KR20080087360A - Radioactive waste ion exchanger resins dehydration apparatus - Google Patents

Abstract

A radioactive waste ion exchange resin dehydration apparatus is provided to offer a safe work environment to a user by connecting a storage unit and a dehydration unit through a transfer line to prevent exposure of radioactive waste ion exchange resin. A radioactive waste ion exchange resin dehydration apparatus includes a porous vessel(210), an intermediate vessel(220), and a shielding vessel(230). The porous vessel receives radioactive waste ion exchange resin and has pores on a bottom. The intermediate vessel receives the porous vessel to protect the porous vessel. The shielding vessel receives the intermediate vessel and shields radiation emitted from the radioactive waste ion exchange resin. The bottom of the porous vessel is made of stainless steel.

Description

Radioactive Waste Ion Exchange Resin Dehydration System {RADIOACTIVE WASTE ION EXCHANGER RESINS DEHYDRATION APPARATUS}

1 is a schematic diagram of a radioactive waste ion exchange resin dehydration apparatus of the present invention.

Figure 2 is a side cross-sectional view showing a dehydration unit.

Figure 3 is a side cross-sectional view showing a porous container.

4 is a plan view showing the bottom of the porous container.

Figure 5 is a side cross-sectional view showing a scene in which the radioactive waste ion exchange resin is supported by the transfer cart.

Figure 5 is a side cross-sectional view showing a shielding drum for storing the porous container.

Figure 6 is a side cross-sectional view showing a shielding container containing a shielding drum.

<Explanation of symbols for the main parts of the drawings>

1: Radioactive waste ion exchange resin dehydration device

100: storage unit 200: dehydration unit

210: porous unit 212: opening

214: Bottom 215: Hall

216 ： dry cover 217 ： vent hole

218: Storage cover 220: Intermediate container

230: shield container 240: dry air supply unit

242 ： Dry air supply line 300 ： Transport unit

310: first transfer line 312: pump

314: grinder 320: second transfer line

342: first valve 344: second valve

400: transfer cart 500: shielding drum

600: shielding container

The present invention relates to a radioactive waste ion exchange resin dehydration apparatus for treating a radioactive waste ion exchange resin, and more particularly, to a radioactive waste ion exchange resin dehydration apparatus capable of safely dehydrating and drying the radioactive waste ion exchange resin and storing it in a store. It is about.

Waste ion exchange resins used to purify stored water in spent fuel storage tanks or to remove radionuclides in low-level waste liquids are ground to 100 mesh and mixed with concentrates for asphalt solidification. At the time of asphalt solidification of radioactive liquid waste, the temperature of the solidified asphalt solid is about 160 to 180 ° C.

However, since the waste ion exchange resin decomposes when it exceeds 110 ° C and generates H ₂ O and CO ₂ gas, decomposition gas is generated in the process of solidifying with asphalt at a temperature of 160 to 180 ° C. Bubbles are generated in the solid. By the way, the generated bubbles increase the volume of the solids in the apparatus to suppress the flow of the solids, thereby clogging the apparatus, making it difficult to solidify. Because of this, the waste ion exchange resin is treated by reducing the processing speed by 1/3 or more than the normal speed when asphalt solidification treatment. It is causing a lot of difficulties in processing.

In addition, the waste ion exchange resin has a swelling characteristic that increases in volume upon contact with water, so that when the solidified body of the radioactive waste is placed in contact with water, the solidified body swells, deteriorating the mechanical stability of the solidified substance and the rate of leaching of the radionuclide. There is an increasing disadvantage. Therefore, the treatment is usually performed with a small amount of resin, and the volume of waste solids increases accordingly.

Because of these difficulties, new methods of treating waste ion exchange resins have to be sought instead of solidifying them.

One object of the present invention for solving the above problems is to provide a radioactive waste ion exchange resin dehydration apparatus that can increase the treatment efficiency by increasing the amount of radioactive waste ion exchange resin processing.

It is another object of the present invention to provide a radioactive waste ion exchange resin dehydration apparatus that can reduce unnecessary work by continuing to work without equipment failure in the radioactive waste ion exchange resin treatment process.

Another object of the present invention is to provide a radioactive waste ion exchange resin that can be easily transported and stored in the storage.

In order to achieve the object of the present invention as described above, the radioactive waste ion exchange resin dehydration apparatus of the present invention includes a porous container, an intermediate container, and a shielding container.

The porous container provides a space for storing the radioactive waste ion exchange resin therein, the bottom portion may be formed of a porous network. The intermediate container may accommodate the porous container therein, and an inner surface thereof may be spaced apart from the outer surface of the porous container at a predetermined interval. In addition, the shielding container may accommodate the intermediate container therein to shield radiation from the radioactive waste ion exchange resin.

The porous container, the intermediate container and the shielding container of the present invention may be formed in a cylindrical shape, but the shape is not limited.

The porous container is formed by opening the top, the cover may be coupled to the open top. The cover may be made of a drying cover and a storage cover, respectively, and the drying cover is a cover formed with a vent hole penetrated on the cover surface, and the air when the radioactive waste ion exchange resin stored in the porous container is dried upon The lamp can be discharged to the outside. The storage cover is a cover provided with a handle on an upper surface of the storage cover, and may be used when the porous cover is sealed and stored. The bottom portion of the porous container may be formed of a stainless steel material, but the material is not limited thereto.

The porous container has a dry air supply line capable of supplying dried air is coupled to one side. The radioactive waste ion exchange resin stored in the porous container may be dried using the dried air supplied through the dry air supply line. In this case, the dried air or the like may be discharged to the outside through the ventilation holes formed in the drying cover.

A dry air control valve is formed on the dry air supply line to control the flow of the dried air.

In addition, the porous container may be coupled to one side of the waste liquid discharge line for discharging the waste liquid coming out of the radioactive waste ion exchange resin dehydrated. A waste liquid control valve is also formed on the waste liquid discharge line to control the flow of the waste liquid.

On the other hand, the radioactive waste ion exchange resin dehydration device may further comprise a transfer cart. The transfer cart may be safely transported by supporting the radioactive waste ion exchange resin dehydration device.

In addition, the radioactive waste ion exchange resin dehydration apparatus of the present invention is a storage unit for storing a radioactive waste ion exchange resin, a dehydration unit for receiving and dehydrating the radioactive waste ion exchange resin and the transfer unit connecting the storage unit and the dewatering unit It includes a unit.

The transfer unit includes a first transfer line for circulating the storage unit in a closed structure, a second transfer line for connecting the first transfer line and the dehydration unit to transfer the radioactive waste ion exchange resin, and the dewatering unit and the And a third transfer line connecting the storage unit to transfer the waste liquid dewatered from the radioactive waste ion exchange resin.

The dewatering unit has an inner space with an open upper side, and a plurality of holes are formed in the bottom portion, and a porous container for storing the radioactive waste ion exchange resin in the inner space, and the porous container And a shielding container for storing the intermediate container and the intermediate container for protection, and shielding the radiation from the radioactive waste ion exchange resin.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments.

1 is a schematic diagram of a radioactive waste ion exchange resin dehydration apparatus of the present invention.

As shown therein, the radioactive waste ion exchange resin dehydration apparatus 1 of the present invention includes a storage unit 100, a dehydration unit 200, and a transfer unit 300.

The storage unit 100 may accommodate the radioactive waste ion exchange resin in the inner space. The dewatering unit 200 may receive the radioactive waste ion exchange resin stored in the storage unit 100 to dehydrate the radioactive waste ion exchange resin. Then, the transfer unit 300 is connected to the storage unit 100 and the dehydration unit 200 to transfer the radioactive waste ion exchange resin, or the radioactive waste ion exchange resin from the dehydration unit 200 Waste water generated by dehydration may be transferred to the storage unit 100.

The transfer unit 300 includes a first transfer line 310, a second transfer line 320 and a third transfer line 330. Both ends of the first transfer line 310 are coupled to the storage unit 100 to form a closed structure. That is, one end side of the first transfer line 310 is coupled to the storage unit 100, and the other end side of the first transfer line 310 is coupled to the storage unit 100.

Here, the pump 312 may be installed on the first transfer line 310. The pump 312 may pressurize the radioactive waste ion exchange resin transferred from the transfer unit 300 to continuously transfer the waste ion exchange resin on the transfer unit 300. In addition, a grinder 314 may be installed on the first transfer line 310. The grinder 314 may finely grind the radioactive waste ion exchange resin transferred through the first transfer line 310 to increase fluidity of the radioactive waste ion exchange resin.

In addition, one side of the second transfer line 320 is formed to extend from the first transfer line 310, and the other side thereof is connected to the dehydration unit 200 to be transferred through the first transfer line 310. The radioactive waste ion exchange resin may be transferred to the dehydration unit 200.

The third transfer line 330 connects the dehydration unit 200 and the storage unit 100 to the wastewater discharged while the radioactive waste ion exchange resin stored in the dehydration unit 200 is dehydrated. It can be transferred to the storage unit 100.

The first valve 342 and the second valve 344 are formed on the second transfer line 320 and the third transfer line 330, respectively, to control the flow of the radioactive waste ion exchange resin and wastewater. . The valve may be a check valve or the like, but is not limited thereto.

On the other hand, the radioactive waste ion exchange resin dehydration apparatus 1 may further include a dry air supply unit 240. One side of the dry air supply unit 240 is coupled to a dry air supply line 242 that can transfer the dried air, one end thereof is coupled to the dehydration unit 200. As a result, the dried air is supplied from the dry air supply unit 240 to the inner space of the dehydration unit 200 in which the radioactive waste ion exchange resin is stored, thereby drying the dehydrated radioactive waste ion exchange resin. A third valve 244 is formed on the dry air supply line 242 to control the flow of the dried air.

In this case, the first valve 342, the second valve 344 and the third valve 244 can be properly opened and closed to proceed with a series of processes to dehydrate and dry the radioactive waste ion exchange resin. have.

Figure 2 is a side cross-sectional view showing a dehydration unit, Figure 3 is a side cross-sectional view showing a porous container, Figure 4 is a plan view showing the bottom portion of the porous container.

 As shown in the drawing, the dehydration unit 200 includes a porous container 210, an intermediate container 220, and a shielding container 230. Dehydration unit 200 of the present invention is formed in a cylindrical shape, but is not limited thereto.

The porous container 210 may accommodate the radioactive waste ion exchange resin in the inner space. A plurality of holes 215 are formed in the bottom portion 214 of the porous container 210. Through the hole 215, the wastewater dewatered from the radioactive waste ion exchange resin may be discharged to the outside. A third transfer line 330 is formed at the lower side of the porous container 210 to discharge the waste water, and a second valve 344 is formed on the third transfer line 330 to control the flow of the waste water. Can be.

In this embodiment, the diameter of the hole 215 is 80 mesh, the size of the inner space of the porous container 210 is 60L, but the diameter and size are not limited.

On the other hand, the lower side of the porous container 210 to which the third transfer line 330 is coupled is a dry air supply line 340 that can multiply the dried air. In addition, a third valve 244 is formed on the dry air supply line 340 to control the flow of the dry air.

On the other hand, the upper portion of the porous container 210 is open, the drying cover 216 is coupled to shield the upper portion 212 of the open porous container 210. The drying cover 216 is formed with a vent 217, through the vent 217 is supplied to dry the dehydrated waste ion exchange resin stored in the interior space of the porous container 210 is dried Air can be released to the outside.

The porous container 210 is preferably made of a reinforcing material having chemical resistance, acid resistance and corrosion resistance, and the shape of the porous container 210 may be formed in a cylindrical shape, but is not limited thereto.

The intermediate container 220 may be housed and protected by the porous container 210. The inner surface of the intermediate container 220 is formed spaced apart from the outer surface of the porous container 210 by a predetermined distance.

The intermediate container 220 may mitigate the amount of impact delivered to the porous container 210 when the dehydration unit 200 is impacted from the outside, and in addition, when the porous container 210 is damaged The radioactive waste ion exchange resin housed therein serves to prevent exposure to the outside. As the material of the intermediate container 220, preferably, stainless steel (SUS) or the like may be used, but is not limited thereto.

In this embodiment, the internal capacity of the intermediate container 220 is formed to be 140L, but the size is not limited.

The shielding container 230 may accommodate the intermediate container 220 therein. The shielding container 230 may shield radiation that may be emitted from the radioactive waste ion exchange resin stored in the porous container 210. As the material of the shielding container 230, it is preferable to use a material having a high radiation shielding rate. For example, a wall may be formed on the inner wall or the outer wall of the shielding container 230 by additionally using lead having excellent radiation shielding rate for radiation shielding.

The upper portion of the shield container 230 is formed to be open, the shield cover 232 may be coupled to seal the inner storage space.

In the present embodiment, the shielding container 230 is manufactured to have an inner diameter of 590 mm, an outer diameter of 1,000 mm, and a lead shield thickness of 20 mm, but the size thereof is not limited.

Figure 5 is a side cross-sectional view showing a scene in which the radioactive waste ion exchange resin is supported by the transfer cart.

As shown in this, the radioactive waste ion exchange resin dehydration apparatus 1 of the present invention may further include a transfer cart 400. The transfer cart 400 has a support 410 having a wide support surface so that the bottom surface of the radioactive waste ion exchange resin dehydration apparatus 1 may be raised to stably support the radioactive waste ion exchange resin dehydration apparatus 1. ) And a handle portion 420 connected to the support portion 410 to be pulled or pushed by an operator. A plurality of wheels may be provided on the bottom surface of the support part 410 to easily move the radioactive waste ion exchange resin dehydration apparatus 1.

Figure 6 is a side cross-sectional view showing a shielding drum for storing the porous container. As shown in the drawing, when all of the radioactive waste ion exchange resins stored in the inner space of the porous container 210 are dehydrated and dried, the porous container 210 may be accommodated in the shielding drum 500. In this case, the porous container 210 may use a storage cover 218 with a handle instead of a drying cover (see FIG. 2) in which a vent 217 is formed to shield the open top.

The porous container 210 is accommodated in the drum receiving portion 510 of the shielding drum 500, and the drum cover 520 is coupled to an open upper side of the drum receiving portion 510. In order to prevent the drum cover 520 from being separated from the shielding drum 500, a drum fastening part 530 is formed in the drum cover 520. In this embodiment, a screw is used, but is not limited thereto. Do not.

Figure 7 is a side cross-sectional view showing a shielding container containing a shielding drum. As shown in the drawing, the shielding container 600 may store the shielding drum 500 in which the porous container 210 is stored. To this end, the shielding container 600 is formed with a container receiving portion 610 of a size capable of safely storing the shielding drum 500 therein. The upper side of the container accommodating part 610 is formed to be open, and after receiving the shielding drum 500, the container cover 620 may be coupled to block the outside. At this time, the container cover 620 is formed in the container cover 620 to increase the coupling force, in this embodiment, a screw may be used as the container fastening portion 630, but is not limited thereto.

As such, after storing the radioactive waste ion exchange resin in a dehydration unit formed of a porous network, it is dehydrated and dried to manufacture a large amount of radioactive waste ion exchange resin in an easy-to-store state. It is useful for safe dehydration and storage of radioactive waste ion exchange resins from research institutes, facilities and radioisotope facilities without the risk of radioactive exposure or environmental pollution.

As described above, according to the present invention, the radioactive waste ion exchange resin is dehydrated and dried to safely store the radioactive waste ion exchange resin without radioactive exposure or environmental pollution.

In addition, the transfer line is connected to the dehydration unit from the storage unit in which the radioactive waste ion exchange resin is stored, thereby preventing the radioactive waste ion exchange resin from being exposed to the outside, thereby providing a safe working environment for the user.

In addition, it can be dried together with dehydration, thereby reducing the time for converting the radioactive waste ion exchange resin into a storage state.

Claims (21)

A porous container accommodating a radioactive waste ion exchange resin and having a pore formed at its bottom; An intermediate container for storing the porous container to protect the porous container; And A shielding container accommodating the intermediate container and shielding radiation from the radioactive waste ion exchange resin; Dehydration apparatus of the radioactive waste ion exchange resin comprising a. The method of claim 1, The bottom portion of the porous container dehydration apparatus of the radioactive waste ion exchange resin, characterized in that formed of stainless steel. The method of claim 1, The upper portion of the porous container is open, the dewatering device of the radioactive waste ion exchange resin, characterized in that the cover is coupled to the open upper portion. The method of claim 3, Dehydration apparatus of the radioactive waste ion exchange resin, characterized in that the vent is formed in the cover. The method of claim 1, The porous container dehydration apparatus of the radioactive waste ion exchange resin, characterized in that the dry air supply line for supplying the dried air is coupled. The method of claim 5, Dehydration apparatus of the radioactive waste ion exchange resin, characterized in that the dry air control valve is formed on the dry air supply line. The method of claim 1, The porous container dehydration apparatus of the radioactive waste ion exchange resin, characterized in that the waste liquid discharge line for discharging the waste liquid dewatered from the radioactive waste ion exchange resin is coupled. The method of claim 7, wherein The dewatering device of the radioactive waste ion exchange resin, characterized in that the waste liquid control valve is formed on the waste liquid discharge line. The method of claim 1, And a transport cart for transporting the radioactive waste ion exchange resin dehydration apparatus, wherein the transport cart carries and supports the radioactive waste ion exchange resin dehydration apparatus. A storage unit storing a radioactive waste ion exchange resin; A dewatering unit to receive and dehydrate the radioactive waste ion exchange resin; And A transfer unit connecting the storage unit and the dehydration unit; Radioactive waste ion exchange resin dehydration device comprising a. The method of claim 10, The transfer unit A first transfer line circulating the storage unit in a closed structure; A second transfer line connecting the first transfer line and the dehydration unit to transfer the radioactive waste ion exchange resin; And A third transfer line connecting the dehydration unit and the storage unit to transfer the waste liquid dewatered from the radioactive waste ion exchange resin; Radioactive waste ion exchange resin dehydration apparatus comprising a. The method of claim 11, Radioactive waste ion exchange resin dewatering device, characterized in that the valve is formed on the transfer unit. The method of claim 11, A radioactive waste ion exchange resin dewatering device, characterized in that a pump is formed on the first transfer line. The method of claim 11, Grinder (Grinder) is formed on the first transfer line, the radioactive waste ion exchange resin dehydration apparatus, characterized in that to crush the radioactive waste ion exchange resin. The method of claim 10, The dehydration unit is A porous container having an upper space open at an upper side thereof, and having a plurality of holes formed at a bottom thereof, and storing the radioactive waste ion exchange resin in the inner space; An intermediate container for storing the porous container to protect the porous container; And A shielding container accommodating the intermediate container and shielding radiation from the radioactive waste ion exchange resin; Radioactive waste ion exchange resin dehydration device comprising a. The method of claim 15, Radioactive waste ion exchange resin dewatering device further comprises a cover for shielding the upper side of the porous container. The method of claim 10, The dehydration unit is a radioactive waste ion exchange resin dewatering device, characterized in that the dry air supply line for transporting the dried air is coupled. The method of claim 10, The bottom portion of the porous container radioactive waste ion exchange resin dewatering device, characterized in that formed of stainless steel material. The method of claim 10, A radioactive waste ion exchange resin dewatering device, characterized in that further comprising a transfer cart for transporting the radioactive waste ion exchange resin dehydration device, wherein the radioactive waste ion exchange resin dehydration device is supported on an upper surface. The method of claim 10, And a shielding drum containing the porous container in which the dehydrated radioactive waste ion exchange resin is stored, wherein the shielding drum is formed of a concrete material. The method of claim 20, A radioactive waste ion exchange resin dewatering device further comprising a concrete shielding container for storing the shielded drum and transporting the shielded drum.

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