CN113985829A - Distributed industrial control system of nuclear power station and virtual and physical switching control method thereof - Google Patents
Distributed industrial control system of nuclear power station and virtual and physical switching control method thereof Download PDFInfo
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- CN113985829A CN113985829A CN202111291986.9A CN202111291986A CN113985829A CN 113985829 A CN113985829 A CN 113985829A CN 202111291986 A CN202111291986 A CN 202111291986A CN 113985829 A CN113985829 A CN 113985829A
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- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/418—Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
- G05B19/41845—Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by system universality, reconfigurability, modularity
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Abstract
The invention belongs to the technical field of industrial control, and particularly relates to a distributed industrial control system of a nuclear power station and a virtual and physical switching control method thereof. The invention uses a minimized hardware structure, meets the requirements of hardware defect screening and testing, enables the verified virtual simulation model to be tested in an environment closer to reality, can realize cross verification and rapid verification of various large DCS system functions and configurations, and improves verification efficiency and verification reliability.
Description
Technical Field
The application belongs to the technical field of industrial control, and particularly relates to a distributed industrial control system of a nuclear power station and a virtual and physical switching control method thereof.
Background
As a central nervous System of a large-scale industry, a Distributed Control System (DCS) System controls operations of main process equipment in a plant area, and a large-scale DCS System (for example, a DCS System used in a nuclear power plant, a thermal power plant, a large-scale chemical plant, and the like) is generally installed in a main Control room to perform centralized monitoring Control of the whole plant. In addition, a plurality of DCS cabinets are arranged in each factory building for carrying out input acquisition and output control and operation calculation of various closed-loop control logics, sequence control logics and system protection logics.
Due to the need of testing and training, the industry usually establishes a testing and training platform of the DCS system, and generally constructs a simplified DCS system that realizes some specific functions by using actual configurations of various industrial control systems as prototypes. This simplified DCS system can be used for system functional testing, personnel training, and testing of specific modules. But because only a few specific logic functions are realized, the test, verification and training of all logic functions of the actual DCS system cannot be realized.
In addition, in the technical field of DCS software verification, a DCS virtual simulation system is usually set up to perform virtual verification of functions and configurations of DCS software, but the verification is incomplete because the hardware of an actual DCS system is not combined.
Disclosure of Invention
The application aims to provide a distributed industrial control system of a nuclear power station and a virtual and physical switching control method thereof, solve the problem of incomplete existing verification tests, and can carry out operation and maintenance analysis and verification work of a DCS system in a full range.
The technical scheme for realizing the purpose of the application is as follows:
a first aspect of the present application provides a distributed industrial control system for a nuclear power plant, including: the system comprises a minimized physical human-computer interface, a virtual simulation system, a physical control cabinet, a verification control station and a process system simulation model;
the minimized physical human-computer interface is connected with the virtual simulation system and used for realizing operation and parameter monitoring;
the virtual simulation system is also connected with the process system simulation model through a virtual simulation system IO communication program and is used for loading virtual simulation models of all process control cabinets of the nuclear power unit DCS system to simulate relevant control logic configuration faults;
the verification control station is loaded with a verification control communication program and is responsible for communication among the virtual simulation system, the verification control station and the process system simulation model;
the minimized physical human-computer interface is also connected with the physical control cabinet;
the physical control cabinet is connected with the process system simulation model through a physical IO interface device and is used for loading the nuclear power unit DCS system engineering configuration and operating the nuclear power unit DCS process control configuration logic;
the process system simulation model is used for simulating the operation condition of the nuclear power unit process equipment.
Optionally, the virtual simulation system includes configuration logics of all control systems of the nuclear power station, and the physical control cabinet can be used for installing a plurality of DCS control system configuration logics of all control systems of the nuclear power station.
Optionally, the minimized physical human-computer interface includes: a set of operator stations, a set of administrator stations, an interface unit, a data archiving unit, a processing unit, an engineer station, and a diagnostic system.
Optionally, the physical IO interface device is connected to the physical control cabinet by hard wiring.
Optionally, the physical IO interface device integrates an AI data interface module, an AO data interface module, a DI data interface module, a DO data interface module, and a simulation RTD data interface module, and is configured to perform data communication between the physical control cabinet and the process system simulation model in DCS process control.
Optionally, the virtual simulation system runs in a simulation model server;
the virtual simulation system IO communication program is loaded in the simulation model server;
the process system simulation model is installed in the simulation model server.
A second aspect of the present application provides a virtual and physical switching control method for a distributed industrial control system of a nuclear power plant, which is applied to the distributed industrial control system of the nuclear power plant provided by the first aspect of the present application; the method comprises the following steps:
loading the control logic configurations of a system B ', a system C ' and a system D ' in the virtual simulation system;
loading 0-1 layer IO point-to-point lists of the system B ', the system C ' and the system D ' in a matched manner on the verification control station;
loading the control logic configuration of the system A on the physical control cabinet;
connecting the material object control cabinet and the material object IO interface device through hard wiring according to an actual IO point of the system A;
loading an IO (input/output) point-to-point list between an IO interface device of the system A and the process simulation model in a matching way on the verification control station;
and carrying out data docking on the inter-station communication points of the system A' and the system A loaded in the virtual simulation system through a data transfer module loaded in the simulation model server.
Optionally, the method further includes:
unloading the system B 'in the virtual simulation system, and loading the control logic configurations of the system A', the system C 'and the system D';
loading 0-1 layer IO point-to-point lists of the system A ', the system C ' and the system D ' in a matched manner on the verification control station;
loading the control logic configuration of the system B on the physical control cabinet;
removing the hard wiring of the originally connected system A, and according to the actual IO point of the system B, carrying out hard wiring on the physical control cabinet and the physical IO interface device;
loading an IO (input/output) point-to-point list between an IO interface device of the system B and the process simulation model in a matching way on the verification control station;
and carrying out data docking on the inter-station communication points of the system B' and the system B through the data transfer module loaded in the data.
Optionally, the method further includes:
removing hard wiring between the object control cabinet and the object IO interface device of the originally connected system B;
unloading an IO (input/output) point-to-point list between an IO interface device of a system B and the process simulation model at the verification control station;
unloading a data relay module at the simulation model server;
loading control logic configurations of a system A ', a system B', a system C 'and a system D' in the virtual simulation system;
and loading 0-1 layer IO point-to-point lists of the system A ', the system B', the system C 'and the system D' in a matched manner on the verification control station.
Optionally, the loading of the control logic configurations of the system B ', the system C ', and the system D ' in the virtual simulation system further includes:
and performing joint debugging test on the logic configurations of the virtual simulation system and the physical control cabinet respectively through IO (input/output) point list, inter-station communication point list, hard wiring and data configuration preprocessing.
The beneficial technical effect of this application lies in:
(1) according to the distributed industrial control system of the nuclear power station and the virtual and physical switching control method thereof, a full-range DCS simulation test system is formed by a human-computer interface, a physical control cabinet, a virtual simulation model and a process system simulation model, a minimized hardware structure is used, hardware defect screening and test requirements are met, a typical hardware configuration, module performance and the like of the DCS can be verified by a physical part, and a complete software configuration, logic functions and the like of the DCS can be verified by the virtual simulation model.
(2) According to the distributed industrial control system of the nuclear power station and the virtual and physical switching control method thereof, the physical control cabinet and the virtual simulation model can be simultaneously connected with the process system simulation model to operate to carry out DCS software and hardware verification, the physical control cabinet can also be cut off, and the virtual simulation model is independently connected with the process system simulation model to operate to carry out DCS software verification. The verified virtual simulation model is tested in an environment closer to reality, cross verification and rapid verification of various large DCS system functions and configurations can be achieved, and verification efficiency and verification reliability are improved.
(3) The distributed industrial control system of the nuclear power station and the virtual and physical switching control method thereof can provide a verification platform for various upgrading, reconstruction, fault solution, maintenance schemes and the like of a real DCS through a switching control mode of a partial physical cabinet and a partial virtual model of the DCS, can carry out test verification, fault analysis and troubleshooting on the DCS in an environment close to the real environment, can be used for on-site fault reproduction and test, and therefore can facilitate the analysis of fault reasons and fault points.
Drawings
Fig. 1 is a schematic structural diagram of a distributed industrial control system of a nuclear power plant according to an embodiment of the present application;
fig. 2 is a schematic structural diagram of a specific distributed industrial control system of a nuclear power plant according to an embodiment of the present application;
fig. 3 is a schematic flow chart of a virtual and physical switching control method for a distributed industrial control system of a nuclear power plant according to an embodiment of the present application.
Detailed Description
In order to make the technical solutions in the embodiments of the present application more comprehensible to those skilled in the art, the following description will be made in detail and completely with reference to the accompanying drawings in the embodiments of the present application. It should be apparent that the embodiments described below are only some of the embodiments of the present application, and not all of them. All other embodiments that can be derived by a person skilled in the art from the embodiments described herein without inventive step are within the scope of the present application.
In order to solve the technical problem, an embodiment of the present application provides a distributed industrial control system of a nuclear power plant and a virtual and physical switching control method thereof. The system uses a minimized hardware structure, and meets the requirements of hardware defect screening and testing. In addition, the system can realize all logic configurations and functions of the DCS through the simulation model, so that operation and maintenance analysis and verification work of the DCS can be carried out in a full range. The physical control cabinet and the virtual simulation model can be simultaneously connected with the process system simulation model to operate to carry out DCS software and hardware verification, and the physical control cabinet can also be cut off and independently connected with the process system simulation model to operate through the virtual simulation model to carry out DCS software verification. The method enables the verified virtual simulation model to be tested in an environment closer to reality, can realize cross verification and rapid verification of various large DCS system functions and configurations, and improves verification efficiency and verification reliability.
Based on the above, in order to clearly and specifically explain the above advantages of the present application, the following description of the embodiments of the present application will be made with reference to the accompanying drawings.
Referring to fig. 1, the diagram is a schematic structural diagram of a distributed industrial control system of a nuclear power plant according to an embodiment of the present application.
The embodiment of the application provides a nuclear power plant full-range DCS simulation test system includes: a minimized physical human-computer interface 100, a virtual simulation system 200, a verification control station 300, a process system simulation model 400 and a physical control cabinet 600;
the minimized physical human-computer interface 100 is connected with the virtual simulation system 200 and used for realizing operation and parameter monitoring;
the virtual simulation system 200 is further connected with the process system simulation model 400 through a virtual simulation system IO communication program 500, and is used for loading virtual simulation models of all process control cabinets of the nuclear power unit DCS system to simulate relevant control logic configuration faults;
the verification control station 300 is loaded with a verification control communication program and is responsible for communication among the virtual simulation system 200, the verification control station 300 and the process system simulation model 400;
and the process system simulation model 400 is used for simulating the operation condition of the nuclear power unit process equipment.
The minimized physical human-computer interface 100 is also connected with a physical control cabinet 600;
the material object control cabinet 600 is connected with the process system simulation model 400 through the material object IO interface device 700, and is used for loading the nuclear power generating unit DCS system engineering configuration and operating the nuclear power generating unit DCS process control configuration logic.
In some possible implementations of the embodiments of the present application, the virtual simulation system 200 may run in a simulation model server; the virtual simulation system IO communication program 500 may be loaded in the simulation model server; process system simulation model 400 is installed in a simulation model server.
In one example, the simulation model server runs the process system simulation model 400, modeling data of the process system simulation model 400 comes from a nuclear power unit, and the process system simulation model 400 with high fidelity is established through graphical modeling software, so that the running condition of the nuclear power unit can be simulated, and interface information and dynamic response and the like between transmitters and actuators in each plant and a DCS (distributed control system) in an actual control equipment layer of the nuclear power unit can be simulated.
In practical applications, the simulation object of the simulation model server may be a full-scale process system of the nuclear power plant. As an example, the nuclear power plant full-scale process system may specifically include: a main coolant system, a main water supply system, a turbine bypass exhaust system, a main steam system, a nuclear island equipment cooling water system and the like, which are not listed.
In some possible implementation manners of the embodiment of the application, the verification control station 300 runs verification control software, the verification control software has functions of controlling the virtual simulation model to run, suspend and load working conditions, selecting a point-to-point list and inserting a simulation fault, and test verification of the nuclear power unit DCS system under various working conditions and various faults can be realized by means of the verification control station.
In some possible implementation manners of the embodiment of the present application, the minimizing the physical human-computer interface 100 specifically includes: a set of operator stations, a set of administrator stations, an interface unit, a data archiving unit, a processing unit, an engineer station, and a diagnostic system.
The operator station is used for operation and maintenance personnel to perform operation monitoring and operation on the nuclear power unit process simulation model; the administrator station is used for modifying the configuration of the human-computer interface, downloading and maintaining the operation monitoring layer; the interface unit is used for carrying out data communication with a third-party system; the data archiving unit is used for storing the historical operating data of the DCS; the processing unit is used for carrying out data communication with the DCS real object control cabinet and the virtual DCS process control layer, and distributing the processed data to other equipment units of the operation monitoring layer; the engineer station is used for modifying and downloading configuration data of the DCS physical control cabinet and the virtual DCS process control layer; the diagnosis system is used for self-checking and diagnosis of the DCS process control layer and the operation monitoring layer and prompting system fault information. The full-range DCS simulation test system of the nuclear power plant is realized by combining a minimized hardware architecture with a virtual simulation model.
In practical applications, the physical IO interface device 700 and the physical control cabinet 600 may be connected by hard wiring.
In this embodiment, the physical control cabinet 600 may adopt a physical example consistent with the model and configuration of the nuclear power unit DCS process control physical cabinet, and is configured to download and operate the nuclear power unit DCS process control configuration logic, receive a control instruction issued by an operator station, issue the control instruction to the process system simulation model 400 through the IO interface device 700 after logic operation, receive state feedback data of the process system simulation model 400 at the same time, and feed the state feedback data back to the operator station after logic operation.
The controller, the input/output module, the power supply module and the communication module can be verified and analyzed for faults such as offline and power failure on the physical control cabinet 600, and a specific DCS instrument control configuration logic can be downloaded to the physical control cabinet 600 for verification and analysis of the instrument control configuration logic. Meanwhile, if the nuclear power unit DCS cabinet has the corresponding real object module to be replaced, the real object module can be tested and verified on the real object control cabinet 600, and the real object module is used for the nuclear power unit DCS cabinet after verification is qualified.
In one example, the physical IO interface device 700 integrates an Analog Input (AI) data interface module, an Analog Output (AO) data interface module, a Digital Input (DI) data interface module, a Digital Output (DO) data interface module, and an analog Resistance Temperature Detector (RTD) data interface module, and is used for performing data communication between the DCS process control physical control cabinet and the process system simulation model.
In the embodiment of the present application, the virtual simulation system 200 realizes the function of DCS process control through simulation of DCS virtual controller software. The DCS virtual controller software loads and operates the DCS logic control configuration of the nuclear power generating set, and realizes data interaction with the process system simulation model 400 through an interface communication program in a network communication mode. In the DCS virtual controller software, relevant control logic configuration faults are simulated, and DCS instrumentation control logic configuration faults can be analyzed and verified. The virtual simulation system 200 is combined with the real object control cabinet 600 to realize the control function of the complete DCS process control layer.
In practical application, the DCS system architecture of a nuclear power plant is generally divided into three layers: a control device layer (level0 layer), a process control layer (level1 layer) and an operation monitoring layer (level2 layer). The level0 layer refers to transmitters, actuators and the like in each factory building, and the devices are connected with input/output (I/O) cards in a DCS process control cabinet through hard wiring and are input/output ends of a DCS system; the level1 layer refers to each DCS process control cabinet, the configuration in the cabinets mainly comprises a main controller, an I/O card and a networking communication part, and the networking communication part is used for acquisition of transmitter signals, processing of signals and logic and output of control commands, and a single nuclear power unit generally comprises 60-80 DCS process control cabinets; the level2 layer refers to terminal devices such as operator terminals, data storage units, engineer stations, diagnostic systems, printers, and the like.
In some possible implementation manners of the embodiment of the application, in order to implement communication between the devices, the full-range DCS simulation test system for a nuclear power plant further includes: a DCS0 layer switch, a DCS1 layer switch and a DCS2 layer switch;
the DCS0 layer switch is used for interconnection communication among the simulation model server, the DCS1 layer switch, the IO interface device 700 and the verification control station 300;
the DCS1 layer switch is used for minimizing interconnection communication among the physical man-machine interface 100, the physical control cabinet 600 and the DCS0 layer switch;
a DCS2 level switch to minimize the interconnection of servers within the physical human machine interface 100.
In one particular example, the DCS0 layer switch, the DCS1 layer switch, and the DCS2 layer switch are network switches.
In the embodiment of the application, on the basis of minimizing a hardware architecture, a nuclear power plant full-range DCS simulation test system is realized by combining a virtual simulation model, a complete nuclear power plant DCS test training platform which is consistent with the actual situation on site is formed in the mode, and the aim of integrating multiple functions of personnel training and examination, fault diagnosis, functional verification, spare part maintenance test and the like is achieved through the platform.
In specific implementation, refer to fig. 2, which is a schematic structural diagram of a specific nuclear power plant full-range DCS simulation test system provided in the embodiment of the present application. This nuclear power plant full-range DCS simulation test system includes: the system comprises a real object DCS operation monitoring layer (comprising a minimized real object human-computer interface 100), a virtual DCS process control layer (comprising a virtual simulation system 200), a DCS process control real object cabinet (comprising a real object control cabinet 600), an IO interface device (namely a real object IO interface device 700), a nuclear power unit process equipment simulation model (comprising a process system simulation model 400) and a verification control station 300. The virtual DCS system process control layer combines the DCS process control physical cabinet to realize the control function of the complete DCS process control layer.
Based on the distributed industrial control system for the nuclear power plant provided by the embodiment, the embodiment of the application also provides a virtual and physical switching control method for the distributed industrial control system for the nuclear power plant, and the method is applied to any distributed industrial control system for the nuclear power plant provided by the embodiment.
According to the embodiment of the application, the verification control station is connected with the virtual simulation system and the physical control cabinet so as to selectively access the virtual simulation system and the physical control cabinet to realize switching control.
The virtual simulation system comprises configuration logics of all control systems of the nuclear power plant, and the physical control cabinet can be provided with a plurality of DCS control system configuration logics in the whole plant control system.
Switching mode 1: and mutually switching the configurations of the virtual simulation system and the physical control cabinet, for example, switching the system A from a physical model to a virtual model, and switching the system B from the virtual model to the physical control cabinet. The number of the systems for virtual control and physical control is respectively a plurality, and the systems for virtual control and physical control form a complete control logic;
switching mode 2: and all configurations in the physical control cabinet are switched to the virtual model and are controlled by the virtual model.
For example, the control logic of the physical control cabinet comprises A, B, C, D systems, and the control logic of the virtual simulation system comprises the same systems, which are denoted by A ', B', C 'and D'.
Referring to fig. 3, the figure is a schematic flow chart of a virtual and physical switching control method for a distributed industrial control system of a nuclear power plant according to an embodiment of the present application.
The virtual and physical switching control method for the distributed industrial control system of the nuclear power station, provided by the embodiment of the application, comprises the following steps:
s301: loading the control logic configurations of a system B ', a system C ' and a system D ' in the virtual simulation system;
s302: loading 0-1 layer IO point-to-point lists of the system B ', the system C ' and the system D ' in a matched manner on the verification control station;
s303: loading the control logic configuration of the system A on the physical control cabinet;
s304: connecting the material object control cabinet and the material object IO interface device through hard wiring according to the actual IO point of the system A;
s305: loading an IO (input/output) point-to-point list between an IO interface device of the system A and the process simulation model in a verification control station in a matched manner;
s306: and carrying out data docking on the inter-station communication points of the system A' and the system A loaded in the virtual simulation system through a data transfer module loaded in the simulation model server.
Therefore, the process system simulation model is butted with data points of the virtual simulation systems (B ', C ' and D ') and the physical control cabinet (system A) to form a control closed loop with complete control logic.
In some possible implementation manners of the embodiment of the present application, the method may further include:
unloading the system B ', loading the control logic configurations of the system A', the system C 'and the system D' in the virtual simulation system;
loading 0-1 layer IO point-to-point lists of the system A ', the system C ' and the system D ' in a matching manner at a verification control station;
loading the control logic configuration of the system B on the physical control cabinet;
removing the hard wiring of the originally connected system A, and controlling the cabinet and the physical IO interface device through the hard wiring physical according to the actual IO point of the system B;
loading an IO (input/output) point-to-point list between an IO interface device of the system B and the process simulation model in a verification control station in a matched manner;
and carrying out data docking on the inter-station communication points of the system B' and the system B through a data transfer module loaded in the data.
Therefore, the process system simulation model is butted with data points of the virtual simulation systems (A ', C ' and D ') and the physical control cabinet (system B) to form a control closed loop with complete control logic.
In some possible implementation manners of the embodiment of the present application, the method may further include:
removing hard wiring between the originally connected material object control cabinet of the system B and the material object IO interface device;
an IO (input/output) point-to-point list between an IO interface device of the unloading system B and the process simulation model is displayed in the verification control station;
unloading the data transfer module in the simulation model server;
loading the control logic configurations of a system A ', a system B', a system C 'and a system D' in the virtual simulation system;
and loading 0-1 layer IO point-to-point lists of the system A ', the system B', the system C 'and the system D' in a matching way on the verification control station.
In this way, the process system simulation model is interfaced with the data points of the virtual simulation systems (A ', B', C ', D') to form a control closed loop of the complete control logic.
In some possible implementation manners of the embodiment of the present application, before step S301, the method further includes:
and performing joint debugging test on the logic configurations of the virtual simulation system and the physical control cabinet respectively through IO (input/output) point list, inter-station communication point list, hard wiring and data configuration preprocessing.
Thus, pre-handover preparation is achieved.
The embodiment of the application provides a switching control method of a virtual simulation model and a physical control cabinet, which is suitable for a large-scale distributed industrial control system. The system uses a minimized hardware structure, and meets the requirements of hardware defect screening and testing. In addition, the system can realize all logic configurations and functions of the DCS through the simulation model, so that operation and maintenance analysis and verification work of the DCS can be carried out in a full range. The physical control cabinet and the virtual simulation model can be simultaneously connected with the process system simulation model to operate to carry out DCS software and hardware verification, and the physical control cabinet can also be cut off and independently connected with the process system simulation model to operate through the virtual simulation model to carry out DCS software verification. The method enables the verified virtual simulation model to be tested in an environment closer to reality, can realize cross verification and rapid verification of various large DCS system functions and configurations, and improves verification efficiency and verification reliability.
The present application has been described in detail with reference to the drawings and examples, but the present application is not limited to the above examples, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present application. The prior art can be used for all the matters not described in detail in this application.
Claims (10)
1. A distributed industrial control system of a nuclear power station is characterized in that: the system, comprising: the system comprises a minimized physical human-computer interface, a virtual simulation system, a physical control cabinet, a verification control station and a process system simulation model;
the minimized physical human-computer interface is connected with the virtual simulation system and used for realizing operation and parameter monitoring;
the virtual simulation system is also connected with the process system simulation model through a virtual simulation system IO communication program and is used for loading virtual simulation models of all process control cabinets of the nuclear power unit DCS system to simulate relevant control logic configuration faults;
the verification control station is loaded with a verification control communication program and is responsible for communication among the virtual simulation system, the verification control station and the process system simulation model;
the minimized physical human-computer interface is also connected with the physical control cabinet;
the physical control cabinet is connected with the process system simulation model through a physical IO interface device and is used for loading the nuclear power unit DCS system engineering configuration and operating the nuclear power unit DCS process control configuration logic;
the process system simulation model is used for simulating the operation condition of the nuclear power unit process equipment.
2. The distributed industrial control system of nuclear power plants of claim 1, wherein:
the virtual simulation system comprises configuration logics of all control systems of the nuclear power station, and the physical control cabinet can be provided with a plurality of DCS control system configuration logics in all control systems of the nuclear power station.
3. The distributed industrial control system of nuclear power plants of claim 1, wherein:
the minimized physical human-computer interface comprises: a set of operator stations, a set of administrator stations, an interface unit, a data archiving unit, a processing unit, an engineer station, and a diagnostic system.
4. The distributed industrial control system of nuclear power plants of claim 1, wherein:
the material object IO interface device is connected with the material object control cabinet through hard wiring.
5. The nuclear power plant distributed industrial control system of claim 4, wherein:
the physical IO interface device integrates an AI data interface module, an AO data interface module, a DI data interface module, a DO data interface module and a simulation RTD data interface module and is used for carrying out data communication between the physical control cabinet and the process system simulation model in DCS process control.
6. The distributed industrial control system of nuclear power plants of claim 1, wherein:
the virtual simulation system runs in a simulation model server;
the virtual simulation system IO communication program is loaded in the simulation model server;
the process system simulation model is installed in the simulation model server.
7. A virtual and physical switching control method for a distributed industrial control system of a nuclear power station is characterized by comprising the following steps: the distributed industrial control system is applied to the nuclear power plant as claimed in any one of claims 1 to 6; the method comprises the following steps:
loading the control logic configurations of a system B ', a system C ' and a system D ' in the virtual simulation system;
loading 0-1 layer IO point-to-point lists of the system B ', the system C ' and the system D ' in a matched manner on the verification control station;
loading the control logic configuration of the system A on the physical control cabinet;
connecting the material object control cabinet and the material object IO interface device through hard wiring according to an actual IO point of the system A;
loading an IO (input/output) point-to-point list between an IO interface device of the system A and the process simulation model in a matching way on the verification control station;
and carrying out data docking on the inter-station communication points of the system A' and the system A loaded in the virtual simulation system through a data transfer module loaded in the simulation model server.
8. The virtual and physical switching control method for the distributed industrial control system of the nuclear power plant as claimed in claim 7, characterized in that: the method further comprises the following steps:
unloading the system B 'in the virtual simulation system, and loading the control logic configurations of the system A', the system C 'and the system D';
loading 0-1 layer IO point-to-point lists of the system A ', the system C ' and the system D ' in a matched manner on the verification control station;
loading the control logic configuration of the system B on the physical control cabinet;
removing the hard wiring of the originally connected system A, and according to the actual IO point of the system B, carrying out hard wiring on the physical control cabinet and the physical IO interface device;
loading an IO (input/output) point-to-point list between an IO interface device of the system B and the process simulation model in a matching way on the verification control station;
and carrying out data docking on the inter-station communication points of the system B' and the system B through the data transfer module loaded in the data.
9. The virtual and physical switching control method for the distributed industrial control system of the nuclear power plant as claimed in claim 8, characterized in that: the method further comprises the following steps:
removing hard wiring between the object control cabinet and the object IO interface device of the originally connected system B;
unloading an IO (input/output) point-to-point list between an IO interface device of a system B and the process simulation model at the verification control station;
unloading a data relay module at the simulation model server;
loading control logic configurations of a system A ', a system B', a system C 'and a system D' in the virtual simulation system;
and loading 0-1 layer IO point-to-point lists of the system A ', the system B', the system C 'and the system D' in a matched manner on the verification control station.
10. The virtual and physical switching control method for the distributed industrial control system of the nuclear power plant as claimed in claim 7, characterized in that: the loading of the control logic configurations of the system B ', the system C ', and the system D ' in the virtual simulation system previously further includes:
and performing joint debugging test on the logic configurations of the virtual simulation system and the physical control cabinet respectively through IO (input/output) point list, inter-station communication point list, hard wiring and data configuration preprocessing.
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