KR20120126292A - Heat load unit and hydrogen reorientation testing apparatus of spent nuclear fuel having the same - Google Patents

Abstract

PURPOSE: A thermal load unit and hydrogenation rearrangement examination apparatus including the same are provided to shield the exposure of radiation by constructing the shielding unit of a polyimide material. CONSTITUTION: A heating unit(31) includes an insertion space for receiving specimen including used nuclear fuel. The heating unit heats the specimen. A shielding unit(34) supports the heating unit. A pressure unit provides pressure to the specimen. The shielding unit includes polyimide materials. A heating body is composed of insulation materials and includes the insertion space. A heat loading unit includes a plurality of shielding films.

Description

Heat load unit and apparatus for testing hydrogen fires of spent nuclear fuel including the same {HEAT LOAD UNIT AND HYDROGEN REORIENTATION TESTING APPARATUS OF SPENT NUCLEAR FUEL HAVING THE SAME}

The present invention relates to a heat load unit and an apparatus for testing hydrogenation of spent fuel including the same, and more particularly, to a heat load unit and a spent fuel including the same, which can create an excellent shielding environment during a hydrogenation test. An array test apparatus.

Nuclear fuels (hereinafter referred to as "used fuels") used as fuels in nuclear reactors are high-level radioactive waste, and require post-treatment. This spent fuel is covered by a tubular cladding tube, thereby minimizing radioactive leakage.

In order to test the hydride rearrangement (H ₂ reorientation) phenomenon of the spent fuel cladding, a test system capable of applying constant pressure and thermal cycling to the spent fuel coated cladding is used. On the other hand, even if the spent fuel is coated by a cladding tube, radiation is emitted during the test. Accordingly, in order to test the hydrogen re-arrangement of the spent fuel, shielding for the spent fuel is essential. Therefore, in addition to the shielding of the spent fuel, there is a continuous demand for research / development of a heat load unit capable of heat load experiments.

The present invention has been made in view of the above problems, and an object thereof is to provide a heat load unit excellent in shielding of radiation emitted from spent fuel.

Another object of the present invention is to provide an apparatus for testing hydrogenation of spent fuel including a heat load unit in which the above object is achieved.

The spent fuel heat load unit for achieving the above object is to test the hydrogen re-arrangement phenomenon of the spent fuel, and has an insertion space into which a test body containing fuel is selectively inserted, and a heating unit for heating the test body. And a shield that surrounds and supports the heating unit to shield the test body, and the shield is formed of a polyimide material.

According to one side, the cross section provided with the insertion space of the heating portion has a hollow cylindrical shape of the ring, the shielding portion has a hollow cylindrical shape having a ring-shaped cross section surrounding the outer circumference of the heating portion.

According to one side, the heating unit, the insertion space is provided, and a heating body formed of a heat insulating material, a plurality of heating bodies are spaced apart at equal intervals in the heating body.

According to one side, the shielding portion is provided with a plurality of shielding thin film formed of lead (Pb) material.

According to one side, to protect the heating portion and the shield includes a protective portion surrounding the outer periphery of the shield.

Hydrogen rearrangement test apparatus for experimenting the hydrogen rearrangement phenomenon of the spent fuel for achieving the object of the present invention, a support unit for supporting a test body containing the spent fuel, a pressurizing unit for providing pressure to the test body And an insertion space for selectively inserting the test body including the spent nuclear fuel, and including a heating part for heating the test body and a shielding part surrounding the test part by surrounding the heating part, wherein the shielding part is made of polyimide. (Polyimde) includes a heat load unit formed of a material, and a control unit for controlling the pressure and temperature of the pressure unit and the heat load unit.

According to one side, it comprises a mobile unit for selectively lifting the heat load unit.

According to the present invention as described above, first, the heat load unit for the hydrogen fuel array test of the spent fuel includes a shield of polyimide material, it is possible to shield the leakage of radiation from the spent fuel during the test. Accordingly, radiation shielding is simultaneously implemented with high temperature heat load, thereby improving test performance and safety.

Second, by minimizing the leakage of radiation from spent fuel, it is possible to minimize the radiation exposure to the peripheral device, thereby contributing to the life of the device.

1 is a perspective view schematically showing an apparatus for testing hydrogenation of spent nuclear fuel according to an embodiment of the present invention, and
FIG. 2 is a cross-sectional view schematically illustrating the heat load unit by cutting along the line II-II of FIG. 1.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Referring to Figure 1, the hydrogen fuel array test apparatus 1 of the spent fuel according to an embodiment of the present invention, the support unit 10, the pressurizing unit 20, the heat load unit 30, the mobile unit ( 40 and a control unit 50.

The support unit 10 supports a test body (T) containing spent fuel. The support unit 10 supports the test body T not to flow, as in a kind of holder.

For reference, the test body (T) is a coated tube covering the spent fuel, hereinafter referred to as test body (T) for convenience of explanation. At this time, the test body (T) has a cylindrical tube shape having a length of about 15 to 20cm.

The pressurizing unit 20 provides a pressure to the test body (T). Specifically, the pressurizing unit 20 applies a gas pressure or hydraulic pressure to the inside of the test body T supported by the support unit 10 to apply a predetermined pressure to the test body T. The pressure unit 20 is provided with a pressure pipe 21 for communicating with the test body (T) supported by the support unit (10). The pressurizing unit 20 tests the leakage of the test body T by applying pressure to the test body T at room temperature. For reference, the pressurizing unit 20 is preferably applied to the test body (T) gas pressure or hydraulic pressure up to a maximum ring stress of 200Mpa.

The heat load unit 30 applies heat to the test body T to test the heat load on the test body T. The heat load unit 30 has a cylindrical shape provided with an insertion space (S) to selectively insert the test body (T), a detailed configuration of such a heat load unit 30 will be described later with reference to FIG.

The mobile unit 40 selectively raises and lowers the heat load unit 30. Specifically, the mobile unit 40 lowers the heat load unit 30 toward the test body T supported by the support unit 10, or moves the heat load unit 30 so as to deviate from the test body T. Elevate. In this embodiment, the mobile unit 40 is exemplified by the hydraulic cylinder is employed to selectively lift the heat load unit 30. However, the present invention is not necessarily limited thereto, and various modified embodiments capable of moving the heat load unit 30 such as a rack / pinion gear are possible.

The control unit 50 controls the pressure and temperature of the pressurizing unit 20 and the heat load unit 30. That is, the control unit 50 controls the pressure and temperature test conditions of the test body T by the pressurizing unit 20 and the heat load unit 30. Specifically, the control unit 50 controls the pressure supplied from the pressurizing unit 20 to the test body T, and maintains the pressure at a set pressure during the test for a long time. In addition, the control unit 50 controls the temperature of the test body (T) to be heated up to 500 ° C. at room temperature, and controls the control rate at the time of cooling or heating to 1 ° C./min to 100 ° C./min. . For reference, the control unit 50 simultaneously controls the pressure and temperature of the pressurizing unit 20 and the heat load unit 30.

Hereinafter, referring to FIG. 2, the configuration of the thermal load unit 30 will be described in detail.

Referring to FIG. 2, the heat load unit 30 includes a heating part 31, a shielding part 34, and a protection part 36.

The heating unit 31 has an insertion space (S) into which the test body (T) containing the spent fuel is selectively inserted, and heats the inserted test body (T). To this end, the heating unit 31 is provided with an insertion space (S) and a plurality of heating bodies 33 are spaced apart at equal intervals in the heating body 32 and the heating body 32 is formed of a heat insulating material. It includes.

Here, the heating body 32 has a hollow cylindrical shape provided with an insertion space (S). Specifically, the heating body 32 has a ring-shaped cross section in which an insertion space S is provided in a substantially central region. At this time, the insertion space (S) is formed to correspond to the test body (T) having a cylindrical tube shape. In addition, the heaters 33 may be spaced apart from each other side by side in the circumferential direction of the insertion space (S), it is preferable to uniformly heat the test body (T) inserted into the insertion space (S).

The shielding part 34 surrounds and supports the heating part 31 to shield the radiation emitted from the test body T. The shielding part 34 has a hollow cylindrical shape having a ring-shaped cross section that surrounds and supports the outer circumference of the heating part 31. The shielding part 34 is formed of a material having excellent shielding properties, and in the present embodiment, it is illustrated that the shielding part 34 is formed of a polyimide material. Here, the polyimide material employed as the shielding part 34 may have a specific gravity of 1/10 of lead (Pb), which is another shielding material, thereby contributing to weight reduction of the heat load unit 30 that is moved up and down. .

On the other hand, the shield 34 is provided with a plurality of shielding thin film 35 formed of a lead (Pb) material to surround the test body (T) at a position spaced from the outer periphery of the insertion space (S) to add shielding force. . In the present embodiment, the shielding thin film 35 is illustrated as three, but is not limited to the illustrated example. At this time, the thickness of the shielding thin film 35 is preferably about 3mm.

For reference, the shielding portion 34 formed of the polyimide material is thermally decomposed at a temperature of approximately 600 degrees, and the plurality of shielding thin films 35 formed of the lead material are thermally decomposed at a temperature of approximately 328 degrees due to material properties. do. Accordingly, even when the shielding thin film 35 is melted during the heat load test of the test body T, the shielding part 34 may implement stable shielding.

The protection part 36 is installed to surround the shielding part 34 to protect the heating part 31 and the shielding part 34. The protection part 36 is installed in close contact with the outer circumference of the shielding part 34, thereby protecting the heating part 31 and the shielding part 34 from external force.

The test method of the spent fuel hydrogen fired array tester 1 according to the present invention having the configuration as described above will be described with reference to FIG.

First, a test body T, which is a cladding tube coated with the spent fuel, is fixed to the support unit 10. Thereafter, the heat load unit 30 is lowered by the mobile unit 40 and the test body T enters the insertion space S. Then, the test body T is pressed and heated by the pressurizing unit 20 and the heat load unit 30. For reference, in the process of heating and cooling the test body T, the volume inside the test body T is expanded and contracted by the temperature change. In order to maintain the annular stress of the test body T, the pressure according to the temperature change is simultaneously controlled by the control unit 50.

On the other hand, the test body (T) inserted into the insertion space (S) of the thermal load unit 30, as shown in Figure 2, as the radiation leakage is shielded by the shielding portion 34 formed of a polyimide material, thermal load Radiation shielding is possible during the test.

Although the present invention has been described with reference to the preferred embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the following claims. It can be understood that

1: spent fuel hydrogen fire arrangement test apparatus 10: support unit
20: pressure unit 30: heat load unit
31: heating part 34: shielding part
40: mobile unit 50: control unit

Claims (7)

In the heat load unit for testing the hydrogen rearrangement phenomenon of spent fuel,
A heating unit having an insertion space into which a test body including the spent fuel is selectively inserted and heating the test body; And
A shield that surrounds and supports the heating unit to shield the test body;
Including;
The shield is a thermal load unit formed of a polyimide (Polyimde) material.
The method of claim 1,
And a hollow cylindrical shape having a ring-shaped cross section having the insertion space of the heating portion, and the shielding portion having a hollow cylindrical shape having a ring-shaped cross section surrounding the outer circumference of the heating portion.
The method of claim 1,
The heating unit includes:
A heating body provided with the insertion space and formed of a heat insulating material;
A plurality of heating bodies spaced apart from each other at equal intervals in the heating body;
Thermal load unit comprising a.
The method of claim 1,
A heat load unit in which the plurality of shielding thin films formed of lead (Pb) is installed in the shield.
The method of claim 1,
A protective part surrounding an outer circumference of the shielding part to protect the heating part and the shielding part;
Thermal load unit comprising a.
In the hydrogen rearrangement test apparatus for experimenting the hydrogen rearrangement phenomenon of spent fuel,
A support unit for supporting a test body including the spent fuel;
A pressurizing unit for providing a pressure to the test body;
A heat load unit according to any one of claims 1 to 5, wherein heat is applied to the test body; And
A control unit for controlling pressure and temperature of the pressurizing unit and the heat load unit;
Hydrogen fire arrangement test apparatus of the spent fuel comprising a.
The method according to claim 6,
Hydrogen fire arrangement test apparatus comprising a mobile unit for selectively lifting the heat load unit.

Images