NL1004739C2 - Purification of contaminated soil using isolation barrier - with simple gas removal and allowing building construction on land - Google Patents

Abstract

Contaminated soil (1) is isolated from its surroundings (2) by covering it with a liquid- and gas-tight cover (4,5) so that gaseous components present in, or close to, the contaminated soil can flow to a higher level under the cover. Means (7,8) are provided to remove the collected gas. Also claimed is a method for cleaning soil by the method described above using the removed gas as power source.

Description

Method for insulating soil

The invention relates to a method for insulating soil. Methods for insulating soil, especially when this soil is contaminated, are known. It is known, for example, to excavate an area with contaminated soil to a depth of one to a few meters, after which it is possible to apply around a sealing wall, usually in the form of a sheet pile or foil wall. Such a sealing wall is usually placed many meters deeper into the ground. Subsequently, the removed contaminated soil 10 is replaced by clean soil, whether or not preceded by applying a foil layer under the clean soil.

This method works satisfactorily, but can lead to problems if gaseous components are present in the residual contaminated soil or are formed by chemical reactions between the components present and / or biological processes under the influence of micro-organisms present. There are known cases where toxic gases have been observed in significant concentrations in the indoor environment, particularly in basements and crawl spaces of houses built on remediated land. This was particularly evident in complaints such as dizziness, headache and nausea among residents. Depending on the nature of the gaseous components released from the contaminated soil, odor nuisance can sometimes also occur.

It also happens that remediated soil still appears to contain residual contamination or is contaminated by non-remediated soil located below. Certainly in the latter case it is difficult to adequately remediate the site in question, where the ground 25 is present, in an economically acceptable manner, for example to make it suitable for housing construction.

The present invention aims to find a solution to these problems and in particular to prevent such problems.

The invention therefore relates to a method for insulating soil, wherein (i) the soil to be insulated is covered at the top with a liquid and gas-tight covering layer which is ultimately located underground and of such a geometric shape that gaseous components, which the contaminated soil is present and / or formed under the covering layer, can flow to at least one higher part directly below the covering layer, and (ii) the covering layer at such an higher part is provided with 5 means to to collect collected gaseous components.

Thus, the cover layer should be shaped such that there is at least one portion directly below the cover layer, which is higher than the insulated soil at the edge of the cover layer. In this way it is achieved that gas present or formed under the covering layer flows to the highest point or the highest points directly below the covering layer, where it can subsequently be removed.

The method according to the invention is therefore very suitable for insulating contaminated soil, but it is also very suitable for insulating remediated soil, under which there may still be contaminated soil or in which residual contamination may still be present. In order to increase the certainty that no contamination is released from the soil after construction, the remediated soil can then be isolated by means of the method according to the invention. After the application of a layer of thin thickness (0.5 to 1.5 meters is sufficient), the insulated soil is almost certainly protected from the release of contaminants. The application further speaks of insulating contaminated soil, although, as explained, it may also include remediated soil.

The method according to the invention is very suitably combined with the provision of one or more (vertical) sealing walls, whereby the soil to be insulated is separated all around from the surrounding soil. Such a sealing wall is then connected to the cover layer, preferably in a gastight manner. In this way, a package of (contaminated) soil can be completely insulated. It depends on the degree and nature of the contamination, as well as the extent to which horizontal migration of contaminants could take place, whether one or more sealing walls are used.

As a sealing wall, if it is used to separate the contaminated soil to be insulated from the surrounding soil, all known walls which can be applied in the usual ways can be used. Examples of such materials are steel, concrete, certain clays, 1004739 3 bentonite and plastics, such as polyvinyl chloride (PVC) and high density polyethylene (HDPE). The first two materials are used in particular for rigid sealing walls, also called sheet piling, while plastics are generally used as flexible foil walls with a much smaller thickness (a few millimeters). Preferably, however, use is made of sealing walls consisting of clay-containing gel or a mixture of bentonite, water-soluble polymer (in particular polyacrylamide and / or polyacrylic acid) and filler (in particular sand), from which, after adding water, an excellent sealing wall is formed. Depending on whether active bentonite (sodium bentonite) or inactive bentonite (calcium bentonite) is used, an amount of activator can be added. Such activators are known and include sodium and lithium carbonate and various sodium and lithium phosphates, among others. Examples of useful mixtures are described, for example, in EP-A-0,244,981; GB-A-1,439,734 and WO-A-94/18284. The thickness of such a sealing wall can vary within fairly wide limits and will normally be between 5 and 100 cm. Preferably, however, a thickness of 10 to 50 cm is used. The installation of such a wall can be effected by digging a trench with the desired depth and width in which all components are arranged. This can be done, for example, by first mixing all components including water into a gel and applying this gel in the slot. An alternative method is to first apply all components in dry form, after which the sealing wall is formed under the influence of natural water (groundwater and / or rainwater), added water or a combination of both. As mentioned, the sealing wall has a gel-like structure and is therefore quite flexible, which is particularly important for insulating soil consisting of different layers of soil which can also show some movement in the horizontal direction or in the vertical direction.

After the contaminated soil has been excavated to the desired depth and, if desired, the sealing wall has been applied, the covering layer is applied. Optionally, the sealing wall, if present, and the covering layer can also be applied simultaneously. The soil under the covering layer is the contaminated soil to be insulated.

As mentioned, this ground to be insulated is covered at the top by a liquid- and gastight covering layer, which is optionally gastight around the edge 1004739 4 connected to the sealing wall and which has a shape such that at least one part is directly below the covering layer, which is higher than the insulated ground at the edge of the covering layer. This creates one or more higher parts immediately below the cover layer. The number of these higher parts under the covering layer mainly depends on the surface of the contaminated soil on which the covering layer is applied and the amount of gas that is released from the contaminated soil and which has to be removed. Due to this shape of the covering layer, the gaseous constituents present in the contaminated soil located under the covering layer will move along the underside of the covering layer 10 to the higher parts below the covering layer. An increased gas concentration will therefore develop at these higher parts, after which the gas collected there can be discharged by applying suitable means for removing gas in the cover layer at these higher parts.

Contaminated soil may of course be located in the higher elevation. But in those cases where the contaminated soil has a pore structure such that the permeability of gas is not particularly great, as can for instance be the case with clay soil, it may be preferable to fill the higher parts with a material that is much more gas permeable is. An example of such a material is sand, preferably coarse-grained sand.

The creation of the aforementioned higher parts under the cover layer can be realized in different ways and the cover layer can therefore have different shapes. Some examples of suitable shapes are shown in Figures 2a, 2b and 2c.

Preferably, there are only one to ten parts located higher under the cover layer, because in this way the number of points where gas must be discharged can be properly controlled and operated. However, more than ten parts located higher up can also be used, especially for insulating large areas. At each higher part, the covering layer is provided with means for discharging the gaseous constituents present in the contaminated soil, which collect in this higher part.

The thickness of the cover layer will generally vary from 5 cm to 100 cm and preferably from 10 cm to 50 cm, but is not limited to these thicknesses. The thickness of the cover layer may be more or less uniform over its entire surface, but may also vary. Preferably, the covering layer has a more or less uniform thickness, on the one hand because this is often easier to realize and on the other hand because it is most economically advantageous.

The covering layer can have all kinds of shapes, as long as there is at least one higher part directly below the covering layer 5. For example, the cover layer can take the form of a more or less round dome, a cone, a pyramid-like shape, as well as all kinds of intermediate shapes or combinations thereof. Of course, a certain shape can occur several times in a single covering layer. For example, a form in which two planes are placed at an angle to each other with their longitudinal sides, in which the cutting line between these planes slopes upwards to a certain point and then slopes again, or in which the cutting line slopes upwards against the sealing wall, is for instance suitable.

The materials that make up the cover layer are the same as discussed above for the sealing wall (steel, concrete, bentonite, certain clays, plastics, and the like). Preferably, however, a clay-containing gel or a mixture comprising bentonite, polymer and an inert filler, preferably sand, is used. Depending on the type of bentonite (active or inactive), an activator may be added, such as sodium or lithium carbonate or various sodium or lithium phosphates. Preferably a mixture is used, as described in WO-A-94/18284 (ie a dry mixture of inactive bentonite, activating agent, water-soluble polymer and possibly inert filler) or a mixture based on active / activated bentonite, water -soluble polymer and sand. Such a mixture can be applied in dry form to the contaminated soil in more or less uniform thickness, after which a covering layer is formed after adding water. Optionally, the mixture can also be applied as a gel to the contaminated soil, i.e. after water has been mixed in it. In order for the bottom side of the covering layer to have the correct shape, the ground on which the covering layer is applied must already be formed in such a way that at least one higher part can be distinguished.

Depending on the destination of the remediated site, the highest point of the top side of the covering layer is usually at a depth of 0.5 to 10 meters, preferably 1 to 5 meters. The difference in height between the highest and lowest point of the surface under the covering layer can vary within wide margins, but from a practical point of view a difference of at most 7.5 meters will be preferred. Larger height differences are of course possible, but in practice will require such large excavations that it is unfavorable from an economic point of view. Furthermore, with such large height differences, a lot of clean soil must also be applied to the covering layer, which is also not economically desirable. A difference in height between 0.2 and 5 meters will usually be very suitable.

The means for discharging the gas that collects in the higher parts immediately below the cover layer can in principle be any means known for this purpose. Very suitably, however, such means comprise at least one pipe, which at one end is in direct communication with the gaseous constituents present in the polluted soil at the one end by means of an opening in the covering layer at a higher part below, and at the other end is in communication with the air or with means for processing these gaseous components. The latter may include installations for purifying gas, for example via oxidation (incineration) or other (catalytic) chemical reactions, possibly after dissolving the gas in a suitable solvent. The gas can also be neutralized by passing it into an acidic or basic solution, depending on whether it is an acidic or basic gas. Another very suitable option is to pass the gas through a compost filter, a biobed or bed of absorbent material, such as activated carbon. The exact method will generally depend on the toxicity and amount of the gas.

If there are several higher parts directly below the cover layer, where gas can collect from the insulated, contaminated soil, each of these higher parts is preferably connected to a pipe, through which the gas can be discharged. The different pipes can very suitably still come together under the ground in a single pipe which then rises above the ground. In this way, the discharge of the gas above ground is easier to control. An alternative is to let all pipes rise above the ground separately. In this way it is possible to determine more precisely where the impurities are highest. The pipes can optionally also be connected to means which forcefully extract the gas from the contaminated soil, such as, for example, fans. Gas removal can also be stimulated by injecting air into the ground, for example through the discharge pipe (s) or through other injection points. In this way, the gaseous pollutants from the higher parts are driven underneath the cover layer, while dilution of these pollutants also occurs.

It is recommended to use a water level management system to check and maintain the moisture level of the insulated soil as well as to monitor the groundwater level. Because gas is extracted from the contaminated soil, the moisture can drop and if the moisture content becomes very low, the covering layer, especially if this is a covering layer based on a clay-containing gel or bentonite, could crack. Such systems for measuring and controlling the humidity level are known and are also used in practice. The known level control systems can therefore be used very suitably in the method according to the invention. In addition, suitable means are also used to regulate the moisture content of the soil on top of the covering layer. For example, there may be drainage means that drain rainwater.

In order to clean the contaminated soil under the covering layer without extensive excavation work, the means for removing gaseous constituents present in the contaminated soil can also be used for introducing into the contaminated soil means that clean the contaminated soil. Such agents can be biological in nature, such as microorganisms that can degrade certain toxic chemical compounds, but can also be agents with a neutralizing, oxidizing or reducing effect, depending on the nature of the impurities in the relevant isolated soil. Nutrients for micro-organisms already present in the soil can also be added to the contaminated soil. The microorganisms will be able to multiply so quickly, so that their cleaning effect will increase accordingly.

The cleaning of soil by means of micro-organisms, also referred to as in-situ remediation, is particularly interesting if a certain contaminated location has to be prepared for construction in a relatively short time. By applying the insulation method according to the invention, a covering layer can then be applied after excavation of the site, to which a living layer suitable for building up can then be applied immediately. Remediation of the contaminated soil present under the covering layer can then take place by adding micro-organisms and / or nutrients via the means for the discharge of the gas.

1004739 8

The invention therefore also relates to a method for the remediation of contaminated soil, wherein after application of the above-described method for isolating contaminated soil, the means for discharging gaseous components present in the contaminated soil are also used for introducing agents into the contaminated soil to clean the contaminated soil. Such agents are preferably microorganisms and / or nutrients for these or already present microorganisms.

The invention is further illustrated by a number of figures.

Figure 1 illustrates a representative embodiment resulting from the method according to the invention, while figure 2 shows three possible forms of the cover layer. Both figures show side views of cross sections.

In Figure 1, the contaminated soil (1) is isolated from the surrounding soil (2) by a sheet pile wall (3) and a dome-shaped covering layer (4) of approximately uniform thickness. The covering layer (4) is connected at the edge (5) to the sheet pile wall (3) in such a way that no gas or liquid along this connection can leave the insulated ground and end up in the clean ground (6), which cover layer (4) is applied. A pipe (8) is arranged in the covering layer (4) at the higher part (7), through which the gases which collect in the higher part are discharged. A drainage system and a level control system, although preferably present, are not shown for the sake of clarity.

Figure 2 shows various forms of a covering layer (4), with one or more discharge pipes (8) therein, wherein this covering layer (4) is connected to sheet pile (3) at the edge (5). For the sake of clarity, the isolated soil, the clean soil and the surrounding soil are not shown.

1004739

Claims (8)

1. A method for insulating soil, wherein (i) the soil to be insulated is covered at the top with a finally underground liquid and gas-tight covering layer with a geometrical shape such that gaseous components, which are contained in the contaminated soil under the cover layer are present and / or are formed, can flow to at least one higher part directly below the cover layer, and (ii) the cover layer at such a higher part is provided with means for discharging the gaseous components collected there. 2. A method according to claim 1, wherein the soil to be insulated is separated all round from the surrounding soil by a sealing wall, which is connected, preferably in a gas-tight manner, to the covering layer. The method of claim 1 or 2, wherein the cover layer is a clay-containing gel. A method according to claims 1 or 2, wherein the cover layer consists of a mixture comprising bentonite, polymer and an inert filler, preferably sand. Method according to one or more of the preceding claims, wherein the highest point of the top side of the covering layer is 0.5 to 10 meters, preferably 25. to 5 meters, below the surface. 6. Method according to one or more of the preceding claims, in which the means for discharging gaseous constituents present in the contaminated soil comprise at least one pipe, which at one end via an opening in the covering layer at a higher part below it. is in direct communication with the gaseous components present in the contaminated soil and at the other end is in communication with the air or with means for processing these gaseous components. 1004739 A method for remediation of contaminated soil, wherein after applying the method according to one or more of claims 1-6, the means for discharging gaseous components present in the contaminated soil are also used for introducing into the contaminated soil of agents that clean the 5 contaminated soil. A method according to claim 7, wherein the means introduced into the contaminated soil are microorganisms and / or nutrients for these or already present microorganisms. ] Q **** 1004739