CN111651491A - Data acquisition method based on mine holographic graph - Google Patents

Abstract

The invention provides a data acquisition method based on a mine holographic one-sheet, which is a solution method for reducing labor cost, realizing strong real-time and re-interaction and expanding by utilizing an RED-MOS system as a carrier of a mine application program, fusing heterogeneous information and heterogeneous networks of multiple systems of a mine enterprise and providing information services of the mine enterprise in the form of a holographic one-sheet. According to the invention, through deep mining of professional data of the mine enterprise, intercommunication and interconnection of personnel, systems, management, environment, equipment and the like are realized, transverse communication and longitudinal integration among the systems are realized, decision basis and intelligent dynamic management can be effectively provided for safety management of the mine enterprise, the system is convenient to deploy, and the operation is reliable.

Description

Data acquisition method based on mine holographic graph

Technical Field

The invention relates to a data processing method, in particular to a data acquisition method based on a mine hologram.

Background

According to the requirements of mine enterprises on intelligent coal mine construction, an intelligent mine is an unmanned mine which can actively sense, automatically analyze and rapidly process safety generation states of personnel, systems, management, environment, equipment and the like, and is an intrinsically safe mine, an efficient mine and a clean mine, and digitization and informatization of the mine are the premise and the foundation of construction. The safety production of coal mines relates to various professional contents such as mining, digging, mechanical operation, transportation, communication, ground measurement, water prevention and control, gas, roof, fire, mine pressure and the like, and has the advantages of various types, fast data updating and frequent service data interaction. How to integrate dispersed and isolated service data resources into an integrated and unified management application platform to perform statistical analysis on various data to guide decision-making mine safety production is the main purpose of the invention.

Disclosure of Invention

The invention provides a data acquisition method based on a mine holographic one-sheet, which is a solution method for providing information services of mine enterprises in a holographic one-sheet mode by using an RED-MOS system as a carrier of a mine application program, fusing heterogeneous information and heterogeneous networks of multiple systems of the mine enterprises and reducing labor cost and realizing strong real-time, re-interaction and expandability. The technical scheme is as follows:

a data acquisition method based on a mine hologram comprises the following steps:

s1: based on an RED-MOS system, taking a roadway under a mine as a data acquisition unit, drawing a two-dimensional and three-dimensional GIS Web display structure, and forming a thematic map layer of the roadway;

s2: acquiring required service application data, and mapping the service application data to a thematic map layer;

s3: classifying the service application data, and performing grading processing of different attributes on the same class;

s4: and performing correlation processing on different types of service application data to enable the personnel, the system, the management, the environment and the equipment to be intercommunicated and interconnected, thereby realizing the transverse communication and the longitudinal integration among the systems.

The RED-MOS system comprises a data acquisition layer, a data storage layer, a data service layer and a data gateway layer which are sequentially connected; the data acquisition layer realizes intelligent acquisition of production monitoring data, safety monitoring data, production execution data and graphic resource data through an intelligent data gateway; the data storage layer comprises a cache database, a relational database and a time sequence database, wherein the cache database is used for performing staged washing on collected data and temporarily caching applicable contents, the relational database is used for performing correlation fusion on the data which are put in storage through a specific relation to form data reprocessing, and the time sequence database is used for performing full and deep analysis on the data by using a time dimension and storing an analysis result; the data service layer comprises FAAS, BaaS and MicroService, wherein the FaaS comprises transcoding of video information, uploading of data materials and management of customized events, the BaaS comprises data query and subscription and data push services, and the MicroService comprises integrated analysis of data such as videos and artificial intelligence application services; the data gateway layer is used for serving unified portals, including traffic management, authorization, access control and monitoring.

In the step S1, the data acquisition of the roadway is to slice the corresponding roadway drawing, realize drawing storage after digitization, and complete two-dimensional GIS Web display through a GIS SDK interface; according to the wire point information of the roadway and the roadway acquisition data, a three-dimensional roadway can be generated by utilizing a roadway cross point algorithm, and three-dimensional GIS Web display is realized.

The roadway acquisition data comprise a father roadway geo code, a roadway name, a roadway topo starting point and a roadway topo end point; the wire point information comprises a wire point geo code, a roll call, an X coordinate, a Y coordinate, a bottom elevation, a lane height, a left side bond distance, a right side bond distance, whether a second set of bond lines are opened, a second set of left side bond distance, a second set of right side bond distance and a tunnel geo code.

In step S2, the process of binding the thematic map layer data with the service application data entity includes the following steps:

s21: matching thematic map and map layer;

s22: calling the cooperative service of the system to obtain a thematic map and a map layer;

s23: selecting a business application data binding layer;

s24: selecting a business entity object coding type corresponding to the business application data to obtain all objects with the same type of codes;

s25: selecting a business entity object and binding the business entity object in a corresponding layer;

s26: calling a restful API (application program interface) to acquire corresponding layer information and measuring point binding information;

s27: and calling the Web GIS SDK to perform layer data rendering and service application data rendering.

In step S3, the classifying the service application data includes: (1) the professional viewing module comprises: by clicking any one label name, the corresponding graphic content can be viewed; (2) synthesize "a picture" module: acquiring data resources of each hardware subsystem and a daily management working system of a mine enterprise, and realizing the management and application of various data in one graph according to a unified coordinate value; (3) ground survey "one picture" module: a 'one-map' model method covering data such as geology, measurement, reserves, water prevention and control is constructed by carrying out standardized and standardized processing and storage on professional data of a ground measurement department; (4) producing a "one picture" module: the intellectualization, the visualization and the visualization of the back mining, the tunneling and the goaf management are realized through the statistics and the analysis of professional data of a production technology department; (5) the general defense module is characterized by comprising a general defense module: providing state judgment of a mine ventilation system; (6) electromechanical "one-sheet" module: managing the condition of electromechanical equipment of a mine, and mastering the maintenance and life cycle history of all the equipment; (7) secure "one graph" module: the distribution of various factors is automatically calculated and analyzed, and the current mine safety factor distribution condition is visually displayed in a thermodynamic diagram form; (8) an emergency "one picture" module: the dynamic emergency attendance of an enterprise, one-key emergency starting, accident classification disposal flow management, automatic tracking process recording and automatic summary generation of an accident disposal report are realized; (9) monitor "one graph" module: the method has the advantages that the site-based management of monitoring is realized, the real-time threshold judgment aiming at single parameter or multiple parameters of a single system is established, and the early warning and alarming indication is provided; and further realize information service, data sharing, intelligent control and emergent linkage in the pit.

When the graphic file of the professional graph looking module is designed, all parts in a mine are modeled, each part corresponds to a label name, professional graph drawing personnel realize collaborative drawing and unified standardized management of all graphs of the mine through a collaborative design platform, drawing the graphs in equal proportion into schematic diagrams, integrating the respectively drawn schematic diagrams into a large diagram, and realizing real-time display of model data through regular updating or irregular updating.

In the comprehensive 'one-picture' module, the environmental factor information, the equipment factor information, the management information factor and various system operation conditions of the current position can be obtained in real time through each place in the picture, and the instruction can be directly issued to the site.

In step S4, the service application data of different types in the same lane are interconnected, and an association relationship and a rule are set; the data interface associated with other lanes exists in the lane, so that the transmission of service application data is realized, and further, the data change of other lanes is caused.

According to the data acquisition method based on the mine hologram, through deep mining of various professional data of a mine enterprise, intercommunication and interconnection of personnel, systems, management, environments, equipment and the like are achieved, transverse communication and longitudinal integration among the systems are achieved, decision basis and intelligent dynamic management can be effectively provided for safety management of the mine enterprise, the system is convenient to deploy, and operation is reliable.

Drawings

FIG. 1 is a schematic diagram of a two-dimensional and three-dimensional GIS integrated data calling process;

fig. 2 is a schematic flow chart of data of a business data entity binding layer.

Detailed Description

The invention provides a data acquisition method based on a mine holographic picture, which realizes safety management on a mine and realizes a model of comprehensive application field of each professional 'picture'. Various data of mine enterprise personnel, systems, management, environment, equipment and the like are integrated by means of the RED-MOS system, and are summarized and analyzed through one picture, so that the safety generation management of management personnel based on the one picture is finally realized. The RED-MOS system comprises a data acquisition layer, a data storage layer, a data service layer and a data gateway layer which are sequentially connected.

The data acquisition layer realizes intelligent acquisition of production monitoring data, safety monitoring data, production execution data and graphic resource data mainly through an intelligent data gateway.

The data storage layer comprises a cache database, a relational database and a time sequence database. The cache database is used for performing staged washing on the collected data and temporarily caching the applicable contents; the relational database is used for performing correlation fusion on the data which are put in storage through a specific relation to form data reprocessing; the time sequence database is used for sufficiently deeply analyzing data in a time dimension and storing the analysis result.

The data service layer comprises FAAS, BaaS and Microservice; the FaaS comprises transcoding of video information, uploading of data materials and the like, management of customized events and the like; the BaaS comprises data query, subscription and data push service; the MicroService comprises integrated analysis of video and other data and application service of artificial intelligence.

And the data gateway layer is used for serving a unified entrance and comprises flow management, authorization, access control and monitoring.

According to the technical scheme, underground information service, data sharing, intelligent control and emergency linkage are realized based on a hologram, and finally dangerous source early warning, large-scale equipment fault diagnosis, intelligent mining control service and potential safety hazard perception early warning of a mine are realized through AI big data analysis.

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments.

The invention is based on an RED-MOS intelligent mine Operating System (OS), acquires data resources from each hardware subsystem and a daily management working system of a mine enterprise, transmits the data resources to a unified data storage server through a network, and achieves the practical application of holographic one-sheet data through further standardization and classification processing of various data. The implementation of the invention mainly comprises the following main contents:

the professional picture viewing module comprises: the graphic file is used as the main content of daily management of the mine and is also a carrier capable of reflecting the underground environment and the construction progress condition; and each professional graphic drawing personnel realizes the collaborative drawing and unified standardized management of all the graphics of the mine through a collaborative design platform, and the purpose of looking up each professional graphic through a browser without depending on any client side is realized through a one-picture graphic viewing model method.

For all components in the mine, unified graphic model management is achieved, components of the same type are represented by the same graphic, and even pipelines, machine facilities and the like are all included in the graphic model management. During drawing, professional graphic drawing personnel draw schematic diagrams in equal proportion according to terrain and article positions, the format of the drawing diagrams is the same, the respectively drawn schematic diagrams are integrated into a large diagram, and meanwhile, the latest diagram display is realized through timing or non-timing updating. The map can be consulted through a browser.

In one figure, the module can be provided with an intelligent retrieval module besides a professional picture viewing module.

The professional viewing module clicks any label name on the left part, and the corresponding graphic content can be viewed;

the right part of the intelligent retrieval module can retrieve and look up any information in the mine hologram through intelligent retrieval, can also quickly look up by clicking any one quick label, and can click any retrieved information item to look up specific detailed information.

Secondly, integrating a 'one picture' module: based on an RED-MOS intelligent mine operating system, acquiring data resources of each hardware subsystem and a daily management working system of a mine enterprise, and realizing the management and application of various data in one graph according to a unified coordinate value; the comprehensive, two-dimensional and three-dimensional integrated inspection and supervision can be carried out on the safety production management of the whole mine without going deep into the underground according to different requirements of users through the holographic graph, the environmental factor information, the equipment factor information, the management information factor and various system operation conditions of the current position can be obtained in real time through each place, and the instruction can be directly issued on site.

All information data of the mine can be checked through the levels of dragging and zooming the graph; and any piece of content can be clicked through the right information panel to know various information of the mine, various information data can be quickly screened out by clicking labels such as a working face, safety conditions, automation, electromechanical equipment, safety monitoring, personnel positioning, a drilling site, industrial video and the like, specific position content is correspondingly displayed in the middle graph, and detailed information can be checked by clicking points in the graph.

Thirdly, measuring one graph module: the method comprises the steps of conducting standardized and standardized processing and storage on professional data of a ground survey department, constructing a 'one-map' model method covering data such as geology, measurement, storage capacity and control water, conducting real-time positioning and tracking on construction progress conditions of underground water exploration and drainage operation, conducting real-time dynamic observation on each hydrological observation hole and observation point through integration of a hydrological monitoring system, conducting early warning and alarming on abnormal conditions, and achieving unmanned monitoring on water damage management.

By clicking on the labels related to hydrological monitoring, faults, water inrush points, observation stations, water accumulation areas, drilling site geology, measurement, water prevention and control and storage measurement, various information data can be quickly screened out, specific position contents are correspondingly displayed in the middle graph, and detailed information can be checked by clicking on the points in the graph.

The management and data fusion integration of the ground-survey professional information are realized through the ground survey of one picture, the underground water detection and drainage progress management, the real-time monitoring of water hazard early warning and alarming and the dynamic reminding are realized.

Fourthly, producing a 'one picture' module: by means of statistics and analysis of professional data of a production technology department, aiming at main contents concerned by the department, integration and fusion of various data are achieved through a 'one-figure' model method, intelligentization, visualization and visualization of stoping, tunneling and goaf management are achieved, data information is intercommunicated and shared, and production links of a mine are managed more conveniently and rapidly.

By clicking the production technologies such as back mining working face, driving working face, goaf, roadway, mining continuation and the like, and labels related to mining management and production continuation, various information data can be quickly screened out, specific position contents are correspondingly displayed in the middle graph, and detailed information can be checked by clicking the points in the graph.

The management of production technology professional information and data fusion integration are realized by producing one picture, the fine and standardized management of underground construction sites and various data is realized, and meanwhile, data sharing is provided.

Fifthly, a drawing module is communicated: through processing and analysis of one-ventilation, three-prevention and professional data, network simulation calculation is carried out on ventilation parameters, and based on a result that a one-picture model accurately shows visual images to users in real time, state judgment on a mine ventilation system is provided, if abnormal conditions such as air volume, air pressure and the like exist, state reminding is carried out based on a unified early warning system, and intelligent automatic ventilation management based on the one-picture model method is realized;

through clicking the relevant labels of ventilation, air door, airtight, wind-break wall, safety monitoring, gas control, dustproof management, fire prevention and extinguishing management and the like, various information data can be screened out quickly, the specific position content is correspondingly displayed in the middle picture, and the detailed information can be checked by clicking the point in the picture.

The management of one ventilation, three prevention and professional information and the integration of data are realized through one ventilation and three prevention map, the management of an underground ventilation system based on mine ventilation simulation calculation is realized, the data of a monitoring sensor is integrated, and the conditions of underground wind flow, wind volume and wind pressure are acquired and applied on one map.

Sixthly, an electromechanical 'one-sheet' module: the electromechanical equipment management method has the advantages that the electromechanical equipment information is acquired based on the RED-MOS system through unified location management of one picture, the coordinates are automatically calculated through the system, the regional location management of the electromechanical equipment based on one picture is realized, the electromechanical equipment condition of a mine is comprehensively and normatively managed, and the maintenance and repair and the life cycle process of all the equipment are mastered.

Various information data can be quickly screened out by clicking labels related to electromechanical transportation specialties such as electromechanical equipment, large-scale equipment, underground transportation, main coal flow transportation and the like, specific position contents are correspondingly displayed in the middle graph, and detailed information can be checked by clicking points in the graph.

Management of electromechanical transportation professional information and fusion integration of data are achieved through one electromechanical picture, automatic acquisition and rapid positioning of equipment data in one picture are achieved, regional management of mine electromechanical equipment is achieved, and maintenance, overhaul, maintenance and whole life cycle management of the equipment can be achieved through one picture.

Seventhly, a safety 'one picture' module: the method comprises the steps of obtaining factor data of hidden dangers, violations, risks and the like of safety management of mine enterprises based on an RED-MOS smart mine operation system, independently calculating and analyzing distribution of various factors through a one-picture model method, visually displaying distribution conditions of current mine safety factors in a thermodynamic diagram mode, and providing reliable basis for managers to accurately and quickly decide key areas of mine safety management.

Various information data can be quickly screened out by clicking the labels related to safety management such as risk, hidden danger, violation of three times, AI analysis, safety inspection and the like, the specific position content is correspondingly displayed in the middle graph, and detailed information can be checked by clicking the points in the graph.

The management of safety professional information and the fusion and integration of data are realized through one safety picture, one picture region hot spot classification of risk, hidden danger and violation information of mine enterprises is realized, and underground safety management is emphasized in real time.

The site management and the acquisition of various safety production element information of mine enterprises are realized by integrating one picture, and meanwhile, the daily inspection work is carried out on the underground environment of the mine based on a two-three-dimensional integrated platform.

Eighthly, emergency one-picture module: the intelligent emergency system flow management of the mine is realized through a 'one-figure' model method, an emergency disposal flow integrating emergency on duty, danger avoiding and relief work and monitoring linkage is established, emergency management is started by one key, automatic flow disposal is realized, an accident report is automatically generated, and accident emergency rescue is guided scientifically and normatively.

By clicking the labels related to emergency rescue such as emergency attendance, key areas, refuge chambers, emergency broadcasting, voice communication, historical accidents and the like, various information data can be quickly screened out, the specific position content is correspondingly displayed in the middle graph, and the detailed information can be checked by clicking the points in the graph.

The emergency rescue standardization rapid management of the mine enterprise is realized through an emergency 'one picture', the dynamic emergency duty of the enterprise is realized, one-key emergency starting, the accident classification disposal flow management, the automatic tracking process recording and the automatic summary generation of the accident disposal report are realized.

Ninthly, monitoring a 'one picture' module: the method comprises the steps of obtaining monitoring and automation data of a mine enterprise based on an RED-MOS smart mine operation system, realizing monitoring locality management through a one-picture model method, establishing real-time threshold judgment aiming at single parameter or multiple parameters of a single system, and providing early warning and alarming indication. For example, when the data of the equipment temperature sensor exceeds a threshold value, the system automatically alarms to remind a responsible person, the field situation is investigated in time, corresponding treatment is carried out, and the damage to the equipment is reduced; meanwhile, fusion linkage among multiple systems is realized through the creation of a 'one-map' model method, for example, a gas sensor gives an alarm when abnormal, the system automatically positions the map position of the sensor, sends out an alarm signal through personnel positioning, voice broadcasting and a communication telephone at the same time, grasps the field situation in time through video monitoring, monitors the states of other sensors nearby, acquires the environmental factors of the accident site in real time, intelligently starts disposal and provides a correct disaster and danger avoiding route.

By clicking the labels related to the mine safety risk avoidance system and the comprehensive automation system such as industrial video, hydrological monitoring, emergency broadcasting, dispatching communication, comprehensive monitoring and the like, various information data can be quickly screened out, specific position contents are correspondingly displayed in the middle graph, and detailed information can be checked by clicking points in the graph.

The integration and integration of the monitoring and monitoring systems of the mine enterprises are realized by monitoring one picture, the alarm and early warning of a single-system single-parameter and multi-parameter threshold system are realized, the integration linkage alarm and early warning among multiple systems are realized, and the safe operation state of the mine enterprises is dynamically monitored.

To summarize: according to the invention, through deep mining of professional data of the mine enterprise, intercommunication and interconnection of personnel, systems, management, environment, equipment and the like are realized, transverse communication and longitudinal integration among the systems are realized, decision basis and intelligent dynamic management can be effectively provided for safety management of the mine enterprise, the system is convenient to deploy, and the operation is reliable.

The invention realizes the basic operations of real-time viewing, multilayer screening and overlapping, multi-graph overlapping and the like of CAD graphs necessary for mine enterprises based on a web browser. Establishing a picture management model taking a comprehensive 'picture' as a core and taking a 'picture' for production, ground measurement, communication and defense, electromechanics, safety, emergency and monitoring as assistance.

The invention integrates various data of mine enterprise personnel, systems, management, environment, equipment and the like by utilizing the RED-MOS system, takes the roadway under the mine as a data acquisition unit, but during drawing, a two-dimensional GIS data map is usually drawn, so that a three-dimensional roadway can be generated by utilizing the intersection point of the roadway based on the data acquired by the roadway of the two-dimensional GIS and the data of the wire points of the roadway.

As shown in fig. 1, on the excavation engineering plane defined by the system, a collaborative design platform is utilized to collect data of a roadway first, and the data collected by the roadway can be divided into: the method comprises the steps of father roadway geo code, roadway name, roadway topo starting point and roadway topo ending point. geo code is a geo code and topo represents a topology.

During specific implementation, drawing slicing can be carried out on the corresponding roadway drawing (the front end realizes page codes according to a design drawing), drawing storage is realized after digitization, and two-dimensional GIS Web display is completed through a GIS SDK interface.

Simultaneously, other data in this tunnel need be handled, empty data storage in the tunnel calls the cloud function formatting tunnel data of wire point information, wire point information includes wire point geo code, roll call, X coordinate, Y coordinate, end elevation, lane height, left side nation distance, right side nation distance, two nation lines are opened or not, two left side nation distances, two right side nation distances, tunnel geocode. And finally, completing three-dimensional GIS Web display through a three-dimensional SDK interface.

After a basic display structure is established by using a roadway, in order to realize the association of each module in the implementation of one graph, application data also needs to be acquired and associated.

A diagram of the application and call data is described as follows:

the mine holograph service application data is divided into three types of data, namely layer data, real-time acquisition service data and informationized service data.

And the layer data provides service interfaces for the two-dimensional GIS geographic service and the three-dimensional GIS geographic service corresponding to the tunnel information.

And the real-time acquisition service data is pushed and acquired in real time by an edge data gateway arranged in the tunnel.

The information service data is divided into different level attributes according to the level of an entity, and the entity classification coding rule is as follows:

and each roadway is used as a thematic map, and the coding rule of the thematic map layer is as follows:

thematic map coding	Name of thematic map	Layer coding	Layer name
				001	Plan view of excavation engineering	001001	Roadway

The thematic map layer and the business data mapping rule are as follows:

measuring point ID	Primary coding of service data	Secondary coding of service data	Thematic map coding	Layer coding
					1	001	001001	001	001001

On the layer of the tunnel, all the service data in the tunnel are corresponded, that is, the tunnel carries the specific content of all the modules, so that in one map, only a single module can be displayed on the display structure. Furthermore, the business data are correlated on the roadway, and the correlation relation and the rule are set. Then, the data interface exists in the tunnel, and the interface is connected with the interfaces of other related tunnels to realize the passive association of the service data.

As shown in fig. 2, the data flow of the service data entity binding layer includes the following steps:

s1: matching thematic map and map layer;

s2: calling the cooperative service to obtain a thematic map and a map layer;

s3: selecting a business data binding layer;

s4: selecting the coding type of the business entity object to obtain all objects with the same type of codes;

s5: selecting an actual object and binding the actual object on a corresponding layer;

s6: calling a restful API (service entity primary code) interface to acquire corresponding layer information and measuring point binding information;

s7: and calling the Web GIS SDK to perform layer data rendering and service data rendering.

Thus, the data binding of each module is completed, and then the data association processing between the modules is performed.

According to the invention, through deep mining of professional data of the mine enterprise, intercommunication and interconnection of personnel, systems, management, environment, equipment and the like are realized, transverse communication and longitudinal integration among the systems are realized, decision basis and intelligent dynamic management can be effectively provided for safety management of the mine enterprise, the system is convenient to deploy, and the operation is reliable.

Claims (9)

1. A data acquisition method based on a mine hologram comprises the following steps:

s1: based on an RED-MOS system, taking a roadway under a mine as a data acquisition unit, drawing a two-dimensional and three-dimensional GIS Web display structure, and forming a thematic map layer of the roadway;

s2: acquiring required service application data, and mapping the service application data to a thematic map layer;

s3: classifying the service application data, and performing grading processing of different attributes on the same class;

s4: and performing correlation processing on different types of service application data to enable the personnel, the system, the management, the environment and the equipment to be intercommunicated and interconnected, thereby realizing the transverse communication and the longitudinal integration among the systems.

2. The method of claim 1, wherein the method comprises: the RED-MOS system comprises a data acquisition layer, a data storage layer, a data service layer and a data gateway layer which are sequentially connected; the data acquisition layer realizes intelligent acquisition of production monitoring data, safety monitoring data, production execution data and graphic resource data through an intelligent data gateway; the data storage layer comprises a cache database, a relational database and a time sequence database, wherein the cache database is used for performing staged washing on collected data and temporarily caching applicable contents, the relational database is used for performing correlation fusion on the data which are put in storage through a specific relation to form data reprocessing, and the time sequence database is used for performing full and deep analysis on the data by using a time dimension and storing an analysis result; the data service layer comprises FAAS, BaaS and MicroService, wherein the FaaS comprises transcoding of video information, uploading of data materials and management of customized events, the BaaS comprises data query and subscription and data push services, and the MicroService comprises integrated analysis of data such as videos and artificial intelligence application services; the data gateway layer is used for serving unified portals, including traffic management, authorization, access control and monitoring.

3. The method of claim 1, wherein the method comprises: in the step S1, the data acquisition of the roadway is to slice the corresponding roadway drawing, realize drawing storage after digitization, and complete two-dimensional GIS Web display through a GIS SDK interface; according to the wire point information of the roadway and the roadway acquisition data, a three-dimensional roadway can be generated by utilizing a roadway cross point algorithm, and three-dimensional GIS Web display is realized.

4. The method of claim 3, wherein the method further comprises: the roadway acquisition data comprise a father roadway geo code, a roadway name, a roadway topo starting point and a roadway topo end point; the wire point information comprises a wire point geo code, a roll call, an X coordinate, a Y coordinate, a bottom elevation, a lane height, a left side bond distance, a right side bond distance, whether a second set of bond lines are opened, a second set of left side bond distance, a second set of right side bond distance and a tunnel geo code.

5. The method of claim 1, wherein the method comprises: in step S2, the process of binding the thematic map layer data with the service application data entity includes the following steps:

s21: matching thematic map and map layer;

s22: calling the cooperative service of the system to obtain a thematic map and a map layer;

s23: selecting a business application data binding layer;

s24: selecting a business entity object coding type corresponding to the business application data to obtain all objects with the same type of codes;

s25: selecting a business entity object and binding the business entity object in a corresponding layer;

s26: calling a restful API (application program interface) to acquire corresponding layer information and measuring point binding information;

s27: and calling the Web GIS SDK to perform layer data rendering and service application data rendering.

6. The method of claim 1, wherein the method comprises: in step S3, the classifying the service application data includes: (1) the professional viewing module comprises: by clicking any one label name, the corresponding graphic content can be viewed; (2) synthesize "a picture" module: acquiring data resources of each hardware subsystem and a daily management working system of a mine enterprise, and realizing the management and application of various data in one graph according to a unified coordinate value; (3) ground survey "one picture" module: a 'one-map' model method covering data such as geology, measurement, reserves, water prevention and control is constructed by carrying out standardized and standardized processing and storage on professional data of a ground measurement department; (4) producing a "one picture" module: the intellectualization, the visualization and the visualization of the back mining, the tunneling and the goaf management are realized through the statistics and the analysis of professional data of a production technology department; (5) the general defense module is characterized by comprising a general defense module: providing state judgment of a mine ventilation system; (6) electromechanical "one-sheet" module: managing the condition of electromechanical equipment of a mine, and mastering the maintenance and life cycle history of all the equipment; (7) secure "one graph" module: the distribution of various factors is automatically calculated and analyzed, and the current mine safety factor distribution condition is visually displayed in a thermodynamic diagram form; (8) an emergency "one picture" module: the dynamic emergency attendance of an enterprise, one-key emergency starting, accident classification disposal flow management, automatic tracking process recording and automatic summary generation of an accident disposal report are realized; (9) monitor "one graph" module: the method has the advantages that the site-based management of monitoring is realized, the real-time threshold judgment aiming at single parameter or multiple parameters of a single system is established, and the early warning and alarming indication is provided; and further realize information service, data sharing, intelligent control and emergent linkage in the pit.

7. The method of claim 6, wherein the method comprises: when the graphic file of the professional graph looking module is designed, all parts in a mine are modeled, each part corresponds to a label name, professional graph drawing personnel realize collaborative drawing and unified standardized management of all graphs of the mine through a collaborative design platform, drawing the graphs in equal proportion into schematic diagrams, integrating the respectively drawn schematic diagrams into a large diagram, and realizing real-time display of model data through regular updating or irregular updating.

8. The method of claim 6, wherein the method comprises: in the comprehensive 'one-picture' module, the environmental factor information, the equipment factor information, the management information factor and various system operation conditions of the current position can be obtained in real time through each place in the picture, and the instruction can be directly issued to the site.

9. The method of claim 6, wherein the method comprises: in step S4, the service application data of different types in the same lane are interconnected, and an association relationship and a rule are set; the data interface associated with other lanes exists in the lane, so that the transmission of service application data is realized, and further, the data change of other lanes is caused.

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