KR20220008148A - An interlock bypass device and an interlock system comprising the interlock bypass device - Google Patents

Abstract

The present invention relates to an interlocking device and an interlocking system including the same, capable of preventing or stopping facilities of a nuclear power facility when an abnormality occurs. The interlocking system includes: an emergency stop system connected to a plurality of nuclear power facilities, and configured to output an interlocking signal to at least one nuclear power facility according to a preset alarm signal to perform emergency stop on an operation of the at least one nuclear power facility; and at least one bypass device including a first driving circuit for inducing generation of the interlocking signal by applying the alarm signal to the emergency stop system, and configured to supply a power to one of a first path passing through a radiation monitoring system that detects an abnormal situation of a specific nuclear power facility or a second path bypassing the radiation monitoring system so as to block transmission of the alarm signal obtained according to an abnormal situation detection result of the radiation monitoring system to the emergency stop system.

Description

AN INTERLOCK BYPASS DEVICE AND AN INTERLOCK SYSTEM COMPRISING THE INTERLOCK BYPASS DEVICE

The present invention relates to an interlock system including an interlock device and an interlock device for preventing or stopping facilities of a nuclear power facility when an abnormality occurs in order to prevent radiation exposure in a large nuclear power facility.

In general, in nuclear power facilities, various sensors for measuring and monitoring radiation generated in a radiation management area in real time are disposed in order to prevent radiation exposure of users. These sensors may be organically connected to each other according to the related nuclear facility, and the sensors organically connected in this way may form a single Radiation Monitoring System (RMS).

Meanwhile, these radiation monitoring systems may be connected to an emergency stop system, and the emergency stop system may stop the operation of at least one nuclear facility connected to the emergency stop system according to a detection result of each radiation monitoring system. In this case, although each radiation monitoring system is formed according to the nuclear facility involved, for example, if radiation leaks from a specific facility, at least one blocking door is closed to prevent exposure due to the leaked radiation or to prevent further damage In order to do this, when an abnormality occurs in a specific nuclear facility, such as stopping other facilities connected to the specific facility through which the radiation has leaked, at least one other related nuclear facility should be able to be controlled at the same time.

Accordingly, like the inter-rock system shown in FIG. 1 , the emergency stop system 150 controls a plurality of different nuclear power plants 191 , 192 , and 193 , a plurality of different nuclear power plants. It should be able to be connected to (191, 192, 193), and may also be formed to be connected to a plurality of different radiation monitoring systems (111, 112, 113) corresponding to each of the connected nuclear facilities. And the power supply unit 100 may supply power for driving each radiation monitoring system (111, 112, 113).

Meanwhile, in each radiation monitoring system, an alarm value may be individually set according to its purpose, an arrangement location, and the characteristics of an area. In addition, when the detected value (eg, radiation dose) detected through the provided sensors is greater than or equal to a preset alarm value, an alarm signal may be generated, and the emergency stop system 150 responds to the at least one facility according to the alarm signal. By performing an interlock (inter-rock), it is possible to stop the operation of the at least one facility.

However, in order to guarantee the performance of the radiation monitoring system, maintenance is required for periodic performance check, verification, and calibration. And during this period, an artificial alarm situation may occur due to the use of a radiation source for inspection (calibration source). And this artificial alarm situation may cause the emergency stop system 150 to generate interlock operations.

On the other hand, interlock operations caused by such an artificial alarm situation may cause great confusion to workers despite the intended situation. Moreover, since the emergency stop system 150 is connected to a plurality of nuclear facilities and controls the interlock operation of the plurality of nuclear facilities for safety, the emergency stop system 150 maintains a normal operating state while being inspected. There is a problem in that the interlock operation according to the alarm signal generated from the radiation monitoring system should not be performed.

To this end, in the prior art, before the radiation monitoring system inspection using a calibration source, the inspector manually adjusts the alarm values of the sensors provided in each radiation monitoring system in the field or program of the radiation monitoring system, so that artificial It is possible to stop the alarm signal from being generated.

However, in this method, there is a problem that it takes a long time to recover the alarm set value because the inspector has to change the alarm set value for each equipment during multiple equipment inspection (or calibration and calibration), and manually changing the alarm set value Therefore, there is a problem in that there is a high possibility that an error in which the inspector incorrectly inputs a set value, that is, a human error occurs. In addition, since it is done manually by the operator, there is a problem in that it is difficult to determine whether the control room performs the work related to the inspection of the radiation monitoring system equipment in the control area and the status of the equipment under inspection.

The present invention is to solve the above problem, and includes an interlock bypass device and the interlock bypass device that allow the emergency stop system to ignore an alarm signal generated from a specific radiation monitoring system while maintaining a normal operating state It is to provide an interlock system that

In addition, the present invention provides an interlock bypass device and the interlock that allow the operation of a nuclear facility related to the specific radiation monitoring system to be stopped regardless of the detection result of the specific radiation monitoring system while maintaining the state in which the emergency stop system operates normally It is to provide an interlock system including a lock bypass device.

An interlock system according to an embodiment of the present invention for achieving the above object is connected to a plurality of nuclear facilities and outputs an inter-rock signal to at least one nuclear facility according to a preset alarm signal. , an emergency stop system for emergency stop operation of the at least one nuclear facility, and a first driving circuit for inducing generation of the interlock signal by applying the alarm signal to the emergency stop system, Abnormal situation of the radiation monitoring system by supplying power to any one of a first path passing through a radiation monitoring system that detects an abnormal situation or a second path bypassing the radiation monitoring system and at least one bypass device that blocks transmission of an alarm signal according to the detection result to the emergency stop system.

In an embodiment, the first driving circuit is a circuit for controlling the emergency stop system to induce the generation of the interlock signal according to whether power is supplied, and the first path is a detection result of the radiation monitoring system. is a path for supplying power to the first driving circuit through a contact switch whose opening or closing is determined according to do.

In an embodiment, the bypass device includes a second driving circuit for applying a driving stop signal for stopping operation to a specific nuclear facility associated with the radiation monitoring system according to whether power is supplied, and power through the second path When this is supplied, it characterized in that it further comprises a mode switch for supplying power to any one of the first driving circuit and the second driving circuit according to the set operation mode.

In an embodiment, the emergency stop system includes a relay switch, and includes a driving circuit that generates the interlock signal when the circuit is opened as the power is cut off, and the first driving circuit includes the power supplied It is characterized in that the circuit is formed so as to maintain the closed state of the emergency stop system driving circuit while applying power to the driving circuit of the emergency stop system.

In an embodiment, the specific nuclear facility includes a relay switch, and includes a drive circuit that stops the operation of the specific nuclear facility when the circuit is opened as power is cut off, and the second drive circuit includes: It is characterized in that the circuit is formed so as to maintain a closed state of the specific nuclear facility driving circuit while power is supplied by applying the applied power to the driving circuit of the specific nuclear facility.

In an embodiment, the first driving circuit and the second driving circuit are formed in the form of a relay board.

An interlock bypass device according to an embodiment of the present invention for achieving the above object includes a power supply unit for supplying power, and when the power supplied from the power unit is cut off, the emergency stop system generates the interlock signal. a first driving circuit for controlling the emergency stop system to prevent A switch unit that provides any one of a first path through which the power source unit and the first driving circuit are connected or a second path through which the power unit unit and the second driving circuit are connected, and whether the specific nuclear facility is abnormal A separate power supply that is opened or closed according to a monitoring result of a radiation monitoring system including at least one sensor for monitoring, and the power supply unit and the first driving circuit are connected separately from the first path It is characterized in that it includes a path.

In an embodiment, the radiation monitoring system includes a contact switch that is turned on or off based on a detection value of at least one included sensor, and the separate power supply path includes the power supply unit via the contact switch. and a path connecting the first driving circuit.

In an embodiment, the switch unit includes a power input terminal connected to the power supply unit, a first terminal connected to the first path, and a second terminal connected to the second path, and the separate power supply The supply path may be a path connecting the power supply unit and the first terminal separately from the first path.

In one embodiment, the interlock bypass device is formed to include a plurality of different first and second driving circuits corresponding to each of a plurality of different nuclear facilities, a switch unit, and a separate power supply path. characterized in that

In an embodiment, the first driving circuit and the second driving circuit are formed in the form of a relay board.

In an embodiment, in the interlock bypass device, when the switch unit supplies power through the first path, power is supplied to the first driving circuit through the first path and the separate power supply path and when the switch unit supplies power through the second path, the first driving circuit receives power through the separate power supply path, and the second driving circuit supplies power through the second path. It is characterized in that it is formed to be supplied.

The effects of the interlock bypass device and the interlock system according to the present invention will be described as follows.

According to at least one of the embodiments of the present invention, since the present invention can switch signal transmission to a related system or system without direct manipulation (change of set value) of sensors provided in the radiation monitoring system, human error can be prevented. It has the effect that it can.

In addition, according to at least one of the embodiments of the present invention, in a state in which the emergency stop system is normally operated, it is possible to prevent in advance the occurrence of an emergency situation according to the detection result of all or part of the radiation monitoring system according to the selection of the inspector. there is an effect that

In addition, according to at least one of the embodiments of the present invention, there is an effect that it is possible to more easily check the inspection status of the radiation monitoring systems according to the state of the interlock bypass devices provided in the emergency stop system.

1 is a block diagram showing the configuration of a conventional interlock system.
2 is a block diagram illustrating the configuration of an interlock system including an interlock bypass device according to the present invention.
3 is a block diagram illustrating in more detail the configuration of an interlock bypass device related to the present invention.
4 and 5 are circuit diagrams illustrating a circuit of an interlock bypass device related to the present invention and a path through which power is supplied according to a normal operation state and a check operation state.
6 is an exemplary diagram illustrating an example of an interlock bypass device including a plurality of switch units.

It should be noted that the technical terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. Also, as used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. The suffixes "module" and "part" for the components used in the following description are given or mixed in consideration of only the ease of writing the specification, and do not have a meaning or role distinct from each other by themselves.

As used herein, "consisting of." or "includes." The terms such as etc. should not be construed as necessarily including all of the various components or steps described in the specification, and some components or some steps may not be included, or additional components or steps may not be included. It should be construed as being able to include more.

In addition, in describing the technology disclosed in the present specification, if it is determined that a detailed description of a related known technology may obscure the gist of the technology disclosed in this specification, the detailed description thereof will be omitted.

In addition, the accompanying drawings are only for easy understanding of the embodiments disclosed in the present specification, and the technical idea disclosed herein is not limited by the accompanying drawings, and all changes included in the spirit and scope of the present invention , should be understood to include equivalents or substitutes. In addition, each of the embodiments described below, as well as combinations of embodiments, are changes, equivalents, or substitutes included in the spirit and scope of the present invention, and may correspond to the spirit and scope of the present invention. .

First, FIG. 2 is a block diagram illustrating the configuration of an interlock system including an interlock bypass device related to the present invention.

Referring to FIG. 2 , the interlock system according to an embodiment of the present invention supplies power to the emergency stop system 250 and the emergency stop system 250 connected to a plurality of nuclear facilities 191 , 192 , ... It may be formed to include a power supply unit 200, and a plurality of interlock bypass devices (210, 220, ...) disposed between the emergency stop system 250 and the power supply unit 200.

Here, the emergency stop system 250 may emergency stop the operation of at least one connected nuclear power plant. To this end, the emergency stop system 250 may output an interlock signal to at least one nuclear facility when a preset alarm signal is received, and each nuclear facility may be configured to emergency stop operation according to the interlock signal. have. To this end, each nuclear facility may include a drive switch, and each nuclear facility may be configured to be operated in a state in which the drive switch is on, that is, closed. In this case, the drive switch of each nuclear facility may be turned off, that is, open, when an interlock signal is received from the emergency stop system 250 , and when the drive switch is opened, the operation of each nuclear facility is stopped can be That is, the interlock signal may be a signal for turning off a driving switch provided in the nuclear facility.

Meanwhile, the emergency stop system 250 may generate the interlock signal based on an alarm signal received from the radiation monitoring system. And the interlock signal may be generated through the interlock bypass device (hereinafter, the bypass device, 210, 220) according to an embodiment of the present invention.

The bypass device may include a radiation monitoring system (RMS) corresponding to a specific nuclear facility, and may include a driving circuit for generating the interlock signal. Here, the driving circuit may be formed to generate an alarm signal in the emergency stop system 250 when the power supplied from the power supply unit 200 is cut off.

Here, the bypass device includes a first path for supplying the power supplied from the power supply unit 200 to the driving circuit via the radiation monitoring system, and the power supply unit 200 directly to the driving circuit by bypassing the radiation monitoring system. It may include a second path for supplying power.

In addition, the radiation monitoring system may form a contact switch for determining the opening and closing of the first path. That is, the radiation monitoring system may be formed in the form of a switch that opens and closes the first path based on a detection value detected by at least one provided sensor. In this case, the detection value is a condition according to a preset alarm setting value. If not satisfied, the first path may be opened by the contact switch. Then, the first path is cut off and power supplied to the driving circuit is cut off, so that an alarm signal may be applied to the emergency stop system 250 .

Meanwhile, the second path may be a switch that connects between the power supply unit 200 and the driving circuit through a switch that opens or closes the second path according to the operator's selection. In this case, when the switch formed in the second path is off, that is, when the switch is open, the second path is cut off, and the power of the power supply unit 200 can be supplied to the driving circuit only through the first path. Accordingly, when the first path is blocked by the radiation monitoring system, the power supply to the driving circuit is cut off, and an alarm signal may be applied to the emergency stop system 250 .

On the other hand, when the switch formed in the second path is on, that is, when the switch is closed, the power of the power supply unit 200 may be directly supplied to the driving circuit by bypassing the radiation monitoring system. Accordingly, even when the first path is blocked by the radiation monitoring system, power supply to the driving circuit may be maintained, and thus the driving circuit may not output an alarm signal.

On the other hand, each bypass device may be associated with a specific nuclear facility according to the area and location where the radiation monitoring system is located. Therefore, as shown in FIG. 2 , the interlock system according to the embodiment of the present invention is related to the first nuclear facility (hereinafter, the first facility, 191), the first switch 211, the first radiation monitoring system ( RMS) 212 and a first bypass device 210 including a first drive circuit 213 , is associated with a second nuclear power plant (hereinafter referred to as a second plant 192 ), and a second switch 221 . ), a second radiation monitoring system (RMS) 222 and a second bypass device 220 including a second driving circuit 223 .

Meanwhile, in FIG. 2, a case in which the first bypass device 210 and the second bypass device 220 are provided as an example was described as an example on the assumption that the first facility 191 and the second facility 192 are provided. Of course, this is omitted for convenience of description and may include more or fewer nuclear power plants and bypass devices accordingly.

Meanwhile, in the case of the interlock system shown in FIG. 2 , when the inspector turns on the first switch 211 for the inspection of the first radiation monitoring system 212 , regardless of the monitoring result of the first radiation monitoring system 212 . Since power is supplied to the first driving circuit 213 , an alarm signal may not be output to the emergency stop system 250 . Accordingly, the inspector may perform the inspection of the first radiation monitoring system 212 irrespective of whether an alarm signal is generated.

However, if the first nuclear facility 191, whose abnormality is detected by the first radiation monitoring system 212, is in operation during the inspection of the first radiation monitoring system 212, actually, the first nuclear facility 191 ), there is a problem in that it cannot be detected when an abnormal situation such as radiation leakage occurs.

Accordingly, in order to prevent this problem, the interlock system of the present invention automatically stops the operation of a specific nuclear facility associated with the specific bypass device when a switch formed in the second path of the specific bypass device is turned on. Accidents that may occur during the inspection of the monitoring system can be prevented.

3 is a block diagram showing in more detail the configuration of the interlock bypass device according to the present invention. Hereinafter, for convenience of explanation, FIG. 3 will be described using the first bypass device 210 including the first nuclear power plant 191 and the first radiation monitoring system 212 associated with the first nuclear power plant 191 as an example. do. For example, the first radiation monitoring system 212 may be a monitoring system including at least one sensor disposed in an area where the first nuclear facility 191 is installed.

Referring to FIG. 3 , the first bypass device 210 according to an embodiment of the present invention includes a first driving circuit 311 and a second driving circuit 312 , and a first radiation monitoring system 212 and a first It may be formed to include a switch 211 .

Here, the first driving circuit 311 may be a circuit that applies an alarm signal to the emergency stop system 250 when the power supplied from the power supply unit 200 is cut off.

In addition, the second driving circuit 312 may be a circuit that applies a driving stop signal that turns off the driving switch of the first nuclear facility 191 when the power supplied from the power supply unit 200 is cut off.

In addition, the first radiation monitoring system 212 may include at least one sensor for monitoring whether the first nuclear facility 191 is abnormal.

In addition, the first switch 211 includes a first path connected to the power supply unit 200 and the first driving circuit 311 or a second path connected to the power supply unit 200 and the second driving circuit 312 . Any one of the paths may be provided.

Accordingly, if the second path is selected by the first switch 211 , the first driving circuit 311 passes through the first radiation monitoring system 212 , that is, the first radiation monitoring system contact switch 212 . Thus, power may be supplied through a path connected to the power supply unit 200 . In addition, the second driving circuit 312 may receive power through a second path connected to the power supply unit 200 via the first switch 211 .

Accordingly, when the first radiation monitoring system contact switch 212 is turned off according to the detection values of the sensors, the first driving circuit 311 applies an alarm signal to the emergency stop system 250 , and the emergency stop system 250 . ) may generate an interlock signal to at least one or more nuclear facilities, including the first nuclear facility 191 , to stop the operation of at least one nuclear facility.

That is, when the second path is selected by the first switch 211 , the emergency stop system is normally operated, and an interlock signal may be generated according to the radiation monitoring system.

On the other hand, when the power supply path is selected as the first path by the first switch 211 , the first switch 211 indicates that the power of the power supply unit 200 is supplied to the first driving circuit 311 through the first path. ) can be supplied directly to In this case, since the power supplied to the second path is cut off, power may no longer be supplied to the second driving circuit 312 . Accordingly, the second driving circuit 312 may apply a driving stop signal to the driving switch of the connected first nuclear facility 191 , and the operation of the first nuclear facility 191 may be stopped according to the driving stop signal. have.

Meanwhile, the first driving circuit 311 may receive power directly from the power supply unit 200 via the first switch 211 through the first path. Therefore, even if the first radiation monitoring system contact switch 212 is off and the power supply path connected to the power supply unit 200 via the first radiation monitoring system contact switch 420 is blocked, through the first path Power supply to the first driving circuit 311 may be maintained.

Accordingly, the alarm signal may not be transmitted to the emergency stop system 250 regardless of the monitoring result of the sensors of the first radiation monitoring system 212 , and accordingly, the emergency alarm and interlock signal of the emergency stop system 250 are may not occur. Accordingly, the inspector can freely inspect the performance of the first radiation monitoring system.

Meanwhile, the first switch 211 may maintain a state in which the power supply path is selected as the second path during normal times. In addition, the power supply path may be set to be switched to the first path only when the first radiation monitoring system is checked, that is, only during maintenance of the first radiation monitoring system.

Meanwhile, FIGS. 4 and 5 are circuit diagrams illustrating a circuit of an interlock bypass device related to the present invention and a path through which power is supplied according to a normal operation state and a check operation state.

First, FIG. 4 illustrates an example in which the first switch 211 selects a second path to supply power to the power supply unit 200 to the second driving circuit 312 .

Referring to FIG. 4 , the first bypass device 210 according to an embodiment of the present invention may include a switch unit 211 and a first radiation monitoring system contact switch 420 , and an emergency stop system 250 . A first driving circuit 311 connected to the driving circuit 430 of

First, the first driving circuit 311 is formed in the form of a relay board, and when operating power is applied, the driving switch of the emergency stop system 250 is closed, and the driving circuit of the emergency stop system 250 is closed. 430 may be formed to be connected. Accordingly, when the operating power is not applied to the first driving circuit 311 , the driving circuit 430 of the emergency stop system 250 may be opened to stop the operation of the emergency stop system 250 . Here, the driving switch of the emergency stop system driving circuit 430 is, as shown in FIG. 4, when power is applied to the first driving circuit 311, a voltage is applied to both ends of the driving switch so that the circuit is It may be formed as a relay switch to be connected.

In addition, the second driving circuit 312 is also formed in the form of a relay board, and when operating power is applied, the driving switch of the first nuclear facility 191 is closed, and the driving circuit ( 440) may be formed to be connected. Accordingly, if the operating power is not applied to the second driving circuit 312 , the driving circuit 440 of the first nuclear power plant 191 may be opened to stop the operation of the first nuclear power plant 191 . Here, as shown in FIG. 4 , the driving switch of the first nuclear facility driving circuit 440 applies voltage to both ends of the driving switch when power is applied to the second driving circuit 312 . It may be formed as a relay switch to which is connected.

In addition, the first switch unit 211 includes a power input terminal to which power is supplied from the power supply unit 200 , a first terminal 411 connected to a first path connected to the first driving circuit 311 , and the second One of the second terminals 412 connected to the second path 402 connected to the driving circuit 312 may be connected. In addition, the power input from the power supply unit 200 may be supplied to any one of the first path and the second path according to the connected terminal.

Meanwhile, the first bypass device 210 may further include a separate power supply path 401 for supplying power to the first terminal 411 . The separate power supply path 401 is a power supply path connected to the power supply 200 through the first radiation monitoring system contact switch 420, and when the first radiation monitoring system contact switch 420 is closed, the power supply unit By connecting 200 and the first terminal 411 , the power input from the power supply unit 200 may be supplied to the first driving circuit 311 through the first path.

In the case of the interlock bypass device 210 according to the embodiment of the present invention formed as described above, as a default state, the first switch unit 211 has a power input terminal and a second terminal ( 412) can maintain a connected state. Therefore, when the first nuclear facility 191 is normally operated, that is, when it is not during the maintenance period of the first radiation monitoring system, the first switch 211 is input from the power supply unit 200 through the second terminal 412. A state in which power is supplied to the second driving circuit 312 may be maintained.

Meanwhile, when power is supplied to the second driving circuit 312 through the first switch unit 211 , power may be supplied to the first driving circuit 311 through the separate power supply path 401 . Accordingly, as shown in FIG. 4 , both the driving circuit 430 of the emergency stop system 250 and the driving circuit 440 of the first nuclear power plant 191 are closed, so that they can be operated normally.

Meanwhile, in this case, when an abnormal situation, such as radiation exceeding the reference value, occurs as a result of detection of the first radiation monitoring system, the first radiation monitoring system contact switch 420 may be turned off. Then, the separate power supply path 401 may be cut off, and thus power supplied to the first driving circuit 311 may be cut off. Then, the driving switch of the emergency stop system driving circuit 430 may be turned off, and the emergency stop system 250 detects an open circuit of the driving circuit 430 and outputs an emergency alarm and the first nuclear facility ( 440) and may output an interlock signal for at least one nuclear facility. Then, the operation of at least one nuclear facility receiving the interlock signal may be stopped.

Meanwhile, when maintenance of the first radiation monitoring system is performed, the first switch unit 211 may connect the power input terminal to the first terminal 411 as shown in FIG. 5 .

Then, the supply of power to the second path 402 may be stopped, and accordingly, the power supplied to the second driving circuit 312 may be cut off. Accordingly, as shown in FIG. 5 , the driving switch of the first nuclear facility driving circuit 440 may be turned off, and the operation of the first nuclear facility 191 may be stopped.

Meanwhile, when the power input terminal is connected to the first terminal 411 , the power input from the power supply unit 200 is applied to the first driving circuit 311 , and at the same time, the power supply unit 200 through the separate power supply path 401 . ) may be applied to the first driving circuit 311 . Therefore, even if an abnormal situation occurs as a result of detection of the first radiation monitoring system and the power supply to the first driving circuit 311 through the separate power supply path 401 is stopped, through the first terminal 411 Power input from the power supply unit 200 may be applied to the first driving circuit 311 . That is, regardless of the detection result of the first radiation monitoring system, the driving circuit 430 of the emergency stop system may always be maintained in a closed state.

Meanwhile, in the above description of FIGS. 3 to 5, one bypass device connected to one nuclear facility has been described as an example, but a plurality of switch units connected to a plurality of different nuclear facilities may be combined into one interlock bypass device. Of course it could be.

6 is an exemplary diagram illustrating an example of an interlock bypass device including a plurality of switch units in this case.

Referring to FIG. 6 , an example of generating one interlock bypass device by combining switch units related to different zones, that is, different nuclear facilities. In this case, each switch unit may be formed so that any one of a manual (Manual) and an auto (Auto) mode is selected by a user's operation.

Here, the manual mode (switch 'on') is a mode for supplying power to the first driving circuit connected to the driving circuit of the emergency stop system, and may be a mode set during the maintenance period of the radiation monitoring system disposed in a specific area. In addition, the auto mode (switch 'off') is a mode for supplying power to the second driving circuit connected to the driving circuit of a specific nuclear facility, and may be a default mode set during normal operation.

Accordingly, the inspector may set the switch unit corresponding to the at least one zone to the manual mode as needed. Then, power can be supplied to the first driving circuit connected to the emergency stop system through a separate power supply path, so that the alarm signal output to the emergency stop system can be prevented regardless of the monitoring result of the radiation monitoring system. Therefore, it is possible to prevent the output of an alarm signal and the occurrence of an emergency situation even if the radiation leakage phenomenon is artificially induced by using a radiation source for inspection (calibration source) while the emergency stop system is operating normally.

Meanwhile, as shown in FIG. 6 , a plurality of switch units related to different nuclear facilities are combined to create one interlock bypass device, so that the inspector can easily identify the radiation monitoring systems currently being inspected. For example, among the switch units constituting the interlock bypass device, it is possible to easily recognize an area or a nuclear facility corresponding to a radiation monitoring system currently being inspected according to switch units set to manual mode.

Meanwhile, in the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. In particular, in the embodiment of the present invention, an example in which the first driving circuit 311 and the second driving circuit 312 are formed in the form of a relay board is given, but the present invention is not limited thereto.

In addition, various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

200: power unit 210: first bypass device
211: first switch unit 212: first radiation monitoring system
311: first driving circuit 312: second driving circuit
250: emergency stop system 191: first nuclear power plant

Claims (12)

an emergency stop system connected to a plurality of nuclear facilities and outputting an inter-rock signal to at least one nuclear facility according to a preset alarm signal to emergency stop the operation of the at least one nuclear facility; and,
a first driving circuit for inducing generation of the interlock signal by applying the alarm signal to the emergency stop system; At least for supplying power to any one of the path or the second path bypassing the radiation monitoring system to block the transmission of an alarm signal according to the abnormal situation detection result of the radiation monitoring system to the emergency stop system Interlock system with one bypass device. According to claim 1,
The first driving circuit,
It is a circuit that controls the emergency stop system to induce the generation of the interlock signal depending on whether power is supplied,
The first path is
A path for supplying power to the first driving circuit through a contact switch that determines whether to open or close according to a detection result of the radiation monitoring system,
The second path is
An interlock system, characterized in that it is a path for supplying power to the first driving circuit by bypassing the contact switch. According to claim 2, wherein the bypass device,
a second driving circuit for applying a driving stop signal for stopping the operation of a specific nuclear facility associated with the radiation monitoring system according to whether power is supplied; and,
and a mode switch for supplying power to one of the first driving circuit and the second driving circuit according to a set operation mode when power is supplied through the second path. 3. The method of claim 2,
The emergency stop system is
Including a relay switch, and a driving circuit that generates the interlock signal when the circuit is opened as the power is cut off,
The first driving circuit,
The interlock system according to claim 1, wherein the circuit is formed to maintain a closed state of the emergency stop system driving circuit while power is supplied by applying the supplied power to the driving circuit of the emergency stop system. 4. The method of claim 3,
The specific nuclear power plant is
Including a relay switch, and a driving circuit that stops the operation of the specific nuclear facility when the circuit is opened as the power is cut off;
The second driving circuit,
The interlock system according to claim 1, wherein the circuit is formed to maintain a closed state of the specific nuclear facility driving circuit while power is supplied by applying the supplied power to the driving circuit of the specific nuclear facility. According to claim 3, wherein the first driving circuit and the second driving circuit,
Interlock system, characterized in that formed in the form of a relay board (relay board). An interlock bypass device for preventing generation of an interlock signal of an emergency stop system for at least one nuclear facility according to an abnormal situation detection result of a specific nuclear facility,
a power supply unit for supplying power;
a first driving circuit for controlling the emergency stop system so that the emergency stop system generates the interlock signal when the power supplied from the power supply is cut off;
a second driving circuit for controlling the operation of the specific nuclear facility so that the operation of the specific nuclear facility is stopped when the power supplied from the power supply unit is cut off;
a switch unit providing any one of a first path through which the power unit and the first driving circuit are connected or a second path through which the power unit and the second driving circuit are connected; and,
It is opened or closed according to a monitoring result of a radiation monitoring system including at least one sensor for monitoring whether or not the specific nuclear facility is abnormal, and the power supply unit and the first driving unit separately from the first path An interlock bypass device comprising a separate power supply path to which the circuit is connected. 8. The method of claim 7,
The radiation monitoring system,
It includes a contact switch that is turned on or off based on the detection value of the included at least one sensor,
The separate power supply path is
Interlock bypass device, characterized in that it is a path for connecting the power supply unit and the first driving circuit via the contact switch. 8. The method of claim 7,
The switch unit,
a power input terminal connected to the power supply;
a first terminal connected to the first path; and,
a second terminal connected to the second path;
The separate power supply path is
The interlock bypass device, characterized in that it is a path connecting the power supply unit and the first terminal separately from the first path. The method of claim 7, wherein the interlock bypass device,
An interlock bypass device, characterized in that it is formed to include a plurality of different first and second driving circuits, a switch unit, and a separate power supply path corresponding to each of a plurality of different nuclear facilities. The method of claim 7, wherein the first driving circuit and the second driving circuit,
Interlock bypass device, characterized in that formed in the form of a relay board (relay board). The method of claim 7, wherein the interlock bypass device,
When the switch unit supplies power through the first path, power is supplied to the first driving circuit through the first path and the separate power supply path,
When the switch unit supplies power through the second path, the first driving circuit receives power through the separate power supply path, and the second driving circuit receives power through the second path. Interlock bypass device, characterized in that formed.

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