groundwater flow by blocking elements 1 . An upstream side 4 and an downstream side 5 are formed. FIG. 2b shows the situation after the locking elements have been provided according to the invention 1 with water-pervious apertures 6, which have been filled with treatment material 7. For example, the surface of a non-contaminated area enclosed by the blocking elements on the upstream side 4 can also be opened. The contaminated groundwater 2 emerges through the water-permeable openings 6 filled with treatment material 7 to the downstream side 5 in the cleaned state, along its natural flow potential, without measures for detection, collection and discharge being necessary.

The water-permeable openings 6 can now be formed in various ways, for example as a hole of different diameters, as an in-situ concrete structure or as a prefabricated part. Fig. 3 shows the cross section of a water-permeable opening 6 as a tube of any diameter, the walls of which are provided with perforations 13 and which is filled with treatment material 7, which is accommodated in a water-permeable container 11 , so that the treatment material 7 can be exchanged as desired can. The container 11 is expediently at the upper end with a device for pulling out 12 , for example a cover with a hook. Attention is drawn to the possibility of not only providing the pipe with perforations 13 along its entire length, but alternating a fully cased section with a perforated pipe section and thus capturing different groundwater horizons. It is also pos sible not to form the tube up to the barrier layer 10 , but shorter.

The second embodiment of the invention is shown in FIG. 4. Here, the water-permeable opening 2 is designed as an in-situ concrete structure with two water-permeable treatment chambers 14 . These water-permeable treatment chambers 14 can be filled with different treatment materials 7 . The flow in this example is preferably in the horizontal direction Rich. In contrast, Fig. 5 shows an embodiment in which the flow is preferably in the vertical direction. For this purpose, the outer walls 15 and the partition 16 are designed as water-impermeable elements.

Reference list

1

Locking elements

2nd

Contaminated groundwater

3rd

Contaminated area

4th

Upstream side

5

Downstream side

6

openings

7

Treatment material

8th

Outside water level

9

Interior water level

10th

Barrier layer

11

container

12th

Pull-out device

13

Perforations

14

Treatment chambers

15

Exterior walls

16

partition wall

Claims (23)

1. A method for the subsequent passive in-situ cleaning of contaminated groundwater ( 2 ) within a contaminated area ( 3 ) separated from the natural groundwater flow by water-impermeable blocking elements ( 1 ), characterized in that at least one water-permeable opening ( 6 ) into the blocking elements ( 1 ) is introduced and at least one opening ( 6 ) is filled with a treatment material ( 7 ), which degrades, filters or converts the pollutants in the groundwater. 2. The method according to claim 1, characterized in that the openings ( 6 ) are dimensioned hy draulically so that a hydraulic gradient arises from the area inside the locking elements ( 1 ) to the area outside the locking elements ( 1 ). 3. The method according to any one of claims 1 to 2, characterized in that no water build-up occurs on the upstream side of the blocking elements ( 1 ). 4. The method according to any one of claims 1 to 3, characterized in that the treatment material ( 7 ) is substantially more water permeable than the material of the locking elements ( 1 ). 5. The method according to any one of claims 1 to 4, characterized in that the contaminated groundwater ( 2 ) flows through at least one opening ( 6 ) in the locking elements ( 1 ). 6. The method according to any one of claims 1 to 5, characterized in that the contaminations in the groundwater during passage of the contaminated groundwater sers ( 2 ) through the treatment material ( 7 ) are broken down, filtered or converted. 7. The method according to any one of claims 1 to 6, characterized in that the treatment material ( 7 ) is selected in accordance with the existing contaminations in the groundwater Kon. 8. The method according to any one of claims 1 to 7, characterized in that the treatment material ( 7 ) is zero-valent iron. 9. The method according to any one of claims 1 to 8, characterized in that the treatment material ( 7 ) is activated carbon. 10. The method according to any one of claims 1 to 9, characterized in that the treatment material ( 7 ) is fly ash. 11. The method according to any one of claims 1 to 10, characterized in that the treatment material ( 7 ) is zeolite. 12. The method according to any one of claims 1 to 11, characterized in that the treatment material ( 7 ) serves as a substrate for microorganisms. 13. The method according to any one of claims 1 to 12, characterized in that the Contamination contained in the groundwater due to the activity of this microor mechanisms are broken down. 14. The method according to any one of claims 1 to 13, characterized in that the purified water immediately enters the local aquifer. 15. The method according to any one of claims 1 to 14, characterized in that the treatment material ( 7 ) is housed in a container which allows the exchange of the treatment material ( 7 ). 16. The method according to any one of claims 1 to 15, characterized in that the locking elements ( 1 ) with a plurality of openings ( 6 ) arranged one behind the other are seen ver. 17. The method according to any one of claims 1 to 16, characterized in that the openings ( 6 ) are filled with different treatment materials ( 7 ) for the common treatment of pollutants in the groundwater. 18. The method according to any one of claims 1 to 17, characterized in that the openings ( 6 ) in the locking elements ( 1 ) are made by bores. 19. The method according to any one of claims 1 to 18, characterized in that the openings ( 6 ) in the locking elements ( 1 ) as an in-situ concrete structure executed who. 20. The method according to any one of claims 1 to 19, characterized in that the openings ( 6 ) in the locking elements ( 1 ) are provided with devices by which the residence time of the contaminated water in the treatment material ( 7 ) is increased. 21. The method according to any one of claims 1 to 20, characterized in that the openings ( 6 ) in the locking elements ( 1 ) are installed as a finished part. 22. The method according to any one of claims 1 to 21, characterized in that the openings ( 6 ) in the locking elements ( 1 ) are provided with devices for closing the openings ( 6 ). 23. The method according to any one of claims 1 to 22, characterized in that seen in the direction of flow before, in and / or after the openings ( 6 ) Vorrichtun gene for removal and control of the groundwater are installed.