KR102491785B1 - Compactor for volume reduction of low-level radioactive waste - Google Patents

Abstract

The present invention relates to a compactor for volume reduction of low-level radioactive waste, which is to compress waste contained in a waste container. The compactor for volume reduction of low-level radioactive waste comprises: a body with a space formed therein, an opening formed on the front, and a door for opening and closing the opening; a pressure rod mounted on the upper outer side of the body and vertically inserted into the interior; a power source for raising and lowering the pressure rod; a compression part including a compression plate formed at an end of the pressure rod and inserted into the inside of the container, and a compression guide tube disposed on an outer periphery of the compression plate and supporting the exterior of the container; and a container moving part formed on the lower part of the body, and including an input ramp formed with a flat part on which the container is supported and an inclined part on which the container slides, rail grooves on both sides formed on both sides to communicate with the inclined part and the flat part of the input ramp, and a movable supporter coupled to the rail grooves on both sides and supporting the outer peripheral surface of the container. Therefore, the present invention can increase throughput.

Description

Low-level radioactive waste compression reduction processor {Compactor for volume reduction of low-level radioactive waste}

The present invention relates to a compression reduction processor for low-level radioactive waste, and more particularly, to a compression reduction volume processor for achieving the purpose of safe radioactive waste treatment by putting radioactive waste into a container and sealing it.

In general, radioactive waste is waste generated from nuclear facilities and workshops or laboratories that handle radioactive materials, and is classified into intermediate/low-level radioactive waste and high-level radioactive waste depending on the degree of contamination with radioactive materials.

The definition of radioactive waste is radioactive material or material contaminated by it, which is defined in related laws and regulations as material subject to disposal. In nuclear power plants, contaminated work products are generated during maintenance, in hospitals, contaminated items during treatment, and in industries, they are generated during non-destructive testing.

On the other hand, high-level radioactive waste is a representative example of nuclear fuel remaining after generating electricity in a nuclear power plant.

In other words, radioactive waste is generated in all fields using nuclear power, such as schools, hospitals, research institutes, industries, and nuclear power generation.

On the other hand, low-level radioactive waste such as protective clothing, gloves, goggles, and hoods worn by workers are placed in steel drums, compressed as much as possible, sealed with lids, and stored in a stack.

However, in the prior art, in compressing radioactive waste into a drum, there was a problem in that the maximum space utilization of the drum was degraded due to insufficient performance of compressing by maximizing the amount of input.

Republic of Korea Patent Registration No. 10-1554520 (Announced on September 21, 2015)

The present invention has been made to solve the problems of the prior art, and the throughput can be increased by putting radioactive waste into a container and compressing it, the compression level can be displayed to check the amount of compression, and the amount of compression can be confirmed by discharging fume. Its purpose is to provide a compression reduction processor for low-level radioactive waste that can prevent contamination and utilize the compression rate by utilizing the accumulated data according to the material.

An object of the present invention described above is to compress the waste contained in a container for holding the waste, a body having a space formed therein, an opening formed on the front side, and a door formed to open and close the opening; A pressing rod mounted on the outer side of the upper part of the main body and vertically inserted therein; a power source for elevating the pressure rod; A compression unit having a compression plate formed at an end of the pressure rod and inserted into the inside of the container, and a compression guide tube disposed on the outer periphery of the compression plate and supporting the outside of the container; and an input ramp formed on the lower part of the main body and formed with a flat plate part supporting the container and an inclined part for sliding the container, rail grooves on both sides formed on both sides so as to pass through the inclined part of the input ramp and the flat plate part, and the rail grooves on both sides. It can be achieved by a low-level radioactive waste compression reduction processor including a container moving unit coupled to and composed of a moving support supporting the outer circumferential surface of the container.

a guide rod mounted vertically on the compression plate and protruding upward from the main body; It is connected to the guide rod and operated together to lift and includes a height display unit for displaying the height of the compression plate.

The height display unit includes a bracket connected horizontally to an upper end of the guide rod, an indicator rod body connected vertically to the bracket and inserted into the inside through an upper portion of the main body, and a compression plate formed at the lower end of the indicator rod body and It is characterized in that it includes a display body formed at the same height.

The container moving unit is formed on the input ramp to detect that the moving support is in place, or is formed in the input lamp to detect that the container is in place. Characterized in that it includes a stopper coupled to the bottom of the container do.

The movable support unit connects movable pads respectively coupled to rail grooves on both sides of the input ramp, one end of the movable pads on both sides, and a slide plate on which one lower side of the container is seated, and the other ends of the movable pads on both sides, and is in close contact with the outer circumferential surface of the container. And characterized in that it comprises a band coupled to both ends to the rail grooves on both sides.

The compression guide tube is characterized in that it comprises an arc-shaped body in close contact with a part of the outer circumferential surface of the container, both wings hinged to both ends of the body to open and close, and fasteners for fixing both wings.

It is characterized in that the wings on both sides are formed with circumferential lengths covering the same angle or each with circumferential lengths covering different angles.

The wings on both sides are divided and characterized in that they are formed in two or three stages.

It is characterized in that a window is formed on one side or both sides of the wings on both sides.

It is characterized in that it includes an exhaust pipe formed to pass through the inner space of the main body to remove fumes, and a purifier connected to the exhaust pipe.

According to the present invention, there is an excellent effect of increasing the throughput by injecting radioactive waste into a container, but by attaching a compression guide tube to the container to compress a large amount of waste after inputting it.

In addition, it is possible to prevent contamination by discharging fume generated inside the main body, and to check the amount of compression by displaying the compression level of radioactive waste, and to improve work efficiency by utilizing data accumulated according to the material. There is an effect.

1 is a perspective view of a low-level radioactive waste compression reduction processor according to the present invention;
2 is a front view of a low-level radioactive waste compression reduction processor according to the present invention;
3 is a plan view of a low-level radioactive waste compression reduction processor according to the present invention;
Figure 4 is an enlarged view of the 'compression unit' of the low-level radioactive waste compression reduction processor according to the present invention;
5 is a view showing the 'container moving unit' of the low-level radioactive waste compression reduction processor according to the present invention;
Figure 6 is a side cross-sectional view showing the 'container moving unit' of the low-level radioactive waste compression reduction processor according to the present invention;
7 is a perspective view showing a 'compression guide tube' of the low-level radioactive waste compression reduction processor according to the present invention;
8 is an exemplary view showing the compression operation of the low-level radioactive waste compression reduction processor according to the present invention;
9 is a view showing various forms of 'compression guide tube' of the low-level radioactive waste compression reduction processor according to the present invention.

Hereinafter, a preferred embodiment will be described in detail based on the accompanying drawings.

The embodiments to be described below are intended to be described in detail so that those skilled in the art can easily practice the invention, thereby limiting the technical spirit and scope of the present invention. doesn't mean

In addition, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description, and terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. It can be, and it is revealed that the definitions of these terms should be made based on the contents throughout this specification.

Among the accompanying drawings, Figure 1 is a perspective view of a low-level radioactive waste compression and volume processor according to the present invention, Figure 2 is a front view of a low-level radioactive waste compression and volume processor according to the present invention, Figure 3 is a low-level radioactive waste according to the present invention A plan view of the compressed volume processor, Figure 4 is an enlarged view of the 'compression unit' of the low-level radioactive waste compression and volume processor according to the present invention, Figure 5 is a view showing the 'container moving unit' of the low-level radioactive waste compression and volume processor according to the present invention Figure 6 is a cross-sectional side view showing the 'container moving part' of the low-level radioactive waste compression reduction volume processor according to the present invention, Figure 7 is a perspective view showing the 'compression guide tube' of the low-level radioactive waste compression reduction volume processor according to the present invention, and FIG. is an exemplary view showing a compression operation of the low-level radioactive waste compression and volume processor according to the present invention, and FIG.

As shown in FIGS. 1 to 9, the low-level radioactive waste compression reduction processor according to the present invention compresses the waste (X) stored in the container (D) containing the waste, and the main body 100 , It is configured to include a power source 200, a compression unit 300 and a container moving unit 400.

A space is formed inside the main body 100, an opening is formed on the front surface, and a door 120 is formed to open and close the opening.

The door 120 may be formed in two upper and lower stages and may be opened and closed respectively. Therefore, additional waste may be introduced by allowing only the upper side door to be individually opened.

In addition, an exhaust pipe 140 formed to pass through the inner space of the main body 100 to remove fume, and a purifier (not shown) connected to the exhaust pipe 140 are formed.

Air pollution can be prevented by inhaling fumes that may be generated during compression, discharging them through the exhaust pipe 140 and then purifying them in a purifier.

Preferably, the purification device includes a filtering means for removing nuclides such as cesium (Cs), strontium (Sr) and iodine (I).

The power source 200 is mounted on the upper outer side of the main body 100 and has a pressing rod 220 vertically inserted into the inside to elevate the pressing rod 220 .

As the power source 200 according to an example, a hydraulic cylinder powered by hydraulic pressure or pneumatic pressure may be used, mounted vertically on the upper part of the main body 100, and the pressure rod 220 is inserted into the main body 100 connected vertically. Energy of the power source 200 is supplied from the power generating device 160, and a hydraulic unit may be used as an example of the power generating device 160.

The compression unit 300 is formed at the end of the pressure rod 220 and is disposed on the outer periphery of the compression plate 320 inserted into the container D, and the compression plate 320 to support the outside of the container. A guide tube 340 is provided.

The container D is a cylindrical drum, and after low-level radioactive waste is put into the container D, a lid D-2 is coupled to the top and sealed.

The compression guide tube 340 has an arc-shaped body 342 in close contact with a part of the outer circumferential surface of the container D, both ends of the body 342 are hinged to open and close both wings 344 and both wings ( and a fastener 346 for fixing 344.

Preferably, both wings 344 are formed in an arc shape having a circumferential length of 1/4 and arranged symmetrically. It is bonded to the outer surface to prevent the contents from overflowing during compression, and a greater amount of compression may be possible.

As shown in Figure 9,

Both wings 344 are formed with a circumferential length covering the same angle. As shown in (a), both wings 344 have a cover angle of 90°.

Alternatively, as in (b), one wing 344 has a circumferential length formed to have a cover angle of x ° (0 < x < 180), and the other wing 344 'has a cover angle of 180 ° - x ° A circumferential length can be formed. (b) of FIG. 9 is an example when the value of x is 120.

As shown in (c) and (d), the wings 344 on both sides may be formed in two stages by dividing the middle.

Alternatively, as in (e) and (f), the wings 344 on both sides may be formed in three stages by dividing the middle into three. Furthermore, it is possible to form more stages of wings as needed.

Alternatively, as in (g), one or a plurality of windows 348 may be formed on both side wings 344. Radioactive waste can be additionally injected through the window.

In addition, as in (h), some of the divided wings 344 can be opened and closed individually, so that additional input can be made while preventing pouring out by opening and introducing only some of them.

On the other hand, the container moving unit 400 is formed on the lower part of the main body 100 and includes a flat plate part 422 for supporting the container D and an input ramp 420 having a slope 424 for sliding the container D, Rail grooves 440 on both sides formed on both sides to pass through the inclined portion 424 and the flat plate portion 422 of the input ramp 420, coupled to the rail grooves 440 on both sides, and the lower outer circumferential surface of the container D It is configured to include a movable support 480 for supporting.

The container moving unit 400 moves the moving support 480 along the rail grooves 440 on both sides of the input ramp 420 to raise or lower the container D on the flat plate part 422 of the input ramp 420. can

The moving support 480 connects the moving pads 482 coupled to the rail grooves 440 on both sides of the input ramp 420 and one end of the moving pads 482 on both sides, and the lower one side of the container D is seated. It connects the slide plate 484 and the other ends of the moving pads 482 on both sides and is in close contact with the outer circumferential surface of the container D and includes a band 486 having both ends coupled to the rail grooves 440 on both sides.

Meanwhile, an electric power source 470 capable of moving the moving pad 482 of the moving support 480 forward and backward along the rail groove 440 may be further included inside the input ramp 420 .

Referring to FIG. 6, the electric power source 470 is connected to a motor 472, a main gear 474 coupled to the shaft of the motor 472, and a main gear 474 and a chain 475, so that the input lamp 420 ) It may include a driven gear 476 formed in and a guide slot 477 formed on the inside side of the input ramp 420 to move the driven gear 476.

Therefore, as the motor 472 is turned on by manipulating the remote controller, the chain 475 is rotated to move the driven gear 476 and the moving pad 482 forward or backward, thereby moving the moving support 480 forward and backward. movement may be possible.

Meanwhile, a sensing means 490 for detecting that the movable support 480 is properly positioned is formed in the flat plate part 422 or the rail groove 440 of the input lamp 420 .

The sensing means 490 may include a touch sensor or light sensor 491 and a notification member 492 made of a lamp or buzzer that is interlocked with the touch sensor or light sensor 491 to notify the operator that the position is in place. can

A sensing means is formed on the flat plate part 422 or the rail groove 440, detects whether the moving support 480 coupled to the lower end of the container D is in the correct position, and turns on the notification member when the correct position is detected. and inform the workers.

The normal position means that the center of the container D and the center of the compression plate 320 coincide.

In addition, a stopper (not shown) formed on an upper surface of the input lamp 420 and coupled to a lower portion of the container may be included to detect that the container is properly positioned.

In one embodiment, the stopper for preventing the container D from moving out of position is preferably semi-circular in correspondence with the container D being a cylindrical drum.

On the other hand, the guide rod 360 is mounted vertically on the compression plate 320 and protrudes upward from the main body 100. It may include a height display unit 350 for displaying.

Referring to FIGS. 2 and 4 , the height display unit 350 includes a bracket 352 horizontally connected to an upper end of a guide rod 360 and a bracket 352 vertically connected to the bracket 352 to form the main body 100. It includes an indicator rod body 354 inserted through the top and inserted into the inside, and an indicator 356 formed at the lower end of the indicator rod body 354 and formed at the same height as the compression plate 320.

Therefore, as the compression plate 320 descends, the height display unit 350 descends, so that the height of the compression plate 320 in the compression guide tube 340 can be checked from the outside of the main body 100 through the viewing window.

According to the regulations, only waste of the same material must be put into each container, so the compression rate of each material is accumulated as data in advance, and appropriate compression can be performed according to the material by using this.

The process of putting, compressing, and sealing radioactive waste into a container is as shown in FIG. 8 .

First, after coupling the compressed guide tube 340 with both wings open to the upper part of the container D, the waste X is introduced, and both wings are closed and then compressed.

Thereafter, secondary waste (X2) is further introduced and compressed.

Afterwards, the tertiary waste (X3) can be put in and compressed to contain as much as possible.

After inputting the tertiary waste (X3), close the lid (D-2) to seal it.

The above process is an example, and a fourth or higher input is also possible if necessary.

At this time, by using the height display unit 350 connected to the compression plate 320, the compression rate of the waste is calculated to determine the input amount after the second time, and the optimal amount can be input during the second and subsequent inputs. The compression rate according to the type of waste becomes data that can be utilized in the future operation of each waste.

Although described in relation to preferred embodiments, it will be readily recognized by those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, and all such changes and modifications fall within the scope of the appended claims. self-explanatory

D: vessel 100: body
120: door 140: exhaust pipe
200: power source 220: pressure rod
300: compression unit 320: compression plate
340: compression guide tube 342: body
344: wing 346: fastener
350: height display unit 360: guide rod
400: container moving unit 420: input lamp
440: rail home 480: moving support
482: moving pad 484: slide plate
486: band 470: electric power source
490: detection means 491: sensor
492: absence of notification

Claims (10)

By compressing the waste stored in the container containing the waste,
a main body having a space formed therein, an opening formed on a front surface, and a door opening and closing the opening;
a pressure rod mounted on the outer side of the upper part of the main body and vertically inserted therein;
a power source for elevating the pressure rod;
A compression unit having a compression plate formed at an end of the pressure rod and inserted into the container, and a compression guide tube disposed on an outer periphery of the compression plate and supporting the outside of the container; and
An input ramp formed on the lower part of the main body and formed with a flat plate part supporting the container and an inclined part for sliding the container, rail grooves on both sides formed on both sides so that the inclined part of the input ramp and the flat plate part pass through, and both sides of the input ramp. It includes a container moving part coupled to the rail groove and composed of a moving support supporting the outer circumferential surface of the container,
A guide rod mounted vertically to the compression plate and protruding upward from the main body;
A low-level radioactive waste compression reduction processor characterized in that it includes a height display unit connected to the guide rod and operated together to lift and display the height of the compression plate. delete According to claim 1,
The height display unit,
A bracket connected horizontally to the upper end of the guide rod;
An indicator rod body connected vertically to the bracket and inserted into the inside through the upper portion of the main body;
Low-level radioactive waste compression reduction processor, characterized in that it includes a display body formed at the lower end of the indicator rod body and formed at the same height as the compression plate. By compressing the waste stored in the container containing the waste,
a main body having a space formed therein, an opening formed on a front surface, and a door opening and closing the opening;
a pressure rod mounted on the outer side of the upper part of the main body and vertically inserted therein;
a power source for elevating the pressure rod;
A compression unit having a compression plate formed at an end of the pressure rod and inserted into the container, and a compression guide tube disposed on an outer periphery of the compression plate and supporting the outside of the container; and
An input ramp formed in the lower part of the main body and formed with a flat plate part supporting the container and an inclined part for sliding the container, rail grooves on both sides formed on both sides so that the inclined part of the input ramp and the flat plate part pass through, and the both sides It includes a container moving part coupled to the rail groove and composed of a moving support supporting the outer circumferential surface of the container,
The container moving part
Low-level radioactive waste, characterized in that it includes a sensing means formed on the input lamp to detect that the movable support is in place or a stopper formed on the input lamp and coupled to the lower portion of the container to detect that the container is in place. compression decompression processor. By compressing the waste stored in the container containing the waste,
a main body having a space formed therein, an opening formed on a front surface, and a door opening and closing the opening;
a pressure rod mounted on the outer side of the upper part of the main body and vertically inserted therein;
a power source for elevating the pressure rod;
A compression unit having a compression plate formed at an end of the pressure rod and inserted into the container, and a compression guide tube disposed on an outer periphery of the compression plate and supporting the outside of the container; and
An input ramp formed in the lower part of the main body and formed with a flat plate part supporting the container and an inclined part for sliding the container, rail grooves on both sides formed on both sides so that the inclined part of the input ramp and the flat plate part pass through, and the both sides It includes a container moving part coupled to the rail groove and composed of a moving support supporting the outer circumferential surface of the container,
The movable support,
A moving pad coupled to the rail grooves on both sides of the input ramp, a slide plate connecting one end of the both moving pads and seating one lower side of the container, and a slide plate connecting the other ends of the both moving pads to the outer circumferential surface of the container. Low-level radioactive waste compression reduction processor, characterized in that it comprises a band that is in close contact and both ends are coupled to the rail grooves on both sides. By compressing the waste stored in the container containing the waste,
a main body having a space formed therein, an opening formed on a front surface, and a door opening and closing the opening;
a pressure rod mounted on the outer side of the upper part of the main body and vertically inserted therein;
a power source for elevating the pressure rod;
A compression unit having a compression plate formed at an end of the pressure rod and inserted into the container, and a compression guide tube disposed on an outer periphery of the compression plate and supporting the outside of the container; and
An input ramp formed in the lower part of the main body and formed with a flat plate part supporting the container and an inclined part for sliding the container, rail grooves on both sides formed on both sides so that the inclined part of the input ramp and the flat plate part pass through, and the both sides It includes a container moving part coupled to the rail groove and composed of a moving support supporting the outer circumferential surface of the container,
The compression guide tube,
An arc-shaped body in close contact with a part of the outer circumferential surface of the container;
Low-level radioactive waste compression reduction processor, characterized in that it comprises both wings hinged to both ends of the body to open and close, and fasteners for fixing the wings on both sides. According to claim 6,
The low-level radioactive waste compression reduction processor, characterized in that the wings on both sides are formed with a circumferential length covering the same angle or each with a circumferential length covering different angles. According to claim 6,
The low-level radioactive waste compression reduction processor, characterized in that the wings on both sides are divided and formed in two or three stages. The method of any one of claims 6 to 8,
Low-level radioactive waste compression reduction processor, characterized in that windows are formed on one side or both sides of the wings on both sides. By compressing the waste stored in the container containing the waste,
a main body having a space formed therein, an opening formed on a front surface, and a door opening and closing the opening;
a pressure rod mounted on the outer side of the upper part of the main body and vertically inserted therein;
a power source for elevating the pressure rod;
A compression unit having a compression plate formed at an end of the pressure rod and inserted into the container, and a compression guide tube disposed on an outer periphery of the compression plate and supporting the outside of the container; and
An input ramp formed in the lower part of the main body and formed with a flat plate part supporting the container and an inclined part for sliding the container, rail grooves on both sides formed on both sides so that the inclined part of the input ramp and the flat plate part pass through, and the both sides It includes a container moving part coupled to the rail groove and composed of a moving support supporting the outer circumferential surface of the container,
an exhaust pipe formed to pass through the inner space of the main body to remove fumes;
Low-level radioactive waste compression reduction processor, characterized in that it comprises a purification device connected to the exhaust pipe.

Images