CN115033951A - Fire alarm response support system for holographic digital nuclear power operation and construction method thereof - Google Patents

Abstract

The invention relates to a fire alarm response support system for holographic digital nuclear power operation and a construction method thereof, wherein the method comprises the following steps: receiving a fire detection signal from a nuclear power plant fire detection system, determining the occurrence position of the current fire, and performing associated mapping on the occurrence position and a pre-established nuclear power plant three-dimensional virtual model so as to add a corresponding fire identifier in the nuclear power plant three-dimensional virtual model; acquiring a fire detection signal from an industrial control system of the nuclear power plant in real time, and dynamically mapping the fire detection signal to a three-dimensional virtual model of the nuclear power plant; according to the occurrence position, acquiring fire fighting equipment information related to the current fire condition by calling a pre-established information base related to the three-dimensional virtual model of the nuclear power plant, and marking the information on the three-dimensional virtual model of the nuclear power plant; and pushing the current three-dimensional virtual model of the nuclear power plant to a master control room and/or terminal equipment of field personnel. Through this technical scheme, improved fire alarm response efficiency, simultaneously, alleviateed on-the-spot personnel's work load.

Description

Fire alarm response support system for holographic digital nuclear power operation and construction method thereof

Technical Field

The invention relates to the field of nuclear power operation, in particular to a fire alarm response support system for holographic digital nuclear power operation and a construction method thereof.

Background

When a safety-related plant of a nuclear power plant is in a fire, the existing fire alarm response mode is generally as follows: the information of fire occurrence places, surrounding fire-fighting facilities and the like is confirmed in a manual alarm mode, and then field personnel carry out corresponding operation according to a paper fire alarm response flow and an operation sheet, and an operator controls a machine set and executes accident regulations. However, this mode has the following problems:

1. because the information of the fire occurrence place, the surrounding fire-fighting facilities and the like needs to be confirmed manually, the fire alarm response efficiency is low, the optimal time for on-site personnel to put out a fire is possibly delayed, the control of a machine set by an operator and the execution of accident regulations are delayed, and the risk of out-of-control of the machine set exists;

2. the workload of field personnel is high and the risk of human error exists.

Disclosure of Invention

The invention aims to solve the technical problems that in the prior art, the fire alarm response support system for the holographic digital nuclear power operation and the construction method thereof are provided, aiming at the defects that the fire alarm response efficiency is low and the workload of field personnel is large.

The technical scheme adopted by the invention for solving the technical problems is as follows: a construction method for constructing a fire alarm response support system for holographic digital nuclear power operation comprises the following steps:

receiving a fire detection signal from a nuclear power plant fire detection system, determining the occurrence position of the current fire according to the fire detection signal, and performing associated mapping on the occurrence position and a pre-established nuclear power plant three-dimensional virtual model so as to add a corresponding fire identifier in the nuclear power plant three-dimensional virtual model;

acquiring a fire detection signal from an industrial control system of a nuclear power plant in real time, and dynamically mapping the fire detection signal to a three-dimensional virtual model of the nuclear power plant;

according to the occurrence position, acquiring fire-fighting facility information related to the current fire condition by calling a pre-established information base related to the three-dimensional virtual model of the nuclear power plant, and marking the fire-fighting facility information on the three-dimensional virtual model of the nuclear power plant, wherein the information base stores the fire-fighting facility information inside and outside each factory building or fire-fighting partition;

and pushing the current three-dimensional virtual model of the nuclear power plant to a master control room and/or terminal equipment of field personnel.

Preferably, the method further comprises the following steps:

receiving a query request from a master control room and/or terminal equipment, and acquiring query result information related to the current fire condition by calling the information base, wherein the information base also stores structure information of each plant, system equipment information inside and outside each plant or fire-proof subarea, and fire-fighting management information of each plant or fire-proof subarea; the query request includes: a structure query request, a system equipment query request and a fire fighting management query request; the query result information includes: structure information, system equipment information, fire management information;

and pushing the query result information to a corresponding main control room and/or terminal equipment.

Preferably, the method further comprises the following steps:

determining the level of the current fire according to the fire detection signal, and calling out a corresponding fire response regulation and/or a fire response decision instruction according to the level of the current fire;

and pushing the fire response rules and/or the fire response decision instructions to a master control room and/or terminal equipment of field personnel.

Preferably, the method further comprises the following steps:

and receiving command scheduling information of an operator from a nuclear power plant communication system, and issuing the command scheduling information to terminal equipment of field personnel through the nuclear power plant communication system.

Preferably, the method further comprises the following steps:

receiving a path searching instruction of field personnel from terminal equipment, and planning a path according to the current position of the field personnel and the occurrence position of the current fire;

and navigating according to the planned path.

Preferably, the method further comprises the following steps:

receiving a view angle selection request from a master control room and/or terminal equipment, and adjusting a current roaming scene of the three-dimensional virtual model of the nuclear power plant;

and pushing the adjusted three-dimensional virtual model of the nuclear power plant to a corresponding main control room and/or terminal equipment.

The invention also constructs a fire alarm response support system for holographic digital nuclear power operation, which comprises the following steps:

a nuclear power plant three-dimensional virtual model which is created and stored in advance;

the method comprises the steps that an information base which is associated with the three-dimensional virtual model of the nuclear power plant is established in advance, and fire-fighting facility information inside and outside each factory building or fire-fighting subarea is stored in the information base;

a processor and which when executing a stored computer program performs the steps of nuclear power operation fire alarm response support described above.

The invention also constructs a fire alarm response support system for holographic digital nuclear power operation, which comprises the following steps:

the system comprises a first acquisition module, a second acquisition module and a third acquisition module, wherein the first acquisition module is used for receiving a fire alarm detection signal from a fire alarm detection system of the nuclear power plant, determining the occurrence position of the current fire according to the fire alarm detection signal, and performing associated mapping on the occurrence position and a pre-established three-dimensional virtual model of the nuclear power plant so as to add a corresponding fire identifier into the three-dimensional virtual model of the nuclear power plant;

the second acquisition module is used for acquiring a fire detection signal from an industrial control system of the nuclear power plant in real time and dynamically mapping the fire detection signal to the three-dimensional virtual model of the nuclear power plant;

a third obtaining module, configured to obtain, according to the occurrence position, fire-fighting equipment information related to a current fire by calling a pre-established information base associated with the three-dimensional virtual model of the nuclear power plant, and mark the fire-fighting equipment information on the three-dimensional virtual model of the nuclear power plant, where the information base stores fire-fighting equipment information inside and outside each plant or fire-fighting partition;

and the pushing module is used for pushing the current three-dimensional virtual model of the nuclear power plant to a master control room and/or terminal equipment of field personnel.

Preferably, a fourth obtaining module is further included, and,

the fourth acquisition module is used for receiving the query request from the main control room and/or the terminal equipment and acquiring query result information related to the current fire condition by calling the information base, wherein the information base also stores the structure information of each plant, the system equipment information inside and outside each plant or fire-fighting partition and the fire-fighting management information of each plant or fire-fighting partition; the query request includes: a structure query request, a system equipment query request and a fire fighting management query request; the query result information includes: structure information, system equipment information, fire management information;

the pushing module is further configured to push the query result information to a corresponding main control room and/or terminal device.

Preferably, a fifth obtaining module is further included, and,

the fifth acquisition module is used for determining the level of the current fire according to the fire detection signal and calling out a corresponding fire response regulation and/or a fire response decision instruction according to the level of the current fire;

the pushing module is further used for pushing the fire response rules and/or the fire response decision instructions to a main control room and/or terminal equipment of field personnel.

According to the technical scheme provided by the invention, when a fire occurs in the nuclear power plant, the current three-dimensional virtual model (with a fire identifier, labeled with fire-fighting facility information and displayed with the state of the fire-fighting equipment) of the nuclear power plant is automatically pushed to the terminal equipment of a main control room and/or field personnel, and an operator and/or the field personnel can intuitively and timely know the occurrence place of the current fire, the related fire-fighting facility information, the state of the fire-fighting equipment and the like through the three-dimensional virtual model of the nuclear power plant, so that the fire response efficiency is improved, the fire response event is optimized, the optimal time is won for the field personnel to extinguish the fire, the enough time is won for the operator to control the unit and execute the accident procedures, and the risk of out-of-control of the unit is reduced. Meanwhile, the workload of field personnel is reduced, and the risk of human errors is reduced.

Drawings

In order to illustrate the embodiments of the invention more clearly, the drawings that are needed in the description of the embodiments will be briefly described below, it being apparent that the drawings in the following description are only some embodiments of the invention, and that other drawings may be derived from those drawings by a person skilled in the art without inventive effort. In the drawings:

FIG. 1 is a flow chart of a first embodiment of a construction method of a holographic digital nuclear power operation fire alarm response support system of the invention;

FIG. 2 is a logic structure diagram of a first embodiment of the fire alarm response support system for holographic digital nuclear power operation according to the present invention;

fig. 3 is a logical structure diagram of a second embodiment of the fire alarm response support system for holographic digital nuclear power operation according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Fig. 1 is a flowchart of a first embodiment of a method for constructing a holographic digital nuclear power operation fire alarm response support system according to the present invention, the method of the embodiment including the steps of:

s10, receiving a fire detection signal from a nuclear power plant fire detection system, determining the occurrence position of the current fire according to the fire detection signal, and performing associated mapping on the occurrence position and a pre-established nuclear power plant three-dimensional virtual model so as to add a corresponding fire identifier in the nuclear power plant three-dimensional virtual model;

s20, acquiring a fire-fighting detection signal from an industrial control system of the nuclear power plant in real time, and dynamically mapping the fire-fighting detection signal to a three-dimensional virtual model of the nuclear power plant;

s30, acquiring fire-fighting facility information related to the current fire situation by calling a pre-established information base related to the three-dimensional virtual model of the nuclear power plant according to the occurrence position, and marking the fire-fighting facility information on the three-dimensional virtual model of the nuclear power plant, wherein the information base stores the fire-fighting facility information inside and outside each factory building or fire-fighting partition;

and S40, pushing the current three-dimensional virtual model of the nuclear power plant to a main control room and/or terminal equipment of field personnel.

In this embodiment, there are the following points to be explained:

1. regarding the creation of the three-dimensional virtual model of the nuclear power plant, it should be noted that, firstly, the three-dimensional virtual model of the nuclear power plant is constructed, for example, a three-dimensional model of a civil structure of a plant of the nuclear power plant and an appearance of a system device (including a pump, a valve, a pipeline, a box, an electric panel, a motor and a flammable and explosive substance) can be constructed by using three-dimensional modeling software. And then, rendering the virtual environment effect, for example, rendering the virtual environment effect of the nuclear power plant in a rendering engine through material, map, shadow, special effect and other modes based on the constructed three-dimensional virtual model of the nuclear power plant, so as to restore the actual site environment of the nuclear power plant one by one.

2. Regarding the information base, it should be noted that, an information base of the nuclear power operation fire alarm response full information may be established first, and the following information is stored in the information base: the information of the structures of the factory buildings (including the factory building coding information of floors and rooms, the fire-resistant limit information of fire barriers, the fire load and material storage information, the storage information of dangerous chemicals, the room power supply, the channel smoke exhaust operation and other information); information on fire-fighting facilities inside and outside the plant and fire-fighting partition (including fixed fire-fighting facilities, mobile fire extinguishers, fire hydrants/reels, attack/escape tunnels, telephones, ventilation/smoke exhaust panels, fire alarm operation panels, etc.); information of system equipment inside and outside the plant and the fire-protection subarea (including a system equipment list contained in the room or the fire-protection subarea, information of system equipment which fails after a fire, a fault mode, influence consequences and the like); fire control management information of factory buildings and fire zones (including maintenance information, temporary configuration information, unavailable information and the like of fire barriers, fire plugs, fire-fighting facilities, smoke-discharging facilities and the like of rooms). And then carrying out association mapping on various types of information in the information base and the created three-dimensional virtual model of the nuclear power plant.

3. With respect to the fire detection signals, it should be noted that the fire detection system of the nuclear power plant includes a plurality of different types of fire detectors distributed in each plant and fire zone. When a fire occurs, the fire detector at the position is triggered to send out a fire detection signal, and the address codes in the fire detection signals of different plants and fire prevention partitions can be associated with the three-dimensional virtual model of the nuclear power plant. Specifically, the fire information in different factory building rooms of the nuclear power plant is detected by different types of fire detectors respectively, the fire information comprises address codes of the fire detectors which detect the fire, and the position of the current fire in the three-dimensional virtual model of the nuclear power plant can be determined by combining a pre-stored address code mapping table (a corresponding relation table between the address codes of the fire detectors of the nuclear power plant and the codes of the factory building rooms in which the fire detectors are located). After the fire position is determined, a fire mark can be added at the corresponding position of the three-dimensional virtual model of the nuclear power plant so as to display a virtual three-dimensional picture of the fire.

4. Regarding the fire detection signal, it should be noted that the industrial control system of the nuclear power plant includes a plurality of fire detectors distributed in each plant and fire partition of the nuclear power plant, and is used for detecting status signals of fire-fighting facilities, fire doors, fire baffles, smoke exhaust systems and ventilation systems. Furthermore, the address codes in the fire detection signals sent by the fire detectors can be associated with the three-dimensional virtual model of the nuclear power plant so as to dynamically drive the evolution of the three-dimensional virtual model of the nuclear power plant.

Through the technical scheme of the embodiment, when a fire occurs, the current three-dimensional virtual model (with the fire identification, the information of the fire-fighting facilities marked and the state of the fire-fighting equipment displayed) of the nuclear power plant is automatically pushed to the terminal equipment of the master control room and/or field personnel, and an operator and/or the field personnel can intuitively and timely know the occurrence place of the current fire, the related information of the fire-fighting facilities, the state of the fire-fighting equipment and the like through the three-dimensional virtual model of the nuclear power plant, so that the fire response efficiency is improved, the fire response event is optimized, the optimal time is won for the field personnel to extinguish the fire, the time is enough for the operator to control the unit and execute the accident regulations, and the risk of losing control of the unit is reduced. Meanwhile, the workload of field personnel is reduced, and the risk of human errors is reduced.

Further, in an optional embodiment, the method for constructing the holographic digital nuclear power operation fire alarm response support system further comprises:

s50, receiving a query request from a master control room and/or terminal equipment, and acquiring query result information related to the current fire situation by calling the information base, wherein the information base also stores structure information of each plant, system equipment information inside and outside each plant or fire-fighting partition, and fire-fighting management information of each plant or fire-fighting partition; the query request includes: a structure query request, a system equipment query request and a fire fighting management query request; the query result information comprises: structure information, fire management information;

and S60, pushing the query result information to a corresponding main control room and/or terminal equipment.

In this embodiment, in the presented three-dimensional virtual model of the nuclear power plant, the user can view the following contents by clicking on the corresponding option: the information includes structure information (fire endurance of the fire barrier, fire load and material storage information, hazardous chemical storage information, information on power on/off of a room, operation of ventilation and smoke exhaust), system equipment information (a list of stored system equipment, information on system equipment that has failed after a fire, failure modes, consequences and the like), and fire management information (maintenance information, temporary configuration information, unavailability information, and the like of the fire barrier, fire block, fire protection facility, smoke exhaust facility, and the like of the room).

Further, in an optional embodiment, the method for constructing the holographic digital nuclear power operation fire alarm response support system of the present invention further comprises:

determining the level of the current fire according to the fire detection signal, and calling out a corresponding fire response rule and/or a fire response decision instruction according to the level of the current fire;

and pushing the fire response rules and/or the fire response decision instructions to a master control room and/or terminal equipment of field personnel.

In the embodiment, the intelligent aid decision-making function of multi-stage fire alarm response can be provided for an operator, and comprises automatic pushing of multi-stage fire alarm response procedures and automatic pushing of fire alarm response decision-making instructions.

Further, in an optional embodiment, the method for constructing the holographic digital nuclear power operation fire alarm response support system further comprises: and receiving command scheduling information of an operator from a nuclear power plant communication system, and issuing the command scheduling information to terminal equipment of field personnel through the nuclear power plant communication system. In the embodiment, the communication and command dispatching functions of the operator and other fire alarm response organizations and members of the nuclear power plant through the communication system are realized through the intercommunication and interconnection with the nuclear power plant communication system (such as the communication systems including a telephone system, a voice broadcasting system, a mobile communication system, a pager communication system and the like).

Further, in an optional embodiment, the method for constructing the holographic digital nuclear power operation fire alarm response support system of the present invention further comprises:

receiving a path searching instruction of field personnel from terminal equipment, and planning a path according to the current position of the field personnel and the occurrence position of the current fire;

and navigating according to the planned path.

In the embodiment, the occurrence position of the current fire marked on the map of the APP is automatically pushed through the mobile office network and the port of the terminal device (such as a mobile phone) APP, a one-key route searching can be selected, the path from the current position to the fire scene position is planned, and the automatic navigation is realized, and the suitable attack route and the withdrawing route are included.

Further, in an optional embodiment, the method for constructing the holographic digital nuclear power operation fire alarm response support system further comprises:

receiving a view selection request from a main control room and/or a terminal device, and adjusting a current roaming scene of the three-dimensional virtual model of the nuclear power plant, wherein the selectable vision comprises: a first person perspective; the third person is called the view angle; a bird's eye view angle; a free viewing angle;

and pushing the adjusted three-dimensional virtual model of the nuclear power plant to a corresponding main control room and/or terminal equipment.

In this embodiment, the user can implement the roaming function of different view angles in the three-dimensional virtual scene.

Fig. 2 is a logical structure diagram of a first embodiment of the holographic digital nuclear power operation fire alarm response support system according to the present invention, and the system 100 of this embodiment includes: the system comprises a processor 10, a three-dimensional virtual model 20 of the nuclear power plant and an information base 30, wherein the three-dimensional virtual model 10 of the nuclear power plant is a three-dimensional virtual model which is created in advance according to the actual environment of the nuclear power plant and is consistent with the actual environment; the information base 30 is pre-established and stores information of fire-fighting facilities inside and outside each factory building or fire-fighting partition, and the stored information is associated with the three-dimensional virtual model of the nuclear power plant; the processor 10 is configured to implement the steps of the nuclear power operation fire alarm response support of the above embodiments when executing the stored computer program.

In addition, the holographic digital nuclear power operation fire alarm response support system 100 of the embodiment is also in communication connection with a nuclear power plant fire alarm detection system, a nuclear power plant industrial control system, a nuclear power plant communication system, a main control room and a terminal device through development of interfaces, so that the requirement of nuclear power plant operation fire alarm response is met.

Fig. 3 is a logical structure diagram of a second embodiment of the holographic digital nuclear power operation fire alarm response support system according to the present invention, and the holographic digital nuclear power operation fire alarm response support system of the embodiment includes: the system comprises a first acquisition module 11, a second acquisition module 12, a third acquisition module 13 and a push module 14, wherein the first acquisition module 11 is used for receiving a fire detection signal from a fire detection system of the nuclear power plant, determining the occurrence position of the current fire according to the fire detection signal, and performing association mapping on the occurrence position and a pre-established three-dimensional virtual model of the nuclear power plant so as to add a corresponding fire identifier into the three-dimensional virtual model of the nuclear power plant; the second obtaining module 12 is configured to obtain a fire detection signal from an industrial control system of a nuclear power plant in real time, and dynamically map the fire detection signal to the three-dimensional virtual model of the nuclear power plant; the third obtaining module 13 is configured to obtain fire protection facility information related to a current fire condition by calling a pre-established information base associated with the three-dimensional virtual model of the nuclear power plant according to the occurrence position, and mark the fire protection facility information on the three-dimensional virtual model of the nuclear power plant, where the information base stores fire protection facility information inside and outside each plant or fire-protection partition; the pushing module 14 is configured to push the current three-dimensional virtual model of the nuclear power plant to a terminal device of a main control room and/or a field person.

Furthermore, the holographic digital nuclear power operation fire alarm response support system further comprises a fourth acquisition module, wherein the fourth acquisition module is used for receiving an inquiry request from a main control room and/or terminal equipment and acquiring inquiry result information related to the current fire condition by calling the information base, and the information base also stores structure information of each plant, system equipment information inside and outside each plant or a fire-protection subarea and fire-protection management information of each plant or the fire-protection subarea; the query request includes: a structure query request, a system equipment query request and a fire protection management query request; the query result information comprises: structure information, system equipment information, fire management information; the pushing module is further used for pushing the query result information to a corresponding main control room and/or terminal equipment.

Furthermore, the fire alarm response support system for holographic digital nuclear power operation further comprises a fifth acquisition module, wherein the fifth acquisition module is used for determining the level of the current fire according to the fire detection signal and calling out a corresponding fire response rule and/or a fire response decision instruction according to the level of the current fire; the pushing module is also used for pushing the fire response rules and/or the fire response decision instructions to a main control room and/or terminal equipment of field personnel.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (10)

1. A construction method of a fire alarm response support system for holographic digital nuclear power operation is characterized by comprising the following steps:

receiving a fire detection signal from a nuclear power plant fire detection system, determining the occurrence position of the current fire according to the fire detection signal, and performing associated mapping on the occurrence position and a pre-established nuclear power plant three-dimensional virtual model so as to add a corresponding fire identifier in the nuclear power plant three-dimensional virtual model;

acquiring a fire detection signal from an industrial control system of a nuclear power plant in real time, and dynamically mapping the fire detection signal to a three-dimensional virtual model of the nuclear power plant;

according to the occurrence position, acquiring fire-fighting facility information related to the current fire situation by calling a pre-established information base related to the three-dimensional virtual model of the nuclear power plant, and marking the fire-fighting facility information on the three-dimensional virtual model of the nuclear power plant, wherein the information base stores the fire-fighting facility information inside and outside each plant or fire-fighting partition;

and pushing the current three-dimensional virtual model of the nuclear power plant to a master control room and/or terminal equipment of field personnel.

2. The method for constructing the fire alarm response support system for holographic digital nuclear power operation according to claim 1, further comprising:

receiving a query request from a master control room and/or terminal equipment, and acquiring query result information related to the current fire condition by calling the information base, wherein the information base also stores structure information of each plant, system equipment information inside and outside each plant or fire-fighting subarea, and fire-fighting management information of each plant or fire-fighting subarea; the query request includes: a structure query request, a system equipment query request and a fire fighting management query request; the query result information includes: structure information, system equipment information, fire management information;

and pushing the query result information to a corresponding main control room and/or terminal equipment.

3. The method for constructing the holographic digital nuclear power operation fire alarm response support system according to claim 1, further comprising:

determining the level of the current fire according to the fire detection signal, and calling out a corresponding fire response regulation and/or a fire response decision instruction according to the level of the current fire;

and pushing the fire response rules and/or the fire response decision instructions to a master control room and/or terminal equipment of field personnel.

4. The construction method of the holographic digital nuclear power operation fire alarm response support system according to any one of claims 1 to 3, further comprising:

and receiving command scheduling information of an operator from a nuclear power plant communication system, and issuing the command scheduling information to terminal equipment of field personnel through the nuclear power plant communication system.

5. The method for constructing the holographic digital nuclear power operation fire alarm response support system according to claim 4, further comprising:

receiving a path searching instruction of field personnel from terminal equipment, and planning a path according to the current position of the field personnel and the occurrence position of the current fire;

and navigating according to the planned path.

6. The method for constructing the fire alarm response support system for holographic digital nuclear power operation according to claim 1, further comprising:

receiving a view selection request from a main control room and/or terminal equipment, and adjusting a current roaming scene of the three-dimensional virtual model of the nuclear power plant;

and pushing the adjusted three-dimensional virtual model of the nuclear power plant to a corresponding main control room and/or terminal equipment.

7. A fire alarm response support system for holographic digital nuclear power operation is characterized by comprising the following components:

a nuclear power plant three-dimensional virtual model which is created and stored in advance;

the method comprises the steps that an information base which is associated with the three-dimensional virtual model of the nuclear power plant is established in advance, and fire-fighting facility information inside and outside each factory building or fire-fighting subarea is stored in the information base;

a processor and which when executing a stored computer program performs the steps of the nuclear power operation fire alarm response support of any one of claims 1 to 6.

8. A fire alarm response support system for holographic digital nuclear power operation is characterized by comprising the following components:

the system comprises a first acquisition module, a second acquisition module and a third acquisition module, wherein the first acquisition module is used for receiving a fire detection signal from a nuclear power plant fire detection system, determining the occurrence position of the current fire according to the fire detection signal, and performing associated mapping on the occurrence position and a pre-established nuclear power plant three-dimensional virtual model so as to add a corresponding fire identifier into the nuclear power plant three-dimensional virtual model;

the second acquisition module is used for acquiring a fire detection signal from an industrial control system of the nuclear power plant in real time and dynamically mapping the fire detection signal to the three-dimensional virtual model of the nuclear power plant;

a third obtaining module, configured to obtain, according to the occurrence position, fire-fighting equipment information related to a current fire by calling a pre-established information base associated with the three-dimensional virtual model of the nuclear power plant, and mark the fire-fighting equipment information on the three-dimensional virtual model of the nuclear power plant, where the information base stores fire-fighting equipment information inside and outside each plant or fire-fighting partition;

and the pushing module is used for pushing the current three-dimensional virtual model of the nuclear power plant to a master control room and/or terminal equipment of field personnel.

9. The holographic digital nuclear power operation fire alarm response support system according to claim 8, further comprising a fourth acquisition module, and,

the fourth acquisition module is used for receiving the query request from the master control room and/or the terminal equipment and acquiring query result information related to the current fire situation by calling the information base, wherein the information base also stores the structure information of each plant, the system equipment information inside and outside each plant or fire-fighting partition, and the fire-fighting management information of each plant or fire-fighting partition; the query request includes: a structure query request, a system equipment query request and a fire protection management query request; the query result information includes: structure information, system equipment information, fire management information;

the pushing module is further configured to push the query result information to a corresponding main control room and/or terminal device.

10. The holographic digital nuclear power operation fire alarm response support system according to claim 8, further comprising a fifth acquisition module, and,

the fifth acquisition module is used for determining the level of the current fire according to the fire detection signal and calling out a corresponding fire response regulation and/or a fire response decision instruction according to the level of the current fire;

the pushing module is further used for pushing the fire response rules and/or the fire response decision instructions to a main control room and/or terminal equipment of field personnel.

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