KR102203956B1 - Rack for storage of integral spent nuclear fuel for neutron absorption and shielding - Google Patents

Abstract

The present invention can reduce the thickness, weight, and volume of the rack by making the used waste nuclear fuel integrally using stainless steel alloys containing neutron absorbers or shielding materials of various materials, and workability containing neutron absorption and shielding materials. It relates to an integrated waste fuel storage rack for neutron absorption and shielding that can manufacture a rack that eliminates the weakness of the mechanical properties of the welded part by manufacturing it in a seamless square tube structure using this high stainless steel alloy steel.It is stainless steel in a molten state. A certain amount of shielding mixture is added and mixed into the alloy steel, and the alloy steel is formed into a cylindrical or polygonal cylindrical shape through extrusion or compression, or an alloy steel plate formed in a plate shape is formed through welding to form the body and closed inside. It is characterized by storing and sealing nuclear fuel.

Description

Rack for storage of integral spent nuclear fuel for neutron absorption and shielding}

The present invention relates to an integrated waste nuclear fuel storage rack for neutron absorption and shielding, and in more detail, the used waste nuclear fuel is integrally made by using stainless steel alloy steel containing neutron absorbers or shielding materials of various materials. It can reduce the thickness, weight, and volume, and absorbs neutrons that can manufacture a rack that eliminates the weakness of the mechanical properties of the welded part by manufacturing a seamless square tube structure using stainless steel alloy with high workability containing neutron absorption and shielding materials. And a shielding integrated waste nuclear fuel storage rack.

Generally used nuclear fuel is sealed and stored in a rack made of a material that absorbs or shields neutrons, and is stored underwater or underground for disposal.

Such a storage rack is stored in a storage rack made of a shielding material, and a separate external rack having strong strength is formed outside the storage rack to be wrapped in double or triple to prevent neutrons from leaking to the outside.

However, since such a storage rack is made of a multi-structure, the manufacturing time and volume are increased to occupy a large volume of space, so there is a problem that a lot of space for storing the rack is required, and the rack is made in a multi-structure. However, there is a problem that only a small amount of used nuclear fuel is stored.

The prior patent describes a nuclear fuel rod assembly storage rack having a square sturdy structure that defines a space and is accommodated in at least one of the empty spaces, is formed of a neutron absorption plate, and has a square neutron absorption panel surrounded by at least two support grids. Has been.

However, the prior patent has a problem in that a storage rack, which is a conventional problem, has a multi-structure, so that manufacturing time and volume are increased to occupy a large volume of space, and thus a lot of space for storing the rack is required. Since the rack is made in a structure, there is a problem that only a small amount of used nuclear fuel is stored as it is.

In addition, Japanese Unexamined Patent Application Publication No. 2002-020828 has applied aluminum and boron alloy powder to a nuclear fuel assembly as a basket molded body. Since the boron material has a shielding function for waste nuclear fuel, it is also used in other conventional Japanese Unexamined Patent Application Publication No. 2006-177697, but the aluminum material is a material having excellent structural strength on the outside of the basket molded body because the structural strength is very weak. There is a problem of wrapping it in several layers again.
In addition, the melting point of the aluminum is about 400°C, and in the case of mixing and molding with boron powder, cracks are generated during extrusion or rolling molding, and the extrusion or rolling molding process widely used in the general molding process cannot be performed. , There is a problem in that the cost increases during processing of the molded body.

Prior Patent Korean Laid-Open Patent Publication No. 10-1998-071205 (1998.10.26.) Prior Patent Japanese Unexamined Patent Application Publication No. 2002-020828 (2002.01.23) Prior Patent Japanese Unexamined Patent Application Publication No. 2006-177697 (2006.07.06)

The present invention can reduce the thickness, weight, and volume of the rack by making the used waste nuclear fuel integrally using stainless steel alloys containing neutron absorbers or shielding materials of various materials, and workability containing neutron absorption and shielding materials. Its purpose is to provide an integrated waste fuel storage rack for neutron absorption and shielding that can manufacture a rack that eliminates the weakness of the mechanical properties of the welded part by manufacturing it in a seamless square tube structure using this high stainless steel alloy steel.

The integrated waste nuclear fuel storage rack for absorbing and shielding neutrons according to the present invention for achieving the above object is made of alloy steel by inputting and mixing a certain amount of shielding mixture into metal steel made of stainless steel in a molten state, and the alloy steel is extruded. Alternatively, the body is formed in a cylindrical or polygonal shape through compression, and the waste fuel is stored and sealed in the body.

The main body is characterized in that it is formed in a plate shape through rolling and formed into a cylindrical or polygonal cylindrical shape through welding.

The shielding mixture is characterized in that it is formed by mixing one or two or more of gadolium (Gd), boron (B), erbium (Er), or samarium (Sm).

The shielding mixture is 0.01 to 2 parts by weight per type constituting the shielding mixture compared to 100 parts by weight of alloy steel, and the stainless steel is made of 99.99 to 92 parts by weight based on 100 parts by weight of alloy steel, and 0.01 to 2 parts by weight per type of the shielding mixture. It is characterized in that the weight is reduced.

The present invention has the effect of reducing the thickness, weight, and volume of a rack by making the used waste nuclear fuel integrally using stainless steel alloy steel containing neutron absorbers or shielding materials of various materials.

In addition, there is an effect of manufacturing a rack that eliminates the weakness of the mechanical properties of the welded portion by manufacturing it in a seamless square tube structure using stainless steel alloy having high workability containing neutron absorption and shielding material.

1 is a view showing the formation and use process of the integrated waste nuclear fuel storage rack for neutron absorption and shielding according to an embodiment of the present invention.

Hereinafter, specific embodiments for carrying out the present invention will be described with reference to the drawings. Embodiments of the present invention are for explaining one invention, and the scope of rights is not limited to the illustrated embodiments, and the illustrated drawings are limited to the drawings because only the essential content is enlarged and ancillary items are omitted for clarity of the invention. And should not be interpreted.

The present invention is made of alloy steel by inputting and mixing a certain amount of shielding mixture 2 into metal steel 1 made of stainless steel in a molten state, and the alloy steel is formed into a cylindrical or polygonal cylindrical shape through extrusion or compression. ), and storing and sealing the waste nuclear fuel 3 in the interior of the main body 20.

The main body 20 is characterized in that it is formed in a plate shape through rolling and formed into a cylindrical or polygonal cylindrical shape through welding.

The shielding mixture 2 is characterized in that it is formed by mixing one or two or more of gadolilium (Gd), boron (B), erbium (Er), or samarium (Sm).

The shielding mixture 2 is 0.01 to 2 parts by weight per type constituting the shielding mixture 2 relative to 100 parts by weight of alloy steel, and the metal steel 1 is made of 99.99 to 92 parts by weight compared to 100 parts by weight of alloy steel, It is characterized in that 0.01 ~ 2 parts by weight per type of the shielding mixture (2) is reduced.

1 is a view showing the formation and use process of an integrated waste nuclear fuel storage rack for absorbing and shielding neutrons according to an embodiment of the present invention, in a metal steel 1 made of molten stainless steel with a certain amount of shielding mixture ( 2) is added and mixed to produce alloy steel, and the alloy steel is formed into a cylindrical or polygonal cylindrical shape through extrusion or compression, and waste nuclear fuel (3) is stored inside the main body (20). Close it.

The metal steel 1 is provided in a molten state so that the shielding mixture 2 can be easily melted and mixed.

The metal steel 1 is made of a stainless steel material that does not rust even after a long time, and the structure is approximately three times stronger than that of aluminum, and its melting point is also twice as high, so it has a very advantageous effect on extrusion molding. have.

The shielding mixture (2) is added to the molten metal steel (1) to be made of alloy steel.

The alloy steel in which the shielding mixture 2 is mixed has a body 20 formed in a cylindrical or polygonal shape through an extrusion device 10 or a compression device 10, and one side of the body 20 is sealed to Space is formed in

The alloy steel is formed by mixing the shielding mixture (2) with stainless steel, which is a metal steel (1).

The main body 20 is formed by forming an alloy steel in a plate shape to manufacture an alloy steel plate, and the alloy steel plate is welded in a cylindrical or polygonal shape to form the main body 20, and one side of the main body 20 is sealed so that the inside It is formed to form a space.

The used waste fuel 3 is stored in the inner space of the main body 20, and the open side is sealed with an alloy steel plate to form a rack.

The shielding mixture (2) mixed with the metal steel (1) constituting the body (20) is a mixture of one or two or more of gadolium (Gd), boron (B), erbium (Er), or samarium (Sm). Done.

That is, the shielding mixture (2) is made of any one of gadolilium (Gd), boron (B), erbium (Er), or samarium (Sm), or two or more are mixed with metal steel 1 to be alloyed steel Is formed by

When the shielding mixture 2 is of one type, it is composed of 0.01 to 2 parts by weight and mixed with stainless steel, and the stainless steel is composed of 99.99 to 98 parts by weight to correspond thereto.

When the two shielding mixtures 2 are mixed, each type is made up of 0.01 to 2 parts by weight, and the total weight is made up of 0.02 to 4 parts by weight, and the metal steel 1 is made up of 99.98 to 96 parts by weight to correspond thereto.

When the three shielding mixtures 2 are mixed, each consists of 0.01 to 2 parts by weight, and the total weight is made up of 0.03 to 6 parts by weight, and the metal steel 1 is made up of 99.97 to 94 parts by weight to correspond thereto.

When the four shielding mixtures 2 are mixed, each consists of 0.01 to 2 parts by weight, and the total weight is made of 0.04 to 8 parts by weight, and the metal steel 1 is made up of 99.96 to 92 parts by weight to correspond thereto.

That is, when the number to be mixed of the shielding mixture 2 is increased one by one, each material is mixed by increasing 0.01 to 2 parts by weight, and the weight of the metal steel 1 corresponding thereto is made up of 99.98 to 92 parts by weight and 0.01 to 92 parts by weight. It is mixed by decreasing by 2 parts by weight.

The process of manufacturing the rack of the present invention and sealing the used waste nuclear fuel 3 by using it will be described as follows.

First, a certain amount of the shielding mixture 2 is added to the molten metal steel 1 and mixed to prepare an alloy steel.

And, by forming the main body 20 through an extrusion or compression process in the shape of a cylindrical or polygonal cylindrical shape with one side sealed, or formed in a plate shape and welded into a cylindrical or polygonal cylindrical shape with one side sealed. The body 20 is formed.

The used waste nuclear fuel 3 is stored in the body 20 formed in this way, and the open side is sealed with an alloy steel plate.

The present invention made as described above has the effect of reducing the thickness, weight, and volume of the rack by making the used waste nuclear fuel integrally using stainless steel alloy steel containing neutron absorbers or shielding materials of various materials.

In addition, there is an effect of manufacturing a rack that eliminates the weakness of the mechanical properties of the welded portion by manufacturing it in a seamless square tube structure using stainless steel alloy having high workability containing neutron absorption and shielding material.

The integrated waste nuclear fuel storage rack for neutron absorption and shielding as described above is not limited to the configuration and operation method of the embodiments described above. The above embodiments may be configured so that all or a part of each of the embodiments may be selectively combined to make various modifications.

1: metal steel 2: shielding mixture
3: waste nuclear fuel
10: extrusion device, compression device 20: main body

Claims (4)

A certain amount of shielding mixture (2) is added to and mixed with metal steel (1) made of stainless steel in a molten state to form alloy steel, and the alloy steel is extruded or pressed to form a body 20 in a cylindrical or polygonal cylindrical shape. And storing and sealing the waste nuclear fuel 3 in the main body 20;
The main body 20 is formed in a plate shape through rolling and formed in a cylindrical or polygonal cylindrical shape through welding;
The shielding mixture 2 is made by mixing three or more of gadolilium (Gd), boron (B), erbium (Er), or samarium (Sm);
When the shielding mixture 2 is mixed with three types selected from gadolium (Gd), boron (B), erbium (Er), or samarium (Sm), each type consists of 0.01 to 2 parts by weight. The weight is made of 0.03 to 6 parts by weight, and the metal steel 1 is made of 99.97 to 94 parts by weight to correspond to this,
When the shielding mixture 2 is mixed with four types selected from gadolium (Gd), boron (B), erbium (Er), or samarium (Sm), each type consists of 0.01 to 2 parts by weight. An integrated waste fuel storage rack for neutron absorption and shielding, characterized in that the weight is made of 0.04 to 8 parts by weight, and the metal steel 1 is made of 99.96 to 92 parts by weight to correspond thereto.
delete delete delete

Images