RU2465076C1 - Buried waste storage and method of its creation - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: storage comprises regional confining layer, said layer there above, at least one layer of loam and/or clay sediments making sorption (filtration) shield above sand layer, system of horizontal tubular drains fitted in sand layer along storage edges to extend to pits for possible feed of filtrate to surface. Proposed method comprises selecting regional confining layer proceeding from hydrogeological data on estimates of flows over refining layer, analysing engineering survey of soil stratum section town to refining layer to reveal shielding and filtering layers at future storage bed and excavating soil to reach, at least, one pillar of loan and/or clay beds making a natural sorption and/or filtration shield. Note here that, additionally, cuts in pillar are exposed along pit edges down to sand layer under lower filtration layers for laying horizontal drains along pit edges and mounting pumps therein.

EFFECT: decreased costs.

5 cl, 1 dwg

Description

1. The technical field

The present invention is intended for use in urban industrial utilities by creating a repository of solid household and industrial waste (TPBO). To create the proposed type of storage, it is mandatory to identify geological conditions under which the upper stratum of the Quaternary sand-clay deposits, located at a depth of about 20 ÷ 50 m, is lined with a seasoned regional water resistance.

2. The level of technology

There are various proposals protected by patents on methods for isolating the bottom, sides and slopes of the storage.

The patent RU 2337419 proposes the laying of storages on the surface of the earth with a geological barrier of cover loam at its base, used as a sorption screen with the preparation of barrier rocks to achieve the required filtration and sorption properties, which are justified on the basis that the time of filling of the shielding layer with sorbed components did not exceed storage time. The disadvantages of this proposal: 1) after the sorption capacity of the screen soils has been exhausted, it ceases to play the role of a hydrochemical barrier and becomes an additional source of groundwater pollution; 2) do not linger in such a screen and unsorbed toxic components freely enter groundwater.

Patent RU 2235610 proposes the development of a pit for a storage with the construction of a protective screen and a drainage base along its bottom and sides, followed by a breakdown of the pit into separate sections. This solution is for low-density waste disposal. The disadvantages of this proposal, mainly designed for low-density waste, are the need to create an artificial screen and incomplete drainage of the filtrate by the proposed drainage device.

The patent RU 2344238 proposes a device for a two-layer geological barrier, and at least one of its layers is made of geosynthetic materials, and also provides a means for moving fluid at the exit of the barrier. The disadvantage here is, in addition to the device of an artificial barrier, the uncertainty of a technical solution to the problem of water drainage at the exit from the barrier.

In the patent RU 2336206 it is proposed to dispose of the stored waste in a tank, which is made up of separate sections separated by anti-filtration curtains, with a tubular drainage located along the contour of the curtain. In this proposal, the waste storage is located on the surface of the earth and the geological conditions of the storage area are not taken into account in the device of its anti-filtration protection.

The closest to the solution proposed in this application to the problem of antifiltration protection of a closed landfill for municipal solid waste (MSW) is the proposal MosVodokanalProekta (L.I. Mongayt, B.A. and industry of Russia ", No. 10, 1999) on the deposit of silt sediment in the area" Maryinsky Park "mountains. Moscow. In this project, a pit was constructed for the storage of sewage sludge sediment to a regional water confinement (Jurassic clay), leaving a pillar of sandy rocks up to 6 m deep. To protect against the influx of groundwater into the pit, an anti-filtration curtain was created using the “wall in soil” method, which cuts the aquifer to the water confinement (to a depth of about 20 m). In addition, a vertical drainage system is used to drain the storage. The operation of this system revealed its low efficiency, and the appropriateness of the installation of the curtain was not proved, which led to a significant increase in the cost of construction of the storage facility due to the installation of the curtain, while the vertical drainage, due to the small influx to the wells, worked in an extremely uneven mode of pumps in the wells . It should be noted the low efficiency of the pumping system in combination with the installation of a filter curtain, which leads to high operating costs per unit volume of pumped filtrate.

Close to the technical solution claimed here is the proposal of V. M. Shestakov (V. M. Shestakov. Deposit of industrial waste in buried storage / "Ecology and Industry of Russia", No. 3, 2000), in which the storage is laid directly on the regional water storage (Jurassic clays) with horizontal reservoir drainage at the base of the storage body. The disadvantages of this proposal are the lack of a sorption screen at the bottom of the store and the need for a drainage device under the entire surface of the bottom of the store.

Disclosure of invention

3. The invention

In the proposed type of storage, solid waste is placed in a previously dug pit, in the lower part of which a whole of loamy and / or clay soils are left, under which there is a sand layer. The storage facility is constructed in such a way that the filtrate from the storage facility passes through a clay screen in which well-adsorbed toxic components are retained. After this, the filtrate enters the horizontal tubular drains laid in the underlying sand layer along the contour of the storage under the protection of water reduction. For these purposes, additional openings are made in this pillar (playing the role of a sorption screen) along the contour of the pit to the sand layer for laying horizontal drains at a depth of 1-2 m.

Filtration flow from the surrounding storage area comes to the same drains. Water flows from the drains to the mines, from which it is pumped to the surface of the earth, where, if necessary, it is subjected to additional purification before being discharged to a nearby watercourse. Thus, the proposed technical solution provides for two stages of purification of the filtrate. The first stage is carried out when the cleaning takes place on the whole clay and / or loamy soils, which play the role of a sorption (filtering) screen, and it uses the natural sorption capacity of clay rocks. At the final stage, if necessary, additional purification of the filtrate in the treatment facilities is used. After filling the repository, its surface is reclaimed with a green cover.

Excavation under the pit is carried out under the protection of building water reduction. As such, systems of contour drainage wells or floor-mounted needle filters can be used.

4. The novelty of the proposal

Compared to existing solutions for the construction of closed-type storages, the new is the special device for the foundation of the storage. It provides:

- the presence of at least two natural screens, namely: at least one - sorption - directly at the base of the repository and the second, located below, in the form of a natural confinement, practically eliminating the flow of filtrate through it into the underlying aquifers;

- a horizontal drainage device between these screens (or, if there are several sorption screens, between the bottom of the sorption screens and regional water stop) to drain the filtrate and the inflowing filtration stream;

- the presence of natural water repellent.

As an additional protection against filtrate contamination, the use of treatment facilities on the surface of the earth is provided. Such a storage device, based on the fullest use of the natural capabilities of the hydrogeological and engineering-geological structure of the site selected according to the invention, eliminates the need for constructing an artificial screen along the bottom of the storage, which significantly reduces the cost of creating a storage. If there are permeable (sandy or sandy-gravel) rocks in the upper parts of the section, their screening may be provided in the sides of the slopes of the storehouse.

The advantage of this type of storage is the natural nature of the screens, which protects against the almost mandatory drawbacks of artificially constructed barriers, which are due to the complexity of the technology of their construction and high cost. Thus, in the proposed solution, the possibility of rejecting expensive artificial screens and the maximum protection of groundwater from industrial pollution is realized.

The principle of the proposed solution, ensuring its effectiveness, comes from the fullest possible use of the structure of the geological environment for controlling the flow of leachate from the storage. For this purpose, a system of two natural screens at the base of the storehouse is used: a sorption screen at the bottom of the storehouse and a regional water storage beneath it with a natural drainage layer and horizontal drains between them. The filtrate, passing through at least one filtering (sorbing) screen, gives up the adsorbed part of the toxic components, after which, taking into account the protection against flowing down with a regional water seal, it enters horizontal drains. Then, by draining from drains, the filtrate is fed to the treatment plant, where it is brought to a condition suitable for discharge into the nearest natural watercourses. In addition, the external inflow to the horizontal drains serves as a hydraulic barrier to protect against penetration of the filtrate into the groundwater horizon.

After filling the storage to the level of the surface of the earth, a full restoration of the territory is carried out. At the same time, the water level in the drainage is maintained at a depth necessary for the required reclamation effect in the surrounding area.

5. The technical result

The method for creating a storage facility proposed here and the operation of the storage facility as claimed in accordance with the invention make it possible to obtain a number of positive effects and environmental and economic benefits. First of all, this relates to the protection of aquifers from the infiltration of filtrate: the filtrate is not allowed to enter groundwater due to the influence of the hydraulic barrier carried out by the flow to horizontal drains; Due to the interception of the filtrate seeping through the sorbing screen by horizontal drains and the shielding effect of the regional water confinement, the contaminated filtrate getting into the underlying aquifer is significantly reduced. In some cases, associated with an increased risk of contaminated water from the upper layers of the storehouse to groundwater due to the hydraulic conditions of a particular storehouse, additional measures for waterproofing the sides of the storehouse may be provided, and the storehouse itself must include this waterproofing.

It should be noted that it is impossible to completely exclude the possibility of leaking a certain amount of filtrate through the water storage in such storages with any method of antifiltration protection and this possibility should be evaluated in each case by special calculations; at the same time, the possibility of using such storages for the storage of highly toxic, in particular highly radioactive, effluents is excluded a priori.

In addition, in such a system of anti-filtration protection of the storage facility, it is possible to discharge environmentally friendly residues of the treated filtrate into natural water bodies and streams with a minimum expenditure of funds for its cleaning at engineering structures, as well as land reclamation, which are initially uncomfortable land for use, including the storage surface area .

It is significant that due to the maximum use of the geological structure, these favorable consequences are achieved at the lowest cost in comparison with storages equipped with artificial screens.

Thus, the claimed technical result is implemented by a solid-state solid propellant storage facility, the basis of which includes:

- regional waterproofing,

- sand layer above it,

at least one layer of loamy and / or clay deposits as a sorption screen over a sandy drainage layer,

- a system of horizontal tubular drains laid in the sand layer along the contour of the storage, led to the mines, providing the possibility of feeding the filtrate to the surface.

The specified solid waste storage facility can additionally be equipped with treatment facilities on the surface for cleaning the filtrate before dumping it into a reservoir.

The claimed result is achieved by the method of creating a solid-state solid proprietary solid waste storage facility, in which:

- search for regional water storage based on hydrogeological materials for assessing overflow through water storage,

- study of the engineering-geological section of the soil stratum to water confinement with the identification of the screening and filter layers at the base of the future storage,

- excavation under the pit until at least one pillar of clay and / or loamy rocks, which is a natural sorbing screen, is reached,

- additional opening of slots in this pillar along the contour of the pit to the sand layer under the bottom of the filter layers for laying horizontal drain;

- the device of horizontal tubular drainage along the contour of the pit of the storage with shafts for the location of the pumps.

In the method of creating a storage, it can be further provided that the excavation under the excavation is carried out under the protection of building water reduction. At the same time, contour drainage systems or floor-mounted needle filters can be used as protective building water reduction.

6. Brief description of the drawing

The application shows a figure, which is a schematic view of a section of an in-depth drained solid waste storage facility. In the diagram, the foundation pit under the solid solid waste is indicated by the number 1, it is built in the thickness of sand and clay deposits, in the lower part of which there is a clay layer. The entire thickness is indicated by the number 2. The whole clay and / or loamy rocks, representing a natural sorbing screen at the bottom of the pit, are designated as 2a. The bottom filtering sand layer, in which horizontal drainage is laid, is indicated by the number 3, regional water resistance - by the number 4. The horizontal tubular drainage along the contour of the storage pit with the shafts for the location of the pumps is indicated by the figure 5. The location of the temporary construction drainage is indicated by the number 6.

7. An example of a possible embodiment of the invention

The following example does not limit the possible application of the claims and only illustrates the claimed invention.

On the example of the Moscow region, the possible construction of a storage facility of the proposed type is considered. In this territory, a regional aquiculture, represented by Jurassic clays, is quite widespread. According to regional hydrogeological studies on watershed spaces, Jurassic clays are practically a water-resistant layer. They are especially widely represented in the western, northern, and southeastern territories of the region. The main conditions for the suitability of the territory for the construction of a solid waste storage facility of the proposed type are: the presence of a water stop, i.e. thicknesses of waterproof or poorly permeable rocks that isolate aquifers from each other.

According to Geolink Consulting (I.S. Pashkovsky), a “Cartogram of the Jurassic sediment overflow coefficient” was compiled, which shows the distribution areas of Jurassic water-resistant clays with values of the overflow coefficient χ = k / m per day ^-1 (k is the filtration coefficient, m - sediment thickness): in the ranges from less than 10 ^-7 , from 10 ^-7 to 10 ^-6 , from 10 ^-6 to 10 ^-5 , from 10 ^-5 to 10 ^-4 , from 10 ^-7 to 10 ^-3 , less 10 ^-3 .

As a result of studying the above data, one of the sites suitable for implementing the proposed technical solution can be selected to create a repository. It is located near the village. Podrezkovo in the Khimki district. Geological and hydrogeological structure of the territory:

- cover loam, age QII-III, thickness 2-3 m;

- loams of the Moscow moraine, age QII ₄ , thickness 12 m;

- fluvioglacial sands, age QII ₃ , thickness 8 m;

- loams of the Dnieper moraine, age QII ₂ , thickness 9.0 m;

- sands, age K ₁ , thickness 8 m;

- clay, age J _2-3 , thickness 30 m,

- limestones, age C ₃ , thickness 100 m.

In the attached figure, cover loams, loams of the Moscow moraine, fluvioglacial sands and loams of the Dnieper moraine are shown together as sand-clay deposits and are indicated by the number 2. The layer of Cretaceous sands is indicated by the figure 3, and the layer of Jurassic clays, representing the regional water resistance, in the figure number 4.

Two aquifers are developed in the territory under consideration: a non-pressure horizon in the sands of the Quaternary and Cretaceous at a depth of 20 m from the earth's surface, which is used by the local population for decentralized water supply, and a high-pressure horizon in coal-bearing limestones with a pressure level of 30 m, which is an exploited aquifer in this area horizon of centralized water intakes. Protect both aquifers from leachate from storage.

The filtration coefficient of chalk sand according to the survey work in Moscow and the region is 3 ÷ 10 m / day, which is sufficient for horizontal drainage. According to the “Cartogram”, the Jurassic clay overflow coefficient in this area is from 10 ^-7 to 10 ^-6 days ^-1 or the clay filtration coefficient in the vertical direction is 3 × 10 ^-6 ÷ 3 × 10 ^-5 m / day, i.e. the clay layer in the area can be considered an almost impermeable waterproofing.

The excavation pit (figure 1 on the figure) is constructed to the roof of the loams of the Dnieper moraine (marked as 2a). The construction of the pit and the arrangement of horizontal drains is carried out under the protection of vertical drainage laid along the contour of the pit in the areas indicated on the figure by the number 6, in chalk sand (number 3 on the figure). After completion of the horizontal drainage construction, the vertical drainage wells are dismantled. The loams inside the pit, designated as 2 in the figure, will serve as the sorbing layer. The depth of the pit under the storage will be 30-31 m. Cretaceous sands in this case are a draining layer. A cut is made along the contour of the foundation pit in a layer of Dnieper loams with a deepening in chalk sands of up to 2 m for laying horizontal drains. At the same depth as the drains, wells for pumps are laid. The storage created by the method indicated here implements the technical result according to the invention and is the storage of the solid waste of the proposed type.

Claims (5)

1. A repository of solid domestic and / or industrial waste of a buried type, the base of which includes:
- regional waterproofing,
- sand layer above it,
- at least one layer of loamy and / or clay deposits as a sorption (filter) screen above the sandy drainage layer,
- a system of horizontal tubular drains laid in the sand layer along the contour of the storage, led to the mines, providing the possibility of feeding the filtrate to the surface. 2. The storage according to claim 1, characterized in that it is additionally equipped with treatment facilities on the surface for cleaning the filtrate before dumping it into the reservoir. 3. A method of creating a repository of solid domestic and / or industrial waste of a buried type, in accordance with which they produce:
- search for regional water storage based on hydrogeological materials for assessing overflow through water storage,
- study of the engineering-geological section of the soil stratum to water confinement with the identification of the screening and filter layers at the base of the future storage,
- excavation under the pit until at least one pillar of clay and / or loamy rocks is reached, which is a natural sorbing (filtering) screen,
- additional opening of slots in this pillar along the contour of the pit to the sand layer under the bottom of the filter layers for laying horizontal drains;
- the device of horizontal tubular drainage along the contour of the pit of the storage with shafts for the location of the pumps. 4. The method according to claim 3, characterized in that the excavation under the excavation is carried out under the protection of building water reduction. 5. The method according to claim 4, characterized in that the system of contour drainage wells or floor-mounted needle filters are used as protection for building water reduction.

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