KR20130141755A - Apparatus for measurement of creep strain on irradiated fuel cladding - Google Patents

Abstract

The present invention relates to an apparatus for measuring creep strain on an irradiated fuel cladding (100) and, more particularly, to an apparatus for measuring creep strain on an irradiated fuel cladding (100), capable of securing the reliability of measurement and safely measuring the creep strain on the irradiated fuel cladding (100) of high radiation.

Description

Apparatus for measurement of creep strain on irradiated fuel cladding}

The present invention relates to an apparatus for measuring the amount of deformation of a nuclear fuel cladding tube, and more particularly, to an apparatus for measuring the amount of deformation of a nuclear fuel cladding tube that can ensure reliability of measurement and can safely measure the creep strain of a high-radiation fuel cladding tube. It is about.

Nuclear fuel used in nuclear power plants is stored and used inside the cladding tube, and the spent fuel cladding tube removes the internal fuel, and then deforms the amount of the fuel cladding tube under constant pressure and temperature to evaluate creep integrity during dry storage. Measure

In this case, the deformation amount may be measured by a contact method using a linear variable differential transformer (LVDT) and a non-contact method using an optical technology such as a laser.

In particular, as a strain measuring device, Republic of Korea Patent No. 0927542 (invention name: interference optical two-dimensional strain measuring device and method) has been proposed, as a displacement measuring device, Korea Patent Publication No. 2010-0042412 (name of the invention) : Displacement measuring devices and displacement measuring monitoring systems which can be used under high temperature and high pressure hydraulic environment have been proposed.

However, the nuclear fuel cladding tube is a high radiation material even when the internal fuel is removed, and it is difficult to use a contact measuring method, and even if it is a non-contact type, it is necessary to measure a long time and different conditions to measure the creep deformation amount. , There is a problem that it is difficult to ensure the safety of the radiation protection of the experimenter.

In addition, the components constituting the measuring device may also cause a decrease in durability due to high radiation, and there is a problem that the measuring reliability may also decrease.

Therefore, while it is possible to easily measure the creep deformation amount of the fuel cladding tube, it is possible to increase the measurement reliability and to develop a device and a method for measuring the strain amount of the fuel cladding tube which can ensure the durability of the test apparatus and the safety of the tester. .

1. Republic of Korea Patent No. 0927542 (Invention name: interference optical two-dimensional strain measurement device and method) 2. Korean Patent Application Publication No. 2010-0042412 (Invention name: Displacement measurement device and displacement measurement monitoring system that can be used under high temperature and high pressure hydraulic environment)

The present invention has been made to solve the problems described above, an object of the present invention is to measure the amount of deformation in the base and the frame that can block radiation and heat, the temperature control unit, the pressure control unit and The optical measuring unit is provided to provide a strain measuring device for a nuclear fuel cladding tube that can safely measure the strain of the nuclear cladding tube.

In particular, an object of the present invention is further provided with a protective tube inside the body to prevent the contamination of the tester body and the peripheral equipment from the radioactive material by scattering the radioactive particles fixed to the inner surface of the cladding during the creep break of the fuel cladding during the measurement It is possible to provide, and to provide a device for measuring the amount of deformation of the nuclear fuel cladding can further improve safety and durability.

In addition, an object of the present invention is the irradiation portion and the collecting portion of the optical measuring unit is wrapped by the shielding portion, by irradiating and collecting the laser beam through the first reflecting portion and the second reflecting portion radiation of the nuclear fuel cladding tube through the first through hole and the second It is to provide an apparatus for measuring the amount of deformation of a nuclear fuel cladding tube that can prevent damage to the irradiation section and the collecting section through the through hole.

In addition, an object of the present invention is to form a temperature evenly in the height direction of the body through the temperature control unit, the nuclear fuel cladding tube to improve the measurement reliability by measuring the temperature of the inner surface of the protective tube or the fuel cladding tube and thereby controlling the heater It is to provide a strain measuring device of.

In addition, an object of the present invention is that the first fixture and the second fixture is formed in the nuclear fuel cladding tube, the second fixture is fixed by the base portion or the body at the lower side, by being fixed by a fixing block for fixing the first fixture in the upper side To provide a nuclear fuel cladding strain measuring device that can be prevented from being provided inside the body in a bent state even the nuclear cladding tube long in the height direction.

Deformation measuring device 1000 of the nuclear fuel cladding tube of the present invention is a measuring device for measuring the deformation of the nuclear fuel cladding tube 100, it is possible to block radiation and heat, the insertion hole 210 in which the nuclear fuel cladding tube 100 is fixed The hollow formed base portion 200; A frame 300 capable of blocking radiation and heat and forming a predetermined space on the base part 200; It is formed to surround the fuel cladding tube 100 inserted through the insertion hole 210 in the frame 300, so that a laser beam B passes in a direction perpendicular to the fuel cladding tube 100. A body 400 in which the first through hole 401 and the second through hole 402 are hollow formed; A temperature controller 500 for controlling the temperature of the nuclear fuel sheathing tube 100; A pressure regulator 600 connected to the lower side of the nuclear fuel sheath 100 to control pressure; And an optical measuring unit 700 provided in the frame 300 and including an irradiation unit 710 for irradiating a laser beam B and a collecting unit 720 for collecting the irradiated laser beam B; And a control unit.

In addition, the temperature controller 500 includes a temperature sensor 510 for measuring a temperature inside the body 400, a heater 520 formed on an inner circumferential surface of the body 400, and the temperature sensor 510. It characterized in that it comprises a first control unit 530 for controlling the operation of the heater 520 by using the measured information.

In addition, the strain measuring device 1000 of the nuclear fuel cladding tube is characterized in that the protective tube 410 of the material that can pass through the laser beam (B) inside the body 400 is further provided.

In addition, the temperature sensor 510 is formed in a plurality in the longitudinal direction and the circumferential direction of the body 400, the first temperature sensor 511 for measuring the temperature inside the protective tube 410, and the nuclear fuel cladding tube ( 100) It characterized in that it comprises a second temperature sensor 512 for measuring the temperature of the surface.

In addition, the temperature controller 500 is the heater 520 is divided into a plurality of modules (500a, 500b, 500c) in the height direction of the body 400, the first controller 530 is a plurality of The heaters 520 forming the modules 500a, 500b, and 500c are individually controlled.

In addition, the strain measuring device 1000 of the nuclear fuel cladding tube is characterized in that the first fixing part 110 and the second fixing sphere 120 at the lower side of the nuclear fuel cladding tube 100 is connected.

In addition, the deformation amount measuring apparatus 1000 of the nuclear fuel cladding tube is hollow formed in a predetermined region on the upper side of the body 400, the hollow portion 403 through the hollow portion 403 through the first fixing part 110 It characterized in that the fixing block 800 for fixing the.

In addition, the pressure control unit 600 is connected to the nuclear fuel cladding tube 100 through the second fixing sphere 120, the connection line 610, and the pump 620 provided on the connection line 610 and And, it characterized in that it comprises a second control unit 630 for controlling the operation of the pump 620.

In addition, the optical measuring unit 700 is formed such that the irradiation unit 710 and the collecting unit 720 is spaced apart from the first through hole 401 and the second through hole 402 by a predetermined distance in the height direction. The first reflector 731 reflects the laser beam B irradiated through the irradiator 710 into the first through hole 401, and the laser beam B passed through the second through hole 402. The second reflector 732 is reflected to the collecting unit 720 is characterized in that it is further provided.

In addition, the optical measuring unit 700 is characterized in that the irradiation unit 710 and the collecting unit 720 is wrapped by a shielding portion 740 that blocks the radiation.

In addition, the frame 300 is characterized in that the other side of the side on which the base portion 200 is formed is formed to be openable.

Accordingly, the strain measuring device of the nuclear fuel cladding tube of the present invention having the characteristics as described above, the body, the temperature control unit, the pressure control unit and the optical fiber which can measure the strain amount formed inside the base and the frame that can block radiation and heat By providing the measuring unit there is an advantage that can safely measure the deformation amount of the nuclear fuel cladding.

In particular, the strain measuring device of the fuel cladding tube of the present invention is further provided with a protective tube inside the body, the radioactive particles adhered to the inner surface of the cladding during scattering during the measurement of the fuel cladding is scattered to contaminate the body and peripheral equipment from the radioactive material It can be prevented in advance, there is an advantage that can increase the safety and durability more.

In addition, the apparatus for measuring the deformation amount of the nuclear fuel cladding tube of the present invention is surrounded by the shield and the irradiation portion and the collecting portion of the optical measuring unit, the radiation of the nuclear fuel cladding tube by irradiating and collecting the laser beam through the first reflecting unit and the second reflecting unit Through the through hole and the second through hole there is an advantage that can be prevented in advance to damage the irradiator and the collector.

In addition, the strain measuring device of the nuclear fuel cladding tube of the present invention can form a temperature evenly in the height direction of the body through the temperature control unit, by measuring the temperature of the inner surface of the protective tube or nuclear fuel cladding tube to control the heater through this to improve the measurement reliability There is an advantage to this.

In addition, the strain measuring device of the fuel cladding tube of the present invention, the first fixing sphere and the second fixing sphere is formed in the nuclear fuel cladding tube, the second fixing sphere is fixed by the base portion or the body from the lower side, the fixing to fix the first fixture on the upper side By being fixed by the block, even if the nuclear fuel cladding long in the height direction there is an advantage that can be prevented from being provided inside the body in a bent state.

1 is a view showing a strain measuring device of a nuclear fuel cladding tube according to the present invention.
2 to 4 is a partial cutaway perspective view, longitudinal cross-sectional view, and cross-sectional view of the strain measuring device of the nuclear fuel cladding according to the present invention.
5 is a view for explaining the operation of the temperature control unit and the pressure control unit of the strain measuring device of the nuclear fuel cladding according to the present invention.
6 and 7 are a longitudinal sectional view and a detailed operation diagram showing another example of the strain measuring device of the nuclear fuel cladding according to the present invention.

Hereinafter, the deformation amount measuring apparatus 1000 of the nuclear fuel cladding tube of the present invention having the characteristics as described above will be described in detail with reference to the accompanying drawings.

1 is a view showing a strain measuring device 1000 of the nuclear fuel cladding according to the present invention, Figures 2 to 4 is a partial cutaway perspective view, longitudinal cross-sectional view, and cross-sectional view of the strain measuring device 1000 of the nuclear fuel cladding according to the present invention. 5 is a view illustrating the operation of the temperature control unit 500 and the pressure control unit 600 of the strain measuring device 1000 of the nuclear fuel cladding according to the present invention, Figures 6 and 7 of the nuclear fuel cladding according to the present invention It is a longitudinal cross-sectional view and operation | movement detail drawing which showed still another example of strain amount measuring apparatus 1000. FIG.

Deformation measuring device 1000 of the nuclear fuel cladding of the present invention is the base portion 200, the frame 300, the body 400, the temperature control unit 500, the pressure control unit 600, and the optical measuring unit 700 It includes.

The base portion 200 is formed of a material capable of blocking radiation and heat, and is formed of a material capable of providing a durability enough to stably support the remaining components in the lowermost layer.

The base portion 200 has a hollow insertion hole 210 is inserted into the nuclear fuel cladding tube 100 is fixed, the base and the base portion 200 is spaced apart a predetermined distance to facilitate the insertion of the nuclear fuel cladding tube 100 It may be formed to have a height.

The frame 300 is formed on the upper side of the base portion 200, and forms a predetermined space therein.

At this time, the frame 300, like the base portion 200, is formed of a material that can block radiation and heat.

The strain measuring apparatus 1000 of the nuclear fuel cladding tube of the present invention has an advantage that the components for measuring the fuel cladding tube 100 and the deformation amount of the nuclear fuel cladding tube 100 are provided in the frame 300 to increase the safety of the operator. There is this.

The frame 300 and the base 200 may be made of a material having sufficient durability while shielding radiation.

As an example, the frame 300 may use 80 mm thick pure lead and a stainless steel material surrounding the lead material for shielding radiation.

The base portion 200 is a plate of a 40mm steel material is used to support the weight of the frame 300 of about 1 ton, and at the same time the structure of the 40mm lead plate laminated on the upper and lower side of the steel plate for the radiation shielding Can be used.

In addition, the frame 300 is preferably formed on the other side of the side provided with the base portion 200 to be opened and closed to facilitate the maintenance and inspection work with the mounting of the internal components. (See FIGS. 1-3, 6, and 7)

1 to 3, 6 and 7, the entire upper side of the frame 300 forming the upper side is a separate cover 310, showing an example formed to be openable and closed, the nuclear fuel cladding of the present invention The deformation amount measuring apparatus 1000 is not limited thereto, and an opening and closing area and a fixing method may be variously formed.

The body 400 is a structure provided inside the frame 300, and is formed to surround the nuclear fuel cladding tube 100 inserted through the insertion hole 210, a predetermined region is perpendicular to the nuclear fuel cladding tube 100. The first through hole 401 and the second through hole 402 are hollowed to pass the laser beam B in one direction.

That is, the body 400 is a tubular member that forms a predetermined space therein by blocking the upper and lower surfaces, at this time, the cross-sectional shape may be formed in a variety of forms, including circular, polygonal. .

The body 400 is provided with a nuclear fuel cladding tube 100 therein, the apparatus for measuring the amount of deformation is provided.

At this time, the body 400 is the first through hole 401 and the second through hole 402 is hollow, the body (through the first through hole 401 and the second through hole 402) The laser beam B irradiated from the irradiator 710 of the optical measuring unit 700 located outside is penetrated through the fuel cladding tube 100 and collected through the collector 720. The amount of deformation of the fuel cladding tube 100 is calculated through the collection information of 720.

The body 400 may be automatically moved and mounted in the height direction by the body transfer means 910.

The temperature control unit 500 is a means for controlling the temperature of the nuclear fuel cladding tube 100, it is possible to form a plurality in the circumferential direction and the height direction of the cladding tube.

The temperature controller 500 is formed to include a temperature sensor 510, a heater 520, and a first controller 530.

The temperature sensor 510 is a means for measuring the temperature inside the body 400, the measurement information is transmitted to the first control unit 530.

The temperature sensor 510 may be fixed to the body 400, and various means capable of measuring the surface temperature of the inner surface of the body 400 or the nuclear fuel cladding tube 100 may be used.

The heater 520 is formed on the inner circumferential surface of the body 400 and may be formed in various forms.

The first controller 530 is a means for controlling the operation of the heater 520 using the temperature information measured by the temperature sensor 510.

On the other hand, when measuring the deformation amount of the fuel cladding tube 100, it is very important to control the temperature uniformly in the height direction of the fuel cladding tube 100 formed long in the longitudinal direction, for this purpose, the deformation amount of the fuel cladding tube 100 of the present invention In the apparatus, the heater 520 is partitioned into a plurality of modules 500a, 500b, and 500c in the height direction of the body 400, and the first control unit 530 is the plurality of modules 500a, 500b and 500c. Can be controlled individually.

In FIG. 5, the heater 520 is shown as an example consisting of three modules 500a, 500b, and 500c.

In FIG. 5, the temperature information measured by the temperature sensor 510 is represented by a dotted line in the electrical connection state transmitted to the first control unit 530, and a control signal of the heater 520 of the first control unit 530. Is shown by the solid line.

In addition, the strain measuring apparatus 1000 of the nuclear fuel cladding tube of the present invention may be further provided with a protective tube 410 of a material that can pass the laser beam (B) between the body 400 and the fuel cladding tube (100).

When the deformation amount of the fuel cladding tube 100 is measured, the nuclear fuel cladding tube 100 may be damaged as temperature and pressure are controlled, and at this time, radioactive particles adhered to the inner surface of the nuclear fuel cladding tube 100 are scattered to spread the body. (400) If the inner circumferential surface, the entire body 400 is contaminated with radioactive material should be replaced.

The protective tube 410 is a radioactive material only in the protective tube 410 even if the nuclear fuel cladding 100 is damaged and can be easily removed or replaced by decontamination. Accordingly, the strain measuring apparatus 1000 of the nuclear fuel cladding tube of the present invention can prevent the trouble such as replacing the entire body 400, there is an advantage that easy maintenance and repair work.

In the form provided with the protective tube 410, the temperature sensor 510 is formed in a plurality in the longitudinal direction and the circumferential direction of the body 400, of the inside of the body 400, the protective tube 410 inside It may include a first temperature sensor 511 for measuring the temperature, and a second temperature sensor 512 for measuring the temperature of the nuclear fuel cladding (100).

The protective tube 410 may be hollow in a predetermined region so that a predetermined region of the first temperature sensor 511 and the second temperature sensor 512 can be inserted.

On the other hand, the nuclear fuel cladding tube 100 is a tubular member in which the nuclear fuel stored therein is removed, and the first fixing part 110 and the second fixing hole 120 are connected to the upper side so that the deformation amount of the nuclear fuel cladding tube of the present invention. It may be mounted on the measuring device (1000).

The first fixing part 110 closes one side (upper part in the drawing) of the nuclear fuel cladding tube 100 and is additionally fixed by the fixing block 800 provided on the upper side of the body 400 in the correct position. It may play a role of fixing the fuel cladding tube (100).

That is, the fixing block 800 passes through the hollow portion 403 in which a predetermined upper area of the body 400 (upper middle area in the drawing) is hollowed so that the first fixing part 110 inside the body 400 is fixed. Plays the role of fixing it.

In addition, the second fixture 120 is fixed to the other side (lower portion in the drawing) of the nuclear fuel cladding tube 100, so that the connection line 610 of the pressure regulator 600 and the fuel cladding tube 100 communicate with each other. Fix it.

In this case, the second fixing tool 120 may be fixed through the insertion hole 210 of the base portion 200 or may be fixed through the body 400.

Through this, the deformation amount measuring apparatus 1000 of the fuel cladding tube of the present invention can be more easily performed temperature and pressure control of the fuel cladding tube 100 by fixing the fuel cladding tube 100 in the correct position, and the measurement reliability It can be increased further.

The pressure regulator 600 is formed to include a connection line 610, a pump 620, and a second control unit 630.

The connection line 610 is configured to adjust the pressure inside the fuel cladding tube 100 by the operation of the pump 620, the second control unit 630 controls the operation of the pump 620.

The optical measuring unit 700 includes a radiator 710 and a collecting unit 720 and is provided in the frame 300.

The irradiation unit 710 is configured to irradiate the laser beam (B), the irradiated laser beam (B) is moved into the body 400 through the first through hole 401 of the body 400, Pass through the nuclear fuel cladding 100 is moved to the outside through the second through hole 402 of the body 400, it is collected through the collection unit 720.

At this time, the portion irradiating and collecting the laser beam (B) of the irradiation unit 710 and the collecting unit 720 is the first through hole 401 and the second through hole 402 of the body 400 When it is located so as to correspond to the formed height, the radiation unit 710 and the collecting unit 720 may be damaged by the radiation emitted through the fuel cladding 100.

Deformation measuring device 1000 of the nuclear fuel cladding of the present invention is provided with the height of the irradiation unit 710 and the collecting unit 720 of the first through hole 401 and the second through hole 402 of the body 400 Is formed to be different from the formation height, the movement path of the laser beam (B) by using the first reflecting portion 731 and the second reflecting portion 732 is adjusted to the irradiation portion by the radiation of the fuel cladding tube 100 Damage to the 710 and the collection unit 720 can be prevented in advance.

In more detail, referring to FIG. 3, radiation may be emitted through the first through hole 401 and the second through hole 402, but the first reflecting unit 731 and the second reflecting unit may be disposed at the position. Since the inner wall surface of the 732 and the frame 300 is located, the direct damage of the irradiation unit 710 and the collecting unit 720 is not applied, and the area (irradiation unit 710 and collection) that may be indirectly affected. The shield 740 may be formed on the circumferential portion of the portion 720 to further increase overall durability.

At this time, the height direction movement of the irradiator 710 and the collector 720 can be performed through the irradiator transfer means 940 and the collector transfer means 950, respectively, of the first reflecting portion 731 The height direction movement and fixation angle are adjustable by the first reflector position control means 920, and the height direction movement and fixation angle of the second reflector 732 is applied to the second reflector position control means 930. Adjustable by (See Figures 6 and 7)

Accordingly, the deformation amount measuring apparatus 1000 of the nuclear fuel cladding tube of the present invention having the characteristics as described above can safely measure the deformation amount of the nuclear fuel cladding tube 100, and has an advantage of increasing the measurement reliability.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1000: Deformation measuring device of nuclear fuel cladding
100: nuclear fuel cladding 110: first fixing sphere
120: second fixing ball
200: base portion 210: insertion hole
300: frame 310: cover
400: body 401: first through hole
402: second through hole 403: hollow part
410: sheriff
500: temperature controller 510: temperature sensor
511: first temperature sensor 512: second temperature sensor
520: Heater (500a, 500b, 500c)
530: first control unit
600: pressure control unit 610: connection line
620: pump 630: second control unit
700: optical measurement unit 710: irradiation unit
720: collecting unit 731: first reflecting unit
732: second reflecting unit 740: shielding unit
800: fixed block
910: body transfer means
920: position control means of the first reflector
930: position control means of the second reflector
940: transport means of the irradiation unit
950: collection unit transfer means
B: laser beam

Claims (11)

In the measuring device for measuring the deformation amount of the nuclear fuel cladding tube 100,
A base portion 200 capable of blocking radiation and heat and having an insertion hole 210 in which a nuclear fuel cladding tube 100 is inserted and fixed;
A frame 300 capable of blocking radiation and heat and forming a predetermined space on the base part 200;
It is formed to surround the fuel cladding tube 100 inserted through the insertion hole 210 in the frame 300, so that a laser beam B passes in a direction perpendicular to the fuel cladding tube 100. A body 400 in which the first through hole 401 and the second through hole 402 are hollow formed;
A temperature controller 500 for controlling the temperature of the nuclear fuel sheathing tube 100;
A pressure regulator 600 connected to the lower side of the nuclear fuel sheath 100 to control pressure; And
An optical measuring unit 700 provided in the frame 300 and including an irradiation unit 710 for irradiating a laser beam B and a collecting unit 720 for collecting the irradiated laser beam B; Deformation measuring device of the nuclear fuel cladding pipe comprising a.
The method of claim 1,
The temperature control unit 500
A temperature sensor 510 for measuring a temperature inside the body 400;
A heater 520 formed on an inner circumferential surface of the body 400,
And a first controller (530) for controlling the operation of the heater (520) by using the information measured from the temperature sensor (510).
The method of claim 1,
Deformation measuring device 1000 of the nuclear fuel cladding
Deformation measuring device of the nuclear fuel cladding tube further comprises a protective tube (410) made of a material that can pass through the laser beam (B) inside the body (400).
The method of claim 3,
The temperature sensor 510 is formed in a plurality along the longitudinal direction and the circumferential direction of the body 400,
A first temperature sensor 511 for measuring a temperature inside the protective tube 410;
And a second temperature sensor (512) for measuring the temperature of the surface of the nuclear fuel cladding (100).
3. The method of claim 2,
The temperature control unit 500
The heater 520 is divided into a plurality of modules (500a, 500b, 500c) in the height direction of the body 400,
The first control unit (530) controls the deformation amount of the nuclear fuel cladding pipe, characterized in that for controlling the heater (520) for forming the plurality of modules (500a, 500b, 500c) individually.
The method of claim 1,
Deformation measuring device 1000 of the nuclear fuel cladding
Deformation measuring device of the nuclear fuel cladding tube characterized in that the first fixing part 110 and the second fixing sphere 120 is connected to the upper side of the fuel cladding tube (100).
The method according to claim 6,
Deformation measuring device 1000 of the nuclear fuel cladding
The hollow portion 403 is hollow formed in a predetermined region on the upper side of the body 400, and the fixing block 800 for fixing the first fixing part 110 through the hollow portion 403 is provided. Deformation measuring device of a nuclear fuel cladding tube.
The method according to claim 6,
The pressure control unit 600
A connection line 610 in communication with the nuclear fuel sheathing tube 100 through the second fixture 120;
A pump 620 provided on the connection line 610;
Deformation measuring device of the nuclear fuel cladding pipe, characterized in that it comprises a second control unit (630) for controlling the operation of the pump (620).
The method of claim 1,
The optical measuring part 700 is formed such that the irradiation part 710 and the collecting part 720 are spaced apart from the first through hole 401 and the second through hole 402 by a predetermined distance in a height direction.
A first reflecting unit 731 reflecting the laser beam B irradiated through the irradiating unit 710 into the first through hole 401;
And a second reflecting portion (732) for reflecting the laser beam (B) passing through the second through hole (402) to the collecting portion (720).
10. The method of claim 9,
The optical measuring unit 700
Deformation measuring device of the nuclear fuel cladding tube, characterized in that the irradiation unit 710 and the collecting unit 720 is wrapped by a shield 740 for blocking the radiation.
The method of claim 1,
The frame 300 is a strain measuring device of the nuclear fuel cladding, characterized in that the other side of the side formed with the base portion 200 is formed to be openable.

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