KR100988408B1 - Apparatus for treating radioactive solidwaste and treating method thereof - Google Patents

Abstract

PURPOSE: A device and a method for processing radioactive waste are provided to reduce a process space and the number of drums by immediately processing the radioactive waste of medium and low levels. CONSTITUTION: Radioactive waste is inputted to an inlet(100). A grinding unit(200) grinds the radioactive waste and includes a plurality of compressing rollers. A compressing unit(300) compresses the grinded radioactive waste and includes a compressing chamber and a piston. The piston moves along the length direction of a compression chamber to compress the radioactive waste. A paraffin solution supply unit(400) supplies paraffin solutions to the grinded radioactive waste. A gate unit(500) selectively opens and closes the compressing unit.

Description

Apparatus for treating radioactive solidwaste and treating method

The present invention relates to a radioactive waste treatment apparatus. More specifically, the present invention relates to a radioactive waste treatment apparatus that can be immediately processed safely while reducing the volume of radioactive waste of medium and low levels discharged from nuclear power plants, hospitals, and the like.

Radioactive waste is an undesired radioactive material that arises from the use of nuclear energy, and is used in experiments or work as well as leaks from wastes, fission products, cooling water and cooling gases from nuclear facilities or workshops or laboratories dealing with radioactive materials. Tools, cloth, paper, wash water, etc.

The treatment of radioactive waste depends on whether the waste is solid, liquid, or gas. Among them, solid waste is divided into non-combustibles and combustibles. After hardening, it is buried in deep sea or ground for disposal.

Radioactive waste can be classified into high and low level radioactive waste, depending on the radioactivity level. High-level radioactive waste is not considered to be waste because it can recycle more than 95% of the fuel from spent fuel and its reprocessing.

Low-level radioactive waste may be classified as medium-level waste with a relatively high radioactivity level. Most low-level radioactive wastes are beta / gamma wastes that emit beta rays or gamma rays, and alpha wastes that are somewhat more intense are called alpha wastes. In addition, it is called super uranium waste (TRU waste) that contains ultra uranium element among alpha wastes.

Low-level radioactive waste is a solid waste from gloves, gumshoes, work clothes, mops, various replacement parts, and related industries, hospitals, and research institutes used by operators and maintenance personnel of nuclear power plants. It is buried in deep sea or ground for disposal.

This method is a method of storing the radioactive waste in a container without a separate treatment, so that the volume is increased to occupy a lot of drum space, there is a problem that the number of the drum can be increased and the storage space in which the drum can accumulate that much.

In particular, as the use of nuclear power becomes full-fledged, the problem of disposal of radioactive waste, which is increasing day by day, becomes an important task.

Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to provide a radioactive waste treatment apparatus which can be safely treated immediately while reducing the volume of the radioactive waste of medium and low levels discharged from a nuclear power plant, a hospital, and the like.

The present invention is a radioactive waste input unit; A pulverizing unit which moves while crushing the injected radioactive waste; And a pressing unit for pressing the crushed radioactive waste and extruding the compressed radioactive waste into a storage container. It provides a radioactive waste treatment apparatus comprising a.

The crushing unit may include a plurality of pressing rollers provided in a pair at an upper portion and a lower portion to convey the radioactive waste while compressing the radioactive waste.

The plurality of pressing rollers may be arranged in an order of increasing speed toward the moving direction so that the radioactive waste may be crushed while moving.

The pressing part may include a pressing chamber in which a space in which the radioactive waste is pressed is formed, and a piston for pressing the radioactive waste while moving along the longitudinal direction of the pressing chamber.

The compression chamber may be provided with a heater unit and a cooling unit.

And a gate portion coupled to the crimping portion, wherein the gate portion is formed with an insertion hole into which the storage container is inserted and is coupled to the front plate and slidably movable to the front plate. It may include a slide wall for opening and closing the.

The apparatus may further include a paraffin solution supply unit supplying a paraffin solution to the crushed radioactive waste.

One side of the gate unit may further include a storage container transfer unit for supplying and discharging the storage container.

The storage container transfer unit is a storage container rotating unit for rotating the storage container; A transfer roller for transferring the storage container; And it may include a storage container forward and backward unit for forward and backward the storage container rotating unit toward the insertion hole.

On the other hand, the present invention is the input step of injecting radioactive waste; A compression crushing step of crushing the injected radioactive waste; Paraffin solution mixing step of supplying and mixing the paraffin solution to the ground radioactive waste; A pressing step of pressing the supplied paraffin solution and the ground radioactive waste; Provided is a radioactive waste disposal method comprising a storage container receiving step of compressing a radioactive waste compressed into a predetermined volume into a storage container.

After the storage container receiving step may be a discharge step of discharging the storage container.

According to the present invention can reduce the cost of the radioactive waste of the middle and low level discharged from nuclear power plants, hospitals, etc. immediately safe treatment can reduce costs and increase the number of drums required for storage and the processing space can be relatively increased. It works.

The present invention is a radioactive waste input unit; A pulverizing unit which moves while crushing the injected radioactive waste; And a pressing unit for pressing the crushed radioactive waste and extruding the compressed radioactive waste into a storage container. It provides a radioactive waste treatment apparatus comprising a.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, a 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.

1 is a perspective view of a radioactive waste treatment apparatus according to an embodiment of the present invention, Figure 2 is a view of the main portion of Figure 1, Figure 3 is a cross-sectional view of Figure 2, Figure 4 is the operation of the compacting roller of Figure 2 State diagram.

As shown in FIG. 1, the apparatus for treating radioactive waste according to the present invention includes an injection unit 100 into which radioactive waste is injected, a crushing unit 200 for moving while crushing the injected radioactive waste, and compression of the crushed radioactive waste. The unit 300, the paraffin solution supply unit 400 for supplying a paraffin solution to the crushed radioactive waste to be compressed together, the gate unit 500 for selectively opening and closing the pressing unit 300, and processed It may include a storage container transfer unit 600 for transporting the storage container (D) in which radioactive waste is accommodated.

The input unit 100 may be formed in the form of a hopper having an upper portion opened so that the radioactive waste is easily introduced into the radioactive waste. The input unit 100 may be naturally moved to the crushing unit 200 while the inclined surface is formed therein and the radioactive waste injected from the upper slides downward.

In addition, a frame 10 having a work table 13 and a ladder 11 is installed at one side of the input unit 100 so that an operator can easily input the radioactive waste through the input unit 100. Therefore, the worker may climb the workbench 13 on the ladder 11 to inject the radioactive waste into the input unit 100. Of course, the radioactive waste treatment apparatus may be installed at a low position and may be implemented in a structure in which the injector can be directly injected into the inlet unit 100 at a high position.

In this case, the radioactive waste introduced into the input unit 100 is a medium-low level solid waste generated in a nuclear power plant, a hospital, etc., and is mainly made of work clothes, gloves, shoes, toilet paper, and other nonmetallic radioactive pollutants.

In other words, the radioactive waste introduced into the input unit 100 is a solid waste, so that there is a constant volume before treatment, it is necessary to reduce the volume. Therefore, the radioactive waste that is injected into the input unit 100 is pulverized while moving to the grinding unit 200 and undergoes a process of primarily reducing its volume.

To this end, the crushing unit 200 includes a plurality of pressing rollers 210, 220, 230, and 240 moving the radioactive waste moved from the feeding unit 100 in a planar manner. The plurality of pressing rollers 210, 220, 230, 240 are provided in a pair at the top and bottom, respectively, so that radioactive waste is inserted in the middle.

In this embodiment, the pressing roller is composed of four pairs, the first pressing roller 210, the second pressing roller 220, the third pressing roller 230, first 4 will be referred to as a roller 240.

The fourth compression roller 240 illustrated in an enlarged manner in FIG. 2 may be formed in a concave-convex shape in which a plurality of grooves 241 and protrusions 243 in which parts having different diameters are alternately disposed along the length direction are formed. . Similarly, the first compression roller 210, the second compression roller 220, and the third compression roller 230 may also be provided to have such grooves and protrusions.

Of course, the shape of the projections and the grooves of the plurality of pressing rollers may vary as needed, and may be installed to face the grooves and the projections adjacent to each other. And the size of the pressing rollers can also be implemented differently.

Radioactive waste passing through the plurality of pressing rollers (210, 220, 230, 240) is primarily reduced in volume and may be separated into several pieces by folding or cutting a portion passing through the projections and grooves.

In addition, the plurality of pressing rollers 210, 220, 230, and 240 may be arranged in an order of increasing speed toward the moving direction so that the radioactive waste may be crushed while moving. For example, the rotational speed of the first compression roller 210 is 8rpm, the rotational speed of the second compression roller 220 is 9rpm, the rotational speed of the third compression roller 230 is 10rpm, and the fourth compression roller 240 is The rotation speed can be 12 rpm.

Therefore, as shown in FIG. 4, the traveling speed of the radioactive waste passing through the first compression roller 210 is v1, and the traveling speed of the radioactive waste passing through the second compression roller 220 is v2 and the third compression roller 230. When the moving speed of the radioactive waste passing through v) is v3 and the running speed of the radioactive waste passing through the fourth compression roller 240 is v4, the magnitude of the moving speed may be v1 <v2 <v3 <v4. .

Accordingly, the radioactive waste moving while traveling between the plurality of pressing rollers 210, 220, 230, and 240 is crushed while being torn along the longitudinal direction by the speed difference while being compressed.

As such, the radioactive waste that is crushed while being primarily compressed in volume is moved to the pressing unit 300 and mixed with the paraffin solution to be compressed.

To this end, the pressing unit 300 is a pressing chamber 310 is formed with a space for pressing the crushed radioactive waste, as shown in Figure 3, the radioactive waste while moving along the longitudinal direction of the pressing chamber 310 It comprises a piston 330 for pressing.

The pressing chamber 310 is formed in a cylindrical shape having a circular cross section and an inlet 320 is formed at one upper side thereof. Therefore, the radioactive waste crushed from the crushing unit 200 and the paraffin solution are supplied from the paraffin solution supply unit 400 through the inlet 320, and may be accumulated in the pressing chamber 310.

The piston 330 reciprocates in a horizontal direction, and when the mixture of the pulverized radioactive waste and the paraffin solution accumulated in the compression chamber 310 reaches a predetermined volume, the piston 330 compresses the volume thereof secondarily. The piston 330 may be supplied with high pressure power by hydraulic pressure or the like.

As described above, the pressing unit 300 reduces the volume of the crushed radioactive waste secondaryly by reducing the volume by the crushing unit 200. In addition, the pressing of the piston 330 may proceed with pressing the mixture of the radioactive waste and the paraffin solution as much as the capacity contained in the storage container (D).

At this time, the paraffin solution supply unit 400 may be crushed by the crushing unit 200 and the radioactive waste may be compressed together by the piston 330 while supplying the paraffin solution to the radioactive waste accumulated in the pressing chamber 310. Make sure

The paraffin solution supply unit 400 may be provided with a heater therein to supply the paraffin solution in a liquid state, or may be sprayed in a spray form to increase the mixing area with radioactive waste.

The paraffin solution supplied to the radioactive waste not only prevents secondary pollution of the environment by the radioactive waste, but also mixes with the pulverized radioactive waste and solidifies the radioactive waste so that it can be easily contained in the storage container (D).

Furthermore, a heater and a cooling unit may be installed on the outer circumference of the pressing chamber 310 to cool or heat the paraffin solution administered in the pressing chamber 310. That is, when the paraffin solution and the radioactive waste are compressed together, the paraffin solution needs to be kept in the liquid phase, so that the heater unit is operated, and after the mixture is compressed, the cooling unit is easily contained in the storage container (D). Run to solidify it.

After the mixture of the radioactive waste and the paraffin solution is compressed and solidified by the crimping unit 300, it should be contained in the storage container (D). At this time, the volume of the solidified mixture is preferably sized to accommodate the storage container (D) at a time to increase the space utilization.

On the other hand, the pressing portion 300 is coupled to the gate portion 500 for selectively opening and closing the side inlet portion of the pressing chamber 310.

The gate part 500 is formed with an insertion hole 505 into which the storage container D is inserted, the front plate 510 coupled to the inlet of the crimping chamber 310 and sliding to the front plate 510. It may be made to include a slide wall 520 is coupled to the moveable to open and close the insertion hole 505. Here, the slide wall 520 may selectively open and close the insertion hole 505 while moving in the manner of lifting up and down by the hydraulic cylinder 530.

Therefore, while the radioactive waste is compressed by the crimping unit 300, the slide wall 520 is in a state in which the insertion hole 505 is closed, and the radioactive waste solidified from the compression chamber 310 is stored. When the slide wall (520) is to be contained in the slide wall (520) to move upwards to open the insertion hole (505).

When the radioactive waste is first and secondly crushed and compressed and treated, it should be contained in the storage container (D) and discharged to the outside.

5 to 8 is a view showing the operation of discharging radioactive waste, the configuration and operation thereof will be described in detail.

First, the storage container transfer part 600 enters the storage container D into the gate part 500 to receive a mixture of the treated radioactive waste and the paraffin solution or discharges it to the outside after the mixture is accommodated. do.

The storage container transfer unit 600 is a storage container rotating unit 610 to rotate the storage container (D) to be inserted into the insertion hole 505 of the gate portion 500, and transfers the storage container (D). It may be made to include a conveying roller 620 and the storage container forward and backward unit 630 for advancing the storage container rotating unit 610 toward the insertion hole 505 of the gate portion 500.

As shown in FIG. 5, the storage container rotating unit 610 is fixed while holding the circumference of the storage container D, and the insertion hole 505 of the gate part 500 is opened as shown in FIG. 7. When the fixed storage container (D) is rotated by 90 degrees can be positioned to correspond to the inlet of the storage container (D) in the insertion hole (505).

The transfer roller 620 is provided with a plurality of rollers to transport the storage container (D) upright or lying down, the storage container forward and backward unit 630 is the storage container rotating unit located in the gate portion 500 ( In order to insert the 610 into the insertion hole 505 of the gate part 500, the back and forth operation may be performed in detail.

Therefore, as shown in FIG. 6, when the radioactive waste solidified from the pressing chamber 310 is to be contained in the storage container D, the slide wall 520 moves upward to open the insertion hole 505. As shown in FIG. 7, the storage container rotating unit 610 rotates the storage container D by 90 degrees to position the inlet of the storage container D side by side in the insertion hole 505.

Subsequently, as shown in FIG. 8, the storage container rotating unit 610 advances to the insertion hole 505 by the storage container forward and backward unit 630 and inserts the inlet of the storage container D into the insertion hole 505. To communicate with the pressing chamber 310.

Next, the heater unit provided on the outer circumference of the pressing chamber 310 is temporarily operated to dissolve the paraffin to separate the outer circumference of the solidified radioactive waste from the outer wall of the pressing chamber 310, and to operate the piston 330 to solidify the radioactive waste. It is put in the storage container (D).

When the treated radioactive waste is contained in the storage container (D), the storage container forward and backward unit 630 reverses the storage container (D), and the storage container rotating unit 610 again stores the storage container (D). Rotate 90 degrees in the opposite direction to the original position.

The storage container D containing the radioactive waste is sealed with a lid and then discharged to the outside along the transport roller 620, and then a new empty storage container D enters the gate 500 along the transport roller 620. Can be.

As described above, according to the radioactive waste treatment apparatus of the present invention, it is possible to safely process the radioactive waste discharged from a nuclear power plant, a hospital, etc. while reducing the volume of radioactive waste at a low level, thereby reducing the cost and the number and processing space of drums required for storage. There is an effect that can be increased relatively.

9 is a flow chart of the radioactive waste treatment method of the present invention, the radioactive waste treatment method of the present invention will be described with reference to FIG.

First, an input step (S10) of injecting radioactive waste into the input unit 100 is performed.

When the radioactive waste is input, the pressurized crushing step (S20) of crushing the injected radioactive waste is primarily compressed in the crimping unit 300 is followed.

The pressing machine crushing step (S30) is to squeeze and crush the radioactive waste using the grooves and protrusions of the plurality of pressing rollers (210, 220, 230, 240) and different rotational speeds.

The radioactive waste that passed through the compression milling step (S30) is first moved to the compression chamber 300 while the volume is reduced.

Subsequently, a paraffin solution mixing step (S30) is performed in which the paraffin solution is supplied to and mixed with the crushed radioactive waste by moving to the squeezing chamber 300, and a squeezing step of secondarily compressing the supplied paraffin solution and the crushed radioactive waste ( S40) proceeds.

The radioactive waste compressed to a predetermined volume while repeatedly performing the pressing step (S40) is a storage container extruded in the storage container (D) by the pressing part 300, the gate part 500, the storage container transfer part 600, etc. A receiving end step (S50) and the discharge step (S60) for discharging the storage container (D) to the outside is performed.

As described above, according to the radioactive waste treatment method of the present invention, it is possible to safely process the radioactive waste discharged from nuclear power plants, hospitals, etc. while reducing the volume of the radioactive waste at a low level, thereby reducing costs and the number and processing space of drums required for storage. There is an effect that can be increased relatively.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 is a perspective view of a radioactive waste treatment apparatus according to an embodiment of the present invention.

FIG. 2 is a view of an essential part of FIG. 1; FIG.

3 is a cross-sectional view of FIG.

4 is an operating state of the compression roller of FIG.

5 to 8 show the operation of discharging radioactive waste.

9 is a flow chart for the radioactive waste treatment method of the present invention.

<Description of reference numerals for main parts of the drawings>

10 frame 11 ladder 13 work table

100: input part 200: grinding part 300: pressing part

400: paraffin solution supply part 500: gate part 600: storage container transfer part

Claims (11)

delete delete An input unit into which radioactive waste is input; A crushing unit having a plurality of pressing rollers provided in a pair at an upper portion and a lower portion so as to transport the radioactive wastes while pressing them, and a crushing unit for moving the radioactive wastes while grinding them; And And a pressing unit for compressing the crushed radioactive waste and extruding the compressed radioactive waste into a storage container. Wherein the plurality of pressing rollers are arranged in an order of increasing speed toward the moving direction so that the radioactive waste may be crushed while moving. The method of claim 3, The pressing portion A compression chamber in which a space in which the radioactive waste is compressed is formed; And a piston for compressing the radioactive waste while moving along the longitudinal direction of the compression chamber. The method of claim 4, wherein Radioactive waste treatment apparatus characterized in that the compression chamber is provided with a heater and a cooling unit. The method of claim 4, wherein Further comprising a gate portion coupled to the crimping portion, The gate portion Radioactive waste treatment, characterized in that the insertion hole is formed is inserted into the storage container and the front plate coupled to the inlet of the compression chamber, and the slide wall is slidably coupled to the front plate and the opening and closing the insertion hole Device. The method according to any one of claims 3 to 6, Radioactive waste treatment apparatus further comprises a paraffin solution supply unit for supplying a paraffin solution to the crushed radioactive waste. The method of claim 6, One side of the gate portion is a radioactive waste treatment apparatus further comprising a storage container transfer unit for supplying and discharging the storage container. The method of claim 8, The storage container transfer unit A storage container rotating unit for rotating the storage container; A transfer roller for transferring the storage container; And And a storage container forward and backward unit for forwarding the storage container rotating unit back and forth toward the insertion hole. delete delete

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