KR20230072609A - Component inserted in Guide Tubes with forced disengagement mechanism of a Nuclear Fuel Assembly - Google Patents

Abstract

The present invention relates to an insert inserted into a guide tube provided in a nuclear fuel assembly of a light water reactor type nuclear reactor, and more particularly, to a radioactive isotope such as Co-60 using a neutron source of a nuclear fuel assembly or a neutron flux generated during operation. It relates to a guide tube insert for accommodating a target for production, which has a hollow cylindrical shape, a lower housing having a curved head cap 111 at one end and accommodating a target for generating a neutron source or radioactive isotope. (110) and; an upper housing 120 connected to the lower housing via a connector member; a guide member 130 provided at an upper end of the upper housing 120 and having at least two or more guide slots 131 cut in the longitudinal direction from the upper open end; an inner core 140 inserted into the lower end of the guide member 130 and fixed to the upper end of the upper housing 120 to guide the vertical sliding of the guide member 130; A fitting part 150 including a plurality of elastic pieces 151 inserted into the guide member 130 and having a lower end fixed to the inner core 140 and having elasticity in a radial direction corresponding to the guide slot 131 )and; It includes an upper core 160 inserted into the fitting part 150 to press the elastic piece 151 in an outer diameter direction, and each elastic piece 151 of the fitting part 150 has a protruding engaging end ( 151a), and a protruding protrusion 151b located at the lower end of the first holding end 151b.

Description

Component inserted in Guide Tubes with forced disengagement mechanism of a Nuclear Fuel Assembly

The present invention relates to an insert inserted into a guide tube provided in a nuclear fuel assembly of a light water reactor type nuclear reactor, and more particularly, to a radioactive isotope such as Co-60 using a neutron source of a nuclear fuel assembly or a neutron flux generated during operation. It relates to a guide tube insert intended to receive a target for production.

Co-60, a radioactive isotope, is a radioactive isotope with a half-life of 5.2 years. It emits powerful gamma rays and is widely used as a cheap gamma-ray source instead of radium. There is a wide range of applications and high demand, such as sterilization and sterilization.

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

In heavy water reactors, Co-59 targets can be used instead of control rods that absorb surplus neutrons without affecting the output stability of the reactor, so Co-60 produced in Canada, the originator of heavy water reactor technology, is in global demand. Currently supplying most of

In the case of pressurized water reactors, which account for most of commercial nuclear reactors, Co-60 was not used for production due to sufficient supply of Co-60 from existing heavy water reactors. I'm going.

Patent Document 1: Registered Patent Publication No. 10-1502414 (Public date: 2015.03.13.)

Accordingly, the present invention relates to an insert inserted into a guide tube provided in a nuclear fuel assembly of a light water reactor type nuclear reactor, for producing a radioactive isotope such as Co-60 using a neutron source of a nuclear fuel assembly or a neutron flux generated during operation. It is an object to provide a guide tube insert to receive a target.

A guide tube insert for a nuclear fuel assembly according to the present invention for achieving this object has a hollow cylindrical shape, a lower housing having a curved head cap at one end and accommodating a neutron source or a target for generating radioactive isotopes. class; an upper housing connected to the lower housing via a connector member; a guide member provided at an upper end of the upper housing and having at least two or more guide slots cut in the longitudinal direction from the upper open end; an inner core inserted into a lower end of the guide member and fixed to an upper end of the upper housing to guide vertical sliding of the guide member; a fitting part including a plurality of elastic pieces inserted into the guide member, having a lower end fixed to the inner core, and having elasticity in a radial direction corresponding to the guide slot; An upper core inserted into the fitting part to press the elastic piece in an outer diameter direction, and each elastic piece of the fitting part includes a protruding protrusion to be inserted into a groove formed in an upper screw of the top fixture. .

Preferably, the fitting part has a pressing protrusion protruding inward from the upper opening end.

Preferably, each elastic piece of the fitting part further includes a locking end protruding from an upper end of the locking protrusion and seated on an upper portion of an upper screw of the upper end fixture.

A guide tube insert for a nuclear fuel assembly according to the present invention includes a lower housing accommodating a neutron source or a target for generating radioactive isotopes, and an upper housing connected to the lower housing via a connector member; a guide member provided at an upper end of the upper housing and having at least two or more guide slots cut in the longitudinal direction from the upper open end; an inner core inserted into the lower end of the guide member and fixed to the upper end of the upper housing to guide the up and down sliding of the guide member; a fitting part including a plurality of elastic pieces inserted into the guide member and having a lower end fixed to the inner core and having elasticity in a radial direction corresponding to the guide slot; It includes an upper core inserted into the fitting part to press the elastic piece in the outer diameter direction, and each elastic piece of the fitting part protrudes and includes a protrusion that is fitted into a groove formed in the upper screw of the top fixture to insert a guide tube. During insertion and withdrawal of the sieve, no separate work is required to fix or unfix the guide tube insert, and the guide tube insert can be naturally fixed and released during insertion and withdrawal.

1 is a perspective configuration diagram of a guide tube insert according to an embodiment of the present invention.
2 is an enlarged cross-sectional view of a main part of a guide tube insert according to an embodiment of the present invention.
3 is a cross-sectional view showing the installation of an upper end of a guide tube of an upper end fixture for a nuclear fuel assembly.
Figure 4 (a) is a side configuration diagram of the upper end of the guide tube insert according to an embodiment of the present invention, (b) (c) is a cross-sectional configuration diagram showing an operation example, respectively.

Specific structural or functional descriptions presented in the embodiments of the present invention are merely exemplified for the purpose of explaining 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 interpreted as being limited to the embodiments described in this specification, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and scope of the present invention.

Meanwhile, terms used in this specification are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as "comprise" or "having" are intended to indicate that there is an embodied feature, number, step, operation, component, part, or combination thereof, but one or more other features or numbers, It should be understood that the presence or addition of steps, operations, components, parts, or combinations thereof is not precluded.

The guide tube insert of the present invention may be a neutron source rod inserted into the guide tube, or a target rod for generating radioactive isotopes using a guide tube of a nuclear fuel assembly for a light water reactor. For example, in the case of an APR1400 type reactor among standard light water reactors, 93 control rod assemblies can be inserted into 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 each fuel assembly has 4 guide tubes. Even excluding the guide tubes into which the control rod assemblies are inserted and the guide tubes required for loading the source rods, some empty guide tubes exist. And, the guide tube insert of the present invention is characterized in that it is loaded into the redundant guide tube of the nuclear fuel assembly. Hereinafter, "excess guide tube" refers to a guide tube into which the control rod assembly or the source rod is not inserted. On the other hand, the source rod is pressurized by an insert tube after being loaded into the nuclear fuel assembly to secure a sufficient pressing force during operation of the nuclear reactor, but the insertion tube applied to the surplus guide tube is opened up and down to remove the guide tube insert. I have a problem that I can't press enough. Accordingly, the present invention is characterized by providing a means capable of securing sufficient pressing force of the guide tube insert itself in order to utilize the surplus guide tube of the nuclear fuel assembly. Hereinafter, referring to the accompanying drawings, embodiments of the present invention In detail, it is as follows.

1 is a perspective configuration view of a guide tube insert according to an embodiment of the present invention, and FIG. 2 is an enlarged cross-sectional view of a main part of the guide tube insert according to an embodiment of the present invention.

1 and 2, the guide tube insert 100 of this embodiment includes a lower housing 110, an upper housing 120, a guide member 130, an inner core 140, and a fitting part 150. , and an upper core 160.

The lower housing 110 has a hollow cylindrical shape, and a curved head cap 111 is provided at a lower front end, and a target for generating a neutron source or radioactive isotope is accommodated. The head cap 111 serves to seal the lower opening of the lower housing 110 to prevent the inflow of coolant and to protect the target rod assembly from flow velocity. The irradiation target includes a target for generating a radioisotope, and may be, for example, a Co-59 target for generating a CO-60 radioisotope. Such an irradiation target may include a single or double structured can or capsule.

The upper housing 120 is connected to the lower housing 110 via a connector member 112 . For example, the connector member 112 may be screwed together with the lower housing 110 and the upper housing 120 to connect the lower housing 110 and the upper housing 120 .

The guide member 130 is provided at the top of the upper housing 120 and slides up and down along the inner core 140, and has at least two or more guide slots 131 cut in the longitudinal direction from the top opening end, Preferably, it has an elastic restoring force in an inward direction. In this embodiment, the guide slot 131 has an angle of 90° and is shown as an example that is composed of four.

The inner core 140 is inserted into the guide member 130, welded and fixed to the upper end of the upper housing 120, and a groove for fixing the fitting part 150 is formed along the outer circumferential surface at the lower end.

The fitting part 150 is inserted into the guide member 130 and has a lower end fixed to the inner core 140, and a plurality of elastic pieces 151 having elasticity in a radial direction corresponding to the guide slot 131 includes A hook 152 fitted and fixed to the groove of the inner core 140 may be formed at a lower end of the fitting part 150 .

Preferably, each elastic piece 151 of the fitting part 150 includes a protruding hooking end 151a and a protruding protrusion 151b located at the lower end of the first engaging end 151b in the inner diameter direction. It has elasticity in the inward direction.

More preferably, the fitting part 150 has a pressing protrusion 151c protruding inward from the upper open end.

The upper core 160 is inserted into the upper opening of the fitting part 150 and serves to press the elastic piece 151 in the outer diameter direction.

FIG. 3 is a cross-sectional view showing the top of the guide tube of the top fixture for nuclear fuel assembly installed. In general, the top fixture 10 of the nuclear fuel assembly is of the inner insertion tube 12 inserted into the outer guide column 11. The lower end is directly fastened to the guide tube, and the upper end of the inner insertion tube 12 is fixed by the upper screw 13. Reference numeral 14 is a pressure plate and reference numeral 15 is a pressure spring. On the other hand, the upper screw 13 of the upper fixing body 10 has a groove 13a drawn into a certain section A on the inner diameter, and the guide tube insert according to the embodiment of the present invention has an upper screw 13 It is characterized in that the locking is performed using the groove (13a) provided in, and the locking process of the guide tube insert will be described below with reference to FIG.

Figure 4 (a) is a side configuration diagram of the top of the guide tube insert according to an embodiment of the present invention, (b) (c) is a cross-sectional configuration diagram showing an example of operation, respectively.

Referring to FIG. 4 , after the guide tube insert of the present invention configured as described above is loaded into a guide tube (not shown), the upper core 160 comes down and presses the guide member 130 to the upper side of the fitting part 150. In this process, the pressing protrusion 151c of the fitting part 150 is pressed, so that the upper opening of the fitting part 150 opens outward, and the holding protrusion 151b is attached to the upper screw 13. It is inserted into the groove (13a) (see Fig. 3) and the guide tube insert is fixed to the top fixture. In (b) and (c) of FIG. 4, a and b indicate the outer diameter of the fitting part 150 before and after the upper core 160 is inserted, and indicate the outer diameter before and after insertion (a) and the outer diameter (b) after insertion. (a < b). On the other hand, while the guide tube insert is fixed to the upper fixing body, the locking end 151a is seated on the upper end of the upper screw 13.

On the other hand, the process of withdrawing the guide tube insert is a process in reverse order. When the upper core 160 is withdrawn, the guide member 130 is restored to the inward direction, and the fitting part 150 also shrinks inward to screw the upper screw. As the locking protrusion 151b inserted into the groove of (13) is removed, the guide tube insert can be withdrawn from the fuel assembly.

The guiding tube insert of the present invention does not require a separate operation to fix or release the guiding tube insert during the insertion and withdrawal process, and the guiding tube insert is naturally fixed and unfixed during the insertion and withdrawal process. .

The present invention described above is not limited by the foregoing embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible within a range that does not deviate from the technical spirit of the present invention. will be clear to those who have knowledge of For example, in this embodiment, a target rod for generating a radioactive isotope has been described as an example, but the guide tube insert of the present invention can be equally applied to a neutron source rod for accommodating a neutron source.

110: lower housing 120: upper housing
130: guide member 140: inner core
150: fitting part 151a: engaging end
151b: stumbling protrusion 151c: pressing protrusion
160: upper core

Claims (3)

a lower housing having a hollow cylindrical shape, provided with a curved head cap at one end, and accommodating a neutron source or a target for generating radioactive isotopes;
an upper housing connected to the lower housing via a connector member;
a guide member provided at an upper end of the upper housing and having at least two or more guide slots cut in the longitudinal direction from the upper open end;
an inner core inserted into the lower end of the guide member and fixed to the upper end of the upper housing to guide the up and down sliding of the guide member;
a fitting part including a plurality of elastic pieces inserted into the guide member, having a lower end fixed to the inner core, and having elasticity in a radial direction corresponding to the guide slot;
An upper core inserted into the fitting part to press the elastic piece in an outer diameter direction;
The guide tube insert of the nuclear fuel assembly including a locking protrusion in which each elastic piece of the fitting part protrudes and is fitted into a groove formed in an upper screw of the upper end fixture. The guide tube insert for a nuclear fuel assembly according to claim 1, wherein the fitting part has a pressure protrusion protruding inward from an upper open end thereof. The guide tube insert of claim 1, wherein each elastic piece of the fitting part further comprises a hooking end protruding from an upper end of the hooking protrusion and seated on an upper part of an upper screw of the upper end fixture.

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