JP2001272495A - Reactor power monitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure the performance of startup range monitor detector even in the case the startup range monitor detectors are integrated in a detector assembly tube by thinning and prolonging. SOLUTION: A detector assembly tube 3 containing inside a local, power range monitor detector 4, a startup range monitor detector 5 and a calibration means 6, a startup range monitor surveillance device 7 for measuring the power of the startup range monitor detector 5 and watching reactor power and a local power range are provided. The startup range monitor detector 5 is provided with a plurality of electrode pairs having an anode and a cathode and insulation holding members for holding the gap between the two electrodes in a specific gap and insulating between both electrodes and with en electrode connection means for connecting these electrode pairs.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reactor power monitoring apparatus for monitoring a power distribution in a reactor pressure vessel (hereinafter, also referred to as "reactor interior") of a boiling water reactor (hereinafter, referred to as "BWR"). .

2. Description of the Related Art A reactor power monitoring device measures a neutron and displays the power of the reactor because the power of the reactor is proportional to the neutron flux, evaluates the burnup of fuel, and evaluates the power inside the reactor. It is used as an output detection means for reactor protection, such as shutting down a reactor at the time of excessive output.

This reactor power monitoring device is composed of a neutron detector and a signal processing device for amplifying and shaping the signal, and its measurement range is very wide, from the rated output to the 10th.
Since it is necessary to measure with high accuracy over a ^{-1 0} fold range, it is difficult to measure the full range in one type of measurement device. Therefore, in order to measure a region where the output at the time of starting the reactor is low, a start region monitor (SRNM: Start) is used.
-Up Range Neutron Monitor)
Is used, and in a high output area, a local output area monitor (LPRM: Local Power Range M) is used.
monitor) is used.

[0003] The SRNM further uses two measurement techniques. In the region where the reactor power is low, that is, when the reactor power is 10 ⁻⁹ % to 10 ⁻⁴ %, the number of output pulses of the detector is reduced. The start area output is monitored by counting (hereinafter, referred to as pulse measurement). On the other hand, the region where the reactor power is high, that is, the reactor power is 10 ⁻⁵ % to 10%
In this technology, the output of a nuclear reactor is monitored by measuring fluctuation power caused by overlapping of output pulses from a detector (hereinafter referred to as Campbell measurement). The LPRM detector is a set of four, and is vertically arranged in the axial direction in the reactor pressure vessel to form an in-core monitor assembly.

Conventionally, eight or ten SRNM detectors are usually installed in a reactor pressure vessel, and about 52 in-core monitor assemblies (about 208 LPRM detectors).
) Was installed. Then, the SRNM detector and the in-core monitor assembly were individually installed in a radial cross section in the reactor pressure vessel.

Further, the SRNM is used as a detecting element of a reactor protection function at the time of excessive power, detects an unexpected abnormal transient change occurring during operation, and issues a reactor emergency stop (reactor scram) signal. Shut down the reactor. Therefore, in order to detect this abnormal transient change, each detector in the reactor is assigned to a reactor protection system separation section.
In this reactor protection system separation section, the double “1 out of
A special logic circuit configuration such as “f2” and “2outof4” prevents unnecessary shutdown of the reactor due to malfunction and abnormal operation due to malfunction.

[0006] Incidentally, detectors such as SRNM detectors need to be regularly inspected and maintained. When maintenance and adjustment of these detectors is performed, if data at the time of adjustment is detected as abnormal data, A reactor emergency shutdown (reactor scram) signal is issued and the reactor shuts down.
Therefore, during maintenance and adjustment of the detector itself, the detector is excluded from normal monitoring, and this is called bypass. In order to perform this bypass, a grouping of detectors different from the reactor protection system separation section is performed.

In the reactor protection system separation section and the bypass group, the distribution of individual SRNM detectors is different. For this reason, recognition and handling of the detector become complicated by the operator who operates the reactor, which is a problem in operability.

On the other hand, in recent years, in order to increase the reactor power, the size of the reactor core, that is, the size of the reactor pressure vessel in the radial direction has been increasing. Along with this, it has become necessary to increase the number of SRNM detectors which has conventionally been eight or ten.

However, when the number of SRNM detectors is increased, many in-furnace guide tubes and flanges for the SRNM detectors must be provided, and the number of through-holes in the pressure vessel increases, thereby lowering reliability. In addition, there is a problem in that the cost is increased, and the complexity in the design and operation is further increased with the increase in the number of detectors.

[0010] Specifically, the current improved boiling water type (AB
WR) In a nuclear plant, 10 SRNM detectors
There are 52 bodies and in-core monitor assemblies, each of which is individually inserted and installed in the nuclear pressure vessel.
For this reason, the number of neutron detectors is 62 in total, and it is necessary to provide 62 guide tubes and flanges in the furnace.

On the other hand, there is a need for more efficient fuel exchange and higher burnup of fuel in a nuclear reactor. As one countermeasure, in the BWR, the fuel is replaced for each fuel bundle, which is an assembly of fuel rods. Therefore, it is conceivable to increase the size of the fuel bundle and increase the efficiency of replacement. At this time, the BWR has a structure in which a control rod and an SRNM detector or an in-core monitor assembly are inserted between the fuel bundles. However, as the fuel bundle becomes larger, these insertions are performed. Space is decreasing and an efficient detector arrangement is needed.

[0012]

As means for solving such a problem, it is conceivable that the SRNM detector and the LPRM detector are constituted by the same detector assembly.

However, the SRNM detector and the LPRM
The detectors have the following installation differences, and cannot be simultaneously installed in the same detector assembly with the current design, and it has been found that the structure of the sensor needs to be improved.

The first problem is that the SRNM detector and the LP
This is the difference in the measurement range from the RM detector. The SRM detector is larger than the LPRM detector,
The M detector is configured to store one in the detector assembly. That is, when the SRNM detector is inserted into the conventional in-core monitor assembly, the diameter of the detection unit of the SRNM detector needs to be smaller than that of the conventional one.

The SRNM detector comprises a fission detector, in which case the neutron sensitivity is determined by the amount of fissile material applied to the electrode surface. However, if the coating density per unit area of the electrode surface is increased, fission fragments generated by fission at the electrode will be attenuated by the applied fission material itself, so the sensitivity will increase even if the coating thickness is increased. do not do. Conventionally, the maximum coating thickness of uranium has been evaluated from the viewpoint of these conditions and manufacturing stability, and the electrode structure has been determined to have the smallest size that satisfies the sensitivity.

Therefore, even when the diameter of the cylindrical electrode of the SRNM detector is reduced, it is necessary to make the electrode area equal in order to make the neutron sensitivity equal to the conventional one. In other words, it has been found that the length of the cylindrical electrode needs to be increased as the diameter of the cylindrical electrode is reduced.

However, when the length of the SRNM detector is increased in order to store it in the in-core monitor assembly, it is very difficult to keep the electrode interval constant, and a countermeasure is required. That is, the electrodes of the SRNM detector are composed of a central anode and a cylindrical cathode provided on the outer peripheral side thereof, and the interval between the electrodes needs to be maintained at a constant interval of about 0.2 mm. .

The method of applying a fission substance to the inner surface of the cathode by flowing a coating substance from the lower part is used. In this method, when a long electrode is targeted, the lower part and the upper part of the cathode are used. There is a problem that the coating thickness is different between and. In addition, there is a problem that it is necessary to sufficiently reduce thermal distortion with the lengthening.

Next, a second problem is a measurement problem. SRNM is susceptible to extraneous noise because it performs pulse measurement and Campbell measurement that handle minute AC signals. Therefore, the SRNM is insulated from the reactor pressure vessel / detector support and the like, and is configured to be grounded only at the measurement device position.

On the other hand, since the LPRM performs direct current measurement, it is hardly affected by extraneous noise, which is mostly an AC component. Therefore, no special insulation is provided for these components.

Due to such measurement problems, the LPRM detector is configured such that the detector assembly is configured to actively contact the reactor water (about 300 ° C.) in order to cool the heat generated by the gamma rays in the reactor. Have been. On the other hand, the SRNM detector has a structure that does not come into contact with the reactor water from the viewpoint of the above-mentioned noise resistance, and the detector temperature is about 400 ° C. to 500 °
Considering that the temperature rises to about ° C, the structure is designed with excellent heat resistance.

Therefore, it has been found that the structure of the sensor itself needs to be reconsidered in order to store it in the same detector assembly at the same time due to such a difference in detector installation conditions.

The present invention has been made in view of the above circumstances, and even when the starting area monitor detector is integrated into the detector assembly tube to reduce the diameter and length, the starting area monitor detector is used. It is an object of the present invention to provide a reactor power monitoring device capable of ensuring the performance of a reactor.

[0024]

According to a first aspect of the present invention, there is provided a reactor power monitoring apparatus for monitoring the power in a reactor pressure vessel of a nuclear reactor. A local output area monitor detector for monitoring, a start area monitor detector for monitoring the output from start-up to output of the reactor, a calibration means for calibrating the sensitivity of the local output area monitor detector, and a local output area A monitor detector, a detector assembly tube for storing the activation area monitor detector and the calibrating means therein, an output of the activation area monitor detector, an activation area monitor monitoring device for monitoring the output of the nuclear power, Measuring a signal of the local output area monitor detector, comprising a local output area monitor monitoring device for monitoring the output of the nuclear power, the activation area monitor detector, the positive electrode and A plurality of electrode pairs having electrodes and an insulating holding member for holding the electrodes at predetermined intervals and insulating between the two electrodes, and electrode connection means for connecting these electrode pairs are provided. .

According to the first aspect of the present invention, the starting area monitor detector includes an electrode pair composed of a positive electrode, a negative electrode, an insulating holding member for electrically insulating these electrodes, and an electrode pair composed of these electrodes. Since a plurality of electrode connection means to be connected are separately provided, the diameter can be reduced for insertion into the detector assembly tube, and the effect of thermal deformation accompanying the lengthening can be divided into a plurality of electrodes. It can be reduced by connecting each with the electrode connecting means.

In particular, the heat resistance can be further improved by forming the electrode connecting means with a foil, a spring, or the like. Furthermore, it is easy to ensure uniformity of the uranium-coated surface during uranium coating by dividing the electrodes.

The local output area monitor detector and the activation area monitor detector are simultaneously calibrated by the calibrating means for calibrating the sensitivity of the local output area monitor detector to perform abnormality diagnosis and to measure the distribution in the axial direction of the reactor. I do. These detectors are stored in a detector assembly tube. The output of the active area monitor detector is measured by the active area monitor monitoring device according to its characteristics. The signals of the output area monitor detector are collectively measured by the local output area monitor monitoring device.

As a result, the starting area monitor detector, the output area monitor detector, and their calibration means can be stored in the same detector assembly tube, and the entire range of the reactor can be monitored collectively. Become. And the calibration of the detector is also possible with the same calibration system.

According to a second aspect of the present invention, in the reactor power monitoring apparatus according to the first aspect, the activation area monitor detector includes a detector for detecting radiation distributed in a height range equivalent to a reactor core. Features.

According to the second aspect of the present invention, in the activation area monitor detector, the detection section for detecting radiation is distributed within a height range equivalent to the core, so that the detection area in the axial direction of the activation area monitor detector is provided. Can be adjusted depending on the installation position. The activation area monitor detector includes a neutron detector,
That is, the electrode pair is not installed at one place, but is divided and distributed over the entire axial direction of the core, so that the electrode pair can be inserted into the detector assembly tube. With this split,
It is possible to reduce the sensor diameter and reduce the influence of thermal deformation and the like.

According to a third aspect of the present invention, in the reactor power monitoring apparatus according to the first or second aspect, the start area monitor detector is surrounded by surrounding means.

According to the third aspect of the present invention, since the starting area monitor detector is surrounded by the surrounding means, it is possible to realize a configuration in which reactor water does not come into contact with the starting area monitor detector. It is possible to improve the performance of the pulse propagation characteristics, which is the output of. Further, the output area monitor detector requiring cooling is in contact with the reactor water, and the start area monitor detector having excellent heat resistance can be stored simultaneously in the same detector assembly in a state insulated from the reactor water. As a result, the output area monitor detector and the activation area monitor detector having different heat-resistant specifications can be stored in the same detector assembly tube, and the number of detector assemblies to be inserted into the reactor can be reduced. Become.

According to a fourth aspect of the present invention, in the reactor power monitoring apparatus according to any one of the first to third aspects, the electrode pairs of the local power area monitor detector and the activation area monitor detector are formed in the same shape. It is characterized by the following.

According to the fourth aspect of the present invention, since the negative electrode coated with uranium can be applied to both the local output area monitor detector and the start area monitor detector, a common uranium coating apparatus at the time of manufacture is used. It is possible to stabilize the performance of the detector assembly itself that stores the information.
This makes it possible to reduce the cost and improve the reliability of the detector assembly by making the uranium electrodes of the local output area monitor detector and the activation area monitor detector stored in the same detector assembly the same. Become.

According to a fifth aspect of the present invention, in the reactor power monitoring device for monitoring the power in the reactor pressure vessel of the nuclear reactor, the detector for detecting radiation is distributed within a height range equivalent to the core. A detector for monitoring the entire range from the start of the reactor to the output of the entire range, and a power distribution monitoring means for calibrating the sensitivity of the detector for monitoring the full range and monitoring the power distribution in the core A detector assembly tube for storing the detector for all-range monitoring and the output distribution monitoring means, and a full-range monitoring device for measuring the output of the detector for full-range monitoring and monitoring the output of the nuclear power And characterized in that:

According to the fifth aspect of the present invention, the detector for monitoring the entire range monitoring can adopt a long sensor shape distributed in the axial direction of the reactor core. Until the rated output, it is possible to design a sensor that obtains an output proportional to the neutron flux in the reactor, more precisely, the axial average output of the installed position.

Conventionally, the local output area monitor detector and the start area monitor detector have provided a function of generating a reactor stop signal when the reactor is abnormal, that is, a trip function. With the use of the detector, it becomes possible to design a sensor having a high-speed response that satisfies a request for a trip response equivalent to that of the conventional local output area monitor detector and activation area monitor detector. Further, the axial power distribution of the reactor and the axial sensitivity distribution of the detector for the full range monitoring monitor are measured and calibrated by the power distribution monitoring means,
Diagnose abnormalities. These detectors are stored in a detector assembly tube. The outputs of the full-range monitoring monitor detector and the output distribution monitoring means are input to the full-range monitoring device and continuously monitor the output of the reactor.

By integrating the functions of the conventional active area monitor detector and local output area monitor detector into one long detector for monitoring the entire range monitor, the same detector assembly is provided. It becomes possible to integrate.

According to a sixth aspect of the present invention, in the reactor power monitoring apparatus according to any one of the first to fifth aspects, the anode of the electrode pair installed in the starting area monitor detector or the detector for the full range monitoring monitor is provided. In addition, a hollow portion is formed along the axial direction.

In the invention according to claim 6, since the anode is thermally insulated by a portion of the ionized gas other than the holding ceramics, the longer the length of the electrode, that is, the length of the electrode between the holding ceramics, the longer the anode. Although the heat generated by the gamma ray heat generation in the anode is difficult to escape, the increase in the heat generation due to the lengthening of the start area monitor detector is reduced by making the inside of the anode hollow.

Thus, the length and diameter of the activation area monitor detector can be increased, and the local output area monitor detector and the activation area monitor detector can be stored in the same detector assembly tube. In addition, the number of detector assemblies inserted into the reactor can be reduced.

According to a seventh aspect of the present invention, in the reactor power monitoring apparatus according to any one of the first to sixth aspects, the sensor case on the outer surface of the starting area monitor detector or the detector for the full range monitoring monitor is ceramic. An insulating layer is formed.

In the invention according to claim 7, the ceramic coating is directly applied to the surface of the sensor case of the starting area monitor detector or the detector for the full range monitoring monitor, so that an alumina component or the like is conventionally used as a spacer. In comparison, the diameter of the sensor can be reduced. This makes it possible to increase the length and diameter of the activation area monitor detector.

According to an eighth aspect of the present invention, in the reactor power monitoring system according to any one of the first to seventh aspects, the impedance of the plurality of electrode pairs and the electrode connection line connecting these are made the same. A matching device is provided.

According to the eighth aspect of the invention, when a plurality of electrodes are connected in series, reflection of a pulse signal occurs due to a difference in pulse transmission impedance between the connection portion and the electrode portion. By making the impedance the same as that of the electrodes, this pulse reflection can be prevented, and a long sensor or a sensor structure in which a plurality of detection units are scattered in the axial direction of the core can be realized.

As a result, the length of the activation area monitor detector can be increased, and the local output area monitor detector and the activation area monitor detector can be stored in the same detector assembly tube.

[0047]

Embodiments of the present invention will be described below with reference to the drawings.

[First Embodiment] FIG. 1 is a system configuration diagram showing a first embodiment of a reactor power monitoring apparatus according to the present invention.

As shown in FIG. 1, an in-core monitor detector assembly tube (hereinafter abbreviated as an assembly tube) is provided from below in a reactor core 2 installed in a reactor pressure vessel 1.
3 are inserted. In an actual nuclear reactor, a large number of the assembly tubes 3 are inserted as described above. However, FIG. 1 shows only one assembly tube 3 as a representative. The assembly tube 3 is provided with a plurality of holes 3a for guiding the reactor water therein.

In the assembly tube 3, an LPRM (local output area monitor) which is a fission detector or a self-powered detector (SPND) for monitoring the local output of the reactor is provided.
Detectors 4 (4a to 4d) are vertically arranged at four locations in the axial direction of the reactor core 2, and have a plurality of electrode pairs and electrode connection means. The SRNM monitors the output from the start of the reactor to the output. (Activation area monitor) A detector 5 is provided. In the assembly tube 3, a gamma thermometer 6 as a calibration means for calibrating the sensitivity of the LPRM detectors 4a to 4d is also arranged. As the calibration means, a mobile in-core monitor, an activated ball, or the like can be used other than the gamma thermometer 6. Therefore, the LPRM detector 4a is provided in the assembly tube 3.
~ 4d, SRNM detector 5 and gamma thermometer 6
Will be stored.

Further, the reactor power monitoring apparatus of this embodiment measures the output of the SRNM detector 5 inserted in the assembly tube 3 and other tubes installed in the reactor, and monitors the output of nuclear power. An SRNM monitoring device 7 that performs
LPRM monitoring device 8 that measures signals of LPRM detectors 4a to 4d inserted into tubes in assembly tube 3 and tubes installed in other furnaces and monitors the output of nuclear power.
And a GT monitoring device 9 for monitoring the output of the gamma thermometer 6 and for calibrating the sensitivity of the LPRM detectors 4a to 4d and the SRNM detector 5 and monitoring the power distribution in the core axis direction. 9 functions as a part of the reactor safety protection system.

FIG. 2 is a block diagram showing the structure of the SRNM detector 5 of FIG.

In the SRNM detector 5, five electrode pairs 11 (11 a to 11 e) are inserted into the inside of the sensor case 10 at fixed intervals, and these electrode pairs 11 a to 11 e are
Each of the cathodes 12 formed in a cylindrical shape, and the cathode 12
And a holding ceramic 14 as an insulating holding member that holds the cathode 12 and the anode 13 respectively and insulates them, respectively.

The cathode 12 and the anode 13 have a cylindrical cathode 1
In many cases, a positive voltage, that is, a voltage difference from +100 V to +500 V is applied to the anode 2 and the anode 13 disposed therein. In order to insulate this voltage and keep the distance between the electrodes constant, a holding ceramic 14 is used. As the holding ceramic 14, ceramics such as alumina, zirconia, and beryllia are generally used. Also,
The inner peripheral surface of the cathode 12 is coated with a fission material that is fissioned by neutrons, for example, uranium 15. In addition, this uranium 15 is not only the cathode 12 but also the anode 13 or the cathode 1.
2 and the anode 13 in some cases.

In the general SRNM detector, only one electrode pair 11 configured as described above is provided inside the sensor, but in this embodiment, the assembly tube 3 is provided.
As shown in FIG. 2, the electrode pair 11 is divided into two to five parts, and a cathode 13, an anode 12, and a holding ceramic 14, which are an electrode pair, are provided for each of them.
In order to connect the cathode 12 and the anode 13, each anode 13 is connected to the core wire of an MI cable (inorganic insulated cable) 16 as an electrode connecting means, while the cathode 12 is connected to the cathode 12.
A metal foil or the like is welded so that each can be electrically connected to the shield part of the MI cable 16.

Next, the operation of the present embodiment will be described.

Internally, LPRM detectors 4a to 4d, SRN
The assembly tube 3 supporting the M detector 5 and the gamma thermometer 6 is inserted into the core 2 in the reactor pressure vessel 1. Then, the LPRM detector 4a that monitors the local output
4d, the power at four locations in the axial direction of the core 2 is measured,
This measurement signal is transmitted to the LPRM monitoring device 8 and the LRM
The PRM monitoring device 8 monitors local fluctuations of the reactor together with detection signals of the LPRM detectors 4a to 4d installed in tubes inserted into the other reactors. That is, L
The PRM monitoring device 8 collectively measures the detection signals of the LPRM detectors 4a to 4d installed in the assembly tube 3 and other tubes inserted into the furnace.

As described above, L for monitoring the local power of the reactor
The PRM detectors 4a to 4d monitor the local fluctuation of the local output during the reactor rated operation at high speed, while
Monitors the output during reactor start-up and shutdown from reactor start-up to output. The output of the SRNM detector 5 is measured by the SRNM monitor 7 according to its characteristics. The SRNM monitoring device 7 collectively measures the detection signals of the SRNM detectors 5 installed in the assembled tube 3 and other tubes inserted into the furnace, similarly to the LPRM monitoring device 8.

The SRNM detector 5 has a positive electrode 13 and
Since a plurality of electrode connection means such as an MI pair 16 and an electrode pair 11 composed of a negative electrode 12 and a holding ceramic 14 for electrically insulating both electrodes are separately divided, the assembly tube 3 It is possible to reduce the diameter for insertion, and furthermore, by dividing into a plurality of electrode pairs 11 and connecting them by electrode connection means, it is possible to reduce the influence of thermal deformation and the like accompanying the lengthening, and to reduce the number of electrodes. One to one
By dividing 1, it is easy to ensure uniformity of the uranium-coated surface during uranium coating. By configuring the electrode connection means with a foil, a spring, or the like, the heat resistance can be further improved.

Further, the LPRM detectors 4a to 4d and the SRNM detector 5 are simultaneously calibrated by the gamma thermometer 6 as a calibrating means for calibrating the sensitivity of the LPRM detectors 4a to 4d, and an abnormality diagnosis is performed. The distribution of the direction is measured.

Thus, the LPRM detectors 4a to 4d
And the SRNM detector 5 and the gamma thermometer 6 serving as a calibration detector thereof can be stored in the same assembly tube 3, so that the entire range of the reactor can be monitored collectively. Further, the calibration of the detector can be performed by the same calibration system.

As described above, according to the present embodiment, the SRNM
The detector 5 is constituted by a plurality of electrode pairs 11,
Since it is possible to adopt a structure that is thinner and longer than a detector composed of one set of electrodes, it can be inserted into the assembly tube 3 and the holding ceramics 14 can prevent ingress of reactor water. it can.

Also, by using the plurality of electrode pairs 11 and the electrode connecting means configured as described above, even if the temperature becomes high due to the generation of gamma rays, deformation due to heat is prevented,
Further, it is possible to maintain the electrode spacing between the individual cathode 12 and anode 13 by the holding ceramics 14.

[Second Embodiment] FIG. 3 is a system configuration diagram showing a second embodiment of the reactor power monitoring apparatus according to the present invention. Note that the same or corresponding portions as those in the first embodiment are denoted by the same reference numerals, and redundant description will be omitted.
The same applies to the following embodiments.

As shown in FIG. 3, this embodiment employs a core 2
SRNM detector 1 so that it is distributed over the entire axial direction of
7 are arranged. That is, in the long SRNM detector 17, detectors for detecting radiation are distributed in a height range equivalent to the core 2.

In general, since the core 2 is about 4 m high, the SRNM detector is designed as a long SRNM detector 17 having a length corresponding to its height or about 20 cm or more. A detector having the same performance as the current SRNM detector can be installed in the current in-core monitor aggregate.

The electrode pair structure inside the long SRNM detector 17 has a structure in which the core is distributed uniformly in the height direction of the core and in a case where the electrode is concentrated and distributed near the position of the neutron source at the time of starting the reactor. The electrodes, that is, the sensitive parts, can be distributed at a height that matches the design. Therefore,
The detection range in the axial direction of the long SRNM detector 17 can be adjusted by its installation position. Other configurations and operations are the same as those of the first embodiment, and thus the description thereof is omitted.

As described above, according to the present embodiment, the long SRNM detector 17 is arranged so as to be distributed over the entire axial direction of the core 2.
Is arranged, sensors can be arranged at a plurality of positions in the height direction in order to improve the monitoring in the axial direction at the time of starting, and the average output in the axial direction can be monitored.
In addition, by making the SRNM detector longer than the conventional one and up to the maximum core height, the total electrode area in the sensor can be increased, thereby increasing the uranium coating amount, that is, the neutron sensitivity of the sensor. Neutron flux at the time of weak start-up can be monitored from a lower level than before even in a large core.

[Third Embodiment] FIG. 4 is a system configuration diagram showing a third embodiment of the reactor power monitoring apparatus according to the present invention.

As shown in FIG. 4, in the present embodiment, all-range sensors (detectors for monitoring all-range monitoring) 18a and 18b which are longer than the SRNM detector of the first embodiment are used.
And a gamma thermometer 6 similar to that of the first embodiment are installed in the assembly tube 3, and the output signals of the full-range sensors 18 a and 18 b are measured by the full-range monitoring device 19 while the output signals are output. The output signal of the gamma thermometer 6 as the distribution monitoring means is measured by the GT monitoring device 9.

Accordingly, the full-range monitoring device 19 measures the outputs of the full-range sensors 18a and 18b and monitors the output of nuclear power, while the gamma thermometer 6 calibrates the sensitivity of the full-range sensors 18a and 18b. The power distribution in the core 2 is monitored.

Next, the operation of the present embodiment will be described.

By the way, a general SRNM detector performs pulse measurement and Campbell measurement when the reactor is started and stopped. However, at the time of rated operation when the output of the reactor is increased, the filled gas accompanying the nuclear fission in the sensor is removed. The ionization amount cannot be collected by the voltage applied between the electrodes, and a saturation phenomenon occurs in which the output is not proportional to the fission amount, that is, the neutron intensity, and cannot be used for measurement.

However, as in this embodiment, the reactor height 4
In the case of having an electrode longer than 1/2 m, even if uranium for realizing the required neutron sensitivity is applied to the electrode, the electrode area of the detector is large. It is possible to design a sensor in which the amount is reduced. That is, by increasing the length of the SRNM detector, that is, by increasing the electrode area, it is possible to realize the full-range sensors 18a and 18b capable of monitoring from the starting region to the rated operation.

Therefore, all range type sensors 18a, 18a
8b can adopt a long sensor shape distributed in the axial direction of the reactor core 2, whereby the neutron flux and the neutron flux in the reactor from the low output at the time of starting the reactor to the rated output of the reactor are obtained.
To be more precise, it is possible to design a sensor that obtains an output proportional to the average output in the axial direction of the installed position.

In addition, when the reactor is abnormal, the LPR
The function (trip function) of generating a reactor stop signal with the M detector and SRNM detector was secured.
With these full-range sensors 18a and 18b, the SRNM
It is possible to design a high-speed response sensor that satisfies the same trip response requirements as the detector and the LPRM detector.

Further, the axial power distribution of the nuclear reactor and the axial sensitivity distribution of the full-range sensors 18a and 18b are measured and calibrated by the gamma thermometer 6 to perform abnormality diagnosis. The full-range sensors 18a and 18b and the gamma thermometer 6 are stored in the assembly tube 3.

Then, all range type sensors 18a, 18b
Is output to the full-range monitoring device 19, while the output signal of the gamma thermometer 6 is output to the GT monitoring device 9.
Is input to the entire range monitoring device 19, and the entire range monitoring device 19 continuously monitors the output of the reactor based on the calculation result.

As described above, according to the present embodiment, the SRNM
By integrating the functions of the detector and the LPRM detector into one long full-range sensor 18a, 18b, it becomes possible to integrate them in the same assembly tube 3.

Further, according to the present embodiment, the use of the full-range sensor 18 makes it possible to obtain a reactor safety which requires a conventional response, especially a fast response which cannot be monitored by the GT monitoring device 9. LP used for abnormality detection as a protection system and for generating a reactor stop signal (trip function)
The RM detector can be eliminated. However, the LPRM detector is used for the distribution measurement in the height direction (axial direction) in order to manage the burnup of the fuel or to flatten the output distribution, and the function is performed by the GT monitoring device 9.

Further, according to the present embodiment, in order to avoid redundancy of the reactor safety protection system, two range type sensors are used.
It is installed in the body and the assembly tube 3. With such a configuration, a simpler assembly tube 3 can be realized, and the measurement device can be more easily integrated than before.

[Fourth Embodiment] FIG. 5 is a system configuration diagram showing a fourth embodiment of the reactor power monitoring apparatus according to the present invention.

As shown in FIG. 5, this embodiment uses the SRN
The M detector 5 is surrounded by a dry tube 20 as a surrounding means, and the SRNM detector 5 is isolated from the reactor water. As a result, the tolerance of the SRNM detector 5 against external noise can be improved.

Further, using the dry tube 20 for the SRN
When the M detector 5 is configured not to be in contact with the reactor water, the SRNM detector 5 is heated by gamma ray heat generation. However, as in the configuration of the present embodiment, the electrode is divided into a plurality of parts to cool the central part of the electrode. Heat generation can be reduced by improving the effect. That is, the holding ceramics 14 are inserted into the center of the electrode pair 11, and the thermal conductivity of the holding ceramics 14 is several orders of magnitude higher than the thermal conductivity of air, so that the cooling effect is improved.

As described above, according to the present embodiment, the SRNM
Since the detector 5 is surrounded by the dry tube 20 and is isolated from the reactor water, the S is loaded into the assembly tube 3.
The noise tolerance of the RNM detector 5 can be improved, and a highly reliable system having excellent heat resistance can be constructed.

The dry tube 20 is used for SRNM.
A configuration in which reactor water does not come into contact with the detector 5 can be realized,
The performance of the pulse propagation characteristic output from the SRNM detector 5 can be improved. The LPRM detectors 4a to 4d requiring cooling are in contact with the reactor water, and the SRNM detector 5 having excellent heat resistance is isolated from the reactor water, and the same assembly tube 3
Can be stored simultaneously.

Due to these, LPRMs with different heat-resistant specifications
The detectors 4a to 4d and the SRNM detector 5 can be stored in the same assembly tube 3, and the number of assembly tubes 3 to be inserted into the nuclear reactor can be reduced.

[Fifth Embodiment] FIG. 6 is a sectional view showing an electrode pair of an SRNM detector in a reactor power monitoring apparatus according to a fifth embodiment of the present invention.

As shown in FIG. 6, the present embodiment
A hollow portion 21a is formed along the axial direction inside an anode 21 disposed at the center of the electrode pair 11 of the M detector 5 or the full range type sensors 18a and 18b. As a result, the amount of metal generated by gamma rays can be reduced, and the amount of heat generated by gamma rays can be reduced.

The hollow portion 21a of the anode 21 is sealed with a sensor gas such as vacuum or argon in advance and is hermetically welded. The hollow portion 21a is provided with a through portion and the gas in the hollow portion 21a leaks between the electrodes. Can be considered.

The anode 21 of the SRNM detector 5 has a long electrode length, that is, the length of the electrode between the holding ceramics 14 because the portion other than the holding ceramics 14 is thermally insulated by the sealed ionized gas. The more the heat generated by the gamma-ray heat generation in the anode 21 is less likely to escape, but in the above configuration, the increase in the heat generation due to the longer length of the SRNM detector 5 is reduced by making the inside of the anode 21 hollow.

In the present embodiment, the SRNM detector 5
By mixing helium with the enclosed gas, the thermal conductivity of the gas inside the detector can be improved, and the heat generation temperature of the sensor can be reduced. That is, by mixing helium, which is a rare gas having excellent thermal conductivity, into the sealed gas, it is possible to reduce an increase in the amount of heat generated due to the lengthening of the SRNM detector 5.

For example, by mixing about 50% helium with argon, the output current is reduced to about 1/2, but the thermal conductivity is more than doubled, and the heat mobility can be improved.

As a result, the length of the SRNM detector 5 can be increased,
The diameter can be reduced, and the LPRM detectors 4a to 4d and the SR
The NM detector 5 can be stored in the same assembly tube 3, and the number of insertions of the assembly tube 3 into the nuclear reactor can be reduced.

As described above, the use of the hollow anode 21 and the mixing of helium with the enclosed gas and the use of a dry tube or the like use the heat generated by the SRNM detector 5 which is loaded in the assembly tube 3 and becomes high in temperature. It is possible to reduce the temperature, thereby reducing the failure rate of the SRNM detector 5.

[Sixth Embodiment] FIG. 7 is a block diagram showing the structure of a ceramic-coated SRNM detector in a reactor power monitoring apparatus according to a sixth embodiment of the present invention.

As shown in FIG. 7, in this embodiment, the SRNM detector 5 (or the full-range sensor 18a,
A dry tube 20 is provided as a reactor water isolating means for isolating the dry tube 20 from the sensor case 10 of the SRNM detector 5 (or the full range type sensors 18a and 18b) in order to electrically insulate the dry tube 20 from the dry tube 20. The ceramic insulating layer 22 is formed on the surface.

That is, the outer surface of the sensor case 10 of the SRNM detector 5 is coated with a ceramic insulating material by a ceramic coating. This coating thickness is 1 ~
It has been confirmed that a sufficient insulation can be ensured at about 4 mm. As the ceramic, a material such as alumina having excellent coatability or silicon nitride or aluminum nitride having excellent heat conductivity is applied.

In the case where the outer surface of the sensor case 10 is ceramic-coated, it is possible to prevent ceramics from peeling off due to thermal stress by plating a metal such as chromium and then applying a ceramic.

In general, a ceramic part such as alumina is inserted as a spacer between the dry tube 20 and the sensor case 10 to ensure insulation between them. However, by using this embodiment, the sensor case 10 The air insulating layer between the ceramic coatings can be reduced, and the thermal conductivity from the sensor to the dry tube 20 can be improved. In addition, since the insulating film can be made thinner than a general ceramic part, the distance between the sensor case 10 and the dry tube 20 can be narrowed, thereby further increasing the escape of heat. The heat generation temperature can be reduced.

As described above, according to the present embodiment, the SRNM
Detector 5 or sensor case 1 of full-range sensor 18
By performing ceramic coating directly on the outer surface of the sensor, the diameter of the sensor can be reduced as compared with the case where an alumina component or the like is used as a spacer.

Therefore, the length of the SRNM detector 5 is increased,
The diameter can be reduced, and the LPRM detectors 4a to 4d and the SR
The NM detector 5 and the NM detector 5 can be stored in the same assembly tube 3, and the number of assembly tubes 3 to be inserted into the nuclear reactor can be reduced.

By the way, at least one of alumina, silicon nitride, and aluminum nitride having a high purity of 99.5% or more is used as the ceramic 14 for holding the SRNM detector 5 or the electrode pair 11 of the all-range sensor 18. It is possible to suppress a chemical reaction with an electrode which is a metal at a high temperature. Here, the purity of the holding ceramics 14 is 99.5.
%, The chemical reaction with the electrode cannot be suppressed.

Further, the use of silicon nitride or aluminum nitride having excellent thermal conductivity between the sensor case 10 and the dry tube 20 makes it possible to reduce the heat generated by gamma rays. Then, as the hermetic sealing component for sealing the sealing gas, silicon nitride with less swelling due to neutrons is used.

Therefore, the SRN is placed in the assembly tube 3.
When the M detector 5 is loaded, the heat generation temperature of the SRNM detector 5 can be reduced, and a system capable of performing stable monitoring can be constructed. That is, it is possible to reduce the temperature rise due to the gamma heat generated by making the SRNM detector 5 longer and smaller in diameter, and to maintain the sensor performance at a high temperature.

[Seventh Embodiment] FIGS. 8A and 8B are configuration diagrams showing the structures of an SRNM detector and an LPRM detector in a reactor power monitoring apparatus according to a seventh embodiment of the present invention.

As shown in FIG. 8, this embodiment uses the LPR
The electrode pair 11f of the M detector 4 and the electrode pairs 11a to 11e inside the SRNM detector 5 have the same structure. Thereby, the uranium application step of uranium 15 applied to the cathode 12 can be shared.

That is, in the present embodiment, the SRN having a plurality of electrode pairs 11a to 11e composed of negative electrodes having the same shape as the negative electrode shape of the electrode pair 11f of the LPRM detector 4 is used.
An M detector 5 is provided.

Therefore, the negative electrode 12 coated with uranium 15 is connected to the LPRM detector 4 and the SRNM detector 5
Can be applied in common, so that the uranium coating device at the time of manufacture can be shared, and the performance of the assembly tube 3 itself that stores these can be stabilized.

As described above, according to the present embodiment, LPRM
Since the electrode pair 11f of the detector 4 and the electrode pairs 11a to 11e inside the SRNM detector 5 are formed in the same shape, the uranium coating process of the uranium 15 applied to the cathode 12 can be shared. That is, the reliability of uranium coating, which is a key point of the sensor, is improved, and the manufacturing cost can be reduced.

Further, by using the same uranium electrode for the LPRM detector 4 and the SRNM detector 5 stored in the same assembly tube 3, the cost and reliability of the assembly tube 3 can be reduced. .

[Eighth Embodiment] FIG. 9 is an explanatory diagram showing a sensor connection state of an eighth embodiment of a reactor power monitoring apparatus according to the present invention, and FIG. 10 is an explanatory diagram showing a reflection waveform in the eighth embodiment. is there.

As shown in FIG. 9, when a plurality of electrode pairs 11a and 11b of the sensor are connected in series in the height direction of the core, the pulse of the electrode pair 11a and 11b of the sensor and the electrode connection line 23 connecting them are connected. When the transmission impedance is different, the pulse output of the detector is reflected, and the pulse waveform is deformed.

That is, as shown in FIG. 10, in the case where two electrode pairs 11a and 11b are used, a neutron reacts at the lower electrode pair 11b and a pulse signal is generated at that position (pulse generation position A ), A pulse is generated in the cable direction as shown by a and measured. However, when they are connected by a cable or the like, the pulse generated in the opposite direction is delayed and further reflected at the connection portion, and a multiplexed signal is finally measured.

In order to prevent the reflection, in the present embodiment, as shown in FIG.
And insert a ferrite core. Alternatively, an inductance component is added to the core portion, and the cable and the electrode connection line 23 are added.
Can be matched.

As described above, according to the present embodiment, the pulse reflection can be prevented by making the impedance of the electrode connection line 23 the same as that of the electrode pair 11a, 11b by the impedance matching unit 24, and the long sensor or the core can be prevented. It is possible to realize a sensor structure in which a plurality of detection units are scattered in two axial directions. Thereby, the length of the SRNM detector 5 can be increased.

According to the present embodiment, the impedance matching unit 24 is provided to prevent pulse reflection during pulse transmission inside the detector.
It is possible to prevent improper matching between the pulse impedances of 1a, 11b and the electrode connecting means 23, and it is possible to secure the pulse response characteristics of a normal detector even with a small-diameter and long sensor.

[0118]

As described above, according to the present invention, by dividing the electrodes of the active area monitor detector into a plurality of electrode pairs, the active area monitor detector can be placed in the detector assembly tube. Even when the diameter and the length are reduced so that they can be integrated, the performance of the start area monitor detector can be ensured.

Further, the realization of the integrated sensor assembly promotes the sharing of the detector itself and the sharing of the measuring device.
The space required for inserting the integrated sensor assembly into the reactor pressure vessel can be reduced, and the equipment configuration such as the flange of the reactor pressure vessel can be reduced accordingly.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram showing a first embodiment of a reactor power monitoring device according to the present invention.

FIG. 2 is a configuration diagram showing a structure of the SRNM detector of FIG. 1;

FIG. 3 is a system configuration diagram showing a second embodiment of the reactor power monitoring device according to the present invention.

FIG. 4 is a system configuration diagram showing a third embodiment of the reactor power monitoring device according to the present invention.

FIG. 5 is a system configuration diagram showing a fourth embodiment of the reactor power monitoring device according to the present invention.

FIG. 6 is a sectional view showing an electrode pair of an SRNM detector in a reactor power monitoring apparatus according to a fifth embodiment of the present invention.

FIG. 7 is a configuration diagram showing the structure of a ceramic-coated SRNM detector in a reactor power monitoring device according to a sixth embodiment of the present invention.

8 (A) and 8 (B) are an SRNM detector and an LP in a reactor power monitoring apparatus according to a seventh embodiment of the present invention.
The block diagram which shows the structure of an RM detector.

FIG. 9 is an explanatory diagram showing a sensor connection state of an eighth embodiment of the reactor power monitoring apparatus according to the present invention.

FIG. 10 is an explanatory diagram showing a reflection waveform in the eighth embodiment.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 reactor pressure vessel 2 core 3 in-core monitor detector assembly tube 4, 4a to 4d LPRM detector 5 SRNM detector 6 gamma thermometer (calibration means, power distribution monitoring means) 7 SRNM monitoring device 8 LPRM monitoring device 9 GT Monitoring device 10 Sensor case 11, 11a to 11f Electrode pair 12 Cathode 13 Anode 14 Holding ceramic (insulating holding member) 15 Uranium 16 MI cable (electrode connecting means) 17 Long SRNM detector 18a, 18b Full range sensor (all Range monitoring monitor detector) 19 All range monitoring device 20 Dry tube 21 Anode 22 Ceramic insulating layer 23 Electrode connecting wire 24 Impedance matching device

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (Reference) G21C 17/10 XJL (72) Inventor Yutaka Tanaka 1385-1 Shimoishigami, Otawara-shi, Tochigi Pref. Inside the plant (72) Inventor Teruji Tarumi 8 Shinsugita-cho, Isogo-ku, Yokohama-shi, Kanagawa Prefecture Inside the Toshiba Yokohama office (72) Inventor Akira Yuzuki 1 Toshiba-cho, Fuchu-shi, Tokyo Toshiba Fuchu plant F-term (Reference) 2G075 AA04 BA03 CA08 DA01 FA18 FA19 FB05 FC14 FC15 FC16 FC17 GA02 GA06 GA18 GA21 2G088 EE22 FF04 FF09 FF17 GG06 GG26 JJ01 JJ09 JJ31 JJ33 JJ37 LL11 LL21 LL27

Claims (8)

[Claims] A reactor power monitoring device for monitoring the power in a reactor pressure vessel of a reactor, comprising: a local power area monitor detector for monitoring a local power of the reactor; And a calibration means for calibrating the sensitivity of the local output area monitor detector, and a detection means for storing the local output area monitor detector, the activation area monitor detector and the calibration means therein. Vessel assembly tube, measuring the output of the activation area monitor detector, the activation area monitor monitoring device for monitoring the output of the nuclear power, measuring the signal of the local output area monitor detector, the output of the nuclear power A monitoring device for monitoring a local output area, wherein the activation area monitor detector holds the positive electrode and the negative electrode at a predetermined distance from each other, and insulates the two electrodes from each other. A reactor power monitoring device comprising: a plurality of electrode pairs each having an insulating holding member; and electrode connection means for connecting these electrode pairs. 2. The reactor power monitoring apparatus according to claim 1, wherein the starting area monitor detector has a detector for detecting radiation distributed in a height range equivalent to a reactor core. Monitoring device. 3. The reactor power monitoring device according to claim 1, wherein the starting area monitor detector is surrounded by surrounding means. 4. The reactor power monitoring device according to claim 1, wherein the electrode pairs of the local power region monitor detector and the activation region monitor detector are formed in the same shape. Furnace output monitoring device. 5. A reactor power monitoring device for monitoring the power in a reactor pressure vessel of a nuclear reactor, wherein a detector for detecting radiation is distributed within a height range equivalent to a reactor core, and the power is output after the reactor is started. A detector for monitoring the entire range monitoring up to the output of the entire range, power distribution monitoring means for calibrating the sensitivity of the detector for monitoring the entire range and monitoring the power distribution in the core, A detector assembly tube for storing the monitor detector and the output distribution monitoring means, and measuring the output of the detector for the full range monitoring monitor,
A reactor power monitoring device, comprising: a full range monitoring device for monitoring the output of the nuclear power. 6. The reactor power monitoring apparatus according to claim 1, wherein an anode of an electrode pair installed in a start area monitor detector or a detector for monitoring an entire range monitor is axially mounted on the anode. A reactor power monitoring device, wherein a hollow portion is formed along the reactor. 7. The reactor power monitoring device according to claim 1, wherein a ceramic insulating layer is formed on a sensor case on an outer surface of the start area monitor detector or the detector for monitoring the entire range monitor. A reactor power monitoring device characterized by the following. 8. The reactor power monitoring apparatus according to claim 1, further comprising: an impedance matching device for making a plurality of electrode pairs have the same impedance as an electrode connection line connecting them. A reactor power monitoring device characterized by the following.