KR102085529B1 - Pluck vibration test system for mock fuel assembly using tongs - Google Patents

Abstract

The present invention relates, in particular, to a vibration test system provided with means for towing a fuel assembly to an exact position and immediately detaching the housing; A plurality of displacement sensors (60) installed at different positions along the longitudinal direction of the housing (50) to capture horizontal displacement of the nuclear fuel assembly; A band-like material for binding the simulated fuel assembly N, the fixed fixture 40 being variable together with the simulated fuel assembly N by wrapping the body of the simulated fuel assembly N; It is composed of an exciter 30 to add vibration to the fixed fixture 40 and the simulated fuel assembly (N) by towing the fixed jig 40 to release the traction, the center of the fixed jig 40 A stop projection 422 is formed to protrude toward 30, and the excitation device 30 has a gripping mechanism for holding the stop projection 422 and a push mechanism for pushing the stop projection 422 to stop the stop projection 422. It is installed in the form of protruding in parallel to the direction, the stop projection 422 is formed to have a constant area or width so that both the end of the gripping mechanism and the push mechanism in contact with the front, the gripping mechanism gripping the stop projection 422 When the exciter 30 pulls the stop protrusion 422, the fixture jig 40, and the simulated fuel assembly N while the push mechanism pushes the stop protrusion 422, the gripping state due to the grip mechanism is changed. Nuclear fuel assembly characterized by immediate release The pluck to provide a vibration test system.

Description

Pluck vibration test system for mock fuel assembly using tongs}

The present invention relates to a vibration test system for a simulated fuel assembly, and more particularly, to a vibration test system provided with means for pulling a fuel assembly to an exact position and then immediately detaching it.

The nuclear fuel loaded in the reactor is designed to satisfy the seismic performance against earthquake and other accidents. Recently, the Nuclear Regulatory Commission (NRC) issued a view on the seismic degradation of End of Life (EO L) fuels based on AREVA's reporting data [Ref. 1] We urged suppliers to take countermeasures for reducing the stiffness and support grid strength of nuclear fuels exposed to high temperature coolant conditions for a long time, and mentioned that detailed explanations are needed for future licenses. The seismic performance was evaluated for the initial fuel rate, but it is necessary to evaluate the EOL fuel in the future.

Most recently, WEC's testing and evaluation method with APlOOO nuclear fuel under EOL is known to have been approved by the NRC. WEC was able to secure seismic margins by adding aquatic attenuation as a way to compensate for the structural integrity of EOL fuels. In the case of AREVA, WEC also introduced submarine attenuation to promote EPR nuclear power plant licensing.

Meanwhile, the EOL condition was excluded from the seismic analysis method performed by KNF (Korea Nuclear Fuel), and it is in the process of establishing the application of the current methodology by recognizing the necessity of evaluating the nuclear seismic performance and securing the mechanical integrity in the EOL condition. The support grid under EOL condition is considered to be vulnerable to external impact due to chemical changes such as corrosion, hydrogen embrittlement, and gap between cladding tube and spring / dimple.

Therefore, simulation equipment for seismic analysis is being developed. Among them, Patent Publication No. 10-1349134 (Registration Date: 2014. 01. 02) of the prior art shown in Figure 1 'bed apparatus for seismic performance evaluation of the fuel assembly' is a situation where the fuel assembly is exposed to the lateral vibration A bed apparatus for evaluating the seismic performance of a nuclear fuel assembly for simulating, comprising: a test bed unit which is slidably movable with respect to the ground, on which a nuclear fuel assembly is seated, a linearly movable waveform control unit, and a rotation drive unit for rotating the waveform control unit. It consists of a drive unit adjacent to the test bed unit, the drive arm 130 for 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. By configuring as described above, it is possible to simulate various types of seismic waves over a wide frequency range, so that an effective seismic performance evaluation of the fuel assembly can be made.

However, the prior art has a problem that it is difficult to accurately follow the free vibration in real time in the case of the nuclear fuel assembly is installed long in the vertical direction because the driving arm is continuously connected to the bed portion during the vibration process, it is difficult to make accurate measurements.

In addition, looking at the 'test apparatus for analyzing the support behavior and vibration characteristics of the nuclear fuel rod support patent registration No. 10-0306537 (Registration date: August 1, 2001) shown in Figure 2, in the longitudinal direction on the bottom surface Jig-mounted tank, heater installed on the side of the tank, support grid fixed on the jig to support fuel rod, shock device to impact fuel rod supported on support grid, laser displacement meter for measuring displacement of nuclear fuel rod, tank Consists of a controller that measures and controls the internal temperature and analyzes the measured data, so that the vibration characteristics of the fuel rod, which is formed as long as the real one, can be measured, but the fuel rod is not actually measured in the vertical direction. As a result, the behavior is not measured in the actual installation state.

And many of the prior art because the vibration characteristics are measured by the measuring equipment formed to a height corresponding to the length of the fuel assembly, there is a problem that a considerable cost is required to manufacture and build the facility itself for the vibration characteristics of the fuel assembly.

Therefore, the vibration characteristics of the fuel assembly installed in the rising fluid while being upright as in the real state with a simple configuration can be checked, and the vibration addition method to the fuel assembly can be checked without any external restraint after the vibration is added. And a technique in which free vibration of the support grid itself can be measured so that the vibration characteristics of the accurate fuel assembly and the support grid can be checked.

Registered Patent Publication No. 10-1349134 (Registration Date: 2014. 01. 02)

Registered Patent Publication No. 10-0306537 (Registration Date: Aug. 01, 2001)

Accordingly, the present invention is to improve the problems of the prior art, it is possible to check the vibration characteristics of the nuclear fuel assembly, which has a simple configuration and installed in the ascending fluid while being upright as in reality, The pluck vibration test system of the simulated fuel assembly, in which the vibration addition method is configured to measure the free vibration of the fuel assembly and the support grid itself without any external restraint after vibration addition, so that the vibration characteristics of the fuel assembly and the support grid can be checked accurately. To provide.

The pluck vibration test system of the simulation fuel assembly using the clasp according to the present invention for achieving the above object is a simulated fuel assembly manufactured for the seismic test of the support grid (S) of the fuel assembly consisting of a combination of the fuel rod and the support grid (S). A vibration test system for the seismic performance test of (N), wherein the simulated fuel assembly (N) is made vertically long so that it can be tightly embedded, and is fixed invariably and fixedly installed, and the housing (50). A plurality of displacement sensors (60) installed one at a different position along the longitudinal direction of the trap to capture in real time a horizontal displacement of the nuclear fuel assembly;

As a band-shaped material consisting of a rigid member for binding the simulated fuel assembly (N), by wrapping the body of the simulated fuel assembly (N), the fixed jig (40) variable with the simulated fuel assembly (N), and the It is composed of an exciter 30 to pull the fixture jig 40 to release the traction to add vibration to the fixture jig and the simulated fuel assembly, the stop projection protruding toward the exciter 30 in the center of the fixture jig 422 is formed, the exciter 30 is installed in a form in which the gripping mechanism for holding the stop projection 422 and the push mechanism for pushing the stop projection 422 protrude in parallel toward the stop projection 422, The stopper projection 422 is formed to have a predetermined area or width so that both ends of the gripping mechanism and the push mechanism are in contact with the front surface, and the gripping mechanism is variable by holding the stopper protrusion 422, thereby providing an exciter 30. ) Pulls the stop projection 422 and the fixture jig 40 and the simulated fuel assembly N, and the push mechanism pushes the stop projection 422 to release the grip state caused by the gripping mechanism, thereby simulating the nuclear fuel assembly N. It is characterized in that the vibration is added to.

Here, the gripping mechanism is preferably a gripping body 36, two clasps 362 fixedly coupled to both sides of the gripping body 36 and holding or releasing both sides of the stop projection 422, and the clasp A first power transmission member 31 for advancing or retracting 362 in the direction of the stop projection, wherein the push mechanism includes a detent 35 for pushing or retracting against the front of the stop projection 422; It consists of a second power transmission member 32 for advancing or retracting the detent 35 in the direction of the detent projection 422.

In addition, both sides of the stopper 422 is preferably formed with two clasps and projections engaging one by one, and the clasps are formed with wings extending in a direction in which two clasps face each other at the ends of the two clasps so as to engage with the projections. The contact surface contacting the extension blade and the projection one by one is formed in a direction away from the exciter as the angle formed by the two contact surfaces gets closer to the center of the stop projection. When pushed with a constant force, it is a sliding protrusion formed to slide out of the latches on both sides.

In the gripping mechanism, the gripping body 36 is preferably formed with a first screw groove in which a screw thread is formed on the inner circumferential surface of the gripping body 36 in the longitudinal direction, and the first power transmission member is long and is threaded from one end to a predetermined length. A clasp drive rotary shaft 31 formed on the outer circumferential surface and an incision surface is formed from an opposite end to a predetermined length so that one end is inserted into the gripping screw groove, and a hollow into which the opposite end of the clasp drive rotary shaft 31 is inserted The clasp drive handle 38 is formed in the grip body 36 is moved forward or backward in accordance with the rotation of the clasp drive handle 38, the detent 35 in the push mechanism is the length of the detent 35 A second screw groove is formed in the center along the direction of the thread is formed on the inner peripheral surface, the second power transmission member is formed long so that the thread is formed on the outer peripheral surface from one end to a certain length and the opposite end To a predetermined length, a clasp drive handle having a detent surface formed with a detent driving rotary shaft 32 into which one end is inserted into the push mechanism screw groove, and a hollow into which an end on the opposite side of the detent driving rotary shaft 32 is inserted. (37), the detent (35) moves forward or backward as the latch drive handle (37) rotates.

In addition, the gripping body is preferably formed with a first rail groove along the longitudinal direction, the detent is formed with a second rail groove along the longitudinal direction, the first rail inserted into the first rail groove is formed long inside An inner sealing case in which a first chamber to be formed, a second chamber inserted into a second rail groove, and a second chamber having a long length formed therein are formed in parallel with each other, a flange tube surrounding the outside of the inner sealing case, and a flange tube By forming an outer sealing case formed integrally with the flange formed at one end of the flange and tightly coupled to the housing, the clasp and the detent may be operated in a watertight manner.

The pluck vibration test system of the simulated nuclear fuel assembly using the clasp according to the present invention has a simple configuration and can be checked the vibration characteristics of the nuclear fuel assembly which is installed in the rising fluid while being upright as in the case of the vertical assembly. The vibration adding method is configured to measure the free vibration of the fuel assembly and the support grid itself without any external restraint after the vibration addition, so that the vibration characteristics of the fuel assembly and the support grid can be checked accurately.

1 and 2 is a view showing a conventional nuclear fuel assembly vibration measurement technology,
3 is a perspective view of a nuclear fuel assembly equipped with a vibration test system according to the present invention;
4 is a side view of FIG. 3;
5 is a perspective view of one side of the excitation unit in FIG. 3;
6 is a perspective view of the other side of FIG.
7 is an exploded perspective view of FIG. 6, FIG.
8 is a side cross-sectional view of an installation state of a vibration test system according to the present invention;
9 is a plan sectional view of FIG. 8;
FIG. 10 is a perspective view illustrating a coupling part and a fixing jig of FIG. 5;

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

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

3 and 5, the pluck vibration test system according to the present invention includes a housing 50 in which a simulated fuel assembly N is embedded, a displacement sensor 60, a fixture jig, and an exciter. It consists of 30.

The housing 50 has a watertight structure so that the fluid can be filled therein so that the fluid-induced vibration test can be made in the same state as the actual environment in the state where the simulated fuel assembly N is embedded, and the simulated fuel assembly N is embedded. It is manufactured in the form of a chamber that is made vertically long as the simulated fuel assembly (N) so that it can be.

Displacement sensor 60 (LVDT, linear variable differential transformer) is also referred to as inductive displacement sensor 60 by using an induction phenomenon, it is used to measure the horizontal displacement of the fuel assembly (N). The displacement sensor 60 converts the displacement into an electrical signal when the simulated fuel assembly N is vibrated.

Fixture jig 40 is in the form as shown in Figure 5, in the form of a band that is bound to the mock fuel assembly (N) in the form of surrounding the outside of the mock fuel assembly (N) that is the assembly of the simulated fuel rod and support grid (S). As the rigid member, the excitation portion 30 coupled with the excitation portion 30 which will be described later is brought into contact with the fixing jig 40 to add vibration to the simulated fuel assembly N, thereby towing the fixing jig 40. It adds vibration in the form of rapidly disconnecting the contact.

The exciter 30 pulls the fixture jig 40 and releases traction to add vibration to the fixture jig 40 and the simulated nuclear fuel assembly N. To this end, a stop projection 422 protruding toward the exciter 30 is formed at the center of the fixture jig 40, and a grip mechanism and a stop projection 422 gripping the stop projection 422 are formed on the exciter 30. Push mechanism for pushing the is installed in the form protruding in parallel toward the stop projection (422).

Here, as shown in FIGS. 5 and 6, the stop protrusion 422 is formed to have a constant area or width such that both ends of the gripping mechanism and the push mechanism are in contact with each other. That is, when both the gripping mechanism and the push mechanism are horizontally disposed, the stop projection 422 is also formed to be horizontally long, and as shown in FIG. 5, when the gripping mechanism and the push mechanism are installed up and down in parallel, the stop projection 422 is also illustrated. As in 5, it is formed to have a long width up and down.

Then, the holding mechanism is gripped by the stop protrusion 422 and is variable, so that the exciter 30 pulls the stop protrusion 422, the fixture jig 40, and the simulated fuel assembly N, and the push mechanism stops the stop protrusion 422. ), The gripping state due to the gripping mechanism is immediately released, thereby adding vibration to the simulated fuel assembly (N).

Hereinafter, the coupling mechanism of the gripping mechanism and the push mechanism and the stop protrusion 422 will be described in detail.

As shown in FIGS. 5 and 6, the gripping mechanism is fixed to the gripping body 36 and two sides of the gripping body 36 one by one, and two clasps for gripping or releasing both sides of the stop protrusion 422 ( 362 and a first power transmission member 31 for advancing or retracting the clasp 362 in the direction of the stop projection, and the push mechanism contacts the front of the stop projection 422 to push or retract the detent ( 35 and a second power transmission member 32 for advancing or retracting the detent 35 in the direction of the detent projection 422.

In this case, as shown in FIG. 5, both sides of the stop protrusion 422 are formed with protrusions that engage with the two clasps 362, and the clasps 362 have two ends at the ends of the two clasps 362 so as to engage with the protrusions. Extension blades 361 are formed in the direction in which the clasps 362 face each other, but the contact surface where the extension blades 361 and the protrusions come into contact with each other is closer to the center of the stop protrusion as the angle formed by the two contact surfaces 30 The protrusion is formed in a direction away from the sliding projections formed so that the detent 35 slides out of the latches on both sides when the detent 35 pushes the detent projection 422 with a constant force while the protrusion and the latch 362 are engaged. 423).

That is, when the extension blade 361 is caught by the sliding protrusion 423 so that the exciter 30 is retracted in a direction away from the simulated fuel assembly N, the fixed jig 40 for binding the simulated fuel assembly N is provided. The simulated nuclear fuel assembly N is towed together by the exciter 30, wherein the angle of contact between the sliding protrusion 423 and the extension blade 361 is perpendicular to the forward direction of the exciter 30. After the extension blades 361 are applied to the sliding protrusions 423, the sliding protrusions 423 and the extension blades 361 are not separated from each other and can only be moved together, and the vibrator 30 is applied to the simulated fuel assembly N. You cannot add vibration.

Therefore, in the present invention, the contact surface angle formed by contacting the sliding protrusion 423 and the extension blade 361 is small in FIG. The point of meeting is the direction toward the simulated fuel assembly (N).

Thus, when the detent 35 pushes the stop projection 422 with a force of a certain intensity or more, the sliding protrusion 423 and the extension blade 361 are separated from each other while the contact surface slides, and the shaker 30 and the fixture jig 40 are separated. Vibration is added to the simulated fuel assembly N as the contact between them is immediately disconnected.

On the other hand, during the operation of the gripping mechanism and the push mechanism, the leakage between the vibrator 30 and the housing 50 due to the operation of the gripping mechanism or push mechanism should be prevented. Thus, inner and outer sealed cases are provided surrounding the gripping mechanism and the push mechanism. In addition, in order to prevent such leakage, leakage may occur if the external device is operated in a forward or backward direction toward the simulated fuel assembly N, which is a variable direction of the gripping mechanism and the push mechanism itself when the gripping mechanism or the push mechanism is operated. Thus, the steering of the gripping mechanism and the push mechanism outside the housing 50 should not be in the forward or backward direction. This will be described in more detail below.

As illustrated in FIG. 7, the gripping body 36 has a first screw groove (not shown) in which threads are formed on an inner circumferential surface thereof in a longitudinal direction thereof.

Here, the first power transmission member is formed long, the screw thread is formed on the outer circumferential surface from one end to a certain length to form a screw section 312 and the incision surface 311 is formed along the length direction from the opposite end to a predetermined length of the screw The clasp drive handle 38 having a hollow formed therein so that the clasp drive rotation shaft 31 into which the section 312 is inserted into the first screw groove (not shown) and the opposite end where the incision surface 311 is formed can be inserted. ), The grip body 36 is moved forward or backward in accordance with the rotation of the latch drive handle 38.

In the push mechanism, the detent 35 is formed with a second screw groove (not shown) in which a thread is formed on the inner circumferential surface of the detent 35 along the longitudinal direction of the detent 35.

Here, the second power transmission member is formed long and the thread is formed on the outer circumferential surface from one end to a predetermined length to form a screw section 322 and the incision surface 321 is formed along the length direction from the opposite end to the predetermined length of the screw. A detent drive handle having a hollow formed therein for insertion of a detent drive rotary shaft 32 into which a section 322 is inserted into a second screw groove (not shown), and an opposite end formed with an incision surface 321. (37), the detent (35) is advanced or retracted in accordance with the rotation of the detent drive handle (37).

As such, the rotational movement of the clasp drive handle 38 or the detent drive handle 37 is converted to the forward or backward movement of the grip body 36 or the detent 35, whereby the clasp drive handle 38 or the detent drive handle (37) The surroundings can be kept tight and the operation is easily configured.

In this case, the inner sealing case 34 and the outer sealing case 33 are provided so that the forward and backward movements of the detent 35 and the gripping body 36 can be made more smoothly and the watertightness can be maintained.

Specifically, as shown in FIG. 7, the grip body 36 has a first rail groove 361 formed in the longitudinal direction, and the detent 35 has a second rail groove 351 formed along the longitudinal direction. A first chamber 343 having a first rail 3431 inserted into the first rail groove 361 and a second rail 3342 inserted into the second rail groove 351 is formed therein. The second chamber 342, which is elongated, is formed in the inner sealing case 34 formed in parallel with each other, the flange tube 332 surrounding the outside of the inner sealing case 34, and the edge of one end of the flange tube 332. The outer sealing case 33 formed by integrally forming the flange 331 which is formed and tightly coupled to the housing 50 is installed, so that the grip body 36 and the detent 35 are operated in a watertight manner.

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

N: simulated fuel assembly S: support grid
30: excitation part 31: latch drive rotation shaft
32: detent drive rotary shaft 33: outer sealed case
34: internal sealing case 35: detent
36: holding body 40: fixed jig
41 body support band 42: binding band
50 housing 60 displacement sensor
311,321: Incision surface 312,322: Screw section
313,323: sealing disc 314, 324: sealing seal
315,325 Front bearings 316,326 Rear bearings
331: flange 332: flange tube
333: cover disc 342: second chamber
343: first chamber 351: second rail groove
361: first rail groove 362: latch
411: fastening end 421: bolt fastener
422: stop protrusion 423: sliding protrusion
3421: Second rail 3431: First rail

Claims (5)

A vibration test system for seismic performance test of a simulated fuel assembly (N) manufactured for a support grid (S) seismic test of a nuclear fuel assembly composed of a combination of a nuclear fuel rod and a support grid (S),
A housing 50 which is manufactured vertically long so that the simulated fuel assembly N can be tightly embedded therein and is fixedly fixed;
A plurality of displacement sensors (60) installed at different positions along the longitudinal direction of the housing (50) and capturing a horizontal displacement of the nuclear fuel assembly in real time;
A band-like material composed of a rigid member for binding the simulated nuclear fuel assembly (N), the fixed jig (40) variable with the simulated nuclear fuel assembly (N) by wrapping the body of the simulated nuclear fuel assembly (N);
The exciter is installed to penetrate the housing 50 at the position where the fixing jig 40 is installed, and the vibration is added to the simulated nuclear fuel assembly N by releasing the fixing jig 40 in a horizontal direction by a predetermined length and then releasing it. Consisting of 30;
In the center of the fixture jig 40 is formed a stop projection 422 protruding toward the exciter 30, the exciter 30 is a gripping mechanism and a stop projection 422 gripping the stop projection 422 Pushing push mechanism is installed in the form of protruding in parallel toward the stop projection 422,
The stop projection 422 is formed to have a constant area or width so that both the end of the gripping mechanism and the push mechanism in contact with the front,
The gripping mechanism grips and stops the stop protrusion 422 so that the exciter 30 pulls the stop protrusion 422, the fixture jig 40, and the simulated fuel assembly N, while the push mechanism stops the stop protrusion 422. Puck vibration test system of the simulation fuel assembly using the clasp, characterized in that the vibration is added to the simulated fuel assembly (N) by the release of the gripping state due to the holding mechanism immediately. The method of claim 1,
The gripping mechanism is fixed to the gripping body 36, one side of the gripping body 36, two clasps 362 for holding or releasing both sides of the stop projection 422, and the clasp 362 It consists of a first power transmission member 31 for advancing or retracting in the direction of the stopping projection,
The push mechanism includes a detent 35 for pushing or retracting in contact with the front of the detent projection 422 and a second power transmission member 32 for advancing or retracting the detent 35 in the direction of the detent projection 422. Pluck vibration test system of the simulation fuel assembly using the clasp, characterized in that consisting of. The method of claim 2,
On both sides of the stopper 422, two latches 362 are formed with projections that engage one by one, and the latches 362 have two clasps 362 at the ends of the two clasps 362 to engage with the projections. Extending wing 361 is formed in the viewing direction,
The contact surface contacting the extension blades 361 and the projections one by one is formed in a direction away from the exciter 30 as the angle formed by the two contact surfaces gets closer to the center of the stop projection, whereby the projection is engaged with the projection 362. Pluck vibration test of the simulated nuclear fuel assembly using the clasp, characterized in that the detent (35) is a sliding protrusion (423) which is formed to slide out of the clasp on both sides when the detent (35) pushes the detent projection (422) with a constant force. system. The method of claim 3,
In the gripping mechanism, the gripping body 36 is formed with a first screw groove in which a screw thread is formed on an inner circumferential surface thereof in a longitudinal direction thereof.
The first power transmission member is formed long and the clasp driving rotary shaft 31 is formed in the outer peripheral surface from one end to a predetermined length and the incision surface is formed from the opposite side end to a predetermined length is inserted into the gripping screw screw groove, and, Consists of a clasp drive handle 38 is formed therein is a hollow in which the opposite end of the clasp drive rotation shaft 31 is inserted, the grip body 36 is moved forward or backward in accordance with the rotation of the clasp drive handle 38,
In the push mechanism, the detent 35 is formed with a second screw groove in which a screw thread is formed on the inner circumferential surface at the center thereof in the longitudinal direction of the detent 35,
The second power transmission member is formed long, the end of the screw thread is formed on the outer circumferential surface from one end to a certain length, and a cut-off surface is formed from the opposite end to a predetermined length end is inserted into the push mechanism screw groove 32 and , The hollow is inserted into the opposite end of the detent drive rotary shaft 32 is formed of the clasp drive handle 37, the detent 35 is moved forward or backward in accordance with the rotation of the clasp drive handle 37 Pluck vibration test system of the simulation fuel assembly using the clasp. The method of claim 4, wherein
A first rail groove 361 is formed in the gripping body 36 along the longitudinal direction, and a second rail groove 351 is formed in the pawl 35 along the longitudinal direction.
The first chamber 343 having a first rail 3431 inserted into the first rail groove 361 and the second rail 3342 inserted into the second rail groove 351 is long therein. An inner sealing case 34 having a second chamber 342 formed therein in parallel with each other;
An outer sealing case formed by integrally forming a flange tube 332 surrounding the outside of the inner sealing case 34 and a flange 331 formed at an edge of one end of the flange tube 332 to be tightly coupled to the housing 50. 33 is installed,
Pluck vibration test system of the simulation fuel assembly using the clasp, characterized in that the gripping body (36) and the detent (35) is made of water tightly.

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