KR20210041275A - Co-60 generating method, and target device used thereof - Google Patents

Abstract

The present invention relates to a target rod for generating Co-60 radioactive isotopes for producing Co-60 radioactive isotopes using neutron flux generated during the operation of a nuclear reactor, and a method for manufacturing Co-60 using the same. The method for producing Co-60 radioactive isotope of the present invention includes loading a Co-59 target in a surplus guide tube among guide tubes provided in a nuclear fuel assembly of a light-water reactor, and manufacturing Co-60 radioactive isotopes by neutron flux generated during the operation.

Description

Co-60 radioactive isotope manufacturing method, and target rod used therein TECHNICAL FIELD [Co-60 generating method, and target device used thereof]

The present invention relates to a method for producing a Co-60 radioisotope by using neutron flux generated during operation of a light water reactor type reactor, and to a target rod used therein.

Co-60, a radioactive isotope, is a radioactive isotope with a half-life of 5.2 years and is widely used as a low-cost gamma source instead of radium by emitting strong gamma rays. Or sterilization, etc.

In general, radioactive isotopes are produced in a large number of research reactors, whereas Co-60 is mainly produced in commercial reactors due to a long period of irradiation of required neutrons and a high required neutron flux.

In heavy water reactors, Co-59 targets can be used in place of control rods that absorb excess neutrons with little impact on the reactor's output stability, so Co-60 produced in Canada, the source of heavy water reactor technology, is in demand worldwide. It is a fact that most of them are supplied.

In the case of pressurized light water reactors, which occupy most of the commercial reactors, the supply of Co-60 from the existing heavy water reactors was sufficient and was not used for production, but as the operation of the existing heavy water reactors gradually arrived, the need for Co-60 production in light water reactors increased. I'm going.

Patent Document 1: Registered Patent Publication No. 10-1502414 (announced on March 13, 2015)

The present invention is to provide a method for producing a Co-60 radioactive isotope by loading a Co-59 target on a guide rod of a light water reactor type reactor, and a target rod used therein.

The method of producing a Co-60 radioactive isotope according to the present invention for achieving this purpose is a driving process by loading a Co-59 target in an unused surplus guide tube among guide tubes provided in a nuclear fuel assembly of a light water reactor type reactor. It is characterized by generating Co-60 by the neutron flux generated in.

Preferably, the Co-59 target is recovered in a replacement cycle.

Next, the target rod for generating CO-60 radiation isotopes according to the present invention includes a housing having a hollow cylindrical shape, having a curved head cap at one end and a locking end protruding outwardly at the other end; An irradiation target made of a radioactive isotope Co-59 housed in the housing; And a fixing part fixed to the housing to support an elastic body that provides a reaction force to the irradiation target housed in the housing.

Preferably, the irradiation target further includes a can for enclosing and protecting Co-59. (Use by coating with Ni to wrap and protect. -> Described in the detailed description)

The method for producing a Co-60 radioactive isotope according to the present invention includes Co-60 radioactivity by neutron flux generated during operation by loading a Co-59 target in an excess guide tube among guide tubes provided in a nuclear fuel assembly of a light-water reactor. As the isotope is produced, there is an advantage that Co-60 can be economically produced by using a light water reactor type reactor in operation.

Next, the target rod for producing CO-60 radiation isotopes according to the present invention includes a housing having a hollow cylindrical shape and a curved head cap at one end and a locking end protruding outwardly at the other end; An irradiation target made of a radioactive isotope Co-59 housed in the housing; Including a fixing part fixed to the housing to support an elastic body that provides a reaction force to the irradiation target housed in the housing, it is easy to press-in and withdraw from the surplus guide tube among the nuclear fuel assemblies of the light water reactor type reactor. It has the advantage of not requiring modification or additional installation structure.

1 is a cross-sectional configuration diagram of a target rod according to an embodiment of the present invention,
2(a)(b)(c)(d) and 3(a)(b) are views showing various modified examples of an irradiation target according to an embodiment of the present invention;
4 is a side view of a nuclear fuel assembly in which the target rod of the present invention is installed,
5 is a plan view showing a supporting grid of a nuclear fuel assembly.

Specific structural or functional descriptions presented in the embodiments of the present invention are exemplified only for the purpose of describing the embodiments according to the concept of the present invention, and embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as limited to the embodiments described in the present specification, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, terms indicating directions such as upper, lower, left, or right are based on the accompanying drawings and are used as a relative meaning between components.

1 is a cross-sectional view of a target rod according to an embodiment of the present invention.

Referring to FIG. 1, the target rod 100 of this embodiment includes a housing 110, an irradiation target 120, and a fixing part 130.

The housing 110 is a hollow cylindrical shape, the outer diameter of the housing 110 is smaller than the inner diameter of the guide tube constituting the nuclear fuel assembly, a material such as zirconium alloy may be used, but is not limited thereto, and stainless steel or an alloy thereof Can be used.

The housing 110 is provided with a curved head cap 111 at the lower front end, and the head cap 111 seals the lower opening to prevent coolant inflow and protects the target rod from the flow velocity.

The housing 110 has a locking end 112 protruding in a radial direction at the upper opening end, and is fixed to the upper fixing body of the nuclear fuel assembly by the locking end 112 so that the housing 110 is a guide tube. It is placed in the insert.

The housing 110 accommodates one or a plurality of irradiation targets 120, and the irradiation target may have various shapes within a range capable of minimizing self-shielding. For example, the irradiation target 120 may be in the form of a pellet having a small size, and a specific embodiment thereof will be described again with reference to the related drawings.

There is a fixing part 130 for closing the upper opening of the housing 110, and the fixing part 130 may be fixed to the housing 110 by welding. Preferably, an elastic body 131 for elastically supporting the irradiation target 120 may be added in the housing 110, and such an elastic body 131 may be provided by a coil spring, in order to minimize loss of reactivity. It can be designed to introduce hazardous coolant.

The housing 110 has a certain length L1, and specifically, the length of the housing 110 may be determined so that it is located in the center of the active core height of the nuclear fuel assembly, and for this, refer to the related drawings. Will be described again.

2(a)(b)(c)(d) and 3(a)(b) are views showing various modifications of an irradiation target according to an embodiment of the present invention, and FIG. 2(a) (b) (c) and (d) are longitudinal and cross-sectional configurations of the irradiation target, respectively.

Referring to Figure 2 (a) (b) (c) (d), each irradiation target 220, 320, 420, 520 has various types of Co-59 (221) (321) (421) It includes (521), and may include a single or double structure can (can) to protect Co-59. In this case, aluminum or stainless steel may be used as the material of the can. On the other hand, a coating layer of Ni material may be added to protect the surface of Co-59.

3A, 3B, and 3B show a cross-sectional configuration diagram of the irradiation target, respectively, and the Co-59 (621, 721) may be in the form of a long rod or a slab.

The target rod 100 configured as described above may be loaded in a light water reactor type reactor, and a Co-60 radioactive isotope may be generated by a neutron flux generated during the operation of the reactor.

Standard light water reactors operating in Korea include the OPR1000 type with an output of 1000MW and the APR1400 type with an output of 1400 MW, and use enriched uranium as the nuclear fuel that generates electricity.

A nuclear fuel assembly consisting of a bundle of nuclear fuels is located in the core of a nuclear reactor where nuclear fuel is located and fission takes place.

4 is a configuration diagram of a nuclear fuel assembly in which a target rod of the present invention is installed, wherein the nuclear fuel assembly includes a plurality of fuel rods 10 arranged in a grid form, a plurality of support grids 20 for fixing the fuel rods 10, and , The guide pipe 30 to form a skeleton structure by fixing the support grids 20, and the upper fixing body 40 and the lower fixing body respectively fixed to the upper and lower ends of the guide pipe 30 to support the load Includes 50.

5 is a plan view showing a support grid of a nuclear fuel assembly of a standard domestic light water reactor type reactor. The support grid 20 is composed of an inner grid plate 21 and an inner grid plate 22 and 23, and the inner grid plate 23 ( In 23), a plurality of vertical grating plates 21 and horizontal grating plates 22 are assembled in a 16x16 square lattice shape, so that 236 fuel rods are located in each lattice cell. In addition, the support grid 20 is provided with one measurement tube sleeve 24 in the center and four guide tube sleeves 25 around it, and the measurement tube sleeve 24 and the guide tube sleeve 25 are each It is assembled by means of a measuring pipe, a guide pipe, and welding, etc. The measuring pipe is provided to load the in-furnace measuring instrument, and the guide pipe is used to insert or withdraw the control rod.

Meanwhile, in the case of the APR1400 type reactor among standard light water reactors, 93 control rod assemblies can be inserted in the core, and each control rod assembly has 12 or 4 control rods. The total number of nuclear fuel assemblies in the core of the APR1400 type is 241, and there are 4 guide tubes per nuclear fuel assembly, so even though the guide tube into which the control rod assembly is inserted and the guide tube required for loading the source bar are excluded, some empty and surplus guide tubes exist. , The target rod of the present invention is characterized in that it is loaded in the surplus guide tube of the nuclear fuel assembly. Hereinafter, the "excess guide tube" refers to a guide tube into which the control rod assembly or the source rod is not inserted.

Referring to FIG. 4 again, the upper stationary body 40 includes a flow path plate 41 that supports the vertical motion load of the nuclear fuel assembly, a central column 42 connected to the measurement tube 60, and a guide tube 30. ), and a coil spring 45 that is inserted into each of the outer pillars 43 and supported by a pressing plate 44 at the top to provide a reaction force to the flow path plate 41. Includes.

The target rod 100 is inserted along the outer pillar 43 connected to the guide tube 30, and at this time, the locking end 112 of the target rod 100 is in the end cap 43a of the upper end of the outer pillar 43. It is caught and settled.

The target rod 100 is loaded in the surplus guide tube 30 in the nuclear fuel assembly of the core, and preferably, the irradiation target 120 is located in the center of the core, for example,

It is preferable that the irradiation target 120 is positioned at a height of 1/2 of the effective core height (L). As described above, since the irradiation target 120 is disposed at a height located in the center of the effective core height of the nuclear fuel assembly, it is advantageous for core safety.

In general, for mass production of Co-60, the irradiation target of Co-59 should be burned in a nuclear reactor for at least 1 to 1.5 years at a place with high neutron flux, which is the core cycle length of 15 in a light-water reactor. It is possible to manage approximately the same as ~18 months, so it is possible to recover the target rod during the nuclear fuel replacement cycle.

In addition, the target rod of the present invention has the advantage of being able to insert and withdraw into the guide tube through the same equipment and procedures as the conventional sailor rod without structural changes or additional installation structures of the conventional light water reactor type reactor.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those who have the knowledge of.

10: fuel rod 20: support grid
30: guide tube 40: upper fixture
50: lower fixture 60: measuring tube
100: target rod 110: housing
111: head cap 112: locking end
120: irradiation target 130: fixed portion
131: elastic body

Claims (4)

As a method of generating Co-60 radioactive isotopes in a light water reactor type reactor,
A method of manufacturing Co-60 radioactive isotopes by neutron flux generated during operation by loading a Co-59 target in an excess guide tube among guide tubes provided in a nuclear fuel assembly of a light water reactor type reactor. The method of claim 1, wherein the Co-59 target is recovered in a replacement cycle. A housing having a hollow cylindrical shape, having a curved head cap at one end and a locking end protruding outwardly at the other end;
An irradiation target made of a radioactive isotope Co-59 housed in the housing;
A target rod for producing CO-60 radiation isotopes comprising a fixing portion fixed to the housing to support an elastic body that provides a reaction force to the irradiation target housed in the housing. The target rod of claim 3, wherein the irradiation target further comprises a can for enclosing and protecting Co-59.

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