NL9301596A - Method and device for signaling soil contamination or remediation of contaminated soil in situ. - Google Patents

Description

Method and device for signaling soil contamination or remediation of contaminated soil in situ.

The present invention relates to a method for detecting soil contamination and remediation of contaminated soil in situ.

The detection of soil contamination by taking samples with soil material and analyzing these samples elsewhere is generally known. The taking of such a sample is very laborious, since a tube is driven vertically or obliquely into the ground for this purpose and subsequently taken out of the ground together with the soil material to be analyzed. Such sampling is considerably impeded by buildings, cables, sewers and the like. If soil contamination was subsequently detected during the chemical analysis, the contaminated soil must usually be excavated and taken to a cleaning installation for cleaning. The cleaned soil material can then be returned, or new clean soil material is returned. Remediation of contaminated soil in this way is very expensive.

The object of the present invention is to provide a method for signaling soil contamination or in-situ remediation of contaminated soil, which does not, among other things, exhibit these disadvantages.

This object is achieved according to the invention in that - contaminated (soil) air via one or more air drainage pipes, which are located in the soil above the groundwater level, and / or contaminated liquid via one or more other liquid drainage pipes, which are located in the soil below the ground water level, extracts it from the contaminated soil and subjects the air and / or liquid extracted in this way to analysis or purification.

By means of such drainage pipes, which are preferably arranged permanently in the soil, air and / or liquid can be extracted from the soil and subsequently analyzed. Furthermore, the extracted air and / or liquid can also be purified, so that the contaminated soil can be remediated in situ without excavating it and cleaning it elsewhere. If samples are taken and analyzed at a sufficiently large frequency via the air and / or liquid drainage pipes, a contamination of the soil is signaled in good time, so that remediation via the drainage pipes can be remediated quickly, before this contamination has largely penetrated the soil. to spread.

The method according to the invention can be applied at locations where environmentally harmful substances (such as for instance solvents, mineral oils, volatile hydrocarbons or mixtures thereof) can penetrate into the soil, and a contamination of the soil, and / or the groundwater and / or the soil air. can cause. The method according to the invention is particularly suitable for fuel sales points (filling stations), transfer stations, storage depots and other locations, where there is an increased risk of soil contamination due to above and underground activities, such as, among other things, production locations for chemicals, bus depots, car repair places, etc.

At a large number of fuel outlets, the ground is contaminated as a result of leaks at the installations or due to spills during refueling, for example. Many provisions are nowadays taken against this. However, despite these facilities, such as cathodic protection of the tanks, overfill protection, liquid-tight containers around filling points, and liquid-tight pavements around the so-called pump islands, etc., it cannot be excluded that cases of contamination may still occur. This can happen on the one hand due to calamities, on the other hand also because the effectiveness and longevity of the materials used for the facilities are not fully known. With the method according to the invention, it is possible, for example at such fuel sales points, to extract air and / or liquid from the soil at regular intervals, to analyze this air and / or liquid for contaminants, and if necessary to immediately clean up the contaminated soil if pollution is found. by extracting and purifying contaminated air and / or liquid from the soil. Expansion of soil contamination can be prevented at an early stage. For cleaning the air and / or liquid extracted from the ground, an apparatus as described in EP-B1-0.385 · 555 can for instance be used.

The method according to the invention can also continuously extract and clean air and / or liquid from the soil, without any contamination having first been detected. The identification and remediation can therefore take place simultaneously or in conjunction with one another, as well as independently.

According to an advantageous embodiment, the air and / or liquid drainage pipes extend substantially horizontally. In this way a large area can be covered with one drainage pipe.

Furthermore, according to the invention it is advantageous if a number of air and / or liquid drainage pipes are arranged parallel to each other and at a mutual distance, preferably at least 2 to 3, in a substantially horizontal plane. In this way a large soil area can be covered efficiently with the aid of a number of drainage pipes.

In order to extract air and / or liquid from the soil, an underpressure is advantageously applied in the air and / or liquid drainage pipes, for example an underpressure of 1 k 10 kPa and preferably of 3 to 6 kPa. With such an underpressure, the extraction of air and / or liquid from the soil is such that the concentrations of any impurities are not too low (this is difficult, for example, during analysis), while again too little air and / or liquid is the soil is extracted.

Air from the environment is also sucked into the soil by drawing in air via the air drainage pipes. This ambient air is conducive to any bioactivity in the soil. Such bioactivity can have a beneficial effect in combating soil contamination. According to an advantageous embodiment, the bioactivity of the soil is further stimulated by introducing biomass and / or nutrients for biomass into the soil, which can for instance take place via air and / or liquid drainage pipes. During the introduction of biomass and / or nutrients to the soil, the extraction of air and / or liquid from the soil may be temporarily stopped in the latter case.

Furthermore, according to the invention it is advantageous if the purification installation for purifying air and / or liquid extracted from the soil is also used for treating waste fluids. This includes waste fluids, fluids other than air and / or liquid extracted from the soil, such as domestic waste water, vapors collected above ground, fluids released during production processes, etc.

The invention further relates to a method for building, renovating or renovating a chemical installation, such as a filling station, in which a number of drainage pipes, preferably extending substantially horizontally, are provided in the bottom under the chemical installation, these drainage pipes above and / or below the ground water level, connect the drainage pipes to suction means for applying a negative pressure in the drainage pipes, and the drainage pipes connect to a treatment device. The treatment device can herein be a device for sampling, and / or analyzing, and / or cleaning fluid withdrawn from the bottom.

According to the invention it is furthermore advantageous here to first excavate part of the soil and replace it with a sandy soil material, and to provide drainage pipes in this sandy soil material. In particular, it is advantageous here to first dig a number of trenches in the soil and replace them with moderately fine to coarse sand, and to provide drainage pipes in this moderately fine to coarse sand. This is particularly advantageous with clay and / or loamy soils, since the permeability of such soils is low, which makes it difficult to extract air and / or liquid via drainage pipes. However, a soil with moderately fine to coarse sand is very suitable for extracting air and / or liquid from the soil by means of drainage pipes.

The invention furthermore relates to the application of an underground drainage system with: - air drainage pipes located in the soil above the groundwater level, and / or liquid drainage pipes located in the soil below the groundwater level, for the analysis of (soil) air and / or groundwater and any remediation of contaminated (soil) air and / or contaminated groundwater.

Finally, the invention also relates to an apparatus for applying the methods according to the invention.

The invention will now be explained in more detail with reference to an exemplary embodiment shown in the accompanying figure.

The figure shows a pumping station for refilling fuel for cars 6. A number of fuel pumps 5 are placed on a liquid-tight pavement 4. Below the liquid-tight pavement 4 and above the ground water level 3, a number of parallel air drainage pipes 1 are arranged in the unsaturated zone of the soil. Furthermore, a number of parallel liquid drainage pipes 2 are arranged in the soil below the ground water level 3. The fuel pumps 5 are connected via lines 9 to storage tanks 7 for fuel. According to the invention it is advantageous if additional drainage pipes (not shown) are arranged along the pipes 9. Depending on the depth at which the pipes 9 lie, these can be air or liquid drainage pipes. The fuel tanks 7 also advantageously provide additional air and liquid drainage pipes 1 and 2.

The drainage pipes 1 and 2 are connected to a treatment device 8 via suction means, which can create an underpressure in the drainage pipes. This treatment device can comprise sampling means and / or analysis means and / or detection means and / or cleaning means for cleaning soil. air and / or liquid. When air is extracted from the soil, a forced evaporation of volatile components present in the soil takes place, as a result of the underpressure provided in the air drainage pipes. In the air drainage pipes, the soil air with the volatilized components is collected and discharged to the treatment device 8. Here the soil air is treated, in the sense that contaminants are detected or analyzed, or that soil air is sampled for analysis in a laboratory, for example, and / or that the soil air is cleaned.

For the detection and analysis means, a PID meter (PID = Photo ionisation detector), FID meter (FID = flame ionisation detector), the DrSger method, active carbon tubes, air bags with additional GC analysis (GC = Gas Chromatography), the FTIR method (FTIR = Fourier Transformed Infra Red), etc. An apparatus as described in EP-B1-Ο.385.555 can advantageously be used for the cleaning agents. However, it will be clear that other detection / analysis means and cleaning agents can also be used very well.

The air and / or liquid drains are in particular applied in those places where the risk of soil contamination is high. In the case of a fuel point of sale, these places are located in particular: under the liquid-tight pavement and around it; around the storage tanks 7 »around the fuel lines 9 * and near the filling points for the storage tanks 7 ·

The soil section above the groundwater level (the unsaturated zone) is particularly suitable for manipulating the possible contamination, since micro-organisms present in this soil section are stimulated by extracting soil air from this soil section. As a result of the underpressure in the air drainage pipes, there will also be transport of oxygen from the ambient air to the soil part above the groundwater level. This oxygen is an excellent source of oxygen for microorganisms living in this soil section. These microorganisms can then biodegrade any impurities into non-harmful compounds or less harmful compounds.

Such biostimulation can be improved by adding biomass and nutrients for this to the soil part above the soil level. This biomass and nutrients can possibly be introduced into the soil via the air drainage pipes. The availability for biodegradation of the contamination can be improved by the introduction of surfactants, such as detergents. These substances can also improve the effectiveness of flushing or leaching of the soil through improved absorption. During this introduction via the drainage pipes, the extraction of fluids from the soil can optionally be stopped for a short or longer period of time.

The air drainage pipes and the liquid-tight pavement are preferably installed at a pumping station, as shown in the figure, near the fuel pumps. For the extraction of soil air from the soil, it is advantageous if the air drainage pipes are at least about 1 meter above the ground water level since little or no groundwater is then drawn in. The air drainage pipes must also be deep enough in the soil, so that they are not damaged when, among other things, the liquid-tight pavement and other installations are placed on the ground. The air drainage pipes along the underground pipes 9 and / or at the storage tanks 7 · are preferably in the vicinity of these pipes 9 and storage tanks 7, respectively.

The liquid drainage pipes are preferably applied substantially perpendicularly below the air drainage pipes, but at a greater depth than the air drainage pipes. Preferably, these liquid drainage pipes are located at least 1 meter below the ground water level in a sandy environment.

Depending on, among other things, the soil conditions and the ground water level, it is possible to apply both air drainage pipes and liquid drainage pipes, but it is also conceivable to apply only air drainage pipes or only liquid drainage pipes. For example, if the groundwater is very high, it will in practice become very difficult to impossible to install air drainage pipes. At a lower groundwater level, such as from 4 meters below ground level, and on solid rock soils, the drainage pipes, possibly in combination with horizontal drainage pipes, can also be applied vertically, making them suitable for so-called deep well and / or string drainage. Furthermore, at a low groundwater level, that is to say at a large unsaturated zone, a number of layers or levels can also be applied with horizontal air drainage pipes. However, fluid drainage pipes at multiple depth levels are also conceivable in principle.

The frequency for taking soil air and / or groundwater samples must in particular be adapted to the distribution of the contamination in groundwater. The determining factor here is the natural groundwater flow rate on the one hand, and the possibility of attracting contaminated groundwater against the natural groundwater in the direction of flow in the other direction, on the other hand.

Taking into account a certain time interval between sampling, analysis and taking organizational and logistical measures, a sampling frequency of preferably twice a year is desirable. The sampling frequency must be such that any contamination of the groundwater can still be controlled with the aid of the drainage pipes, so that the drainage pipes present in the ground can suffice for remediation and no additional measures need to be taken. As an example, a soil contamination situation can be given, where a soil with a water permeability factor (k) of 30 m / day, a groundwater flow rate (v) of 30 m / year, a package thickness (D) of 50 m, and extraction flow rate (Q) of 353 m3 / day (= 15m3 / hour) a contamination spot spread up to 25 m downstream in the groundwater can be controlled with a sampling frequency of 2 times a year. The sampling frequency can be adjusted for soils where the groundwater flow rate is very high or very low.

Many variants and extensions are possible on the methods and device according to the invention. For example, it is conceivable at a petrol station to lead the (domestic) waste water, possibly after pre-treatment, for example by means of a septic tank to the treatment device 8 and to clean it here, and to release vapors released at the fuel pumps, filling points, vents 10, etc. catch it, lead it to the treatment device 8 and clean it here.

Claims (21)

1. Method for detecting soil contamination or in-situ remediation of contaminated soil, whereby contaminated air via one or more air drainage pipes, which are located in the soil above the groundwater level, and / or contaminated liquid via one or more other liquid drainage pipes , which are located in the soil below the groundwater level, extract it from the contaminated soil, and subject the thus extracted air and / or liquid to analysis or purification. A method according to any one of the preceding claims, wherein the air drainage pipes extend substantially horizontally, and are preferably at least 1 meter above the groundwater level. A method according to any one of the preceding claims, wherein the liquid drainage pipes extend substantially horizontally, and are preferably at least 1 meter below the groundwater level. Method according to any one of the preceding claims, wherein a number of air and / or liquid drainage pipes are arranged parallel to each other and at a mutual intermediate distance, preferably at least 2 to 3 Ui, in a substantially horizontal plane. A method according to any one of the preceding claims, wherein an underpressure, for example of 1 to 10 kPa and preferably of 3 to 6 kPa, is applied in the air drainage pipes. A method according to any one of the preceding claims, characterized in that the bioactivity of the soil is stimulated by introducing biomass and / or nutrients for biomass into the soil, preferably via the air and / or liquid drainage pipes. A method according to any one of the preceding claims, characterized in that the air and / or liquid extracted from the soil is analyzed for volatile compounds. A method according to any one of the preceding claims, wherein a purification device is provided for purifying air and / or liquid extracted from the soil. A method according to claim 8, wherein waste fluids are treated in this purification device. Device for applying the method according to one of the preceding claims. 11. Method for building, renovating or renovating a chemical installation, such as a filling station, in which a number of drainage pipes are placed in the soil under the chemical installation, these drainage pipes are installed above and / or below the groundwater level, the drainage pipes are connected to suction means for applying a negative pressure in the drainage pipes, and connecting the drainage pipes to a treatment device. A method according to claim 11, wherein a number of drainage pipes are arranged such that they extend substantially horizontally. A method according to claim 11 or 12, wherein a liquid and / or gastight layer is applied between the drainage pipes and the chemical installation. A method according to any one of claims 11-13. in which part of the soil is first excavated and replaced by a sandy soil material, and drainage pipes are provided in this sandy soil material. A method according to any one of claims 11-14, wherein a number of trenches are excavated in the soil and replaced by a moderately fine to coarse sand, and drainage pipes are provided in this moderately fine to coarse sand. A method according to any one of claims 11-15. whereby the air rotation pipes are installed at least 1 meter above the groundwater level. A method according to any one of claims 11-16, wherein the liquid drainage pipes are arranged at least 1 meter below the groundwater level. A method according to any one of claims 11-17, wherein the treatment device comprises a purification device, and conduits for waste fluids are connected to the purification device. A method of building, renovating or renovating a filling station according to claim 18, wherein the pipes for waste fluids comprise pipes for domestic waste water and / or pipes for above-ground released and collected fuel vapors. 20. Application of an underground drainage system with: - air drainage pipes in the soil above the groundwater level, and / or - liquid drainage pipes in the soil below the groundwater level, for the analysis and possible remediation of contaminated soil. Use according to claim 20, wherein the air and / or liquid drainage pipes extend substantially horizontally in the soil. ********