CN108960513B

CN108960513B - Intelligent identification and monitoring system for major hazard source of construction project

Info

Publication number: CN108960513B
Application number: CN201810735612.3A
Authority: CN
Inventors: 王晓明; 陈芳; 施景桓
Original assignee: Zhonglian Luhai Group Co ltd
Current assignee: Zhonglian Luhai Group Co ltd
Priority date: 2018-07-06
Filing date: 2018-07-06
Publication date: 2022-09-06
Anticipated expiration: 2038-07-06
Also published as: CN108960513A

Abstract

The invention discloses an intelligent identification and monitoring system for major hazard sources of construction engineering; the system includes network switch, database server, the camera of subregion, visits the display end, still includes: the information acquisition terminal is used for acquiring production state information; the data uploading module is used for uploading basic information of the dangerous operation place to the database server; the video monitoring module is used for managing monitoring videos of real-time conditions of all dangerous operation points; the situation analysis module is used for drawing a real-time situation curve graph on the access display end; the trend analysis and prediction module is used for analyzing the dangerous situation conditions of a specific dangerous place in a period of time and drawing a prediction situation curve graph on an access display end; calling a management module; according to the invention, the data are integrated, the safety production situation of the whole engineering surface is evaluated, and the overall situation of the safety production is grasped; and the calling management module issues calling commands according to the distribution weight sequence to improve the comprehensive efficiency of emergency treatment.

Description

Intelligent identification and monitoring system for major hazard source of construction project

Technical Field

The invention relates to the field of project management, in particular to a high-comprehensiveness intelligent identification and monitoring system for major hazard sources of construction engineering.

Background

A significant source of danger in the general sense is a unit which produces, handles, uses or stores hazardous materials, either permanently or temporarily, with a number of hazardous materials equal to or exceeding a critical amount. The unit refers to a (set of) production device, facility or place, or a plurality of (set of) production devices, facilities or places which belong to a production and operation unit and have edge distance less than 500 m; major hazard sources of construction engineering have wider meanings, and a dangerous building, dangerous equipment or dangerous operation environment also belongs to a hazard source; comprehensive identification, monitoring and treatment of major hazard sources of construction projects have been a major issue.

Disclosure of Invention

The technical scheme adopted by the invention for solving the technical problem is as follows: the system of the invention comprises a network switch, a database server for integrated management, a camera for zoning, an access display end for administrator control and query, and also comprises: the information acquisition terminal is used for acquiring production state information, screening out basic information of a dangerous operation place and carrying out wireless communication with the data uploading module through a network switch; the production state information comprises production place information, production order maker information, production quantitative information, production violation information, production hidden danger information and production special equipment information; the data uploading module is interacted with the database server and is used for uploading basic information of the dangerous operation place to the database server, wherein the basic information of the dangerous operation place comprises a dangerous point name, a dangerous level, a dangerous property, a dangerous monitoring standard and a dangerous point geographical position; the video monitoring module is wirelessly connected with the cameras of each subarea and interacts with the database server, and is used for managing the monitoring videos of the real-time conditions of each dangerous operation point, acquiring the real-time videos from the video cameras of each dangerous operation point and storing the videos into the database server; the situation analysis module is interacted with the database server and also interacted with the access display terminal, and is used for taking the acquired basic information of the dangerous work place as input, analyzing the current situation of the dangerous place according to an algorithm, drawing a real-time situation curve graph on the access display terminal by taking a geographic map data model as a reference, and marking and displaying red, yellow and green three colors of different dangerous places as three danger levels; and the trend analysis and prediction module is interacted with the database server and the access display terminal, is used for analyzing the dangerous situation conditions of a specific dangerous place in a period of time, draws a prediction situation curve graph on the access display terminal by taking the time coordinate data model as a reference, and provides a decision basis for the next safety production work.

Furthermore, the information acquisition end is a fixed terminal machine arranged at different project area points, and the fixed terminal machine at least comprises an information input unit, a singlechip and a communication interface.

In addition, the information acquisition end is used for the prisoner to mark the danger source on the geographical position information map at the information input unit, the danger source at least marks map coordinate information and danger source information, and the system records an acquisition log.

Further, the system further comprises: the emergency processing calling information terminal is in radio communication with the calling management module, and the calling management module is in interaction with the data server; the emergency equipment is distributed at each construction project area point and is used for handling danger or assisting in handling danger, and the emergency equipment comprises vehicles and special equipment; the emergency processing calling information terminal is distributed at each construction project area point and in an office area of a processor, and is used for receiving a calling command issued by the calling management module; and the calling management module distributes calling personnel and calling vehicles according to the specific information content of each dangerous place and issues calling commands to the emergency treatment calling information terminal according to the distribution weight sequence.

Furthermore, the emergency processing calling information terminal comprises a mobile phone APP and a wireless terminal.

Furthermore, the calling management module issues calling commands according to the distribution weight sequence, specifically, firstly, ID is distributed to the emergency equipment, and ID is distributed to each emergency personnel; then, respectively distributing outer layer weights to the three data of the danger level, the danger property and the geographical position of the danger point, wherein the outer layer weight of the danger level is X, the outer layer weight of the danger property is Y, the outer layer weight of the geographical position of the danger point is Z, and X + Y + Z is 1; the hazard level is graded with the attached weights again: 1/2/3/4/5/6/7/8/9/10, the hazard property is re-weighted by specific type: 1/2/3/4/5/6/7/8/9/10, the geographical location of the hazard point is re-weighted by the distance of the location from the emergency personnel: 1/2/3/4/5/6/7/8/9/10, the weight corresponding to each dangerous place is the sum of X multiplied by the corresponding attached weight, Y multiplied by the corresponding attached weight and Z multiplied by the corresponding attached weight, each dangerous place is subjected to bubbling sequencing according to the corresponding weight, and a calling command is issued according to the sequencing, wherein the calling command comprises the ID information of the called emergency equipment, the ID information of the emergency personnel and the calling destination.

The method has the advantages that the method is used for information management of major hazard source analysis, identification and processing and method coping, and the safety production situation of the whole engineering surface is evaluated by integrating data, so that the overall situation of safety production is grasped, and an effective basis is provided for decision-making command of safety production; management departments or construction and supervision units at all levels can check the specific information of the danger source through accessing the display terminal, and the calling management module issues calling commands according to the distribution weight sequence to improve the comprehensive efficiency of emergency treatment.

Drawings

FIG. 1 is a schematic diagram of the system connection architecture of the present invention.

FIG. 2 is a plot of hazardous work site versus real-time situation. Wherein red (where red is shown in fig. 2 for clarity, the letter a is written in the red mark area in fig. 2) represents a place with the highest risk level, yellow (where yellow is shown in fig. 2 for clarity, the letter B is written in the yellow mark area in fig. 2) represents a place with a medium risk level, and green (where green is shown in fig. 2 for clarity, the letter C is written in the green mark area in fig. 2) represents a place with the lowest risk level; the non-color marked areas represent areas without danger or areas without construction work.

Fig. 3 is a dangerous work place-prediction situation graph. Wherein the abscissa represents the predicted period in days; the hazard degree represented by the ordinate is a negative number, and a smaller negative number indicates a greater hazard degree, and a zero hazard degree indicates a non-hazardous state.

Detailed Description

In the embodiment shown in fig. 1, the system of the present invention includes a network switch, a database server for integrated management, a partitioned camera, an access display end for administrator control and query, and further includes: the information acquisition terminal is used for acquiring production state information, screening out basic information of a dangerous operation place and carrying out wireless communication with the data uploading module through a network switch; the production state information comprises production location information, production personnel information, production quantitative information, production violation information, production hidden danger information and production special equipment information; the data uploading module is interacted with the database server and is used for uploading basic information of the dangerous operation place to the database server, and the basic information of the dangerous operation place comprises a dangerous point name, a dangerous level, a dangerous property, a dangerous monitoring standard and a dangerous point geographical position; the video monitoring module is wirelessly connected with the cameras of each subarea and interacts with the database server, and is used for managing the monitoring videos of the real-time conditions of each dangerous operation point, acquiring the real-time videos from the video cameras of each dangerous operation point and storing the videos into the database server; the situation analysis module is interacted with the database server and also interacted with the access display terminal, and is used for taking the acquired basic information of the dangerous work place as input, analyzing the current situation of the dangerous place according to an algorithm, drawing a real-time situation curve graph on the access display terminal by taking a geographic map data model as a reference, and marking and displaying red, yellow and green three colors of different dangerous places as three danger levels; and the trend analysis and prediction module is interacted with the database server and the access display terminal, is used for analyzing the dangerous situation conditions of a specific dangerous place in a period of time, draws a prediction situation curve graph on the access display terminal by taking the time coordinate data model as a reference, and provides a decision basis for the next safety production work.

The information acquisition end is a fixed terminal machine arranged at different project area points, and the fixed terminal machine at least comprises an information input unit, a singlechip and a communication interface. In addition, the information acquisition end is used for monitoring personnel to identify a danger source on the geographical position information map in the information input unit, the danger source at least marks map coordinate information and danger source information, and the system records an acquisition log.

In the implementation, or the information acquisition end is a mobile terminal, and the mobile terminal at least comprises a wireless uploading unit, an information recording unit and a singlechip.

The system of the present invention further comprises: the emergency processing calling information terminal is in radio communication with the calling management module, and the calling management module is in interaction with the data server; the emergency equipment is distributed at each construction project area point and is used for handling danger or assisting in handling danger, and the emergency equipment comprises vehicles and special equipment; the emergency processing calling information terminal is distributed at each construction project area point and in an office area of a processor, and is used for receiving a calling command issued by the calling management module; the calling management module distributes calling personnel and calling vehicles according to the specific information content of each dangerous place and issues calling commands to the emergency treatment calling information terminal according to the distribution weight sequence; the emergency processing calling information terminal comprises a mobile phone APP and a wireless terminal.

The calling management module issues calling commands according to the distribution weight sequence, specifically the distribution sequence is as follows, firstly, an ID is distributed to emergency equipment, and an ID is distributed to each emergency personnel; then, respectively distributing outer layer weights to the three data of the danger level, the danger property and the geographical position of the danger point, wherein the outer layer weight of the danger level is X, the outer layer weight of the danger property is Y, the outer layer weight of the geographical position of the danger point is Z, and X + Y + Z is 1; the hazard level is graded with the attached weights again: 1/2/3/4/5/6/7/8/9/10, the hazard properties are subdivided into additional weights by specific type: 1/2/3/4/5/6/7/8/9/10, the geographical location of the hazard point is re-weighted by the distance of the location from the emergency personnel: 1/2/3/4/5/6/7/8/9/10, the weight corresponding to each dangerous place is the sum of X multiplied by the corresponding attached weight, Y multiplied by the corresponding attached weight and Z multiplied by the corresponding attached weight, each dangerous place is subjected to bubbling sequencing according to the corresponding weight, and a calling command is issued according to the sequencing, wherein the calling command comprises the ID information of the called emergency equipment, the ID information of the emergency personnel and the calling destination. In implementation, firstly, the information acquisition module acquires production state information including production site information, production personnel information, production quantitative information, production violation information, production hidden danger information and production special equipment information, and selects a proper data access type according to the actual situation of a dangerous operation place to acquire and butt joint dangerous point data. In implementation, the data uploading module uploads basic information of the dangerous work place to the database server, wherein the basic information comprises dangerous point names, dangerous levels, dangerous properties, dangerous monitoring standards and dangerous point geographic positions; in implementation, the video monitoring module acquires real-time videos from video cameras of all dangerous operation points and stores the videos into the database server.

The situation analysis module in implementation takes the acquired basic information of the dangerous operation places as input, analyzes the current situation of the dangerous places according to an algorithm, draws a real-time situation curve graph on an access display end by taking a geographic map data model as a reference, and marks and displays different dangerous places by taking red, yellow and green colors as three dangerous levels, wherein the real-time situation curve graph is shown in figure 2.

And the in-implementation trend analysis and prediction module is used for analyzing the dangerous situation conditions of a specific dangerous place in a period of time, and drawing a predicted situation curve graph on an access display terminal by taking the time coordinate data model as a reference. A predicted situation graph is shown in figure 3.

In implementation, the method is used for registration, identification and early warning calling of sub-project projects with high risk, monitoring of a risk source and artificial intelligence intervention; management departments at all levels can check the dangerous source distribution condition of each item in the jurisdiction through the system and count the dangerous sources; the construction and supervision unit can check the specific information of the dangerous source of the carried project through the system, and is beneficial to the responsible unit to carry out key supervision in a targeted manner.

It will be appreciated by those skilled in the art that the invention can be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The embodiments disclosed above are illustrative and not exclusive in all respects. All changes which come within the scope of or equivalence to the invention are intended to be embraced therein.

Claims

1. The utility model provides an intelligent discernment monitoring system of major hazard source of construction engineering, includes network switch, is used for the database server of integrated management, divides regional camera, is used for the administrator to control and the visit display terminal of inquiry, its characterized in that still includes:

the information acquisition terminal is used for acquiring production state information, screening out basic information of a dangerous operation place and carrying out wireless communication with the data uploading module through a network switch; the production state information comprises production place information, production order maker information, production quantitative information, production violation information, production hidden danger information and production special equipment information;

the data uploading module is interacted with the database server and is used for uploading basic information of the dangerous operation place to the database server, wherein the basic information of the dangerous operation place comprises a dangerous point name, a dangerous level, a dangerous property, a dangerous monitoring standard and a dangerous point geographical position;

the video monitoring module is wirelessly connected with the cameras of each subarea and interacts with the database server, and is used for managing the monitoring videos of the real-time conditions of each dangerous operation point, acquiring the real-time videos from the video cameras of each dangerous operation point and storing the videos into the database server;

the situation analysis module is interacted with the database server and also interacted with the access display terminal, and is used for taking the acquired basic information of the dangerous work place as input, analyzing the current situation of the dangerous place according to an algorithm, drawing a real-time situation curve graph on the access display terminal by taking a geographic map data model as a reference, and marking and displaying red, yellow and green three colors of different dangerous places as three danger levels;

the trend analysis and prediction module is interacted with the database server and the access display terminal, is used for analyzing the dangerous situation conditions of a specific dangerous place in a period of time, draws a prediction situation curve graph on the access display terminal by taking the time coordinate data model as a reference, and provides a decision basis for the next safety production work; the information acquisition end is a fixed terminal machine arranged at different project area points, and the fixed terminal machine at least comprises an information input unit, a singlechip and a communication interface; the information acquisition end is used for monitoring personnel to identify a dangerous source on the geographical position information map in the information input unit, the dangerous source at least marks map coordinate information and dangerous source information, and the system records an acquisition log; the emergency processing calling information terminal is in radio communication with the calling management module, and the calling management module is in interaction with the data server; the emergency equipment is distributed at each construction project area point and is used for handling danger or assisting in handling danger, and the emergency equipment comprises vehicles and special equipment; the emergency processing calling information terminal is distributed at each construction project area point and in an office area of a processor, and is used for receiving a calling command issued by the calling management module; the calling management module distributes calling personnel and calling vehicles according to the specific information content of each dangerous place and issues calling commands to the emergency treatment calling information terminal according to the distribution weight sequence; the calling management module issues calling commands according to the distribution weight sequence, and specifically comprises the following steps: firstly, an ID is allocated to emergency equipment, and an ID is allocated to each emergency personnel; then, respectively distributing outer layer weights to the three data of the danger level, the danger property and the geographical position of the danger point, wherein the outer layer weight of the danger level is X, the outer layer weight of the danger property is Y, the outer layer weight of the geographical position of the danger point is Z, and X + Y + Z is 1; the hazard level is graded with the attached weights again: 1/2/3/4/5/6/7/8/9/10, the hazard property is re-weighted by specific type: 1/2/3/4/5/6/7/8/9/10, the geographical location of the hazard point is re-weighted by the distance of the location from the emergency personnel: 1/2/3/4/5/6/7/8/9/10, the weight corresponding to each dangerous place is the sum of X multiplied by the corresponding attached weight, Y multiplied by the corresponding attached weight and Z multiplied by the corresponding attached weight, each dangerous place is subjected to bubbling sequencing according to the corresponding weight, and a calling command is issued according to the sequencing, wherein the calling command comprises the ID information of the called emergency equipment, the ID information of the emergency personnel and the calling destination.

2. The system for intelligently identifying and monitoring the major hazard source of the construction project according to claim 1, wherein the emergency treatment calling information terminal comprises a mobile phone APP and a wireless terminal.