UA32221C2 - Method of burial of ecologically dangerous objects - Google Patents

Abstract

The present invention relates to a method of burial of ecologically dangerous objects and can be used in the mine industry and underground construction. The proposed method implies that the dangerous object (1) is covered by a protecting shell (2) before burial in an underground shelter (4). In the underground shelter, under the object, a well (3) for sinking the shell with the object is constructed at the depth required for the burial. During the course of storing the object, the parameters are monitored that characterize the internal state of the object.

Description

Description of the invention

The invention relates to the field of burial of dangerous objects and especially dangerous objects and can be applied in the construction of large engineering objects in mining and underground construction.

The closest technical solution chosen as a prototype is the method of burying environmentally hazardous objects, including the penetration of a vertical shaft in the zone of burial of environmentally hazardous objects, a complex of horizontal, vertical and inclined mine workings, the creation of a solid receiving bottom and storage, lowering of environmentally hazardous objects of the object into the storage at a given depth by releasing from the discharge holes of the receiving solid bottom the mining rock previously destroyed by the blasting method, which is located under the object, filling with the rock formed during the release of the container. The object is lowered slowly and continuously down the mine with loose walls to a given depth into the underground reinforced concrete storage. (Ukraine, PM 9547 А MPK? 021 E9/24, 1997).

The disadvantage of the known method is the insufficient reliability of the storage of the object during the specified period 79 without ensuring monitoring and the insufficient scope of application due to the fact that the lowering of the object is done through a mine with loose walls to a specified depth into an underground reinforced concrete storage, it may happen self-collapse of the walls of the mine in the process of lowering the object, crushing it, both in the process of lowering and during storage by bulk rocks that fill the mine in the absence of constant control of the position of the object in the storage.

The reason that prevents the prototype from obtaining the technical result of the proposed invention is: when an object is lowered down a mine with unsecured walls to a given depth into an underground reinforced concrete storage, self-collapse of the mine walls may occur in the process of lowering the object, crushing it, as in the process of lowering, as well as when stored with bulk rocks that fill the mine. There is no permanent control of the position of the object in the storage. Such technology can lead to insufficient reliability of storage of 79 objects within a given period of time without the possibility of ensuring monitoring. Go)

The task of the invention is the development of a method of burying environmentally hazardous objects, in which, by means of the possibility of ensuring the maximum permissible load of bulk rocks on the capsule overlap and maintaining the structural integrity of the buried object, both when the object is lowered and to a given depth and monitoring in averages of the object for the specified period of its storage, achieve an increase - the reliability of the storage of the object during the specified period at a great depth and the expansion of the field of application. Ge

The task is achieved by the fact that in the method of burying environmentally hazardous objects, which includes the penetration of a vertical shaft in the burial zone of an environmentally hazardous object, a complex of horizontal, cm vertical and inclined mine workings, the creation of a receiving continuous bottom and underground storage, Ge! lowering an ecologically hazardous object into the storage to a given depth by releasing from the outlet holes of the receiving continuous bottom the mining rock previously destroyed by the blasting method, which is located under the object, filling with the rock formed during the release of the capacity, according to the invention, previously in alluvial rocks under ecologically a dangerous object is created in one of the known ways by creating a sinking well with a base in bedrock and a height up to the level of the day surface, before lowering the object into the well, it is locked in a safety capsule with a foundation plate at the base and as the object is lowered into capsule into the well and upon reaching its overlap with the level of the day surface, the walls of the capsule are built up, and the capacity formed between the capsule overlap is filled with destroyed mining rock taken out through the bottom or containers with radioactive waste, and upon reaching the weight of bulk rocks on the capsule cover, which do not exceed the bearing capacity of the floor, another floor is erected and as the object in the capsule is lowered into the well, the whole process is repeated up to the specified depth of burial of the object. o 395 When performing this technology of burying the object, it is possible to preserve the structural integrity of the object, both during its deepening and long-term storage, and to ensure the conditions of monitoring inside the object during the specified period, as well as storage of containers with waste of nuclear fuel and other radioactive waste in the safety capsule between the overlaps provides, if necessary, conditions for monitoring the condition of the containers. ko 50 The essential features of this invention are; vertical shaft penetration in the burial area of an ecologically hazardous object; penetration of a complex of horizontal, vertical and inclined mine workings; creation of a receiving solid bottom; creation of underground storage; lowering an ecologically hazardous object into the repository to a given depth by releasing it from the graduations

GF) of the holes of the receiving solid bottom of the mining rock previously destroyed by blasting, which is located under the object; And filling with rock formed during the release of the capacity; creation in advance in the alluvial rocks under the ecologically dangerous object by one of the known methods of 60 lowering wells with a foundation in bedrock and a height up to the level of the day surface; locking the object before lowering it into the well in a safety capsule with a base plate at the base; building up the walls of the capsule as the object in the capsule descends into the well and reaches its overlap with the level of the day surface; filling the formed capacity between the caps of the capsule removed through the bottom with destroyed mining rock or containers with radioactive waste;

erection of the next floor when the weight of bulk rocks is reached on the floor of the capsule, which does not exceed the load-bearing capacity of the floor; repeating the process as the object in the capsule is lowered into the well to the specified burial depth of the object.

New essential features of this invention are; creation of a submersible well with a base in bedrock and a height up to the level of the day surface in alluvial rocks under an ecologically hazardous object using one of the known methods; locking the object before lowering it into the well in a safety capsule with a base plate at the base; building up the walls of the capsule as the object in the capsule descends into the well and reaches its overlapping level of the 70-day surface; filling the formed capacity between the caps of the capsule with destroyed rock taken out through the bottom or containers with radioactive waste; erection of the next floor when the weight of bulk rocks is reached on the floor of the capsule, which does not exceed the load-bearing capacity of the floor; repeating the process as the object in the capsule is lowered into the well to the specified burial depth of the object.

The specified essential features are necessary and sufficient in all cases of implementation of the method.

As a result of the fact that one of the well-known methods is previously created in sedimentary rocks under an ecologically hazardous object, a sinking well with a base in bedrock and a height up to the level of the day surface, it is a protection of the walls of the mine against self-collapse, which protects the object from crushing and, accordingly, preserves 2o Integrity of the structure of the object, both when it is lowered and when it is stored for a given period. In addition, the lowering well serves as a load-bearing fence from the surrounding mining massif, and as a guide during immersion, and this makes it possible to exclude distortions or jamming of the capsule in the process of immersion and self-collapse of large-area outcrops of the mining massif, and this contributes to increasing the reliability of the storage of the object during the specified period term if it is possible to carry out monitoring in the middle of the object for this period and to expand the scope of application.

As a result of the fact that before lowering the object into the well, it is locked in a safety capsule with i) a foundation plate at the base, we have the opportunity to protect the object during its descent from the impact of the load of bulk rocks and thereby preserve the integrity of the object's structure, which contributes to increasing reliability of storage of the object during the specified period at a great depth with the possibility of monitoring the center of the object "- this period and the expansion of the field of application.

As a result of the fact that as the object in the capsule is lowered into the well and reaches its overlapping level with the day surface, the walls of the capsule are built up, and the capacity formed between the caps of the capsule is filled with destroyed mining rock taken out through the bottom or containers with radioactive waste and upon reaching covering the capsule with the weight of bulk rocks that do not exceed the bearing capacity of the covering and as the object in the capsule is lowered into the well, the whole process is repeated up to the specified depth of burial of the object, we get the opportunity to eliminate the need to build an independent storage for containers with radioactive waste, to reliably protect the object both in the process of immersion and during its storage at a great depth for a given period of time, as well as to conduct monitoring during its storage period, which increases the reliability of the storage of the object during the given period of time with monitoring and expands the scope of application. "

As a result of the combination of the above-mentioned known and new significant features, it became possible to create conditions for preserving the structural integrity of the buried object, where by constructing a lowering well and . safety capsule under the object for its burial at a great depth and for a given period, allows to increase the guaranteeing the structural integrity of the object in the process of immersion and long-term storage, as well as creating conditions for monitoring it and, in addition, storing containers with radioactive waste or nuclear fuel in the containers of the safety capsule. The essence of the invention is explained by the drawings, where: 2) in fig. 1 shows a general view in a vertical section after the creation of an underground storage, a receiving solid bottom and a lowering well; and in fig. 2 - general view in a vertical section of the safety capsule; which in fig. C - a general view in a vertical section of the object after the start of closing it in the capsule prevention; and in fig. 4 - also in the process of lowering the object in the capsule and building up the walls of the capsule; as in fig. 5 - also in the process of lowering the object in the capsule, building up walls and building dome-shaped ceilings; in fig. 6 - also after the construction of the conical roof and the completion of the construction of the capsule; in fig. 7 shows a general view in a vertical section of the object in the capsule after its installation in the underground storage while filling the capsule's capacity with destroyed rocks;

F) in fig. 8 - also, when filling the capsule containers with radioactive waste containers. The method is as follows.

The object to be buried 1 is lowered into the safety capsule 2 through the lowered reinforced concrete well C into the underground storage 4. For this purpose, a vertical shaft (not shown in the drawings) is passed to the specified burial depth and an underground bunker is built (not shown in the drawings). From the shaft, notches of the shaft yards are carried out with the subsequent penetration of horizontal mine workings (not shown on the drawings) on three levels from the shaft to the underground storage 4.

Simultaneously with the production of these works, first an ice barrier (not shown on the drawings) in the form of an empty cylinder is created around the zone of mining operations in aquifer layers, then a tamponage barrier (not shown on the drawings) inside the ice barrier. After that, groundwater drainage is carried out inside fences. From the horizontal workings near the lowering route of object 1 and wells C, uplifted and inclined mining workings (not shown on the drawings) of various technological purposes are made.

After a complex of mining workings has been penetrated, an underground storage 4 with a receiving solid bottom 6 is constructed parallel to object 1 in bedrock 5. After that, one of the known methods is constructed in the massif of alluvial rocks 7 with a foundation in bedrock 5, in part by replacement of the natural massif with an artificial one, a reinforced concrete lowering well With a diameter exceeding the diameter of the safety capsule 2, from storage 4 to the level of the day surface simultaneously with several holes from several horizons. Then they carry out 70 destruction of the mining massif alluvium 7 and bedrock 5 inside the lowering well Z and the underground storage 4 from the receiving solid bottom b to the base of the object 1 in its initial position with the simultaneous construction of the foundation plate 8 and the walls 9 of the safety capsule 2.

After that, the destroyed mining rock 10 is released through the outlet holes of the receiving solid bottom 6 and its delivery through the barrel (not shown in the drawings) to the bottom surface at the same time /5 Immersion of the object 1 in the safety capsule 2 through the lowering well C to the underground storage 4 When reaching the upper edge of the walls 9 of the first floor of the safety capsule 2 at the level of the day surface, a dome-shaped or other-shaped reinforced concrete floor 11 is built on them, the walls 9 of the second floor of the safety capsule 2 are built up, and as the object 1 sinks, the resulting capacity of the second floor of the safety capsule 2 is filled released to the surface by destroyed rocks 10 or containers with radioactive waste 12.

Then, upon reaching the level of the day surface, the upper edge of the walls 8 of the last floor of the safety capsule 2 are built on them together with a reinforced concrete dome-shaped 11 and a conical reinforced concrete floor 13 of the safety capsule 2. At the same time, the height of the floor between the floors 11 of the safety capsule 2 is determined from the correspondence of the mass of loose rocks of the destroyed mine rocks 10 or containers 12 with radioactive waste carrying capacity of the dome-shaped overlap 11 of the safety capsule 2.

The method is carried out as follows. From the surface in the burial area of object 1, a vertical shaft, equipped with cage and skip lifts, passes. In the process of drilling the barrel, notches are made in the near-barrel yards i) with subsequent drilling of horizontal workings from them to the lowering route of the object 1 or to the lowering well

Z, from which a complex of horizontal and inclined mining operations pass, ensuring the construction of a receiving continuous reinforced concrete bottom 6, an underground storage 4, a lowered reinforced concrete well "from Z, the production of works on the destruction and release of alluvium 7 and bedrock 5 and other conditions for the production of mining works . with

Around the area of mining operations, first create an ice barrier in the form of a hollow c cylinder in the layers of water-bearing rocks, then a backfill barrier inside the ice back barrier and drain underground water from under the backfill barrier before the start of work on the passage of a complex of horizontal, lifting c z5 | inclined products. co

After the completion of the construction of the lowering well Z, the foundation plate 8 of the safety capsule 2 is built under the base of the object 1 underground by replacing the natural mining massif with artificial, for example, reinforced concrete.

Then, on the foundation plate 8, the walls of the lower floor are built on the surface of the wall 9 of the safety capsule 2. "

Then, after the destruction of alluvium 7 and root 5 rocks within the lowering well Z and their release through the outlet holes of the receiving solid bottom 6, the object 1 in the safety capsule 2 is lowered through the lowering well 3. Upon reaching the upper edge of the walls 9U of the first floor of the safety 2 capsules per day;" surfaces on the walls 9 build a dome-shaped overlap 11 of the safety capsule 2 above the object 1, then build up the walls In the second floor of the safety capsule 2 and upon reaching the upper edge of the walls 9 of the second floor at the level of the day surface when immersing the object 1 in the safety capsule 2 capacity its second floor is filled with rocks 10 released through the outlets of the receiving bottom 6 and released to the surface through the barrel, or containers 12 with radioactive waste are placed. In the same way, further floors of the safety capsule 2 are built, and on the walls of the last floor, in addition to the domed reinforced concrete floor 11, a conical reinforced concrete floor 13 of the safety 5r of Capsule 2 is built and the process of lowering the object 1 in the safety capsule 2 into the underground storage 4 is continued at the same time by filling with rock 10 of the descent well Z as the capsule 2 descends. The height of the floors of the safety capsule 2 between the floors 11 is determined from the conditions of correspondence of the bearing capacity of the dome-shaped floor 11 and the mass placed in the floor of the rock 10. The bearing capacity of the conical reinforced concrete floor 13 is determined by the mass of the rock 10 , placed above the reinforced concrete conical floor 13.

After installation of the object 1 in the safety capsule 2 in the underground storage, the complex will be inspected

F) mine workings (not shown on the drawings), providing conditions for monitoring the condition of object 1 during its long-term storage.

An example of the implementation of the claimed invention is given in relation to the conditions of the destroyed nuclear reactor of the fourth power unit of the Chornobyl NPP.

Burial of the remains of the reactor of the fourth power unit together with the nuclear fuel and adjacent temporary grave sites is assumed to be carried out by lowering the object in a safety capsule through a pre-constructed lowering well into the underground storage. At the same time, a lowering well and storage, as well as a receiving solid bottom are built in the virgin mining massif, after which rock destruction and stockpiling of rocks are carried out within the limits of the lowering well and underground storage. The lowering of the object in the safety capsule is carried out simultaneously with the release of mining rocks through the outlet holes of the receiving solid bottom and their delivery along the shaft to the bottom surface to fill the capacity formed by it in the lowering well as the object is immersed in the safety capsule.

To do this, a shaft is being drilled at the industrial site of the Chernobyl NPP, it is being equipped with skip and cage lifts, and an underground bunker is being built. Simultaneously with the execution of these works, freezing and siltation wells are drilled from the NPP industrial site around the area of mining operations, an ice-bearing barrier in the form of a hollow cylinder is initially created in the rocks of aquifers, then a silage barrier is created.

At the same time, the thickness of the walls of the tamponage barrier is determined from the quality of the injection solution and the pressure value of 7/0 V in the aquifers.

After the tamponage layer is created, groundwater is drained into temporary reservoirs.

After that, horizontal workings are passed from the shaft towards the lowering well and underground storage on several horizons as necessary, from which a complex of horizontal, rising and inclined workings are drilled, from which work is carried out on the construction of a solid receiving bottom with 7/5 discharge holes of the underground storage , lowering well and other works necessary for burying the object according to the considered scheme.

Then a reinforced concrete capsule is built around the object, which has a foundation slab under the base of the object, on which the walls of the capsule and dome-shaped ceilings are erected in several floors on the last (top) of which a conical ceiling is erected to absorb the load of bulk rocks. The second and bottom 2 floors (capacity) of the capsule are intended for placement of destroyed mining rocks or containers of radioactive waste. The foundation plate is designed to absorb static loads, including the mass of the object, bulk rocks, or containers with radioactive waste, and the capsule covers protect the object from destruction by its bulk rocks. At the same time, the height of the floor of the safety capsule is determined by the correspondence of the load-bearing capacity of the floor and the mass of the rock or containers that are placed on the floors of the capsule. high school

The bearing capacity of the conical overlap of the capsule corresponds to the load of the mass of rocks filling the well down to the level of the day surface.

The construction of the foundation slab of the safety capsule and the construction of the walls of the first floor around the object are carried out simultaneously with the destruction and storage of the rocks of the mining massif within the limits of the lowering well and the underground storage. "- zo Then they release the destroyed mining rocks through the outlet holes of the receiving solid bottom, release them through the shaft to the bottom surface with the simultaneous lowering of the object in the safety capsule into the lowering well. with

As the object in the capsule is immersed in the lowering well, the walls are built up and the ceiling is erected above the object, then the walls of the safety capsule of the second floor are built up, the capacity of the second floor is filled with c 5 Ruined mining rocks released to the surface along the shaft, or containers with radioactive (in waste and construction of a circular floor.

Similar processes are performed on the third and subsequent floors of the safety capsule.

On the last floor, in addition to the dome-shaped ceiling, a conical one is erected, on which the destroyed rock is poured before lowering the object in a safety capsule into the underground storage. The space between the walls of the lower

Wells and safety capsules are filled with rock. The number of floors is determined by the load-bearing capacity with the overlap of the safety capsule. This technology of burying environmentally hazardous objects makes it possible to monitor the object during the entire period of its burial. The application of the claimed invention makes it possible to achieve an increase in the reliability of object storage during a given period at a great depth and to expand the field of application through the possibility

Ensuring the maximum allowable load of bulk rocks on the covering of the capsule and storage 2) structural integrity of the object, both when lowering it and to a given depth, and monitoring the centering of the object for the given period of its storage, due to the fact that before its descent into the underground storage, the object is enclosed in a safety capsule and lowered into a pre-created lowering well. Moreover, lowering the object in the safety capsule is done sequentially with the creation of containers between the caps of the capsule, filling them with destroyed rocks or containers with radioactive waste to the specified depth of the object's storage. When the object is buried at a great depth, it makes it possible to monitor

Kk inside the object during the specified period of its burial.

Claims (1)

The formula of the invention (F) The method of burying environmentally hazardous objects, which includes the penetration of a vertical shaft in the GI zone of the burial of an ecologically hazardous object, a complex of horizontal, vertical and inclined mine workings, the creation of a solid receiving bottom and underground storage, lowering the ecologically hazardous object into the object into the storage to a given depth by releasing from the outlet holes of the receiving solid bottom rock previously destroyed by drilling and blasting, which is located under the object, filling with rock formed during the release of the capacity, which differs in that previously in alluvial rocks under the ecologically hazardous object one of the well-known methods is to create a lowering well with a foundation in bedrock and a height up to the level of the day surface, before lowering the object into the well, it is locked in a safety capsule with a foundation plate at the base, and as the object in the capsule is lowered into the well and reaching its overlapping the level of the day surface, the walls of the capsule of the na are felt, and the capacity formed between the caps of the capsule is filled with rock removed through the bottom destroyed or containers with radioactive waste, and upon reaching the weight of bulk rocks on the cap of the capsule, which does not exceed the load-bearing capacity of the cap, another cap is erected and as the object in the capsule is lowered into well, the whole process is repeated up to the specified depth of burial of the object. 70 s s o «- s s s Ge) - with . and (95) ko ko ko - ko 6o 65