RU2132467C1 - Method for isolation of underground toxic waste storage in salt-bearing rock mass - Google Patents

Abstract

FIELD: mining technology. SUBSTANCE: method can be used in areas where risk of flooding underground storages of toxic waste in salt-bearing rock formations is possible. According to method, storages are created by driving chambers and connecting underground workings for connection with mine shaft. Made are V-shaped sections in longitudinal profile of underground workings. Pipeline is laid through connecting underground workings to storage via V-shaped sections. They are flooded with brine saturated with components of surrounding rock mass. Gas or air is supplied to storage through pipeline. Their amount compensates for increasing pressure brought to bear upon brine by raising height of water column. Application of aforesaid method and arrangement enhances operational reliability and prevents ecological danger. EFFECT: higher efficiency. 9 cl, 1 dwg

Description

 The invention relates to the mining industry and can be used when there is a threat of flooding of underground repositories of toxic waste, built and operated in saline geological formations.

 A known method of isolating toxic waste storages, including the formation of chambers in the salt column, securing chambers, placement of toxic waste and the construction of waterproofing lintels (Drisenroth N., Kind J. Die Untertage-Deponie Herfa-Neurode-Umwelt gerechte Beseitigung von problematischen toxischen Abfallen, Kali und steinsalr, 1989, pp. 182-195).

 The disadvantage of this method is the lack of the ability to quickly create reliable waterproofing jumpers in situations where the time for which they need to be built is measured in hours.

 Closest to the proposed method is a method of creating underground storage of toxic waste in saline rocks, including the creation of a storage of toxic waste, excavation of excavations connecting the storage to the mine shaft, the creation of U-shaped sections in the longitudinal profile of the workings, which performs the function of mash mines that are filled with concrete with a filler from salt (US Pat. 2066770, MKI: E 21 F 17/16, E 21 F 9/34; publ. 09/20/96, bull. N 26). However, this method also does not allow to quickly isolate the storage in case of a threat of flooding, because involves the filling of the U-shaped sections of the workings with salt concrete, which cannot be completed in a matter of hours, and which takes time to harden the concrete and its subsequent isolation from contact with brine, bitumen or similar material.

 The technical result of the invention is to increase operational reliability and eliminate environmental hazards that may be created by contact with toxic waste disposed of in storage in saline rocks, water and brines that can enter the storage.

 The specified technical result is achieved by the fact that in the method of isolation of the underground storage of toxic waste in saline rocks, including the creation of a toxic waste storage by tunneling with inter-chamber pillars, the excavation of mine workings connecting the storage to the mine shaft, the creation of U-shaped sections in the longitudinal profile of these workings moreover, along the connecting workings in the storage, a pipeline is laid through the U-shaped sections, and if there is a risk of flooding, the U-shaped section is filled with brine, saturated the components that make up the array surrounding this section, after which gas or air is supplied through the pipeline to the storage in an amount that compensates for the increasing pressure on the brine of the growing water column as its height grows in the flooded mined-out space.

где V₂ - объем полости подземного выщелачивания;
V₁ - не заполненный отходами объем хранилища;
P₁ - давление максимально возможного столба минерализованной воды, при угрозе затопления рудника и шахтных стволов;
P₂ - давление воздуха или газа в полостях подземного выщелачивания.Air or gas creating a compensating pressure in the storage is supplied from cavities previously formed in saline rocks created by underground leaching and having a volume determined from the ratio

where V ₂ is the volume of the underground leaching cavity;
V ₁ - storage volume not filled with waste;
P ₁ - pressure of the maximum possible column of mineralized water, with the threat of flooding of the mine and shaft shafts;
P ₂ - pressure of air or gas in the cavities of the underground leaching.

 In this case, the air or gas in the underground leaching cavity contains at a pressure exceeding the pressure of the water column acting on the brine in the U-shaped section of the connecting mine workings, but not exceeding the weight of the column of rocks lying over the storage. Compressed air or gas from the leaching cavities is supplied to the storage in a metered and in such quantity that the level of brine in the U-shaped section of the mine does not fall from the side of the storage to the level of the roof of its lower part and does not rise to the level of the soil of the connecting mine, into which the U- shaped section, and the adjustment of the supply of compressed air or gas to the storage is carried out automatically.

 They use pipelines made of materials that are not susceptible to corrosion in salt brines, or pipelines insulated with coatings that are inert to such brines, and after stabilizing the level of flooding water, the pipelines are hermetically sealed.

 In the vicinity of the U-shaped sections of the connecting mine workings, buried chambers pass, a concentrated brine is placed in them that is inert with respect to the saline mass surrounding these sections, and if there is a threat of flooding, the brine is pumped into U-shaped sections, and if it is eliminated, the pump back to buried cameras.

 The essence of the technical solution is illustrated by the drawing, where in FIG. Figure 1 shows a general isolation scheme for a toxic waste storage facility.

 In the drawing: 1 - chambers of an underground storage of toxic waste, 2 - a U-shaped section of a mine that connects the store with a shaft shaft filled with saturated brine, 3 - a shaft shaft, 4 - a pipeline through which a hydraulic shutter is created in the U- when the filling section is filled with saturated brine, compressed air (or gas) is supplied, 5, 6 — salt underground leaching chambers filled with compressed air (gas), designed to fill the storage in case of threat of flooding, 7 — range of possible fluctuations level of saturated brine filling the U-shaped section of the mine, 8 - saline rock, 9 - locking device (chambers, etc.) at the end of the pipeline, 10 - sensor transmitting a signal about the rise or lowering of the brine level from the reservoir to marks at which it is necessary to change the air pressure in the store.

 If necessary, realize the possibility of isolating the underground storage of toxic waste placed in the chambers in the appropriate containers, the proposed method takes into account that the storage is created on the basis of an existing potash mine working out potash seams while maintaining the overlying stratum with compliant pillars, and therefore a waterproof saline stratum lying under by worked out seams, undergoes deformations which, if there are weakening surfaces in this thickness that are not detected by modern methods, can revratitsya in the water-and a threat of flooding as the mine and waste storage.

Baseline
The toxic waste storage facility is formed in the salt stratum underlying the mined potash strata at a depth of 50 meters from them.

 The repository is a series of chambers separated by interchamber pillars, the degree of loading of which is such that it excludes their deformation and deformation of the salt ceiling located between the repository and the mined seams.

 The storage is opened by slopes, including U-shaped sections, which can serve both to create a salt-concrete bridge in them and to create a water seal if the back pressure of compressed air or gas in the storage is adjusted according to the increase in the height of the water column in the flooded mine and in it trunks.

 The immersion of U-shaped sections in relation to the storage is 13.5 m. Therefore, with a height of workings in which U-shaped sections are equal to 3.5 m, and such filling of these sections with concentrated brine, at which its level is located below the soil of the workings storage at 5 m, a change in this level when it is adjusted by supplying compressed air within ± 2 m is permissible, since ± 3 meters remain in reserve.

Initial storage volume V ₁ = 100,000 m ³ .

 The repository will develop as its initial volume is filled with packaged waste.

The specific gravity of the rocks lying over the storage is equal to γ ₂ = 2.2 t / m ³ = 2.2 g / cm ³ .

The specific gravity of the mineralized waters that flooded the mine and mine shafts is γ ₁ = 1.25 t / m ³ = 1.25 g / cm ³ .

 The thickness of the underlying salt in the area of the created storage is 120 m.

In order to eliminate the risk of occurrence in the leach chambers of a phenomenon such as hydraulic fracturing, the pressure of compressed air (gas) in them must be less than the specific gravity of the rocks of the overlying stratum. In this regard, we take it equal to P = 2.0 • H • L • γ ₂ , H = 2.2 • H, where H is the depth of the storage and roof of the leaching chambers.

Decision
From the trunk 3 in the salt-bearing stratum 8 there are slopes up 3 m from the design level of the mine yard (to create capacities at its level in case water inflows appear in the mine), which go into horizontal sections and then downward slopes ending in U-shaped sections 2 , after which create a storehouse, consisting of a number of cameras 1, separated by inter-chamber pillars (Fig. 1).

Slopes, chambers and workings brought to the chambers pass in one stroke of the combine with a cross section of chambers S ₁ = 9 m ² or S ₂ = 17 m ² .

With a length of chambers 1 equal to l = 200 m, the volume of each of them is in the first case h ₁ = 1800 m ³ , and in the second h ₂ = 3400 m ³ .

For a given volume of storage, 10% of which falls on preparatory workings, the number of chambers that the storage will consist of by the beginning of its operation is h ₁ = 50 pieces and h ₂ = 26 pieces, respectively.

With an annual waste filling of a part of the storage volume equal to 10,000.0 m ³ , they can expand every 2 years when using a combine with a cross-section S ₁ = 9 m ² for 10 chambers, and with a combine with a cross-section of chambers S ₂ = 17 m ² 5 cameras while maintaining the same storage volume; which must be filled with compressed air (gas) in case of danger of flooding the mine (and storage).

To create a container of 5.6 with compressed air (gas), which would be enough to provide the back pressure from the storage equal to P ₁ for brine, which, in case of flooding danger, will fill the U-shaped sections of the openings leading to the storage in salt rock 8 at the same depths at which the storage is located, create cylindrical chambers of surface leaching 5, 6; this is achieved by dissolving salt with fresh water (see books: "Salt mining technology." Authors: R.S. Permyakov, V.S. Romanov, M.P. Beldy. M .: Nedra, 1981. "Salt development by underground leaching ". Collection of articles edited by V. S. Romanov. L., 1975 and others).

где P₂ - давление сжатого воздуха или газа, численно равное P₂ = γ^* • H = 2 • 350 = 700 т/м² = 70 кг/см², γ₂ • H = 2,2 • 350 = 77 кг/см³.In order to reduce the height of the underground leaching chambers 5, 6 and fit them into the bedding salt 13, as well as to reduce the formation time of compressed air tanks by 2 times, we create two such chambers. The volume of each of them to ensure the necessary counter-pressure of air (gas) in the storage in the event of complete flooding of mine shafts used for sinking chambers 1, designed to store waste and for lowering waste into these chambers, should be

where P ₂ is the pressure of compressed air or gas, numerically equal to P ₂ = γ ^* • H = 2 • 350 = 700 t / m ² = 70 kg / cm ² , γ ₂ • H = 2.2 • 350 = 77 kg / cm ³ .

Общая высота камер 5, 6 с учетом сводовой части и нижней конусной, которая является элементом технологии размыва соли, и в которой скапливаются нерастворимые включения (глина и т.п.) будет в этом случае составлять около 70 м. Следовательно, в соленосную породу 8 камеры выщелачивания, представляющие резервуары сжатого воздуха, вписываются с необходимым запасом.With a diameter of leaching chambers equal to 50 m, when designing their roof in the form of a stable arch with a height close to 15 m (to ensure its stability when taking compressed air), their cylindrical part at a given V ₂ must have a height of at least a value equal to

The total height of the chambers 5, 6, taking into account the arched part and the lower cone, which is an element of the salt erosion technology, and in which insoluble inclusions (clay, etc.) accumulate in this case will be about 70 m. Therefore, in the saline rock 8 leaching chambers representing reservoirs of compressed air fit with the necessary margin.

 To ensure sealing of the formed leaching chambers 5, 6, the annular space and the annular space in the wells are plugged using the technologies used to create compressed air and gas in the axes of underground storages.

 On the earth's surface above the outgoing pipes, heads with three nozzles are equipped, one of which serves to mount the manometer, the other to inject air (or gas) into the cavity, and the third to supply this air through pipeline 4 to the waste storage. All three nozzles are equipped with appropriate locking devices.

 The pipeline 4, through which air will be supplied to the waste storage through the shaft 3, is made of a material inert with respect to brines and fresh water or of metal with a corresponding external coating that protects this metal from contact with water and brines for an infinitely long time.

 In addition to pipeline 4, a cable is supplied to the waste storage, which is designed, firstly, to receive signals about the acceptable level of concentrated brine from the storage in the U-shaped sections of the mine workings connecting the storage to the mine shaft, and about the need to adjust the pressure in the compressed air storage, and, secondly, to drive the locking device, which equips the end of the pipeline section located in the storage. After the end of the process of flooding the mine, if any, and the end of the stabilization of the pressure of the waters that flooded it on a concentrated brine placed in the U-shaped sections of the supply openings (this brine, being the heaviest, always remains in the U-shaped sections of the openings, without mixing with less concentrated brine that flooded the mine), at the command of the earth’s surface, transmitted by cable, a locking device is actuated mounted at the end of the pipeline section, which is located in the storage, and ruboprovod plugging.

 As a result, a store with internal back pressure of air (gas) is walled up forever.

 The proposed method of isolating the underground storage in saline rocks improves operational reliability and eliminates the danger that threatens flooding of the toxic waste storage.

Claims (10)

 1. The method of isolation of an underground storage of toxic waste in saline rocks, including the creation of a storage of toxic waste by tunneling with inter-chamber pillars, the excavation of connecting mine workings connecting the storage to the mine shaft, and the creation of U-shaped sections in the longitudinal profile of these workings, characterized in that along the connecting workings in the storage, a pipeline is laid through the U-shaped sections and, if there is a risk of flooding, the U-shaped section is flooded with brine saturated with components from ryh includes an array surrounding this portion, after which the specified line store gas or air is fed in an amount of compensating an increasing pressure on the brine rising water column at least in its height growth flooded goaf.  2. The method according to claim 1, characterized in that the air or gas is supplied to the storage from the cavities previously formed in the saline rocks.  3. The method according to claim 2, characterized in that the cavity from which air or gas is supplied to the storage is created by underground leaching.  4. The method according to claim 2 or 3, characterized in that the air or gas is contained in the underground leaching chamber under pressure exceeding the pressure of the water column acting on the brine in the U-shaped section of the connecting workings, but not exceeding the weight of the column of rocks lying under repository. 5. The method according to claim 2 or 3, characterized in that the underground leaching cavity create a volume determined from the ratio

where V ₂ is the volume of the underground leaching cavity;
V ₁ - storage volume not filled with waste;
P ₁ - pressure of the maximum possible column of saline water with the threat of flooding of the mine and mine shafts;
P ₂ - pressure of air or gas in the cavities of the underground leaching.  6. The method according to claim 1 or 2, characterized in that the air or gas from the underground leaching cavities is dosed in a quantity such that the level of brine in the U-shaped section does not fall from the side of the storage to the level of the roof of its lower part and does not rose to the level of the soil of the connecting excavation, into which the U-shaped section passes.  7. The method according to claim 1 or 5, characterized in that when raising or lowering the level of brine in the U-shaped section of the development from the storage side to the specified values, the air or gas supply to the storage is automatically adjusted.  8. The method according to claim 1, characterized in that the use of pipelines made of materials not amenable to corrosion in salt brines, or pipelines insulated with coatings inert to such brines.  9. The method according to any one of claims 1, 6-8, characterized in that after stabilizing the level of flooding waters, the pipelines are hermetically sealed.  10. The method according to any one of claims 1, 6-8, characterized in that buried chambers pass near the U-shaped sections of the connecting mine workings, a concentrated brine is placed in them, inert to the saline mass surrounding these sections, and if there is a threat of flooding storages pump this brine into U-shaped sections, and in the event of liquidation of the danger of flooding, they pump it back into buried chambers.