KR101143370B1 - Apparatus for impact test of nuclear fuel assembly - Google Patents

Abstract

The fuel assembly impact test apparatus according to the present invention is configured to fix the fuel assembly in a position spaced upward from the ground, and to mechanically release the fuel assembly during the impact test of the fuel assembly so that the fuel assembly is freely dropped.
Specifically, the present invention, the ball is fixed to the top of the nuclear fuel assembly; And a clamp part configured to fix the ball to be spaced upwardly from the ground, and to remove the ball in the impact test of the fuel assembly so that the fuel assembly falls freely, wherein the clamp part is spaced upward from the ground. Vertical bars fixed to the top plate; An inner cylinder disposed at a lower end of the vertical bar and having a receiving groove in which the head of the ball is inserted and received upward; A fixing member disposed in a horizontal hole radially formed on a sidewall of the receiving groove, the fixing member having a diameter larger than the length of the horizontal hole; And an outer cylinder which is movable upward and downward while surrounding the inner cylinder and has a release groove formed along an inner circumferential surface thereof, wherein the inner wall of the outer cylinder pushes the fixing member toward the center to press and fix the head of the ball. When the outer cylinder is moved upward, the release groove which is located at the lower side of the fixing member is moved upward and the fixing member is moved radially as the fixing member is introduced into the release groove, so that the head of the ball is removed from the inner cylinder to free fall. It is configured to.

Description

Apparatus for impact test of nuclear fuel assembly}

The present invention relates to a nuclear fuel assembly impact test apparatus, and in performing a shock characteristic test to evaluate the integrity of a nuclear fuel assembly structure due to a drop, it relates to a nuclear fuel assembly impact test apparatus using a simple mechanical mechanism.

A nuclear fuel assembly is charged to the core of the pressurized light reactor, and the nuclear fuel assembly includes a plurality of fuel rod bundles into which a cylindrical uranium sintered body is inserted.

The fuel assembly is a structural component composed of an upper fixing body, a lower fixing body, a support grid, a guide tube, and a measuring tube, and functions to resist all loads received by the fuel.

At this time, the upper stationary body is composed of the upper flow path plate, hole down spring, the diaphragm and when handling the nuclear fuel to fix the upper stationary body with a handling tool to perform the loading and withdrawal to the core.

During this process, the nuclear fuel is separated from the handling tool and free-falls, or excessive hydraulic flotation occurs due to overspeed during the transition of the coolant pump, which causes the fuel assembly to become a lower core plate. An accident that can be lifted and dropped from the vehicle can occur.

Under these accident conditions, axial impact tests are conducted to assess the integrity of the fuel assembly.

The axial impact test is a test for identifying the impact characteristics of the fuel assembly through the relationship between the impact force and the drop height when the fuel assembly is lifted at a constant drop height and then released to the rigid body to impact the rigid surface. to be.

1 is a view showing a cylindrical nuclear fuel assembly, Figure 2 is an enlarged view showing the upper end of the cylindrical fuel assembly of Figure 1;

Referring to the drawings, the fuel assembly 10 includes a nuclear fuel rod 1, a support grid 2, a guide tube 3, an upper fixing body 4 and a lower fixing body 5.

At this time, the upper fixing body 4 is composed of a hole down spring (6), a hole down plate (7), an upper flow path plate (8) and a central guide column (9).

3 is a view showing a conventional test apparatus for impact test using the explosives of the cylindrical fuel assembly of FIG.

Referring to the drawings, the test apparatus is a device for performing a test by fixing a wire to a thick plate capable of vertical displacement of the nuclear fuel assembly and exploding the wire to separate the heavy plate and the fuel assembly.

A device that performs an axial impact test of a fuel assembly using such explosives can perform a rigorous and relatively simple test in many respects.

However, the axial impact test of a fuel assembly must be carried out about 20 times on one fuel assembly, which requires a number of explosive devices in view of the fact that explosives cannot be used over and over again. There is a limitation in terms of cost that can be quite uneconomical.

The present invention has been made to solve the above problems, and in performing the impact characteristic test to evaluate the integrity of the nuclear fuel assembly structure by the drop, providing a nuclear fuel assembly impact test apparatus using a simple mechanical mechanism Its purpose is to.

In order to achieve the above object, the nuclear fuel assembly impact test apparatus according to a preferred embodiment of the present invention, the nuclear fuel assembly is positioned up spaced apart from the ground, and mechanically unlock the fuel assembly during the impact test of the fuel assembly The fuel assembly is configured to free fall.

Specifically, the present invention, the ball is fixed to the top of the nuclear fuel assembly; And a clamp unit configured to fix the ball to be spaced upward from the ground, and to remove the ball in the impact test of the fuel assembly so that the fuel assembly falls freely.

Here, the clamp unit, a vertical bar fixed to the upper plate spaced upward from the ground; An inner cylinder disposed at a lower end of the vertical bar and having a receiving groove in which the head of the ball is inserted and received upward; A fixing member disposed in a horizontal hole radially formed on a sidewall of the receiving groove, the fixing member having a diameter larger than the length of the horizontal hole; And an outer cylinder which is movable upward and downward while surrounding the inner cylinder and has a release groove formed along an inner circumferential surface thereof, wherein the inner wall of the outer cylinder pushes the fixing member toward the center to press and fix the head of the ball. When the outer cylinder is moved upward, the release groove which is located at the lower side of the fixing member is moved upward and the fixing member is moved radially as the fixing member is introduced into the release groove, so that the head of the ball is removed from the inner cylinder to free fall. It is preferably configured to.

In addition, in the present invention, it is preferable that a locking groove is formed along the outer circumferential surface of the head of the ball, and the fixing member is inserted into the locking groove so that the fixing member presses and fixes the head of the ball.

At this time, the fixing member is preferably a ball (ball).

In addition, the clamp unit, the slide member is disposed on the upper side of the inner cylinder in the vertical bar, the movable movable member while wrapping the vertical bar; And a connecting member connecting the slide member and the outer cylinder, wherein the outer cylinder is configured to slide up and down with respect to the inner cylinder according to upper and lower slides of the slide member.

The clamp part further includes a lever having one end fastened to the slide member and disposed in the transverse direction and having a portion closer to one end than the other end connected to the upper plate, the lever being lowered to the other end of the lever. When applying a force, it is preferable that the slide member is moved upward.

In addition, the clamp unit may further include an elastic member provided between the upper plate and the slide member to apply a downward elastic force to the slide member.

On the other hand, the vertical bar is installed in the upper plate so as to pass through the upper plate, and has a vertical hole in communication with the receiving groove of the inner cylinder, the clamp portion is disposed through the vertical hole of the vertical bar, the lower end is It is preferable to further include a wire connected to the head of the ball and the upper end is connected to the lifting device capable of lifting the ball.

The clamp unit may further include a stopper mounted at a portion of the wire spaced apart from the vertical bar and configured to be caught by an upper end of the vertical bar when the wire is lowered, such that a downward impact of the fuel assembly is attenuated by the ball. It is desirable to.

Nuclear fuel assembly impact test apparatus according to the present invention, because the mechanical mechanism is used, its structure is simple and economical in terms of cost, and with this effect it is easy and simple to perform the impact test of the fuel assembly. In addition, the impact test of the nuclear fuel assembly can be performed without environmental pollution by explosives.

In addition, the present invention can be carried out a semi-infinite repeated test by fixing the nuclear fuel assembly at a certain height and taking a mechanical structure that allows instant removal during the impact test. This makes it possible to perform the test efficiently since about 20 tests have to be carried out on one fuel assembly.

In addition, the present invention can be temporarily released to reduce the time loss in positioning another fuel assembly in the inner cylinder after the fuel assembly free fall.

1 illustrates a cylindrical fuel assembly.
FIG. 2 is an enlarged view illustrating an upper end fixture of the cylindrical fuel assembly of FIG. 1.
3 is a view showing a conventional test apparatus for impact test using the explosives of the cylindrical nuclear fuel assembly of FIG.
4 is a view showing a nuclear fuel assembly impact test apparatus according to a preferred embodiment of the present invention.
5 is a view showing a ball in the nuclear fuel assembly impact test apparatus of FIG.
6 is a view showing the inner cylinder in the nuclear fuel assembly impact test apparatus of FIG.
FIG. 7 is a view illustrating an outer cylinder in the nuclear fuel assembly impact test apparatus of FIG. 4.
8 is a view showing that the outer cylinder is moved downward relative to the inner cylinder in the nuclear fuel assembly impact test apparatus of FIG.
9 is a view showing that the outer cylinder is moved upward with respect to the inner cylinder in the nuclear fuel assembly impact test apparatus of FIG.
10 is a view showing that the lever is further included in the nuclear fuel assembly impact test apparatus of FIG.

The present invention is characterized in that the fuel assembly is positioned to be spaced apart from the ground and spaced apart from the ground, and in the impact test of the fuel assembly by mechanically unlocking the fuel assembly characterized in that the fuel assembly is configured to free fall.

4 is a view showing a nuclear fuel assembly impact test apparatus according to a preferred embodiment of the present invention.

Specifically, Figure 5 is a view showing a ball in the nuclear fuel assembly impact test apparatus of Figure 4, Figure 6 is a view showing the inner cylinder in the nuclear fuel assembly impact test apparatus of Figure 4, Figure 7 is a nuclear fuel assembly impact test of Figure 4 A diagram showing an external cylinder in the device.

8 is a view showing that the outer cylinder is moved downwards with respect to the inner cylinder in the nuclear fuel assembly impact test apparatus of FIG. 4, and FIG. 9 is a top cylinder moving upward with respect to the inner cylinder in the nuclear fuel assembly impact test apparatus of FIG. It is the figure which showed.

Referring to the drawings, the nuclear fuel assembly impact test apparatus of the present invention includes a ball 30 fixed to the nuclear fuel assembly, and the clamp unit 40 for fixing and removing the ball 30.

The ball 30 is configured to be connected and fixed to the upper portion of the nuclear fuel assembly. Specifically, the ball 30 is fixed to the hole down plate (7 of FIG. 2) of the upper fixture (4 of FIG. 2).

The ball 30 has a head 31 is formed on the top, the head 31 has a locking groove 31a is formed along the outer circumferential surface.

Here, the locking groove 31a is formed so that the fixing member 70, which will be described later, is introduced into the locking groove 31a so that the fixing member 70 presses the head 31 of the ball 30. Detailed description thereof will be described later.

On the other hand, the clamp portion 40 is configured to fix the position of the ball 30 spaced upward from the ground, and selectively removes the ball 30 during the impact test of the nuclear fuel assembly, the ball 30 is configured to free fall. As the ball 30 falls freely as described above, the nuclear fuel assembly fixed to the ball 30 is also freely dropped, and the impact test of the fuel assembly is performed.

In detail, the clamp unit 40 includes a vertical bar 50 fixed to the upper plate 20, an inner cylinder 60 and an outer cylinder 80 installed on the vertical bar 50, and the inner cylinder 60. It includes a fixing member 70 mounted on.

The vertical bar 50 is fixed to the upper plate 20 spaced upward from the ground, at this time is disposed perpendicular to the ground. Here, the vertical bar 50 is fixed to the upper plate 20 by fixing nuts 51 and 52 fitted to upper and lower portions of the upper plate 20.

In addition, the inner cylinder 60 is disposed at the lower end of the vertical bar 50, the vertical bar 50 is inserted downward in the upper fastening groove 60a is preferably screwed.

The inner cylinder 60 has a receiving groove 60b in which the head 31 of the ball 30 is inserted and received upward. At this time, the receiving groove (60b) has a size that is accommodated in a predetermined portion of the head 31 of the ball 30, the head 31 of the ball (30) accommodated only the shanghaidong shape is not shaken from side to side Has

In addition, the inner cylinder 60 has a horizontal hole (60c) is formed in the radial direction on the side wall of the receiving groove (60b), a plurality of horizontal holes (60c) around the center of the inner cylinder 60 a predetermined interval It is preferably formed to be spaced apart.

The fixing member 70 having a diameter larger than the length of the horizontal hole 60c is disposed in the horizontal hole 60c. At this time, the fixing member 70 is preferably a ball (ball) is utilized.

The fixing member 70 is pushed by the outer cylinder 80 is moved in the center direction to fix the ball 30, when the outer cylinder 80 is moved upward, there is no force to push the fixing member 70 inside The ball received in the cylinder 60 is moved downward in the radial direction under the downward pressure by the weight of the ball 30.

In addition, the outer cylinder 80 is configured to be movable up and down while wrapping the inner cylinder (60). At this time, the outer cylinder 80 is moved up and down the slide with the slide member 91 by the connecting member 92 to be described later, a detailed description thereof will be described later.

In addition, the outer cylinder 80 has a release groove (80a) is formed along the inner circumferential surface, the release groove (80a) takes the structure that the fixing member 70 is drawn in a predetermined portion.

Due to the structure of the inner cylinder 60 having the fixing member 70 such as a ball as described above and the outer cylinder 80 installed in the inner cylinder 60, the head 31 is accommodated in the inner cylinder 60 The ball 30 to be positioned and can be selectively removed.

Specifically, when the head 31 of the ball 30 accommodated in the receiving groove 60b of the inner cylinder 60 is fixed, as shown in FIG. 8, the inner wall of the outer cylinder 80 is fixed member 70. ) By pressing the head 31 of the ball 30 in the center direction.

And, as shown in Figure 9, when the outer cylinder 80 is moved upward, the release groove (80a) of the outer cylinder 80, which is located below the fixing member 70 is also moved upward, thereby fixing The member 70 is moved radially as it enters the release groove 80a, and as a result, the head 31 of the ball 30 is removed from the inner cylinder 60 so that the ball 30 falls.

This allows the nuclear fuel assembly fixed to the lower portion of the ball 30 to free fall downward.

On the other hand, the clamp unit 40 includes a slide member 91 which slides up and down while surrounding the vertical bar 50, and a connection member 92 connected downward to the slide member 91.

The slide member 91 is disposed above the inner cylinder 60 in the vertical bar 50 and is configured to be movable while wrapping the vertical bar 50.

In addition, the connecting member 92 is fixed to an extension part extending outward from the slide member 91 and the outer cylinder 80 so as to connect the slide member 91 and the outer cylinder 80 in the vertical direction. A structure is arranged.

As a result, the outer cylinder 80 slides up and down with respect to the inner cylinder 60 according to the upper and lower slides of the slide member 91.

And, as shown in Figure 9, the clamp portion 40 is disposed in the transverse direction as one end is fastened to the slide member 91, a portion closer to the one end side than the other end to the top plate 20 It may further include a connection fixed lever 93.

Accordingly, when a downward force is applied to the other end of the lever 93, the slide member 91 is moved upward, and as a result, the outer cylinder 80 slides upward with respect to the inner cylinder 60.

As the slide member 91, the connection member 92, and the lever 93 is configured as described above, it is possible to adjust the shanghaidong of the outer cylinder (80) from a distance.

That is, by applying a force above a certain distance from the outer cylinder 80 at a predetermined distance or more, the shanghaidong of the outer cylinder 80 is made, it is possible to safely remove the position of the ball 30 fixed by this Allow free fall of the nuclear fuel assembly.

In addition, the clamp portion 40 further includes an elastic member 94 provided between the upper plate 20 and the slide member 91 to apply a downward elastic force to the slide member (91).

The elastic member 94 may move the slide member 91 moved upward again downward by a predetermined distance so that the outer cylinder 80 reaches its original position, that is, the position where the fixing member 70 is pressed in the center direction. have.

In addition, the vertical bar 50 is installed in the upper plate 20 so as to pass through the upper plate 20, and has a vertical hole (50a) in upward communication with the receiving groove (60b) of the inner cylinder 60, wherein the clamp portion 40 includes a wire 95 disposed through the vertical hole 50a of the vertical bar 50.

Here, the wire 95 has a lower end connected to the head 31 of the ball 30 and the upper end is connected to a lifting device capable of lifting the ball 30.

Accordingly, when the head 31 of the ball 30 is fastened to the inner cylinder 60, the ball 30 fixed to the nuclear fuel assembly can be raised by an appropriate height for the impact test.

In addition, the clamp portion 40 is mounted on a portion of the wire 95 spaced apart from the vertical bar 50, and further includes a stopper 96 configured to be caught by the upper end of the vertical bar 50 when descending. desirable.

The stopper 96 acts to attenuate the downward impact of the nuclear fuel assembly by the ball 30 when the nuclear fuel assembly falls freely and hits the lower rigid body.

The present invention, which is configured as described above, is economical in terms of cost due to its simple structure due to the use of a mechanical mechanism, and can easily and simply perform an impact test of the nuclear fuel assembly. In addition, the impact test of the nuclear fuel assembly can be performed without environmental pollution by explosives.

In addition, the present invention can be carried out a semi-infinite repeated test by fixing the nuclear fuel assembly at a certain height and taking a mechanical structure that allows instant removal during the impact test. This makes it possible to perform the test efficiently since about 20 tests have to be carried out on one fuel assembly.

In addition, the present invention can be temporarily released to reduce the time loss in positioning the nuclear fuel assembly after the fuel assembly is free-falling.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

20: top 31: head
31a: locking groove 40: clamp portion
50: vertical bar 50a: vertical hole
51, 52: fixing nut 60: inner cylinder
60a: fastening groove 60b: receiving groove
60c: horizontal hole 70: fixing member
80: outer cylinder 80a: release groove
91: slide member 92: connecting member
93: lever 94: elastic member
95: wire 96: stopper

Claims (10)

delete delete A ball anchored to the top of the fuel assembly; And
Fixing the position spaced upwards from the ground, the clamp assembly is configured to remove the ball during the impact test of the fuel assembly to free fall the fuel assembly,
The clamp unit,
A vertical bar fixed to the upper plate spaced upwardly from the ground;
An inner cylinder disposed at a lower end of the vertical bar and having a receiving groove in which the head of the ball is inserted and received upward;
A fixing member disposed in a horizontal hole radially formed on a sidewall of the receiving groove, the fixing member having a diameter larger than the length of the horizontal hole; And
And an outer cylinder which is movable upward and downward while surrounding the inner cylinder and has a release groove formed along an inner circumferential surface thereof.
The inner wall of the outer cylinder pushes the fixing member toward the center to press and fix the head of the ball, and when the outer cylinder is moved upward, the release groove located at the lower side of the fixing member is moved upward to move the fixing member. The nuclear fuel assembly impact test apparatus, characterized in that the head of the ball is removed from the inner cylinder to free fall as it is moved radially while entering the release groove.
The method of claim 3,
The head of the ball is formed with a engaging groove is formed along the outer circumferential surface, the fixing member is introduced into the locking groove, the fixing member is a nuclear fuel assembly impact test apparatus, characterized in that for pressing the head of the ball fixed.
The method of claim 3,
The stationary member is a nuclear fuel assembly impact test apparatus, characterized in that the ball (ball).
The method of claim 3,
The clamp unit,
A slide member disposed above the inner cylinder in the vertical bar, the slide member being movable while surrounding the vertical bar; And
Further comprising: a connecting member for connecting the slide member and the outer cylinder,
A nuclear fuel assembly impact test apparatus, characterized in that the outer cylinder is slide up and down with respect to the inner cylinder in accordance with the vertical slide of the slide member.
The method of claim 6,
The clamp unit,
One end portion is fastened to the slide member is disposed in the transverse direction, the portion closer to the one end side than the other end portion is fixed to the upper plate;
And applying a downward force to the other end of the lever, wherein the slide member is moved upward.
The method of claim 6,
The clamp unit,
An elastic member provided between the upper plate and the slide member to apply a downward elastic force to the slide member;
Nuclear fuel assembly impact test device further comprising.
The method according to any one of claims 3 to 8,
The vertical bar is installed in the upper plate so as to pass through the upper plate, and has a vertical hole in communication with the receiving groove of the inner cylinder,
The clamp unit,
A wire disposed through a vertical hole of the vertical bar, and having a lower end connected to a head of the ball and an upper end connected to a lifting device capable of lifting the ball;
Nuclear fuel assembly impact test device further comprising.
10. The method of claim 9,
The clamp unit,
A stopper mounted at a portion of the wire spaced apart from the vertical bar and configured to be caught by an upper end of the vertical bar when descending;
A nuclear fuel assembly impact test apparatus, characterized in that for reducing the downward impact of the fuel assembly by the ball.

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