KR100961600B1 - Method and Apparatus for Collecting Spent Nuclear Fuel - Google Patents

Abstract

The present invention is to provide a spent fuel stripping recovery apparatus and method for oxidizing and pulverizing spent fuel and separating hulls without pretreatment for separating hulls from spent fuel. The spent fuel stripping recovery apparatus of the present invention comprises an oxidation unit, a driving unit, a discharge unit, and a collection unit, wherein the pellets oxidized and powdered in the oxidation unit and the hull separated during the oxidation process are discharged and the collection unit, respectively. Can be discharged. By using the spent fuel stripping recovery apparatus of the present invention, there is no need to go through a pretreatment process in which the hulls are separated for oxidation of the spent fuel, and the separated hulls and the powdered pellets are discharged with a time difference. Consumption efficiency can be increased.

Spent fuel, oxidation, powdered. Hull, pellet.

Description

Apparatus and method for recovering spent fuel de-coating {Method and Apparatus for Collecting Spent Nuclear Fuel}

The present invention relates to an apparatus and a method for separating and recovering spent nuclear fuel into hulls and powdered pellets, and specifically, to pulverizing pellets by oxidizing spent nuclear fuel through an oxidation process. At the same time, the present invention relates to a spent fuel stripping recovery apparatus and method capable of separating hulls and discharging them separately.

In general, nuclear fuel rods use aluminum, magnesium, and zirconium alloys as hulls to cover nuclear fuel and prevent the leakage of fission products. Is presented.

The stripping processes that are generally used up to now are processes using wet method and dry method by classification by operation method, and are classified into chemical method and mechanical method by classification according to stripping mode. Chemical stripping involves the process of dissolving the nuclear fuel material using a suitable solvent or reactant, in which part of the nuclear fuel material is lost along with the reactant. The wet process is a process of cutting a nuclear fuel into short pieces and then dissolving the fuel element by nitric acid, which requires post-treatment to remove the hull from the dissolution tank as well as the fuel material generated from the melt that is buried in the hull. Results in the loss of.

On the other hand, in the case of adopting a mechanical method, it is possible to reduce the problem of the amount of waste generated in the wet stripping process, but has a disadvantage in that it must be dependent on the batch treatment in the operation method. Looking at the dry stripping process known to date, stripping by a roller-straightner technique in which the fuel rod is passed between the multi-stage rollers to increase the axial length and break the fuel element inside the fuel rod by radial deformation. Recovery process, cutting-slitting the hull in the longitudinal direction at both points of the fuel rod cut to a certain length, cutting the fuel rod cut to a certain length by heating in a furnace of air atmosphere There is a method of separating the hull and the fuel element by rupturing (voloxidation), a hole in the longitudinal direction of the fuel rod cut to a certain length and heating in an air atmosphere to rupture the hull by volume expansion (Airox), and the like. The dry stripping process described above is one of the multi-stage independent units operated batchwise as previously described. Relates to a process of my break repeat method, separate from the hull break the good nuclear fuel material, leaving a disadvantage in that the inconvenience of subsequent processing to be removed.

Meanwhile, in France, a continuous stripping process has been attempted by using a ball mill method, but it has failed because pneumatic transfer of uranium oxide (U ₃ O ₈ ) using pneumatic pressure is not possible.

Therefore, the present invention, unlike the conventional spent fuel stripping recovery device and method described above, separates the hull and the powdered pellet into a hull collection container and a powder collection container separately without the need for adding a pretreatment process or a subsequent process. It is an object of the present invention to provide an apparatus and method for recovering spent fuel de-coating.

In addition, another object of the present invention is to remove the hull and powdered pellets by selectively replacing the hull and the powder collection container to collect the separated hull and powdered pellets to increase the space consumption efficiency To provide a spent fuel stripping recovery apparatus and method.

Another object of the present invention is to separate the collected hulls and powdered pellets into a single collection container, respectively, to further increase the space consumption efficiency and to further shorten the collection time, thereby increasing the efficiency of the entire process. It is to provide an apparatus and method for post-nuclear desorption recovery.

The spent fuel stripping recovery apparatus of the present invention includes a pellet collection container, a hull collection container, a guide unit, a transfer unit, and a powder receiving unit provided at the lower portion of the oxidation container, and the hull separated after oxidation is a hull collection container. The collected and powdered pellets are collected in a pellet collecting container, and the guide unit serves to guide the pellet collecting container or the collecting container into a seating area where the pellet collecting container or the hull collecting container is seated. It is discharged to the outside of the container, and the powder receiving unit is located under the oxidation container to receive the powdered pellets.

The spent fuel stripping recovery apparatus of the present invention further includes an air injection unit for injecting high pressure air into the oxidation vessel or the powder receiving unit.

The shape of the oxidizing vessel is a hollow cylinder is formed around the net, the powdered pellet is temporarily stored in the powder receiving unit through the net.

 The guide unit has a funnel shape, and a valve is installed at the upper end of the guide unit in contact with the hull collection container or the pellet collection container to control the entry and exit of the hull or pellets.

The transfer unit has a spiral screw shape, which is mounted on a rotating shaft penetrating the oxidation vessel and transfers spent nuclear fuel or separated hulls by forward rotation and reverse rotation. It may further include a drive unit for rotating the rotating shaft forward or reverse, the transfer unit is driven by this drive unit.

The waste container and the pellet container may be alternately arranged in the seating part. For example, when the hull collection by the hull collection container is completed, the hull collection container is replaced with a pellet collection container at the seating part. Preferably, the hull collection container and the pellet collection container may be made of a detachable collection container in one piece. In this case, a shutoff valve is installed at the center of the collection container so that after the collection of any one of the hulls or pellets is completed, the shutoff valve blocks the top and bottom of the container to collect the other one of the hulls or pellets. Form. The powder receiving unit has a hollow hemispherical cylindrical shape, and has a rotating element that allows rotation about the oxidation vessel.

The present invention also provides a method for recovering spent fuel de-coating.

The spent fuel stripping recovery method according to the present invention comprises the steps of: separating the spent fuel into hulls and powdered pellets by oxidation in an oxidation vessel; collecting the powdered pellets into a powder receiving unit; The step of discharging to the outside of the oxidizing vessel, collecting the hull into the hull collection container, replacing the hull collection container and the pellet collection container, and collecting the powdered pellet into the pellet collection container.

When recovering the hull and the pellets by the spent fuel stripping recovery method according to the present invention, the hull collection container and the pellet collection container without going through the step of replacing the hull collection container and the pellet collection container in the above-described method, The process can be simplified by using an integrated collection container. The upper part of the integrated collection container collects the pellets and the lower part collects the hull, and a shutoff valve is installed therebetween, so that the step of replacing the hull collection container and the pellet collection container is performed by blocking the shutoff valve.

In addition, the spent fuel stripping recovery method according to the present invention comprises the steps of separating the spent fuel into hulls and powdered pellets by oxidation in an oxidizing vessel, collecting the powdered pellets into a powder receiving unit, Collecting the powdered pellet into a pellet collecting container, replacing the pellet collecting container and the hull collecting container, discharging the hull out of the oxidation container, and collecting the hull into the hull collecting container.

At this time, the pellet collection container and the hull collection container are integrated, the hull collection container is located at the top of the pellet collection container, and is composed of a collection container having a shutoff valve between the pellet collection container and the hull collection container. The step of replacing the container may be accomplished by shutting off the shutoff valve.

Preferably, the step of discharging the hull out of the oxidation vessel is achieved by reverse rotation of the helical screw mounted on the rotating shaft passing through the oxidation vessel.

Preferably, the step of collecting the hull into the hull collection container, the funnel-shaped guide unit located in the lower portion of the oxidation vessel guides the hull to the seating area where the hull collection container is seated, opening the valve installed between the guide unit and the seating part And collecting the hull with the hull collection container, and closing the valve after the collection of the hull is completed.

Preferably, the step of collecting the powdered pellets into a pellet container. Rotating the powder receiving unit, spraying the high pressure air to the oxidation container or the powder receiving unit by the air spray unit, and the funnel-shaped guide unit located at the lower part of the oxidation container for guiding the pellets to the seating unit where the pellet collecting container is seated; , Opening the valve installed between the guide unit and the seating unit, collecting the pellets into the pellet collecting container, and closing the valve after the collection of the pellets is completed.

When the spent fuel is separated into hulls and powdered pellets using the spent fuel stripping recovery apparatus and method according to the present invention, the spent fuel is stripped and used as hulls and pellets without undergoing pretreatment and subsequent treatment. Each can be separated.

In addition, according to the spent fuel stripping recovery device and method according to the present invention, since the hull collection container and the pellet collection container can be used in the same seating portion, there is an effect of increasing the space consumption efficiency.

In addition, the spent fuel de-coated oxidation apparatus and method of the present invention can separate and collect the separated hulls and powdered pellets in one collection container, thereby further increasing space consumption efficiency and shortening collection time. There is an advantage that can increase the efficiency of the entire process.

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. For reference, the same numbers in this description refer to substantially the same elements and can be described with reference to the contents described in the other drawings under the above-mentioned rules, and the contents which are judged to be obvious to the person skilled in the art or repeated can be omitted.

1 is a schematic front view of a spent fuel stripping recovery apparatus according to the present invention. Figure 2 is a plan view of a spent fuel stripping recovery apparatus of the present invention, Figure 3 shows a side view thereof.

The spent fuel stripping recovery device 100 of the present invention comprises a pellet collecting container 160, a hull collecting container 150, a guide unit 120, a conveying unit 140, and a powder receiving unit 130. It may further include an air injection unit 170. In addition, the spent fuel stripping recovery apparatus 100 is provided with an oxidation container 110 in which spent fuel is separated into hulls and powdered pellets.

The oxidation vessel 110 has a hollow cylindrical shape and has a circumferential net. Pre-oxidation of spent fuel is located in the oxidation vessel 110 by the network structure, but when the spent fuel is separated into hull and powdered pellets by the oxidation process, the hull remains in the oxidation vessel 110 but is powdered. The pellets come out of the net and are collected in the powder receiving unit 130 disposed below the oxidation vessel 110.

Guide unit 120 is located in the lower portion of the oxidation container 110, funnel shape to guide the hull and powdered pellets separated from the oxidation container 110 to the hull collection container 150 or pellet collection container 160 It is. A valve 121 is installed between the seating unit on which the hull collection container 150 or the pellet collection container 160 is seated and the guide unit 120. That is, the valve 121 is disposed in the lower portion of the guide unit 120, the movement of the hull or powdered pellets collected in the guide unit 120 to the hull collection container 150 or pellet collection container 160 is a valve ( By the opening and closing of 121).

4 is a partial cutaway perspective view schematically showing the oxidation container 110, the transfer unit 140 and the powder receiving unit 130.

The powder receiving unit 130 is positioned below the oxidation vessel 110, and has a rotating element (not shown) to rotate about the rotation shaft 141 passing through the oxidation vessel 110. The powder receiving unit 130 has a hollow hemispherical cylindrical shape, and the powdered pellets exiting from the oxidation vessel 110 are temporarily collected in the powder receiving unit 130. Allowing the powder receiving unit 130 to rotate about the rotating shaft 141 is to send the powdered pellets collected in the powder receiving unit 130 to the guide unit 120, which is then turned over. The powdered pellets in the receiving unit 130 fall to the guide unit 120 located below the powder receiving unit 130 by gravity, and the remaining pellets remaining in the powder receiving unit 130 will also be described later. It is dropped to the guide unit 120 by the high-pressure air injection of (170).

As can be seen in Figure 4, the transfer unit 140 has a spiral screw shape formed on the rotating shaft 141 penetrating the oxidation vessel 110. The spiral screw of the transfer unit 140 is formed from one end to the other end of the oxidation vessel 110, the diameter should be smaller than the cross-sectional diameter of the oxidation vessel 110, the spacing between the spiral screw and the oxidation vessel 110 is small. The smaller the better. The driving unit 180 rotates the rotating shaft 141 to rotate the spiral screw to transfer the spent fuel into the oxidation vessel 110, or by reverse rotation of the spiral screw due to the opposite rotation of the rotating shaft 141. The hull in the oxidation vessel 110 is discharged to the outside of the oxidation vessel 110.

The driving unit 180 is disposed on one side of the rotating shaft 141 extending to the outside of the oxidation vessel 110, and transmits a driving force to the rotating shaft 141. The drive unit 180 is composed of a motor and a rotating element. The drive shaft of the motor may be arranged in parallel with the rotation shaft 141, in which a belt is used as a connecting element, by which the motor transmits a driving force to the rotation shaft 141. If the rotating shaft 141 and the driving shaft of the motor are vertically arranged, the driving force may be transmitted using a bevel gear as a connecting element. The drive unit 180 may not only rotate the rotating shaft 141 forward but also reversely.

The hull collection container 150 and the pellet collection container 160 may be configured as separate containers. The hull collection container 150 or the pellet collection container 160 is disposed at a seating portion located below the valve 121 of the guide unit 120. The hull collection container 150 and the pellet collection container 160 may not be located at the same time in the seating part, and optionally only one of them may be located so that they may be alternately arranged with each other. This is because the hull separated by the oxidation of spent nuclear fuel must be discharged to the hull collection vessel 150 and the powdered pellets to the pellet collection vessel 160, respectively. The hull collection container 150 and the pellet collection container 160 is not particularly limited, but in general, it is preferable that it is a bulky container capable of collecting hulls or pellets, and the valve 121 of the guide unit 120. At the top of the hull collection container 150 and the pellet collection container 160 to be in contact with the opening and closing cap is preferably installed to seal the inside of the container.

5 is a perspective view of a modified example in which the hull collection container 150 and the pellet collection container 160 are integrally formed, and the hull collection container 150 and the pellet collection container 160 are integrally formed. One of the hull collection container 150 or the pellet collection container 160 is located at the top, the other is configured to be located in the lower, between the hull collection container 150 and the pellet collection container 160 to block A shutoff valve 155 is provided. In this embodiment, the pellet container 160 is located on the upper portion, the hull collection container 150 is described a modified example of the lower portion, but is not necessarily limited to the hull container 150 is located on the top, pellets Collection container 160 may have a configuration located below.

The upper part of the hull collection container 150 and the pellet collection container 160, which are integrally formed, have a narrower shape than the lower end of the hull collection container 150 so as to easily collect the hull supplied from the top. Since the hull in the state in which the shutoff valve 155 is opened to pass through the pellet collecting container 160 should be collected into the hull collecting container 150, the lower end of the pellet collecting container 160 has a hull collecting container 150. It has a narrow funnel shape for easy movement. The hull collection container 150 and the pellet collection container 160, which are integrally formed, are separable, and when the hulls and pellets are collected in each container, the hull and pellets are separated, and then the hulls and pellets can be easily processed. Because it can. After separation, the hull collection container 150 and the pellet collection container 160 may be provided with a stopper to seal the inside, respectively.

The air injection unit 170 is disposed below the powder receiving unit 130, and sprays high pressure air into the powder receiving unit 130 and the oxidation vessel 110. When the powder receiving unit 130 is turned 180 degrees around the rotating shaft 141 to discharge the collected pellets in the powder receiving unit 130, most of the pellets are dropped into the guide unit 120 by gravity, but some The remaining pellets remain inside the powder receiving unit 130 and the oxidation vessel 110. At this time, the air injection unit 170 by spraying the high pressure air to the powder receiving unit 130 and the oxidation vessel 110, the remaining pellets are separated from the powder receiving unit 130 and the oxidation vessel 110 to guide the unit ( 120). It is configured to rotate by a predetermined amount without configuring the injection port of the air injection unit 170 fixedly, as well as the rotary shaft 141, the transfer unit 140, the guide unit (130) and the oxidation vessel 110 120) may leave the remaining pellets that did not leave the component.

The present invention also provides a method for spent fuel stripping oxidation. This will be described in detail below.

The spent fuel is separated into hull and pellet powder by oxidation. For this purpose, the spent fuel is transported to the oxidation vessel 110 through an inlet. The spent nuclear fuel transported to one end of the oxidizing vessel 110 is transferred into the oxidizing vessel 110 by the rotation of the spiral screw which is the transfer unit 140. During the oxidation process by heating inside the oxidation vessel 110, the pellets are powdered and separation from the hull occurs. Since the oxidation vessel 110 has a network structure, the powdered pellets pass through the network and fall into the powder receiving unit 130 located below the oxidation vessel 110 to be collected there. At this time, the spiral screw, which is the transfer unit 140, periodically repeats the forward rotation and the reverse rotation, so that the oxidation reaction of the spent fuel can be performed smoothly, and the powdered pellets are easily supplied to the powder receiving unit 130. To be collected.

When the spent fuel is separated into hulls and powdered pellets by the oxidation process, the separated hulls and pellets must be discharged separately. Since the order of discharging the hull and pellets is not determined, it does not matter which one is discharged first. However, in general, since the hull is discharged first, in the present embodiment, the discharge step of the pellet is performed after the discharge step of the hull is completed as an example.

The discharge of hull is caused by the following process. After oxidation, the hull remains in the oxidation vessel 110. This hull is discharged to the outside of the oxidation vessel 110 by the reverse rotation of the spiral screw transfer unit 140. The hull discharged to the outside of the oxidation vessel 110 is dropped to the guide unit 120 located below the oxidation vessel 110 by gravity, and collected in the lower portion of the guide unit 120. This is the shape of the guide unit 120 is funnel shape. By opening the valve 121 installed at the bottom of the inner unit 120, the hull is collected by the hull collection vessel 150 disposed in advance under the guide unit 120. When all the hulls enter the hull collection vessel 150, the valve 121 is closed and the hull collection vessel 150 is recovered to complete the recovery of the hull.

Subsequently, a recovery process of the pellets is performed. First, the pellet collection container 160 is disposed in the seating portion where the hull collection container 150 is recovered. When the powder receiving unit 130 in which the pellets are collected is rotated 180 degrees about the rotating shaft 141 by a rotating element (not shown), the pellets fall down by gravity to collect at the lower portion of the guide unit 120. do. At this time, by spraying the high pressure air from the air injection unit 170, the remaining pellets remaining in the powder receiving unit 130 and the oxidation vessel 110 is separated to fall down by gravity. When the valve 121 is opened, the powdered pellets are collected into the pellet collecting container 160, and collection is completed by closing the valve 121 and recovering the pellet collecting container 160, thereby recovering the pellets. .

When the hull collection container 150 and the pellet collection container 160 are integrally formed, the hull collection process and the pellet collection process proceed as follows.

With the shutoff valve 155 open, the hull recovery process takes place as described above. When the recovery of the hull is completed, the shutoff valve 155 blocks the hull collection container 150 and the pellet collection container 160 which are integrally formed. Subsequently, a pellet recovery step occurs, and the pellet recovery step at this time is the same as described above.

Until now, the method of recovering spent fuel stripping has been described taking the case where the hull recovery process is preceded by the pellet recovery process. However, as noted above, the hull recovery process may occur after the pellet recovery process occurs, which proceeds in the same manner as the above-described pellet recovery process and the hull recovery process, and the hull collection container 150 and pellet collection, which are integrally formed. Only the upper and lower positions of the container 160 are reversed only. This will be omitted for simplicity of explanation.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

Included in this specification.

1 is a schematic view showing a spent fuel stripping recovery apparatus according to the present invention;

2 is a plan view of the spent fuel stripping recovery apparatus according to the present invention;

3 is a front configuration diagram of a spent fuel stripping recovery apparatus according to the present invention;

4 is a cutaway perspective view of the transfer unit and the powder receiving unit of the present invention;

5 is a modified example of the hull collection container and the pellet collection container of the present invention.

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

100: spent fuel stripping recovery device

110: oxidation vessel 120: guide unit

121: valve 130: powder receiving unit

140: transfer unit 141: rotation axis

150: hull collection container 155: shut-off valve

160: pellet collection container 170: air spray unit

180: drive unit

Claims (16)

In the spent fuel stripping recovery device consisting of a pellet (pellet) and a hull (hull) is provided, the oxidation vessel is provided in the lower portion of the oxidation vessel, A pellet collecting container for storing the oxidized and powdered pellets; A hull collection container for storing the hull after oxidation; A guide unit for guiding the pellet container or the hull collection container from the oxidation container to a seating unit on which the pellet collection container is mounted; A transfer unit provided in the oxidation vessel and discharging the hull to the outside; And A powder receiving unit located under the oxidation container to temporarily store powdered pellets; Used nuclear fuel stripping recovery device comprising a. The method of claim 1, A spent fuel stripping recovery device further comprising an air injection unit for injecting high pressure air into the oxidation vessel or the powder receiving unit. The method according to claim 1 or 2, The oxidation container is a hollow cylindrical shape, the circumference is formed in a net, the spent fuel stripping recovery device, characterized in that the powdered pellet is received into the powder receiving unit through the net. The method according to claim 1 or 2, And the guide unit has a funnel shape, and a valve for controlling the hull or pellets is installed between the seating unit and the guide unit. The method according to claim 1 or 2, The transfer unit is spent fuel stripping recovery device, characterized in that the spiral screw formed on the rotating shaft penetrating the oxidation vessel. The method of claim 5, And a driving unit connected to the rotary shaft, the driving unit capable of forward or reverse rotation of the rotary shaft. The method according to claim 1 or 2, The spent fuel stripping recovery device, characterized in that the hull collection container and the pellet collection container is disposed in the seating portion alternately with each other. The method according to claim 1 or 2, The hull collection container and the pellet collection container is an integrally separable collection container, and a spent fuel stripping recovery device, characterized in that a shutoff valve is installed at the center of the collection container. The method according to claim 1 or 2, The powder receiving unit has a hollow hemispherical cylindrical shape, and the spent fuel stripping recovery device, characterized in that it comprises a rotating element to rotate about the oxidation vessel. Oxidation vessel is provided, using a stripping recovery device of spent nuclear fuel consisting of pellets and hulls, Separating the spent fuel into hulls and powdered pellets by oxidation in the oxidation vessel; Collecting the powdered pellets into a powder receiving unit; Discharging the hull out of the oxidation vessel; Collecting the hulls into a hull collection container; Replacing the hull collection vessel and the pellet collection vessel; And Collecting the powdered pellets into the pellet container; Used nuclear fuel stripping recovery method comprising a. The method of claim 10, The hull collection container and the pellet collection container are integrated, and the pellet collection container is located on the upper part of the hull collection container, and is composed of a collection container having a shutoff valve between the hull collection container and the pellet collection container. Replacing the spent fuel stripping recovery method, characterized in that made by blocking the shut-off valve. Oxidation vessel is provided, using a stripping recovery device of spent nuclear fuel consisting of pellets and hulls, Separating the spent fuel into hulls and powdered pellets by oxidation in the oxidation vessel; Collecting the powdered pellets into a powder receiving unit; Collecting the powdered pellets into a pellet collecting container; Replacing the pellet container and the hull collection container; Discharging the hull out of the oxidation vessel; And Collecting the hulls into a hull collection container; Used nuclear fuel stripping recovery method comprising a. 13. The method of claim 12, The pellet container and the hull collection container are integrated, and the hull collection container is located at the top of the pellet collection container, and is composed of a collection container having a shutoff valve between the pellet collection container and the hull collection container. Replacing the container is a spent fuel stripping recovery method, characterized in that made by blocking the shut-off valve. The method according to any one of claims 10 to 13, Discharging the hull to the outside of the oxidation vessel, A spent fuel stripping recovery method, characterized in that the reverse rotation of the helical screw mounted on the rotating shaft passing through the oxidation vessel. The method according to any one of claims 10 to 13, Collecting the hull into a hull collection container, A funnel-shaped guide unit located below the oxidation vessel to guide the hull to a seating portion on which the hull collection vessel is seated; Opening a valve installed between the guide unit and the seating portion; Collecting the hull into the hull collection vessel; And Closing the valve installed between the guide unit and the seating part after the collection of the hull is completed; Used nuclear fuel stripping recovery method comprising the. The method according to any one of claims 10 to 13, Collecting the powdered pellets into the pellet container. Rotating the powder receiving unit; Injecting high-pressure air into the oxidation vessel or the powder receiver by an air injection unit; A funnel-shaped guide unit located below the oxidation container to guide the pellets to a seating part on which the pellet collection container is seated; Opening a valve installed between the guide unit and the seating portion; Collecting the pellets into the pellet container; And Closing the valve after the collection of the pellets is completed; Used nuclear fuel stripping recovery method comprising the.

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