JP2002228787A - Heat generation monitor for neutron reflector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To monitor the heating temperature and temperature distribution of a neutron reflector with higher accuracy. SOLUTION: This heat generation monitor for the neutron reflector comprises a pipe 5 brought into contact with the neutron reflector 1; an optical fiber 6 arranged inside the pipe 5; and a temperature measuring apparatus for analyzing light emitted from the optical fiber 6. The temperature measuring apparatus measures the temperature of the neutron reflector 1 on the basis of the light. The temperature measuring apparatus allows laser to enter the optical fiber 6 from one end and measures the temperature of the neutron reflector 1 on the basis of scattered light on which the laser is scattered. Or the optical fiber 6 contains a scintillator, and the temperature measuring apparatus measures a radiation dose on the basis of scintillation generated by the reaction of radiation and the scintillator, and assumes the temperature on the basis of the radiation dose.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a neutron reflector heat generation monitor, and more particularly to an improved pressurized water reactor (hereinafter referred to as "light water reactor").
The present invention relates to a neutron reflector heat generation monitor that measures the heat value of a neutron reflector used for “improved PWR”.

[0002]

2. Description of the Related Art In an improved PWR, a cylindrical stainless steel neutron reflector is provided around a reactor core in a reactor vessel. Such neutron reflectors reflect neutron radiation emitted from the reactor core, reduce the neutron dose irradiated to the reactor vessel, and reduce the fuel cycle cost by using the reflected neutrons for nuclear reactions. ing. FIG. 14 shows a neutron reflector. The neutron reflector 101 has a cylindrical shape and surrounds a reactor core in a reactor vessel.
The neutron reflector 101 includes eight ring blocks 102-
A structure in which i (i = 1, 2, 3,..., 8) are stacked is adopted.

FIG. 15 shows a ring block 102-i. Each ring block 102-i is provided with an alignment pin 103, and the adjacent ring block 1
02- (i-1) is fixed. The stacked eight-stage ring blocks 102-i are further tightened by eight tie rods 104. Each ring block 10
A channel hole 105 is provided in 2-i. The neutron reflector 102 generates heat due to radiation (especially γ rays) emitted from the reactor core. Cooling water, which is a cooling medium, flows through the flow passage hole 105 to cool the neutron reflector 101. At this time, it is required to monitor the heating temperature of the neutron reflector 101.

A Raman scattering type temperature distribution sensor (hereinafter abbreviated as “RDTS”) for measuring temperature is known. When high-intensity light such as a laser enters the optical fiber, the incident light is backscattered at each point in the optical fiber, and the scattered light propagates to the incident side. The scattered light is composed of Rayleigh scattered light and Raman scattered light. Raman scattered light is composed of two components called a Stokes component having a longer wavelength and an anti-Stokes component having a shorter wavelength than the Rayleigh scattered light. The intensity ratio between the Stokes and anti-Stokes components is a function of the temperature of the scattering point. By solving this inverse problem, the temperature at the scattering point can be obtained from the intensity ratio.

[0005] To determine the scattering point, Optical T
The im Domain Reflectometry method (hereinafter abbreviated as “OTDR method”) is used. FIG. 16 shows a measuring device for measuring a loss distribution on an optical fiber using the OTDR method. The measuring device 110
Comprises an oscillator 111 for transmitting a pulse laser 115, a coupler 112, an optical fiber 113, and a photodetector 114 for detecting scattered light 116.

[0006] An oscillator 111 injects a pulse laser 115 into an optical fiber 113, a coupler 112 provides a scattered light 116 backscattered at each value on the optical fiber 113 to a photodetector 114, and a photodetector 114 outputs
The time from the incidence to the scattering is obtained based on the waveform of the optical fiber 113, and the distance is obtained from the time.
The loss distribution at each position is measured.

FIG. 17 shows a measuring device for measuring the position distribution of the temperature on the optical fiber 113 from the scattered light 116. The measuring device 117 extracts a Stokes component 121 and an anti-Stokes component 122 from the scattered light 116, a photodetector 119 that measures the intensity of the Stokes component 121, and measures the intensity of the anti-Stokes component 122. And a photodetector 120. Similarly to the OTDR method, the temperature at each position on the optical fiber 113 can be measured based on the waveform of the scattered light 116.

Measurement of radiation distribution by optical fiber (T
OF method) is known. FIG. 18 shows a measurement system for measuring a radiation distribution. The measurement system 130
Includes an optical fiber 131, and a photomultiplier tube (PMT) 132 and a preamplifier (F) at both ends of the optical fiber 131.
PA) 133 and a wave height discriminator (CFD) 134. The measurement system 130 further includes a time-to-peak converter (TAC) 135 and a multi-channel analyzer (MCA) 136.

A part of the scintillation generated in the optical fiber 131 in response to the γ-ray is
Propagation toward both ends of. The PMT 132 converts the scintillation into an electric signal. FPA 133 amplifies the electric signal. The CFD 134 selects the peak of the amplified electric signal and further generates a time signal. TAC
The 135 measures the arrival time difference at both ends from the two time signals acquired from the two CFDs 134, and converts the arrival time difference into a wave height. The MCA 136 analyzes a scintillation generation position based on the wave height.

[0010]

SUMMARY OF THE INVENTION An object of the present invention is to provide a neutron reflector heat generation monitor for monitoring the heat generation temperature of a neutron reflector.

It is another object of the present invention to provide a neutron reflector heat generation monitor for more accurately measuring the heat generation temperature of a neutron reflector.

Still another object of the present invention is to provide a neutron reflector heat generation monitor for measuring a temperature distribution of a neutron reflector.

Still another object of the present invention is to provide a neutron reflector heat generation monitor that can be easily processed for mounting on a neutron reflector.

[0014]

Means for solving the problem are described as follows. The technical items appearing in the expression are appended with numbers, symbols, etc. in parentheses (). The numbers, symbols, and the like are technical items that constitute at least one embodiment or a plurality of the embodiments of the present invention, in particular, the embodiments or the examples. Corresponds to the reference numerals, reference symbols, and the like assigned to the technical matters expressed in the drawings corresponding to the above. Such reference numbers and reference symbols clarify the correspondence and bridging between the technical matters described in the claims and the technical matters of the embodiments or examples. Such correspondence / bridge does not mean that the technical matters described in the claims are interpreted as being limited to the technical matters of the embodiments or the examples.

The neutron reflector heat generation monitor according to the present invention comprises:
A tube (5) in contact with the neutron reflector (1), an optical fiber (6) disposed in the tube (5), and a thermometer for analyzing light emitted from the optical fiber (6); The thermometer measures the temperature of the neutron reflector (1) based on the light. The tube (5) isolates the cooling medium for cooling the neutron reflector (1) from the optical fiber (6) and makes the temperature measurement of the neutron reflector (1) more reliable.

In the temperature measuring device, a laser is made to enter the optical fiber (6) from one end, and the light is scattered light scattered by the laser. The scattered light is composed of Rayleigh scattered light and Raman scattered light. Raman scattered light is composed of two components called a Stokes component having a longer wavelength and an anti-Stokes component having a shorter wavelength than the Rayleigh scattered light. The intensity ratio between the Stokes and anti-Stokes components is a function of the temperature of the scattering point.
By solving this inverse problem, the temperature at the scattering point can be obtained from the intensity ratio. Such a temperature measuring method is known.

The inside of the tube (5) is filled with a heat insulating material (12), and the optical fiber (6) is located at a position where the tube (5) is in contact with the neutron reflector (1) from the center of the tube (5). It is arranged unevenly. By arranging the optical fiber (6) in this way, the influence of the cooling medium is reduced. More preferably, the optical fiber (6) is in contact with the part where the tube (5) is in contact with the neutron reflector (1).

The light generated by the optical fiber (6) is scintillation generated by the reaction between the radiation and the scintillator. The thermometer measures the radiation dose based on the scintillation and measures the temperature based on the radiation dose. . The neutron reflector (1) generates heat by exposure to radiation. The exothermic temperature of the neutron reflector (1) is a function of the radiation dose applied. By measuring the radiation dose, the heat generation temperature of the neutron reflector (1) is estimated.

There are a plurality of optical fibers (6-1 to 6-n), and each of the plurality of optical fibers (6-1 to 6-n) is disposed at one end inside the tube (5). Length of (6-1 to 6-n) (L (1) to L (n))
Are different from each other, and the temperature measuring device has a plurality of optical fibers (6
The position distribution of the temperature of the neutron reflector (1) is measured based on the light emitted from -1 to 6-n). The radiation dose at each position of the tube (5) is estimated from the difference between the radiation doses measured by the plurality of optical fibers (6-1 to 6-n). From this radiation dose, the heat generation temperature at each position of the neutron reflector (1) is estimated.

The optical fiber (6) has a first end and a second end, the temperature measuring device is connected to the first end and the second end, and light is emitted from the first end and the second end. , And the temperature measuring device measures the temperature distribution of the neutron reflector (1) based on the first light and the second light. The scintillation generated in response to the radiation propagates toward both ends of the optical fiber (6). The scintillation occurrence position can be obtained based on the difference in arrival time of the scintillation at both ends. Such a measuring method is known.

The neutron reflector (1) is a neutron reflector (1)
The tube (5) is disposed inside the hole (4). The generatrix direction is the axial direction of the cylindrical neutron reflector (1). With such an arrangement of the tube (5), the temperature distribution in the generatrix direction of the neutron reflector (1) can be measured. The hole (4) is preferably a channel hole (3) through which a cooling medium flows, because the neutron reflector (1) can be easily processed.

It is more preferable that one end of the hole (4) is closed because the influence of the cooling water is small. Tube (5)
Is more preferably fixed to the neutron reflector (1) by joint welding. It may further include a mounting bracket (8) fixed to the neutron reflector (1), and the tube (5) may be fixed by welding with the mounting bracket (8). The inner wall (9) of the hole (4) and the mounting bracket (8) may be threaded, screwed and fixed. Alternatively, the neutron reflector (1) and the mounting bracket (8) may be fixed with bolts (17).

The neutron reflector (1) further has another hole (19) which communicates with the hole (4) and extends in the circumferential direction of the neutron reflector (1), and the tube (5) has the hole (4). Inside and other holes (1
9). With such an arrangement of the tube (5), the temperature distribution in the circumferential direction of the neutron reflector (1) can be measured.

The tube (5) is preferably disposed on the outer peripheral wall (14) of the neutron reflector (1) in that it can be easily mounted. A mounting bracket (11) is fixed to the neutron reflector (1) by welding, and the tube (5) is fixed by being sandwiched between the wall (14) of the neutron reflector (1) and the mounting bracket (11). I have.

The neutron reflector (1) is located on the outer peripheral wall (1).
4) has a groove (15), and the tube (5) is arranged in contact with the groove (15). The groove (15) provides a more accurate measurement of the temperature of the neutron reflector (1) by reducing the contact between the tube (5) and the cooling medium and increasing the contact with the neutron reflector (1). Can be. The grooves (15) further prevent the tube (5) from wobbling. Groove (15) width (18)
Is shorter than the diameter of the tube (5). At this time, the pipe (5) is easily fixed without using a fitting.

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a neutron reflector heat generation monitor according to the present invention will be described with reference to the drawings. The neutron reflector 1 is composed of eight ring blocks 2-1 to 2-8, and as shown in FIG.
(I = 1, 2, 3,..., 8) are provided with a plurality of flow passage holes 3 through which the cooling water flows. In the ring block 2-i, a measurement hole 4 is provided in parallel with the flow path hole 3. When the ring blocks 2-i are assembled to the cylindrical neutron reflector 1, the measurement holes 4 provided in each ring block 2-i are connected linearly. The measurement hole 4 is newly provided in the ring block 2-i. The measurement hole 4 can use the channel hole 3. When the channel hole 3 is used as the measurement hole 4, the processing of the ring block 2-i is easy.

FIG. 2 shows a cross section of the measurement hole 4. A metal tube 5 is provided in the measurement hole 4 of the assembled neutron reflector 1.
Is inserted. An optical fiber 6 is inserted into the metal tube 5, one end of the optical fiber 6 is arranged inside the metal tube 5, and the other end is outside the metal tube 5. The tip of the optical fiber 6 located in the metal tube 5 is cut obliquely. The metal tube 5 facilitates putting the optical fiber 6 in and out of the neutron reflector 1. One end of the metal tube 5 is closed to isolate the optical fiber 6 from the cooling water flowing through the flow path hole 3. As shown in FIG. 3, if the measurement hole 4 of the lowermost ring block 2-8 is not penetrated, the metal tube 5 is prevented from coming into contact with the cooling water from below, and the temperature due to the cooling water is reduced. Measurement errors can be reduced.

As shown in FIG. 2, the metal pipe 5 is joint-welded to the uppermost ring block 2-1 to form a fillet 7.
It is fixed by. Note that a part of the contact surface between the metal tube 5 and the ring block 2-1 may be cut and fixed by screwing. After screwing, joint welding may be further performed. Further, as shown in FIG. 4, the metal tube 5 and the ring block 2-
1 and may be fixed. Male screw 1 around mounting bracket 8
0 is cut, a female screw 9 is cut on the inner wall of the measurement hole 4 of the ring block 2-1, and the mounting bracket 8 is screwed and fixed to the ring block 2-1. The metal tube 5
It is fixed to the mounting bracket 8 by joint welding. Further, the mounting bracket 8 may be fixed by the ring block 2-1 and the bolt 17 as shown in FIG. At this time, similarly, the metal pipe 5 is joint-welded to the mounting bracket 8 and is fixed by the fillet 7.

The distal end of the optical fiber 6 protruding outside the metal tube 5 is connected to a temperature measuring device (not shown). The temperature measuring device measures the temperature of each position on the optical fiber 6 by injecting a pulse laser into the optical fiber 6 and detecting the backscattered Raman scattered light. Such a measuring method is known. By such a temperature measurement, the temperature distribution of the ring blocks 2-1 to 2-8 can be monitored. In addition, as shown in FIG. 6, both ends of the optical fiber 6 may be arranged outside the metal tube 5. At this time, similarly, the temperature at each position on the optical fiber 6 can be measured.

In another embodiment of the neutron reflector heat generation monitor according to the present invention, a metal tube 5 is arranged on the outer peripheral surface of the neutron reflector 1. The metal tube 5 is, as shown in FIG.
The outer wall 14 outside the neutron reflector 1 by the mounting bracket 11
Fixed to. An optical fiber 6 is inserted into the metal tube 5 in the same manner as in the previous embodiment. One end of the metal tube 5 is closed to separate the optical fiber 6 from the cooling water.

FIG. 8 shows a cross section of the mounting bracket 11 and the metal tube 5. The metal tube 5 is fixed between the ring block 2-i of the neutron reflector 1 and the mounting bracket 11. The mounting bracket 11 is the outer wall 1 of the ring block 2-i.
4 is fixed by welding. The metal tube 5 is welded to the mounting bracket 11. The inside of the metal tube 5 is further filled with a heat insulating material 12. The optical fiber 6 is arranged to be deviated from the center 13 of the metal tube 5 toward the ring block 2-i. With such an arrangement, it is possible to reduce an error in temperature measurement by the cooling water.

The ring block 2-i may be provided with a groove 15 on the outer wall 14 as shown in FIG. When the ring blocks 2-i are assembled to the neutron reflector 1, the grooves 15 provided in each ring block 2-i are connected linearly. The metal tube 5 is fixed between the wall surface 16 of the groove 15 and the mounting bracket 11. Groove 1
5 reduces the area in which the metal tube 5 comes into contact with the cooling water, and prevents the metal tube 5 from shaking. The inside of the metal tube 5 may be filled with a heat insulating material 12. At this time, the optical fiber 6
Are biased and arranged near the contact portion between the metal tube 5 and the wall surface 16. Such an arrangement can reduce errors in temperature measurement by the cooling water.

The metal tube 5 can be fixed to the outer wall 14 of the neutron reflector 1 without using a fitting. At this time, as shown in FIG. 10, the width 15 of the opening of the outer wall 14 of the groove 15 is smaller than the diameter of the metal tube 5. By such a groove 15, the metal tube 5 is fixed to the neutron reflector 1 in close contact with the metal tube 5 as it is. At this time, the total number of parts in the reactor vessel is preferably reduced. The inside of the metal tube 5 may be filled with a heat insulating material 12. At this time, the optical fiber 6 is biased near the contact portion between the metal tube 5 and the wall surface 16. Such an arrangement can reduce errors in temperature measurement by the cooling water.

In another embodiment of the neutron reflector heat generation monitor according to the present invention, both ends of the metal tube 5 are open,
The neutron reflector 1 is exposed outside. The metal tube 5 is fixed to an outer wall 14 outside the neutron reflector 1, as shown in FIG. At this time, the metal tube 5 is fixed using the mounting bracket 11 in the same manner as in the previous embodiment. The metal tube 5 extends linearly downward from the uppermost ring block 2-1 to the lowermost link block 2-8, is bent in a U-shape and is directed upward, and the lowermost ring block 2 is formed. -8 extends linearly from the uppermost link block 2-1.

The metal tube 5 may be inserted and fixed in the measurement hole 4 provided inside the neutron reflector 1. The metal tube 5 is fixed to the measurement hole 4 by joint welding in the same manner as in the previous embodiment. A measurement hole 5 bent in a U-shape is provided in the lowermost ring block 2-8. The bent measurement hole 5 fixes a bent portion of the metal tube 5.

The metal tube 5 may be arranged around the neutron reflector 1 in the circumferential direction. As shown in FIG. 12, the metal tube 5 is inserted from the measurement hole 4 of the uppermost ring block 2-1 and the ring block 2-.
i, makes one round in the circumferential direction on the upper surface of i, and extends outward from the measurement hole 4 of the uppermost ring block 2-1. On the upper surface of the ring block 2-i, a metal tube 5 is provided with a ring block 2- (i-1) and a ring block 2-i.
The groove 19 is cut so as not to be crushed. Groove 1
9 further fixes the metal tube 5. By disposing the metal tube 5 and the optical fiber 6 in the circumferential direction as described above, it is possible to measure not only the vertical direction of the neutron reflector 1 but also the temperature distribution in the circumferential direction.

In still another embodiment of the neutron reflector heat generation monitor according to the present invention, a plurality of optical fibers are arranged in a metal tube 5. Each optical fiber 6
As shown in FIG. 13, j (j = 1, 2, 3,..., n) has a length L (j), and each length L (j)
Are different from each other. The metal tube 5 in which each optical fiber 6-j is arranged is arranged in the same manner as in the previous embodiment.

The distal ends of the optical fibers 6-j protruding outside the metal tube 5 are respectively connected to temperature measuring devices (not shown). The temperature measuring device measures the radiation dose I (j) by counting the scintillation emitted from each optical fiber 6-j. Here, I (1) -I (2)
Corresponds to the average radiation dose in the position range indicated by a (1) in FIG. I (2) -I (3) corresponds to a in FIG.
This corresponds to the average radiation dose in the position range shown in (2).
In general, I (j) -I (j + 1) is the position range a (j)
Corresponding to the average radiation dose. Thus, based on the radiation dose I (j) measured by each optical fiber 6-j,
The distribution of radiation dose at each position is measured. Temperature is a function of the radiation dose that is delivered. The temperature distribution is estimated from the measured radiation dose distribution at each position. Furthermore, the length L
The optical fiber 6- (n +
It is more preferable to add 1), measure the light loss distribution by the OTDR method, and correct the measured radiation dose.

In still another embodiment of the neutron reflector heat generation monitor according to the present invention, both ends of the optical fiber 6 are exposed outside the metal tube 5 as shown in FIG. 6, FIG. 11 or FIG. . Both ends of the optical fiber 6 are connected to a temperature measuring device (not shown), and the radiation dose distribution at each position of the optical fiber 6 is measured by a known TOF method.
That is, part of the scintillation generated in the optical fiber 6 in response to the radiation propagates toward both ends of the optical fiber 6. The temperature measurement device measures the radiation dose by counting the scintillation, measures the arrival time difference of the scintillation obtained from both ends of the optical fiber 6, analyzes the scintillation generation position, and calculates the radiation dose at each position of the optical fiber 6. Measure the distribution. The temperature distribution is estimated from the measured radiation dose distribution at each position.

[0040]

The neutron reflector heat generation monitor according to the present invention can monitor the heat generation temperature of the neutron reflector.

[Brief description of the drawings]

FIG. 1 is a plan view showing a ring block.

FIG. 2 is a cross-sectional view showing a measurement hole and a metal tube.

FIG. 3 is a cross-sectional view showing a measurement hole and a metal tube.

FIG. 4 is a cross-sectional view showing a method of connecting a measurement hole and a metal tube.

FIG. 5 is a cross-sectional view showing a method of connecting a measurement hole and a metal tube.

FIG. 6 is a sectional view showing an embodiment of a neutron reflector heat generation monitor according to the present invention.

FIG. 7 is a perspective view showing an arrangement of metal tubes.

FIG. 8 is a cross-sectional view showing a method of fixing the metal tube and the ring block.

FIG. 9 is a sectional view showing a metal tube and a groove.

FIG. 10 is a sectional view showing a metal tube and a groove.

FIG. 11 is a perspective view showing an arrangement of metal tubes.

FIG. 12 is a perspective view showing an arrangement of metal tubes.

FIG. 13 is a schematic diagram showing a form of a plurality of optical fibers.

FIG. 14 is a perspective view showing a neutron reflector.

FIG. 15 is a plan view showing a ring block.

FIG. 16 is a block diagram showing a measuring device for measuring a loss distribution on an optical fiber by the OTDR method.

FIG. 17 is a block diagram showing a measuring device for measuring a temperature distribution on an optical fiber by the OTDR method.

FIG. 18 is a block diagram showing a measuring device for measuring a radiation distribution by the TOF method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Neutron reflector 2-1-2-8 ... Ring block 3 ... Channel hole 4 ... Measurement hole 5 ... Metal tube 6 ... Optical fiber 7 ... Fillet 8 ... Mounting bracket 9 ... Female screw 10 ... Male screw 11 ... Mounting Metal fittings 12 ... Insulation material 13 ... Center 14 ... Outside wall 15 ... Groove 16 ... Wall wall 17 ... Bolt 18 ... Groove width 19 ... Groove

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G01T 1/20 G21C 17/10 GDPL F-term (Reference) 2F056 VF02 VF11 VF12 VF17 2G075 AA05 CA08 DA03 FA01 FA11 FB03 FC14 GA21 2G088 AA03 EE22 EE30 FF04 GG15 KK15 KK24 KK35

Claims (12)

[Claims] 1. A tube in contact with a neutron reflector, an optical fiber disposed in the tube, and a temperature measuring device for analyzing light emitted from the optical fiber, wherein the temperature measuring device includes the light A neutron reflector heat generation monitor that measures the temperature of the neutron reflector based on the following. 2. The neutron reflector heat generation monitor according to claim 1, wherein the temperature measuring device causes a laser to enter the optical fiber from one end, and the light is scattered light scattered by the laser. 3. The optical fiber according to claim 2, wherein the inside of the tube is filled with a heat insulating material, and the optical fiber is arranged at a position where the tube is in contact with the neutron reflector from the center of the tube. Neutron reflector heating monitor. 4. The device according to claim 1, wherein the light is scintillation generated by radiation, the temperature measuring device measures a radiation dose based on the scintillation, and measures the temperature based on the radiation dose. Neutron reflector heat generation monitor. 5. The optical fiber according to claim 4, wherein a plurality of the optical fibers are provided, each of the plurality of optical fibers has one end disposed inside the tube, and the lengths of the plurality of optical fibers are different from each other; The neutron reflector heat monitor monitors the temperature distribution of the neutron reflector based on the light emitted from each of the plurality of optical fibers. 6. The optical fiber according to claim 4, wherein the optical fiber has a first end and a second end, the temperature measuring device is connected to the first end and the second end, and the light is: A first light emitted from the first end and a second light emitted from the second end, wherein the temperature measuring device is configured to determine a temperature position of the neutron reflector based on the first light and the second light. Neutron reflector heat generation monitor to measure distribution. 7. The neutron reflector according to any one of claims 1 to 6, wherein the neutron reflector has a hole extending in a generatrix direction of the neutron reflector, and the tube is disposed inside the hole. Neutron reflector heat generation monitor. 8. The neutron reflector heat generation monitor according to claim 7, wherein one end of the hole is closed. 9. The neutron reflector according to claim 7, further comprising another hole communicating with the hole and extending in a circumferential direction of the neutron reflector, wherein the tube has an inside of the hole and the other hole. Neutron reflector heat generation monitor located inside and inside the hole. 10. The neutron reflector heat generation monitor according to claim 1, wherein the tube is disposed on an outer peripheral surface side of the neutron reflector. 11. The neutron reflector heat generation monitor according to claim 10, wherein the neutron reflector has a groove on an outer peripheral surface side, and the tube is arranged in contact with the groove. 12. The neutron reflector heat generation monitor according to claim 11, wherein the width of the groove is shorter than the diameter of the tube.