JP2013213760A - Start-up range monitor calibration system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a start-up range monitor calibration system that achieves a reduction of a radiation exposure amount of an operator and a reduction of a number of apparatuses installed in a high-dose area without newly installing a signal line.SOLUTION: A start-up range monitor calibration system 50A is a system used for an inspection test of a start-up range monitor system 1 and comprises: a signal generator 51 for generating a calibration signal obtained by simulating reactor power with a sufficiently high level with respect to a level of external noise, a data acquisition device 22 for acquiring calibration data from an SRNM output monitor 7, a personal computer 52 that controls generation of the calibration signal and evaluates soundness of the start-up range monitor system 1 and a relay unit 53 for relaying the calibration signal and power supply to a multi-core cable 9, which are installed at a central control room 6 side; and a signal converter 54A that is installed at a reactor building 3 side and gives the power supply relayed to the multi-core cable and the calibration signal attenuated to an appropriate signal level by a signal attenuation section 64 to an SRNM pre-amplifier 5.

Description

  The present invention relates to a start-up area monitor calibration system that performs an inspection test of a start-up area monitor system that monitors the output state of a nuclear reactor in a nuclear power plant.

  FIG. 5 is a schematic diagram showing a configuration example of a startup region monitoring system during operation of a conventional nuclear power plant.

  The startup region monitoring system 1 is installed in a reactor pressure vessel, and SRNM (SRNM: Start up Ranged Neutron) that measures the neutron flux from inside the reactor pressure vessel from the viewpoint of measuring the reactor output state of the reactor startup region. The electrical signal output from the SRNM neutron flux detector 2 installed in the reactor building 3 and connected via the detector output cable 4 SRNM preamplifier 5 for receiving the power, and a function for receiving the electrical signal output from the SRNM preamplifier 5 and converting it into reactor output data and a function for supplying power to the SRNM amplifier 5 And an SRNM output monitoring device 7.

  The SRNM preamplifier 5 and the SRNM output monitoring device 7 are a preamplifier output cable 8 for transmitting the electric signal amplified by the SRNM preamplifier 5 to the SRNM output monitoring device 7 and the SRNM preamplifier 7. 5 is connected by a multi-core cable 9 for supplying power and transmitting signals.

  The SRNM output monitoring device 7 supplies power to the SRNM preamplifier 5 to the SRNM preamplifier 5 via a power line (not shown) in the multicore cable 9 and is used for interlocking in the multicore cable 9. The detachment state of the multi-core cable 9 is monitored via a signal line (not shown).

  Further, a high voltage of 200 V, for example, is applied to the detector output cable 4 for transmitting the electrical signal from the SRNM neutron flux detector 2 to the SRNM preamplifier 5 in order to give a bias voltage to the SRNM neutron flux detector 2. ing.

  Here, the preamplifier output cable 8 and the multi-core cable 9 are an SRNM preamplifier 5 installed in the reactor building 3 and an SRNM output monitor provided in a different building from the reactor building 3. In order to connect the apparatus 7, the length is several tens of meters or more, and in the case of being long, may exceed 100 meters. Therefore, from the viewpoint of protecting the electric signals propagating through the preamplifier output cable 8 and the multi-core cable 9 from external noise (preventing the mixing of external noise), they are respectively covered with the conduits 10 and 11 grounded every several meters. It has been broken.

  FIG. 6 is a schematic diagram illustrating a configuration example of the activation area monitor calibration system during the inspection test of the activation area monitor system 1.

  The startup area monitor calibration system 20 at the time of the inspection test of the startup area monitor system 1 is a system that performs an inspection test of the startup area monitor system 1 that is an object to be inspected, and is installed in the reactor building 3 to simulate the reactor output. A signal generator 21 as a signal generating means for generating a calibration signal and inputting it to the SRNM preamplifier 5 and a calibration signal installed in the central control room 6 and amplified by the SRNM preamplifier 5 And a data acquisition device 22 including calibration data acquisition means for acquiring the calibration data output from the SRNM output monitoring device 7 through the process of conversion into calibration data.

  The signal generation control of the signal generation device 21 is performed by, for example, a computer such as a personal computer 23 connected to the signal generation device 21, and the personal computer 23 functions as a signal generation control unit of the signal generation device 21. Further, the evaluation (soundness evaluation) of whether or not the activation area monitor system 1 is healthy is performed by, for example, a computer such as the personal computer 24 connected to the data acquisition device 22. It functions as a sex evaluation means.

  The data acquisition device 22 has a function of converting data into a format in which the personal computer 24 can take in the calibration data. The personal computer 24 receives the calibration data converted in the format by the data acquisition device 22, and based on the received calibration data. The soundness evaluation of the activation area monitor system 1 is performed.

  Further, when performing the inspection test of the activation region monitor system 1, the detector output cable 4 between the SRNM neutron flux detector 2 and the SRNM preamplifier 5 is removed, and the signal generator 21 is connected to the SRNM preamplifier 5 and Connected. Examples of the activation area monitor calibration system as described above include the following patent documents.

Japanese Patent Publication No. 6-34077 JP 2008-309548 A Japanese Patent Application No. 2003-403246

  For example, as shown in FIG. 6, the conventional startup area monitor calibration system performs an inspection test because the signal generator 21 and the personal computer 23 are installed in the reactor building 3 that is a high-dose area. In the meantime, workers in the reactor building are exposed, and the signal generator 21 and the personal computer 23 are also exposed for a long time, so that procedures relating to handling, storage, management and the like are complicated. Furthermore, since the signal generating device 21 and the personal computer 23 and the data acquisition device 22 and the personal computer 24 are installed in different places, the work in the soundness evaluation of the activation area monitor system 1 is complicated, and a skilled worker A lot of inspection test time is required.

  In order to solve such a problem, for example, as described in Patent Document 3, a personal computer and a signal generator are arranged in a central control room, a signal cable for an inspection test is provided, and a calibration signal is sent from the central control room. A technique for inputting to an SRNM preamplifier installed in a reactor building has been proposed.

  However, in the technique described in Patent Document 3, a calibration signal is input from the signal generator arranged in the central control room to the SRNM preamplifier installed in the reactor building. Compared with the prior art in which 21 and the personal computer 23 are installed, the longer the signal transmission path, the more susceptible to external noise. If the calibration signal, which is a minute signal of several microvolts to several tens of millivolts, is affected by external noise, there is a problem that it is difficult to evaluate the soundness of the activation area monitoring system based on the calibration signal. In addition, there is a demand to avoid newly providing a signal line for an inspection test as a countermeasure against external noise from the viewpoint of economy.

  The present invention has been made in consideration of the above-described circumstances, and reduces the radiation dose (time) of workers operating the activation area monitor calibration system and the activation area monitor calibration system installed in a high dose area. It is an object of the present invention to provide a start-up area monitor calibration system capable of evaluating the soundness of the start-up area monitor system without reducing the number of constituent elements related to the above and without newly installing a signal line for an inspection test.

  In order to solve the above-mentioned problem, an activation area monitor calibration system according to an embodiment of the present invention is installed in a reactor pressure vessel, and an SRNM neutron flux detector that measures a neutron flux from the reactor pressure vessel; An SRNM preamplifier for receiving an electrical signal output from the SRNM neutron flux detector installed in the reactor building and connected via a detector output cable, and installed in the central control room, and at least the reactor A function of receiving an electrical signal output from the SRNM preamplifier connected via a multicore cable having a signal line used for operation and a power supply line for supplying power, and converting it into reactor output data, and the SRNM A start-up area monitor used for an inspection test of a start-up area monitor system comprising an SRNM output monitoring device having a function of supplying power to an amplifier A signal generation means for generating a calibration signal simulating a reactor output at a sufficiently high signal level with respect to the level of external noise that can be superimposed on the calibration signal, and output from the signal generation means Signal relay means having a function of relaying the calibration signal to the signal line of the multi-core cable, and a first power source having a function of relaying the power supplied from the SRNM output monitoring device to the power line of the multi-core cable And a signal attenuating unit for attenuating the calibration signal propagating through the signal line of the multicore cable to a signal level to be input to the SRNM preamplifier, and the calibration signal attenuated by the signal attenuating unit Is connected to the SRNM preamplifier from which the detector output cable has been removed during the inspection test via an inspection test cable. Signal conversion means for input to the signal input stage of the detector, data acquisition means for acquiring calibration data obtained by converting the calibration signal amplified by the SRNM preamplifier by the SRNM output monitoring device, and the signal generation A signal generation control means for controlling the generation of the calibration signal in the means; and the activation region monitor based on the information that the signal generation control means controls the generation of the calibration signal and the calibration data received from the data acquisition means A soundness evaluation means for evaluating the soundness of the system is installed in the central control room, and the power relayed to the power line of the multicore cable is relayed to the power input means of the SRNM preamplifier. A second power supply relay means is installed in the reactor building.

  According to the present invention, it is possible to input a calibration signal in the central control room during an inspection test of the activation area monitor system, and it is possible to easily evaluate the soundness of the activation area monitor system. In addition, long-term operation by workers in the reactor building is eliminated and the exposure dose is reduced. Furthermore, the test equipment to be exposed becomes only the signal converter, and handling, storage, management and the like become easy.

Schematic which showed the example of a structure of the starting area monitor calibration system which concerns on the 1st Embodiment of this invention. Schematic which showed the example of a structure of the starting area monitor calibration system which concerns on the 2nd Embodiment of this invention. Schematic which showed the example of a structure of the starting area monitor calibration system which concerns on the 3rd Embodiment of this invention. Schematic which showed the example of a structure of the starting area monitor calibration system which concerns on the 4th Embodiment of this invention. Schematic which shows the structural example of the conventional starting area | region monitoring system at the time of nuclear power plant operation. Schematic which shows the structural example of the conventional starting area monitor calibration system which test-inspects the conventional starting area monitor system.

  Hereinafter, a startup area monitor calibration system according to an embodiment of the present invention will be described with reference to the accompanying drawings.

[First Embodiment]
FIG. 1 is a schematic diagram illustrating a configuration example of a first activation area monitor calibration system 50A that is an example of an activation area monitor calibration system according to the first embodiment of the present invention.

  In the following description, differences between the first activation area monitor calibration system 50A and the activation area monitor calibration system 20 will be mainly described, and components that are not substantially different will be denoted by the same reference numerals and description thereof will be omitted.

  The first activation area monitor calibration system 50A includes a data acquisition device 22 as data acquisition means for acquiring calibration data output from the SRNM output monitoring device 7, a signal generation device 51 as signal generation means, and a signal generation device. The signal generation control means for controlling the signal generation at 51 and the personal computer 52 as the soundness evaluation means of the start-up area monitor system 1, the calibration signal output from the signal generator 51 and the SRNM installed on the central control room 6 side A relay 53 that relays the power supplied from the output monitoring device 7 and a SRNM preamplifier that is installed on the reactor building 3 side and attenuates the calibration signal relayed from the relay 53 to a desired level internally. 5, and a first signal converter 54 </ b> A that inputs power supplied from the repeater 53 to the SRNM preamplifier 5.

  The repeater 53 includes input units 55 and 56 to which signals are input and an output unit 57 from which signals are output. The input unit 55 is connected to the output unit 57 via a calibration signal line 58a which is a signal transmission line, and the input unit 56 is connected to the output unit 57 via a power supply line 59a.

  Further, the first signal converter 54A outputs an input unit 61 to which a signal and power are input, an output unit 62 that outputs the power input to the input unit 61, and a signal input to the input unit 61. An output unit 63 and a signal attenuating unit 64 provided between the input unit 61 and the output unit 63 and attenuating a signal input to the input unit 61 to a desired level or less are provided. Here, reference numeral 58b is a calibration signal line, 59b is a power supply line, and 60 is a preamplifier input signal line which is a signal transmission line.

  In the first activation area monitor calibration system 50A described above, the multicore cable 9 is connected to the output unit 57 of the repeater 53 on the central control room 6 side. The SRNM output monitoring device 7 and the input unit 56 of the repeater 53 are connected by an inspection test multicore cable 66a.

  The inspection test multi-core cable 66a has the same configuration as the multi-core cable 9, and includes a power supply line and an interlock signal line. In addition, the interlock signal line in the inspection test multicore cable 66a is appropriately processed in the repeater 53 so as not to alarm.

  The SRNM output monitoring device 7 is connected via a data acquisition device 22 to a personal computer 52 provided with means (soundness evaluation means) for performing soundness evaluation of the activation area monitor system 1. The personal computer 52 further includes means for controlling the generation of a calibration signal (signal generation control means) in addition to the soundness evaluation means, and controls the generation of the calibration signal for the signal generator 51 connected thereto. . The calibration signal generated by the signal generator 51 is input to the input unit 55 of the repeater 53.

  On the other hand, on the reactor building 3 side, the multicore cable 9 is connected to the input unit 61 of the first signal converter 54A. Further, the power input stage of the SRNM preamplifier 5 and the first signal converter 54A are connected by a multicore cable 66b for inspection test.

  When inspecting the activation area monitor system 1, the detector output cable 4 from the SRNM neutron flux detector 2 is disconnected from the SRNM preamplifier 5, and the signal input stage of the SRNM preamplifier 5 and the first The output unit 63 of the signal converter 54A is connected by an inspection test cable 67. Here, the inspection test multicore cable 66b has the same configuration as the inspection test multicore cable 66a, and includes a power supply line and an interlock signal line.

  The power supplied from the SRNM output monitoring device 7 through the power line in the multicore cable 9 is supplied to the output unit 62 connected to the input unit 61 through the power line 59b, and further to the output unit 62 and the inspection test. Is supplied to the SRNM preamplifier 5 connected via the multicore cable 66b.

  The calibration signal supplied from the repeater 53 via the interlock signal line in the multicore cable 9 is given to the signal attenuating unit 64 connected to the input unit 61 via the calibration signal line 58b. The signal attenuating unit 64 attenuates the calibration signal to a desired signal level, for example, from one thousandth to several tens of thousands, that is, a signal level suitable for input to the SRNM preamplifier 5. The signal attenuating unit 64 supplies the attenuated calibration signal to the output unit 63 connected to the signal attenuating unit 64 via the preamplifier input signal line 60 which is a signal transmission line. Is supplied to the SRNM preamplifier 5 connected through the cable 67 for use.

  In the first startup area monitor calibration system 50A configured as described above, in order to confirm the soundness of the startup area monitor system 1 during the inspection test, the SRNM neutron flux detector 2 that detects the in-reactor neutron flux is used. A calibration signal is output from the signal generator 51 controlled by the personal computer 52 for the purpose of simulating an electrical signal generated by the neutron flux.

  Here, the calibration signal output from the signal generator 51 is, for example, several thousand times to several times the signal level required in advance by the SRNM preamplifier 5 from the viewpoint of reducing the influence of the external noise on the calibration signal. The signal is propagated to the first signal converter 54A in a state of being set to a sufficiently high signal level such as 10,000 times, and attenuated to a signal level suitable for input to the SRNM preamplifier 5 in the first signal converter 54A. . For example, when a calibration signal of several tens of microvolts is input to the SRNM preamplifier 5, the signal generator 51 can set the calibration signal level from several tens of millivolts to several hundreds of millivolts.

  In this way, the calibration signal generated at a sufficiently high signal level with respect to the external noise level that can be mixed during propagation is propagated at a sufficiently high signal level until just before being input to the SRNM preamplifier 5. Even if external noise is mixed into the calibration signal that is being propagated, the influence of the external noise can be reduced as compared with the case where the normal signal level is propagated. The signal level sufficiently higher than the external noise level is a signal level that is 100 times (= 40 dB) or more larger in voltage (or current) ratio. If there is such a level difference, even if external noise is superimposed on the signal, it will not affect the inspection test.

  The calibration signal output from the signal generator 51 is propagated through the interlock signal line in the multi-core cable 9 from the viewpoint of preventing external noise from being mixed into the calibration signal, and the reactor from the central control room 6 side. It is transmitted to the building 3 side. The calibration signal propagated through the multicore cable 9 and transmitted to the reactor building 3 side is input from the input unit 61 to the first signal converter 54A.

  In this way, by making the electric path through which the calibration signal propagates be an interlock signal line in the multicore cable 9 covered by the grounded conduit 11, the calibration signal is generated from the external noise generated from the nuclear power plant. It can be made less affected.

  Subsequently, the power supplied to the first signal converter 54A is supplied from the input unit 61 to the output unit 62 connected via the power supply line 59b, and from the output unit 62 to the inspection test multi-core cable 66b. Is supplied to the SRNM preamplifier 5 connected through the. In addition, the calibration signal input to the input unit 61 of the first signal converter 54A is input to the SRNM preamplifier 5 such as 1 / 1,000 to tens of thousands by the signal attenuating unit 64, for example. After that, the signal level is attenuated to an appropriate signal level, and then supplied to the output unit 63. Further, the signal level is supplied from the output unit 63 to the SRNM preamplifier 5 connected via the test test cable 67.

  The calibration signal input to the SRNM preamplifier 5 is amplified in the SRNM preamplifier 5 and input to the SRNM output monitoring device 7 via the preamplifier output cable 8. The SRNM output monitoring device 7 converts the calibration signal into calibration data and outputs it to the data acquisition device 22. The data acquisition device 22 converts the calibration data into data that can be taken into the personal computer, and transmits the data to the personal computer 52 as soundness evaluation means of the activation area monitor system 1.

  The personal computer 52 as soundness evaluation means of the start-up area monitor system 1 compares the data received from the data acquisition device 22 with the control information of the calibration signal output to the signal generator 51, and the SRNM neutron flux detector 2 The health evaluation of the activation area monitor system 1 excluding the above is performed.

  As described above, according to the first start-up area monitor calibration system 50A, the calibration signal can be input from the central control room 6 side during the inspection test. The amount of exposure of workers can be reduced. Further, in the first activation area monitor calibration system 50A, only the first signal converter 54A is exposed to the test equipment, and the number of test equipment is reduced as compared with the prior art. Therefore, handling, storage, management and the like are facilitated. .

  Furthermore, since the first signal converter 54A is composed of components that do not require a power source, wiring of the power source is unnecessary, and the ease of handling and economy can be improved. Furthermore, the signal generation means, data acquisition means, signal generation control means, and soundness evaluation means in the first activation area monitor calibration system 50A are all integrated (unified) on the central control room 6 side. Since the calibration signal can be input and the calibration data output from the SRNM output monitoring device 7 can be acquired on the control room 6 side, the soundness of the data can be easily evaluated.

  Furthermore, in the first activation area monitor calibration system 50A, the configuration (connection state) during operation of the nuclear power plant, that is, the activation area monitor system 1 is substantially compared with the activation area monitor system 1 of the conventional example. Therefore, the reactor power monitoring function and user operation and monitoring are not affected.

  The first activation area monitor calibration system 50A described above is an example in which an interlock signal line is used as a signal transmission line for a calibration signal. However, in place of the interlock signal line, it is not used during an inspection test. The signal transmission line may be used.

[Second Embodiment]
FIG. 2 is a schematic diagram showing a configuration example of a second activation area monitor calibration system 50B which is an example of the activation area monitor calibration system according to the second embodiment of the present invention.

  The second activation area monitor calibration system 50B is different from the first activation area monitor calibration system 50A in that a second signal converter 54B is provided instead of the first signal converter 54A. Therefore, in the description of the present embodiment, the description will focus on the second signal converter 54B, and the same components are denoted by the same reference numerals and description thereof is omitted.

  The second signal converter 54B removes electromagnetic noise from the first signal converter 54A before the signal attenuation unit 64, that is, to the calibration signal line 58b connecting the input unit 61 and the signal attenuation unit 64. The configuration includes a ferrite core 68 as an element. The ferrite core 68 is preferable in that it can easily remove electromagnetic noise because it does not require a power source or does not require grounding.

  In the second activation area monitor calibration system 50B configured as described above, the signal processing content in the second signal converter 54B, which is different from the first activation area monitor calibration system 50A, is different. With respect to the first signal converter 54A, the second signal converter 54B further provided with a ferrite core 68 effective in the measurement band of the activation area monitor system 1 in the previous stage (input side) of the signal attenuation unit 64 Before being input to the attenuating unit 64, the ferrite core 68 removes the external noise mixed in the calibration signal when propagating from the central control room 6 side to the reactor building 3 side, and the calibration signal from which the external noise has been removed. Is input to the signal attenuation unit 64. The signal processing content after the signal attenuating unit 64 is the same as that of the first signal converter 54A.

  As described above, according to the second activation area monitor calibration system 50B, the same effect as that of the first activation area monitor calibration system 50A can be obtained, and more central than the first activation area monitor calibration system 50A. The effect of removing external noise mixed during propagation from the control room 6 side to the reactor building 3 side can be enhanced. Therefore, according to the second activation area monitor calibration system 50B, it is possible to carry out an inspection test with higher accuracy than the first activation area monitor calibration system 50A.

[Third Embodiment]
FIG. 3 is a schematic diagram showing a configuration example of a third activation area monitor calibration system 50B which is an example of the activation area monitor calibration system according to the third embodiment of the present invention.

  The third activation area monitor calibration system 50C is different from the first activation area monitor calibration system 50A in that a third signal converter 54C is provided instead of the first signal converter 54A. Therefore, in the description of the present embodiment, the description will focus on the third signal converter 54C, and the same components are denoted by the same reference numerals and description thereof is omitted.

  The third signal converter 54C is a preamplifier input signal that connects the signal attenuator 64 after the signal attenuator 64, that is, the signal attenuator 64 and the output unit 63, with respect to the first signal converter 54A. The line 60 is further provided with a filter.

  For example, in the third signal converter 54C shown in FIG. 3, a low-frequency cutoff capacitor 71 and a high-frequency cutoff capacitor 72 are provided as filters. The low-frequency cutoff capacitor 71 is provided between the signal attenuating unit 64 and the output unit 63, and the high-frequency cutoff capacitor 72 is provided between the low-frequency cutoff capacitor 71 and the output unit 63, and the third signal converter. It is provided between the housing 73 of 54C.

  The low-frequency cutoff capacitor 71 and the high-frequency cutoff capacitor 72 are preferably capacitors having a withstand voltage equal to or higher than the bias voltage output from the SRNM preamplifier 5. If a capacitor having a withstand voltage equal to or higher than the bias voltage output from the SRNM preamplifier 5 is selected, the test can be performed with the bias voltage output from the SRNM preamplifier 5 applied, including the bias voltage circuit. This is because the soundness of the entire circuit system can be confirmed.

  In the third startup area monitor calibration system 50C configured as described above, the signal processing content in the third signal converter 54C, which is different from the first startup area monitor calibration system 50A, is different. In the third signal converter 54C in which a filter element is further provided at the subsequent stage of the signal attenuating unit 64 with respect to the first signal converter 54A, the signal processing content up to the signal attenuating unit 64 is the same as the first signal converter. Same as 54A. Thereafter, the calibration signal attenuated by the signal attenuating unit 64 is applied to the filter and is output from the output unit 63 after being filtered.

  In the third signal converter 54C shown in FIG. 3, by appropriately selecting the capacity of the low frequency cutoff capacitor 71, the DC current is cut off and low frequency noise outside the measurement band is greatly attenuated (cut off). Can serve as a high pass filter. For example, when the measurement band is 100 kHz to 10 MHz and the input impedance of the SRNM preamplifier 5 is 50Ω, the low frequency cutoff capacitor 71 has a cutoff frequency fc when the capacitance of the low frequency cutoff capacitor 71 is 0.1 μF. It becomes a high-pass filter of about 32 kHz, and low frequency noise at 32 kHz or less can be greatly reduced.

  Further, in the third signal converter 54C shown in FIG. 3, the high-frequency noise outside the measurement band can be greatly attenuated (cut off) by appropriately selecting the capacitance of the high-frequency cutoff capacitor 72 as well. It can serve as a low-pass filter. For example, when the path impedance is 1Ω, if the capacitance of the high-frequency cutoff capacitor 72 is 5000 pF, a low-pass filter having a cutoff frequency fc of about 32 MHz can be obtained, and high-frequency noise at 32 MHz or higher can be greatly reduced.

  As described above, by appropriately selecting the capacitances of the low-frequency cutoff capacitor 71 and the high-frequency cutoff capacitor 72, impedance matching of the transmission path in the measurement band can be achieved, and signal loss in the measurement band is eliminated.

  According to the third activation area monitor calibration system 50C, it is possible to configure an activation area monitor calibration system having the same effects as the first activation area monitor calibration system 50A and more resistant to noise.

  For example, by providing a low-frequency cutoff capacitor 71 as a low-pass filter, it is possible to cut off direct current and greatly reduce low-frequency noise outside the measurement band. Further, by providing the high-frequency cutoff capacitor 72 as a high-pass filter, high-frequency noise outside the measurement band can be significantly reduced. Furthermore, by providing the low-frequency cutoff capacitor 71 and the high-frequency cutoff capacitor 72, it can serve as a band-pass filter, cuts off direct current and significantly reduces low-frequency noise outside the measurement band, and It is possible to greatly reduce high frequency noise outside the measurement band.

  If the withstand voltages of the low-frequency cutoff capacitor 71 and the high-frequency cutoff capacitor 72 as filters are equal to or higher than the bias voltage output from the SRNM preamplifier 5, the bias voltage output from the SRNM preamplifier 5 (for example, , 100V, 200V, etc.) can be applied, and the soundness of the entire circuit system including the bias voltage circuit can be confirmed.

  In the example of the third activation area monitor calibration system 50C shown in FIG. 3, the low-frequency cutoff capacitor 71 and the high-frequency cutoff capacitor 72 are provided in the third signal converter 54C. If it is sufficient if a function as a filter is obtained, the high frequency cutoff capacitor 72 may be omitted. Conversely, if it is sufficient if the function of a high-pass filter is obtained, the low-frequency cutoff capacitor 71 may be omitted.

[Fourth Embodiment]
FIG. 4 is a schematic diagram showing a configuration example of a fourth activation area monitor calibration system 50D which is an example of the activation area monitor calibration system according to the fourth embodiment of the present invention.

  The fourth activation area monitor calibration system 50D is different from the first activation area monitor calibration system 50A in that a fourth signal converter 54D is provided instead of the first signal converter 54A. Therefore, in the description of the present embodiment, the description will be focused on, and the same components will be denoted by the same reference numerals and description thereof will be omitted.

  The fourth signal converter 54D is removed from the first signal converter 54A at the time of the inspection test in the low-frequency cutoff capacitor 71 and the first to third activation area monitor calibration systems 50A to 50C described above. And an input / output unit 75 for connecting the detector output cable 4 connected to the fourth signal converter 54D.

  The low-frequency cutoff capacitor 71 is provided between the signal attenuating unit 64 and the output unit 63, and cuts off direct current and significantly attenuates (cuts off) low-frequency noise outside the measurement band. The input / output unit 75 is connected between the preamplifier input signal line 60, the low frequency cutoff capacitor 71, and the output unit 63 via the SRNM neutron flux detector signal line 76 which is a signal transmission line. Note that the low-frequency cutoff capacitor 71 provided in the fourth signal converter 54D applies a bias voltage to the SRNM neutron flux detector 2 via the SRNM neutron flux detector signal line 76, as will be described later. The one having a withstand voltage higher than the bias voltage is selected.

  In the fourth activation area monitor calibration system 50D configured as described above, the detector output cable 4 is connected to the input / output unit 75 of the fourth signal converter 54D with respect to the first activation area monitor calibration system 50A. The difference is that the inspection test is carried out in this state. That is, in the fourth activation region monitor calibration system 50D, the SRNM preamplifier 5 and the SRNM neutron flux detector 2 are connected to the inspection test cable 67 and the fourth signal converter 54D (output unit 63, preamplifier input). The signal line 60, the SRNM neutron flux detector signal line 76 and the input / output unit 75) and the detector output cable 4 are connected, and the DC component due to the bias voltage is blocked by the low-frequency blocking capacitor 71. .

  By connecting the detector output cable 4 to the input / output unit 75, the fourth signal converter 54D can apply a bias voltage to the SRNM neutron flux detector 2, and SRNM while inputting the calibration signal. The electrical signal from the neutron flux detector 2 can be received by the SRNM preamplifier 5. Therefore, if a neutron flux simulation signal simulating the fuel loading state is input, the electrical signal from the SRNM neutron flux detector 2 mixed with irregular noise in a state equivalent to the measurement of the neutron flux before fuel loading is simulated. And the impact on measurement can be evaluated.

  According to the fourth activation area monitor calibration system 50D, the same effect as that of the first activation area monitor calibration system 50A can be obtained, and an electric signal from the SRNM neutron flux detector 2 can be input to the SRNM pre-set while inputting the calibration signal. The signal can be received by the amplifier 5.

  In addition, in the conventional activation region monitor calibration system 20 or the like in which the inspection output test is performed by removing the detector output cable 4 connected to the SRNM neutron flux detector 2, the electrical power from the SRNM neutron flux detector 2 is input while inputting the calibration signal. Although the signal cannot be received by the SRNM preamplifier 5, the fourth activation region monitor calibration system 50D receives the electrical signal from the SRNM neutron flux detector 2 by the SRNM preamplifier 5 while inputting the calibration signal. Therefore, it is possible to simulate an electrical signal from the SRNM neutron flux detector 2 mixed with irregular noise before fuel loading, and to evaluate the influence on measurement.

  That is, in the fourth activation area monitor calibration system 50D, an SRNM neutron flux detector in which irregular noise is mixed when the neutron flux before fuel loading, which cannot be evaluated by the conventional activation area monitor calibration system 20 or the like, is sufficiently low. The influence of the electrical signal from 2 on the measurement can also be evaluated. Therefore, after the conventional fuel loading, it is possible to prevent an event that irregular noise mixed in from the SRNM neutron flux detector 2 hinders measurement before starting the reactor.

  As described above, according to the first to fourth activation area monitor calibration systems 50A, 50B, 50C, and 50D, during the examination of the activation area monitor system 1, the test equipment installed (exposed) in the high-dose area is: Since only the signal converter is used and the test equipment to be exposed to the starting area monitor calibration system 20 is reduced, the radiation exposure amount (time) of workers operating the starting area monitor calibration systems 50A, 50B, 50C, 50D. , Reduction of components installed in the high-dose area, and easy handling, storage and management.

  In the first to fourth start-up area monitor calibration systems 50A, 50B, 50C, and 50D, at least one hundred times or more (several thousand times to several tens of thousands times in the above-described embodiment) until immediately before input to the SRNM preamplifier 5. A calibration signal having a high signal level, that is, a sufficiently high signal level with respect to external noise, is propagated from the central control room 6 to the SRNM preamplifier 5 and is input to the SRNM preamplifier 5 by the signal attenuator 14 immediately before being input. Attenuation from 1 / 1,000th to 1 / 10,000, so it is possible to reduce the effect of external noise without installing a new test test signal line. Can evaluate the soundness.

  Furthermore, in the first to fourth start-up area monitor calibration systems 50A, 50B, 50C, and 50D, the first to fourth signal converters 54A, 54B, 54C, and 54D are configured with components that do not require a power source. Therefore, the wiring of the power source is unnecessary, and the ease of handling and the economy can be improved.

  Furthermore, the signal generation means, data acquisition means, signal generation control means, and soundness evaluation means in the first to fourth activation area monitor calibration systems 50A, 50B, 50C, 50D are all integrated on the central control room 6 side. Since the central control room 6 can input calibration signals and obtain calibration data output from the SRNM output monitoring device 7, the soundness of the data can be easily evaluated. Can do.

  Furthermore, in the first to fourth startup area monitor calibration systems 50A, 50B, 50C, and 50D, the configuration (connection state) during operation of the nuclear power plant, that is, the startup area monitor system 1 is a conventional startup area monitor. Since it is not substantially different from the system 1, it does not affect the power monitoring function of the reactor and the operation and monitoring of the user.

  It should be noted that the present invention is not limited to the above-described embodiment as it is, and can be implemented in various forms other than the above-described examples in the implementation stage, and various modifications can be made without departing from the spirit of the invention. Can be omitted, added, replaced, or changed. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  For example, a configuration in which a ferrite core 68 is further added to the third start-up area monitor calibration system 50C shown in FIG. 3 or a low-frequency cutoff capacitor 71 and a high frequency are added to the third start-up area monitor calibration system 50C shown in FIG. A configuration in which any one of the blocking capacitors 72 is omitted can be employed as the activation area monitor calibration system according to the embodiment of the present invention.

DESCRIPTION OF SYMBOLS 1 Start area monitoring system 2 SRNM neutron flux detector 3 Reactor building 4 Detector output cable 5 SRNM preamplifier 6 Central control room 7 SRNM output monitoring device 8 Preamplifier output cable 9 Multi-core cables 10 and 11 Conduit 20 (Conventional) start-up area monitor calibration system 21 Signal generator 22 Data acquisition device (data acquisition means)
23 PC (Signal generation control means)
24 personal computer (health assessment means)
50A, 50B, 50C, 50D Start area monitor calibration system 51 Signal generator 52 Personal computer (signal generation control means and soundness evaluation means)
53 Repeaters 54A, 54B, 54C, 54D Signal Converter 55 Input Unit 56 Input Unit 57 Output Units 58a, 58b Calibration Signal Line (Signal Transmission Line)
59a, 59b Power line 60 Preamplifier input signal line (signal transmission line)
61 Input unit 62 Output unit 63 Output unit 64 Signal attenuation unit 66a, 66b Multi-core cable for inspection test 67 Cable for inspection test 68 Ferrite core (electromagnetic noise removing element)
71 Low-frequency blocking capacitor 72 High-frequency blocking capacitor 73 Housing 75 Input / output unit 76 SRNM neutron flux detector signal line

Claims (9)

An SRNM neutron flux detector installed in a reactor pressure vessel and measuring a neutron flux from the reactor pressure vessel, and the SRNM installed in a reactor building and connected via a detector output cable An SRNM preamplifier that receives an electrical signal output from the neutron flux detector, and a multi-core cable that is installed in the central control room and has at least a signal line used during reactor operation and a power supply line for supplying power SRNM output monitoring device having a function of receiving an electrical signal output from the SRNM preamplifier connected thereto and converting it into reactor output data and a function of supplying power to the SRNM amplifier Is a start-up area monitor calibration system used for the inspection test of
A signal generating means for generating a calibration signal simulating a reactor output at a sufficiently high signal level with respect to the level of external noise that can be superimposed on the calibration signal;
A signal relay unit having a function of relaying the calibration signal output from the signal generation unit to a signal line of the multicore cable;
First power relay means having a function of relaying power supplied from the SRNM output monitoring device to a power line of the multicore cable;
A signal attenuating unit for attenuating the calibration signal propagating through the signal line of the multicore cable to a signal level input to the SRNM preamplifier, and the calibration signal attenuated by the signal attenuating unit A signal conversion means for inputting to the signal input stage of the SRNM preamplifier via a test test cable connected to the SRNM preamplifier from which the detector output cable has been removed,
Data acquisition means for acquiring calibration data obtained by converting the calibration signal amplified by the SRNM preamplifier by the SRNM output monitoring device;
Signal generation control means for controlling the generation of the calibration signal in the signal generation means;
Based on the information that the signal generation control means controls the generation of the calibration signal and the calibration data received from the data acquisition means, the soundness evaluation means that evaluates the soundness of the activation area monitoring system is the central control. Installed in the room,
A start-up region characterized in that a second power relay means having a function of relaying the power source relayed to the power line of the multicore cable to a power input means of the SRNM preamplifier is installed in the reactor building. Monitor calibration system. The signal conversion means is configured by further providing an electromagnetic noise removing element on a signal line that guides the calibration signal input from the signal line of the multicore cable to the signal input unit from the signal input unit to the signal attenuation unit. The start-up area monitor calibration system according to claim 1. The signal conversion means allows the calibration signal attenuated by the signal attenuation unit to pass between the calibration signal attenuated by the signal attenuation unit and a signal output unit that outputs the calibration signal to the outside. At least one of a high-pass filter that cuts off a signal in a frequency band lower than the frequency band of the calibration signal and a low-pass filter that cuts off a signal in a frequency band higher than the frequency band of the calibration signal. Item 3. The starting area monitor calibration system according to Item 1 or 2. The signal converting means includes
When the high-pass filter is further provided, the high-pass filter includes a low-frequency signal blocking capacitor provided between the signal attenuating unit and the signal output unit,
In the case where the low-pass filter is further provided, an electric path connecting the signal attenuating unit and the signal output unit, and a metal housing installed on the reactor building side that houses the signal conversion unit, A high-frequency signal blocking capacitor provided between
In the case where the high-pass filter and the low-pass filter are further provided, the low-frequency signal blocking capacitor, the electric circuit connecting the low-frequency signal blocking capacitor, and the signal output unit, and the housing 4. The start-up area monitor calibration system according to claim 3, further comprising a high-frequency signal blocking capacitor provided. 5. The start-up area monitor calibration system according to claim 3, wherein the filter further provided in the signal conversion means has a voltage tolerance capable of withstanding the application of a bias voltage of the SRNM preamplifier during the inspection test. The signal output unit that outputs the calibration signal attenuated by the signal attenuation unit to the outside, and a signal input / output unit that is provided separately from the signal input unit and the signal output unit and serves as a signal input / output port with the outside 6. The start-up area monitor calibration system according to claim 5, further comprising a signal transmission path connected so that signal transmission is possible on the output side of the signal attenuating section. 7. The activation area monitor calibration system according to claim 1, further comprising a signal converter including the signal conversion unit and the second power supply relay unit. An interface to connect a computer;
8. The start-up area monitor calibration according to claim 1, further comprising data conversion means for converting the calibration data into a data format that can be captured by a computer connected via the interface. system. 9. The activation area monitor calibration system according to claim 8, wherein the signal generation control unit and the soundness evaluation unit are configured by a computer connected via the interface.

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