Fire-fighting supervision platform with three screens in linkage and fire-fighting supervision method

By integrating building information models, 3D floor plans, and operational data through a three-screen interconnected fire monitoring platform, the problem of information fragmentation in traditional fire monitoring systems has been solved, enabling efficient information acquisition and rapid response.

CN122243706APending Publication Date: 2026-06-19SICHUAN FIRE RES INST OF MEM +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SICHUAN FIRE RES INST OF MEM
Filing Date
2026-03-19
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Traditional fire monitoring systems suffer from fragmented information, resulting in low regulatory efficiency and making it difficult to meet the needs of rapid response and precise handling in fire supervision.

Method used

The fire safety monitoring platform adopts a three-screen linkage, including a data acquisition module, a display module, and a linkage control module. It displays building information models, three-dimensional floor plans, and operational data through the linkage of the main display area, left display area, and right display area, so as to achieve a unified display of information.

Benefits of technology

It greatly improves information acquisition efficiency and situational awareness, simplifies operation procedures, and enhances rapid positioning and emergency response efficiency in complex buildings.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This application relates to the field of fire protection technology and provides a three-screen linkage fire protection monitoring platform and method. The fire protection monitoring platform includes: a data acquisition module for collecting operational data of the fire protection system of a target building; a display module including an independently displayed main display area, a left display area, and a right display area, wherein the main display area displays the overall building information model of the target building, the left display area displays the three-dimensional floor plan of the floors in the target building, and the right display area displays the operational data. The building information model and the three-dimensional floor plan include the layout information of the fire protection system; and a linkage control module, which, in response to a first trigger operation on the building information model in the main display area, controls the left display area to display the three-dimensional floor plan of the target floor corresponding to the first trigger operation, and controls the right display area to display the operational data of the target floor.
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Description

Technical Field

[0001] This application belongs to the field of fire protection technology, and particularly relates to a fire supervision platform with three-screen linkage and a fire supervision method. Background Art

[0002] In modern cities, high-rise and super high-rise buildings are increasing day by day. The fire protection system is the most extensive equipment system with the largest number of points in the building. The efficient and accurate operation of the fire protection system is a key and difficult problem urgently needed to be solved at the fire scene, and it is a prerequisite for ensuring the safe evacuation of personnel and the smooth development of fire fighting and rescue operations.

[0003] Traditional fire monitoring systems usually rely on two-dimensional floor plans or simple equipment lists, dispersing various types of information of the fire protection system in different monitoring interfaces. Monitoring personnel need to frequently switch between different screens or different software interfaces to obtain the overall layout of the building, the specific equipment distribution on a certain floor, and the real-time operation data of the equipment. This information fragmentation leads to low supervision efficiency and is difficult to meet the fire supervision requirements of rapid response and precise disposal. Summary of the Invention

[0004] The embodiments of this application provide a fire supervision platform with three-screen linkage and a fire supervision method, which can solve the technical problems in the related art that information fragmentation leads to low supervision efficiency and is difficult to meet the fire supervision requirements of rapid response and precise disposal.

[0005] In the first aspect of the embodiments of this application, a fire supervision platform with three-screen linkage is provided, including:

[0006] A data acquisition module for acquiring the operation data of the fire protection system of the target building;

[0007] A display module including a main display area, a left display area, and a right display area that are independently displayed. Among them, the main display area is used to display the building information model of the entire target building, the left display area is used to display the three-dimensional floor plan of the floors in the target building, and the right display area is used to display the operation data. The building information model and the three-dimensional floor plan include the layout information of the fire protection system;

[0008] A linkage control module, in response to a first trigger operation on the building information model in the main display area, controls the left display area to display the three-dimensional floor plan of the target floor corresponding to the first trigger operation, and controls the right display area to display the operation data of the target floor.

[0009] In the second aspect of the embodiments of this application, a fire supervision method is provided, which is applied to a fire supervision platform with three-screen linkage. The fire supervision platform with three-screen linkage includes a data acquisition module, a display module, and a linkage control module. The display module includes an independent main display area, a left display area, and a right display area. The fire supervision method includes:

[0010] The main display area displays the building information model of the target building, which includes the layout information of the fire protection system of the target building.

[0011] The left display area shows a 3D floor plan of the target building, which includes information on the layout of the fire protection system on each floor.

[0012] The right display area shows the operational data of the fire protection system in the target building collected by the data acquisition module.

[0013] In response to the user's first trigger operation on the building information model in the main display area, the system controls the left display area to display the 3D floor plan of the target floor corresponding to the first trigger operation, and controls the right display area to display the operating data of the target floor.

[0014] The fire monitoring platform and method with three-screen linkage provided in this application have the following beneficial effects: By displaying the overall building information model of the target building, the three-dimensional floor plan of the floors in the target building, and the operation data of the fire protection system of the target building in three independent and parallel display areas, these three fragmented dimensions of data can be integrated into a unified interface. Supervisors can obtain all the global, local and data information at once without switching screens or pages, which greatly improves the efficiency of information acquisition and situational awareness. In response to the first trigger operation on the main display area, the system can automatically associate the content of the left and right display areas with the target floor. This interaction logic can greatly simplify the operation steps, realize rapid positioning in complex buildings, and help improve the efficiency of routine inspections and emergency response. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this application, the drawings used in the description of the embodiments or related technologies will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0016] Figure 1 This application provides a three-screen linkage fire monitoring platform according to one embodiment;

[0017] Figure 2 This is a flowchart illustrating the implementation of a fire monitoring method provided in one embodiment of this application;

[0018] Figure 3 This is a schematic diagram of the main display area provided in an embodiment of this application;

[0019] Figure 4 This is a schematic diagram of a fire protection system overlay display provided in one embodiment of this application;

[0020] Figure 5 This is a schematic diagram of a fire protection system piping network provided in one embodiment of this application;

[0021] Figure 6 This is a schematic diagram of an automatic sprinkler fire extinguishing system provided in an embodiment of this application;

[0022] Figure 7 This is a schematic diagram illustrating the selection of parameter information after clicking to select a fire water tank, according to an embodiment of this application.

[0023] Figure 8 This is a three-dimensional plan view of the B1 floor of the target building provided in one embodiment of this application;

[0024] Figure 9 This is a schematic diagram of the right display area provided in an embodiment of this application;

[0025] Figure 10 This is a schematic diagram of the main display area provided in an embodiment of this application;

[0026] Figure 11 This is a schematic diagram of the left display area provided in an embodiment of this application;

[0027] Figure 12 This is a schematic diagram of the right display area provided in an embodiment of this application;

[0028] Figure 13 This is a flowchart illustrating the implementation of a fire monitoring method when the operating data includes alarm information corresponding to alarm devices, according to an embodiment of this application.

[0029] Figure 14 This is a flowchart illustrating the implementation of a fire monitoring method when operational data includes fire alarm signals, provided in one embodiment of this application.

[0030] Figure 15 This is a flowchart illustrating the implementation of a fire monitoring method provided in one embodiment of this application. Detailed Implementation

[0031] In the following description, specific details such as particular system architectures and techniques are set forth for illustrative purposes and not for limitation, in order to provide a thorough understanding of the embodiments of this application. However, those skilled in the art will understand that this application may also be implemented in other embodiments without these specific details. In other instances, detailed descriptions of well-known systems, apparatuses, circuits, and methods have been omitted so as not to obscure the description of this application with unnecessary detail.

[0032] It should be understood that, when used in this application specification and the appended claims, the term "comprising" indicates the presence of the described features, integrals, steps, operations, elements and / or components, but does not exclude the presence or addition of one or more other features, integrals, steps, operations, elements, components and / or a collection thereof.

[0033] As used in this application specification and the appended claims, the term "if" may be interpreted, depending on the context, as "when," "once," "in response to determination," or "in response to detection." Similarly, the phrase "if determined" or "if detected [the described condition or event]" may be interpreted, depending on the context, as meaning "once determined," "in response to determination," "once detected [the described condition or event]," or "in response to detection [the described condition or event]."

[0034] References to "one embodiment" or "some embodiments" as described in this specification mean that one or more embodiments of this application include a specific feature, structure, or characteristic described in connection with that embodiment. Therefore, the phrases "in one embodiment," "in some embodiments," "in other embodiments," "in still other embodiments," etc., appearing in different parts of this specification do not necessarily refer to the same embodiment, but rather mean "one or more, but not all, embodiments," unless otherwise specifically emphasized. The terms "comprising," "including," "having," and variations thereof mean "including but not limited to," unless otherwise specifically emphasized.

[0035] To illustrate the technical solution of this application, the following embodiments will be used for explanation.

[0036] Please see Figure 1 , Figure 1 This application provides a three-screen linkage fire monitoring platform, which includes a data acquisition module, a display module, and a linkage control module.

[0037] The data acquisition module is used to collect operational data of the target building's fire protection system. This module includes various sensors for detecting parameters of the fire protection system and the target building's environment, such as smoke sensors, temperature sensors, fire alarm sensors, pressure sensors, and wind speed sensors. The target building is equipped with a three-screen linked fire monitoring platform. The fire protection system includes fire compartments and evacuation routes, automatic sprinkler systems, fire hydrant systems, automatic fire alarm systems, smoke control and exhaust systems, evacuation guidance and lighting systems, etc. The operational data of the fire protection system includes the status and parameters of various types of fire detectors, pumps, fans, valves, and other equipment.

[0038] The display module comprises three independently displayed areas: a main display area, a left display area, and a right display area. These areas can be three interconnected displays or different areas within the same display screen. The main display area shows the Building Information Modeling (BIM) of the entire target building. BIM is a digital building model containing information about the actual building, describing its shape, dimensions, appearance, spatial structure, and various data and attributes attached to the model. BIM includes the layout information of the fire protection system throughout the target building. The left display area shows the 3D floor plans of the target building's floors, including the layout information of the fire protection system on each floor. The right display area shows operational data.

[0039] The linkage control module responds to a first trigger operation on the building information model in the main display area, controlling the left display area to display the 3D floor plan of the target floor corresponding to the first trigger operation, and controlling the right display area to display the operational data of the target floor. The linkage control module can be a logical control unit jointly implemented by one or more processors (such as a central processing unit (CPU), a graphics processing unit (GPU), etc.) and computer program instructions stored in memory. The first trigger operation includes clicking on a specific floor in the 3D building model; the linkage control module controls the left display area to switch to the floor plan of that floor and controls the right display area to switch to the comprehensive building data of that floor. In practice, the first trigger operation also includes clicking on a specific device in the main display area or the left display area; the platform also uses this to pop up a device information window, displaying the device's static information, dynamic status parameters, and historical trend data.

[0040] In practice, the linkage control module can also respond to trigger operations on the building information model in the left or right display area, controlling the main and right display areas, or controlling the main and left display areas to perform corresponding synchronous display operations. For example, the system simultaneously supports pipeline highlighting linkage. Double-clicking a pipeline in the main display area will highlight the corresponding pipeline. When the pipeline in the main display area is highlighted, the pipelines on the corresponding floors in the right and left display areas will be highlighted synchronously. Similarly, when a pipeline is highlighted in the left display area, the pipelines in the main and right display areas will be highlighted synchronously.

[0041] In this application, three independent and parallel display areas are used to display the overall building information model of the target building, the three-dimensional floor plan of the target building, and the operation data of the target building's fire protection system, respectively. These three previously fragmented dimensions of data can be integrated into a unified interface. Supervisory personnel can obtain all the global, local, and data information at once without switching screens or pages, greatly improving information acquisition efficiency and situational awareness. In response to the first trigger operation on the main display area, the system can automatically associate the content of the left and right display areas with the target floor. This interactive logic can greatly simplify the operation steps, enable rapid positioning in complex buildings, and help improve the efficiency of routine inspections and emergency response.

[0042] In some embodiments, when the operating data includes alarm information corresponding to the alarm device, the linkage control module performs the following alarm linkage operations: controls the floor area where the alarm device is located in the main display area to be highlighted and flashed; controls the left display area to switch to the three-dimensional plan view of the floor where the alarm device is located, and highlights and flashes the alarm device and the fire compartment where the alarm device is located; controls the right display area to display the alarm handling plan pop-up window corresponding to the alarm information.

[0043] Alarm information refers to information indicating an abnormality or alarm in a device within the fire protection system. Based on urgency, alarm information can be categorized into three types: equipment warning, equipment malfunction, and equipment action. Equipment warning indicates that the system has detected an abnormal state or that pre-set conditions have been met. This is typically an alarm signal from a detector or an anomaly detected by system logic, but a fire has not yet been confirmed or the equipment has not yet started. This serves as a reminder or early warning; for example, a smoke detector detecting smoke or a heat detector detecting a temperature rise and issuing a fire alarm signal, or a low water level in the fire water tank or an abnormal fire power supply. Equipment malfunction indicates a problem with a component, wiring, or function of the fire protection system itself, preventing the system from functioning properly when needed. This is an alarm indicating the system's internal health status; examples include equipment offline, signal loss, short circuit / open circuit, and equipment self-test failure. Equipment action refers to the confirmed activation or controlled execution of a device's designed function within the fire protection system; this is an execution feedback mechanism. For example, after a fire is confirmed, the control system automatically or manually starts the sprinkler pump; when the temperature at the fire scene reaches a threshold, the glass bulbs of the sprinkler heads burst and begin spraying water, and the water flow indicator sends a signal; upon receiving a fire alarm signal, the fireproof roller shutter begins to descend to the designated position; the control system starts the smoke exhaust fan, etc. Here, based on alarm information of different urgency levels, the three display areas can use different colors to highlight and flash. For example, equipment operation is highlighted and flashed in red, equipment malfunction is highlighted and flashed in yellow, and equipment warning is highlighted and flashed in blue.

[0044] The alarm handling plan pop-up window corresponding to the alarm information displays pre-set handling plan information. For example, if the smoke detector in room 1 malfunctions, the right display area can show the corresponding handling plan information: Step 1: Impact Assessment - Text Description: This fault causes the smoke detector in room 1 to malfunction, and the impact is limited to this room. Step 2: Handling Suggestions - Tip: Notify maintenance personnel to handle the situation. Generate a maintenance work order. Step 3: Temporary Measures - Tip: Before the fault is resolved, increase the frequency of video surveillance in this area.

[0045] Here, the main display area can also show a button to clear alarms, allowing supervisors to clear alarms after confirming that the system has made a false alarm.

[0046] In this embodiment, when an alarm message from the fire protection system is received, the main display area highlights and flashes to show the floor area where the alarm device is located. The display area also highlights and flashes to show the alarm device and its corresponding fire compartment. The right display screen shows a pop-up window of the alarm handling plan corresponding to the alarm message. This can achieve accurate visualization of alarm information and streamlined handling process, enabling proactive guidance and rapid response to alarm information.

[0047] In some embodiments, when the operating data includes a fire alarm signal, the linkage control module performs the following fire alarm operations: controls the main display area to highlight and flash the floor area where the fire alarm detector is located, displays the three-dimensional pipe network of the fire protection system's water system, and displays an alarm confirmation pop-up window; controls the left display area to switch to the three-dimensional plan view of the floor where the fire alarm detector is located, highlights and flashes the fire alarm detector and the fire compartment where the fire alarm detector is located, and displays the three-dimensional pipe network of the water system; controls the right display area to display an emergency response plan pop-up window corresponding to the fire alarm signal.

[0048] The emergency response plan pop-up window displays the emergency response plan information corresponding to the fire alarm signal. For example, if a fire alarm signal is detected in Room 1 on the 2nd floor, the main display area will highlight and flash Room 1 on the 2nd floor of the target building and the 3D water system network. The left display area will automatically switch to displaying the 3D floor plan of the 2nd floor, highlighting and flashing the fire alarm detector and the fire compartment where the fire alarm detector is located. The right display area will display the corresponding emergency response plan information: Step 1: Confirm Alarm - Text prompt: "Please confirm the alarm area through video surveillance or on-site personnel." Step 2: Preliminary Measures - Prompt: "If it is confirmed to be a false alarm, click the 'Extinguish Alarm' button. If it is a real fire, click 'Activate Emergency Response Plan'." Step 3: Joint Preparation - Prompt: "Preparing to activate emergency broadcasting, smoke extraction system, etc."

[0049] In this embodiment, when a fire alarm signal from the fire protection system is received, the main display area highlights and flashes the floor where the corresponding fire alarm detector is located, and displays the three-dimensional water system network and alarm confirmation pop-up of the fire protection system. The left display area automatically switches to the three-dimensional plan of the floor where the fire alarm detector is located and the three-dimensional water system network, and highlights and flashes the fire alarm detector and the fire compartment where the fire alarm detector is located. The right display area displays the emergency response plan pop-up corresponding to the fire alarm signal. This can further enhance the overall situational awareness and resource visualization management of fire emergency, enabling supervisors to intuitively grasp the distribution of key fire-fighting resources, providing spatial information support for subsequent command and decision-making, and helping to improve the scientificity and accuracy of emergency decision-making.

[0050] In some embodiments, when the operating data includes a sprinkler system start signal, the linkage control module performs the following sprinkler display operations: controls the main display area to highlight the sprinkler equipment started in the sprinkler system and the water flow path; controls the left display area to display the sprinkler status of the sprinkler equipment in the first preset area corresponding to the fire alarm detector.

[0051] In this embodiment, when the sprinkler system is started, the system highlights the started equipment and water flow path on the main screen and left screen, so that the supervisor can confirm in real time whether the fire extinguishing system is working as expected and whether the water flow has reached the predetermined area, which helps to enhance the reliability of the system and realize dynamic visual feedback of the system's operating status.

[0052] In some embodiments, the alarm linkage operation or fire alarm operation further includes: controlling the main display area to display a camera call button, the camera call button being able to call a camera in a second preset area of ​​the alarm device or fire alarm detector in response to a click operation, wherein the fire protection system includes a camera.

[0053] In this embodiment, by calling the camera near the alarm device or fire alarm detector, the supervisor can directly and remotely confirm the actual situation on site, avoid false alarms, and help improve the accuracy and reliability of the system.

[0054] In some embodiments, in response to a water test command for the fire protection system's test device in the main display area, the linkage control module performs the following end-point test operations: controls the main display area to display the fire protection system's sprinkler system piping network and the sprinkler system process flow diagram; controls the left display area to switch to a three-dimensional plan view of the floor where the test device is located and displays the sprinkler system piping network of that floor; controls the right display area to display a test control form, which is used to control the test process and display the test status.

[0055] During the water test, the main display area and the left display area dynamically highlight the water flow path in the water test device and the sprinkler system network.

[0056] In this embodiment, the water flow path is dynamically highlighted by the display module, allowing supervisors to intuitively understand the testing status of the entire pipeline network and verify the fire protection system. Meanwhile, the test control form in the right display area ensures the standardization of the testing process and the integrity of data recording, which helps to improve the quality and efficiency of the testing work.

[0057] Please see Figure 2 , Figure 2 This is a flowchart of the implementation of a fire monitoring method provided in an embodiment of this application. The fire monitoring method is applied to a three-screen linkage fire monitoring platform. The three-screen linkage fire monitoring platform includes a data acquisition module, a display module, and a linkage control module. The display module includes an independent main display area, a left display area, and a right display area. The flowchart may include the following steps 101 to 104.

[0058] Step 101: Display the building information model of the target building in the main display area.

[0059] The Building Information Model (BIM) is a pre-built information model of the target building, including the layout information of the target building's fire protection system. This layout information indicates the location of each piece of equipment and the routing of pipes within the fire protection system, such as the location of water pumps and the routing of water pipes.

[0060] In this embodiment, the executing entity of the aforementioned fire monitoring method is typically a server. It should be noted that the server can be hardware or software. When the server is hardware, it can be implemented as a distributed server cluster consisting of multiple servers, or as a single server. When the server is software, it can be implemented as multiple software programs or software modules, or as a single software program or software module; no specific limitation is made here. Specifically, the executing entity can be a linkage control module.

[0061] In practice, the implementing entity can send corresponding display commands to the main display area to control the display of the overall building BIM drawing, such as... Figure 3 As shown, Figure 3 This is a schematic diagram of the main display area provided in an embodiment of this application. In the default state, the building is displayed as a solid entity. A system button is provided in the main display area; when selected, the building is displayed in a semi-transparent state, and the automatic sprinkler system, fire hydrant system, and smoke control system within the fire protection system are displayed overlaid, as shown below. Figure 4 As shown. A piping network button is located in the main display area. When selected, the building model will be hidden, and the main display area will overlay the automatic sprinkler system, fire hydrant system, and smoke control system, as shown. Figure 5As shown. In network mode, supervisors can click on any of the three systems to display them individually. For example, selecting the automatic sprinkler system will display it, while the other two systems will be hidden. Figure 6 As shown.

[0062] Here, both the automatic sprinkler system and the fire hydrant system contain corresponding equipment. Double-clicking on the equipment will display a pop-up window with information about it, typically including: basic information, parameter information, trend charts, and historical events. For example, selecting a fire water tank will display its basic information (including equipment name, equipment code, and equipment location), parameter information (including effective liquid level, connectivity status, water level status, real-time water volume, standard water volume, and percentage), trend charts (including real-time water volume and effective liquid level for the past 24 hours), historical events, and water level status for the past 24 hours. Hovering the mouse over the line graph in the pop-up window allows you to query specific equipment information such as water volume and water level status at the current statistical time point. Figure 7 As shown, Figure 7 This is a schematic diagram illustrating the selection of parameter information after clicking to select a fire water tank, according to an embodiment of this application.

[0063] In practical applications, the system allows users to perform basic operations such as moving, rotating, and zooming in the main display area using the mouse. Specifically, right-clicking and moving the mouse moves the building model; right-clicking and moving the mouse rotates the building model and adjusts the viewing angle; scrolling the mouse wheel zooms in / out on the building model; and clicking the middle mouse button returns the model to the optimal viewing position.

[0064] Step 102: Display a 3D floor plan of the target building's floors in the left display area.

[0065] The 3D floor plan includes information on the layout of the fire protection system on each floor.

[0066] In practice, supervisors can select the floor to be displayed in the left display area from the main display area, or directly select and switch the floor to be displayed in the left display area. The aforementioned execution entity can respond to the supervisor's operation by sending corresponding display commands to the left display area, controlling the left display area to display the three-dimensional floor plan of the corresponding floor.

[0067] like Figure 8 As shown, Figure 8 This is a three-dimensional plan view of the B1 floor of the target building provided in one embodiment of this application.

[0068] Step 103: Display the operation data of the fire protection system in the target building collected by the data acquisition module in the right display area.

[0069] The right display area shows BI data for each floor of the target building. Supervisors can select the floors to be displayed in the right display area from the main display area, or directly select the floors to be displayed in the right display area. The BI data displayed in the right display area can include alarms from the fire protection system over the past 30 days (e.g., alarms from the fire water system, smoke control system, etc.), the fire safety index for the past 30 days, fire pump status, and fire water tank flow trends. For example, such as... Figure 9 As shown, Figure 9 This is a schematic diagram of the right display area provided in an embodiment of this application.

[0070] Step 104: In response to the user's first trigger operation on the building information model in the main display area, control the left display area to display the three-dimensional floor plan of the target floor corresponding to the first trigger operation, and control the right display area to display the operation data of the target floor.

[0071] The first trigger operation involves clicking on a specific floor in the 3D building model. The linked control module then switches the left display area to the floor plan of that floor and the right display area to the comprehensive building data for that floor. For example, selecting the -1F model in the main display area (e.g., ...) Figure 10 As shown), the left display area automatically switches to displaying the 3D plan view of -1F (as shown). Figure 11 As shown), the right display area automatically switches to display the running data of -1F (such as...). Figure 12 (As shown).

[0072] In practice, the first trigger operation also includes clicking on a specific device in the main display area or the left display area. The platform is also used to pop up a device information window to display the device's static information, dynamic status parameters and historical trend data.

[0073] In practice, the system also supports synchronized highlighting of pipes. Double-clicking to select a pipe network in the main display area will highlight the corresponding network. When a pipe network is highlighted in the main display area, the pipe networks on the corresponding floors in the left display area will also be highlighted synchronously. Furthermore, when a pipe network is highlighted in the left display area, the pipe network in the main display area will be highlighted synchronously. The right display area synchronously displays the operating data of the pipe network.

[0074] In this application, three independent and parallel display areas are used to display the overall building information model of the target building, the three-dimensional floor plan of the target building, and the operation data of the target building's fire protection system, respectively. These three previously fragmented dimensions of data can be integrated into a unified interface. Supervisory personnel can obtain all the global, local, and data information at once without switching screens or pages, greatly improving information acquisition efficiency and situational awareness. In response to the first trigger operation on the main display area, the system can automatically associate the content of the left and right display areas with the target floor. This interactive logic can greatly simplify the operation steps, enable rapid positioning in complex buildings, and help improve the efficiency of routine inspections and emergency response.

[0075] Please see Figure 13 , Figure 13 This is a flowchart of the implementation of a fire monitoring method when the operating data includes alarm information corresponding to the alarm device, according to an embodiment of this application. The flowchart may include the following steps 201 to 203.

[0076] Step 201: Control the floor area where the alarm device is located in the main display area to be highlighted and flashed.

[0077] Among them, alarm devices are those that trigger alarms in the fire protection system, as collected by the data acquisition module. For example, a smoke detector may detect smoke, a heat detector may detect an increase in temperature and issue a fire alarm signal, or the fire water tank level may be too low, or the fire power supply may be abnormal.

[0078] When the aforementioned execution entity receives the alarm information from the alarm device, it can locate the alarm device using the location information in the alarm information, and then send a display command to the main display area to control the floor area where the alarm device is located to be highlighted and flashed in the main display area.

[0079] Step 202: Control the left display area to switch to the three-dimensional floor plan of the floor where the alarm device is located, and highlight and flash the alarm device and the fire compartment where the alarm device is located.

[0080] Correspondingly, the aforementioned executing entity can simultaneously send display commands to the left display area, controlling the left display area to switch to displaying a three-dimensional floor plan of the floor where the alarm device is located, while simultaneously highlighting and flashing the corresponding fire compartment.

[0081] Step 203: Control the right display area to display the pop-up window of the processing plan information corresponding to the alarm information.

[0082] Among them, the processing plan information is the pre-set step information for processing alarm information.

[0083] In practice, different processing plans are pre-set for different types of alarm information. After receiving an alarm, the aforementioned execution entity can find the processing plan information corresponding to the current alarm information in the pre-stored processing plan information based on the alarm information, and then send a display command to the right display area to control the right display area to display a pop-up window of the processing plan information for the supervisor to view.

[0084] In this embodiment, when an alarm message from the fire protection system is received, the main display area highlights and flashes to show the floor area where the alarm device is located. The display area also highlights and flashes to show the alarm device and its corresponding fire compartment. The right display screen shows a pop-up window of the alarm handling plan corresponding to the alarm message. This can achieve accurate visualization of alarm information and streamlined handling process, enabling proactive guidance and rapid response to alarm information.

[0085] Please see Figure 14 , Figure 14 This is a flowchart of the implementation of a fire monitoring method when the operating data includes a fire alarm signal, provided in an embodiment of this application. The flowchart may include the following steps 301 to 303.

[0086] Step 301: Control the floor area where the fire alarm detector is located in the main display area to be highlighted and flashed, display the three-dimensional pipe network of the fire protection system's water system, and display the alarm confirmation pop-up window.

[0087] In practice, fire alarm signals are usually generated by fire alarm detectors. After receiving a fire alarm signal, the aforementioned execution entity can confirm the location of the corresponding fire alarm detector in the target building through the location information in the fire alarm signal. Then, based on the location, it sends a display command to the main display area to control the floor area where the fire alarm detector is located to be highlighted and flashed in the main display area. At the same time, it displays the three-dimensional pipe network of the fire protection system's water system and displays an alarm confirmation pop-up window.

[0088] Step 302: Control the left display area to switch to the three-dimensional plan view of the floor where the fire alarm detector is located, highlight and flash the fire alarm detector and the fire compartment where the fire alarm detector is located, and display the three-dimensional water system network.

[0089] Correspondingly, the aforementioned executing entity can simultaneously send display commands to the left display area, controlling the left display area to switch to the three-dimensional plan view of the floor where the fire alarm detector is located, highlighting and flashing the fire alarm detector and the fire compartment where the fire alarm detector is located, as well as displaying the three-dimensional pipe network of the water system.

[0090] Step 303: Control the right display area to display the emergency response plan information pop-up window corresponding to the fire alarm signal.

[0091] Among them, the emergency response plan information is the pre-set procedure information for handling fire alarm signals.

[0092] In practice, different emergency response plans are pre-set for different types of fire alarm signals. After receiving a fire alarm signal, the aforementioned implementing entity can find the emergency response plan information corresponding to the current fire alarm signal in the pre-stored emergency response plan information based on the fire alarm signal, and then send a display command to the right display area to control the right display area to display a pop-up window of the emergency response plan information for supervisory personnel to view.

[0093] In this embodiment, when a fire alarm signal from the fire protection system is received, the main display area highlights and flashes the floor where the corresponding fire alarm detector is located, and displays the three-dimensional water system network and alarm confirmation pop-up of the fire protection system. The left display area automatically switches to the three-dimensional plan of the floor where the fire alarm detector is located and the three-dimensional water system network, and highlights and flashes the fire alarm detector and the fire compartment where the fire alarm detector is located. The right display area displays the emergency response plan pop-up corresponding to the fire alarm signal. This can further enhance the overall situational awareness and resource visualization management of fire emergency, enabling supervisors to intuitively grasp the distribution of key fire-fighting resources, providing spatial information support for subsequent command and decision-making, and helping to improve the scientificity and accuracy of emergency decision-making.

[0094] Please see Figure 15 , Figure 15 This is a flowchart of the implementation of a fire monitoring method provided in an embodiment of this application. The flowchart may include the following steps 401 to 403.

[0095] Step 401: In response to the test water command for the test water device of the fire protection system in the main display area, control the main display area to display the sprinkler system piping network of the fire protection system and the process flow diagram of the sprinkler system.

[0096] The test water instruction includes the location information of the test water device to be tested. Supervisory personnel can select the terminal device to be tested in the main display area. The aforementioned execution entity can send a display instruction to the main display area through the location information in the test water instruction, and control the main display area to display the sprinkler system pipeline of the fire protection system, as well as the sprinkler system process flow diagram.

[0097] Step 402: Control the left display area to switch to the three-dimensional plan view of the floor where the test water device is located, and display the sprinkler system network of that floor.

[0098] Correspondingly, the aforementioned executing entity can simultaneously send corresponding display commands to the left display area to control the left display area to switch to the three-dimensional plan view of the floor where the test water device is located, and to display the sprinkler system network of that floor.

[0099] Step 403: Control the right display area to display the water test control form. The water test control form is used to control the water test process and display the water test status.

[0100] During the water test, the main display area and the left display area dynamically highlight the water flow path in the water test device and the sprinkler system network.

[0101] In this embodiment, the water flow path is dynamically highlighted by the display module, allowing supervisors to intuitively understand the testing status of the entire pipeline network and verify the fire protection system. Meanwhile, the test control form in the right display area ensures the standardization of the testing process and the integrity of data recording, which helps to improve the quality and efficiency of the testing work.

[0102] In the above embodiments, the descriptions of each embodiment have different focuses. For parts that are not described in detail or recorded in a certain embodiment, please refer to the relevant descriptions of other embodiments.

[0103] The above embodiments are only used to illustrate the technical solutions of this application, and are not intended to limit them. Although this application has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this application, and should all be included within the protection scope of this application.

Claims

1. A fire safety monitoring platform with three interconnected screens, characterized in that, include: The data acquisition module is used to collect operational data of the fire protection system of the target building; The display module includes an independently displayed main display area, a left display area, and a right display area. The main display area is used to display the overall building information model of the target building. The left display area is used to display the three-dimensional floor plan of the floors in the target building. The right display area is used to display the operating data. The building information model and the three-dimensional floor plan include the layout information of the fire protection system. The linkage control module, in response to a first trigger operation on the building information model in the main display area, controls the left display area to display a three-dimensional plan view of the target floor corresponding to the first trigger operation, and controls the right display area to display the operating data of the target floor.

2. The fire monitoring platform with three screens linked according to claim 1, characterized in that, When the operating data includes alarm information corresponding to the alarm device, the linkage control module performs the following alarm linkage operation: Control the main display area to highlight and flash the floor area where the alarm device is located; Control the left display area to switch to a three-dimensional floor plan of the floor where the alarm device is located, and highlight and flash the alarm device and the fire compartment where the alarm device is located; Control the right display area to display the alarm handling plan pop-up window corresponding to the alarm information.

3. The fire monitoring platform with three screens linked according to claim 1, characterized in that, When the operating data includes a fire alarm signal, the linkage control module performs the following fire alarm operation: The system controls the flashing of the floor area where the fire alarm detector is located in the main display area, displays the three-dimensional pipe network of the water system of the fire protection system, and displays the alarm confirmation pop-up window; The left display area is controlled to switch to a three-dimensional plan view of the floor where the fire alarm detector is located, and the fire alarm detector and the fire compartment where the fire alarm detector is located are highlighted and flashed, as well as the three-dimensional pipe network of the water system is displayed; The right display area is controlled to display an emergency response plan pop-up window corresponding to the fire alarm signal.

4. The fire monitoring platform with three screens linked according to claim 3, characterized in that, When the operating data includes a sprinkler system start signal, the linkage control module performs the following sprinkler display operation: The main display area is controlled to highlight the spraying equipment activated in the spraying system and the water flow path; The left display area is controlled to display the spraying status of the sprinkler system within the first preset area corresponding to the fire alarm detector.

5. The fire monitoring platform with three screens linked according to claim 2 or 3, characterized in that, The alarm linkage operation or the fire alarm operation also includes: The main display area is controlled to display a camera call button. The camera call button can be clicked to call a camera in a second preset area of ​​the alarm device or the fire alarm detector. The fire protection system includes the camera.

6. The fire monitoring platform with three screens linked according to claim 1, characterized in that, In response to a test command for the fire protection system's test device in the main display area, the linkage control module performs the following end-point test operation: The main display area is controlled to display the sprinkler system piping network of the fire protection system, as well as the process flow diagram of the sprinkler system; Control the left display area to switch to a three-dimensional plan view of the floor where the test water device is located, and display the sprinkler system network of that floor; The right display area is controlled to display the water test control form, which is used to control the water test process and display the water test status. During the water test, the main display area and the left display area dynamically highlight the water test device and the water flow path in the spray system network.

7. A fire monitoring method applied to a three-screen linked fire monitoring platform, wherein the three-screen linked fire monitoring platform includes a data acquisition module, a display module, and a linkage control module, wherein the display module includes an independent main display area, a left display area, and a right display area, characterized in that, The fire safety supervision methods include: The main display area displays a building information model of the target building, wherein the building information model includes the layout information of the fire protection system of the target building; The left display area displays a three-dimensional floor plan of the target building, wherein the three-dimensional floor plan includes information on the layout of the fire protection system on the floor; The right display area displays the operational data of the fire protection system in the target building collected by the data acquisition module; In response to a user's first trigger operation on the building information model in the main display area, the left display area is controlled to display a three-dimensional floor plan of the target floor corresponding to the first trigger operation, and the right display area is controlled to display the operating data of the target floor.

8. The fire safety supervision method according to claim 7, characterized in that, When the operating data includes alarm information corresponding to the alarm device, the method further includes: Control the main display area to highlight and flash the floor area where the alarm device is located; Control the left display area to switch to a three-dimensional floor plan of the floor where the alarm device is located, and highlight and flash the alarm device and the fire compartment where the alarm device is located; Control the right display area to display a pop-up window showing the processing plan information corresponding to the alarm information.

9. The fire safety supervision method according to claim 7, characterized in that, When the operational data includes fire alarm signals, the method further includes: The system controls the flashing of the floor area where the fire alarm detector is located in the main display area, displays the three-dimensional pipe network of the water system of the fire protection system, and displays the alarm confirmation pop-up window; The left display area is controlled to switch to a three-dimensional plan view of the floor where the fire alarm detector is located, and the fire alarm detector and the fire compartment where the fire alarm detector is located are highlighted and flashed, as well as the three-dimensional pipe network of the water system is displayed; The right display area is controlled to display a pop-up window containing emergency response plan information corresponding to the fire alarm signal.

10. The fire safety supervision method according to claim 7, characterized in that, The method further includes: In response to a test water command for the test water device of the fire protection system in the main display area, the main display area is controlled to display the sprinkler system piping network of the fire protection system and the process flow diagram of the sprinkler system; Control the left display area to switch to a three-dimensional plan view of the floor where the test water device is located, and display the sprinkler system network of that floor; The right display area is controlled to display the water test control form, which is used to control the water test process and display the water test status. During the water test, the main display area and the left display area dynamically highlight the water test device and the water flow path in the spray system network.