KR101177214B1 - Handling vessel for tritium - Google Patents

Abstract

The present invention relates to a tritium handling container capable of safely storing and transporting tritium produced in the tritium removal facility. The tritium handling container according to the present invention includes a storage container for storing tritium in the form of metal hydride, a transport container for accommodating the storage container, and a drum container for accommodating the transport container housed therein. In the tritium handling container configured, the transport container 3 for storing the storage container 2 is divided into an upper container part 31 and a lower container part 32, and a lower end of the upper container part 31 and Flange 31a, 32a is formed to correspond to the upper end of the lower container portion 32 to correspond to each other, and the upper and lower container portions 31 and 32 are coupled to be sealed through the metal ring 34. It features.

Description

Tritium handling container {Handling vessel for tritium}

The present invention relates to a tritium handling container capable of safely storing and transporting tritium generated in a nuclear power plant.

In general, tritium is generated from a tritium removal facility (TRF) in a nuclear power plant. Tritium is a radioactive substance that emits beta (β) rays as isotopes of hydrogen (H ₂ ). Such tritium is difficult to liquefy due to low boiling point and difficult to liquefy, and when present in oxide form, it is more dangerous than elemental form, and there is a risk of explosion in gaseous state and the possibility of radiation contamination in case of leakage. Care and care are needed.

In addition, tritium is a strategic material subject to cross-border import and export control, which requires a license for its handling, complies with domestic regulations and possesses technology that meets international standards.

In order to overcome such a problem, a method of combining tritium in the form of metal hydride using a hydrogen storage metal is used. The method using the hydrogen storage metal has the advantage of significantly increasing the storage capacity and safely storing, and thus, attention is focused on the development of hydrogen storage materials for hydrogen vehicles, and storage that can safely and efficiently store and move tritium. And transport containers are also being developed.

In general, the development of a handling container for storing and transporting radioactive materials while ensuring safety has been linked to the system to which the container is applied, and has been made to reflect the design requirements of the target system. In addition, the specification of the transport container classified by the amount of radioactivity is classified as a B (U) type transport container according to the Korean Atomic Energy Act No. 2008-69, and the technical standard of the type B transport container is applied.

In general, the handling container of tritium is largely composed of a storage container for storing tritium in the form of metal hydride, a transport container for transporting the storage container with a primary seal, and an external drum container. The tritium handling container of such a configuration includes zirconium cobalt (ZrCo) or depleted uranium (DU) which can be occluded in the form of metal hydride.

It contains metal media such as Depleted Uranium (DU). Here, the transport container is a sealed container in case the radioactive material leaks due to an unexpected problem from the storage container during the transport process. In addition, the external drum container serves to minimize the transfer of heat due to external physical shock or fire to the internal storage container. Therefore, the design and manufacturing technology of the transport container and the external drum container, which can safely protect the tritium storage container from falling, submerged and fire accidents that may occur during the transport of tritium, are important.

Conventional tritium handling containers have a structure in which a container is fixed between a storage container and a wall of a transport container by using a half-moon-type spring, or a buffer material is inserted, so that it is different from the valves that are weak parts of the storage container during external impact. The components could come in direct contact, which could lead to unstable storage.

In addition, conventional tritium handling containers, such as polyurethane foam applied to the space between the outer drum container and the transport container as a heat insulating and cushioning material, the buffering capacity is reduced at low temperatures, and the cushioning material made of a synthetic material such as polyethylene is a fire accident, There was a drawback that it generates a large amount of combustion gas which raises the pressure of the drum container and thereby increases the possibility of explosion or destruction.

The present invention has been made to solve the problems of the prior art as described above, it is an object of the present invention to minimize the external impact during storage and transportation of tritium and to provide a tritium handling container excellent in heat resistance and durability.

The present invention for achieving the above object, a storage container for storing tritium in the form of metal hydride, a transport container for accommodating the storage container, and a drum containing a storage container housed therein In the tritium handling container composed of a container, a transport container for storing the storage container is divided into an upper container portion and a lower container portion, the lower end of the upper container portion and the upper end of the lower container portion is formed with a flange to fasten them together , The upper and lower container portion is characterized in that the sealing is coupled via the metal ring.

In addition, mounting grooves having different inner diameters are additionally formed at the upper end of the lower container portion, O-rings are respectively installed in these mounting grooves, the inner 0-rings are made of metal, and the outer O-rings are elastic. Characterized in that each formed of a polymer material.

In addition, the inner diameter of the metal ring is smaller than the outer diameter of the storage container, the outer diameter of the metal ring is characterized in that formed in the size that can be pressed on the top of the flange of the container.

In addition, a space portion is formed at an upper end of the upper container portion according to the present invention, and the space portion is provided with a sampling valve for checking whether tritium is leaked from the storage container.

On the other hand, inside the drum container, a filler using balsa wood is cut and installed according to the outer shape of the transport container, characterized in that the outer peripheral surface of the filler is provided with a coating layer wrapped with a polyester film.

The tritium handling container of the present invention can sufficiently withstand high temperature and pressure, external shock and heat invasion during a drop accident and a fire accident, thereby ensuring sufficient safety during storage and transportation of tritium.

1 is a schematic cross-sectional view of a tritium handling container including a storage container, a transport container, and an external drum container according to the present invention.
Figure 2 shows a storage container according to the present invention, (a) is a sectional view, (b) is a plan view.
3 is an exploded cross-sectional view of components of a transport container according to the present invention.
4 is a cross-sectional view of the storage container according to the present invention coupled to the transportation container.
5 is a cross-sectional view of an external drum container according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a tritium handling container 1 according to the present invention includes a storage container 2 for storing tritium, and a storage container 2 for storing and transporting the storage container 2. An outer drum container 4 configured to accommodate a transport container 3 and a transport container 3 containing the storage container 2 therein.

The storage container 2 includes a cylindrical storage part 21 for storing tritium, as shown in Figs. 2 (a) and 2 (b). The storage unit 21 is filled with zirconium cobalt alloy or depleted uranium as a tritium storage material for storing tritium in the form of metal hydride, DT, T2, or a mixture thereof produced by the tritium removal facility.

The support 22 extends and is fixed to the upper portion of the storage portion 21 at a predetermined length, and the supports 22 are installed through the storage portion 21 to fill or withdraw tritium, respectively. The pipes 25 and 26 are combined. In addition, connecting terminals 25a and 26a connected to the tritium supply source are attached to the upper ends of the pipes 25 and 26, respectively. The lower ends of the pipes 25 and 26 are provided with filters 27 and 28 to prevent the storage material powder stored in the storage part 21 from being discharged to the outside.

On the other hand, the transport container 3 is divided into an upper container portion 31 and a lower container portion 32, as shown in FIG. Flanges 31a and 32a are formed to correspond to the lower end of the upper container portion 31 and the upper end of the lower container portion 32, respectively, and a plurality of bolts 33 are fastened to the flanges 31a and 32a to form a metal. A plurality of bolt holes 31b and 32b are formed through the ring 34 so as to seal the upper and lower container portions 31 and 32 to each other. In addition, mounting grooves 35a and 36a having different inner diameters are formed in the upper portion of the lower container portion 32, and a pair of 0-rings 35 and 36 are additionally installed to prevent leakage. (See FIG. 4). Here, preferably, the inner 0-ring 35 is made of metal, and the outer O-ring 36 is formed of an elastomeric material, respectively.

In addition, the inner diameter of the metal ring 34 is smaller than the outer diameter of the storage container 2, the outer diameter of the metal ring 34 is size that can be pressed to the upper end of the flange (31a, 32a) of the transport container (3), In case of a drop accident, the storage unit 21 of the storage container 2, the support 22, the valves 23, 24, etc.

The tooth is designed to cushion the physical impact.

By the way, a space portion 37 is formed at one upper portion of the upper container portion 31, and when tritium is leaked from the storage container 2, the storage container 2 and the transport container ( Sampling valve 38 is installed to confirm in advance whether or not to leak before dismantling 3). The sampling valve 38 is embedded in the space 37 so as not to be exposed to the outside, so that safety can be ensured. In addition, the space portion 37 is provided with safety caps 39a and 39b, respectively, for safe operation of the sampling valve 38 during sampling and inert gas injection.

On the other hand, in the center of the upper end of the upper container portion 31, the upper and lower container portions 31 and 32 are fastened to carry the combined lifting container 3 to combine with the external drum container (4) The lifting female thread part 31c was formed so that (not shown) may be combined, and the work convenience was secured.

4 shows a state in which the storage container 2 is housed in the transport container 3 and coupled thereto, and briefly examines their assembling process. First, the storage container 2 shown in FIG. 2 (a) is closely inserted into the lower container portion 32 of the transportation container 3 without a separate space. Then, the valves 23 and 24 including the support 22, the upper portions of the pipes 25 and 26, the connecting terminals 25a and 26a, and the like protrude upward from the lower container portion 32. Next, the metal ring 34 and the metal 0-ring 35 and the elastomeric O-ring 36 are mounted on the top of the lower container portion 32, and as shown in FIG. And 36a). Then, when the bolts 33 are fastened to the plurality of bolt holes 31b and 32b formed in the flanges 31a and 32a of the upper and lower container portions 31 and 32, respectively, the coupling state is as shown in FIG. At this time, the carrier container 3 is filled with an inert gas of normal pressure to prevent the tritium leakage.

On the other hand, Figure 5 shows the structure of the external drum container (4) for receiving the transport container 3 is stored as shown in Figure 4 (2). The exterior of the drum container 4 is aluminum

Body 41 is made of, and the bottom of the pedestal 42, the stopper 43 of the upper portion and a carrying handle 44.

On the other hand, the inside of the drum container (4), when reducing the thermal shock and physical impact for heat shielding

The filling material 45 using balsa wood as a cushioning material for swelling is cut and installed in accordance with the outer shape of the container 3. Balsawood is highly resistant to high temperatures and rapid temperature changes, and has excellent impact resistance and shock absorption. In addition, it has excellent shear Young's modulus, which not only absorbs shocks but also has high compressive strength to withstand pin point pressure. In addition, balsa wood, unlike other cushioning materials such as urethane foam, which is used in the past, generates less combustion gas, and in the event of a fire, the burned portion becomes charcoal and is extinguished by carbonization. Since it is extinguishable, it is possible to prevent explosion or crest due to pressure rise inside the drum container.

 On the other hand, the outer circumferential surface of the filler 45 made of balsa wood is wrapped with a coating layer 46 made of a polyester film. The coating layer 46 made of the polyester film is a combustion gas generated by combustion while insulating in order to delay the carbonization of the balsa wood inside due to an increase in the surface temperature of the drum container 4 during a fire. Minimize the role.

Experimental results of the tritium handling container (1) produced through the embodiment described above, satisfies the technical standards of the B (U) type of transport container classified according to the Korean Atomic Energy Act No. 2008-69 Appeared.

That is, 9m as a structural evaluation on the transport accident condition of the tritium handling container (1)

After the drop test and the 1m high rupture rod drop test on the most damaged area, the immersion test and the leak test proved that the safety was maintained. In addition, when the fire is left at a temperature of 800 ° C. or more for at least 30 minutes, the integrity of the tritium storage container is maintained by the thermal insulation of the polyester film of the coating layer 46 and the carbonization of the balsa wood of the filler 45. Confirmed.

One; Handling container 2; Storage container
3; Transport container 4; Drum Container
21; Storage 22; support fixture
23,24; Valve 25,25; pipe
27,28; Filter 31; Upper container part
32; Lower container portion 34; Metal ring
35; Metal o-ring 36; Elastomer O-ring
37; Space part 41; Body
45; Filler 46; Coating layer

Claims (7)

In the tritium handling container consisting of a storage container for storing tritium in the form of metal hydride, a transport container for storing the storage container, and a drum container for receiving the transport container housed therein,
The transport container 3 for storing the storage container 2 is divided into an upper container part 31 and a lower container part 32,
Flanges 31a and 32a are formed to correspond to the lower end of the upper container part 31 and the upper end of the lower container part 32 so as to be fastened to each other.
The upper and lower container parts 31 and 32 are coupled to be sealed by a metal ring 34.
The inner diameter of the metal ring 34 is smaller than the outer diameter of the storage container 2, the outer diameter of the metal ring 34 is characterized in that the size formed to be pressed on the top of the flange (31a, 32a) of the transport container (3). Tritium container. According to claim 1, Mounting grooves (35a, 36a) having different inner diameters are further formed on the upper end of the lower container portion 32, O-rings (35, 36) in these mounting grooves (35a, 36a) Tritium handling container, characterized in that each is installed. 3. The tritium handling container according to claim 2, wherein the inner 0-ring (35) is made of metal and the outer O-ring (36) is formed of an elastomeric material, respectively. delete According to claim 1, wherein the upper portion of the upper container portion 31 is formed with a space portion 37, the space portion 37, the sampling valve for checking whether the tritium leakage from the storage container ( Tritium handling vessel, characterized in that 38) is installed. 3. The tritium handling container according to claim 1, wherein a filling material (45) using balsa wood is cut and installed in the drum container (4) to fit the outer shape of the transport container (3). The tritium handling container according to claim 6, wherein an outer circumferential surface of the filler (45) is provided with a coating layer (46) wrapped with a polyester film.

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