JP4528496B2 - Reactor power monitoring device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a reactor power monitoring device that is used during operation of a power region of a nuclear reactor and monitors a neutron flux level in the reactor based on a detection signal output from a neutron detector installed in the reactor core.
[0002]
[Prior art]
A conventional reactor power monitoring apparatus is described in, for example, Patent Document 1 below, and has a configuration as shown in FIG. That is, a signal processing unit 12 to which a plurality of neutron detectors 1 are connected is provided. The signal processing unit 12 is connected to a plurality of detector signal processing cards 6 and these detector signal processing cards 6 via a parallel bus 11. The transmission card 13, the digital output card 7, the digital input card 8, the analog output card 9, the HM (human machine) interface card 14 and the main CPU card 10 are provided. The detector signal processing card 6 includes an amplifier, a digital signal converter 2, a CPU 3a, a program ROM 4a, a RAM 5a, and a bus interface 15a. The main CPU card 10 includes a bus interface 15b, a CPU 3b, a program ROM 4b, a RAM 5b, and a serial input / output unit (SIO).
[0003]
In the reactor power monitoring apparatus having such a configuration, signals from a plurality of neutron detectors 1 installed in the reactor are input to the detector signal processing card 6 of the signal processing unit 12. The signal from the neutron detector 1 is digitized by the digital signal converter 2 and then subjected to digital filter processing by the CPU 3a. The result is stored in the RAM 5a as a local output value (LPRM value) of each detector 1. Stored. The LPRM value stored in the RAM 5a is subjected to a trip determination of each LPRM value, an average output value (APRM value) calculation process from each LPRM value, a thermal output value (TPM value) calculation process, and a trip determination process in the CPU 3a. When an abnormality occurs, a trip output is output from the digital output card 7 via the parallel bus 11, and an operation result such as an APRM value is output from the analog output card 9 to the outside in analog form.
[0004]
[Patent Document 1]
JP-A-7-294688
[0005]
[Problems to be solved by the invention]
In the conventional reactor power monitoring apparatus, the detector signal is transmitted to the main CPU card 10 via the detector signal processing card 6 and the parallel bus 11. If the bus of one of the plurality of detector signal processing cards 6 fails, the LPRM values from the remaining detector signal processing cards 6 cannot be captured. As a result, it becomes impossible to capture signals from all the neutron detectors 1 and to monitor the reactor power.
[0006]
Accordingly, an object of the present invention is to provide a reactor power monitoring device capable of continuing monitoring of reactor power even if a part of a plurality of neutron detector signal processing units provided fails. To do.
[0007]
[Means for Solving the Problems]
The invention of claim 1 is installed in the core of a nuclear reactor. plural Neutron detector And each neutron detector A plurality of detector signal processing units that receive signals from and output digitized serial signals representing local reactor output values; each From the detector signal processor Input by independent serial transmission The serial signal is digitally added and averaged to calculate the average power value of the reactor It has an averaging circuit section and a trip determination section that outputs a trip signal With an averaging processor In the reactor power monitoring apparatus, the detector signal processing unit includes a trip determination unit that outputs a trip signal when the local output value is larger than a set value. The configuration.
[0008]
According to a second aspect of the present invention, the averaging processing unit monitors the operation status of the detector signal processing unit based on the presence or absence of the serial signal. Serial signal from the detector signal processor A diagnostic circuit unit excluded from the addition and averaging operations is provided.
[0009]
According to a third aspect of the present invention, the averaging processing unit includes a detector exclusion setting unit that excludes a serial signal from the specific detector signal processing unit from addition and averaging operations.
[0010]
According to a fourth aspect of the present invention, the averaging processing unit includes a determination circuit unit that checks whether the serial signal from the detection signal processing unit is appropriate and excludes the inappropriate serial signal from addition and averaging operations. The configuration is as follows.
[0011]
According to a fifth aspect of the present invention, the detection signal processing unit includes a calibration signal generation circuit provided in the input unit, and an operation state setting unit that sets operation states of the normal operation mode, the calibration mode, and the bypass mode. The self-operation state information is added to the serial signal, and the averaging processing unit is in a state where the detector signal processing unit is in a state other than the normal operation mode. Serial signal from the detector signal processor A determination circuit unit excluded from addition and averaging operations is provided.
[0012]
According to a sixth aspect of the present invention, the detection signal processing unit is configured to monitor a power supply voltage, a high voltage power supply voltage, a reference voltage, and other operating conditions used in the detection signal processing unit, and information from the monitoring unit. A serial signal conversion unit that serially transmits to the averaging processing unit as a series, the averaging processing unit compares information from the monitoring unit with a determination value to determine an operation status of the detector signal processing unit. Monitor for abnormalities Serial signal from the detector signal processor A determination circuit unit excluded from addition and averaging operations is provided.
[0013]
The serial signal converter that serially transmits information from the monitoring unit is the local output value of the nuclear reactor. The A serial signal conversion unit for serial transmission is used.
The invention according to claim 8 includes a plurality of averaging processing units, and the plurality of detector signal processing units are connected to the plurality of averaging processing units, respectively.
[0014]
The invention according to claim 9 is characterized in that the detector signal processing unit stores a parameter including a trip setting value and a detector signal correction coefficient sent from the averaging processing unit, and the averaging processing unit. A serial signal conversion unit that serially transmits the detector signal and parameter information in time series when a parameter change request is received from the device, and the averaging processing unit checks the request data and the response data, and the check result is incorrect In some cases, a determination circuit unit that outputs abnormality to the outside is provided.
[0015]
The invention of claim 10 is configured such that the detector signal processing unit and the averaging processing unit are mounted on a common motherboard.
In the eleventh aspect of the present invention, internal circuits of the detector signal processing unit and the averaging processing unit are configured by a highly integrated IC, and a monitor signal for outputting a signal necessary for functional verification of the internal circuit from the highly integrated IC. It is set as the structure provided with a part.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, the reactor power monitoring apparatus according to the first embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected. The signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and a serial signal conversion unit 19. The averaging processing card 23 includes a plurality of parallel signal conversion units 20 corresponding to the detector 1, an averaging circuit unit 21 to which signals from the plurality of parallel signal conversion units 20 are input, a digital filter unit 16b, and an analog output unit. 17b, a trip determination unit 18b, and a data transmission unit 22. In the large nuclear reactor core, for example, 208 detectors 1 are provided, and one detector is provided for 52 detectors, and all four signal processing units 12 are provided.
[0017]
The detector signal processing card 6 receives a signal from the detector 1 installed in the nuclear reactor. The input signal is digitized by the digital signal conversion unit 2 and filtered by the digital filter unit 16a to be a local output value (LPRM value). This LPRM value is compared with the set value in the trip determination unit 18a, and when it is larger or smaller than the set value, a trip output is generated.
[0018]
The LPRM value is input to the averaging processing card 23 by serial transmission via the serial signal converter 19. In order to process the signals of the plurality of detectors 1 in the signal processing unit 12, the same number of detector signal processing cards 6 as the detectors 1 are mounted, and from the serial signal conversion unit 19 of the detector signal processing card 6. The output is input to the averaging processing card 23 by independent serial transmission.
[0019]
In the averaging processing card 23, signals from all detector signal processing cards 6 in the signal processing unit 12 are input to the averaging circuit unit 21 via the parallel signal conversion unit 20. The averaging circuit unit 21 performs addition and averaging processing digitally to obtain an average output value (APRM value) and a heat output value (TPM value). The signal is input to the analog output unit 17b, the trip determination unit 18b, and the data transmission unit 22 via the digital filter unit 16b. Then, analog output is performed via the analog output unit 17b, and trip output is performed via the trip determination unit 18b. In addition, the LPRM value, the APRM value, the TPM value, and the trip determination result are transmitted and output to the host computer via the data transmission unit 22.
[0020]
In the reactor power monitoring apparatus of the first embodiment, signals from a plurality of detector signal processing cards 6 are input to the averaging processing card 23 through independent connections, so that the detector signal processing card 6 The reactor power monitoring function will not be lost even if it breaks down.
[0021]
The hardware configuration of the signal processing unit 12 is preferably as follows. That is, as shown in FIG. 2, a plurality of detector signal processing cards 6 and one averaging processing card 23 are mounted on a mother board (printed board) 32, and a plurality of detector signal processing cards 6 and one sheet are processed. The averaging processing card 23 is connected on the mother board 32. Further, the detector signal processing card 6 and the detector 1 are connected by a detector connector 33 provided on the rear surface of the mother board 32, the analog output is connected by an analog connector 34, and the trip output is connected to the trip output. The connector 35 is used, and the input / output connection with the host computer is made using the transmission connector 36. Further, the signal on the mother board 32 separates the analog system signal and the digital system signal so that the noise from the digital system signal does not enter the analog system.
According to this configuration, by making each connection through the mother board 32, the number of connection wirings can be reduced, and the reliability is improved.
[0022]
The averaging processing card in the reactor power monitoring apparatus of the first embodiment may be configured as shown in FIG. With the advancement of semiconductor technology, the digital signal processing portions of the detector signal processing card 6 and the averaging processing card 23 shown in FIG. 1 can be constituted by one highly integrated IC. However, this makes the function verification complicated due to the high integration. Therefore, for example, in the case of the averaging processing card 23, as shown in FIG. 3, the parallel signal conversion unit 20, the averaging circuit unit 21, the digital filter unit 16b, the trip determination unit 18b, and the data transmission unit 22 are combined into one highly integrated IC 37. Consists of. Of the signals of each part, the input signal to the averaging circuit part 21 is output to the monitor signal part 38, the input signal to the digital filter part 16b is output to the monitor signal part 39, and the input signal to the data transmission part 22 is monitored. Output to the signal unit 40. The operation of the parallel signal conversion unit 20 is verified by comparing the input signal to the averaging processing card 23 with the signal of the monitor signal unit 38, and the operation of the averaging circuit unit 21 is verified with the signal of the monitor signal unit 38 and the monitor. This is done by comparing the signals of the signal unit 39.
[0023]
According to this modification, the input / output of each unit can be used as a monitor, so that function verification can be easily performed. Further, even when the internal logic of the highly integrated IC 37 is nonconforming, the nonconforming portion can be separated in function units, and the maintainability is improved.
[0024]
Next, a second embodiment of the present invention will be described.
As shown in FIG. 4, the reactor power monitoring apparatus according to the second embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected. The signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and a serial signal conversion unit 19. The averaging processing card 23 includes a diagnostic circuit 24, a parallel signal conversion unit 20, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, and a data transmission unit 22.
[0025]
A diagnostic circuit 24 provided in parallel with the parallel signal conversion unit 20 of the averaging processing card 23 detects the presence / absence of a signal from the detector signal processing card 6 (the presence / absence of a signal due to disconnection or failure). When the diagnosis circuit 24 detects an abnormality, the signal is excluded from the addition and averaging operations in the averaging circuit unit 21. Also, the abnormality information is output to the outside. Then, reactor power monitoring is continued.
[0026]
The reactor power monitoring apparatus according to the second embodiment detects an abnormality of the serial signal by the diagnostic circuit 24, so that even when the serial signal is abnormal, the averaging process is performed without inputting the signal to the averaging processing circuit. Can be performed normally, and the reliability of the reactor power monitoring function is improved. Further, maintainability is improved by outputting the abnormality information to the outside.
[0027]
Next, a third embodiment of the present invention will be described.
As shown in FIG. 5, the reactor power monitoring apparatus according to the third embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected. The signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and a serial signal conversion unit 19. The averaging processing card 23 includes a parallel signal conversion unit 20, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, a data transmission unit 22, and a detector exclusion setting unit 25.
[0028]
By the setting of the detector exclusion setting unit 25 provided in the averaging processing card 23, the signal from the selected detector 1 is excluded from the addition and averaging operation in the averaging circuit unit 21. Thereby, when the detector signal processing card 6 is abnormal, the abnormal signal output from the detector is easily excluded from the averaging process, and the reactor output is continuously monitored by other signals.
[0029]
The reactor power monitoring apparatus according to the third embodiment excludes the signal from the abnormal detector signal processing card 6 from the addition and averaging operations in the averaging circuit unit 21 on the averaging processing card 23 side. Therefore, when the detector signal processing card 6 breaks down, it can be easily repaired and the maintainability is improved.
[0030]
Next, a fourth embodiment of the present invention will be described.
As shown in FIG. 6, the reactor power monitoring apparatus according to the fourth embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected, and the signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and a serial signal conversion unit 19. The averaging processing card 23 includes a parallel signal conversion unit 20, a determination circuit unit 26, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, and a data transmission unit 22.
[0031]
A determination circuit unit 26 provided between the parallel signal conversion unit 20 and the averaging circuit unit 21 of the averaging processing card 23 performs an appropriate serial signal check. If the check result is invalid, the signal is excluded from the addition and averaging operations in the averaging circuit unit 21, and the reactor output is continuously monitored normally even in the event of an abnormality.
[0032]
In the reactor power monitoring apparatus according to the fourth embodiment, the detection circuit unit 26 detects the abnormality of the serial signal, so that the detector signal can be normally averaged even when the serial signal is abnormal. In addition, the reliability of the reactor power monitoring function can be improved.
[0033]
Next, a fifth embodiment of the present invention will be described.
As shown in FIG. 7, the reactor power monitoring apparatus of the fifth embodiment includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected. The signal processing unit 12 includes a plurality of detector signals. A plurality of detector signal processing cards 6 as processing units and an averaging processing card 23 as an averaging processing unit are provided. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, serial signal conversion units 19 and 29, a calibration signal generation circuit 28, and an operation state setting unit 27. Yes. The averaging processing card 23 includes a parallel signal conversion unit 20, a determination circuit unit 26, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, and a data transmission unit 22.
[0034]
The operation state setting unit 27 provided in the detector signal processing card 6 sets the normal operation, calibration, and bypass operation states of the detector signal processing card 6. The calibration signal generation circuit 28 outputs a signal for the calibration. The serial signal converter 29 outputs a serial signal for online testing. The operation state information of the detector signal processing card 6 is added to the serial signal to the averaging processing card 23, and when the operation state is calibration, a signal from the calibration signal generation circuit 28 is input. Further, the determination circuit unit 26 provided in the averaging processing card 23 checks the operation state information in the serial signal, and when it is in a state other than the normal operation, the signal from the addition and averaging operations in the averaging processing unit 21 Is excluded.
[0035]
Since the reactor power monitoring apparatus of the fifth embodiment includes the operation state setting unit 27, the calibration signal generation circuit 28, and the serial signal conversion unit 29, the detector signal processing card 6 can be tested online. And maintainability can be improved.
[0036]
Next, a sixth embodiment of the present invention will be described.
As shown in FIG. 8, the reactor power monitoring apparatus according to the sixth embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected, and the signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a power supply voltage monitoring unit 30, a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and serial signal conversion units 19 and 19a. The averaging processing card 23 includes parallel signal conversion units 20, 20a, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, a data transmission unit 22, and a determination circuit unit 26.
[0037]
The power supply voltage monitoring unit 30 converts the power supply voltage inside the detector signal processing card 6, the high voltage power supply voltage applied to the detector 1, the reference power supply voltage necessary for A / D conversion, etc. into digital values and monitors them. The serial signal converter 19a transmits the converted data to the averaging processing card 23 as a time-series serial signal separately from the LPRM signal. The parallel signal conversion unit 20a provided in the averaging processing card 23 receives the data, and the determination circuit unit 26 determines the received data. When the received data is abnormal, the signal is excluded from the addition and averaging operations in the averaging circuit unit 21. Further, the abnormality detected by the determination circuit unit 26 is output to the outside. In this way, the reactor power is continuously monitored even in the event of an abnormality.
[0038]
In the sixth reactor power monitoring apparatus, the power supply voltage monitoring unit 30 to the determination circuit unit 26 detect an abnormality in the detector signal processing card 6, and when the abnormality is detected, the signal is excluded from the averaging process. Thus, the reliability of the reactor power monitoring function can be improved. Also, maintainability can be improved by outputting an abnormality to the outside.
[0039]
Next, a seventh embodiment of the present invention will be described.
As shown in FIG. 9, the reactor power monitoring apparatus according to the seventh embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected, and the signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a power supply voltage monitoring unit 30, a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and a serial signal conversion unit 19. The averaging processing card 23 includes a parallel signal conversion unit 20, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, a data transmission unit 22, and a determination circuit unit 26.
[0040]
The data of the power supply voltage monitoring unit 30 is transmitted in time series by the serial signal conversion unit 19 using the same serial signal as the LPRM signal. Further, the parallel signal conversion unit 20 provided in the averaging processing card 23 receives the data, and the determination circuit unit 26 determines the received data. The determination circuit unit 26 of the averaging processing card 23 compares this voltage value with the determination value to determine the operating state of the detector signal processing card 6, and in the case of an abnormality, addition and averaging operations in the averaging circuit unit 21 are performed. The signal is excluded from Further, the abnormality detected by the determination circuit unit 26 is output to the outside. In this way, the reactor power is continuously monitored even in the event of an abnormality.
[0041]
In the reactor power monitoring apparatus according to the seventh embodiment, the abnormality of the detector signal processing card 6 is detected by the power supply voltage monitoring unit 30 to the determination circuit unit 26, and when the abnormality is detected, the signal is excluded from the averaging process. Thus, the averaging process can be performed normally, and the reliability of the reactor power monitoring function can be improved. Also, maintainability can be improved by outputting an abnormality to the outside.
[0042]
Next, an eighth embodiment of the present invention will be described.
In the reactor power monitoring apparatus of the eighth embodiment, as shown in the block diagram of FIG. 10, a signal processing unit 12 connected to a plurality of neutron detectors 1 and connected to each other by an optical cable 31 is provided. The signal processing unit 12 includes a plurality of detector signal processing cards 6 that are a plurality of detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, and a serial signal conversion unit 19. The averaging processing card 23 includes a parallel signal conversion unit 20, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, and a data transmission unit 22. That is, the detector signal processing card 6 is provided with two systems of serial signal converters 19 and is connected to the two systems of averaging processing cards 23 that require signals through the optical cable 31.
[0043]
According to the eighth embodiment, even in the case of a small furnace with a small number of detectors 1 (for example, 80), the signals of the detectors 1 are transferred between the signal processing units 12, and the averaging processing card 23 The number of per detector 1 can be increased. In signal transmission, physical separation between systems is protected, and high measurement accuracy is obtained. Therefore, an output monitoring system that conforms to the system specifications can be easily configured even for a small furnace with a small number of detectors 1.
[0044]
Next, a ninth embodiment of the present invention will be described.
As shown in FIG. 11, the reactor power monitoring apparatus according to the ninth embodiment of the present invention includes a signal processing unit 12 to which a plurality of neutron detectors 1 are connected, and the signal processing unit 12 includes a plurality of detection units. A plurality of detector signal processing cards 6 that are detector signal processing units, and an averaging processing card 23 that is an averaging processing unit. The detector signal processing card 6 includes a digital signal conversion unit 2, a digital filter unit 16a, an analog output unit 17a, a trip determination unit 18a, a serial signal conversion unit 19, a parallel signal conversion unit 20b, and a parameter storage unit 41a. The averaging processing card 23 includes a parallel signal conversion unit 20, an averaging circuit unit 21, a digital filter unit 16b, an analog output unit 17b, a trip determination unit 18b, a data transmission unit 22, a parameter storage unit 41b, a display operation unit 43, and a determination circuit. And a serial signal converter 19b.
[0045]
A parameter storage unit 41a provided in the detector signal processing card 6 stores parameters used in the digital filter unit 16a and the trip determination unit 18a. The parallel signal conversion unit 20b receives parameters sent as serial signals from the averaging processing card 23. A display operation unit 43 provided in the averaging processing card 23 displays processing results and sets parameters. The serial signal conversion unit 19b provided in the averaging processing card 23 sends parameters to the detector signal processing card 6 as a serial signal. The determination circuit unit 42 checks the data transmitted from the serial signal conversion unit 19b and the data sent back as a response.
[0046]
When the parameters of the detector signal processing card 6 are changed, the data set by the display operation unit 43 is sent to the detector signal processing card 6 to be changed via the serial signal conversion unit 19b. The detector signal processing card 6 receives data via the parallel signal conversion unit 20b, stores the data in the parameter storage unit 41a, and sends it to each unit. For example, if the parameter is a trip set value, it is sent to the trip determination unit 18a, and if the parameter is an LPRM calculation coefficient, it is sent to the digital filter unit 16a. The parameters stored in the parameter storage unit 41a are transmitted to the averaging processing card 23 along with the LPRM signal via the serial signal conversion unit 19 in time series. The parameter response data sent to the averaging processing card 23 is input to the determination circuit unit 42, compared with the transmitted parameter, and the determination result is displayed on the display operation unit 43. Even when each parameter is changed not by the individual detector signal processing card 6 but managed by a single averaging processing card 23, the change result is checked and determined as response data.
[0047]
In the reactor power monitoring apparatus of the ninth embodiment, the parameter change of a plurality of detector signal processing cards 6 is performed by one display operation unit 43, and the determination result is checked by the determination circuit unit 42 as response data. Therefore, the reliability at the time of parameter change can be improved.
[0048]
Although the first to ninth embodiments of the present invention have been described above, the configuration described with reference to FIG. 2 and the configuration described with reference to FIG. The present invention can also be applied to the embodiment.
[0049]
【The invention's effect】
According to the present invention, it is possible to provide a reactor power monitoring device that can continue monitoring reactor power even if some of the neutron detector signal processing units provided are broken. .
[Brief description of the drawings]
FIG. 1 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a first embodiment of the present invention.
FIG. 2 shows a configuration of a main part of the reactor power monitoring apparatus according to the first embodiment of the present invention, where (a) is a top view and (b) is a rear view.
FIG. 3 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a modification of the first embodiment of the present invention.
FIG. 4 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a second embodiment of the present invention.
FIG. 5 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a third embodiment of the present invention.
FIG. 6 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a fourth embodiment of the present invention.
FIG. 7 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a fifth embodiment of the present invention.
FIG. 8 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a sixth embodiment of the present invention.
FIG. 9 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a seventh embodiment of the present invention.
FIG. 10 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to an eighth embodiment of the present invention.
FIG. 11 is a diagram showing a circuit and signal flow of a reactor power monitoring apparatus according to a ninth embodiment of the present invention.
FIG. 12 is a diagram showing a circuit and signal flow of a conventional reactor power monitoring apparatus.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Neutron detector, 2 ... Digital signal conversion part, 3a, 3b ... CPU, 4a, 4b ... Program ROM, 5a, 5b ... RAM, 6 ... Detector signal processing card, 7 ... Digital output card, 8 ... Digital Input card, 9 ... Analog output card, 10 ... Main CPU card, 11 ... Parallel bus, 12 ... Signal processing unit, 13 ... Transmission card, 14 ... HM interface, 15a, 15b ... Bus interface, 16a, 16b ... Digital filter section, 17a, 17b ... analog output unit, 18a, 18b ... trip determination unit, 19, 19a, 19b ... serial signal conversion unit, 20, 20a, 20b ... parallel signal conversion unit, 21 ... averaging circuit unit, 22 ... data transmission unit , 23 ... Averaging processing card, 24 ... Diagnostic circuit, 25 ... Detector exclusion setting unit, 26 Judgment circuit unit 27 ... Operating state setting unit 28 ... Calibration signal generating circuit 29 ... Serial signal conversion unit 30 ... Power supply voltage monitoring unit 31 ... Optical cable 32 ... Motherboard 33 ... Detector connector 34 ... Analog Connector, 35 ... Trip connector, 36 ... Transmission connector, 37 ... Highly integrated IC, 38, 39, 40 ... Monitor signal section, 41a, 41b ... Parameter storage section, 42 ... Determination circuit section, 43 ... Display operation section.

Claims (11)

A plurality of neutron detectors installed in the core of the reactor, a plurality of detector signal processing units that receive a signal from each neutron detector and output a digitized serial signal representing a local output value of the reactor; The serial signal input by serial transmission independent from each detector signal processing unit is digitally added and averaged to calculate the average output value of the reactor and trip determination to output a trip signal In the reactor power monitoring device comprising an averaging processing unit having a unit,
The detector signal processor is the local output value set value trip determination unit reactor power monitoring apparatus characterized that you include a for outputting a trip signal when greater than. The averaging processing unit monitors the operation status of the detector signal processing unit based on the presence or absence of the serial signal, and in the case of abnormality, a diagnostic circuit that excludes the serial signal from the detector signal processing unit from addition and averaging operations The reactor power monitoring apparatus according to claim 1, further comprising a unit.   2. The reactor output according to claim 1, wherein the averaging processing unit includes a detector exclusion setting unit configured to exclude serial signals from the specific detector signal processing unit from addition and averaging operations. Monitoring device.   The averaging processing unit includes a determination circuit unit that checks whether a serial signal from the detection signal processing unit is appropriate and excludes an inappropriate serial signal from addition and averaging operations. Item 1. The reactor power monitoring apparatus according to Item 1. The detection signal processing unit includes a calibration signal generation circuit provided in the input unit, and an operation state setting unit that sets operation states of a normal operation mode, a calibration mode, and a bypass mode, and operates on the serial signal. A state information is added, and the averaging processing unit determines to exclude the serial signal from the detector signal processing unit from addition and averaging operations when the detector signal processing unit is in a state other than the normal operation mode. The reactor power monitoring apparatus according to claim 1, further comprising a circuit unit. The detection signal processing unit includes a monitoring unit that monitors operation states such as a power supply voltage, a high-voltage power supply voltage, and a reference voltage used in the detection signal processing unit, and the averaging processing unit using information from the monitoring unit as a time series. A serial signal conversion unit that performs serial transmission, and the averaging processing unit compares the information from the monitoring unit with a determination value to monitor the operation status of the detector signal processing unit. The reactor power monitoring apparatus according to claim 1, further comprising a determination circuit unit that adds the serial signal from the detector signal processing unit and excludes the serial signal from the averaging calculation. 7. The reactor power monitoring apparatus according to claim 6, wherein the serial signal conversion unit that serially transmits information from the monitoring unit is a serial signal conversion unit that serially transmits a local output value of the reactor.   The reactor power monitoring apparatus according to claim 1, further comprising a plurality of averaging processing units, wherein the plurality of detector signal processing units are connected to the plurality of averaging processing units, respectively.   The detector signal processing unit includes a parameter storage unit that stores parameters including a trip set value and a detector signal correction coefficient sent from the averaging processing unit, and a parameter change request from the averaging processing unit. A serial signal conversion unit that serially transmits the device signal and parameter information in a time series, and the averaging processing unit checks the request data and the response data, and if the check result is invalid, The reactor output monitoring apparatus according to claim 1, further comprising a determination circuit unit for outputting.   The reactor power monitoring apparatus according to claim 1, wherein the detector signal processing unit and the averaging processing unit are mounted on a common motherboard.   An internal circuit of the detector signal processing unit and the averaging processing unit is configured by a highly integrated IC, and includes a monitor signal unit that outputs a signal necessary for functional verification of the internal circuit from the highly integrated IC. The reactor power monitoring apparatus according to any one of claims 1 to 9, wherein

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