NL1002581C2 - Method of protecting the soil from contaminants and soil construction for protecting the soil. - Google Patents

Description

Short designation: Method for protecting the soil against contamination and soil construction for protecting the soil.

The invention relates to a method for protecting the soil against impurities originating from the contents of a storage tank located in or on the ground. The invention further relates to a ground construction for protecting the soil against contaminants originating from the contents of a storage tank located in or on the ground.

Such a construction is known per se from the

European Patent Application 456,094 which describes not only a base layer structure but also a cable disposed therein for displaying a signal when the storage tank leaks and the contents of the tank enter the ground. According to the said European patent application, an impermeable layer or an impermeable film for the liquid in the storage tank is applied to a foundation consisting of asphalt, sand, concrete or the like. Practice has shown, however, that a relatively rigid layer of asphalt or concrete can crack, so that the liquid from the storage tank can end up in the ground layer to be protected. A foil does not provide sufficient protection while sand or the like penetrates after a certain time.

Therefore, a method for protecting the soil against such contaminants and a soil construction that provides sufficient protection of the soil located under the storage tank or of the soil in the vicinity of the tank (s) has been sought.

The method according to the invention is characterized in that a sealing system which is closed to the bottom is arranged against the surface of the storage tank in or on the ground, which sealing system is built up of one or more layers 30, the sealing layer of which consists of a non-water and hydrocarbons permeable water-wetted smectite and polymeric layer.

Furthermore, it is preferable to apply a layer 1 above the smear-retaining layer 3, which ensures good contact between the soil construction and the surface of the storage tank. This layer 1002581 2 1 located against the surface of the bottom of the storage tank consists of an oil-impregnated ground mineral with hydrophobic surface.

By using the layer 1, good adhesion is obtained between the layer which is applied under the surface of the storage tank and the hydrophobic character of the material used provides a water-repellent effect. The term "storage tank" is to be interpreted broadly as it includes piping and the like.

Furthermore, it is preferred that a layer 2 is applied to layer 3 which contains particulate silicate.

Thus, it is particularly preferable to provide a sealing system composed of three layers, viz. A) a layer 1 of an oil-impregnated ground mineral 15 with hydrophobic surface, which is situated against the surface of the bottom of the storage tank.

b) a layer 2 of a particulate silicate compound applied under layer 1 and c) a smectite and polymer-containing layer 3 which is impermeable to water and hydrocarbons and which has been partially or completely wetted.

In particular, the smectite-containing layer referred to under c) is composed of one smectite-containing mixture of clay or smectite-containing natural stone with more than 0.5% by weight of one or more solid inert filler (s) with an average particle size greater than 25 0 0.05 mm, 0.8-6.0 wt.% Powdery solid activating agent and more than 0.2 wt.% Of a water-soluble polymer, the weight percentages being based on the amount of smectite of the mixture. Such a smectite-containing composition is known from WO94 / 18284. However, this PCT patent application does not disclose the method of protecting the soil from contaminants from the contents of an in-ground storage tank. Neither is a ground construction known from this as described in the present patent application.

An alternative to the layer 3 described under c) is a layer containing (1) a mineral clay selected from smectites with a three-layer structure and / or swellable silicates, which are optionally partially activated with 1% by weight (based on weight of the mineral 1002581 3 clay) of an activating agent selected from (i) alkali metal or ammonium salts with an anion which forms water-insoluble precipitates with alkaline earth metal ions and (ii) a smectite which is over-activated with such salts and (2) at least 0.6 wt% (based on the weight of the mineral clay) of a water-soluble polymer that can react with the clay and with a molecular weight between 50,000 and 20,000,000, which mixture can form a gel that can absorb and release water after adding 1 to 5% by weight (based on the weight of the mineral clay) of an activator selected from (i) alkali metal or ammonium salts with an anion forming a water-insoluble precipitate m et an alkaline earth metal ion and (ii) a smectite which is over-activated with such salts. Such a mixture is known per se from EP-A-335,653. From this European patent application a method is known for preparing a gel that is capable of absorbing and dispensing water, but it does not disclose the use of such a mixture as one of the layers in a soil construction to protect the soil from the leakage of hydrocarbons from an underground storage tank.

Much of the equipment for transporting or storing hydrocarbons, such as various pipes and reservoirs, is placed on the ground or surrounded by the ground. The effective sealing of such equipment is an important requirement to avoid contamination of the soil. To provide effective protection, various requirements must be met such as the fact that the seal 25 must protect the metal of the reservoir from the corrosive effect of aqueous mixtures, which can be achieved by preventing the reservoir from coming into contact with the water present in the ground. Furthermore, the closure of the reservoir must have a sufficient load-bearing capacity to be able to carry the heavy load and must be sufficiently flexible to be able to absorb possible movements of both the ground and the reservoir. Also, the soil construction that has a closing effect must provide sufficient insulation against hydrocarbons that are present in the reservoir and that can leak out of the reservoir.

These objectives can be achieved by applying a method according to the invention or with the aid of a ground construction according to the invention.

10 0 Ζ 58 1 4

The invention is further elucidated with reference to the annexed drawing, in which in figure 1: a ground construction according to the invention is shown.

The construction as shown in figure 1 will be further explained below.

To protect the substrate 6 and the underlying soil against the contents of a reservoir consisting of bottom 8 and wall 7, a system of layers 1, 2 and 3 has been arranged under the bottom 8 as described above, whereby between layers 2 and 3 and / or a textile cloth 5 can be arranged between 1 and 2. A drainage 4 can also be arranged between the layers 2 and 3. Optionally, the drainage can also be arranged between layers 1 and 2.

The further construction of the layers, the compositions and the thickness of the layers as used will be further described below.

The new soil construction system according to the invention is particularly suitable for shielding the metal, hydrocarbon-containing reservoirs against corrosion caused by the soil, in particular against the corrosive effect of the groundwater. Furthermore, the soil construction is flexible enough to absorb any movements of the soil and the soil construction effectively prevents any leaking hydrocarbons from entering the soil layers protected against contamination.

In particular, the ground construction consists of several layers, preferably of three layers, the top layer of which contacts the bottom or the wall of the reservoir from an oil-impregnated ground mineral with hydrophobic surface. Preferably, this mineral contains a corrosion inhibitor, which is in particular an oil-soluble amine compound. By impregnating the mineral with oil, a good adhesion is obtained with the metal bottom of the reservoir and a good adaptation to the shape of the bottom is obtained. Preferably, the amount of added oil is 10-60% by weight, based on the weight of the mineral. Furthermore, this prevents groundwater from coming into contact with the metal of the bottom or the wall of the reservoir. It is also prevented that the water required for the smectite and polymer-containing layer 1002581 5 comes into contact with the bottom or the wall of the reservoir. The possible presence of a corrosion inhibitor significantly reduces the risk of external corrosion of the metal container. This layer 1 has a layer thickness of at least 0.3 cm and is preferably 4-6 cm thick.

This layer 1 can also be mixed with a particulate silicate.

The intermediate layer 2 contains a particulate silicate, which is preferably mixed with a ground mineral with a hydrophobic surface. However, no oil has been added to this. This layer can also contain a solid silicate. Without the addition of the ground mineral, this layer can serve as a drainage layer. A drainage pipe made of a plastic such as polyethylene can also be placed. The second layer has a thickness of more than 1 cm, preferably 5-30 cm. This layer 2 serves to absorb the load by the holder and to compensate for any movement of the ground. The addition of the ground mineral with hydrophobic surface serves to absorb potentially leaking hydrocarbons and prevent groundwater from penetrating upwards.

The hydrophilic wetted part of the layer 3 has a sealing effect against the possibly leaking hydrocarbons, thereby preventing any leaking hydrocarbons from entering the soil layer 6. Furthermore, it forms a coherent flexible layer that can well follow the soil deformations. The lower possibly still dry part of layer 3 forms a firm layer with a high load-bearing capacity and forms a barrier against groundwater.

Textile cloth 5, which is preferably moistened with water, can be provided in particular between the layers 2 and 3. This textile cloth (geotextile) ensures an even distribution of the load over the layers and gives a good separation of layers. In principle, this cloth can be applied between all layers.

The top layer 1 of the basic construction according to the invention consists of an oil-impregnated ground mineral with a hydrophobic surface which can contain a corrosion inhibitor. As minerals with a hydrophobic surface, talc, Manusil (brand) and ground oil-containing materials can be mentioned. Mixtures of two or more such ground minerals can also be used. The mineral oil added to the ground mineral is preferably a 1002581 6 liquid or semi-solid hydrocarbon with more than 10 carbon atoms or a mixture thereof. The term "oil" also includes oil mixtures. Bitumen and wax can be mentioned as semisolid hydrocarbons. The oil for impregnation must be used in an amount such that a fine coating of oil is obtained on the ground mineral particles and yet the mineral is easy to process. Examples of corrosion inhibitors to be added which are compatible with the oil system and which are added to layer 1 are oil-soluble amines such as Nalco 192 and 169, Nalcamin, Cronox 100 and Dodigen 213. These indicated corrosion inhibitors are listed with the brand designation. It is also possible to reduce the cost of adding the corrosion inhibitor only to the top of layer 1.

Layer 2 consists of particulate silicate, preferably mixed with a ground mineral with a hydrophobic surface. The ground mineral with the hydrophobic surface may be one of the materials used in layer 1. Particulate silicates are sand, gravel, gravel and ground siliceous asphalt such as ground brick or pans. The particulate silicate itself can be a mixture of such materials. Layer 2 can also serve as a drainage layer.

Layer 3 of the basic structure according to the invention is a clay and polymer-containing mixture, as described in the above-mentioned PCT patent application WO94 / 18284 or in EP-A-0 335 653. In addition to the active ingredients, layer 3 may contain inert filler. Part of the bottom layer must be wetted so that the wet, flexible and hydrophilic layer thus formed has a sealing effect against leaking hydrocarbons and rising groundwater. Typically, the thickness of the wetted layer is more than 3 mm.

According to another preferred embodiment in the basic construction according to the invention, layer 2 consists of two sub-layers 2.1 and 2.2, wherein sub-layer 2.1 consists of a mixture of particulate silicate compound and ground mineral with hydrophobic surface and sub-layer 2.2 consists of particulate silicate compound.

Similarly, layer 3 may also be composed of two sub-layers 3.1 and 3.2, wherein the sub-layer 3.1 adjacent to layer 2 has a low content of inert solid filler and sub-layer 3.2 has a higher content of inert solid filler.

1002581

Claims (28)

Method for protecting the soil against contamination originating from the contents of a storage tank located in or on the ground, characterized in that a sealing sealed to the bottom against the surface in or on the ground of the storage tank system, which sealing system is composed of one or more layers, the sealing layer of which consists of a water-wetted smectite and polymer-containing layer that is impervious to water and hydrocarbons. Method according to claim 1, characterized in that the smectite-containing layer 3 is a mixture of clay or smectite-containing natural stone, with more than 0.5% by weight of one or more solid inert filler (s) with an average particle size greater than 0.05 mm, 0.8-6.0 wt.% powdery solid activating agent and greater than 0.2 wt.% of a water-soluble polymer, the weight percentages being based on the amount of smectite of the mixture , is applied. 3. A method according to claim 2, characterized in that the top side of layer 3 is wetted with water to form a hydrophilic surface. Method according to claim 3, characterized in that the thickness of the water-wetted interface is at least 0.3 cm. 5. Method according to claim 1, characterized in that as the layer 3 a mixture is used, which (1) contains a mineral clay, selected from smectites with a three-layer structure and / or swellable silicates, which are optionally partially activated with 1 wt% (based on the weight of a mineral clay) of an activator selected from (i) alkali metal or ammonium salts with an anion that forms water-insoluble precipitates with alkaline earth metal ions and (ii) a smectite over-activated with such salts and (2) at least 0.6% by weight, (based on the weight of the mineral clay) of a water-soluble polymer that can react with the mineral clay and with a molecular weight between 50,000 and 20,000,000, which mixture is a gel that can absorb and release water after adding 1 to 5% by weight (based on the weight of the mineral clay) of an activator selected from (i) alkali metal or ammonium salts with an anion containing an water 1002581 δ insoluble precipitate with an alkaline earth metal ion and (ii) a smectite over-activated with such salts. Method according to claim 5, characterized in that the mixture of layer (3) contains 1.5-15% by weight of a water-soluble polymer 5. Method according to claims 1-6, characterized in that a layer 1 is applied against the surface of the bottom of the storage tank, consisting of an oil-impregnated ground mineral hydrophobic surface. Method according to claim 7, characterized in that a corrosion inhibitor is added to layer 1. Process according to claim 8, characterized in that an oil-soluble amine compound is added as a corrosion inhibitor. Method according to claims 7-9, characterized in that the corrosion inhibitor content in layer 1 near the interface with the storage tank is highest. 11. A method according to claims 1-10, characterized in that a layer 2 of a particulate silicate compound is applied to layer 3. Method according to claim 11, characterized in that layer 2 is mixed with a ground mineral with a hydrophobic surface. Method according to claims 1-12, characterized in that a textile cloth is applied between layer 1 and layer 2. A method according to claims 1-13, characterized in that a textile cloth moistened with water is applied between layer 2 and layer 3. 15. Process according to claims 7-14, characterized in that talc, Manusil® or oil-based ground slate is used as the ground mineral with hydrophobic surface. A method according to claims 7-15, characterized in that as an oil for impregnating the ground mineral with hydrophobic surface a crude mineral oil, a liquid or semi-solid hydrocarbon with more than 10 carbon atoms, or a mixture thereof, is applied. Method according to claims 11-16, characterized in that layer 2 is composed of two sub-layers 2.1 and 2.2, namely a sub-layer 2.1, consisting of a mixture of a particulate silicate compound and ground 1 0 0 2 5 8 1. mineral with hydrophobic surface, and a sublayer 2.2, consisting of a particulate silicate compound. 18. Method according to claims 2-17, characterized in that layer 3 is composed of two sub-layers 3.1, 3.2, namely a sub-layer 3.1 adjacent to 5-layer 2 with a low content of inert solid filler and a sub-layer 3.2 with a high content of inert solid filler. 19. Ground construction for protecting the soil against contamination originating from the contents of a storage tank situated in or on the ground, characterized in that a sealing system is arranged around the bottom of the storage tank situated in or on the ground. layer consists of a non-water and hydrocarbon permeable wetted smectite and polymer-containing layer. Soil construction according to claim 19, characterized in that it is built up according to a method described in claims 2-18. Soil construction according to claims 19-20, characterized in that the thickness of layer 3 is more than 0.3 cm. Soil construction according to claims 19-21, characterized in that the layer (3) is 4-10 cm. Soil construction according to claims 20-22, characterized in that the amount of added oil to layer 1 is 10-60% by weight. Soil construction according to claims 20-23, characterized in that the layer thickness of layer 1 is at least 0.5 cm. Soil construction according to claims 20-24, characterized in that layer (1) is 4-10 cm. Soil construction according to claims 20-25, characterized in that layer 2 is thicker than 1 cm. Soil construction according to claim 26, characterized in that the thickness of layer (2) is 5-30 cm. Ground construction according to claims 20-27, characterized in that a drainage is arranged under layer 1. 1002581