CN110929985A

CN110929985A - Hierarchical fire fighting management method and system

Info

Publication number: CN110929985A
Application number: CN201911021417.5A
Authority: CN
Inventors: 张志琨
Original assignee: Zhuhai Zhi Cheng Information Technology Co Ltd
Current assignee: Zhuhai Zhi Cheng Information Technology Co Ltd
Priority date: 2019-10-25
Filing date: 2019-10-25
Publication date: 2020-03-27

Abstract

The invention relates to the field of computer application, and discloses a hierarchical fire-fighting management method and a hierarchical fire-fighting management system, wherein the method comprises the following steps: the polling terminal receives polling tasks formulated by the sub-server, checks the fire-fighting nodes according to polling rules formulated by the main server, and collects polling results; the monitoring terminal monitors the state of the fire-fighting system of the Internet of things and determines the alarm type; the sub-service terminal manages fire-fighting affairs, processes the patrol task and feeds back fire-fighting hidden danger information to the service terminal in the monitoring process; the monitoring terminal monitors the fire-fighting affairs of the subordinate level and processes the fire-fighting hidden danger which is not processed in an overdue period; and the main service terminal consults and counts all fire-fighting works at subordinate levels of the jurisdiction, formulates patrol rules and manages information of fire-fighting personnel in the jurisdiction. The invention has the beneficial effects that: the fire-fighting working data are managed in a unified mode, data intercommunication of all levels of fire-fighting units is achieved, the authority of all levels of units is clear, fire-fighting related data are recorded on a case, and the implementation of fire-fighting work is further guaranteed.

Description

Hierarchical fire fighting management method and system

Technical Field

The invention relates to the field of computer application, in particular to a hierarchical fire fighting management method and system.

Background

With the rapid development of urbanization and the improvement of awareness of safety aspects such as fire prevention, fire fighting facilities are installed in almost all large-scale places. Although the fire-fighting facilities are idle for a long time at ordinary times, the life and property safety of people is guaranteed, and therefore, it is very important to manage the fire-fighting facilities and guarantee the safe and effective operation of the fire-fighting facilities.

In the current fire-fighting work, the problems that the management is relatively dispersed, and the fire-fighting manager is difficult to know the specific progress condition of the fire-fighting work in the district are solved.

Disclosure of Invention

The invention aims to solve at least one of the technical problems in the prior art, and provides a hierarchical fire protection management method and a hierarchical fire protection management system, which can uniformly manage fire protection working data, realize data intercommunication of all levels of fire protection units and ensure safe and effective operation of fire protection facilities.

According to a first aspect of the present invention, a hierarchical fire protection management method is provided, which is characterized by comprising the following steps: s1, the inspection terminal inspects the fire-fighting nodes one by one according to the inspection tasks formulated by the sub-server and the inspection rules formulated by the main server, collects the inspection results of the fire-fighting nodes and feeds the inspection results back to the sub-server; s2, the monitoring terminal monitors the state of the Internet of things fire fighting system, receives alarm information of the Internet of things fire fighting equipment, determines an alarm type according to feedback data and/or field inspection of the Internet of things fire fighting system, and feeds an alarm result back to the sub-server; s3, the sub server manages fire-fighting affairs, including: processing the fire-fighting hidden danger information fed back to the server in the polling task and monitoring process; s4, the monitoring terminal monitors fire-fighting affairs of a plurality of subordinate sub-servers and processes the fire-fighting hidden danger which is not processed in an overdue period; and S5, the main server consults and counts the fire-fighting affairs of the subordinate sub-servers according to the classification, and manages the information of the subordinate fire fighters. According to the method, each level of firefighters are clearly assigned to work and each firefighter plays its role, so that the orderly fire fighting work is guaranteed; the two dimensions of routing inspection and monitoring ensure the normal operation of fire-fighting equipment, and are convenient for overall management of fire-fighting hidden dangers and timely maintenance of fault equipment; unified management of fire control data realizes data intercommunication.

The hierarchical fire protection management method according to the first aspect of the present invention is characterized in that the inspection result of the fire protection node includes: node number, node position, node type, inspector, inspection start-stop time and node related information; the node-related information includes a node status. The entry of the information is beneficial to knowing the working condition of the inspector and the state of the relevant fire-fighting node.

Preferably, the fire protection node is configured to: if the fire-fighting node fails, the node state information further includes: node failure cause, problem description and site picture; further, if the hidden danger of the fire-fighting node can be rectified and corrected on the spot, the node state information also comprises a rectification and correction processing description and a processed on-site picture. The on-site solution that the inspector can solve by itself and the report that can not be solved are handled by the primary administrator, so that the on-site treatment can be conveniently carried out according to the difficulty degree of the fault, and the checking and counting of the follow-up hidden trouble problems are convenient.

The hierarchical fire protection management method according to the first aspect of the invention is characterized in that the alarm result includes alarm information and an alarm type of the internet of things fire protection system; wherein the alarm information of the fire fighting system of the internet of things comprises: the method comprises the following steps of (1) the position of an Internet of things fire fighting system, initial alarm time, latest alarm time, alarm times and alarm types; the alarm types comprise real alarm conditions, false alarm conditions and equipment faults. The archiving of the information is beneficial to knowing the working condition of the monitor and the state of the fire fighting system of the Internet of things.

Preferably, the alert type is configured to: if the alarm type is equipment failure, the alarm result also comprises a processing description and a field photo of the alarm equipment; further, if the alarm type is equipment failure and the alarm can be resolved on site, the alarm result further includes a rectification processing description and a processed site picture. The monitor can solve the problem of on-site solution and report the problem of failure, and the problem is handled by a primary administrator, so that the failed Internet of things fire-fighting system can be conveniently and timely handled, and the follow-up hidden danger problem can be conveniently checked, counted and analyzed.

The hierarchical fire protection management method according to the first aspect of the invention is characterized in that the method for processing the fire protection hidden danger information fed back to the server side in the polling task and monitoring process comprises the following steps: sending the information of the hidden fire danger to be maintained to an engineering department of the unit or a corresponding maintenance unit; and checking and accepting the repaired fire-fighting hidden danger information. The primary administrator further handles hidden dangers that the bottom patrol personnel and the monitor can not handle, assigns the hidden dangers to professionals for handling, and timely checks, accepts and files the maintained facilities, thereby facilitating the expansion of follow-up work.

The hierarchical fire protection management method according to the first aspect of the present invention is characterized in that the method for the supervisor to handle the fire hazard of the overdue and unprocessed fire hazard specifically comprises: and reminding the subordinate units to undertake liability according to the time length of expiration, carrying out negotiation or direct home inspection on the subordinate units, and recording related processing contents. The supervisor adopts different monitoring means according to the delay condition of the fire-fighting hidden danger, and the longer the delay is, the more severe the delay is; the record on the case makes follow-up data available for inspection, and facilitates the superior to know the responsibility condition of the supervisor.

The hierarchical fire protection management method according to the first aspect of the present invention, further, the managing fire-fighting affairs by the primary administrator through the management module further includes: recording monthly fire-prevention inspection, safety education training, fire-fighting rescue drilling and fire-fighting related data; the fire-fighting related data comprises fire-fighting key parts, dangerous goods information, fire-fighting facilities and building information. The risk and the hazard of the fire-fighting hidden danger are further reduced by training education and recording important fire-fighting data on the case.

According to a second aspect of the present invention, there is provided a hierarchical fire management system, comprising: the upper management platform is used for consulting all fire-fighting working conditions of lower levels of the jurisdiction according to classification, formulating a uniform patrol rule and managing information of fire fighters in the jurisdiction; the middle-level monitoring platform is used for monitoring the fire-fighting working condition of the subordinate level and monitoring and reminding the problem of hidden danger which is not processed in the overdue period; the basic level management subsystem is used for managing specific fire-fighting affairs of the basic level and fire-fighting data generated in the fire-fighting affairs; and the data storage module is used for storing related data information in the superior management platform, the intermediate supervision platform and the basic level management subsystem. The invention has the beneficial effects that: fire-fighting related data are recorded on a case and can be found according to the records, each level of work is clearly divided, and the implementation of fire-fighting work is ensured according to the level; the superior manager can know the working general of each level of unit in the district in time, so as to guide the direction of the next fire-fighting work, unify the inspection standard and facilitate judging the working condition of each unit to avoid disorder; solving the problem of difficulty by intermediate supervision; the lower level implements the daily work of fire fighting.

The hierarchical fire management system according to the second aspect of the present invention is characterized in that the primary management subsystem includes: the system comprises an inspection module, a data processing module and a data processing module, wherein the inspection module is used for receiving a formulated inspection task, inspecting corresponding fire-fighting nodes in the inspection task and collecting inspection results of the fire-fighting nodes; the monitoring module is used for monitoring the fire fighting system of the Internet of things and collecting related data and alarm information of the fire fighting system of the Internet of things; and the management module is used for managing fire-fighting affairs and processing the fire-fighting hidden dangers discovered by the inspection module and the monitoring module. The safe and effective operation of the fire-fighting equipment is ensured from two dimensions of routing inspection and monitoring, the routing inspection supplements and covers the fire-fighting equipment which cannot be carried out through the Internet of things, and the remote monitoring can better save manpower and material resources; the separation of the modules is beneficial to the separation of the authority, and false operation and failure of food retention can be prevented in actual work; overall management fire control information, the data integration of being convenient for is gone on controlling fire control work on the whole, in time solves the fire control hidden danger problem.

Drawings

The invention is further described below with reference to the accompanying drawings and examples;

FIG. 1 illustrates the main method steps of an embodiment of the present invention;

FIG. 2 is a flow chart of the operation of patrolling a fire node in an embodiment of the present invention;

FIG. 3 is a flow chart of a monitoring operation in an embodiment of the present invention;

FIG. 4 is a flowchart of managing hidden dangers in an embodiment of the present invention;

FIG. 5 is a schematic block diagram of a system in accordance with an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to the present preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as the upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, the meaning of a plurality of means is one or more, the meaning of a plurality of means is two or more, and larger, smaller, larger, etc. are understood as excluding the number, and larger, smaller, inner, etc. are understood as including the number. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present invention, unless otherwise explicitly limited, terms such as arrangement, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention in combination with the specific contents of the technical solutions.

Referring to fig. 1, the main steps of the embodiment of the present invention are as follows. The polling terminal checks the fire-fighting nodes one by one according to polling rules formulated by the main server and polling tasks formulated by the sub-servers, collects polling results of the fire-fighting nodes and feeds the polling results back to the sub-servers; the monitoring terminal monitors the state of the fire fighting system of the Internet of things, receives alarm information of the fire fighting equipment of the Internet of things, determines an alarm type according to feedback data and/or field inspection of the fire fighting system of the Internet of things, and feeds an alarm result back to the sub-server; the sub-server manages fire-fighting affairs, including routing inspection task processing and fire-fighting hidden danger information fed back to the server in the monitoring process; the monitoring terminal monitors fire-fighting affairs of a plurality of sub-servers under the jurisdiction and processes the fire-fighting hidden danger which is not processed in an overdue period; and the main server consults and counts fire-fighting affairs of the subdominant sub-servers according to classification, and manages information of subdominant fire fighters. In the embodiment, an upper-layer administrator (such as a fire branch level administrator) learns the fire-fighting work development condition of the district through a general service terminal, makes a uniform routing inspection rule and manages fire-fighting personnel in the district; the supervisor supervises the fire-fighting work of the fire-fighting unit within the authority range through the supervision terminal; the administrator of the basic fire-fighting unit manages the fire-fighting affairs of the unit through the sub-server; the polling personnel carry out polling work through the polling terminal; and a monitor monitors the Internet of things fire-fighting system through the monitoring terminal. It can be understood that one total service end corresponds to a plurality of monitoring terminals, each monitoring terminal corresponds to a plurality of sub-service ends, and each sub-service end corresponds to a plurality of inspection terminals and a plurality of monitoring terminals; the fire-fighting transaction data of a certain sub-server can not be accessed by other sub-servers, but can be accessed by the corresponding supervision terminal and the total server. Each level unit and fire fighters have clear division of labor, and the implementation of fire fighting work is ensured according to the level; the establishment of the unified inspection rule is beneficial to monitoring inspection work in the district and evaluating the quality of the inspection work, and the establishment of a specific inspection task by a basic fire-fighting unit is beneficial to the actual treatment of fire inspection; the safe and effective operation of the fire fighting equipment is ensured from two dimensions of inspection and supervision.

In one embodiment of the invention, an inspector acquires an inspection task in a data storage module by using an inspection terminal, inspects a corresponding fire-fighting node in the inspection task and submits an inspection result; the patrol inspector can check the patrol task progress of the inspector, check the patrol result submitted by the inspector and track the fire-fighting hidden danger processing progress submitted by the inspector through the patrol terminal. A monitor monitors the fire-fighting system of the internet of things through a monitoring terminal by using a computer or mobile equipment, processes alarm information of the fire-fighting system of the internet of things, judges whether an alarm is a real dangerous case, a false alarm of equipment or an equipment fault according to real-time data or on-site check of the fire-fighting system of the internet of things, and processes the alarm information; the monitor can also check the alarm result submitted by the monitor and track the fire-fighting hidden danger processing progress submitted by the monitor. The primary administrator manages the fire-fighting affairs through the management module, and the method comprises the following steps: reading hidden danger information in the inspection result and the alarm result from the data storage module and carrying out corresponding processing; tracking the processing progress of the fire-fighting hidden danger, and checking and accepting the fire-fighting hidden danger after maintenance; and checking the working data and relevant statistics of the patrolmen and the monitors. In some embodiments of the present invention, preferably, the primary administrator can also record monthly fire inspection reports, safety education training, fire fighting rescue drills and fire fighting related data through the management module; the fire-fighting related data comprises information which is useful in case of fire-fighting dangerous situations, such as fire-fighting key parts, dangerous goods information, fire-fighting facilities, building information and the like. A supervisor supervises the hidden danger treatment of subordinate units through a supervision platform and tracks the fire-fighting hidden danger treatment progress of the supervisor. And the upper manager knows the fire-fighting working condition in the whole district through the upper management platform.

Referring to fig. 2, the polling workflow of the fire node is as follows. The inspection terminal (which can be a mobile terminal such as a mobile phone APP or a WeChat application applet) receives the inspection task, and an inspector goes to the site to inspect the fire-fighting nodes in the inspection task; the inspector can inspect the fire-fighting nodes one by one according to the fire-fighting node sequence in the set inspection task, and can flexibly adjust the inspection sequence according to actual needs (such as the distance between the geographical positions of the fire-fighting nodes). The inspector scans and identifies the fire-fighting node, checks the state of the fire-fighting node and records and submits the state of the fire-fighting node. If the fire-fighting node is normal, only the node needs to be marked to be normal; if the fire-fighting node has hidden danger, reasons need to be confirmed, details are described, and the scene is photographed. If the hidden danger of the fire-fighting node is not serious and the inspector can handle the hidden danger, the fire-fighting node is rectified, the rectification processing is explained, and the rectified site is photographed; the inspection personnel can not process or cannot process the inspection result, and directly submit the inspection result, and the hidden trouble is reported to the sub-server for the primary administrator to perform subsequent processing. No matter whether the state of the fire-fighting node is normal or not, the inspector needs to submit the inspection result so as to check the working record and count the fire-fighting related numerical values. The submitted routing inspection result comprises the following steps: node number, node position, node type, inspector, inspection start-stop time, node state and other related information. The node number, the node position, the node type and the patrol inspector are automatically obtained when the mobile terminal scans and identifies the fire-fighting node; and automatically generating the inspection starting time and the inspection ending time, wherein the inspection starting time is the time when the mobile terminal scans and identifies the fire-fighting node, and the inspection ending time is the time when the inspection result is submitted. And after the polling results of all the fire-fighting nodes are submitted, the corresponding polling tasks are completed.

Referring to fig. 3, a process of processing an alarm message by the monitoring terminal is specifically as follows. The monitoring terminal receives the alarm information of the fire-fighting equipment in the Internet of things fire-fighting system, and firstly confirms whether the alarm is true or not. The internet of things fire fighting system comprises, but is not limited to, an automatic fire alarm system, a fire fighting water system, an electrical fire monitoring system and a video monitoring system; the data in the alarm information includes: the method comprises the steps of the position of the fire fighting equipment of the Internet of things, initial alarm time, latest alarm time, alarm times and alarm types. It is worth noting that some devices in the internet of things fire fighting system can have real-time data feedback. If so, the monitor marks a real alarm through the monitoring module; if not, further determining whether the equipment fails. If the equipment fails, corresponding processing is carried out, a processing description is described, and the scene is photographed; if the equipment does not have a fault, the equipment is simply misreported and marked as false alarm. Alternatively, if the same device continuously reports false alarms for more than a set number of times (e.g. 3 times), the monitoring terminal may automatically mark the device failure. The monitor judges the authenticity of the alarm or whether the equipment has a fault or not, and can directly check the alarm on site or verify the alarm through real-time data feedback of the equipment in the internet of things or a real-time picture of an accessory video monitor. If the monitor can correct the device failure, the monitor needs to explain the processing method and take a picture of the corrected site after correction.

Referring to fig. 4, a primary administrator processes hidden trouble faults which cannot be processed by a patroller and a monitor through a sub-server. The basic level administrator receives the reported hidden danger information, checks the specific content, and assigns tasks to the engineering departments of the unit or the corresponding maintenance units according to actual needs; in the assignment, the processing requirement may be described, for example, how long the maintenance is completed, or a related picture may be further added. After the maintenance is finished, the primary administrator confirms the hidden danger acceptance result, and can also explain the processing after acceptance and add related pictures. Optionally, the hidden danger maintenance acceptance of the fire-fighting node is carried out by an inspector, and the administrator further determines to archive the hidden danger maintenance acceptance, specifically, a new inspection result of the fire-fighting node is submitted in an inspection task; the equipment fault maintenance of the fire fighting system of the Internet of things is checked and accepted by a primary administrator. The fire-fighting node management system has the advantages that a primary administrator can manage patrolmen and supervisors of a unit through the terminal, manage fire-fighting nodes and equipment in the Internet of things fire-fighting system, track hidden danger conditions of the unit and know responsibility conditions of the unit.

Referring to fig. 5, in the embodiment of the present invention, the hierarchical fire protection management system is divided into an upper management platform, a middle supervision platform, and a base management subsystem. An upper manager, such as a city-level team-level manager, can look up all fire-fighting data of the jurisdiction to which the administrator belongs according to each classification by using the upper management platform. The classification includes, but is not limited to, district and town under jurisdiction, unit, fire fighting equipment type, personnel type, hidden danger type; the personnel types include supervisors, primary administrators, inspectors, and monitors. The content referred to includes: statistics of various types of fire fighting data, specific historical data, etc. Through the upper management platform, fire-fighting workers at all levels can be managed, and unified patrol rules are formulated. It is understood that the upper management platform may also publish relevant fire policy news. The supervisor supervises the fire-fighting work of each unit in the responsibility range through the middle-layer supervising platform, which mainly comprises: tracking hidden dangers of incomplete treatment in the overdue period of each subordinate unit, making corresponding reminding, negotiation or home visit for field inspection according to the overdue period, recording corresponding treatment, and assisting with field photo certification if necessary. In the specific embodiment of the invention, the fire-fighting hidden danger is unprocessed after the expiration of one week, and the lower-level unit is reminded to process the hidden danger as soon as possible by sending information through the supervision platform; carrying out negotiation with a lower-level unit through a supervision platform and recording negotiation content when the fire-fighting hidden danger is not processed for more than three weeks; the fire-fighting hidden danger exceeds that which is not processed all around, the fire-fighting hidden danger is detected to the current site inspection of the lower level unit, and the processing content and the site photo during the site inspection are recorded by the supervision platform. The basic level management subsystem is responsible for managing the specific fire-fighting affairs of each unit, and mainly comprises a daily inspection task and a monitoring task. It can be understood that the corresponding fire hazard overtime duration corresponding to each supervision means can be set according to specific conditions. Wherein patrol and examine the module and supply the inspector to use, be responsible for according to the rule of patrolling and examining of making well and patrol and examine the task, patrol and examine and collect the result of patrolling and examining corresponding fire control node. The monitoring module is used by a monitor and is responsible for receiving relevant data and alarm information of the fire-fighting equipment of the Internet of things, the authenticity of the alarm information is determined by the monitor, and a processed alarm result is recorded. The management module is used by a primary administrator and is responsible for managing fire-fighting facilities, personnel and fire-fighting related work of the unit and handling the difficult and complicated hidden dangers which cannot be handled by inspectors and monitors. Optionally, the related data generated in the upper layer management platform, the middle layer supervisory platform and the base layer management subsystem are stored in the same database.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.

Claims

1. A hierarchical fire protection management method is characterized by comprising the following steps:

s1, the inspection terminal inspects the fire-fighting nodes one by one according to the inspection rule formulated by the main server and the inspection task formulated by the sub-servers, collects the inspection results of the fire-fighting nodes and feeds the inspection results back to the sub-servers;

s2, the monitoring terminal monitors the state of the Internet of things fire fighting system, receives alarm information of the Internet of things fire fighting equipment, determines an alarm type according to feedback data and/or field inspection of the Internet of things fire fighting system, and feeds an alarm result back to the sub-server;

s3, the sub-server manages fire-fighting affairs, including the inspection task processing and the fire-fighting hidden danger information fed back to the server in the monitoring process;

s4, the monitoring terminal monitors fire-fighting affairs of a plurality of subordinate sub-servers and processes the fire-fighting hidden danger which is not processed in an overdue period;

and S5, the main server consults and counts the fire-fighting affairs of the subordinate sub-servers according to the classification, and manages the information of the subordinate fire fighters.

2. The hierarchical fire protection management method according to claim 1, wherein the inspection results of the fire protection nodes include node numbers, node positions, node types, inspectors, inspection start and stop times and node related information; the node-related information includes node state information.

3. The hierarchical fire management method of claim 2, wherein the fire nodes are configured to:

if the fire-fighting node has hidden danger, the node state information also comprises the reason of the hidden danger of the node, problem description and site pictures;

further, if the hidden danger of the fire-fighting node can be rectified and corrected on the spot, the node state information also comprises a rectification and correction processing description and a processed on-site picture.

4. The hierarchical fire management method according to claim 2, wherein the alarm result includes alarm information of the internet of things fire fighting equipment and the alarm type;

the alarm information comprises the position of the fire-fighting equipment of the Internet of things, initial alarm time, latest alarm time, alarm times and alarm types;

wherein the alarm types comprise real alarm conditions, false alarm conditions and equipment faults.

5. The hierarchical fire management method of claim 4, wherein the alert type is configured to:

if the alarm type is equipment failure, the alarm result also comprises a processing description and a field photo of the alarm equipment;

further, if the alarm type is equipment failure and the alarm can be resolved on site, the alarm result further includes a rectification processing description and a processed site picture.

6. The hierarchical fire protection management method according to claim 1, wherein the method for processing the fire hazard information fed back to the server side in the inspection task and monitoring process comprises the following steps: sending the information of the hidden fire danger to be maintained to an engineering department of the unit or a corresponding maintenance unit; and checking and accepting the repaired fire-fighting hidden danger information.

7. The hierarchical fire protection management method according to claim 1, wherein the method for the supervisor to handle the fire hazard of the overdue and unprocessed is specifically as follows: and reminding the subordinate units to undertake liability according to the time length of the fire-fighting hidden danger, carrying out negotiation or direct home inspection on the subordinate units, and recording related processing contents.

8. The hierarchical fire management method of claim 1, wherein the sub-server managed fire fighting transactions further comprise: recording monthly fire-prevention inspection, safety education training, fire-fighting rescue drilling and fire-fighting related data; the fire-fighting related data comprises fire-fighting key parts, dangerous goods information, fire-fighting facilities and building information.

9. A hierarchical fire management system for performing the method of any of claims 1-8, comprising:

the upper management platform is used for consulting all fire-fighting working conditions of lower levels of the jurisdiction according to classification, formulating a uniform patrol rule and managing information of fire fighters in the jurisdiction;

the middle-level monitoring platform is used for monitoring the fire-fighting working condition of the subordinate level and monitoring and reminding the problem of hidden danger which is not processed in the overdue period;

the basic level management subsystem is used for managing specific fire-fighting affairs of the basic level and fire-fighting data generated in the fire-fighting affairs;

and the data storage module is used for storing related data information in the superior management platform, the intermediate supervision platform and the basic level management subsystem.

10. A fire management system as recited in claim 9, wherein the primary management subsystem comprises:

the system comprises an inspection module, a data processing module and a data processing module, wherein the inspection module is used for receiving a formulated inspection task, inspecting corresponding fire-fighting nodes in the inspection task and collecting inspection results of the fire-fighting nodes;

the monitoring module is used for monitoring the fire fighting system of the Internet of things, collecting relevant data and alarm information of the fire fighting system of the Internet of things and processing the alarm information;

and the management module is used for managing the fire-fighting affairs at the current level and processing the fire-fighting hidden dangers discovered by the inspection module and the monitoring module.