KR101349134B1 - Bed apparatus for evaluating a seismic performance of a nuclear fuel assembly - Google Patents

Abstract

The present invention relates to a bed apparatus for evaluating the seismic performance of the fuel assembly for simulating the situation where the fuel assembly is exposed to the earthquake in the lateral direction, the test bed unit is provided to be slidably movable to the ground so that the fuel assembly is seated position 110; A driving unit 120 formed of a waveform control unit 121 capable of linear movement and a rotation driving unit 122 rotating the waveform control unit 121 to be adjacent to the test bed unit 110; It is composed of a drive arm 130 which connects the test bed unit 110 and the waveform control unit 121 to transfer the driving force generated in the drive unit 120 to the test bed unit 110, a wide frequency Various types of seismic simulations are possible for the region, which can effectively evaluate the seismic performance of the fuel assembly.

Description

Bed apparatus for evaluating a seismic performance of a nuclear fuel assembly

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bed apparatus for evaluating the seismic performance of a fuel assembly, and more particularly, to a bed apparatus for seismic performance evaluation of a fuel assembly for simulating a situation in which the fuel assembly is exposed to an earthquake in the transverse direction.

A nuclear reactor is a device for artificially controlling the fission reaction of a fissile material and using thermal energy generated from fission as a power source.

Nuclear fuel used in nuclear reactors is manufactured by forming concentrated uranium into cylindrical pellets of a certain size, and then charging a plurality of pellets into fuel rods. After the fuel rods form a fuel assembly, they are loaded into the reactor core. Combustion occurs through nuclear reactions.

The fuel assembly includes a support grid 10 into which a fuel rod is inserted, a guide tube 20 fixed to the support grid 10, and an upper stationary body 30 fastened to the upper end of the guide tube 20 and the support grid 10. It includes a lower fixing body 40 is fastened to the lower side, the fuel rod is supported by a dimple and a spring provided in the support grid 10.

Such fuel assemblies may be affected by an external force generated during an earthquake occurring at the site of a nuclear power plant or a loss of coolant in a reactor coolant system, and the fuel assembly must be safely maintained even under the expected external force. do.

In particular, the fuel assembly is an important structure composed of a plurality of support gratings for supporting the assembly while inducing an effective cooling water flow to maintain an appropriate operating temperature together with a nuclear fuel rod bundle in which fission occurs. In the event of an accident such as an earthquake, it is very important that the structures constituting the fuel assembly remain stable without interference.

Therefore, structural analysis and testing should be conducted for various situations such as earthquake and loss of coolant to ensure structural integrity of fuel assembly.

For example, Japanese Patent Application Laid-Open No. 2001-0076571 (published date: August 16, 2001) discloses a nuclear reactor inside a nuclear reactor for securing structural integrity by improving structural weaknesses related to nuclear fuel control rods due to earthquake loads in addition to the flow of coolant in a PWR reactor. As the structure is proposed, a great deal of effort is put into securing the structural stability of the reactor internal structure.

As another example, Korean Patent Laid-Open Publication No. 10-2010-0076623 (published: 2010.07.06) proposes an impact tester for a support grid of a nuclear fuel assembly that enables an impact test to be performed at room temperature or a high temperature environment.

As such, the design of the reactor requires various structural analysis and various tests and evaluations of the unit structure to secure structural integrity.

The present invention is to provide a bed apparatus for evaluating the seismic performance of the fuel assembly for simulating the situation where the fuel assembly is exposed to the earthquake in the transverse direction in order to evaluate the seismic performance of the fuel assembly in consideration of these matters.

The bed apparatus for evaluating the seismic performance of the nuclear fuel assembly according to the present invention for achieving the above object comprises: a test bed unit which is slidably movable with respect to the ground so that the nuclear fuel assembly is seated; A driving unit comprising a waveform control unit capable of linear movement and a rotation drive unit for rotating the waveform control unit and positioned adjacent to the test bed unit; It is achieved by a drive arm connecting the test bed unit and the waveform control unit to transfer the driving force generated in the drive unit to the test bed unit.

Preferably, in the present invention, the drive arm is characterized in that connected to the universal joint, more preferably, the drive arm is characterized in that the axially rotatable shaft bearing is added.

Also preferably, in the present invention, a plurality of rolling bearings may be provided on the bottom of the test bed to be slidable with respect to the ground.

Preferably, in the present invention, the waveform control unit is a linear motor to drive the end of the drive arm in a straight line, the rotation drive unit is characterized in that the drive motor provided to be perpendicular to the ground to drive the rotation.

The bed apparatus for evaluating the seismic performance of the nuclear fuel assembly according to the present invention includes a test bed unit that is slidable to the ground with a test object seated thereon, a drive unit including a waveform control unit and a rotational drive unit, and transmitting driving force to the test bed unit. It is composed of a driving arm for, it is possible to simulate various types of seismic waves has the effect that an effective seismic performance evaluation for the fuel assembly can be made.

In addition, the bed apparatus for evaluating the seismic performance of the nuclear fuel assembly according to the present invention uses the electric drive motor and the linear motor instead of the hydraulic drive source, the waveform control unit and the rotary drive unit, the excitation for a wider frequency range than the hydraulic drive source There are advantages to it.

1 is a view showing a general nuclear fuel assembly,
2 is a view showing a bed apparatus for evaluating the seismic performance of the fuel assembly according to the present invention,
Figure 3 shows a preferred embodiment of the drive unit in the bed apparatus according to the present invention.
4 is a view showing a preferred embodiment of the driving arm in the bed apparatus according to the present invention;
5 is a cross-sectional view taken along the line AA of FIG. 3.

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

Referring to Figure 1, the bed apparatus for evaluating the seismic performance of the fuel assembly of the present invention, the test bed unit 110 is provided to be slidably movable with respect to the ground to the nuclear fuel assembly seating position; A driving unit 120 formed of a waveform control unit 121 capable of linear movement and a rotation driving unit 122 rotating the waveform control unit 121 to be adjacent to the test bed unit 110; The driving bed 130 is connected to the test bed unit 110 and the waveform control unit 121 to transfer the driving force generated in the drive unit 120 to the test bed unit 110, characterized in that do.

The test bed unit 110 includes a bed body 111 in which a plurality of rolling bearings 111a are provided at a lower portion thereof, where the fuel assembly is located, and a vertical body 112 vertically provided at one end of the bed body 111. The test bed part 110 may be slidably movable with respect to the ground by the rolling bearing 111a provided under the bed body 111.

In the present invention, rolling bearings can be used in a variety of well-known bearings, such as ball bearings, roller bearings, air bearings within the range that the test bed can be freely slid in the horizontal direction with respect to the ground, the object to be seated (fuel assembly) The type, shape or number of bearings can be determined in various ways in consideration of the load.

In addition, although the bearing is installed on the bottom of the test bed in this embodiment, the bearing may be installed on the ground so that the test bed may be slid in the lateral direction.

The driving unit 120 provides a driving force so that the test bed unit 110 can be moved in the horizontal direction.

Specifically, referring to FIG. 3, the driving unit 120 is provided on the fixed plate 120a fixed to the ground perpendicularly to the rotation driving unit 122 which is rotated by a motor, and provided on the rotation driving unit 122 to the linear motor. By the drive arm can be configured as a waveform control unit 121 that can be linearly driven.

In the present invention, the rotation drive unit 122 may be provided by a drive motor, and a cycloidal gear may be used for high deceleration.

The driving unit 120 may determine the excitation frequency acting on the test bed unit 110 through the movable arm by the rotational movement made by the rotation driving unit 122, and according to the position (displacement) of the waveform adjusting unit 121. The excitation width of the test bed portion 110 can be determined.

Therefore, in the present invention, by controlling the waveform control unit 121 and the rotation drive unit 122 driven by the motor appropriately, it is possible to simulate the shape (profile) of various seismic waves in a wide frequency range, in particular, the motor By using it, it is possible to adjust the wide frequency range compared with the hydraulic drive source, and it has economic advantages.

The driving arm 130 is for transmitting the driving force generated in the driving unit 120 to the test bed unit 110, in particular, in the present invention, the driving arm 130 is a universal for controlling the magnitude of the vibration waveform and the accurate transmission of the driving force It would be desirable to connect to the joint 133.

Specifically, referring to FIG. 4, the driving arm 130 has a first driving arm 131 connected to the test bed part, a second driving arm 132 connected to the waveform adjusting part, and a first driving arm ( 131 and the second driving arm 132 are connected to the universal joint 133.

A support frame 134 may be added to the first driving arm 131 connected to the test bed unit, and the support frame 134 guides the lateral movement while supporting the first driving arm 131.

Also preferably, in the present invention, the drive arm 130 may be prevented from generating an axial torsion during operation of the drive arm by the addition of a shaft bearing rotatable in the axial direction.

Specifically, referring to FIG. 5, the first driving arm 131 includes an inner shaft 131a connected to the test bed, an outer shaft 131b connected to the second driving arm by a universal joint, and an inner shaft 131a. ) And the shaft bearing 131c provided between the outer shaft 131b.

The first drive arm 131 is provided with an axial bearing 131c, so that the inner shaft 131a and the outer shaft 131b can be rotated in the axial direction, thereby preventing the axial twist from occurring when the driving arm is driven. Can be.

Such a shaft bearing may be provided in the second driving arm 132 in the same manner.

As described above, the bed apparatus for evaluating the seismic performance of the nuclear fuel rod assembly of the present invention configured to oscillate the test bed unit 110 in the transverse direction through the driving arm 130 is operated on the target (fuel assembly). Seismic performance can be evaluated by simulating lateral earthquake conditions.

Particularly, in the present invention, the driving unit 130 includes a waveform control unit 121 for driving a straight line and a rotation drive unit 122 driving the waveform control unit 121 to rotate. By controlling the width, it is possible to simulate various types of seismic waves, and there is an advantage in that it is possible to have an economical and wide frequency range by using a motor instead of a hydraulic driving source.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

110: test bed portion 120: drive portion
121: waveform control unit 122: rotation drive unit
130: driving arm

Claims (5)

A plurality of rolling bearings (111a) is provided in the lower portion to be slidably movable with respect to the ground, the bed body 111 where the fuel assembly is located, and the vertical body 112 is provided perpendicular to one end of the bed body 111 A test bed unit 110 formed of the test bed unit 110;
It is provided on the waveform control unit 121 is a linear motor by a linear motor and a fixed plate (120a) which is positioned adjacent to the test bed unit 110 and is fixed to the ground perpendicular to the drive motor provided with a cycloid gear A driving unit 120 including a rotation driving unit 122 driving the waveform adjusting unit 121 to rotate;
By connecting the vertical body 112 and the waveform control unit 121 to transfer the driving force generated in the drive unit 120 to the test bed unit 110, the drive arm 130 is connected to the universal joint Bed apparatus for evaluating the seismic performance of the fuel assembly, including; delete The bed apparatus of claim 1, wherein the drive arm (130) is provided with an axially rotatable shaft bearing. delete delete

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