RU2070102C1 - Method for burying of toxic industrial wastes - Google Patents

Abstract

FIELD: environmental control. SUBSTANCE: method for burying of toxic industrial wastes includes formation of dump from wastes on the water-proof screen, with wastes laid by layers and compacted, covering of waste layers with the second water-proof screen. Dump is formed above the level of environment on soil on which a layer of pipe-block material is laid. Water-proof screen is made from morainic loam and clays with easily dissolving compounds introduced into them which provides for exchange of bivalent cations with univalent ones. EFFECT: higher efficiency. 2 dwg

Description

 The invention relates to methods for the disposal of toxic industrial waste.

 A known method of waste disposal, which consists in drilling wells, each of which is filled with a certain amount of waste. This mass is compacted by vibration or pressing, after which another portion of the waste is poured and the compaction process is repeated. After filling the workings, its estuarine part is filled with a fertile layer of soil. To increase the stability and safety of storage of waste, the drills are drilled at distances that ensure their separation from each other by a sufficiently large mass of soil.

 The disadvantage of this method is the high likelihood of environmental pollution due to the filtration of groundwater through the cavity of wells with buried waste and the need to use large areas that meet certain requirements for the geological structure and hydrogeological conditions.

 The closest in technical essence to the invention is a method of landfill in natural recesses of the relief (beams, ravines, pits, etc.), including removal from the sides and bottom of a selected section of the soil-plant layer, layering and compaction of clays with a thickness of 2.5 3.0 m, layering and compaction of buried waste, overlapping the last clay with the same technology and laying a fertile layer for the restoration of the disturbed area.

 However, this method has several disadvantages: its scope is limited not only by the presence of certain landforms, but also by the fact that ravines and beams are elements of a hydraulic system and, therefore, are located in the river protection zone; the lower clay screen is not reliable enough to prevent environmental pollution with water-soluble compounds of toxic waste, since the capillary rise in clay pores is 3.5–4 m from the groundwater level; the application of the method is associated with significant transportation costs of clays, because deposits of this type of valuable mineral raw materials do not have wide development.

 The aim of the invention is to protect the environment from pollution by toxic industrial waste during disposal.

 This goal is achieved by the fact that in the known method of waste disposal, including the formation of a waste dump by stacking and sealing a waterproof screen, layering and compacting the waste, covering the latter with a second waterproof screen, the formation of a waste dump is performed above the level of the surrounding area on soil and plant soil, which lay a layer of coarse material, and as a waterproof screen using moraine loams and clays, which are easily incorporated into fouling of aq ble connections for the exchange of divalent cations with monovalent.

 A comparative analysis of the proposed method with the prototype shows that the claimed method differs from the known one in that the waste dump is produced on soil and plant soil on which a layer of coarse material is laid, and moraine loams and clays are used as a waterproof screen, which are easily incorporated soluble compounds providing the exchange of divalent cations to monovalent. Thus, the claimed method meets the criteria of the invention of "novelty."

 Known technical solutions for the disposal of waste. However, the waste is buried either in a drilled well or in natural recesses of the relief, but in all known solutions the soil-plant layer is removed at the base of the dump. In the proposed method, the soil-plant layer is preserved at the base of the dump, which serves as a natural geochemical barrier, protecting the geological environment, and therefore, the formation of the dump is produced above the environment. This feature, in combination with the other above-mentioned features, allows us to conclude that the proposed technical solution meets the criterion of "significant differences".

 A layer of coarse-grained material with a thickness of, for example, 0.6 m prevents the movement of capillary water and water vapor between the soils of the base of the dump and bulk, and in addition, the air trapped in the pores of this layer acts as a heat insulator, mitigating changes in seasonal temperatures, and consequently, the intensity of movement water vapor both up in winter and down in summer. This, in turn, allows not to limit the choice of the site due to the high occurrence of the groundwater level, which is a characteristic feature of the territory of development of glacial deposits.

 The use of moraine clay soils as waterproof is justified by the heterogeneity of their particle size distribution and low filtration properties (less than 0.05 m per day). This feature of soils provides them with good compaction in a refractory and semi-solid state and stability in slopes. The first advantage of moraine soils is quite widely used in hydraulic engineering for the construction of dams, dams, anti-filter screens, etc. The heterogeneity of the composition, providing high values of specific adhesion in soils, eliminates their heaving during freezing and the destruction of structural bonds when exposed to fluid water.

 When a concentrated solution of rock salt is introduced into the composition of moraine loams and clays, the sorption ability of clay particles increases. Moraine loams and clays, being heterogeneous soils, contain fragments of different rocks, including carbonate, which leads to the formation of divalent cations of calcium and magnesium in aqueous solutions surrounding mineral particles. It is known that clay particles are capable of sorbing not only water molecules on their surface, but also absorb ions from surrounding solutions. It is known that such absorbed ions are capable of exchange with other solution ions, i.e., they are exchangeable. So, the sodium cation replaces the previously absorbed calcium, which leads to an increase in the sorption capacity of the particles, because in the presence of a monovalent sodium cation, ceteris paribus, the particles bind a significantly larger number of water molecules than in the presence of divalent calcium and magnesium cations. Thus, the sodium cation, as it were, enhances the effect of clay particles on the properties of rocks, and divalent cations, on the contrary, reduce this effect. In other words, the replacement of divalent exchange cations in clay soils by sodium cations is equivalent in its effect on the properties of soils to an increase in the content of clay particles in them. Practice confirms the effectiveness of such an effect on clay soils, which is characterized by a decrease in filtering ability by a factor of ten, which justified the possibility of replacing valuable mineral raw materials with more common moraine soils, especially since their greater stability in slopes allows you to increase the height of the dumps, and therefore the volume buried waste.

 The absorption capacity of sodium cations by soil particles depends on the mineral type of clay and is taken into account when calculating the required amount of salt, based on the known values of the absorption capacity per 100 g of dry matter: 3 - 15 mEq. for kaolite, 10 40 mEq. for illite, 80-150 mEq. for montmorillonite. It should be noted that the introduction of rock salt in the soil reduces the depth of seasonal freezing, i.e., it stabilizes the temperature and humidity regime of waste storage.

 In FIG. 1 shows a scheme for the disposal of toxic industrial wastes on a scale of 1: 200; in FIG. 2 shows a section A A in FIG. 1, where 1 is the soil-plant layer; 2 moraine loam t / plastic; 3 plastic sandy loam; 4 coarse material; 5 bulk soil loam; 6 toxic waste; 7 trench; 8 entry.

 The development of moraine loams and clays with trenches 7 along the perimeter of the dump under construction, in addition to cheaper work due to the exclusion of the costs of loading, transportation and unloading, has another concept. Its essence lies both in the protection of areas with burial sites from accidental impacts, and in providing the ability to carry out control studies of the state of the geological environment, and to quickly identify specific areas of the penetration of toxic substances. Considering that the shallow occurrence of moraine loams and clays is characteristic of large areas, the most reasonable is the choice of sites with a depth of up to 2 m, because with a trench depth of 3 meters the volume of necessary soil is determined by simple calculation and is adjusted by changing the width of the trenches . Soils unsuitable for their intended use are intended to be either stored (soil-plant layer) for subsequent laying on the surface of the blade, or placed on the outside of the trench in the form of a protecting shaft (sandy loam, sand, soft-plastic loam).

 The preservation of the lintel between the site and the surrounding area with a width of up to 10 m (entrance 8) is provided to ensure the delivery of toxic waste to the disposal site and return transportation in case of development of technology for their disposal.

 Example. In connection with a railway accident in the Tver region at the Kulitskaya station of the Oktyabrskaya road in October 1990, two tanks filled with a mixture of benzene and toluene were destroyed. The total mass of contaminated soil was about 500 tons. The burial of contaminated soil was organized in the vicinity of the station. To this end, exploratory work has been carried out to identify the most favorable geomorphological conditions. The selected site was characterized by a flat relief, distance from the road, high occurrence of moraine loam and a depth of groundwater of 2.0 2.2 m with a slope towards a slight decrease in relief.

After laboratory studies of loam samples were performed, its physical and mechanical properties were determined and, taking into account the proposed design of the dump, as well as taking into account the unit cost of raw materials for the disposal of 1 ton of waste, the total amount of earthwork, the perimeter of trench 7 and its parameters were determined (see Fig. 1 and Fig. 2) as follows. Knowing the amount of waste being buried (500 tons) and bulk density (1.9 t / m ³ ), we determined the waste volume disposal parameter ≈270 m ³ equal to 2 x 7 x 20 m (height, width, length). Given that the thickness of the protective layer should be at least 2 m, and the angle of slope of the blade during its layer-by-layer formation and compaction of at least 65 ^o , it was determined that the total amount of the required amount of loam 5 will be 1560 m ³ . We determined the volume of soil needed to fill the entrance to the dump, based on the fact that its width is 5.5 m, length 22 m. This will be 180 m ³ . Next, the volume of coarse soil 4 at the base of the dump was determined at a height of this layer of 0.6 m and an area of 9 x 22 m (width and length are taken into account taking into account the projection of the projected area of waste 2 not less than 1 m in any direction), equal to 121 m ³ . Fastening on the terrain of the contours of the trench 7 was carried out when determining the length of the trench, the penetration of which should ensure the production of loam 5 in the volume of 1560 m ³ . Assuming a useful trench cross-section of 12 m ³ under specific geological conditions, it was found that the length of the trench is 130 m. Its shape in plan is taken as a rectangle 42 m long and 28 m wide (with a gap of 10 m for one of the sides to enter). ) After marking the trench 7 began its construction. The soil and plant layer was cut along the perimeter of trench 7. The cut layer was stored in convenient places in the inner contour of the site. Then they started to deepen the trench 7, for which, using an excavator, a layer of grayish-brown plastic sandy loam 5 with a thickness of 0.6 0.7 m was removed and evenly placed on the outside of the trench at a distance of 0.4 0.5 m from its edge in the form the enclosing shaft with a height of up to 0.9 1.0 m (not shown in the diagram). The moraine loams of a refractory and semi-solid consistency 2 lying below were also developed by an excavator, but the intensity of their extraction was made dependent on the procedure for the construction of the dump. After filling the loams along the contour of the base of the dump, the internal area of the dump was filled with coarse-grained soil 4 (slag, broken brick) with a thickness of 0.6 m and the soil was compacted with a bulldozer on a caterpillar track (weighing 10 11 tons). Laying and compaction of the lower thickness of waterproof soil 5 (see Fig. 2) with a thickness of 2.0 m was carried out in layers of 0.25 0.3 m with the number of penetrations by a bulldozer within 10 11 times. Rock salt was added before laying each layer of loam in the calculation of 0.9 kg per 1 ton of soil. This amount was determined after determining the content of clay particles in the soil (in percent) and the predominant clay mineral (illite). Then, taking into account the absorption capacity of illite, taken equal to 25 mEq. per 100 g and the gram equivalent of the sodium cation, the necessary amount of salt was found for the entire clay soil mass, which amounted to 1.8 tons. Stacking and compaction of waste 6 was carried out in more powerful layers up to a height of 5.0 m. The upper part of the dump was erected to the design elevation by moving the loam, loaded onto the access road to the dump using a bulldozer. At the end of compaction of the last soil layer 5 with a bulldozer, the blade surface was trimmed to give it a convex shape, eliminating the accumulation of rain and melt water. The work was completed by filling and compaction of soil and plant soil, and grass sowing is scheduled for spring, as well as shrub planting along the perimeter of the foot of the dump.

In general, the dump ridge was built taking into account the wind rose of a given area (21 ^o CB). This orientation did not contradict the equality of solar heating of its slopes.

 Water sampling from the trench and soil from the sides is planned to be carried out at the beginning of summer, when the movement of water vapor will be directed into the bowels, i.e. towards low temperatures.

 The proposed technical solution allows you to change the established attitude towards burials, the essence of which is either to lay them in the bowels, or to fill in their natural cavities to the level of the surrounding territory (see analogues and prototype). In any of these solutions, landfills are, to one degree or another, exposed to groundwater through rock cracks or capillaries and, therefore, the danger of the spread of toxic compounds seems quite real. Due to the desire to "hide" toxic waste in the bowels, difficulties arise in their waterproofing, which is practically impossible to provide.

 Thus, in comparison with the known solutions, the proposed one is characterized in that the waste is buried above the level of the surrounding area, as a result of which the capillary water of the upper aquifer is interrupted by a layer of coarse material, moraine loams and clays with their strong structural bonds contribute most to the achievement of this goal . Unlike locally occurring clays - finely dispersed, homogeneous, neogene (see prototype) moraine soils are stable in slopes, are not exposed to frost heaving and are widespread in vast territories of our country and other regions. Taking into account the totality of these effects, it seems a real turning point in the existing desire of production managers to reduce the amount and level of toxicity of waste, in the direction of making decisions on the use of this method of disposal. In addition to this, the proposed disposal method may be of interest to other countries with similar geological conditions.

Claims (1)

 A method for the burial of toxic industrial waste, including the sequential laying and compaction of a waterproof screen and waste and coating the latter with a waterproof screen, characterized in that, in order to protect the environment from pollution, the waterproof screen is laid on soil and plant soil and an additional layer of coarse block is laid on it material, and as a waterproof screen using stained loams and clays, which are composed of readily soluble compounds, about effectiveness to the exchange of divalent cations on the monovalent.

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