KR20140010501A - In-core instrument assembly for improvement of neutron flux detection sensitivity - Google Patents

Abstract

The present invention relates to an in-core measuring instrument having improved neutron flux detection sensitivity, capable of: easily detecting a neutron signal by reducing a background signal, largely obtaining a current signal for thermal neutron detection by improving the thermal neutron incidence amount while reducing a fast neutron, improving the neutron flux detection sensitivity by reducing the background signal and improving a thermal neutron detection signal, stably maintaining the shape and the location of internal elements of a measuring part, and reducing the area of an emitter as much as the improved neutron flux detection sensitivity. The in-core measuring instrument having improved neutron flux detection sensitivity of the present invention comprises a measuring part which is inserted into a nuclear reactor to measure the neutron flux in the nuclear reactor, wherein the measuring part includes a filler cable which is arranged along the inside of the measuring part to shield gamma rays; a center pipe which penetrates the inside of the measuring part in the length direction; a guide groove which is formed on the surface of the center pipe to fix the location of a neutron detector, a detector for signal compensation, the filler cable and a thermocouple; and a filler which is filled in the center pipe and is capable of decreasing the fast neutron.

Description

In-Core Instrument Assembly for Improvement of neutron flux detection sensitivity

The present invention relates to an in-vehicle instrument which is installed inside a reactor of a nuclear power plant and measures neutron flux. More particularly, the present invention relates to a signal to noise ratio by minimizing a background signal generated by gamma rays in a nuclear reactor and maximizing a neutron flux detection signal. The present invention relates to an in-vehicle instrument that improves the sensitivity of neutron flux detection by increasing the Noise Ratio.

The stationary in-vehicle instrument accurately measures the Neutron Flux in each reactor in three dimensions at each position and monitors the power distribution. The key component of the furnace instrument is a self-powered neutron detector with an emitter that absorbs neutrons and emits signal current.

The magnetic output neutron detector using rhodium (Rh) conventionally used is operated by the principle of neutron capture reaction of rhodium emitter material. When neutrons are trapped in the rhodium, they undergo beta decay, releasing high-energy electrons with enough energy to leave the emitter. The emitted electrons are collected in a collector through an aluminum oxide (Al 2 O 3) insulator, and a positive charge is generated in an electric conductor attached to the emitter. The positive charge produced produces a current proportional to the neutron absorption of the emitter. Depending on the emitter material, it is classified into a rhodium detector (Rh-detector), a vanadium detector (V-detector), a cobalt detector (Co-detector), and a platinum detector (Pt-detector). The magnetic output neutron detector does not detect fast neutrons with high energy but is a device that detects thermal neutrons whose energy is lost due to the deceleration of the fast neutrons.

1 is a side view of a conventional furnace measuring instrument 10. Referring to FIG. 1, the conventional furnace meter 10 includes a measurement unit 20, a seal plug 30, a flexible hose 40, and a connector. The measuring unit 20 is surrounded by an outer protective tube 25, and a bullet-nose 26 is connected to one end of the measuring unit 20. The measuring unit 20 is inserted into the reactor through the guide tube (not shown), and the length is about 36m.

2 is a longitudinal cross-sectional view of the measuring section A-A of the conventional in-house measuring instrument. Referring to FIG. 2, the measuring unit 20 includes a center tube 21, a thermocouple 22, a filler cable 23, a signal compensation detector 24, an outer protective tube 25, and a neutron detector 27. It is composed.

The central tube 21 penetrates the inside of the measuring unit 20 in the longitudinal direction, and the thermocouple 22 includes chromels 22a and alumels 22b, measures the water temperature of the cooling water, and is used in the K type. Five magnetic output neutron detectors 27 are installed, include emitters, and measure neutron fluxes. The signal compensation detector 24 measures the background signal (noise), and the filler cable 23 and the center tube 21 are mainly made of an alloy of Inconel 600 series, and fill the internal empty space of the measurement unit 20. It serves to maintain the shape of the measurement part. The conventional in-house instrument consisting of the above configuration had the following problems.

The first problem is as follows. Radiation incident to the magnetic output neutron detector in the reactor includes the neutron beam and gamma ray, and when the gamma ray is incident on the detector, it reacts with the emitter with low probability to generate current. In this case, since the neutron detector only concerns the current interacting with the neutron beam, the current obtained by interacting with the gamma ray may be determined as an unnecessary background signal. 3 is a diagram illustrating a relationship between a thermal neutron signal generated by an emitter and a background signal. Referring to FIG. 3, when the same amount of thermal neutron enters the neutron detector, the higher the current amount of the signal generated by the emitter, and the lower the amount of the background signal generated basically, the higher the neutron detector efficiency and the higher the accuracy. As described above, from the viewpoint of signal to noise ratio, the required signal generation amount and the background signal generation amount should be kept small. In the conventional furnace instrument, it is impossible to remove the background signal which is inevitably generated. There was a problem that interferes with the detection of the signal.

The second problem is as follows. In-house instruments using rhodium emitters can generate a large amount of current output, so that currents generated by neutrons can be detected even when there is current caused by a background signal. However, as shown in Table 1, vanadium and platinum emitters, which are spotlighted as long-life furnace meters, have a lower burn-up rate than rhodium emitters, resulting in a longer lifespan and lower current output due to the lower neutron response sensitivity of the emitters. . Therefore, when the current of the background signal is excluded, the amount of current generated by the neutrons is lower than that of the rhodium emitter, which makes it difficult to detect a significant signal. Therefore, an in-vehicle instrument using vanadium or platinum emitters has a problem that it is difficult to discriminate neutron detection signals compared to an in-counter instrumentation using rhodium emitters.

Material Rhodium Vanadium Platinum Thermal neutron
Cross-Section (barns) 145 barns 4.9 barns 24 barns Burn-up Rate (% / month) 0.39 0.01 0.03 Sensitivity of emitter
Ф1mm (A / n / cm ² s) 0.2 x 10 ^-20 1.8 x 10 ^-22 0.9 x 10 ^-22

The third problem is as follows. Looking at the measuring unit 20 of the in-vehicle measuring instrument 10, unnecessary parts that serve only as shape retainers, such as the filler cable 23, are used, and the center tube 21 used to match the diameter of the guide tube (not shown) is also hollow. It is used to keep only the shape of the measurement part in the form. Due to the long structural length of about 36m or more, the measuring instrument is often bent or curled when inserted or transported into the reactor, and at this time, there is a problem that it may be bent or damaged due to the characteristics of the hollow center tube 21 of weak elasticity. When the furnace meter 10 is handled, all the components such as the filler cable 23, the magnetic output neutron detector 27, the thermocouple 22, and the signal compensation detector 24 are formed in the form of a tube. 20) There was a problem that can be pushed out of the original position when the whole bent and stretched.

The problem is summarized as follows. The first problem is that unnecessary background signals generated by gamma rays negatively affect neutron detection. The second problem is that instruments using emitters with low current output, such as vanadium or platinum emitters, are more difficult to detect neutrons due to unnecessary background signals than those using rhodium emitters. A third problem is that physical deformation of the internal components can occur due to the construction of the instrumentation section being inserted into the reactor and bent or curled.

The problem to be solved by the present invention is to propose an in-vehicle instrument with improved sensitivity of neutron flux detection to reduce the unnecessary background signal by increasing the shielding effect of the gamma rays by the filler cable consisting of a metal of atomic number (Z) 82 or more.

 The problem to be solved by the present invention is to increase the detection efficiency of the thermal neutron in the furnace instrument using a vanadium or platinum emitter with a low current output overall by filling a material capable of attenuating the fast neutron in the inner center tube This paper proposes an in-vehicle instrument with improved sensitivity for detecting neutron flux.

The problem to be solved by the present invention is to propose a furnace measuring instrument with improved sensitivity for detecting the neutron flux detected by filling the inside of the center tube with a filler and forming a guide groove on the surface of the center tube to maintain the shape and position of the internal components of the measurement unit stably. .

In-house measuring instrument with improved sensitivity for detecting neutron flux in accordance with the present invention for solving the above-mentioned problems, In the furnace measuring instrument including a measuring unit is inserted into the reactor to measure the neutron flux inside the reactor, the measuring unit, A filler cable disposed along and shielding the gamma ray; A center tube penetrating the inside of the measuring unit in a longitudinal direction; A guide groove formed on a surface of the center tube and fixing the neutron detector, the signal compensation detector, the filler cable, and the thermocouple; And a filler filled in the center tube and capable of attenuating fast neutrons.

Preferably, the filler cable is characterized by including a metal having an atomic number (Z) of 82 or more.

Preferably, the filler is characterized in that composed of a high molecular material containing a hydrogen atom.

According to the in-situ instrument with improved sensitivity for detecting neutron flux, the background signal can be reduced to facilitate neutron signal detection, and the current signal for thermal neutron detection can be largely obtained by reducing fast neutrons and improving the amount of thermal neutron incidence. In addition, as the overall background signal is reduced and the thermal neutron detection signal is improved, the neutron flux detection sensitivity is improved, the shape and position of the internal components of the measurement unit are kept stable, and the area of the emitter can be reduced by the improved neutron detection sensitivity. There is a cost saving effect.

1 is a side view of a conventional furnace instrument.
2 is a longitudinal cross-sectional view of a measuring unit AA of a conventional in-house measuring instrument.
3 is a diagram showing a relationship between a thermal neutron signal generated by an emitter and a background signal;
Figure 4 is a longitudinal cross-sectional view of the measuring unit of the furnace measuring instrument according to an embodiment of the present invention.
Figure 5 is a longitudinal cross-sectional view of the measuring unit of the furnace measuring instrument according to another embodiment of the present invention.

Figure 4 is a longitudinal cross-sectional view of the measuring unit of the in-vehicle measuring instrument according to an embodiment of the present invention. Referring to FIG. 4, the measuring unit 100 according to an exemplary embodiment of the present invention includes a filler cable 110, a filler 120, a central tube 130, a magnetic output neutron detector 140, and a signal compensation detector. 150, a thermocouple 160, and an outer protective tube 170.

The furnace measuring instrument of the present invention is the same as the structure of the conventional furnace measuring instrument 10 except for the measuring unit 100. In addition, the magnetic output neutron detector 140, the signal compensation detector 150, and the thermocouple 160 located inside the measurement unit 100 are the same as those used in the conventional furnace instrument 10. Thermocouple 160 is generally used in the chromel 161 and the alumel 162.

The configuration of the present invention for the first problem is as follows. The filler cable 110, which serves as a gamma ray shield, is disposed along the inside of the measurement unit. Since the magnetic output neutron detector 140 generates electrons by gamma rays in addition to the neutron rays, and the current generation by gamma rays is a background signal, it should be reduced.

The reason for being composed of a heavy material having an atomic number of Z = 82 or more is as follows. Gamma rays are usually shielded by materials with heavy elements, such as lead, because gamma rays, which have photonic properties, lose their energy as they pass through heavy materials with dense atomic arrangements. The atomic number of nickel corresponding to the main component of the filler cable 23 used is Z = 28. It is a hard alloy of copper or similar, but is less effective at shielding high-energy gamma rays, given that the atomic number of lead is Z = 82. Therefore, the material of the filler cable 110 of the present invention is composed of a heavy material whose main material is atomic number Z = 82 or more. For example, alloys such as lead alloy, lead alloy, lead alloy, lead alloy, and lead alloy may be used among lead alloys. That is, through the filler cable 110 of the present invention, it is possible to maximize the shielding efficiency of unnecessary gamma rays to reduce the amount of background signals generated.

On the other hand, the configuration of the present invention for the second problem is as follows. The inside of the central tube 130 is made of a polymer material including a hydrogen atom and filled with a filler 120 capable of attenuating incident fast neutrons. The reason for using the filler 120 to attenuate fast neutrons is as follows. All detectors have inherent detection efficiencies, a measure of how many neutrons are used to generate a signal when incident radiation enters the detector. In general, a magnetic output neutron detector detects a thermal neutron. When 100 thermal neutrons are incident, 20 thermal neutrons react with the emitter to generate a signal, and thus the detection efficiency is 20%. At this time, there are two ways to increase the detection efficiency of the thermal neutron. The first method is to increase the physical reaction area with the thermal neutron. This is a method of increasing the size and diameter of the emitter, there is a disadvantage of the unit cost increase due to the expensive emitter. The second method is to increase the number of incident thermal neutrons themselves. That is, if 200 thermal neutrons are incident, they will react with 40 thermal neutrons at an emitter with a detection efficiency of 20%. Although it is not a method of increasing the inherent efficiency itself, the amount of current signal generated by thermal neutrons can be doubled. Therefore, in the present invention, by filling the inside of the central tube 130 with the filler 120 using the second method to increase the signal generated by the thermal neutron according to the background signal vanadium, platinum already difficult to detect the thermal neutron measurement Complement the furnace instrument, which consists of a meter.

Specifically, neutrons in nuclear reactors can be broadly divided into rapid neutrons and thermal neutrons, which mostly react with emitters to generate signals and participate in nuclear fission. Rapid neutrons that do not generate the signals needed for detection lose energy and become thermal neutrons due to elastic or inelastic scattering reactions with attenuating materials. Generally, light polymers with high hydrogen content, such as paraffin and polyethylene, react with fast neutrons. It can attenuate the energy of fast neutrons. Therefore, when the filler is composed of elemental materials with low hydrogen content, some of the fast neutrons that enter the furnace instrument lose energy and become thermal neutrons, and the amount of current generated by the thermal neutrons increases. That is, in the furnace measuring apparatus of the present invention includes a filler 120 made of a polymer material including hydrogen atoms such as paraffin, polyethylene, epoxy, etc., and the amount produced by the thermal neutron increases as the filler 120 attenuates fast neutrons. do.

On the other hand, the configuration of the present invention for the third problem is as follows. The center tube 130 includes a guide groove 131, penetrates the inside of the measurement unit 100 in the longitudinal direction, and fills the center tube 130 with the filler 120. The center tube 130 and the filler cable 110 can basically fix the shape and position of the internal components, the guide groove 131 is the filler cable 110, magnetic output neutron detector 140, signal compensation The detector 150 and the thermocouple 160 are individually wrapped to fix the shape and position of each component more stably than before. The reason for minimizing the empty space in the measurement unit 100 by the filler 120 is as follows. The largest volume of the empty space inside the measurement unit 100 is the space inside the center tube 130, and thus the durability of the measurement unit 100 is improved by filling the inner space of the center tube 130 with the filler 120. . In addition, since the filler 120 is made of a good elastic material such as polyethylene and light, it can maintain the mechanical elasticity of the measuring unit 100 formed of a metal when the measuring unit 100 is bent. That is, in the present invention, the filler 120 may play a role of increasing the signal of the thermal neutron and simultaneously maintaining a structural integrity of the furnace instrument.

5 is a longitudinal cross-sectional view of a measuring unit of the in-vehicle measuring instrument according to another embodiment of the present invention. Referring to FIG. 5, the measuring unit 100 according to another exemplary embodiment of the present invention may be configured by deforming the shape of the guide groove 131 formed in the center tube 130.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It 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 present invention.

10: conventional furnace measuring instrument 20: measuring unit
21: center tube 22: thermocouple
22a: Cromel 22b: Alumel
23: filler cable 24: detector for signal compensation
25: Outer Protector 26: Blitnose
27: neutron detector 30: seal plug
40: flexible hose 50: connector
100: measuring unit 110: center tube
111: guide groove 120: filler
130: filler cable 140: neutron detector
150: signal compensation detector 160: thermocouple
161: Cromel 162: Alumel
170: outer protective tube

Claims (3)

In the furnace measuring instrument including a measuring unit inserted into the reactor to measure the neutron flux in the reactor,
The measurement unit,
A filler cable disposed along the inside of the measurement unit and shielding a gamma ray;
A center tube penetrating the inside of the measuring unit in a longitudinal direction;
A guide groove formed on a surface of the center tube and fixing the neutron detector, the signal compensation detector, the filler cable, and the thermocouple; And
An in-vehicle instrument with improved sensitivity to neutron flux detection, comprising: a filler filled in the center tube and capable of attenuating fast neutrons. The furnace measuring instrument of claim 1, wherein the filler cable comprises a metal having an atomic number (Z) of 82 or more. The in-vehicle instrument of claim 1, wherein the filler is made of a polymer material including hydrogen atoms.

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