KR101046529B1 - Combined Radioactive Waste Compressor and Compression Method thereof - Google Patents

Abstract

Disclosed is a combined radioactive waste compressor that can maximize the reduction ratio. The complex radioactive waste compressor according to the present invention includes a compressor body having a compression space, a collection member selectively mounted in the compression space with radioactive waste loaded therein, and selectively pressing the collection member mounted on the compressor body. And a vacuum unit for vacuuming the inside of the collecting member, wherein the collecting member is primarily pressed by the pressing unit and inflated by the air therein to be in close contact with the inner surface of the compressor body corresponding to the compressed space. It is compressed by the pressurizing part and the vacuum part. According to such a configuration, the shape of the collecting member in which the radioactive waste is collected by the compressor body can be compressed while maintaining a constant shape without a separate mold, thereby improving the compressibility of the radioactive waste.

Radioactive, Waste, Compressed, Vacuum, Reduced, Recovered, Reclassified.

Description

Combination of Radioactive Waste Compressor and Compression Method thereof {COMBINED TYPR COMPACTOR AND METHOD FOR RADIOACTIVE WASTE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radioactive waste compressor, and more particularly, to a hybrid radioactive waste compressor and a compression method thereof capable of compressing medium and low level radioactive waste by vacuum force and pressure.

The disposal cost for the disposal of medium and low level radioactive waste such as disposable coveralls, gloves, gumshoes, vinyl and decontamination paper among the radioactive wastes generated during the development of the nuclear power plant is approximately 5 million to 6 million won for the 200-l steel drum. It is expensive. As a result, the medium / low level radioactive waste is disposed of at a reduced volume.

On the other hand, the medium / low level radioactive waste is incinerated to reduce volume or re-separated to distinguish deregulated waste whose radiation level is at or below natural radioactivity. Here, the deregulated waste was radioactive waste at the time of collection, but is treated as a general waste since it is a waste whose radioactive intensity decreases over time. With this configuration, the medium / low level radioactive waste is reduced in volume on the premise of incineration and fractionation.

However, when the medium / low level radioactive waste is forcibly compressed by hydraulic / pneumatic type, the compressed material of the medium / low level radioactive waste is distorted or stuck to each other, resulting in difficulty in incineration and reclassification. In addition, the medium / low level radioactive waste is compressed in a sealed state in a sealed waste disposal bag to prevent scattering of contaminants. Thereby, the waste disposal bag is torn by the compressed air inside during the compression of the medium and low level radioactive waste, thereby causing a serious problem that can be leaked to the outside.

On the other hand, in the case of the general compressor, when releasing the compressive force after compressing the radioactive waste, there is a disadvantage that the reduction ratio is not large because the predetermined form is restored by the elastic force of the compressed material. In order to improve the elastic resilience problem, the radioactive waste may be compressed with a vacuum force, but another problem in which the compression form is not uniform is caused because the volume of the radioactive waste is contracted in various directions.

When the radioactive waste is compressed by the vacuum force, the mold may be compressed into a bag in which the radioactive waste is collected to make the compression form constant. However, in this case, since the mold cannot be separated from the bag after the radioactive waste compression process, the mold also has a problem of being radioactive waste. Further, another problem arises such that the compression range of the collecting member is limited by the mold, or the upper part of the compact is convex out of the mold by various kinds of radioactive waste. In addition, the compressed material of a slightly hard solid, such as the decontamination paper which is dried after being treated by a liquid such as decontamination liquid and / or soapy water is insufficient compression only by vacuum force, so there is a problem of lowering the compression efficiency required external auxiliary pressurizing means have.

The present invention has been made in view of the above problems, and to provide a radioactive waste compressor and a compression method thereof that can improve the reduction ratio.

Another object of the present invention is to provide a radioactive waste compressor and a method for compressing the radioactive waste which can be compressed in a predetermined form.

It is still another object of the present invention to provide a radioactive waste compressor and a method for compressing the same, which can prevent recontamination by radioactivity upon compression of radioactive waste.

A radioactive waste compressor for achieving the above object includes a compressor body, a collecting member, a pressurizing portion, and a vacuum portion.

The compressor body according to the present invention includes a compression space and includes a door for selectively opening and closing the compression space. In this case, the compressor body may be formed of lead to shield the radiation. The collection member is selectively mounted in the compression space with radioactive waste loaded therein.

The pressing unit selectively presses and compresses the collection member mounted to the compressor body. The pressing unit includes a pressing plate for pressing the collecting member by lifting and lowering along an inner surface of the compressor body forming the compression space, and a movable unit for lifting and lowering the pressing plate. The movable part includes a handle for adjusting the lifting direction and the pressing force of the pressing plate, a pinion interlocking with the handle, and a rack gear that is driven in engagement with the pinion and installed on the shaft pillar provided on the pressing plate. do. Here, the movable part may be modified such as including a hydraulic / pneumatic system connected with the pressure plate.

On the other hand, the pressing unit, it is preferable to further include a counterweight connected to the pressing plate in order to prevent the pressing plate is lowered by its own weight.

The vacuum unit vacuums the inside of the collecting member. The vacuum unit includes suction means such as a suction fan or a vacuum pump for generating suction force, a suction hose for communicating the collecting member and the suction means with each other, and a flow control means for adjusting the flow rate of the suction air by the suction hose. .

Here, one side of the suction means is provided with a filter member for filtering the air sucked from the collection member. The flow rate control means controls the flow rate through a flow control valve installed in the suction hose, and if the suction means is a suction fan, controls the flow rate through the rotation speed control of the suction fan.

On the other hand, according to the present invention, the collecting member is first pressurized by the pressurizing portion and inflated by internal air to be in close contact with the compression space, and then compressed by the pressurizing portion and the vacuum portion. Thereby, the compression shape of the collection member can be guided by the compressor body.

In accordance with another aspect of the present invention, there is provided a method for compressing a radioactive waste, comprising: mounting a collecting member having radioactive waste collected in a compression space provided inside the compressor body, and the collecting member is inflated by internal air to correspond to the compressed space. Pressurizing the collecting member by a pressing plate descending along the inner surface of the compressor body so as to be in close contact with the inner surface of the compressor body so as to have a shape, and the pressing plate pressurizes the collecting member secondly. And simultaneously compressing the collection member by vacuuming the inside of the collection member. Here, the step of compressing the collecting member further includes the step of pressing the third compression to compress and remove the remaining air in the collecting member by the pressure plate, the compression insufficient only by the secondary pressing force and vacuum force. You may.

According to the present invention having the configuration as described above, first, by collecting the radioactive waste collected by the pressing force and vacuum force, it is possible to maximize the reduction ratio of the radioactive waste to improve the economics.

Second, by pressing the collecting member to be inflated by the internal air to be in close contact with the inner surface of the compressor body corresponding to the compression space and to compress the collecting member, the compressor body can guide the shape of the collecting member to be compressed. Therefore, even if the radioactive waste in the collection member is pressurized without a separate mold, the pressurized form can be made constant. In addition, even when the pressurized radioactive waste is to be separated again, the compressed radioactive waste can be restored to a circular shape by releasing only the vacuum force.

Third, by discharging the internal air of the pressurized collection member to the outside, it is possible to prevent the collection member from being damaged by the pressing force. Therefore, the radioactivity in the collection member can be prevented from leaking to the outside to prevent recontamination by radioactivity, thereby improving the safety of the work.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 and 2, the radioactive waste compressor 1 according to the present invention includes a compressor body 10, a collecting member 20, a pressurizing unit 30, and a vacuum unit 40.

The compressor body 10 provides a compression space S of radioactive waste. The compressor body 10 is generally formed of stainless steel having excellent strength, but may be formed of lead or an alloy containing a certain amount of lead when radiation shielding is required. In addition, the compressor body 10 is provided with a door 11 for selectively opening the compression space (S). As shown in FIGS. 1 and 3, the door 11 is half-opened in the longitudinal direction with respect to the compressor body 10 to expose the compression space. In addition, a latch member 12 is provided between the compressor body 10 and the door 11 to fix the door 11 to the compressor body 10, as shown in FIGS. 1 and 2.

On the other hand, the compressor body 10 is provided with an observation window 13 for displaying the state of the compression space (S), as shown in Figs. This observation window 13 is formed of a transparent material.

The collection member 20 is selectively mounted in the compression space (S), as shown in Figure 4, the radioactive waste (W) is collected. Herein, the radioactive waste (W) refers to medium and low level radioactive waste (W), such as disposable gloves, coveralls, overshoes, vinyl and decontamination paper, which have been used in radioactive handling systems such as nuclear power plants. Such radioactive waste (W) is preferably stacked about 3/4 inside the collection member (20). This is to allow the collection member 20 to be inflated by the air therein before compression. The compression process of the collecting member 20 will be described later in more detail together with the technical configuration of the pressing unit 30 and the vacuum unit 40. For reference, the collecting member 20 shown in Figure 1 is in a compressed state.

As shown in FIG. 4, the collecting member 20 has a predetermined volume by having a flat bottom surface 21 and a side surface 22 extending from an edge of the bottom surface 21. That is, the collection member 20 is not provided with a separate upper surface facing the bottom surface 21. The inlet 23 is opened at the top of the side 22 of the collecting member 20 to be in contact with each other, and the inlet 23 is opened and closed such as a zipper 24. It is selectively opened and closed by means.

On the other hand, in the present embodiment, but the bottom surface 21 of the collecting member 20 is illustrated as a rectangle, but is not necessarily limited thereto. That is, a modification such as the bottom surface 21 of the collection member 20 is formed in a circular shape is possible. In addition, it is a matter of course that the shape of the collecting member 20 may be formed in a hexahedron or cylindrical shape is the upper and lower surfaces are all flat.

Here, the collecting member 20 is deformed into a cylindrical shape of the upper and lower surfaces corresponding to the shape of the compressor body 10 is pressed by the pressing unit 30 to be described later. Therefore, in the present embodiment, the collection member 20 is exemplified as a plastic bag for vacuum, which is easily and economically deformed by the pressing force. For reference, at present, since the bottom surface 21 is a circular cylindrical vinyl pack is not produced in the present invention, in the present invention, the commercially available bottom surface 21 is a rectangular example of the collecting member 20. It was.

The pressing unit 30 selectively pressurizes the collecting member 20 mounted on the compressor body 10 to compress the radioactive waste W collected in the collecting member 20. This pressing portion 30 is provided with a pressing plate 31 and the movable portion 35.

The pressurizing plate 31 pressurizes the collecting member 20, and ascends along the inner surface of the compressor body 10 at an upper portion of the collecting member 20, as shown in FIG. 2. This press plate 31 is illustrated as a circular plate corresponding to the cylindrical compressor body 10, as shown in FIG.

On the other hand, the shaft pillar 32 of the pressing plate 31 is provided at the approximately center of the pressing plate 31. The outer circumferential surface of the shaft column 32 is wrapped by the hollow shaft holder 34. In addition, the shaft column 32 is connected to the balance weight 33 for blocking the pressing plate 31 is lowered by its own weight.

The movable part 35 raises / lowers the pressing plate 31. That is, the movable part 35 presses the collection member 20 by lowering the pressure plate 31, and releases the pressing force of the collection member 20 by lifting the pressure plate 31. This movable part 35 includes a handle 36, a pinion 37 and a rack gear 38.

The handle 36 adjusts the lifting direction and the pressing force of the pressing plate 31. 1 and 3, the pinion 37 is connected by the handle 36 and the connecting member 39, in conjunction with the movement of the handle (36). That is, the handle 36 and the pinion 37 are coaxially connected to each other. The rack gear 38 meshes with the pinion 37 and is installed in the shaft pillar 32 of the pressure plate 31.

By the structure of the movable part 35 as described above, when the handle 36 is operated, the pinion 37 is rotated in association with the handle 36, thereby raising and lowering the rack gear 38 provided in the shaft pillar 32. More specifically, the pinion 37 is rotated while being engaged with the rack gear 38 by the rotational force of the handle 36, but since its installation position is fixed, the shaft pillar of the non-fixed press body 31 ( The rack gear 38 provided in 32 is lifted or lowered by the rotation of the pinion 37. That is, the rotational force of the handle 36 is converted in a linear direction through the pinion 37 and the rack gear 38, so that the pressure plate 31 connected to the shaft column 32 on which the rack gear 38 is formed. ) Is raised and lowered.

The vacuum unit 40 vacuums the inside of the collection member 20. As shown in FIG. 3, the vacuum unit 40 includes a suction fan 41, a suction hose 43, and a flow control means 45.

The suction fan 41 generates a vacuum force. Here, one side of the suction fan 41 is provided with a filter member 42 for filtering the suction air sucked from the collecting member 20. In this embodiment, the filter member 42 is illustrated as a HEPA filter which is a high performance air filter, but is not necessarily limited thereto. By the filter member 42, the air sucked from the collection member 20 can be filtered and discharged to the outside, thereby preventing contamination by air sucked and discharged from the collection member 20. Will be.

For reference, although the suction fan 41 is illustrated as a suction force generating means for vacuuming the collection member 20 in the present embodiment, the present invention is not necessarily limited thereto. That is, it is obvious that any one of various suction force generating means such as a vacuum pump for sucking air of the collecting member 20 may be employed.

The suction hose 43 communicates the collection member 20 with the suction fan. Here, the suction hose 43 is connected to the collection member 20 is compressed by the pressure plate 31 is raised and lowered, so that the length of the suction member 20 when the collection member 20 is compressed. Therefore, a stretchable and stretchable part 47 is provided in a predetermined region of the suction hose 43. In the present invention, it is illustrated that the expansion and contraction portion 47 is provided in an area connected to the collection member 20 inside the compressor body 10.

In order to communicate between the suction hose 43 and the collecting member 20, a communication port 25 is formed on the upper surface 21 of the collecting member 20. In addition, the communication port 25 of the collecting member 20 is provided with a closing valve 26 for selectively sealing the inside of the collecting member 20.

Therefore, the communication port 25 of the collecting member 20 can be selectively opened only when the suction hose 43 and the collecting member 20 communicate with each other by the closing valve 26. For reference, a connector 44 is installed at one end of the suction hose 43 that is connected to the communication port 25 of the collection member 20, and the connection between the collection member 20 and the suction hose 43 is performed. Promote In addition, one side of the suction hose 43 is provided with a vacuum pressure gauge 46 for displaying the degree of suction force inside the collection member.

The flow rate control means 45 adjusts the flow rate of the suction air by the suction hose 43. In the present invention, the flow control means 45 is illustrated as a flow control valve installed in the suction hose 43.

On the other hand, in the present embodiment, but the flow control means 45 is a flow control valve for controlling the amount of air flowing into the suction fan 41 side along the suction hose 43, the suction fan 41 Naturally, the modified example of controlling the flow rate of the intake air at the rotational speed of) is also possible.

In addition, according to the present invention, as shown in FIG. 5, the pressing plate 31 of the pressing unit 30 pressurizes the collecting member 20 primarily to correspond to the compression space S. After being inflated to be in close contact with the inner surface of the vacuum, the vacuum unit 40 vacuums the inside of the collecting member 20. In this case, the compression shape of the collection member 20 can be guided by the compressor body 10, so that the collection member 20 can be pressed in a predetermined shape. That is, the role of the existing mold can be implemented as the inner surface of the compressor body 10 in which the collecting member 20 is in close contact. Therefore, the shape in which the collecting member 20 is compressed is guided by the compressor body 10 to be uniformly formed, and the radioactive waste W that is compressed by the vacuum force, i.e., contracted by the vacuum force, has a circular shape only by releasing the vacuum force. It can be restored closely.

The compression method of the radioactive waste compressor 1 according to the present invention having the above configuration will be described with reference to FIGS. 1 to 6.

First, as shown in FIG. 4, the inlet 23 of the collection member 20 is opened with a zipper 24 to collect the radioactive waste W into the collection member 20. Thereafter, the collection member 20 in which the predetermined amount of the radioactive waste W is collected is in the state in which the inlet 23 is closed by the zipper 24, as shown in FIGS. 1 and 3. By the compression space (S) is mounted to the open compressor body (10). When the collecting member 20 in which the radioactive waste W is collected is mounted on the compressor body 10 as shown in FIG. 2, the closing valve 26 provided in the communication port 25 of the collecting member 20 is installed. ) And the connector 44 of the suction hose 43 are connected to each other, and then the open compression space S of the compressor body 10 is closed by the door 11. At this time, the door 11 is fixed to the compressor body 10 by the latch member 12.

Thereafter, the collecting member 20 is primarily pressed against the inner surface of the compressor body 10 so as to correspond to the shape of the compression space S. The primary pressing step will be described in more detail. First, the operator rotates the pinion 37 which is coaxially connected by rotating the handle 36 in a direction in which the pressing plate 31 can be lowered. Then, the rack gear 38 engaged with the rotated pinion 37 is lowered by the rotational force of the pinion 37. Therefore, as shown in FIG. 5, the shaft column 32 on which the rack gear 38 is installed is lowered in association with the rotation of the pinion 37, whereby the pressing plate 31 is lowered to collect the member ( 20) is first pressurized. Here, the descending speed of the pressing plate 31 is insufficient so that the collection member 20 is not damaged.

Thereafter, as shown in FIG. 6, the air inside the collection member 20 is sucked by the vacuum unit 40. At the same time, the pressing plate 31 is lowered while maintaining a predetermined force to pressurize the collecting member 20 to compress the collecting member 20. At this time, the secondary pressing force, that is, the lowering speed of the pressing plate 31 maintains the shape of the collecting member 21 in close contact with the inner surface of the compressor body 10, similarly to the primary pressing speed. It is a speed in the range that can be guided to maintain the shape corresponding to (S), which is, if the lowering speed of the pressing plate 31 is too fast, the internal air of the collecting member 20 is not sucked and collected This may cause breakage of the member 20, and when the lowering speed is too slow, the collecting member 20 may be contracted in multiple directions due to the too fast vacuum speed compared to the lowering speed.

 Here, the vacuum unit 40 sucks air in the collection member 20 through a suction hose 43 connecting the collection member 20 and the suction fan 41 to each other. At this time, the suction force through the suction hose 43 can be controlled by the flow control means 45, the operator through the observation window 13 provided on the side of the compressor body 10 the collection member 20 is You can also observe the state of compression.

On the other hand, the suction air in the collecting member 20 sucked through the suction hose 43 is filtered by the filter member 42 before being finally discharged to the outside through the suction fan 41, to the radioactive material Recontamination by the air is prevented.

The water rejection material 20 compressed along the inner surface of the compressor body 10 by the secondary pressing force and the vacuum force is pressed once more by the third pressing force of the pressing plate 31, and thus, inside the collecting member 20. Also drain any residual air. At this time, the third pressing force of the pressing plate 31 is greater than the second pressing force, it is possible to compress the hard radioactive waste (W) that could not be compressed, such as a desalted paper wet or dried This is preferred.

As described above, although described with reference to the preferred embodiment of the present invention, those skilled in the art various modifications and variations of the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

1 is a perspective view schematically showing a radioactive waste compressor according to the present invention;

2 is a cross-sectional view of main parts of the radioactive waste compressor shown in FIG. 1;

3 is a plan view of FIG.

4 is a perspective view schematically showing the collection member shown in FIGS. 1 and 2;

5 and 6 are views for sequentially explaining the process of compressing the collecting member.

Description of the Related Art [0002]

1: radioactive waste compressor 10: compressor body

20: collecting member 30: pressurizing portion

40: vacuum part

Claims (13)

A compressor body having a compression space; A collecting member selectively mounted in the compression space with radioactive waste loaded therein; A pressing unit for selectively pressing and compressing the collecting member mounted on the compressor body; And A vacuum unit for vacuuming the inside of the collection member, including suction means for communicating with the collection member and generating a suction force, and a flow control means for adjusting a flow rate of the suction air generated by the suction means; Including; After the collecting member is in close contact with the inner surface of the compressor body corresponding to the compression space and its shape is the same as the internal shape of the compressor body, the pressing member is first pressurized and inflated by internal air, Combination radioactive waste compressor, characterized in that compressed by studying. The method of claim 1, The pressing unit, A pressing plate for pressing the collecting member by lifting / lowering along an inner surface of the compressor body forming the compression space; And A movable part for lifting / lowering the pressure plate; Complex radioactive waste compressor comprising a. The method of claim 2, The movable part, A handle for adjusting a lifting direction and a pressing force of the pressing plate; A pinion interlocked with the handle; And A rack gear engaged with the pinion and driven, the rack gear being installed on the shaft pillar provided on the pressing plate; Complex radioactive waste compressor comprising a. The method of claim 2, And the movable portion comprises a hydraulic / pneumatic system connected with the pressurizing plate. The method of claim 2, The pressing unit, And a counterweight connected to the pressure plate to prevent the pressure plate from being lowered by its own weight. The method of claim 1, And said vacuum part comprises a suction hose for communicating said collection member and said suction means with each other. The method of claim 1, Combination radioactive waste compressor, characterized in that the filter member for filtering the air sucked from the collecting member on one side of the suction means. The method of claim 6, The suction means includes a suction fan, The flow control means includes a flow control valve installed in the suction hose to control the flow rate, or a combined radioactive waste compressor, characterized in that for controlling the flow rate through the rotation speed control of the suction fan. The method of claim 1, The compressor body is a hybrid radioactive waste compressor, characterized in that it has a door that half the compression space. The method of claim 1, Compressor body is a combined radioactive waste compressor, characterized in that formed with lead for shielding of radioactivity. Mounting a collecting member in which radioactive waste is collected in a compression space provided inside the compressor body; Pressurizing the collecting member by a pressing plate descending along the inner surface of the compressor body such that the collecting member is inflated by internal air to closely contact the inner surface of the compressor body to have a shape corresponding to the compression space; ; And Compressing the collection member by pressurizing the collection member with the pressurizing plate while vacuuming the inside of the collection member; Including; Compressing the collecting member by the second pressing the collecting member to compress the collecting member by the second pressing force and the vacuum force, and then to the pressing plate by the pressing plate to the third pressing force greater than the second pressing force Compressing the combined radioactive waste further comprising the step of pressing to remove residual air inside the collecting member by pressing. The method of claim 11, The pressurizing plate is combined with the rack gear is raised and lowered in engagement with the pinion is coaxially connected to the handle rotated by the operator, the composite radioactive waste compression method, characterized in that the lifting. delete

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