CN112820065A - Intelligent fire-fighting command system and method for performing fire-fighting drilling by using same - Google Patents

Abstract

The invention belongs to the field of fire-fighting command, and provides an intelligent fire-fighting command system and a method for fire-fighting drill by using the same, wherein the intelligent fire-fighting command system comprises: the signal receiving module is used for receiving an alarm signal from the fire control cabinet; the virtual scene application module is used for constructing a peripheral three-dimensional virtual scene model and triggering a virtual scene display window corresponding to the accident position in the three-dimensional virtual scene model through an alarm signal; the fire engine management module is used for carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade, or carrying out cross-regional joint fire drill deployment by combining the fire fighting resources of peripheral fire brigades; and the signal sending module is used for sending the virtual scene related information of the accident scene and the fire-fighting command instruction to the firefighter mobile terminal.

Description

Intelligent fire-fighting command system and method for performing fire-fighting drilling by using same

Technical Field

The invention relates to the field of fire-fighting command, in particular to an intelligent fire-fighting command system and a method for fire-fighting drilling by using the same.

Background

The existing three-dimensional fire fighting system is a batch module and a technology, and is not customized according to special requirements of fire fighting teams, each fire fighting team can calculate different fire fighting parameters and flow meters according to different vehicle models, different fire passing areas, different water outlet and foam outlet equipment, different fire extinguishing agent models and the like, and the same results are obtained when a platform at the current stage does not calculate the fire fighting parameters and the flow meters. Therefore, the fire extinguishing process of each fire brigade is the same by using the same system, and the fire extinguishing system is greatly different from the real fire extinguishing situation. The fire-fighting combustion calculation, the water supply calculation, the vehicle tonnage, the fire extinguishing agent discharging equipment and the like are different, the calculation is specifically needed, the engine needs to be adjusted and developed in a large amount, the three-dimensional system company does not have the engine development capability at the present stage, and the fire brigade personnel do not completely know the professional knowledge.

The existing fire control command system is generally used independently, one fire brigade has one command system, and when an emergency management department encounters a super-large fire, the force of one fire brigade cannot be successfully rescued, more fire fighting force cross-regional reinforcement is needed, and the cross-regional combined drilling item is lacked in the system at the present stage. Meanwhile, when the existing command system is used for drilling, the drilling is generally carried out according to the plan script, the ignition position is fixed, and one factory area has a plurality of plans.

Disclosure of Invention

The invention provides an intelligent fire-fighting command system and a method for fire-fighting drilling by using the same, aiming at solving the technical problems.

The scheme of the invention is as follows:

in a first aspect, an intelligent fire-fighting command system is provided, which includes:

the signal receiving module is used for receiving an alarm signal from the fire control cabinet;

the virtual scene application module is used for constructing a peripheral three-dimensional virtual scene model and triggering a virtual scene display window corresponding to an accident position in the three-dimensional virtual scene model through the alarm signal;

the fire engine management module is used for carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade, or carrying out cross-regional joint fire drill deployment by combining the fire fighting resources of peripheral fire brigades;

and the signal sending module is used for sending the virtual scene related information of the accident scene and the fire-fighting command instruction to the firefighter mobile terminal.

Preferably, a virtual scene display window corresponding to an accident position in the three-dimensional virtual scene model includes:

the map display window is used for displaying the peripheral three-dimensional map information, including the information of roads, buildings, fire hydrants, water sources, fire areas, water supply lines and vehicle parking positions;

a 3D visualization window for displaying the building interior structure at a first perspective;

the dangerous chemical physical and chemical property display window is used for displaying the storage condition of dangerous chemicals on an accident site and relevant information of the physical and chemical properties of the dangerous chemicals;

and the ignition point display window is used for displaying relevant information of the ignition equipment, including actual size, material, ignition degree and fire extinguishing difficulty.

Preferably, the intelligent fire-fighting command system further comprises a fire-fighting hidden danger inspection module and a rescue plan management module;

the fire-fighting hidden danger inspection module is used for counting fire-fighting hidden danger information of different peripheral areas, including hidden danger sites, hidden danger content photos, contact ways of responsible persons in inspection areas, hidden danger grading and safety related standard information, analyzing and predicting the severity of hidden dangers of each area through big data, and setting special inspection early warning time for the areas reaching a certain hidden danger degree;

the rescue plan management module is used for formulating an emergency rescue plan according to the hidden danger information, performing fire-fighting simulation drilling on an area reaching a certain hidden danger degree, and making a dynamic drilling video including fire-fighting driving routes, fire-fighting vehicle and fire fighter deployment and fire-fighting tactical application, and the rescue plan management module triggers an emergency rescue plan display window and a dynamic drilling video display window through the alarm signal.

Preferably, the signal receiving module is further configured to receive a monitoring video of an accident scene, and an alarm video and voice information returned from the firefighter mobile terminal;

the alarm signal is also used for triggering a monitoring video display window and an alarm video display window.

Preferably, the intelligent fire-fighting command system further comprises a remote consultation module, the intelligent fire-fighting command systems of different fire brigades are networked, and the remote consultation module is used for being consulted by multiple fire-fighting unit experts together to discuss and analyze an emergency accident handling method.

Preferably, the intelligent fire-fighting command system further comprises: the learning module is used for learning fire-fighting theory business;

the learning module includes 'fire-fighting rescuer' learning materials, 'building structure fireman' learning materials, 'registered fire-fighting engineer' learning materials, fire-fighting learning videos, fire-fighting equipment learning pictures and examination question banks of all learning subjects.

Preferably, the intelligent fire-fighting command system further comprises a drilling module and an examination module;

the rehearsal module is used for inputting fire-fighting equipment and relevant fire-fighting parameters that fire brigade actually disposed, includes: tonnage of vehicle-mounted fire extinguishing agent, flow rate and lift of fire extinguishing equipment, cooling water consumption per unit area and fire extinguishing agent discharging time;

the assessment module is used for deploying positions of fire-fighting vehicles, simulating an actual fire control process by combining the site fixed fire-fighting facilities and the peripheral fixed fire-fighting facilities, calculating the variable of fire extinguishing force and the set fire passing area, judging whether fire extinguishment is successful or not based on the set fire extinguishing logic relation, and scoring each assessment.

In a second aspect, a method for performing fire drill by using an intelligent fire command system is also provided, which includes:

receiving an alarm signal from a fire control cabinet, and triggering a scene display window corresponding to an accident position in a three-dimensional virtual scene model through the alarm signal;

carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade, and carrying out cross-regional joint fire drill deployment by combining the fire fighting resources of peripheral fire brigades;

and sending the relevant information of the virtual scene of the accident scene and a fire command instruction to the firefighter mobile terminal so as to carry out actual fire deployment or cross-regional joint drilling.

Preferably, after receiving the alarm signal, the method further comprises:

triggering an emergency rescue plan display window and a dynamic drilling video display window through the alarm signal;

and receiving the monitoring video of the accident scene, and the alarm video and voice information returned from the firefighter mobile terminal.

Preferably, the deploying of fire rescue according to the fire fighting resources actually configured by the local fire brigade, and the deploying of cross-regional joint fire drill by combining the fire fighting resources of the surrounding fire brigade, include:

inputting fire fighting equipment and relevant fire fighting parameters actually configured by a local fire fighting unit and/or a peripheral fire fighting unit, wherein the fire fighting equipment and the relevant fire fighting parameters comprise: tonnage of vehicle-mounted fire extinguishing agent, flow rate and lift of fire extinguishing equipment, cooling water consumption per unit area and fire extinguishing agent discharging time;

the position and the fire-fighting equipment of the fire-fighting vehicle are deployed, the actual fire control process is simulated by combining the site fixed fire-fighting equipment and the peripheral fixed fire-fighting equipment, whether fire extinguishment is successful or not is judged based on the set fire-extinguishing logical relation through the variable calculation of the fire-extinguishing force and the set fire-passing area, and each check is scored.

Through the technical scheme, fire rescue deployment is carried out according to fire fighting resources actually configured by a local fire brigade, cross-regional joint fire drill deployment is carried out by combining fire fighting resources of peripheral fire brigades, and the purpose of more appropriate actual combat is achieved.

Additional features and advantages of embodiments of the invention will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the embodiments of the invention without limiting the embodiments of the invention. In the drawings:

FIG. 1 is a block diagram of an intelligent fire conductor system;

FIG. 2 is a schematic diagram of rescue and joint drilling using an intelligent fire conductor system;

FIG. 3 is a schematic diagram of learning and drill assessment using the intelligent fire conductor system;

fig. 4 is a flow chart of a method for performing a fire drill using the intelligent fire conductor system.

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating embodiments of the invention, are given by way of illustration and explanation only, not limitation.

The invention provides an intelligent fire-fighting command system, as shown in fig. 1 to 3, a main platform of the intelligent fire-fighting command system comprises: the system comprises a signal receiving module, a virtual scene application module, a fire engine management module and a signal sending module.

The signal receiving module is used for receiving an alarm signal from the fire control cabinet.

The virtual scene application module is used for constructing a peripheral three-dimensional virtual scene model and triggering a virtual scene display window corresponding to an accident position in the three-dimensional virtual scene model through the alarm signal.

The fire engine management module is used for carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade, or carrying out cross-regional joint fire drill deployment by combining fire fighting resources of peripheral fire brigades.

And the signal sending module is used for sending the virtual scene related information of the accident scene and the fire-fighting command instruction to the firefighter mobile terminal.

In the embodiment of the invention, the three-dimensional virtual scene model is initially set according to CAD (computer-aided design) electronic drawings of various factories, 3Dmax software is adopted for carrying out isometric three-dimensional modeling, VR (virtual reality), UE (user equipment) 4 and other software are poured after the model is built, then relevant information of the internal structure of the building is added in a lead-in software platform, and the internal structure is observed from a third visual angle to a first visual angle. The demands of operational command are achieved by inputting fire-fighting equipment information, hazardous chemical physical and chemical property information, emergency rescue plan information and the like.

According to a specific embodiment of the present invention, when receiving an alarm signal, the alarm signal triggers a virtual scene display window corresponding to an accident location in the three-dimensional virtual scene model, including: the system comprises a map display window, a 3D visual window, a dangerous chemical physical and chemical property display window and an ignition point display window.

The map display window is used for displaying surrounding three-dimensional map information, including road, building, fire hydrant, water source, fire area, water supply line and vehicle parking position information.

The 3D visualization window is used for displaying the building internal structure information at a first visual angle.

And the dangerous chemical physical and chemical property display window is used for displaying the dangerous chemical storage condition and the information related to the physical and chemical properties of the dangerous chemical on the accident site.

For example, methanol, formula: CH (CH)₃OH (combustion products carbon dioxide and water, not toxic to combustion products); flash point: 12 ℃ (class a); molecular weight: 32.04; water solubility: completely dissolved with water; density: 0.7918g/cm³(water density 1. lighter than water); description of risks: mixing with air to form an explosive mixture, and heating with heat sourceFire risks of combustion and explosion; the characteristics are as follows: colorless transparent liquid with pungent odor; explosion limit: 6 to 36.5 percent; emergency measures are as follows: (1) skin contact: removing the polluted clothes, and thoroughly washing the skin with soap water and clear water; (2) eye contact: lifting the eyelid, washing with flowing clear water or normal saline, and treating; (3) suction: the oxygen therapy device can be quickly separated from the scene to the fresh air, keep the respiratory tract smooth, if the breathing is difficult, supply oxygen, if the breathing stops, and immediately carry out artificial respiration for medical treatment; (4) eating: drinking sufficient warm water, promoting vomiting or washing stomach with clear water or 1% sodium thiosulfate solution, and treating the doctor).

The ignition point display window is used for displaying relevant information of the ignition equipment, including actual size, material, ignition degree and fire extinguishing difficulty. Such as radius, perimeter, cross-section, high-level data of the fired tank.

On the basis of the above embodiment, according to a specific implementation manner of the present invention, the intelligent fire-fighting command system further includes a fire-fighting hidden danger checking module and a rescue plan management module.

The fire-fighting hidden danger inspection module is used for counting fire-fighting hidden danger information of different peripheral areas, and comprises hidden danger sites, hidden danger content pictures, contact modes of responsible persons in inspection areas, safety relevant specifications and hidden danger classification data, analyzing and predicting the severity of hidden dangers of all areas through big data, and setting special inspection early warning time for the areas reaching a certain hidden danger degree.

The rescue plan management module is used for formulating an emergency rescue plan according to the hidden danger information, performing fire-fighting simulation drilling on an area reaching a certain hidden danger degree, and making a dynamic drilling video including a fire-fighting driving route, deployment of fire-fighting vehicles and fire fighters and fire-fighting tactics application, and the rescue plan management module triggers an emergency rescue plan display window and a dynamic drilling video display window through the alarm signal.

In the embodiment of the invention, by customizing the fire-fighting inspection APP, the fire-fighting hidden danger discovered in the conventional inspection is submitted to the background by using the fire-fighting inspection APP, and the data of hidden danger photos, GPS positioning hidden danger positions, inspection area responsible persons, safety relevant specifications, hidden danger classification and the like are mainly uploaded and submitted to the big database. Through the data accumulation of fire control inspection APP backstage inspection hidden danger every day, provide big data system, utilize big data system to carry out the analysis and predict which regional hidden danger is more, great, more serious, through the contrast in the past the company's security circumstances of data prediction next stage to the great region of big data prediction hidden danger, the fire brigade strengthens daily hidden danger investigation work and the emergent rehearsal work of pertinence, the accident probability of occurrence that has significantly reduced and improves fire control emergency treatment ability.

In the embodiment of the invention, an on-site fire-fighting alarm signal, such as a methanol tank firing signal, is fed back to a fire-fighting control cabinet, and then is fed back to a three-dimensional virtual scene model through a fire-fighting control cabinet signal, and the alarm signal triggers a preset methanol tank emergency rescue plan of an accident point, wherein the plan comprises a fire-fighting driving route, combat deployment, tactical application and the like. The rescue plan management module adopts a unit CAD to be combined with the initial setting to manufacture a three-dimensional stereo image, adds vehicle dynamics into 3Dmax, and then utilizes software such as PR, AE, voice conversion, video distribution and the like to manufacture a dynamic video for fire-fighting, wherein a fire fighting truck is delivered out of a warehouse in 1 minute in the daytime and arrives at the scene within 5 minutes, and in the process, a fire fighter can know the accident site and peripheral conditions, the driving route condition, the ignition device condition, the dangerous chemical condition and the like through a vehicle-mounted video, so that the situation that the team does not know the specific conditions to carry out blind fire-fighting is avoided.

On the basis of the above embodiment, according to a specific implementation manner of the present invention, the signal receiving module is further configured to receive monitoring video of an accident scene, and alarm video and voice information returned from the firefighter mobile terminal. The alarm signal is also used for triggering a monitoring video display window and an alarm video display window.

On the basis of the above embodiment, according to a specific implementation manner of the present invention, the intelligent fire-fighting command system further includes a remote consultation module, which is used for a plurality of fire-fighting unit experts to consult together to discuss and analyze an emergency treatment method.

On the basis of the above embodiment, according to a specific implementation manner of the present invention, the intelligent fire-fighting command system further includes: and the learning module is used for learning fire-fighting theory business. The learning module includes 'fire-fighting rescuer' learning materials, 'building structure fireman' learning materials, 'registered fire-fighting engineer' learning materials, fire-fighting learning videos, fire-fighting equipment learning pictures and examination question banks of all learning subjects. The fire fighters can log in the learning module to learn the fire fighting theory business and evaluate the learning level.

On the basis of the above embodiment, according to a specific implementation manner of the present invention, the intelligent fire-fighting command system further includes a drill module and an examination module.

The rehearsal module is used for inputting fire-fighting equipment and relevant fire-fighting parameters that fire brigade actually disposed, includes: tonnage of vehicle-mounted fire extinguishing agent, flow rate of fire extinguishing equipment, lift, cooling water consumption per unit area and fire extinguishing agent discharging time.

The assessment module is used for deploying positions of fire-fighting vehicles, simulating an actual fire control process by combining the site fixed fire-fighting facilities and the peripheral fixed fire-fighting facilities, calculating the variable of fire extinguishing force and the set fire passing area, judging whether fire extinguishment is successful or not based on the set fire extinguishing logic relation, and scoring each assessment.

According to the scheme of the invention, a fireman arrives at the scene according to the alarm signal for emergency rescue, and simultaneously starts the camera and the bone conduction earphone of the mobile terminal, the fireman mobile terminal is networked with the intelligent fire-fighting command platform, and in the process that the fire truck arrives at the scene within 5 minutes, the fireman knows the accident site and the surrounding conditions, the driving route condition, the ignition device condition, the dangerous chemical condition and the like through the vehicle-mounted video, so that the fireman is prevented from blindly extinguishing the fire and fighting under the condition that the fireman does not know the body. The intelligent fire control command platform is different in attack position through a plurality of team members, and the commander team members form effective combat deployment, and when taking place the personnel and being controlled in the complicated dense area of thick cigarette of structure simultaneously, according to fire hydrant serial number, room serial number, fire extinguisher serial number etc. in the three-dimensional virtual scene model, confirm personnel's position, and command team member in real time and arrive fast and controlled personnel region, and formulate effectual route of fleing, improved fire control emergency rescue comprehensive level greatly. Meanwhile, through the establishment of a local area network, command platforms of a plurality of peripheral emergency rescue units are networked, when a major accident occurs in one unit, VR platforms are started by a plurality of units, and simultaneously, facility equipment parameters, hazardous chemical substance properties and the like at the accident point are displayed through field video return and a virtual scene window, so that experts of the plurality of emergency units can consult together, comprehensively discuss and analyze how the accident is handled, effectively improve the fire emergency rescue level, and reduce economic loss for enterprises.

Because the fire-fighting vehicle model of each fire brigade, the model of the water-discharging and foam-discharging fire-fighting equipment are different, the fire-fighting parameters and the flow are calculated differently, the command system does not consider the fire-fighting parameters and the flow, the same system is shared to ensure that the fire-fighting process of each fire brigade is the same or similar, but the actual fire-fighting process is greatly different from the actual fire-fighting condition because the water supply, the tonnage of the vehicle, the fire-extinguishing agent, the foam-discharging fire-fighting equipment and the like need to be calculated by specific parameters, and a large amount of adjustment and development of an engine. According to the command system provided by the invention, each fire brigade can input the fire fighting resources configured actually in the respective command system, and the fire fighting deployment and the fire fighting force calculation are carried out according to the difference of the fire fighting vehicles, equipment and fire extinguishing agents configured by the local fire brigade and the peripheral fire brigade and the specific conditions of the administered plant area. In practical application, the practice place is not mainly a plan, but is randomly set with an ignition point, the maximum proportion is close to the actual fire extinguishing, and the fire extinguishing operation can be learned in continuous practice. When a fire disaster occurs, the force of one fire brigade is not enough to complete successful rescue, and cross-region fire fighting force needs to be collected to reinforce, all fire fighting command systems are connected to perform cross-region combined drilling, vehicle parameters, equipment parameters, fire extinguishing agent parameters, fire fighting water supply time, pump flow and the like of a plurality of surrounding fire brigades are counted, and fire extinguishing logic operation is performed.

The invention also provides a method for performing fire drill by using the intelligent fire command system, as shown in fig. 4, the method comprises the following steps:

s1, receiving an alarm signal from a fire control cabinet, and triggering a scene display window corresponding to an accident position in a three-dimensional virtual scene model through the alarm signal;

step S2, carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade, and carrying out cross-regional joint fire drill deployment by combining the fire fighting resources of peripheral fire brigades;

and step S3, sending the virtual scene related information of the accident scene and a fire command instruction to the firefighter mobile terminal for actual fire deployment or cross-regional joint drilling.

According to a specific embodiment, in step S1 of the present invention, after receiving the alarm signal, the method further includes:

triggering an emergency rescue plan display window and a dynamic drilling video display window through the alarm signal;

and receiving the monitoring video of the accident scene, and the alarm video and voice information returned from the firefighter mobile terminal.

In step S3, the performing fire rescue deployment according to the fire fighting resources actually configured by the local fire brigade, and performing cross-regional joint fire drill deployment in combination with the fire fighting resources of the surrounding fire brigade includes:

inputting fire fighting equipment and relevant fire fighting parameters actually configured by a local fire fighting unit and/or a peripheral fire fighting unit, wherein the fire fighting equipment and the relevant fire fighting parameters comprise: tonnage of vehicle-mounted fire extinguishing agent, flow rate and lift of fire extinguishing equipment, cooling water consumption per unit area and fire extinguishing agent discharging time;

the position and the fire-fighting equipment of the fire-fighting vehicle are deployed, the actual fire control process is simulated by combining the site fixed fire-fighting equipment and the peripheral fixed fire-fighting equipment, whether fire extinguishment is successful or not is judged based on the set fire-extinguishing logical relation through the variable calculation of the fire-extinguishing force and the set fire-passing area, and each check is scored

In the embodiment of the invention, the intelligent fire command platform is used for performing cross-regional combined drilling, and the fire-fighting variable formula is optimized by setting the random ignition point, so that the purposes of cross-regional combined combat simulation drilling and more appropriate actual combat are realized. The scheme of the invention changes the original plan setting script into a plan-free script, randomly sets fire points, and calculates according to the fire area and the fire extinguishing force variable, thereby achieving the purpose of fire extinguishing. When a super-large accident occurs, one independent fire brigade system is combined with a plurality of emergency unit fire-fighting systems to simulate rehearsal, cross-region combined rehearsal is realized, emergency rescue forces of a plurality of surrounding regions are integrated, and scientific rescue is carried out comprehensively, so that the emergency rescue commanding and fighting level is greatly improved.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

While the present application has been described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems) and computer program products according to embodiments of the application, it will be understood that each flowchart illustration and/or block diagram block or blocks, and combinations of flowchart illustrations and/or block diagrams block or blocks, can be implemented by computer program instructions.

These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

In a typical configuration, a computing device includes one or more processors (CPUs), input/output interfaces, network interfaces, and memory. The memory may include forms of volatile memory in a computer readable medium, Random Access Memory (RAM) and/or non-volatile memory, such as Read Only Memory (ROM) or flash memory (flash RAM). The memory is an example of a computer-readable medium.

Computer-readable media, including both non-transitory and non-transitory, removable and non-removable media, may implement information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, phase change memory (PRAM), Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), Read Only Memory (ROM), Electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), Digital Versatile Discs (DVD) or other optical storage, magnetic cassettes, magnetic tape magnetic disk storage or other magnetic storage devices, or any other non-transmission medium that can be used to store information that can be accessed by a computing device. As defined herein, a computer readable medium does not include a transitory computer readable medium such as a modulated data signal and a carrier wave.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, method, article, or apparatus that comprises the element.

The above are merely examples of the present application and are not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. An intelligent fire-fighting command system, which is characterized in that the intelligent fire-fighting command system comprises:

the signal receiving module is used for receiving an alarm signal from the fire control cabinet;

the virtual scene application module is used for constructing a peripheral three-dimensional virtual scene model and triggering a virtual scene display window corresponding to an accident position in the three-dimensional virtual scene model through the alarm signal;

the fire engine management module is used for carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade and carrying out cross-regional joint fire drill deployment by combining the fire fighting resources of peripheral fire brigades;

and the signal sending module is used for sending the virtual scene related information of the accident scene and the fire-fighting command instruction to the firefighter mobile terminal.

2. The intelligent fire fighting command system according to claim 1, wherein the virtual scene display window corresponding to the accident location in the three-dimensional virtual scene model comprises:

the map display window is used for displaying the peripheral three-dimensional map information, including the information of roads, buildings, fire hydrants, water sources, fire areas, water supply lines and vehicle parking positions;

a 3D visualization window for displaying the building interior structure at a first perspective;

the dangerous chemical physical and chemical property display window is used for displaying the storage condition of dangerous chemicals on an accident site and relevant information of the physical and chemical properties of the dangerous chemicals;

and the ignition point display window is used for displaying relevant information of the ignition equipment, including actual size, material, ignition degree and fire extinguishing difficulty.

3. The intelligent fire-fighting command system according to claim 2, further comprising a fire hazard detection module and a rescue plan management module;

the fire-fighting hidden danger inspection module is used for counting fire-fighting hidden danger information of different peripheral areas, including hidden danger sites, hidden danger content photos, contact ways of responsible persons in inspection areas, hidden danger grading and safety standard information, analyzing and predicting the severity of hidden dangers of each area through big data, and setting special inspection early warning time for the areas reaching a certain hidden danger degree;

the rescue plan management module is used for formulating an emergency rescue plan according to the hidden danger information of each region, performing fire-fighting simulation drilling on the region reaching a certain hidden danger degree, and making a dynamic drilling video comprising a fire-fighting driving route, fire-fighting vehicle and fire fighter deployment and fire-fighting tactical application, and the rescue plan management module triggers an emergency rescue plan display window and a dynamic drilling video display window through the alarm signal.

4. The intelligent fire-fighting command system according to claim 3, wherein the signal receiving module is further configured to receive monitoring video of an accident scene, and alarm video and voice information returned from the firefighter mobile terminal;

the alarm signal is also used for triggering a monitoring video display window and an alarm video display window.

5. The intelligent fire-fighting command system according to claim 4, further comprising a remote consultation module, wherein the intelligent fire-fighting command systems of different fire brigades are networked, and the remote consultation module is used for a plurality of fire-fighting unit experts to consult together to discuss and analyze an emergency treatment method.

6. The intelligent fire conductor system of claim 1, further comprising: the learning module is used for learning fire-fighting theory business;

the learning module includes 'fire-fighting rescuer' learning materials, 'building structure fireman' learning materials, 'registered fire-fighting engineer' learning materials, fire-fighting learning videos, fire-fighting equipment learning pictures and examination question banks of all learning subjects.

7. The intelligent fire conductor system of claim 1, further comprising a drill module and an assessment module;

the rehearsal module is used for inputting fire-fighting equipment and relevant fire-fighting parameters that fire brigade actually disposed, includes: tonnage of vehicle-mounted fire extinguishing agent, flow rate and lift of fire extinguishing equipment, cooling water consumption per unit area and fire extinguishing agent discharging time;

the assessment module is used for simulating an actual fire control process by combining the deployed fire-fighting vehicle positions and fire-fighting equipment and combining the field fixed fire-fighting equipment and the peripheral fixed fire-fighting equipment, judging whether fire extinguishment is successful or not based on the set fire-extinguishing logic relation through variable calculation of fire-extinguishing force and set fire-passing area, and scoring each assessment.

8. A method for performing fire drill by using an intelligent fire command system is characterized by comprising the following steps:

receiving an alarm signal from a fire control cabinet, and triggering a scene display window corresponding to an accident position in a three-dimensional virtual scene model through the alarm signal;

carrying out fire rescue deployment according to fire fighting resources actually configured by a local fire brigade, and carrying out cross-regional joint fire drill deployment by combining the fire fighting resources of peripheral fire brigades;

and sending the relevant information of the virtual scene of the accident scene and a fire command instruction to the firefighter mobile terminal so as to carry out actual fire deployment or cross-regional joint drilling.

9. The method of claim 8, further comprising, after receiving the alert signal:

triggering an emergency rescue plan display window and a dynamic drilling video display window through the alarm signal;

and receiving the monitoring video of the accident scene, and the alarm video and voice information returned from the firefighter mobile terminal.

10. The method of claim 8, wherein the deploying of fire rescue according to fire fighting resources actually configured by a local fire brigade and the deploying of cross-regional joint fire drill in combination with fire fighting resources of surrounding fire brigades comprise:

inputting fire fighting equipment and relevant fire fighting parameters actually configured by a local fire fighting unit and/or a peripheral fire fighting unit, wherein the fire fighting equipment and the relevant fire fighting parameters comprise: tonnage of vehicle-mounted fire extinguishing agent, flow rate and lift of fire extinguishing equipment, cooling water consumption per unit area and fire extinguishing agent discharging time;

the position and the fire-fighting equipment of the fire-fighting vehicle are deployed, the actual fire control process is simulated by combining the site fixed fire-fighting equipment and the peripheral fixed fire-fighting equipment, whether fire extinguishment is successful or not is judged based on the set fire-extinguishing logical relation through the variable calculation of the fire-extinguishing force and the set fire-passing area, and each check is scored.

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