DE3605042A1 - process for the biological treatment of contaminated soils, and device for carrying out the process - Google Patents

Abstract

The invention relates to a process for the biological treatment of contaminated soils and to a device for carrying out the process. A gas which contains nutrients for microorganisms is introduced into the soil horizontally or vertically in a predetermined grid pattern in such a way that microorganisms which degrade even complicated synthetic organic substances colonise each of the zones where gas is introduced into the soil. The gas is passed through tubes which are made of non-porous, gas-permeable material and which run horizontally or vertically through the soil. The tubes may be armed. The tubes are placed in such a way that they form loops, whereby the gas is circulated. The development of a biofilm is brought about on the external surface of the tubes.

Description

The invention relates to a method for biological Treatment of contaminated soil bodies and a pre direction to carry out the procedure.

It is known that as a result of production and storage of synthetic organic substances rich places for the enrichment of such substances in the Ground is coming. Here there is a risk of groundwater pollution. Furthermore, those with such substances contaminated land is usually considered unusable to watch. To eliminate these soil contaminations there is the possibility of a chemical or thermal Combustion. Chemical combustion requires that Leaching and concentration of the pollutants as first process step, which in most cases is not is easily possible. Thermal combustion is due the high content of non-flammable substances and because of the volume of the masses to be treated in many Cases technically and financially not feasible. From most of them also synthetic organic substances can be assumed that they are from the micro living in the ground organisms can be biodegraded. The Ge however, the speed of mining operations is for some Substances very slowly. The advantage of a biological There is degradation of the contaminating substances in the soil in that the danger is eliminated on the spot. The substances are through metabolic processes and through iterative substance conversion via microbial feeding chains mineralized and so in the natural starting materials converted.

The object of the invention is thereby one targeted biodegradation of syn thetic organic substances to enable the enabled microorganisms to do this be activated that for an increase and the  Existence of competition and survival is required environmental conditions are provided, whereby also an incentive to recycle more complicated organization niche substances is offered.

According to the invention. the problem is solved by that in the soil body in a predetermined grid stood horizontally or vertically a nutrient for micro organism-containing gas is introduced so that in the area of the respective gas entry in the soil body Microorganisms settle, the synthetic organic Dismantle soil substances even complicated structures. The gas to be introduced is preferably circulated by means of a hose arranged in a grid pattern in the floor grind from z. B. silicone rubber. Here it should be noted that the targeted enrichment and Ak Activation of specially trained microorganisms only succeeds if the soil body acts as a biological reactor is considered and operated accordingly. After Invention is based on the biological processes in the soil controlling and regulating accordingly.

Further features of the invention are set forth in the dependent Described claims. There is one in the drawings Embodiment of the device for performing the represented method according to the invention, at whose case game the invention is explained in more detail. It shows

Fig. 1, the apparatus for treating soil, in a schematic representation,

Fig. 2 shows the installation of the hoses of the device in the bottom body in a schematic view.

The device 1 consists of a hose arrangement 17 which is formed from hoses 3 inserted into the base body 2 in a grid-like manner. The tubes 3 are formed into tube loops 11 and together via a flow 18 and a return 16 to form a circuit. A heat exchanger 6 and the gas pump 5 are arranged in the feed line 18 . The heat exchanger 6 is used to control the temperature of the gas to be introduced into the base body 2 , while the gas pump can be used to promote the circulation in addition to the circulation, possibly also to increase the pressure. The absorber arranged in the return 16 serves to filter out undesired substances which have been taken up by the gas flowing back from the base body 2 . In order to adapt the gas to be introduced into the soil body 2 with regard to its composition to the needs of the microorganisms located in the soil body 2 , the gas pump 5 is preceded by a metering device 4 . This metering device 4 has a number of metering pumps 19 with which, for. B. oxygen, nitrogen, hydrogen, methane, ammonia or the like. The gas mixture to be introduced into the soil body 2 can be admixed. The metering device 4 is preferably program-controlled, a specific adaptation to the requirements in the soil body 2 taking place on the basis of analyzes of the gas flowing in the return 16 or of soil samples. By introducing gas on the outer wall of the non-porous gas-permeable hoses 3, the formation of a biofilm 20 takes place , which is indicated schematically in FIG .

It is expedient to provide in the area of the hose arrangement 17 wells 21 , by means of which the floor body 2 can be sprinkled. This keeps it moist, which promotes living conditions for the microorganisms. The transport processes in the soil body and thus the transport to the active centers of the microorganisms in the vicinity of the tubes 3 are influenced by varying the amount of water applied. The infiltrating water can be put in wells and circulated. This makes it possible to keep the spread of the pollutants in the soil body 2 under control. At the same time, groundwater can be lowered in the area of the damaged soil body, so that synthetic organic substances are prevented from being washed away by groundwater.

To form the hose arrangement 17 , tubes 18 are driven into the base body 2 at a predetermined grid spacing, which have a tip 9 on the head side ( FIG. 2). The grid spacing depends on the locally given conditions of the soil body 2 and takes into account the transport rates in the soil. The pipe jackets 22 of the pipes 8 are supported on the tips 9 when driven into the base body. When the intended hose depth is reached, a hose 3 made of plastic such as silicone rubber is inserted into the tube 8 via an eyelet 12 at the tip 9 . The hose 3 forms a loop and extends to the low point of the driven tube 8 . A support fabric 15 can be placed around the ascending and descending hose 3 . The tube 8 is then pulled out of the base body 2 , the tube 3 with the support fabric 15 remaining in the base body 2 . The free end sections of the hose 3 are connected to horizontally extending inlet lines 13 and outlet lines 14 laid above or below ground, which serve as supply and disposal lines. These lines connect the hose loops 11 introduced into the base body 2 in a detent with one another and with the flow 18 and the return 16 and thus with the gas pump 5 and the metering device 4 . By means of the metering pumps 19 for the various gas components and the gas pump 5 , the gas passed through the hose arrangement 17 is circulated. Interfering foreign gases as well as carbon dioxide can be reduced in concentration by cleaning the gas flowing in the return 16 in the absorber 7 .

On the surface facing the body 2 and in the vicinity of the hoses 3 , the microorganisms should settle. The building materials and supplies required for this are provided via the gas flow within the tubes 3 and through the diffusion of the gas molecules through the tube material. The gas composition is chosen so that the demands of the microorganisms on the nutrient supply are satisfied at least temporarily. The possibility of simple and fast protein synthesis should be given. By periodically changing the gas composition, an incentive to process the organic substances brought in from the soil can be created. By periodically changing between aerobic and anaerobic conditions, propagation conditions and lack of easily usable substances, control over the community in the vicinity of the tubes 3 is exercised and an incentive to break down complicated synthetic organic substances is created. At the same time, microorganisms are enriched and activated, thus increasing the biological cleansing capacity in the soil.

After installation of the tubes 3 into the bottom body 2 and prior to drawing of the tubes 8 may be in the free spaces between the tubes 3 and the pipes 8 Bakteriensus be introduced inns. In the selection of the bacterial cultures concerned, attention must be paid to the special degradation properties, to the ability to reproduce under the conditions given by the transport of nutrients via the tubes 3 , and to competition with other soil bacteria. If proven hoses are used, the gas mixture can be passed through the hoses 3 with increased pressure. By increasing the temperature by means of the heat exchanger 6 , the volatility, especially of the organic gas components, is favored and the dependence of the biological reactions on the soil temperature is reduced. The device 1 can thus be used to set high reaction speeds all year round.

Using the device 1 , the described method can be used to treat contaminated soil bodies in situ. In this case, the gas-permeable hoses 3 are introduced vertically into the base body 2 . However, it is also possible to use the described method for treating excavated soils. For this, the dredged soil is applied in layers. The gas-permeable hoses 3 are in z. B. furrows laid horizontally, so that a sandwich structure takes place. In this case, too, the gas mixture flowing through the hose arrangement 17 influences the microorganisms located in the soil, which leads to the degradation of synthetic organic substances. Another advantage of the method is that it is also suitable to optimize the composting process. For this purpose, tubes 3 are inserted as tube loops in the form of mats in the material to be composted, a support fabric 15 preventing the tubes 3 from being damaged during installation and removal. In order to optimize the composting process, the tubes 3 are preferably flowed through with pure oxygen since this particularly influences the reactions of the microorganisms in the material to be composted.

Claims (25)

1. A method for the biological treatment of contaminated soil bodies, characterized in that a nutrient for microorganisms containing gas is introduced horizontally or vertically into the soil body at a predetermined grid spacing so that microorganisms settle in the area of the respective gas input into the soil body, the synthetic tables also break down organic substances with a more complicated structure. 2. The method according to claim 1, characterized in that that before or with the gas entry a bacteria suspension is introduced into the soil body, the Bacterial cultures match the synthetic orga African substances of the soil body adapted spe have specific degradation properties.   3. The method according to claim 1 or 2, characterized records that by periodically changing the gas composition of those in the soil body Biofilm alternately changing environmental conditions is exposed. 4. The method according to claim 3, characterized in that the biofilm is alternately anaerobic or aerobic Is exposed to environmental conditions. 5. The method according to claim 1 to 4, characterized records that the gas through horizontally or vertically hoses inserted into the floor from not porous gas-permeable material. 6. The method according to claim 5, characterized in that a hose made of a plastic like silicone Rubber or the like is used. 7. The method according to claim 6, characterized in that a hose with reinforcement is used. 8. The method according to claim 5 to 7, characterized records that the gas is laid through a loop Hoses are circulated. 9. The method according to claim 5 to 7, characterized in net that a bio on the outer surface of the hose film is brought to development. 10. The method according to claim 5 to 9, characterized records that the bacterial suspensions outside the Hose are inserted into the floor.   11. The method according to claim 5 to 10, characterized records that the gas with increased pressure and / or brought into the soil body at an elevated temperature becomes. 12. The method according to claim 5 to 11, characterized records that the soil body by sprinkling with Water is kept moist. 13. The method according to claim 12, characterized in that that the amount of water applied to influence the Transport processes in the soil is varied. 14. The method according to claim 1 to 13, characterized records that for installing the hoses in the ground body in from local conditions depending grid pitch pipes are driven, then a hose in each tube is introduced, then the pipes from the soil body are pulled out and then the end portions of the Hose loops with supply and disposal lines be connected to the metering pumps for ver different gas components are connected. 15. The method according to claim 14, characterized in that in the free spaces between the hoses and the A bacterial suspension was introduced into each tube becomes. 16. The method according to claim 14 and 15, characterized records that around the hoses in the tubes each a support fabric is placed.   17. The method according to claim 1 to 12, 15 and 16, characterized characterized that the hoses are laid horizontally and covered with dredged soil in layers will. 18. The method according to claim 17, characterized in that that the hoses turned into soil to be composted be placed. 19. The method according to claim 1 to 18, characterized records that for protein synthesis from the soil organic substances brought to the biofilm as basic nutrients and supplies in periodic Changing gas components such as oxygen, nitrogen, Hydrogen, ammonia, volatile and good degradable organic substances such as methane or the like through the hoses. 20. Device for performing the method according to claim 1 to 19, characterized by grid-like in the bottom body ( 2 ) introduced hoses ( 3 ) made of plastic such as silicone rubber or the like. Which flows through a gas or gas mixture with nutrients for microorganisms and are connected at the end section to a possibly programmable metering device ( 4 ). 21. The apparatus according to claim 20, characterized in that an absorber ( 7 ) is arranged in the return ( 16 ) of the hose arrangement ( 17 ). 22. The apparatus of claim 20 and 21, characterized in that a gas pump ( 5 ) is arranged in the flow ( 18 ) of the hose arrangement ( 17 ). 23. The device according to claim 20 to 22, characterized in that a heat exchanger ( 6 ) is arranged in the flow ( 18 ). 24. The device according to claim 20 to 23, characterized in that the gas pump ( 5 ) is connected on the suction side to the metering device ( 4 ). 25. The device according to claim 24, characterized in that the metering device ( 4 ) has metering pumps ( 19 ) for gas components to be introduced into the soil body.