KR101399295B1 - Method for constructing semi-basement structure for radioactive waste - Google Patents

Abstract

The present invention relates to a method for constructing a semi-basement for storing radioactive waste and, more particularly, to a method for constructing a semi-basement for storing radioactive waste, capable of performing an impervious construction and preventing the diffusion of radioactive materials by installing hydrophobic limestone powder, a radiation shielding sheet, and a waterproof panel between the ground and a wall while constructing an upper structure on the ground after constructing the wall and base of a silo under the ground by excavating the ground. Also, the structure is applied to a base rock, a soft ground, a sand ground, and a subterranean water ground. An impact buffering space part is separated from the wall installed under the ground with a preset distance. An earthquake-proof structure is designed and the diffusion of the radiation is prevented in an emergency situation by filling the impact buffering space part with cement mortar and curing the cement mortar with the impact buffering materials in the emergency situation when the impact buffering space part is filled with impact buffering materials.

Description

METHOD FOR CONSTRUCTION SEMI-BASEMENT STRUCTURE FOR RADIOACTIVE WASTE BACKGROUND OF THE INVENTION [0001]

The present invention relates to a method of constructing a radioactive waste storage structure for radioactive waste storage, and more particularly, to a method of constructing a radioactive waste storage structure by excavating a ground to construct a foundation and a wall of a silo underground and then constructing an upper structure on the ground, The present invention relates to a method of constructing a radioactive waste storage structure for storing radioactive waste in which limestone powder, a radiation shielding sheet, and a waterproof panel are installed to perform the ordering and to prevent diffusion of radioactive materials.

Radioactive wastes are classified as low- and high-level radioactive wastes and high-level radioactive wastes, depending on the level of contamination with radioactive materials, such as waste from workplaces or laboratories dealing with nuclear facilities or radioactive materials. The definition of radioactive waste is a radioactive substance or a substance contaminated by it, which is a substance to be disposed of. Low- and mid-level radioactive wastes are contaminated work products in the case of nuclear power plants, contaminated products in the case of hospitals, and nondestructive tests in industries, while high-level radioactive wastes are produced in nuclear power plants. . In other words, the generation of radioactive waste occurs in all fields using nuclear energy such as schools, hospitals, research institutes, industries, and nuclear power.

Disposal method of radioactive waste should be disposed within several hundred meters of medium and low level radioactive waste considering the topography characteristics. A shallow land disposal is a method of installing a concrete structure on the earth's surface and a rock cavern disposal is a method of excavating a tunnel / silo in underground rocks of several hundred meters or more, do. In the case of high-level radioactive waste, deep geological disposal is performed on rocks within 500 to 1,000 m from the surface.

The method of disposing of medium and low level radioactive waste varies from country to country, and it is decided based on complex consideration of national sentiment, economical efficiency, construction ability and safety. When a disposal site is exposed to the outside, shielding reinforcement is required to attenuate and block the amount of radiation generated inside the disposal site. It is also necessary to consider terrorism, enhancement of the shielding structure to reduce dose of residents' exposure, and consideration of national sentiment. On the other hand, in case of disposal underground, construction in areas with a lot of groundwater and weak geological condition will increase the construction cost due to prolonged construction period and increase the risk of safety accidents for workers. In the case of Korea, cave disposal method is being constructed in the area where both the celestial disposal and cave disposal are possible.

In the land disposal method for radioactive waste disposal, the concept of multiple barriers is introduced as the basic policy of securing safety as in the case of nuclear power plants. The use of engineered barriers such as waste solid bodies, packaging containers, cushioning materials, and disposal facility structures, and natural barriers provided by the disposal site to confine the radioactive nuclides contained in the waste, Delay.

However, engineering barriers are inevitably deteriorated due to time and environmental influences, and there is a problem of passively blocking the movement of radionuclides that have leaked.

As described in Korean Patent Laid-Open Publication No. 10-2012-0058939, a biological barriers including a limestone layer, a microbial layer and a phosphate layer, a biological barrier for blocking radioactive material from a radioactive waste repository on the ground, The use of radioactive waste treatment facilities consisting of biological barriers, including limestone layers, microbial and phosphate layers, and ground radioactive waste reservoirs, to prevent the diffusion of radioactive materials such as uranium that diffuse into the soil from ground or surface radioactive waste reservoirs Technology has been developed.

However, such a radioactive waste disposal facility excavates the ground floor at a certain depth, secures a large space in the excavated ground, forms a living body barrier, replaces the living body barrier, and then constructs the treatment facility. There is a problem that the construction cost is increased.

In addition, such a radioactive waste treatment facility is equipped with a waterproofing / watering facility outside the wall. However, when maintenance is carried out for hundreds of years to several thousands of years, deterioration of the materials used, There is a problem in that the natural environment may be destroyed.

In addition, such a radioactive waste disposal facility has many limitations according to the installation site and includes seismic design, but unexpected problems may occur in long-term maintenance.

Korean Patent Publication No. 10-2012-0058939

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for constructing a silo base and a wall by excavating a ground, And to provide a method of constructing a ring structure for storage.

The present invention also relates to a method of constructing a radioactive waste storage structure for radioactive waste storage, in which the limestone powder, the radiation shielding sheet, and the waterproof panel are hydrophobized between the ground and the wall, There are other purposes to provide.

It is another object of the present invention to provide a method for constructing a ring structure for storing radioactive waste, which can be applied to rock, soft ground, sand ground, ground water ground, and the like.

In addition, the present invention is characterized in that a shock buffer space is formed by being spaced apart from a wall installed in a basement, a cushion mortar is filled in an emergency in a state of filling the shock buffer with an impact buffer, The present invention also provides a method for constructing a ring structure for radioactive waste storage, which can prevent diffusion of radioactive waste.

According to an aspect of the present invention,

A first step of cutting a target ground to form a horizontal plane; A second step of excavating the horizontal surface to a predetermined depth, placing the shotcrete on the excavation surface, and excavating the shotcrete to a designed depth; A third step of laminating limestone powder after placing shotcrete on the bottom of the excavation surface and laminating a waterproof panel having a radiation shielding sheet attached to the bottom surface thereof on the limestone powder surface; A fourth step of placing a reinforcing bar on the upper surface of the waterproof panel and then placing and curing concrete to form a bottom slab; The waterproof panel having the radiation shielding sheet attached to the back surface thereof is fixed to the back surface form and the front surface form is spaced apart from the back surface form by a predetermined distance, A fifth step of arranging a reinforcing bar, casting and curing concrete to form a wall to be coplanar with or less than the horizontal plane, and forming an upper structure on the wall; And a sixth step of removing the back formwork and the front formwork, and filling the space between the back formwork and the excavation surface with the limestone powder.

In the second step, if the ground is a soft ground, a cable bolt, a rock bolt, a cable bolt and a lock bolt are installed on the excavation surface, grouting is performed outside the excavation surface when groundwater flows out from the ground, In the case of a sandy ground, the upper end of the excavation surface is excavated in a form larger than the designed width.

Here, the limestone powder is subjected to hydrophobic treatment using a hydrophobic treatment agent so as to be waterproofed and adiabatic, and has an average particle size of 5 to 10 탆.

Here, the radiation shielding sheet includes barium sulfate (BaSO4) and boric acid in the silicone rubber.

Here, the waterproof panel is a polyethylene (polyethylene or polypropylene double frame).

In addition, the method for constructing a radioactive waste for radioactive waste storage may be such that a shock buffer space is formed perpendicular to the ground by spacing a certain distance from the wall, a shock buffer such as gravel or sand is filled in the shock buffer space, A vertical pipe having a plurality of discharge holes is inserted so as to be filled with cement mortar and cured together with the shock buffer.

Here, in the shock-absorbing space portion, concrete is laid on the side and bottom surfaces, and a cover is formed on the top.

Here, the wall is formed into a cylindrical shape or a square shape in plan view.

Here, the upper structure may be a dome shape, a horizontal shape, or a triangular shape.

According to the method of constructing the radioactive waste storage structure for radioactive waste according to the present invention as described above, it is possible to shorten the construction period and reduce the construction cost by constructing the silo dome structure on the ground part after excavating the ground to construct the base and walls of the silo underground can do.

In addition, according to the present invention, the limestone powder, the radiation shielding sheet, and the waterproof panel, which are hydrophobized between the ground and the wall, are installed to perform the order of the wall and to prevent diffusion of the radioactive material.

Also, according to the present invention, it is possible to apply to rock, soft ground, sand ground, ground water ground, and the like.

According to the present invention, a shock buffer space is formed by being spaced apart from a wall installed in a basement, a cushion mortar is filled in an emergency in a state where the shock buffer is filled, and the cushion is cured together with the shock buffer. Radiation diffusion can be blocked.

1 is a view showing a ring dome structure constructed by a method of constructing a radioactive waste for radioactive waste storage according to an embodiment of the present invention.
2 is a view showing a ring dome structure constructed by a method of constructing a radioactive waste for radioactive waste storage according to another embodiment of the present invention.
FIGS. 3A to 3F are diagrams for explaining a process of a method of constructing a radioactive waste storage structure according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a method of constructing a radioactive waste storage structure for radioactive waste according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

FIG. 1 is a view showing a ring dome structure constructed by a method of constructing a radioactive waste for radioactive waste storage according to an embodiment of the present invention. FIG. 2 is a perspective view of a ring dome structure for radioactive waste storage according to another embodiment of the present invention. 3A to 3F are diagrams for explaining a process of a method of constructing a radioactive waste storage structure for storing radioactive waste according to an embodiment of the present invention.

1 to 3F, a method of constructing a radioactive waste storage structure for radioactive waste storage according to an embodiment of the present invention is as follows.

&Quot; First process-S100 "

First, as shown in FIG. 3A, the target ground 1 is cut to form a horizontal plane 3. At this time, the horizontal plane 3 is to cut the upper part of the target ground 1 so that the construction surface of the structure is leveled so that various perforations, excavation equipment and materials can be loaded.

&Quot; Second Process-S110 "

When the formation of the horizontal surface 3 is completed, as shown in FIG. 3B, the horizontal surface 3 is excavated to a predetermined depth (for example, when the ground is a rock, it is blasted by 1 to 3 m) The shotcrete (7) is installed and excavated up to the designed depth. At this time, if the ground is a soft ground, it is preferable to install a cable bolt, a lock bolt, a cable bolt and a lock bolt on the excavation surface 5, and to perform grouting outside the excavation surface 7 when the groundwater flows out If the ground is a sandy ground, it is preferable to excavate the upper end of the excavation surface 7 in an enlarged form than the design width.

&Quot; Third Process-S120 &

3C, the shotcrete 7 is laid on the bottom of the excavation surface 5 and then the limestone powder 9 is laminated. On the upper surface of the limestone powder 9, the radiation shielding sheet 11 is placed on the bottom surface And the attached waterproof panel 13 is laminated. In this case, the limestone powder 9 is preferably formed in a horizontal plane through lamination and compaction. The waterproof panel 13 is made of polyethylene or polypropylene double frame (PDF), and the radiation shielding sheet 11 is adhered to the bottom Or the like. It is preferable to fill the space between the radiation shielding sheet 11 and the waterproof panel 13 with a finishing material such as silicone. Here, the limestone powder 9 is treated with a hydrophobic treatment agent such as hexamethyldisilacane (Si2 (CH3) 6) or N-diethylamine (N-DIETHYL ETHANAMINE) And has an average particle size of 5 to 10 탆. Here, the radiation shielding sheet 11 is also produced by mixing powdery barium sulfate (BaSO4) and powdery boric acid in a liquid silicone rubber.

&Quot; Fourth Step-S130 &

When the lamination of the waterproof panel 13 is completed, as shown in FIG. 3D, a reinforcing bar is placed on the upper surface of the waterproof panel 13, and concrete is laid and cured to form the floor slab 100.

&Quot; Fifth step-S140 "

As shown in FIG. 3E, the back surface form 15 is vertically installed at a predetermined distance (about 10 to 50 cm) from the excavation surface 7, and the radiation shield sheet 11 is attached to the back surface form 15, The waterproof panel 13 attached to the back surface is fixed and the front formwork 17 is installed at a distance from the back formwork 15 by a predetermined distance (wall thickness). Then, reinforcing bars are laid and the concrete is laid and cured The wall 110 is formed in line with the horizontal plane 3 and the upper structure 120 is formed at the upper end of the wall 110. [ The upper structure 120 is preferably installed on the ground surface but the wall 110 may be formed lower than the horizontal surface 3 and the upper structure 12 may be formed thereon. 110). At this time, the wall 110 may have a planar shape in a cylindrical shape or a square shape, and the upper structure 120 may be formed in any one of a dome shape, a horizontal shape, and a triangular shape.

&Quot; Sixth step-S 190 &

Then, after removing the back formwork 15 and the front formwork 17, the limestone powder 9 is filled in the space portion 19 between the back formwork 15 and the excavation surface 7 as shown in Fig. 3F do. Here, the limestone powder 9 is a powder subjected to hydrophobic treatment as described above.

2, the shock-absorbing space 130 is formed perpendicularly to the ground by spacing a certain distance from the wall 110 as shown in FIG. 2, The buffer space 130 is filled with the shock buffer 140. At this time, the shock cushioning space part 130 is poured with concrete on the side and bottom surfaces. Meanwhile, the shock buffer 140 is selected from gravel or sand, and the shock buffer space 130 is formed with a lid 131 so that inflow of rainwater and surface water is blocked at the upper end thereof. The shock cushioning space 130 may include a vertical pipe 150 having a plurality of discharge holes 151 so as to be cured together with the impact buffer 140 by filling cement mortar in an emergency, that is, Is inserted.

In addition, the ring-shaped dome structure for storing radioactive waste according to the present invention may be buried in a basement rather than a ring-shaped structure. At this time, a waterproof panel 13 and a radiating panel 13 are formed on the outer side of the wall constituting the upper structure, After the shielding sheet 11 and the limestone powder 9 are installed, the gravel is backfilled.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

9: limestone powder 11: radiation shielding sheet
13: Waterproof panel 100: Floor slab
110: wall 120: superstructure
130: shock buffer space part 140: shock buffer agent
150: Vertical pipe

Claims (9)

A first step of cutting a target ground to form a horizontal plane;
A second step of excavating the horizontal surface to a predetermined depth, placing the shotcrete on the excavation surface, and excavating the shotcrete to a designed depth;
A third step of laminating limestone powder after placing shotcrete on the bottom of the excavation surface and laminating a waterproof panel having a radiation shielding sheet attached to the bottom surface thereof on the limestone powder surface;
A fourth step of placing a reinforcing bar on the upper surface of the waterproof panel and then placing and curing concrete to form a bottom slab;
The waterproof panel having the radiation shielding sheet attached to the back surface thereof is fixed to the back surface form and the front surface form is spaced apart from the back surface form by a predetermined distance, A fifth step of arranging a reinforcing bar, casting and curing concrete to form a wall to be coplanar with or less than the horizontal plane, and forming an upper structure on the wall; And
And a sixth step of removing the back formwork and the front formwork, and filling the limestone powder in a space between the back formwork and the excavation surface,
The shock buffer space is formed to be perpendicular to the ground by spacing a certain distance from the wall to fill the shock buffer space with a shock buffer such as gravel or sand and to fill the interior with cement mortar so as to be cured together with the shock buffer. Wherein a vertical pipe having a plurality of discharge holes is inserted. The method according to claim 1,
In the second step,
If the ground is soft ground, cable bolts, rock bolts, cable bolts and rock bolts are installed on the excavation surface, grouting is performed outside the excavation surface when groundwater flows out from the ground, and if the ground is sand ground, Is excavated in an enlarged form larger than the design width. The method according to claim 1,
The limestone powder may contain,
Wherein the hydrophobic treatment is carried out using a hydrophobic treatment agent so that waterproofing and thermal insulation are carried out, and the average particle size is 5 to 10 탆. The method according to claim 1,
The radiation shielding sheet may include:
Wherein the silicon rubber comprises barium sulphate (BaSO4) and boric acid. The method according to claim 1,
Wherein the waterproof panel comprises:
Wherein the radioactive waste is a polyethylene or polypropylene double frame (PDF). delete The method according to claim 1,
The shock-
Wherein the concrete is laid on the side and bottom surfaces, and the lid is formed on the upper side. The method according to claim 1,
Wherein the wall comprises:
Wherein the planar shape is formed into a cylindrical shape or a square shape. The method according to claim 1,
Wherein the upper structure comprises:
A dome shape, a horizontal shape, and a triangular shape.

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