CN116386163B - Method and system for patrol management, electronic equipment and storage medium - Google Patents

Abstract

The application relates to the technical field of fire control and discloses a method for patrol management, which comprises the following steps: acquiring first position information of a fire occurrence point and second position information of a plurality of patrol personnel; determining passing information between each patrol personnel and each fire occurrence point according to the first position information and the second position information; determining a target inspection terminal according to the traffic information; and sending alarm information corresponding to the fire occurrence point to the target inspection terminal, and triggering the target inspection terminal to display the alarm information. Therefore, the calculated traffic information comprises the journey of the patrol personnel in the building through the layer height of the fire occurrence point and the layer height of the patrol personnel, so that the traffic information between the patrol personnel and the fire occurrence point can be more accurately determined. The police information is conveniently pushed to proper patrol personnel, so that the patrol personnel can confirm the authenticity of the fire as soon as possible. The application also discloses a system, electronic equipment and storage medium for patrol management.

Description

Method and system for patrol management, electronic equipment and storage medium

Technical Field

The application relates to the technical field of fire protection, for example, to a method and a system for patrol management, electronic equipment and a storage medium.

Background

Currently, the scenario of dispatching orders for personnel is usually in power maintenance. For example: chinese patent document publication No. CN107644259a discloses: and filtering out maintenance personnel on duty, dispatching orders according to the priority order set in the personnel system, and pushing fault places and approximate symptoms to the mobile terminal of the most suitable operation and maintenance personnel through the short message cat and the APP. Chinese patent document publication No. CN111600743a discloses: the dispatch unit searches out the field maintainer with the highest historical maintenance times and highest problem success processing rate of the type of fault problems from the operation and maintenance rush repair team processing problem statistics module according to the type of the fault of the field power equipment fed back by the expert diagnosis system; if a plurality of field maintenance personnel meeting the requirements exist, the field maintenance personnel with the highest working life and higher job level are selected from the field maintenance personnel to carry out equipment maintenance.

With the continuous development of science and technology, more and more buildings are provided with sensors to realize automatic fire alarm. However, due to the precision of the sensor, the imperfect fire alarm method and the like, the possibility of false alarm exists in the automatic fire alarm. Therefore, people also need to be dispatched in the scene of fire alarm, so that the patrol personnel can quickly determine whether the fire actually happens. How to push the alarm information to proper patrol personnel needs to be solved.

Disclosure of Invention

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview, and is intended to neither identify key/critical elements nor delineate the scope of such embodiments, but is intended as a prelude to the more detailed description that follows.

The embodiment of the disclosure provides a method and a system for patrol management, electronic equipment and a storage medium, so that police information can be pushed to a patrol terminal used by a proper patrol personnel.

In some embodiments, a method for patrol management, comprising: acquiring first position information of a fire occurrence point and second position information of a plurality of patrol personnel; the first location information includes: the layer height of the fire point; the second position information includes: the layer height of the patrol personnel; determining passing information between each patrol personnel and each fire occurrence point according to the first position information and the second position information; determining a target inspection terminal according to the traffic information; and sending alarm information corresponding to the fire occurrence point to the target inspection terminal, and triggering the target inspection terminal to display the alarm information.

In some embodiments, the traffic information includes a target traffic distance; determining traffic information between the patrol personnel and the fire occurrence point according to the first position information and the second position information, including: determining whether the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel; under the condition that the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel, determining a first horizontal distance between the fire occurrence point and the patrol personnel, and determining the first horizontal distance as a target passing distance; and/or under the condition that the layer height of the fire occurrence point is inconsistent with the layer height of the patrol personnel, determining a second horizontal distance and a vertical distance between the fire occurrence point and the patrol personnel, and determining the sum of the second horizontal distance and the vertical distance as the target passing distance.

In some embodiments, determining a first horizontal distance between the point of fire occurrence and the patrol personnel comprises: acquiring a plane building diagram corresponding to a fire occurrence point; constructing a first communication line with a starting point being the position of a patrol personnel and a finishing point being the fire occurrence point on the plane building diagram; determining a first communication line with the shortest length as a first target routing inspection route; and determining the length corresponding to the first target inspection route as a first horizontal distance between the fire occurrence point and the inspection personnel.

In some embodiments, determining the vertical distance between the point of fire occurrence and the patrol personnel comprises: calculating the layer height of the fire occurrence point minus the layer height of the patrol personnel to obtain the relative layer height; and calculating the relative floor height multiplied by the preset floor height to obtain the vertical distance between the fire occurrence point and the patrol personnel.

In some embodiments, determining a second horizontal distance between the point of fire occurrence and the patrol personnel comprises: acquiring a plane building diagram corresponding to a fire occurrence point; constructing a second communication line with a starting point of the position of the patrol personnel and a finishing point of the position of the patrol personnel in the plane building diagram; constructing a third communication line with a starting point being the position of the stair opening and a finishing point being the fire occurrence point on the plane building diagram; determining a second communication line with the shortest length and a third communication line with the shortest length as a second target inspection route; and determining the sum of the lengths of the second target inspection routes as a second horizontal distance between the fire occurrence point and the inspection personnel.

In some embodiments, the traffic information further includes a traffic time; determining traffic information between each patrol personnel and the fire occurrence point according to the first position information and the second position information, and further comprising: user information of each patrol personnel is respectively obtained; and respectively determining the passing time of each patrol personnel by using the user information corresponding to the patrol personnel and the target passing distance corresponding to the patrol personnel.

In some embodiments, after sending the alert information corresponding to the fire occurrence point to the target patrol terminal, the method further includes: and responding to the first submitting instruction of the user to confirm whether the fire occurrence point is a real fire.

In some embodiments, a system for patrol management, comprising: the inspection dispatch platform is configured to acquire first position information of a fire occurrence point and second position information of a plurality of inspection personnel; the first location information includes: the layer height of the fire point; the second position information includes: the layer height of the patrol personnel; determining passing information between each patrol personnel and each fire occurrence point according to the first position information and the second position information; determining a target inspection terminal according to the traffic information, and sending alarm information corresponding to the fire occurrence point to the target inspection terminal; the target inspection terminal is configured to display warning information.

In some embodiments, an electronic device includes a processor and a memory storing program instructions, the processor being configured, when executing the program instructions, to perform the method for patrol management described above.

In some embodiments, a storage medium stores program instructions that, when executed, perform the method for patrol management described above.

The method and system for patrol management, the electronic equipment and the storage medium provided by the embodiment of the disclosure can realize the following technical effects: by acquiring first position information of a fire occurrence point and second position information of a plurality of patrol personnel. The first location information includes: the fire point is at the high layer. The second position information includes: the level of the inspection personnel is high. And determining the passing information between each patrol personnel and the fire occurrence point according to the first position information and the second position information. And determining the target inspection terminal according to the traffic information. And sending alarm information corresponding to the fire occurrence point to the target inspection terminal, and triggering the target inspection terminal to display the alarm information. Thus, there is often a rapid spread characteristic due to the fire. Therefore, it is required that the inspector can rapidly confirm whether the fire actually occurs, thereby reducing the loss caused by the fire. Through the layer height of the fire occurrence point and the layer height of the patrol personnel, the calculated traffic information comprises the journey of the patrol personnel in the building, so that the traffic information between the patrol personnel and the fire occurrence point can be more accurately determined, and the target patrol terminal with the warning information required to be displayed can be more accurately determined. So that police information can be conveniently pushed to a proper patrol terminal used by patrol personnel, and the patrol personnel can confirm the authenticity of fire as soon as possible.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements, and in which like reference numerals refer to similar elements, and in which:

FIG. 1 is a schematic diagram of a method for patrol management provided by an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of a smoke sensor distribution provided by an embodiment of the present disclosure;

FIG. 3 is a schematic diagram of another method for patrol management provided by an embodiment of the present disclosure;

FIG. 4 is a schematic diagram of yet another method for patrol management provided by an embodiment of the present disclosure;

FIG. 5 is a schematic diagram of a system for patrol management provided by an embodiment of the present disclosure;

fig. 6 is a schematic diagram of an electronic device provided in an embodiment of the disclosure.

Reference numerals:

1: a first smoke sensor; 2: a second smoke sensor; 3: a third smoke sensor; 4: and a fourth smoke sensor.

Detailed Description

So that the manner in which the features and techniques of the disclosed embodiments can be understood in more detail, a more particular description of the embodiments of the disclosure, briefly summarized below, may be had by reference to the appended drawings, which are not intended to be limiting of the embodiments of the disclosure. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may still be practiced without these details. In other instances, well-known structures and devices may be shown simplified in order to simplify the drawing.

The terms first, second and the like in the description and in the claims of the embodiments of the disclosure and in the above-described figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate in order to describe embodiments of the present disclosure. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion.

The term "plurality" means two or more, unless otherwise indicated.

In the embodiment of the present disclosure, the character "/" indicates that the front and rear objects are an or relationship. For example, A/B represents: a or B.

The term "and/or" is an associative relationship that describes an object, meaning that there may be three relationships. For example, a and/or B, represent: a or B, or, A and B.

The term "corresponding" may refer to an association or binding relationship, and the correspondence between a and B refers to an association or binding relationship between a and B.

Currently, in order to be able to rapidly cope with the occurrence of fire, some shops, factories and the like are equipped with patrol staff. Meanwhile, in order to prevent the fire alarm information from being false, the police force is wasted. When a fire occurs, a patrol inspector confirms whether the fire is a real fire or not at the fire occurrence point. In order not to waste police resources and reduce loss caused by fire. It is important to push police information to proper patrol personnel. According to the method and the system, the traffic information is determined according to the layer height of the fire occurrence point and the layer height of the patrol personnel, the calculated traffic information comprises the journey of the patrol personnel in the building, the traffic information between the patrol personnel and the fire occurrence point is determined more accurately, and then the target patrol terminal for displaying the warning information is determined more accurately. So that police information can be conveniently pushed to a patrol terminal used by a proper patrol personnel, and the patrol personnel can confirm the authenticity of fire as soon as possible.

Referring to fig. 1, an embodiment of the disclosure provides a method for patrol management, including:

step S101, the electronic equipment acquires first position information of a fire occurrence point and second position information of a plurality of patrol personnel.

Step S102, the electronic equipment determines traffic information between each patrol personnel and each fire occurrence point according to the first position information and the second position information.

Step S103, the electronic equipment determines a target patrol terminal according to the traffic information.

Step S104, the electronic equipment sends the warning information corresponding to the fire occurrence point to the target inspection terminal, and the target inspection terminal is triggered to display the warning information.

By adopting the method for patrol management provided by the embodiment of the disclosure, the first position information of the fire occurrence point and the second position information of a plurality of patrol personnel are obtained. The first location information includes: the fire point is at the high layer. The second position information includes: the level of the inspection personnel is high. And determining the passing information between each patrol personnel and the fire occurrence point according to the first position information and the second position information. And determining the target inspection terminal according to the traffic information. And sending alarm information corresponding to the fire occurrence point to the target inspection terminal, and triggering the target inspection terminal to display the alarm information. Thus, there is often a rapid spread characteristic due to the fire. Therefore, it is required that the inspector can rapidly confirm whether the fire actually occurs, thereby reducing the loss caused by the fire. The calculated traffic information can comprise the journey of the patrol personnel in the building through the layer height of the fire occurrence point and the layer height of the patrol personnel, so that the traffic information between the patrol personnel and the fire occurrence point can be more accurately determined. The police information is conveniently pushed to proper patrol personnel, so that the patrol personnel can confirm the authenticity of the fire as soon as possible.

Optionally, a plurality of smoke sensors, a plurality of temperature sensors and a plurality of light sensors are disposed within the building. Acquiring first position information of a fire occurrence point, including: and acquiring smoke concentrations respectively measured by the smoke sensors, temperature values respectively measured by the temperature sensors and wavelength values respectively measured by the light sensors. And determining a smoke sensor corresponding to the smoke concentration as a target sensor under the condition that the smoke concentration is larger than a first preset value. And determining the temperature sensor corresponding to the temperature value as the target sensor under the condition that the temperature value is larger than a second preset value. And determining the optical sensor corresponding to the wavelength value as a target sensor when the wavelength value is larger than a third preset value. Respectively acquiring coordinates of each target sensor in a building, and determining the coordinates of each target sensor in the building as alternative coordinates; calculating the average value of each alternative coordinate to obtain a target coordinate; the target coordinates are determined as first location information of the fire occurrence point. The smoke sensor is used for measuring the smoke concentration. And a temperature sensor corresponding to the temperature value, namely a temperature sensor for measuring the temperature value. The light sensor corresponding to the wavelength value is the light sensor measuring the wavelength value. In this way, when the sensors are installed in the building, the coordinates of each sensor can be set together. Therefore, when the measurement result of each sensor is acquired, the coordinates corresponding to the measurement result can be acquired together. According to the measurement result of each sensor, which sensors exist around the fire occurrence point can be roughly determined, and according to the coordinates of the sensors around the fire occurrence point in the building, the first position information of the fire occurrence point can be accurately acquired.

Optionally, a plurality of locators are arranged in the building, and coordinate information is pre-stored in each locator. The coordinate information is used to characterize the coordinates of the locator within the building. Each patrol personnel is provided with an alternative patrol terminal. And under the condition that the alternative patrol terminal is in the communication range of the positioning instrument, the positioning instrument communicates with the alternative patrol terminal and acquires the equipment identification of the alternative patrol terminal. Acquiring second position information of the patrol personnel, including: and obtaining a target identifier sent by the locator. The target identifier is the equipment identifier of the alternative patrol terminal positioned in the communication range of the locator. And determining the coordinate information of the positioning instrument as second position information of the patrol personnel corresponding to the target identifier sent by the positioning instrument. In this way, the coordinate information of the positioning instrument can be used as the second position information of the patrol personnel in the communication range of the positioning instrument by communicating the positioning instrument with the alternative patrol terminal configured by the patrol personnel, so that the second position information of the patrol personnel can be accurately determined.

In some embodiments, the device identification of the alternative patrol terminal is a unique code capable of identifying the alternative patrol terminal. Device identification, for example: device ID (identity document), identification number. Wherein, the device IDs of different alternative inspection terminals are different.

In some embodiments, a plurality of positioners are disposed within a building; each patrol personnel respectively holds alternative patrol terminals with different equipment IDs, for example: the patrol staff P holds an alternative patrol terminal with a device ID of 01, and the patrol staff Q holds an alternative patrol terminal with a device ID of 02. And under the condition that the alternative patrol terminal is in the communication range of the positioning instrument, the positioning instrument communicates with the alternative patrol terminal and acquires the equipment ID of the alternative patrol terminal. And uploading the currently acquired device ID of the alternative patrol terminal to the electronic device by the locator. The electronic equipment acquires the coordinate information of the locator, and the coordinate information is determined to be the second position information of the patrol personnel corresponding to the equipment ID sent by the locator. Thus, the locator can only upload the device ID corresponding to the alternative patrol terminal currently in the communication range of the locator to the electronic device at a time. Therefore, the electronic equipment can distinguish different positions where different patrol personnel are located through the received equipment IDs uploaded by different locators currently.

In some embodiments, a plurality of positioners are arranged in a building, and a two-dimensional plane building diagram or a three-dimensional plane building diagram is built according to the building proportion. Setting a coordinate origin in the two-dimensional plane building diagram or the three-dimensional plane building diagram, and constructing a two-dimensional coordinate system according to the coordinate origin on the two-dimensional plane building diagram or constructing a three-dimensional coordinate system according to the coordinate origin on the three-dimensional plane building diagram. Presetting coordinate information in the positioning instrument according to a two-dimensional coordinate system or a three-dimensional coordinate system, and setting coordinates for the sensor. Wherein the sensor, for example: smoke sensor, temperature sensor, light sensor.

Optionally, the traffic information includes a target traffic distance. Determining traffic information between the patrol personnel and the fire occurrence point according to the first position information and the second position information, including: and determining whether the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel. Under the condition that the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel, determining a first horizontal distance between the fire occurrence point and the patrol personnel, and determining the first horizontal distance as a target passing distance. And/or under the condition that the layer height of the fire occurrence point is inconsistent with the layer height of the patrol personnel, determining a second horizontal distance and a vertical distance between the fire occurrence point and the patrol personnel, and determining the sum of the second horizontal distance and the vertical distance as the target passing distance. Thus, the distance calculation of the patrol personnel to the fire point is different under the condition that the layer height of the patrol personnel is different from that of the fire point. Therefore, whether the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel is determined, and the target passing distance between different patrol personnel and the fire occurrence point can be determined more accurately.

Further, determining a first horizontal distance between the point of fire occurrence and the inspector, comprising: and obtaining a plane building diagram corresponding to the fire occurrence point. The method is characterized in that a first communication line with a starting point being the position of a patrol personnel and a terminal point being the fire occurrence point is constructed on a planar building diagram. And determining the first communication line with the shortest length as a first target inspection route. And determining the length corresponding to the first target inspection route as a first horizontal distance between the fire occurrence point and the inspection personnel. Thus, through the planar building diagram, the first horizontal distance between the fire occurrence point and the patrol personnel can be accurately determined.

Further, determining a vertical distance between the fire occurrence point and the patrol personnel includes: and (5) calculating the layer height of the fire occurrence point minus the layer height of the patrol personnel to obtain the relative layer height. And calculating the relative floor height multiplied by the preset floor height to obtain the vertical distance between the fire occurrence point and the patrol personnel. Thus, the vertical distance between the fire occurrence point and the patrol personnel can be accurately obtained through the relative layer height between the fire occurrence point and the patrol personnel.

Further, determining a second horizontal distance between the point of fire occurrence and the patrol personnel, comprising: and obtaining a plane building diagram corresponding to the fire occurrence point. The construction starting point of the planar building diagram is the position of the patrol personnel, and the end point is the second communication line of the elevator entrance. And constructing a third communication line with a starting point being the position of the stair opening and a finishing point being the fire occurrence point in the planar building diagram. And determining the second communication line with the shortest length and the third communication line with the shortest length as a second target inspection route. And determining the sum of the lengths of the second target inspection routes as a second horizontal distance between the fire occurrence point and the inspection personnel. Thus, the same building usually has the same structure in the plan view of each floor. In the case that the patrol personnel and the fire point are located on different floors, the patrol personnel usually need to reach the floor where the fire point is located from the own position to the stair opening through the stair opening. Then reaches the fire point from the stair opening. Therefore, the horizontal distance that the inspector needs to walk is the sum of the distance from the inspector to the entrance of the stairs and the distance from the entrance of the stairs to the fire occurrence point. The shortest second communication line and the shortest third communication line are respectively determined, so that the target passing distance between the patrol personnel and the fire occurrence point can be accurately determined.

In some embodiments, the planar building map is a two-dimensional planar building map in which the walls and doors are represented by lines of different colors. Thus, the wall location can be distinguished from the plan view. Marking the position of the patrol personnel and the position of the fire occurrence point in the plane building diagram. And constructing a plurality of first communication lines for connecting the position of the patrol personnel and the position of the fire occurrence point. The first connecting line does not pass through the wall body, namely, the first connecting line and the line representing the wall body are not contacted with each other. And determining the length of the first communication line with the shortest length as a first horizontal distance between the fire occurrence point and the patrol personnel. Similarly, marking the position of the patrol personnel and the position of the fire occurrence point in the steps is replaced by marking the position of the patrol personnel and the position of the stair opening, and a second communication line is obtained. Similarly, marking the position of the patrol personnel and the position of the fire occurrence point in the steps is replaced by marking the position of the stair opening and the position of the fire occurrence point, and a third communication line is obtained.

Optionally, the traffic information further includes a traffic time; determining traffic information between each patrol personnel and the fire occurrence point according to the first position information and the second position information, and further comprising: and respectively acquiring the user information of each patrol personnel. And respectively determining the passing time of each patrol personnel by using the user information corresponding to the patrol personnel and the target passing distance corresponding to the patrol personnel. Wherein, the user information includes: one or more of user age, user height, user fitness condition, and user disease information. The user fitness condition includes a user fitness type, a user daily average movement duration, and the like. User fitness type, for example: weightlifting, swimming, running, etc. User disease information, such as: asthma, rhinitis, heart disease, etc. Therefore, due to the difference of physical quality of different patrol workers, some patrol workers can reach a fire occurrence point faster even if the distance is far. Therefore, by calculating the passing time, the police information can be conveniently pushed to the proper patrol personnel, so that the patrol personnel can more quickly confirm the authenticity of the fire.

Further, determining the passing time of the patrol personnel by using the user information corresponding to the patrol personnel and the target passing distance corresponding to the patrol personnel comprises: determining walking speed corresponding to the patrol personnel according to the user information corresponding to the patrol personnel; and obtaining the passing time of the patrol personnel by calculating the target passing distance corresponding to the patrol personnel divided by the walking speed corresponding to the patrol personnel.

Optionally, determining the walking speed corresponding to the patrol personnel according to the user information corresponding to the patrol personnel includes: performing table lookup operation on the user information by using a preset speed database to obtain walking speed corresponding to the user information; the speed database stores the correspondence between user information and walking speed.

Optionally, determining the walking speed corresponding to the patrol personnel according to the user information corresponding to the patrol personnel includes: inputting user information corresponding to the patrol personnel into a preset speed model to obtain walking speed corresponding to the patrol personnel.

Wherein the preset rate model is determined by: acquiring user information with a walking speed label; and inputting the user information with the walking speed label into a preset first neural network model for training to obtain a speed model.

Optionally, the traffic information includes a target traffic distance; determining a target patrol terminal according to the traffic information, including: and determining the patrol personnel corresponding to the shortest target passing distance as the target patrol personnel. And determining the alternative patrol terminal corresponding to the target patrol personnel as the target patrol terminal. The alternative patrol terminal is used for representing an intelligent terminal which is worn by patrol personnel and can check police information. In some embodiments, the alternative patrol terminal is further configured to upload fire confirmation information during patrol by the patrol personnel.

Optionally, the traffic information includes a target traffic distance and a traffic time; determining a target patrol terminal according to the traffic information, including: and determining the patrol personnel corresponding to the transit time with the shortest duration as the target patrol personnel. And determining the alternative patrol terminal corresponding to the target patrol personnel as the target patrol terminal. Thus, the appropriate patrol personnel and the patrol terminal used by the appropriate patrol personnel can be determined.

Further, the method for determining the alternative patrol terminal corresponding to the target patrol personnel comprises the following steps: and searching a database by using a preset terminal to perform table lookup operation, and obtaining an alternative patrol terminal corresponding to the target patrol personnel. The terminal inquiry database stores the corresponding relation between the patrol personnel and the alternative patrol terminal.

In some embodiments, the alert information is the location of the point of occurrence of the fire. The position of the fire occurrence point is first position information of the fire occurrence point. First location information of a fire occurrence point, for example: coordinates of the point of fire occurrence within the building. Therefore, the police information corresponding to the fire occurrence point is sent to the target inspection terminal, so that inspection personnel can know the position of the fire occurrence point conveniently, and the authenticity of the fire can be inspected.

Optionally, after sending the alarm information corresponding to the fire occurrence point to the target inspection terminal, the method further includes: and acquiring whether the fire occurrence point sent by the target inspection terminal is a real fire. The target patrol terminal responds to a first submitting instruction of a user to confirm whether a fire occurrence point is a real fire.

Optionally, after obtaining whether the fire occurrence point sent by the target inspection terminal is a real fire, the method further includes: and under the condition that the fire occurrence point is a real fire, acquiring fire information corresponding to the fire occurrence point. The event type is determined from the fire information. An emergency plan is determined based on the event type. In this way, the event type to which the fire belongs is determined according to the fire information, and the corresponding emergency plan is automatically determined by integrating various event types. The fire control expert can be assisted to quickly determine the corresponding emergency plan of the fire, so that the efficiency of determining the emergency plan is improved. The fire condition can be treated in time, and the fire loss is reduced.

Optionally, after acquiring the first position information of the fire occurrence point, the method further includes: and acquiring fire information corresponding to the fire occurrence point. The event type is determined from the fire information. An emergency plan is determined based on the event type. Therefore, after the first position information of the fire occurrence point is obtained, the event type is determined immediately according to the fire information, the event type corresponding to the fire occurrence point can be determined more rapidly, and a fire specialist can be assisted to determine the corresponding emergency plan of the fire more rapidly.

In some embodiments, acquiring fire information corresponding to a fire occurrence point includes: and acquiring fire information corresponding to the fire occurrence point input by the user.

In some embodiments, the event types include: alert level, building structure attribute level, industry attribute level, venue emphasis level, asset value level, and resource allocation level.

Optionally, the fire information includes fire location information; determining event type based on fire information, comprising: and carrying out table lookup operation on the fire positioning information by using a preset first fire positioning database to obtain event types corresponding to the fire positioning information. The first fire control positioning database stores the corresponding relation between the fire positioning information and the event type. Thus, the type of the fire occurrence point can be rapidly determined through the fire positioning information, and further, the emergency plan can be rapidly determined conveniently.

Optionally, the fire information includes fire positioning information and a fire emitting device, and determining the event type according to the fire information includes: and determining the attribute level of the building structure, the attribute level of the industry, the important level of the place, the value level of the asset and the allocation level of the resource according to the fire positioning information. And determining the alarm level according to the fire sending equipment. Wherein the fire emitting device is used to characterize a device that can be used to confirm the occurrence of a fire, such as: sensors, inspection equipment, etc. A sensor, for example: smoke sensors, temperature sensors, etc. The patrol equipment is an intelligent terminal used for representing the uploading of fire confirmation information by the user in the patrol process. Thus, the fire alarm grade is determined by the fire sending device, and the alarm grade can be determined in a self-adaptive manner according to the fire condition of the building. The prepared emergency plan can be more targeted.

Further, determining a building structure attribute level, an industry attribute level, a place emphasis level, an asset value level and a resource allocation level according to the fire positioning information, including: and carrying out table lookup operation on the fire positioning information by using a preset second fire positioning database to obtain the building structure attribute level, industry attribute level, site key level, asset value level and resource allocation level corresponding to the fire positioning information. The second fire control positioning database stores the corresponding relation among fire information, building structure attribute level, industry attribute level, place key level, asset value level and resource allocation level.

Further, determining an alarm level according to the fire emitting device includes: and carrying out table lookup operation on the fire equipment by using a preset third fire control positioning database to obtain the alarm grade corresponding to the fire equipment. The third fire positioning database stores the corresponding relation between the fire sending equipment and the alarm level. In some embodiments, where the fire emitting device is a sensor, determining the alert level as secondary; and under the condition that the fire sending equipment is the inspection equipment, determining the alarm grade as a first grade.

In some embodiments, the building structure attribute level stored in the database is obtained by: building information is acquired. And performing table lookup operation on the building information by using a preset building structure database to obtain the building structure attribute grade corresponding to the building information. The building structure database stores the correspondence between building information and building structure attribute levels. Wherein the building information includes one or more of a fire rating of the building, a structural score of the building, a usage property score of the building, a protective strength rating of the building, and a number of people in the building.

In some embodiments, industry attribute levels stored in the database are obtained by: and acquiring the industry attribute corresponding to the building. And carrying out table lookup operation on the industry attribute by utilizing a preset industry attribute database to obtain an industry attribute grade corresponding to the industry attribute. The industry attribute database stores the corresponding relation between the industry attribute and the industry attribute grade. Among other things, industry attributes, such as: hospitals, markets, supermarkets, schools, hazardous chemicals, flammable and explosive products production and storage enterprises, petroleum and chemical enterprises, production and office enterprises, transportation and communication enterprises and the like.

In some embodiments, the venue emphasis level, for example: the key management and control units are a first level, a second level, a third level, a fourth level and the like. Among them, emphasis units such as: national emphasis laboratories, data storage centers, national administration centers, energy and traffic centers, and petrochemical industry. Important regulatory sites, such as: hospitals, malls, supermarkets, schools.

In some embodiments, the asset value level stored in the database is obtained by: asset valuations of a building are obtained. And performing table lookup operation on the asset valuation by using a preset asset value grade database to obtain the asset value grade corresponding to the asset valuation. The asset value class database stores the correspondence between asset valuations and asset value classes. Wherein the asset valuation of the building includes the tangible and intangible value of the building. The tangible value is, for example: cash stored in the building and the value of articles stored in the building. Intangible value, for example: historical cultural value of a building.

In some embodiments, the resource allocation levels stored in the database are obtained by: and obtaining the corresponding fire-fighting configuration condition of the building. And carrying out table lookup operation on the fire control configuration condition by utilizing a preset resource allocation level database to obtain a resource allocation level corresponding to the fire control configuration condition. The resource allocation level database stores the corresponding relation between the fire control allocation condition and the resource allocation level. The fire fighting configuration includes one or more of a fire power level, a rescue power level, an evacuation power level, and an escape power level.

In some embodiments, the fire is located inside a building. The fire positioning information is coordinates of fire occurrence points in a building. And acquiring fire positioning information as (x, y). And (3) carrying out table lookup operation on the (x, y) by using a preset first fire control positioning database to obtain the first warning condition grade corresponding to the (x, y), wherein the building structure attribute grade is the second grade, the industry attribute grade is the third grade, the site key grade is the third grade, the asset value grade is the fourth grade and the resource allocation grade is the fourth grade.

Optionally, determining the emergency plan according to the event type includes: determining scale factors respectively corresponding to the alarm condition level, the building structure attribute level, the industry attribute level, the place key level, the asset value level and the resource allocation level; calculating according to a first preset algorithm by using an alarm condition grade, a building structure attribute grade, an industry attribute grade, a place key grade, an asset value grade, a resource allocation grade and a scale factor to obtain an event grade; an emergency plan is determined based on the event level.

Further, determining the scale factors respectively corresponding to the alert level, the building structure attribute level, the industry attribute level, the place emphasis level, the asset value level and the resource allocation level comprises: and respectively carrying out table lookup operation on the alarm condition grade, the building structure attribute grade, the industry attribute grade, the site key grade, the asset value grade and the resource allocation by utilizing a preset proportion database to obtain the corresponding proportion factors of the alarm condition grade, the building structure attribute grade, the industry attribute grade, the site key grade, the asset value grade and the resource allocation grade. The scale database stores the alert level and the scale factor corresponding to the alert level, the building structure attribute level and the scale factor corresponding to the building structure attribute level, the industry attribute level and the scale factor corresponding to the industry attribute level, the place key level and the place key level, the asset value level and the scale factor corresponding to the asset value level, the resource allocation level and the scale factor corresponding to the resource allocation level.

In some embodiments, a table look-up operation is performed in the proportion database to obtain that the scale factor corresponding to the alert level is a, the scale factor corresponding to the building structure attribute level is B, the scale factor corresponding to the industry attribute level is C, the scale factor corresponding to the location key level is D, the scale factor corresponding to the asset value level is E, and the scale factor corresponding to the resource allocation level is F. The event level is obtained according to a first preset algorithm, for example: event level=alert level×a+building structure attribute level×b+industry attribute level×c+site emphasis level×d+asset value level×e+resource allocation level×f. Wherein "×" is multiplication and "+" is addition.

Further, determining an emergency plan based on the event level, comprising: and carrying out table lookup operation on the event level by using a preset first plan database to obtain an emergency plan corresponding to the event level. The first plan database stores the corresponding relation between the event grade and the emergency plan. Therefore, the emergency plan is determined according to the event level, and the emergency plan similar to the fire degree of the fire occurrence point can be obtained, so that a fire specialist can be better assisted to quickly determine the corresponding emergency plan of the fire occurrence point, and further the efficiency of determining the emergency plan is improved.

Optionally, determining the emergency plan according to the event type includes: and carrying out table lookup operation on the event type by using a preset second plan database to obtain an emergency plan corresponding to the event type. The second plan database stores the corresponding relation between the event type and the emergency plan.

In some embodiments, when a fire occurs, fire specialists gather together to learn about the fire information and make decisions. And commanding and dispatching the fire resources according to the decision of fire specialists. Fire-fighting resources are generally classified into dangerous case disposal, life rescue, escape and evacuation, power deployment, emergency guarantee and the like. And forming an emergency plan by the decision of the fire fighter in the research and judgment and the command and dispatch of the fire fighter resource. The emergency plan is the treatment plan for the sudden fire. Optionally, the emergency plan includes decision making, command dispatching, dangerous case treatment, life rescue, escape evacuation, power deployment, emergency guarantee and the like.

Optionally, after determining the emergency plan according to the event type, the method further includes: the emergency plan is presented to the user. And adjusting the emergency plan in response to the selection instruction of the user. Thus, the emergency plan is adjusted in response to the selection instruction of the user, the firefighter can conveniently adjust according to the special attribute of the fire, the utilization of the firefighting resources is more in line with the current fire situation, the fire can be conveniently and rapidly extinguished, and accordingly the loss of life and property is reduced.

In some embodiments, the emergency plan is adjusted in response to a user selection instruction, i.e., the contents of the emergency plan are modified according to the user selection instruction, where the contents of the emergency plan are modified, for example: adding the content of the emergency plan, deleting the content of the emergency plan, and the like.

Further, presenting the emergency plan to the user, including: and sending the emergency plan to a preset display screen, and triggering the display screen to display the emergency plan.

Optionally, after determining the emergency plan according to the event type, the method further includes: determining one or more deployment conditions corresponding to the emergency plan; determining fire terminals corresponding to each deployment condition respectively; and respectively sending each deployment condition to the corresponding fire-fighting terminal, and obtaining a treatment result from each fire-fighting terminal. The fire-fighting terminal responds to a second submitting instruction of the user to obtain a treatment result, or the fire-fighting terminal obtains the treatment result input by the user. The fire control terminal is used for representing the intelligent terminal used by fire fighters participating in fire rescue. Therefore, the fire-fighting tasks can be distributed more rapidly by automatically sending the deployment condition to the fire-fighting terminal, so that firefighters can conveniently and rapidly develop rescue actions, and the rescue time is shortened.

In some embodiments, deployment scenarios, such as: the dangerous situations are disposed, life rescue is conducted, escape evacuation is conducted, strength is conducted, emergency guarantee is conducted, and the like. Wherein the hazardous situation disposition is used to characterize the disposition of the personnel handling the hazardous situation. The life rescue deployment is used for representing the deployment of personnel searching and rescuing. Escape evacuation deployments are used to characterize deployment of personnel evacuated by commander. The power deployment is used to characterize the deployment of backup power. The emergency guarantee deployment is used for representing the deployment of emergency materials and personnel using the emergency materials.

Optionally, a plurality of smoke sensors, a plurality of temperature sensors and a plurality of light sensors are disposed within the building. The fire information further includes: the smoke concentration measured by the plurality of smoke sensors, the temperature measured by the plurality of temperature sensors, and the wavelength measured by the plurality of light sensors. After acquiring the fire information, the method further comprises the following steps: and displaying the fire spreading trend according to the fire information.

Optionally, displaying the fire spread trend according to the fire information includes: and determining the spreading trend of the harmful gas according to the smoke concentration. And determining the flame propagation trend according to the temperature value and the wavelength value. The harmful gas spreading trend and the flame spreading trend are displayed to the user as the fire spreading trend. Thus, by providing different sensors, the flame propagation trend and the flame-accompanying harmful gas propagation trend are predicted at the same time. The fire spreading trend can be comprehensively displayed, and people can be more accurately helped to escape.

Further, determining a harmful gas spreading trend according to the smoke concentration, comprising: the position and direction of each smoke sensor are acquired separately. The smoke sensors are divided into a plurality of smoke direction groups according to the positions and the directions of the smoke sensors, and the smoke sensors of the smoke direction groups are respectively numbered. And according to the serial numbers of the smoke sensors, respectively forming a concentration sequence of the smoke concentrations corresponding to the smoke sensors in each smoke direction group. And respectively determining the harmful gas spreading trend according to the concentration trend of each concentration sequence. Thus, in the event of a fire, the generation of harmful gases is often accompanied. And the diffusion of harmful gases usually shows a certain rule. Therefore, the spreading trend of the harmful gas can be accurately predicted through the change of the smoke concentration at different positions. The concentration trend of each concentration sequence is respectively determined, so that the harmful gas spreading trend can be more clearly distinguished in which positions and directions harmful gas exists.

Further, the position of the smoke sensor comprises the height of the smoke sensor; the direction of the smoke sensor is the direction corresponding to the position of the smoke sensor; dividing the smoke sensors into a plurality of smoke direction groups according to the position and direction of each smoke sensor, comprising: dividing each smoke sensor into different first layer height groups; the smoke sensors in the same first layer height group are located at the same layer height. The smoke sensors are divided into a plurality of smoke direction groups in each of the first layer height groups. Like this, divide smoke transducer through the layer height difference that smoke transducer set up to carry out the division of direction to smoke transducer according to the different directions that the passageway of each floor corresponds, the accurate judgement harmful gas of being convenient for diffuses at which passageway of floor.

In some embodiments, the grouping of the smoke sensors into different first-tier groups comprises: and under the condition that the layer height of the smoke sensor is the same as the layer height corresponding to the first layer height group, establishing the corresponding relation between the smoke sensor and the first layer height group.

In some embodiments, the grouping of smoke sensors into a plurality of smoke direction groups in a first high-rise group comprises: and under the condition that the direction corresponding to the smoke direction group comprises the direction corresponding to the smoke sensor, establishing a corresponding relation between the smoke sensor and the smoke direction group. Wherein the same smoke sensor may belong to a plurality of different smoke direction groups.

Further, the smoke sensors of the smoke direction group are respectively numbered, and include: and the smoke sensors of the smoke direction groups are numbered sequentially according to the direction sequence corresponding to the smoke direction groups. Or, the smoke sensors of the smoke direction groups are numbered sequentially in the reverse order of the direction sequence corresponding to the smoke direction groups.

In some embodiments, the direction set corresponds to the east-west direction, and the smoke sensors are numbered sequentially in the order in which they are placed from east to west. Or the direction corresponding to the direction group is east-west direction, and the smoke sensors are numbered in sequence according to the arrangement sequence of the smoke sensors from west to east.

Optionally, if the smoke sensor numbers of the smoke direction groups are sequentially arranged according to the direction sequence corresponding to the smoke direction groups. Determining a harmful gas spreading trend according to a concentration trend of a concentration sequence, comprising: and under the condition that the concentration trend of the concentration sequence is changed from small to large, determining that the harmful gas spreading trend is consistent with the direction sequence corresponding to the direction group where the concentration sequence is located, and the position of the harmful gas spreading trend is the same as the layer height of the first layer high group corresponding to the direction group where the concentration sequence is located. And under the condition that the concentration trend of the concentration sequence is changed from large to small, determining that the direction sequence of the harmful gas spreading trend is opposite to the direction sequence corresponding to the direction group in which the concentration sequence is positioned, and the position of the harmful gas spreading trend is the same as the layer height of the first layer high group corresponding to the direction group in which the concentration sequence is positioned. Or, if the sequence of the direction sequences corresponding to the smoke direction groups is reverse, the smoke sensor numbers of the smoke direction groups are sequentially given. Determining a harmful gas spreading trend according to a concentration trend of a concentration sequence, comprising: and under the condition that the concentration trend of the concentration sequence is changed from small to large, determining that the direction sequence of the harmful gas spreading trend is opposite to the direction sequence corresponding to the direction group in which the concentration sequence is positioned, and the position of the harmful gas spreading trend is the same as the layer height of the first layer high group corresponding to the direction group in which the concentration sequence is positioned. And under the condition that the concentration trend of the concentration sequence is changed from large to small, determining that the harmful gas spreading trend is consistent with the direction sequence corresponding to the direction group where the concentration sequence is located, and the position of the harmful gas spreading trend is the same as the layer height of the first layer high group corresponding to the direction group where the concentration sequence is located. Thus, a certain rule is usually exhibited due to the diffusion of the harmful gas. Thus, the tendency of harmful gases to spread can be determined by the concentration profile of the concentration sequence.

In some embodiments, the orientation of the smoke sensor is the orientation of the location where the smoke sensor is located. As shown in connection with fig. 2, there is a T-shaped channel within the building, one for each channel branch. On the west leg at 5 floors there are provided 2 smoke sensors, for example: a first smoke sensor 1, a second smoke sensor 2. On the eastern branch of the 5 floors, there are provided 1 smoke sensor, for example: a third smoke sensor 3. There are 1 smoke sensor located on the branches located in the south of the 5 floors, for example: a fourth smoke sensor 4. The smoke concentration measured by the first smoke sensor is a, the smoke concentration measured by the second smoke sensor is b, and the smoke concentration measured by the third smoke sensor is c. The first smoke sensor, the second smoke sensor and the third smoke sensor are divided into a first layer height group with the layer height of 5 layers corresponding to each other. In the case where the direction corresponding to the smoke direction group is west east, the direction corresponding to the smoke direction group includes west and east. The first smoke sensor, the second smoke sensor and the third smoke sensor are divided into a smoke direction group with the direction of west east. And the smoke sensors are numbered sequentially according to the placement sequence of the smoke sensors from west to east, for example: the first smoke sensor is numbered 0001, the second smoke sensor is numbered 0002, and the third smoke sensor is numbered 0003. And forming a concentration sequence of the smoke concentrations corresponding to the smoke sensors in the smoke direction group according to the numbers of the smoke sensors. Wherein the order of concentration sequences, for example: a. b, c. In the case that the concentration trend of the concentration sequence is changed from small to large, the harmful gas spreading trend corresponding to the concentration sequence is determined to be from west to east at 5 layers. In the case that the concentration trend of the concentration sequence is changed from large to small, the harmful gas spreading trend corresponding to the concentration sequence is determined to be from east to west at 5 layers.

Optionally, if the smoke sensor numbers of the smoke direction groups are sequentially arranged according to the direction sequence corresponding to the smoke direction groups. Determining a harmful gas spreading trend according to a concentration trend of a concentration sequence, comprising: and under the condition that the concentration trend of the concentration sequence is changed from small to large, determining that the harmful gas spreading trend is consistent with the direction sequence corresponding to the direction group where the concentration sequence is located. And under the condition that the concentration trend of the concentration sequence is changed from large to small, determining that the harmful gas spreading trend is opposite to the direction sequence corresponding to the direction group in which the concentration sequence is positioned.

Optionally, determining the harmful gas spreading trend according to the smoke concentration includes: respectively combining the smoke concentrations obtained in different time periods with a preset building diagram to obtain smoke concentration diagrams respectively corresponding to different time periods; and comparing the smoke concentration graphs according to the time sequence to obtain the harmful gas spreading trend.

Optionally, determining the harmful gas spreading trend according to the smoke concentration includes: acquiring the acquisition time corresponding to the smoke concentration. Dividing the smoke concentration into different time groups; the corresponding acquisition time of each smoke concentration in the same time group is the same. Respectively combining the smoke concentrations corresponding to each time group with a preset building diagram to obtain smoke concentration diagrams corresponding to different time groups respectively; and comparing the smoke concentration graphs according to the time sequence to obtain the harmful gas spreading trend. The acquisition time corresponding to the smoke concentration is the time when the smoke sensor acquires the smoke concentration. The preset building diagram is a two-dimensional building diagram or a three-dimensional building diagram.

Further, comparing the smoke concentration maps according to time sequence to obtain the harmful gas spreading trend, including: and inputting the smoke concentration graph with the time sequence into a preset harmful gas spreading trend model to obtain a harmful gas spreading trend.

The preset harmful gas spreading trend model is obtained by the following steps: acquiring a plurality of smoke concentration graphs with spreading trend labels and time sequences; and inputting a plurality of smoke concentration maps with spreading trend labels and time sequences into a preset second neural network model for training to obtain a harmful gas spreading trend model.

In some embodiments, a three-dimensional building map is built in advance according to the building equal proportion, and the setting positions and directions of the sensors in the building are also synchronized in the three-dimensional building map. The smoke concentration of each smoke sensor is obtained. And simulating the smoke concentration obtained by each smoke sensor in a three-dimensional building graph to obtain a smoke concentration graph of the building.

Further, determining a flame propagation trend from the temperature value and the wavelength value, comprising: respectively acquiring the position and the direction of each temperature sensor; the temperature sensors are divided into a plurality of temperature direction groups according to the positions and the directions of the temperature sensors, and the temperature sensors of the temperature direction groups are respectively numbered. And according to the numbers of the temperature sensors, respectively forming temperature values corresponding to the temperature sensors in each temperature direction group into a temperature sequence. And determining the flame propagation trend according to the temperature trend and the wavelength value of the temperature sequence. Thus, due to the time delay of the fire, the temperature accompanied by the flame will show a certain rule, and the wavelength values will be different according to the different fire sizes. Therefore, the flame propagation trend can be accurately predicted through the change of temperature values and wavelength values at different positions.

Further, the position of the temperature sensor comprises the layer height of the temperature sensor; the direction of the temperature sensor is the direction corresponding to the position of the temperature sensor; dividing the temperature sensors into a plurality of temperature direction groups according to the positions and directions of the temperature sensors, including: the temperature sensors are divided into different second level groups. The temperature sensors in the same second-layer height group are located at the same layer height. The temperature sensors are divided into a plurality of temperature direction groups in each of the second-layer high groups.

In some embodiments, separating the temperature sensors into different second level groups includes: and under the condition that the layer height of the temperature sensor is the same as the layer height corresponding to the second layer height group, establishing a corresponding relation between the temperature sensor and the second layer height group.

In some embodiments, the grouping of the temperature sensors into a plurality of temperature direction groups in the second high-level group includes: and under the condition that the direction corresponding to the temperature direction group comprises the direction corresponding to the temperature sensor, establishing the corresponding relation between the temperature sensor and the temperature direction group. Wherein the same temperature sensor may belong to a plurality of different temperature direction groups.

Further, the temperature sensors of the temperature direction group are respectively numbered, and include: and the temperature sensors of the temperature direction groups are numbered sequentially according to the direction sequence corresponding to the temperature direction groups. Or, the temperature sensors of the temperature direction group are numbered sequentially in the reverse order of the direction sequence corresponding to the temperature direction group.

In some embodiments, the direction set corresponds to a direction in the southwest direction, and the temperature sensors are numbered sequentially according to the order in which the temperature sensors are placed from the south to the west. Or the direction corresponding to the direction group is southwest, and the temperature sensors are numbered in sequence according to the placement sequence of the temperature sensors from west to south.

Further, the temperature sensors of the temperature direction group are numbered sequentially in the direction order corresponding to the temperature direction group. Determining a flame propagation trend from the temperature profile and the wavelength values of the temperature sequence, comprising: and under the condition that the temperature trend of the temperature sequence is changed from small to large and the wavelength value is in a preset range, determining that the flame propagation trend is consistent with the direction sequence corresponding to the direction group where the temperature sequence is located, and the position of the flame propagation trend is the same as the layer height of the second layer height group corresponding to the direction group where the temperature sequence is located. And under the condition that the temperature trend of the temperature sequence is changed from large to small and the wavelength value is in a preset range, determining that the flame propagation trend is opposite to the direction sequence corresponding to the direction group in which the temperature sequence is positioned, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group in which the temperature sequence is positioned. Or, if the temperature sensors of the temperature direction group are numbered sequentially in the order opposite to the direction order corresponding to the temperature direction group. Determining a flame propagation trend from the temperature profile and the wavelength values of the temperature sequence, comprising: and under the condition that the temperature trend of the temperature sequence is changed from small to large and the wavelength value is in a preset range, determining that the flame propagation trend is opposite to the direction sequence corresponding to the direction group where the temperature sequence is located, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group where the temperature sequence is located. And under the condition that the temperature trend of the temperature sequence is changed from large to small and the wavelength value is in a preset range, determining that the flame propagation trend is consistent with the direction sequence corresponding to the direction group where the temperature sequence is located, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group where the temperature sequence is located. In this way, different flame spreading trends are determined according to the temperature trend of each temperature sequence, so that the flame spreading in which channel of the floor can be accurately judged.

Optionally, the temperature sensors of the temperature direction groups are numbered sequentially according to the direction sequence corresponding to the temperature direction groups. Determining a flame propagation trend from the temperature profile and the wavelength values of the temperature sequence, comprising: and under the condition that the temperature trend of the temperature sequence is changed from small to large and the wavelength value is in a preset range, determining that the flame propagation trend is consistent with the direction sequence corresponding to the direction group in which the temperature sequence is positioned. And under the condition that the temperature trend of the temperature sequence is changed from large to small and the wavelength value is in a preset range, determining that the flame propagation trend is opposite to the direction sequence corresponding to the direction group in which the temperature sequence is positioned.

Optionally, the fire spread trend includes a harmful gas spread trend and a flame spread trend; after the fire spreading trend is displayed according to the fire information, the method further comprises the following steps: and acquiring environment parameters corresponding to the preset escape channel routes respectively. And respectively determining the fire condition of each escape passage route. And respectively determining road blocking conditions of each escape passage route. And determining a target escape route according to the harmful gas spreading trend, the flame spreading trend, the environmental parameters, the fire condition and the road blockage condition. Therefore, according to the environment parameters, fire conditions, road blocking conditions and the spreading trend in the building, which correspond to each preset escape route in the building, the most suitable target escape route can be automatically and rapidly determined, so that a user can quickly escape, and the escape rate of the user is improved.

Optionally, each escape passage is provided with a camera respectively. Determining a fire condition of an escape route, comprising: and obtaining a channel picture shot by the camera. And inputting the channel picture into a preset fire model to obtain whether the escape channel route corresponding to the channel picture fires. Therefore, whether the escape passage route is on fire or not can be accurately judged through the preset fire model.

Further, a preset fire model is obtained by: a sample channel picture with a fire label is obtained. Fire tags are used to characterize a channel firing or a channel not firing. And inputting the sample channel picture with the fire label into a preset third neural network model for training to obtain a fire model.

Optionally, each escape passage is provided with a temperature sensor, respectively. Determining a fire condition of an escape route, comprising: and acquiring a temperature value of the temperature sensor. And under the condition that the temperature value is larger than a preset threshold value, determining that the escape passage route corresponding to the temperature sensor is on fire. Otherwise, the escape passage route corresponding to the temperature sensor does not fire.

Optionally, each escape passage is respectively provided with a camera; determining a road congestion condition of an escape route, comprising: and obtaining a channel picture shot by the camera. Inputting the channel picture into a preset blockage judging model to obtain whether blockage exists in the escape channel route corresponding to the channel picture. Therefore, whether the escape passage route is blocked or not can be accurately judged through the preset blockage judging model.

Further, a preset clogging judgment model is obtained by: and obtaining a sample channel picture with a jam label. The blockage flag is used to characterize whether a channel is blocked or unblocked. And inputting the sample channel picture with the blockage label into a preset fourth neural network model for training to obtain a blockage judging model.

Optionally, determining the target escape route according to the harmful gas spreading trend, the flame spreading trend, the environmental parameter, the fire condition and the road blockage condition, including: determining whether the environmental parameters corresponding to each escape channel route are qualified or not according to the environmental parameters; determining the escape route as an alternative escape route under the conditions that the corresponding environmental parameters of the escape route are qualified, the escape route does not fire, the escape route is not blocked, the escape route does not have a harmful gas spreading trend and the escape route does not have a flame spreading trend; determining the route length of each alternative escape route; and determining the alternative escape route corresponding to the shortest route length as a target escape route.

Further, the environmental parameter includes carbon dioxide concentration; determining whether the environment parameters corresponding to the escape path route are qualified according to the environment parameters, including: comparing the carbon dioxide concentration with a preset carbon dioxide concentration; under the condition that the carbon dioxide concentration is larger than the preset carbon dioxide concentration, determining that the environment parameters corresponding to the escape passage route are unqualified; otherwise, determining that the environment parameters corresponding to the escape passage route are qualified.

In some embodiments, there are multiple trends in the spread of harmful gases. Each harmful gas spreading trend comprises floors and spreading directions corresponding to the floors. For example: the harmful gas spreading trend U is spreading from east to west at 5 layers. The harmful gas spreading trend V is spreading from the west to the south at 4 layers. The escape passage route consists of a plurality of sections of passages, and the position direction of each section of passage is determined. Under the condition that the harmful gas spreading trend comprises the position direction of the channel, confirming that the escape channel route corresponding to the channel has the harmful gas spreading trend; otherwise, the escape channel route corresponding to the confirmation channel does not have the harmful gas spreading trend. For example: the direction of the position of the channel is 4 layers of the western direction. The harmful gas spread trend is spreading from the west to the south at 4 layers. The harmful gas spreading trend includes 4 layers of western medicine, namely the harmful gas spreading trend includes the position direction of the channel, and the harmful gas spreading trend exists in the escape channel route corresponding to the channel is confirmed.

In some embodiments, there are multiple flame spread tendencies. Each flame spread trend includes a floor and a spread direction corresponding to the floor. For example: the flame propagation trend W is spread from east to west at 5 layers. The flame propagation trend Z is from the west to the south at 3 layers. The escape passage route consists of a plurality of sections of passages, and the position direction of each section of passage is determined. Under the condition that the flame spreading trend comprises the position direction of the channel, confirming that the flame spreading trend exists in the escape channel route corresponding to the channel; otherwise, confirming that the escape channel route corresponding to the channel does not have flame spreading trend. For example: the direction of the position of the channel is 4 layers of the western direction. The flame propagation trend is from the west to the south at 4 layers. The absence of the flame spreading trend comprises 4 layers of western medicine, namely the absence of the flame spreading trend comprises the position direction of the channel, and the absence of the flame spreading trend in the escape channel route corresponding to the channel is confirmed.

Optionally, after determining the target escape route according to the harmful gas spreading trend, the flame spreading trend, the environmental parameter, the fire condition and the road blockage condition, the method further comprises: and displaying the target escape route to the user. Thus, the target escape route is displayed to the user, so that the user can know the target escape route conveniently.

In some embodiments, the event type further includes fire performance. Fire performance is determined by: and obtaining various fire control influencing factors corresponding to the unit to be detected. And determining weight factors respectively corresponding to the fire control influence factors. And calculating according to each fire control influence factor and each weight factor by using a second preset algorithm, and determining the fire control performance of the unit to be detected according to the calculation result.

Optionally, acquiring a fire control influencing factor corresponding to the unit to be detected includes: and obtaining the unit name and the unit address of the unit to be detected. And carrying out table lookup operation on the unit names and the unit addresses by using a preset influence factor database to obtain fire control influence factors which are corresponding to the unit names and the unit addresses together. The influence factor database stores the corresponding relation among the unit names, the unit addresses and the fire control influence factors. In this way, the company may be moved away from the original address and the address may not be changed in time, so that the fire control influencing factors of the unit may be more accurately obtained by the unit name and the unit address.

Optionally, the fire control influencing factors include: the building structure fire protection level, the building design service life and the actual service life ratio, the use condition of the fire-fighting equipment and the fire-fighting system, the hidden danger condition of the fire-fighting equipment and the fire-fighting system, the storage condition of the building, the alarm condition error report rate of the fire-fighting equipment and the fire-fighting system, the personnel training condition of the fire-fighting equipment and the fire-fighting system, the on-duty rate of the fire-fighting security personnel, the fire-fighting task completion condition of the fire-fighting security personnel, the periodic fire-fighting inspection completion execution rate, the fire-fighting emergency plan programming completion rate, the fire-fighting emergency plan exercise completion execution rate and the unit personnel fire-fighting knowledge skill training condition.

In some embodiments, fire apparatus and fire system use cases, such as: the utilization rate of the fire-fighting equipment and the fire-fighting system, the integrity rate of the fire-fighting equipment and the fire-fighting system, the failure maintenance completion rate of the fire-fighting equipment and the fire-fighting system, the online rate and the offline rate of the fire-fighting equipment, and the rejection period expiration rate of the fire-fighting equipment and the fire-fighting system. Fire equipment and fire system hidden trouble conditions, for example: the fire control management hidden danger rate, the fire control related area or part potential safety hazard rate, the related hidden danger rectifying completion rate and the overdue rate. Conditions stored in the building, such as: and the storage rate of dangerous chemical products and explosive products. Wherein, the storage rate of the dangerous chemicals and the explosive substances is that the quantity of the dangerous chemicals and the explosive substances accounts for the total quantity of the objects in the building. Fire equipment and fire system personnel training situations, such as: the fire-fighting equipment and the fire-fighting system use the training completion rate, and the fire-fighting equipment and the fire-fighting system use the training standard rate. Fire safety personnel fire task completion, for example: the maintenance task completion rate, the maintenance task overdue rate, the maintenance task completion qualification rate, the maintenance task completion quality level, the nuclear alarm task completion rate, the nuclear alarm task overdue rate, the nuclear alarm task completion qualification rate, the nuclear alarm task completion quality level, the inspection task completion rate, the inspection task overdue rate, the inspection task completion qualification rate, the inspection task completion quality level and the like. Training conditions for fire knowledge skills of employees in units, such as: standard rate and completion rate of training fire knowledge skills of unit staff.

Optionally, determining a weight factor corresponding to the fire control influencing factor includes: performing table lookup operation on fire control influence factors by using a preset weight database to obtain weight factors corresponding to the fire control influence factors; the weight database stores the corresponding relation between the fire control influencing factors and the weight factors.

In some embodiments, the unit name is obtained as AA company and the unit address is BB address. Using a preset influencing factor database to perform table lookup operation on the 'AA company' and the 'BB address', and obtaining fire control influencing factors which are corresponding to the 'AA company' and the 'BB address', for example: the fire rating of the building structure is 1 level. The use condition of the fire-fighting equipment and the fire-fighting system is that the use ratio of the fire-fighting equipment and the fire-fighting system is 90 percent. And (3) carrying out table lookup operation on the building structure fire grade by using a preset weight database to obtain the weight factor corresponding to the building structure fire grade of 0.4. And (3) performing table lookup operation on the utilization rate of the fire-fighting equipment and the fire-fighting system to obtain the weight factor corresponding to the utilization rate of the fire-fighting equipment and the fire-fighting system of 0.6.

Optionally, calculating according to each fire control influencing factor and each weight factor by using a second preset algorithm, and determining fire control performance of the unit to be detected according to a calculation result, including: calculating according to each fire control influence factor and each weight factor by using a second preset algorithm to obtain comprehensive evaluation of the unit to be detected; and determining the fire-fighting property of the unit to be detected according to the comprehensive evaluation of the unit to be detected.

Further, calculating according to each fire control influence factor and each weight factor by using a second preset algorithm to obtain comprehensive evaluation of the unit to be detected, including: multiplying each fire control influence factor by a weight factor corresponding to each fire control influence factor to obtain each value to be evaluated; and determining the sum of all the values to be evaluated as the comprehensive evaluation of the unit to be inspected.

In some embodiments, the fire influencing factors include: the fire-proof grade of the building structure, the execution rate of the regular fire-proof inspection completion and the execution rate of the fire-proof emergency plan exercise completion. The weight factor corresponding to the fire grade of the building structure is 0.7, the weight factor corresponding to the execution rate of the regular fire control inspection is 0.2, and the weight factor corresponding to the execution rate of the fire control emergency plan exercise is 0.1. And obtaining a to-be-evaluated value T1 by multiplying the fire resistance grade of the building structure by 0.7. The periodic fire control check completion execution rate x 0.2 is used to obtain a value to be evaluated T2. And obtaining a to-be-evaluated value T3 by multiplying the execution rate of the fire emergency plan exercise completion by 0.1. And calculating a to-be-evaluated value T1+ to-be-evaluated value T2+ to-be-evaluated value T3 to obtain the comprehensive evaluation of the to-be-detected unit.

Further, determining fire performance of the unit to be inspected according to comprehensive evaluation of the unit to be inspected, including: and carrying out table lookup operation on the comprehensive evaluation of the unit to be detected by utilizing a preset performance determination database to obtain the fire fighting performance corresponding to the comprehensive evaluation of the unit to be detected. The performance determining database stores the corresponding relation between the comprehensive evaluation of the unit to be detected and the fire-fighting performance.

In some embodiments, the fire performance of the unit under test is determined periodically, resulting in fire performance at different times. The fire-fighting performance in different periods is formed into a fire-fighting safety and health file. The fire safety and health files can be monthly fire safety and health files, quarterly fire safety and health files or annual fire safety and health files.

Optionally, after obtaining the fire control influencing factor corresponding to the unit to be detected, the method further includes: and respectively determining grade scores corresponding to the fire control influencing factors. And respectively determining improvement suggestions corresponding to the fire control influence factors according to the grade scores corresponding to the fire control influence factors, and displaying the improvement suggestions to the unit to be detected.

Further, determining a grade score corresponding to the fire control influencing factor includes: and acquiring fire control data corresponding to the fire control influencing factors. And carrying out table lookup operation on fire control factors and fire control data corresponding to the fire control factors by utilizing a preset grade grading database to obtain grade grading commonly corresponding to the fire control factors and the fire control data. The grade grading database stores fire control influencing factors, fire control data corresponding to the fire control influencing factors and corresponding relations among the grade grading data. In some embodiments, the fire data corresponding to the fire influencing factors, such as: the completion rate of the nuclear police task is 80%. Wherein 80% is fire data corresponding to the completion rate of the nuclear police task.

Optionally, determining the improvement suggestion corresponding to the fire control influencing factor according to the grade score corresponding to the fire control influencing factor includes: and carrying out table lookup operation on the fire control influence factors and the grade scores corresponding to the fire control influence factors by using a preset first suggestion database to obtain first improvement suggestions which are commonly corresponding to the fire control influence factors and the grade scores corresponding to the fire control influence factors. The first suggestion database stores fire control influencing factors, corresponding grade scores of the fire control influencing factors and corresponding relations among the first improvement suggestions.

Optionally, determining the improvement suggestion corresponding to the fire control influencing factor according to the grade score corresponding to the fire control influencing factor includes: and obtaining a historical score corresponding to the fire control influence factors. And determining the grading change trend according to the grade grading and the historical grading corresponding to the fire control influence factors. And determining a second improvement suggestion according to the grading change trend.

Further, determining a score change trend according to the grade score and the historical score corresponding to the fire control influence factor comprises: subtracting the historical scores from the grade scores to obtain score difference values; under the condition that the score difference value is negative, determining the score change trend as score reduction; under the condition that the score difference value is a positive number, determining the score change trend as score rising; and in the case of a score difference value of 0, determining the score change trend as the score unchanged.

Further, determining a second improvement suggestion based on the score trend comprises: and carrying out table lookup operation on the scoring variation trends corresponding to the fire control influence factors and the fire control influence factors by using a preset second suggestion database to obtain second improvement suggestions commonly corresponding to the scoring variation trends corresponding to the fire control influence factors and the fire control influence factors. The second suggestion database stores the fire control influencing factors, the scoring change trend corresponding to the fire control influencing factors and the corresponding relation between the second improvement suggestions.

Further, the improvement suggestion includes a first improvement suggestion and/or a second improvement suggestion; displaying the improvement suggestion to the unit under test, comprising: and sending the improvement suggestion to the user terminal corresponding to the unit to be detected, and triggering the user terminal to display the improvement suggestion.

Optionally, after the fire performance is displayed to the user, the method further comprises: and feeding back the rectifying result in response to the input instruction of the user. Or, obtaining the correction result input by the user.

As shown in conjunction with fig. 3, an embodiment of the present disclosure provides another method for patrol management, including:

in step S201, the electronic device obtains first location information of a fire occurrence point and second location information of a plurality of patrol personnel.

Step S202, the electronic equipment determines traffic information between each patrol personnel and each fire occurrence point according to the first position information and the second position information.

And step S203, the electronic equipment determines a target patrol terminal according to the traffic information.

Step S204, the electronic equipment sends alarm information corresponding to the fire occurrence point to the target patrol terminal.

Step S205, the target inspection terminal displays warning information and responds to a first submitting instruction of a user to confirm whether a fire occurrence point is a real fire.

Step S206, the target patrol terminal sends whether the fire occurrence point is a real fire to the electronic equipment.

In step S207, the electronic device obtains the fire information corresponding to the fire point when the fire point is a real fire.

Step S208, the electronic equipment determines event types according to the fire information; an emergency plan is determined based on the event type.

By adopting the method for patrol management provided by the embodiment of the disclosure, the first position information of the fire occurrence point and the second position information of a plurality of patrol personnel are acquired through the electronic equipment. And determining the passing information between each patrol personnel and the fire occurrence point according to the first position information and the second position information. And determining the target inspection terminal according to the traffic information. And sending alarm information corresponding to the fire occurrence point to the target patrol terminal. The target inspection terminal displays warning information and responds to a first submitting instruction of a user to confirm whether a fire occurrence point is a real fire. And simultaneously, whether the fire occurrence point is a real fire or not is sent to the electronic equipment. And under the condition that the fire occurrence point is a real fire, acquiring fire information corresponding to the fire occurrence point by the electronic equipment. The event type is determined from the fire information. An emergency plan is determined based on the event type. Therefore, whether the fire occurrence point is a real fire or not is determined, and fire resource waste caused by the fact that the fire occurrence point is not the real fire can be avoided. The corresponding emergency plan is automatically determined by integrating various event types according to the event type to which the fire point belongs, and the fire expert can be assisted to quickly determine the corresponding emergency plan of the fire point, so that the efficiency of determining the emergency plan is improved. Can timely handle fire under the circumstances of avoiding fire control resource waste, reduce the conflagration loss.

As shown in conjunction with fig. 4, an embodiment of the present disclosure provides yet another method for patrol management, including:

in step S301, the electronic device obtains first location information of a fire occurrence point and second location information of a plurality of patrol personnel.

In step S302, the electronic device determines traffic information between each patrol personnel and the fire occurrence point according to the first position information and the second position information.

Step S303, the electronic equipment determines a target patrol terminal according to the traffic information.

Step S304, the electronic equipment sends alarm information corresponding to the fire occurrence point to the target patrol terminal.

Step S305, the target inspection terminal displays warning information and responds to a first submitting instruction of a user to confirm whether a fire occurrence point is a real fire.

And step S306, the target inspection terminal sends whether the fire occurrence point is a real fire to the electronic equipment.

Step S307, the electronic device obtains the fire information corresponding to the fire point when the fire point is a real fire.

Step S308, the electronic equipment displays a fire spreading trend according to the fire information; the fire spread trend includes a flame spread trend and a harmful gas spread trend.

Step S309, the electronic device obtains environmental parameters corresponding to the preset escape routes respectively; respectively determining fire conditions of each escape passage route; respectively determining road blocking conditions of each escape passage route; and determining a target escape route according to the harmful gas spreading trend, the flame spreading trend, the environmental parameters, the fire condition and the road blockage condition.

By adopting the method for patrol management provided by the embodiment of the disclosure, under the condition that the target patrol terminal determines that the fire occurrence point is a real fire, the fire spreading trend is displayed according to the fire information, and the electronic equipment acquires the environmental parameters corresponding to the preset escape channel routes respectively; respectively determining fire conditions of each escape passage route; respectively determining road blocking conditions of each escape passage route; and determining a target escape route according to the harmful gas spreading trend, the flame spreading trend, the environmental parameters, the fire condition and the road blockage condition. The device can provide a proper target escape route for people at the fire occurrence point, thereby increasing the escape probability of users.

As shown in conjunction with fig. 5, an embodiment of the present disclosure provides a system 5 for patrol management, comprising: a patrol dispatch platform 6 and a target patrol terminal 7. The inspection dispatch platform 6 is configured to acquire first position information of a fire occurrence point and second position information of a plurality of inspection personnel. The first location information includes: the layer height of the fire point; the second position information includes: the level of the inspection personnel is high. Determining passing information between each patrol personnel and each fire occurrence point according to the first position information and the second position information; and determining a target inspection terminal according to the traffic information, and sending alarm information corresponding to the fire occurrence point to the target inspection terminal. The target patrol terminal 7 is configured to display warning information.

The system for patrol management provided by the embodiment of the disclosure comprises: and acquiring the first position information of the fire occurrence point and the second position information of a plurality of patrol personnel through the patrol dispatch platform. And determining the passing information between each patrol personnel and the fire occurrence point according to the first position information and the second position information. And determining a target inspection terminal according to the traffic information, and sending alarm information corresponding to the fire occurrence point to the target inspection terminal. And the target inspection terminal displays warning information. Thus, there is often a rapid spread characteristic due to the fire. Therefore, it is required that the inspector can rapidly confirm whether the fire actually occurs, thereby reducing the loss caused by the fire. Through the traffic information between each patrol personnel and the fire occurrence point respectively, the police information can be conveniently pushed to the proper patrol personnel, so that the patrol personnel can confirm the authenticity of the fire as soon as possible.

Optionally, the target inspection terminal is further configured to confirm whether the fire occurrence point is a real fire to the inspection dispatch platform in response to the first submission instruction of the user.

As shown in connection with fig. 6, an embodiment of the present disclosure provides an electronic device 8 including a processor (processor) 9 and a memory (memory) 10. Optionally, the apparatus may further comprise a communication interface (Communication Interface) 11 and a bus 12. The processor 9, the communication interface 11 and the memory 10 may communicate with each other via a bus 12. The communication interface 11 may be used for information transmission. The processor 9 may call logic instructions in the memory 10 to perform the method for patrol management of the above-described embodiments.

Alternatively, the electronic device is a computer or a server.

By adopting the electronic equipment provided by the embodiment of the disclosure, the first position information of the fire occurrence point and the second position information of a plurality of patrol personnel are obtained. The first location information includes: the fire point is at the high layer. The second position information includes: the level of the inspection personnel is high. And determining the passing information between each patrol personnel and the fire occurrence point according to the first position information and the second position information. And determining the target inspection terminal according to the traffic information. And sending alarm information corresponding to the fire occurrence point to the target inspection terminal, and triggering the target inspection terminal to display the alarm information. Thus, there is often a rapid spread characteristic due to the fire. Therefore, it is required that the inspector can rapidly confirm whether the fire actually occurs, thereby reducing the loss caused by the fire. Through the traffic information between each patrol personnel and the fire occurrence point respectively, the police information can be conveniently pushed to the proper patrol personnel, so that the patrol personnel can confirm the authenticity of the fire as soon as possible.

Further, the logic instructions in the memory 10 described above may be implemented in the form of software functional units and may be stored in a computer readable storage medium when sold or used as a stand alone product.

The memory 10 is used as a computer readable storage medium for storing a software program, a computer executable program, such as program instructions/modules corresponding to the methods in the embodiments of the present disclosure. The processor 9 executes the functional applications and data processing by running the program instructions/modules stored in the memory 10, i.e. implements the method for patrol management in the above-described embodiments.

Memory 10 may include a storage program area that may store an operating system, at least one application program required for functionality, and a storage data area; the storage data area may store data created according to the use of the terminal device, etc. In addition, the memory 10 may include a high-speed random access memory, and may also include a nonvolatile memory.

Embodiments of the present disclosure provide a computer-readable storage medium storing computer-executable instructions configured to perform the above-described method for patrol management.

The disclosed embodiments provide a computer program product comprising a computer program stored on a computer readable storage medium, the computer program comprising program instructions which, when executed by a computer, cause the computer to perform the above-described method for patrol management.

The computer readable storage medium may be a transitory computer readable storage medium or a non-transitory computer readable storage medium.

Embodiments of the present disclosure may be embodied in a software product stored on a storage medium, including one or more instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of a method according to embodiments of the present disclosure. And the aforementioned storage medium may be a non-transitory storage medium including: a plurality of media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, or an optical disk, or a transitory storage medium.

The above description and the drawings illustrate embodiments of the disclosure sufficiently to enable those skilled in the art to practice them. Other embodiments may involve structural, logical, electrical, process, and other changes. The embodiments represent only possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in, or substituted for, those of others. Moreover, the terminology used in the present application is for the purpose of describing embodiments only and is not intended to limit the claims. As used in the description of the embodiments and the claims, the singular forms "a," "an," and "the" (the) are intended to include the plural forms as well, unless the context clearly indicates otherwise. Similarly, the term "and/or" as used in this application is meant to encompass any and all possible combinations of one or more of the associated listed. Furthermore, when used in this application, the terms "comprises," "comprising," and/or "includes," and variations thereof, mean that the stated features, integers, steps, operations, elements, and/or components are present, but that the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof is not precluded. Without further limitation, an element defined by the phrase "comprising one …" does not exclude the presence of other like elements in a process, method or apparatus comprising such elements. In this context, each embodiment may be described with emphasis on the differences from the other embodiments, and the same similar parts between the various embodiments may be referred to each other. For the methods, products, etc. disclosed in the embodiments, if they correspond to the method sections disclosed in the embodiments, the description of the method sections may be referred to for relevance.

Those of skill in the art will appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, or combinations of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the solution. The skilled artisan may use different methods for each particular application to achieve the described functionality, but such implementation should not be considered to be beyond the scope of the embodiments of the present disclosure. It will be clearly understood by those skilled in the art that, for convenience and brevity of description, specific working procedures of the above-described systems, apparatuses and units may refer to corresponding procedures in the foregoing method embodiments, which are not repeated herein.

In the embodiments disclosed herein, the disclosed methods, articles of manufacture (including but not limited to devices, apparatuses, etc.) may be practiced in other ways. For example, the apparatus embodiments described above are merely illustrative, and for example, the division of the units may be merely a logical function division, and there may be additional divisions when actually implemented, for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. In addition, the coupling or direct coupling or communication connection shown or discussed with each other may be through some interface, device or unit indirect coupling or communication connection, which may be in electrical, mechanical or other form. The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units may be selected according to actual needs to implement the present embodiment. In addition, each functional unit in the embodiments of the present disclosure may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit.

The flowcharts and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to embodiments of the present disclosure. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). In some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. In the description corresponding to the flowcharts and block diagrams in the figures, operations or steps corresponding to different blocks may also occur in different orders than that disclosed in the description, and sometimes no specific order exists between different operations or steps. For example, two consecutive operations or steps may actually be performed substantially in parallel, they may sometimes be performed in reverse order, which may be dependent on the functions involved. Each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

Claims (9)

1. The method for patrol management is characterized in that a plurality of locators are arranged in a building, and coordinate information is prestored in each locator; the coordinate information is used for representing the coordinates of the positioning instrument in the building; under the condition that the alternative inspection terminal is in the communication range of the positioning instrument, the positioning instrument communicates with the alternative inspection terminal, and the positioning instrument acquires the equipment identification of the alternative inspection terminal; the method for patrol management comprises the following steps:

acquiring first position information of a fire occurrence point and second position information of a plurality of patrol personnel; the first location information includes: the layer height of the fire point; the second position information includes: the layer height of the patrol personnel;

determining passing information between each patrol personnel and each fire occurrence point according to the first position information and the second position information;

determining a target inspection terminal according to the traffic information;

sending alarm information corresponding to the fire occurrence point to the target inspection terminal, and triggering the target inspection terminal to display the alarm information;

acquiring second position information of the patrol personnel, including: acquiring a target identifier sent by a positioning instrument; the target identifier is an equipment identifier of an alternative patrol terminal positioned in the communication range of the locator; the coordinate information of the positioning instrument is determined to be the second position information of the patrol personnel corresponding to the target mark sent by the positioning instrument;

After sending the warning condition information corresponding to the fire condition occurrence point to the target inspection terminal, the method further comprises the following steps: acquiring whether a fire occurrence point sent by a target inspection terminal is a real fire;

after obtaining whether the fire occurrence point sent by the target inspection terminal is a real fire, the method further comprises the following steps: acquiring fire information corresponding to a fire point under the condition that the fire point is a real fire;

the fire information includes: the smoke concentration measured by the smoke sensors, the temperature measured by the temperature sensors and the wavelength measured by the light sensors;

after acquiring the fire information, the method further comprises the following steps: determining a harmful gas spreading trend according to the smoke concentration; determining a flame propagation trend according to the temperature value and the wavelength value; the harmful gas spreading trend and the flame spreading trend are displayed to a user as the fire spreading trend;

determining a flame propagation trend from the temperature value and the wavelength value, comprising: respectively acquiring the position and the direction of each temperature sensor; dividing the temperature sensors into a plurality of temperature direction groups according to the positions and the directions of the temperature sensors, and respectively numbering the temperature sensors of the temperature direction groups; according to the numbers of the temperature sensors, temperature values corresponding to the temperature sensors in each temperature direction group are formed into a temperature sequence; determining a flame propagation trend according to the temperature trend and the wavelength value of the temperature sequence; sequentially numbering the temperature sensors of the temperature direction groups according to the direction sequence corresponding to the temperature direction groups; determining a flame propagation trend from the temperature profile and the wavelength values of the temperature sequence, comprising: when the temperature trend of the temperature sequence is changed from small to large and the wavelength value is in a preset range, determining that the flame propagation trend is consistent with the direction sequence corresponding to the direction group in which the temperature sequence is positioned, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group in which the temperature sequence is positioned; and under the condition that the temperature trend of the temperature sequence is changed from large to small and the wavelength value is in a preset range, determining that the flame propagation trend is opposite to the direction sequence corresponding to the direction group in which the temperature sequence is positioned, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group in which the temperature sequence is positioned.

2. The method of claim 1, wherein the traffic information comprises a target traffic distance; determining traffic information between the patrol personnel and the fire occurrence point according to the first position information and the second position information, including:

determining whether the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel;

under the condition that the layer height of the fire occurrence point is consistent with the layer height of the patrol personnel, determining a first horizontal distance between the fire occurrence point and the patrol personnel, and determining the first horizontal distance as a target passing distance; and/or the number of the groups of groups,

and under the condition that the layer height of the fire occurrence point is inconsistent with the layer height of the patrol personnel, determining a second horizontal distance and a vertical distance between the fire occurrence point and the patrol personnel, and determining the sum of the second horizontal distance and the vertical distance as a target passing distance.

3. The method of claim 2, wherein determining a first horizontal distance between the point of fire occurrence and the inspector comprises:

acquiring a plane building diagram corresponding to a fire occurrence point;

constructing a first communication line with a starting point being the position of a patrol personnel and a finishing point being the fire occurrence point on the plane building diagram;

determining a first communication line with the shortest length as a first target routing inspection route;

And determining the length corresponding to the first target inspection route as a first horizontal distance between the fire occurrence point and the inspection personnel.

4. The method of claim 2, wherein determining the vertical distance between the point of fire occurrence and the inspector comprises:

calculating the layer height of the fire occurrence point minus the layer height of the patrol personnel to obtain the relative layer height;

and calculating the relative floor height multiplied by the preset floor height to obtain the vertical distance between the fire occurrence point and the patrol personnel.

5. The method of claim 2, wherein determining a second horizontal distance between the point of fire occurrence and the inspector comprises:

acquiring a plane building diagram corresponding to a fire occurrence point;

constructing a second communication line with a starting point of the position of the patrol personnel and a finishing point of the position of the patrol personnel in the plane building diagram;

constructing a third communication line with a starting point being the position of the stair opening and a finishing point being the fire occurrence point on the plane building diagram;

determining a second communication line with the shortest length and a third communication line with the shortest length as a second target inspection route;

and determining the sum of the lengths of the second target inspection routes as a second horizontal distance between the fire occurrence point and the inspection personnel.

6. The method according to any one of claims 2 to 5, wherein the traffic information further comprises a traffic time; determining traffic information between each patrol personnel and the fire occurrence point according to the first position information and the second position information, and further comprising:

user information of each patrol personnel is respectively obtained;

and respectively determining the passing time of each patrol personnel by using the user information corresponding to the patrol personnel and the target passing distance corresponding to the patrol personnel.

7. The system for inspection management is characterized in that a plurality of locators are arranged in a building, and coordinate information is pre-stored in each locator; the coordinate information is used for representing the coordinates of the positioning instrument in the building; under the condition that the alternative inspection terminal is in the communication range of the positioning instrument, the positioning instrument communicates with the alternative inspection terminal, and the positioning instrument acquires the equipment identification of the alternative inspection terminal; the system for patrol management comprises:

the inspection dispatch platform is configured to acquire first position information of a fire occurrence point and second position information of a plurality of inspection personnel; the first location information includes: the layer height of the fire point; the second position information includes: the layer height of the patrol personnel; determining passing information between each patrol personnel and each fire occurrence point according to the first position information and the second position information; determining a target inspection terminal according to the traffic information, and sending alarm information corresponding to the fire occurrence point to the target inspection terminal; wherein, obtain the second position information of inspection personnel, include: acquiring a target identifier sent by a positioning instrument; the target identifier is an equipment identifier of an alternative patrol terminal positioned in the communication range of the locator; the coordinate information of the positioning instrument is determined to be the second position information of the patrol personnel corresponding to the target mark sent by the positioning instrument; after sending the warning condition information corresponding to the fire condition occurrence point to the target inspection terminal, the method further comprises the following steps: acquiring whether a fire occurrence point sent by a target inspection terminal is a real fire; after obtaining whether the fire occurrence point sent by the target inspection terminal is a real fire, the method further comprises the following steps: acquiring fire information corresponding to a fire point under the condition that the fire point is a real fire; the fire information includes: the smoke concentration measured by the smoke sensors, the temperature measured by the temperature sensors and the wavelength measured by the light sensors; after acquiring the fire information, the method further comprises the following steps: determining a harmful gas spreading trend according to the smoke concentration; determining a flame propagation trend according to the temperature value and the wavelength value; the harmful gas spreading trend and the flame spreading trend are displayed to a user as the fire spreading trend;

The target inspection terminal is configured to display warning information;

determining a flame propagation trend from the temperature value and the wavelength value, comprising: respectively acquiring the position and the direction of each temperature sensor; dividing the temperature sensors into a plurality of temperature direction groups according to the positions and the directions of the temperature sensors, and respectively numbering the temperature sensors of the temperature direction groups; according to the numbers of the temperature sensors, temperature values corresponding to the temperature sensors in each temperature direction group are formed into a temperature sequence; determining a flame propagation trend according to the temperature trend and the wavelength value of the temperature sequence; sequentially numbering the temperature sensors of the temperature direction groups according to the direction sequence corresponding to the temperature direction groups; determining a flame propagation trend from the temperature profile and the wavelength values of the temperature sequence, comprising: when the temperature trend of the temperature sequence is changed from small to large and the wavelength value is in a preset range, determining that the flame propagation trend is consistent with the direction sequence corresponding to the direction group in which the temperature sequence is positioned, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group in which the temperature sequence is positioned; and under the condition that the temperature trend of the temperature sequence is changed from large to small and the wavelength value is in a preset range, determining that the flame propagation trend is opposite to the direction sequence corresponding to the direction group in which the temperature sequence is positioned, and the position of the flame propagation trend is the same as the layer height of the second layer high group corresponding to the direction group in which the temperature sequence is positioned.

8. An electronic device comprising a processor and a memory storing program instructions, wherein the processor is configured, when executing the program instructions, to perform the method for patrol management of any one of claims 1 to 6.

9. A storage medium storing program instructions which, when executed, perform the method for patrol management of any one of claims 1 to 6.