CN115545400A - Refinery enterprise environment-friendly monitoring method and device, storage medium and electronic equipment - Google Patents

Abstract

The invention provides an environmental protection monitoring method and device for an refining enterprise, a storage medium and electronic equipment, which are integrated with environmental protection monitoring data of the refining enterprise; the environmental protection monitoring data of the refinery enterprise comprises the following data: at least one of national image data, factory production device and tank area vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data; performing environmental protection monitoring analysis based on the acquired environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring comprises: at least one of waste water online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring; and outputting the results of the environmental protection monitoring analysis to the terminal equipment for display. The invention provides a monitoring scheme for the environmental-friendly comprehensive supervision of the refinery enterprises and realizes the unified management and monitoring of the multi-source pollution source data.

Description

Refinery enterprise environment protection monitoring method, device, storage medium and electronic equipment

Technical Field

The invention relates to the technical field of environmental protection monitoring, in particular to an environmental protection monitoring method and device for an oil refinery enterprise, a storage medium and electronic equipment.

Background

The environmental protection management of the refining and chemical enterprises relates to daily standard-reaching management of waste water, waste gas, solid waste and the like, and the main services comprise environmental monitoring, three-waste management, pollution source management, environmental quality monitoring, risk management and the like. Enterprises achieve the purposes of pollutant source reduction, process control and tail end treatment and clean production through enhancing the cooperative management of various environmental protection services.

At present, the scheme of the environment-friendly geographic information mainly shows dynamic information of wastewater and waste gas pollution, weather and Air Quality dynamic forecast is applied more, and haze weather and other prompts are carried out on living services by monitoring Air Quality Indexes (AQI) so as to care health. The meteorological data and the environmental pollution data are visually monitored based on a Geographic Information System (GIS), and climate query and distribution prediction based on the GIS are realized.

The existing enterprise environment online monitoring scheme is developed by monitoring and displaying the waste water and waste gas discharge of a plurality of surrounding enterprises, and provides a geographic information monitoring solution for environmental monitoring, which is a single environmental protection service, so that enterprises can master the pollutant discharge condition and timely standard exceeding rectification. However, most of the existing technical solutions are based on the single display of key pollution conditions of geographic information technology, and the main functions are to query the air quality and weather conditions of the city or nearby, check pollution sources existing nearby, mainly display the real-time emission conditions of monitoring points, display emission standards, emission trends, emission scene scenes, and simple over-standard alarm.

Therefore, how to provide a monitoring scheme aiming at the environmental-protection comprehensive supervision of the refinery enterprises is a technical problem which needs to be solved urgently in the field.

Disclosure of Invention

In order to solve the above technical problems, embodiments of the present invention provide a method, an apparatus, a storage medium, and an electronic device for environmental monitoring of a refinery enterprise.

In a first aspect, an embodiment of the present invention provides an environmental protection monitoring method for an oil refinery enterprise, including:

integrating and accessing environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring data of the refining enterprise comprises the following data: at least one of national image data, factory production device and tank area vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data;

performing environmental protection monitoring analysis based on the acquired environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring comprises: at least one of waste water online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring;

and outputting the results of the environmental protection monitoring analysis to the terminal equipment for display.

In some implementations, the performing environmental monitoring analysis based on the obtained environmental monitoring data of the refinery enterprise includes:

acquiring a user name of current login, and determining a function mechanism to which the user of current login belongs;

if the function organization to which the user currently logged in belongs is a group, providing a menu function view corresponding to the group user, so as to obtain the code of each enterprise belonging to the group, the name of the enterprise and the map boundary range summarized by all the enterprises;

and if the function mechanism of the currently logged-in user is an enterprise, acquiring the enterprise code, the enterprise name and a map boundary range in the enterprise map boundary range.

In some implementation manners, the environmental protection monitoring analysis is performed based on the obtained environmental protection monitoring data of the refining enterprise, and further includes:

and performing unified projection superposition on various refinery enterprise environment protection monitoring data according to the coordinates of the map boundary range to generate a plant area production plane visual monitoring view.

In some implementations, the environmental monitoring analysis includes: waste water on-line monitoring, waste gas on-line monitoring, solid useless storage site management, VOCs control, air quality control, factory boundary noise control, environmental risk source control, soil and groundwater monitoring, dirty rainwater pipeline integrated analysis when at least one, carry out environmental protection monitoring analysis based on the refinery enterprise environmental protection monitored data who acquires, still include:

filtering and extracting longitude and latitude data of each environmental protection monitoring point from the environmental protection monitoring point spatial position data, and performing coordinate projection to obtain a visual monitoring graph of each environmental protection monitoring point;

and extracting a monitoring value from the monitoring service data of the environment-friendly monitoring point, and combining the visual monitoring graph to realize visual monitoring of the monitoring service data.

In some implementations, for online wastewater monitoring, online exhaust gas monitoring, or VOCs monitoring, the step of extracting a monitoring value from the environmental protection monitoring point monitoring service data and implementing visual monitoring of the monitoring service data in combination with the visual monitoring map includes: extracting real-time monitoring values from the monitoring service data of the environment-friendly monitoring points, judging normal points, alarm points and over-standard points by combining early warning values, and obtaining visual monitoring graphs of the alarm points by combining the visual monitoring graphs of the environment-friendly monitoring points;

aiming at the management of solid waste storage points, the steps of extracting monitoring values from the monitoring service data of the environment-friendly monitoring points and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprise: extracting detailed data of solid waste storage points from monitoring service data of the environment-friendly monitoring points, judging normal points and alarm points by combining solid waste storage design capacity, and obtaining visual monitoring graphs of the alarm points by combining the visual monitoring graphs of the environment-friendly monitoring points;

aiming at air quality monitoring, the steps of extracting a monitoring value from monitoring service data of an environment-friendly monitoring point and realizing visual monitoring of the monitoring service data by combining the visual monitoring graph comprise: extracting the current latest air quality monitoring value from the monitoring service data of the environment-friendly monitoring points, and combining the visual monitoring graphs of all the environment-friendly monitoring points to realize visual monitoring of the air quality data;

aiming at the monitoring of the factory boundary noise, the steps of extracting the monitoring value from the monitoring service data of the environment-friendly monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprise: extracting a current latest factory boundary noise monitoring value from the environmental protection monitoring point monitoring service data, combining the noise standard value to judge a noise normal point and an abnormal point, and combining the visual monitoring graph of each environmental protection monitoring point to realize the visual monitoring of the factory boundary noise data;

aiming at the monitoring of the environmental risk source, the step of extracting the monitoring value from the monitoring service data of the environmental protection monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprises the following steps: extracting coordinate point longitude and latitude and flow direction data of an emergency material inventory point, an accident point position and an emergency command center from the monitoring service data of the environment-friendly monitoring points, and obtaining an emergency material visual monitoring graph by combining visual monitoring graphs of all the environment-friendly monitoring points;

aiming at soil and underground water monitoring, the steps of extracting monitoring values from monitoring service data of environment-friendly monitoring points and combining the visual monitoring graph to realize visual monitoring of the monitoring service data comprise: extracting soil and underground water monitoring values from the monitoring service data of the environment-friendly monitoring points, determining whether normal points and superscript points exceed standards by combining standard values of all indexes corresponding to the soil and underground water monitoring values, and obtaining a visual monitoring graph of the soil and the underground water by combining the judgment result of whether the normal points and the superscript points exceed the standards and the visual monitoring graph of all the environment-friendly monitoring points;

aiming at the comprehensive analysis of the sewage and rainwater pipeline, the step of extracting the monitoring value from the monitoring service data of the environment-friendly monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprises the following steps: and extracting the longitude and latitude and flow direction data of continuous coordinate points of all pipelines from the monitoring service data of the environment-friendly monitoring points, drawing dynamic flow charts of a sewage line, a rain line and an accident line by adopting a coordinate projection mode and adopting different classification colors, and obtaining a water body prevention and control comprehensive graph by combining the visual monitoring view and the dynamic flow charts of all the pipelines.

In some implementation manners, the step of extracting a monitoring value from the environmental protection monitoring point monitoring service data and implementing visual monitoring of the monitoring service data by combining the visual monitoring graph further includes:

and generating at least one of a list of the monitoring service data, a monitoring curve graph and a video of the environment-friendly monitoring point based on the visual monitoring content of the monitoring service data.

In some implementations, when the environmental monitoring analysis includes a composite index monitoring, the environmental monitoring analysis is performed based on the obtained environmental monitoring data of the refining enterprise, including:

acquiring standard-reaching rate calculation parameters, transmission rate calculation parameters and equipment integrity rate calculation parameters of each environmental protection monitoring point from monitoring service data of the environmental protection monitoring points, and calculating the total standard-reaching rate, transmission rate and equipment integrity rate of each enterprise respectively;

and generating an enterprise comprehensive ranking view according to a preset ordering rule.

In a second aspect, an embodiment of the present invention provides an environmental protection monitoring system for an oil refinery enterprise, including:

the integrated access module is used for integrated access to the environmental protection monitoring data of the refinery enterprise; the environmental protection monitoring data of the refinery enterprise comprises the following data: at least one of national image data, factory production device and tank area vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data;

the environmental protection monitoring and analyzing module is used for carrying out environmental protection monitoring and analysis based on the acquired environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring comprises: at least one of waste water online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring;

and the terminal display module is used for outputting the results of the environmental protection monitoring analysis to the terminal equipment for display.

In a third aspect, an embodiment of the present invention is a storage medium, where a computer program is stored, and when the computer program is executed by one or more processors, the computer program implements the method according to the first aspect.

In a fourth aspect, an embodiment of the present invention provides an electronic device, which includes one or more processors and a memory, where the memory stores thereon a computer program, and when the one or more processors execute the computer program, the method according to the first aspect is implemented.

One or more embodiments of the invention have at least the following beneficial effects:

the invention realizes the unified management and monitoring of the multi-source pollution source data, changes the orderless of data management through a unified geographic information system platform and a unified data standard, and realizes the applications of pollution source data query, statistics, thematic map making, spatial analysis and the like. The geographic information space service is provided, the geographic information sharing services such as navigation, visualization, space analysis, decision support and the like are realized through the interface function of a geographic information system, the information communication and business cooperation among departments and enterprises are enhanced, and the aim of improving the efficiency is fulfilled. And supporting part of typical service application functions, providing spatial information support for service work and management decisions through comprehensive analysis and display of spatial data and service data, and realizing part of typical service application functions.

Drawings

To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required in the embodiments will be briefly described below, and it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope.

FIG. 1 is a flow chart of an environmental monitoring method for a refinery enterprise according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of environmental monitoring data of an integrated access refining enterprise according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a user cockpit configuration solution provided by an embodiment of the present invention;

FIG. 4 is a schematic view of an online wastewater monitoring process provided by an embodiment of the invention;

FIG. 5 is a schematic diagram of an exhaust gas on-line monitoring process provided by an embodiment of the invention;

FIG. 6 is a schematic view of a process for managing solid waste storage points according to an embodiment of the present invention;

fig. 7 is a schematic view of a monitoring process for VOCs according to an embodiment of the present invention;

FIG. 8 is a schematic view of an air quality monitoring process provided by an embodiment of the present invention;

FIG. 9 is a schematic diagram of a process for monitoring factory noise according to an embodiment of the present invention;

FIG. 10 is a schematic view of a monitoring process of environmental risk sources according to an embodiment of the present invention;

FIG. 11 is a schematic illustration of a soil/groundwater monitoring process provided by an embodiment of the invention;

FIG. 12 is a schematic view of a comprehensive analysis process of a sewage/rain water pipeline according to an embodiment of the present invention;

FIG. 13 is a schematic view of a monitoring process of a composite index according to an embodiment of the present invention;

fig. 14 is a schematic view of a visualization display mode based on multiple terminals according to an embodiment of the present invention;

FIG. 15 is a schematic view of an environmental monitoring platform for a refinery enterprise according to an embodiment of the present invention;

fig. 16 is a schematic view of an environmental monitoring apparatus for a refinery enterprise according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

GIS technology is a particular very important spatial information system. The system is a technical system for displaying and describing relevant geographic distribution data in the whole or partial earth surface (including the atmosphere) space under the support of a computer hardware and software system, is an information system specially used for collecting, storing, managing, analyzing and expressing spatial data, and is a tool for expressing, simulating the real space world and processing and analyzing the spatial data. The GIS is a computer software tool for the geographic information industry to reach the informatization of various industries, is an important means for information digitization and visual expression, and is widely applied to various aspects such as mapping and mapping, resource management, urban and rural planning, disaster monitoring, environmental protection, national defense, macroscopic decision and the like.

The technical scheme comprises pollution sources, waste water, waste gas, solid waste, air quality, VOCs (volatile organic chemicals), factory noise, sewage pipelines and environmental risk source service themes, the GIS technology and the space technology are adopted, geographic data and map information can be stored, managed, applied and analyzed, and the spatial data and the service data can be fully combined to form digital, graphical and informationalized environment-friendly service elements. Meanwhile, a visual environment-friendly comprehensive supervision platform can be constructed by utilizing multi-service cooperation of environment-friendly management, the overall situation of enterprise environment-friendly monitoring management can be comprehensively mastered, the defect that the monitoring service of the existing environment online monitoring scheme is single is overcome, the grading management and the monitoring capability digitization are realized, the traceability of the whole process of the environment-friendly management is realized, and related resources such as environment risk monitoring, environment emergency dispatching and the like can be helped through audio and video technologies and communication technologies, so that the unified allocation of resources is realized. Aiming at real-time service data such as specific pollution source waste water, waste gas and the like of an refining enterprise, an environment-friendly comprehensive monitoring platform based on a geographic information system is provided, so that the defect that only single information of environment monitoring can be checked in the prior art is overcome, environment-friendly service monitoring cooperation is achieved, and an enterprise environment-friendly management comprehensive monitoring platform and a tool are provided.

Example one

Fig. 1 shows a flowchart of an environmental monitoring method for an refinery enterprise, and as shown in fig. 1, the embodiment provides an environmental monitoring method for a refinery enterprise, which includes steps S110 to S130:

s110, integrating and accessing environmental protection monitoring data of an refinery enterprise; wherein, the environmental protection monitoring data of the refinery enterprise includes: at least one of national image data, factory production device and tank area vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data.

The step realizes data unified integration, and specifically obtains national common precision image data, factory high precision image data, factory production device and tank field vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data. The national common precision image data is accessed from the existing Chinese petrochemical geographic information service platform by adopting a Restful standard protocol, the plant area high precision image data, the plant area production device and the tank area vector data are integrated and accessed from the existing Chinese petrochemical environmental protection geographic information service platform by adopting an OGC standard protocol (an international map standard protocol), the environmental protection monitoring point spatial position data and the environmental protection monitoring point monitoring service data are acquired from the existing Chinese petrochemical environmental protection service database by adopting a WebService protocol, the environmental protection monitoring video data is accessed from the existing Chinese petrochemical video monitoring platform by adopting the Restful standard protocol, and the schematic diagram of the integrated access of the environmental protection monitoring data of the refinery enterprises is shown in figure 2.

It should be understood that the chinese petrochemical geographic information service platform provides a national common precision image data service, the chinese petrochemical environmental protection geographic information service platform provides a plant area high precision image data service, a plant area production device and a tank area vector data service, the chinese petrochemical environmental protection service database provides an environmental protection monitoring point spatial position data service and an environmental protection monitoring point monitoring service data service, and the chinese petrochemical video monitoring platform provides an environmental protection monitoring video data service.

Further, comprehensive monitoring analysis is carried out on the basis of integrating and accessing environmental protection monitoring data of the refinery enterprises, services such as map-based wastewater online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis, comprehensive index monitoring technology and the like are provided, and a user cockpit configuration solution is provided.

S120, performing environmental protection monitoring analysis based on the acquired environmental protection monitoring data of the refinery enterprise; wherein, environmental protection monitoring analysis includes: at least one of waste water on-line monitoring, waste gas on-line monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring.

In some implementations, a solution for configuring the user cockpit is provided, and the step S120 performs environmental monitoring analysis based on the obtained environmental monitoring data of the refinery enterprise, including:

acquiring a currently logged-in user name, and determining a function mechanism to which the currently logged-in user belongs;

if the function organization to which the user currently logged in belongs is a group, providing a menu function view corresponding to the group user, so as to obtain the code of each enterprise belonging to the group, the name of the enterprise and the map boundary range summarized by all the enterprises;

and if the function mechanism of the currently logged-in user is an enterprise, acquiring the enterprise code, the enterprise name and a map boundary range in the enterprise map boundary range.

In this embodiment, a solution for configuring a user cockpit as shown in fig. 3 is provided, a menu customization technology based on a role authority authentication function is adopted, a unified identity authentication system is adopted to determine whether a function organization to which a current user belongs is identified as a group user or an enterprise user by obtaining a current login user name, a customized configuration function of a function view is provided according to a user role, and a menu view is dynamically configured according to different roles. Specifically, for the role of the group user, the code of each enterprise belonging to the group, the name of the enterprise and the map boundary range summarized by all the enterprises can be obtained, and for the enterprise user, the current enterprise code, the name of the enterprise and the map boundary range of the enterprise can be automatically obtained by automatic positioning.

Further, according to the coordinates of the map boundary range, the environmental protection monitoring data of various refinery enterprises are projected and superposed in a unified mode to generate a plant production plane visual monitoring view.

In some implementations, when environmental protection control includes waste water on-line monitoring, waste gas on-line monitoring, solid useless storage site management, VOCs control, air quality control, factory boundary noise control, environmental risk source control, soil and groundwater monitoring, dirty rainwater pipeline integrated analysis's at least one, carry out environmental protection monitoring analysis based on the refinery enterprise environmental protection monitored data who acquires, still include:

step S120-1, filtering and extracting longitude and latitude data of each environment-friendly monitoring point from the environment-friendly monitoring point spatial position data, and performing coordinate projection to obtain a visual monitoring graph of each environment-friendly monitoring point;

and step S120-2, extracting a monitoring value from the monitoring service data of the environment-friendly monitoring point, and realizing the visual monitoring of the monitoring service data by combining the visual monitoring graph.

In some implementations, for online wastewater monitoring, online exhaust monitoring, or VOCs monitoring, the step S120-2 includes: extracting real-time monitoring values from monitoring service data of the environment-friendly monitoring points, judging normal points, alarm points and superscript points by combining early warning values, and obtaining visual monitoring graphs of the alarm points by combining visual monitoring graphs of the environment-friendly monitoring points;

for the solid waste storage point management, the step S120-2 includes: extracting detailed data of solid waste storage points from monitoring service data of the environment-friendly monitoring points, judging normal points and alarm points by combining solid waste storage design capacity, and obtaining visual monitoring graphs of the alarm points by combining visual monitoring graphs of all the environment-friendly monitoring points;

for air quality monitoring, step S120-2 includes: extracting the current latest air quality monitoring value from the monitoring service data of the environment-friendly monitoring points, and combining the visual monitoring graphs of all the environment-friendly monitoring points to realize visual monitoring of the air quality data;

for plant noise monitoring, step S120-2 includes: extracting a current latest monitoring value of the factory boundary noise from the monitoring service data of the environment-friendly monitoring points, judging normal points and abnormal points of the noise by combining with a noise standard value, and realizing the visual monitoring of the factory boundary noise data by combining with the visual monitoring graph of each environment-friendly monitoring point;

for environmental risk source monitoring, step S120-2 includes: extracting emergency material inventory points, accident point positions, coordinate point longitude and latitude and flow direction data of an emergency command center from the environmental protection monitoring point monitoring service data, and obtaining an emergency material visual monitoring graph by combining visual monitoring graphs of all the environmental protection monitoring points;

for soil and groundwater monitoring, step S120-2 includes: extracting soil and underground water monitoring values from the environmental protection monitoring point monitoring service data, realizing the judgment of normal points and standard exceeding points by combining standard values of all indexes corresponding to the soil and underground water monitoring values, and obtaining a visual monitoring graph of the soil and the underground water by combining the judgment result of whether the standard exceeding is achieved and the visual monitoring graph of all the environmental protection monitoring points;

aiming at comprehensive analysis of the sewage and rainwater pipeline, the step S120-2 comprises the following steps: and extracting the longitude and latitude and flow direction data of continuous coordinate points of all pipelines from the monitoring service data of the environment-friendly monitoring points, drawing dynamic flow charts of sewage lines, rain lines and accident lines by adopting a coordinate projection mode and different classification colors, and combining the visual monitoring views and the dynamic flow charts of all the pipelines to obtain a water body prevention and control comprehensive graph.

In some implementations, step S120-2 further includes:

and generating at least one of a list of the monitoring service data, a monitoring curve graph and a video of the environment-friendly monitoring point based on the visual monitoring content of the monitoring service data. And the video of the environment-friendly monitoring point is played and displayed correspondingly based on the video path address provided in the environment-friendly monitoring video data.

The following description of carrying out environmental protection monitoring analysis based on the acquired environmental protection monitoring data of the refinery enterprises is respectively carried out for wastewater online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory boundary noise monitoring, environmental risk source monitoring, soil and underground water monitoring and sewage and rainwater pipeline comprehensive analysis.

(1) Waste water on-line monitoring

The wastewater online monitoring implements hierarchical management and control, and the wastewater online monitoring process is schematically shown in fig. 4.

Firstly, acquiring a visual monitoring graph: automatically acquiring the coordinates of the map perimeter range according to the operation view range of the current user, respectively acquiring picture data in the coordinate range from national common precision image data, factory high precision image data, factory production devices and tank area vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

And secondly, filtering and extracting longitude and latitude data of the wastewater monitoring points and classification control (national control/provincial control/city control/other) types in the environmental protection monitoring point spatial position data, and obtaining a visual monitoring graph of the wastewater monitoring points by adopting a CGCS2000 coordinate projection mode.

And thirdly, acquiring monitoring service data of the environment-friendly monitoring points, extracting real-time wastewater monitoring values from the monitoring service data of the environment-friendly monitoring points, inputting wastewater early warning threshold parameters, judging normal points, warning points and standard exceeding points according to logic, and combining a visual monitoring graph of the wastewater monitoring points to realize visual monitoring of early warning and warning points.

And finally, extracting continuous time real-time monitoring values of different indexes on a visual monitoring graph of the alarm point, drawing a real-time monitoring curve graph of the wastewater discharge port, and providing a corresponding discharge port video path address from the environment-friendly monitoring video data to realize the video playing and displaying of the discharge port.

Wherein, the different indexes comprise one or more of monitoring time, COD, ammonia nitrogen, total phosphorus, total nitrogen and wastewater flow; the normal point meets the condition that the monitoring value is less than the early warning threshold value, the alarm point meets the condition that the monitoring value is greater than the early warning threshold value or the monitoring value is less than the standard value, and the standard exceeding point meets the condition that the monitoring value is greater than the standard value.

Through the process shown in fig. 4, a real-time monitoring curve diagram of the wastewater discharge port and a video playing display of the wastewater discharge port are obtained.

(2) On-line monitoring of exhaust gas

The exhaust gas on-line monitoring process is schematically shown in fig. 5.

Firstly, acquiring a visual monitoring graph: automatically acquiring the coordinates of the perimeter range of the map according to the operation view range of the current user, respectively acquiring picture data within the range from national common-precision image data, factory high-precision image data, factory production devices and tank field vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

And secondly, filtering and extracting longitude and latitude data of the exhaust gas monitoring points from the environmental protection monitoring point spatial position data, and realizing visual monitoring of the exhaust gas monitoring points by adopting a CGCS2000 coordinate projection mode to obtain a visual monitoring graph of the exhaust gas monitoring points.

And thirdly, extracting a waste gas real-time monitoring value from the monitoring service data of the environment-friendly monitoring points, inputting a waste gas early warning threshold parameter, judging normal points, alarm points and standard exceeding points according to logic, and obtaining a visual monitoring graph of the alarm points by combining with a visual monitoring graph of the waste gas monitoring points, so that visual monitoring of the early warning points is realized, and the visual monitoring graph of the alarm points is obtained.

And finally, on the visual monitoring graph of the alarm point position, extracting continuous time real-time monitoring values of different indexes, drawing a real-time monitoring curve graph of the exhaust gas discharge port, and providing a video path address of the corresponding exhaust gas discharge port from the environment-friendly monitoring data to realize video playing and displaying of the exhaust gas discharge port.

Wherein, the different indexes comprise one or more of monitoring time, nitrogen oxides, sulfur dioxide, smoke dust, non-methane total hydrocarbon and waste gas flow; the normal point meets the condition that the monitoring value is less than the early warning threshold value, the alarm point meets the condition that the monitoring value is greater than the early warning threshold value or the monitoring value is less than the standard value, and the standard exceeding point meets the condition that the monitoring value is greater than the standard value.

Through the flow shown in fig. 5, a real-time monitoring graph of the exhaust gas outlet and a video playing display of the exhaust gas outlet are obtained.

(3) Solid waste storage point management

The process of managing the solid waste storage point is schematically shown in FIG. 6.

Firstly, acquiring a visual monitoring graph: according to the current user operation view range, automatically acquiring map perimeter range coordinates, respectively acquiring picture data within ranges from national common precision image data, factory high precision image data, factory production devices and tank area vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

Secondly, in the environment-friendly monitoring point space position data service, longitude and latitude data of the solid waste storage points are filtered and extracted, the solid waste storage points are visually monitored by adopting a CGCS2000 coordinate projection mode, and a solid waste storage visual monitoring graph is obtained.

And thirdly, extracting detailed data of the solid waste storage points from the monitoring service data of the environment-friendly monitoring points, logically judging normal points and alarm points by combining with the design capacity of solid waste storage, and realizing the visual monitoring of the alarm points by combining with a visual monitoring graph of the solid waste storage points.

And finally, extracting the data of each storage type of the current storage point on the visual monitoring graph of the alarm point position to generate a storage point detail table, and providing a video path address of the corresponding solid waste storage point from the environment-friendly monitoring data to realize video playing and displaying of the storage point.

The solid waste storage point detail data comprises one or more of storage point names, design storage capacity, residual storage capacity, stored quantity, longest storage and warehousing time, storage time, dangerous waste names, dangerous waste types and accumulated storage quantity, normal points meet the condition that the stored quantity is less than the design storage quantity energy by 90%, and alarm points meet the condition that the stored quantity is more than the design storage quantity energy by 90%.

Through the flow shown in fig. 6, a detailed list of the solid waste storage points and a video display of the solid waste storage points are obtained.

(4) VOCs monitoring

The VOCs monitoring process is schematically shown in FIG. 7.

Firstly, acquiring a visual monitoring graph: automatically acquiring the coordinates of the perimeter range of the map according to the current user operation view range, respectively acquiring picture data within the range from national common-precision image data, factory high-precision image data, factory production devices and tank field vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

And secondly, filtering and extracting longitude and latitude data of the VOCs monitoring points from the environmental protection monitoring point spatial position data, and realizing visual monitoring of the VOCs monitoring points by adopting a CGCS2000 coordinate projection mode to obtain a visual monitoring graph of the VOCs monitoring points.

And thirdly, extracting real-time monitoring values and standard values of the VOCs from the monitoring service data of the environment-friendly monitoring points, judging normal points, alarm points and standard exceeding points according to logic, and combining a visual monitoring graph of the VOCs monitoring points to realize a visual monitoring graph of the alarm points.

And finally, extracting continuous time real-time monitoring values on the visual monitoring graph of the alarm point positions, drawing a monitoring curve graph when the VOCs monitoring points are drawn, and providing video path addresses of the corresponding VOCs monitoring points from the environment-friendly monitoring data to realize video playing and displaying of the VOCs monitoring points.

The VOCs real-time monitoring value comprises monitoring time and non-methane total hydrocarbons; the normal point meets the condition that the monitoring value is less than the early warning threshold value, the alarm point meets the condition that the monitoring value is greater than the early warning threshold value or the monitoring value is less than the standard value, and the standard exceeding point meets the condition that the monitoring value is greater than the standard value.

Through the process shown in fig. 7, a graph of the real-time monitoring of the VOCs monitoring points and a video playing display of the VOCs monitoring points are obtained.

(5) Air quality monitoring

The air quality monitoring process is schematically illustrated in fig. 8.

Firstly, acquiring a visual monitoring graph: according to the current user operation view range, automatically acquiring map perimeter range coordinates, respectively acquiring picture data within ranges from national common precision image data, factory high precision image data, factory production devices and tank area vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

Secondly, filtering and extracting longitude and latitude data of the air quality monitoring station from the spatial position data of the environment-friendly monitoring point, adopting CGCS2000 coordinate projection, filtering and extracting a monitoring value of the current air quality monitoring station from the monitoring service data of the environment-friendly monitoring point, and combining a visual monitoring graph of the air quality monitoring point to realize visual monitoring of the air quality data.

And thirdly, extracting the monitoring value of the current air quality monitoring station from the monitoring service data of the environment-friendly monitoring point, realizing the detailed display of the historical data of the air quality monitoring station, and providing a video path address of the air quality monitoring station from the environment-friendly monitoring data, so as to realize the video playing and displaying of the monitoring station.

The monitoring values of the air quality monitoring station comprise monitoring station information, monitoring time, monitoring factors, monitoring values and dimension units; the monitoring factors comprise sulfur dioxide, nitrogen oxides, benzene series, non-methane total hydrocarbons, hydrogen sulfide and the like.

Through the process shown in fig. 8, a real-time monitoring curve diagram of the air quality monitoring station and a video playing display of the air quality monitoring station are obtained.

(6) Plant boundary noise monitoring

The plant noise monitoring process is schematically shown in FIG. 9.

Firstly, acquiring a visual monitoring graph: according to the current user operation view range, automatically acquiring map perimeter range coordinates, respectively acquiring picture data within ranges from national common precision image data, factory high precision image data, factory production devices and tank area vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

Secondly, in the environmental protection monitoring point space position data, noise monitoring point longitude and latitude data are filtered and extracted, CGCS2000 coordinate projection is adopted, in the environmental protection monitoring point monitoring service data, current latest noise monitoring values (wherein the noise monitoring values comprise monitoring date, monitoring time (night/day), monitoring values (dB) and standard values (dB)) are filtered and extracted, and the noise normal points and abnormal points are visually monitored by combining the noise standard values and a visual monitoring graph of the factory boundary noise monitoring points.

Finally, extracting the historical monitoring values (monitoring time, monitoring value night/monitoring value day) of the current noise point from the monitoring service data of the environment-friendly monitoring points, and realizing the detailed display of the historical data of the factory boundary noise point.

Wherein, the normal point satisfies the monitoring value less than the standard value, and the abnormal point satisfies the monitoring value more than the standard value.

Through the process shown in fig. 9, a list of historical data of the site noise point location is obtained and displayed.

(7) Environmental risk source monitoring

The environmental risk source monitoring flow is schematically illustrated in fig. 10.

Firstly, acquiring a visual monitoring graph: according to the current user operation view range, automatically acquiring map perimeter range coordinates, respectively acquiring picture data within ranges from national common precision image data, factory high precision image data, factory production devices and tank area vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

Secondly, filtering and extracting longitude and latitude data of the emergency material library points in the environmental protection monitoring point space position data, realizing the visual monitoring of emergency materials by adopting a CGCS2000 coordinate projection mode, obtaining a visual monitoring graph of the emergency materials, filtering and extracting details (including material names, storage quantity, main functions, position description and states) of the emergency materials in the environmental protection monitoring point monitoring business data service, and realizing the comprehensive display of the detail list of the materials library.

And thirdly, in the environmental protection monitoring point space position data, filtering and extracting coordinate point longitude and latitude and flow direction data of all accident waterlines, sewage treatment plants, accident pools (tanks) and emergency command centers, adopting a CGCS2000 coordinate projection mode, adopting different classification colors to realize drawing of the accident waterlines, realizing dynamic monitoring of the accident waterlines and finally obtaining an environmental risk monitoring comprehensive graph.

Through the flow shown in fig. 10, a material library detail table comprehensive display and an environmental risk monitoring comprehensive graph display are obtained.

(8) Soil and groundwater monitoring

The soil and groundwater monitoring process is schematically illustrated in FIG. 11.

Firstly, acquiring a visual monitoring graph: automatically acquiring the coordinates of the perimeter range of the map according to the current user operation view range, respectively acquiring picture data within the range from national common-precision image data, factory high-precision image data, factory production devices and tank field vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

Secondly, filtering and extracting longitude and latitude data of soil and underground water sampling points in the environmental protection monitoring point spatial position data, and realizing visual monitoring of the sampling points by adopting a CGCS2000 coordinate projection mode to obtain a visual monitoring map of the soil and the underground water.

And thirdly, filtering and extracting soil/underground water monitoring values (sampling point information, sampling time, soil monitoring factors (PH, hexavalent chromium, lead, total petroleum hydrocarbon and the like), underground water monitoring factors (PH, sulfide, petroleum, benzene and the like), monitoring values, standard values and dimension units) in the monitoring service data of the environment-friendly monitoring point, judging whether the monitoring index factors exceed standards or not by combining with each index monitoring value standard, realizing a soil and underground water visual graph by combining with a judgment result, and realizing comprehensive display of the detail table of the sampling points of the soil/underground water according to the extracted sampling point monitoring values.

Through the process shown in fig. 11, a detailed list of soil/groundwater sampling points is obtained for comprehensive display.

(9) Comprehensive analysis of sewage and rainwater pipeline

The comprehensive analysis flow of the sewage and rainwater pipeline is schematically shown in fig. 12.

Firstly, acquiring a visual monitoring graph: according to the current user operation view range, automatically acquiring map perimeter range coordinates, respectively acquiring picture data within ranges from national common precision image data, factory high precision image data, factory production devices and tank area vector data according to the coordinate range, and performing unified projection superposition according to a coordinate system CGCS2000 to generate a factory production plane visual monitoring graph.

Secondly, filtering and extracting longitude and latitude data of plugging gates and rainwater pumping station points in the environmental protection monitoring point spatial position data, adopting CGCS2000 coordinate projection, filtering and extracting continuous coordinate point longitude and latitude and flow direction data of all pipelines (including sewage lines, rainwater lines and accident lines) in the environmental protection monitoring point spatial position data, adopting a CGCS2000 coordinate projection mode, adopting different classification colors to realize the drawing of the sewage lines, the rainwater lines and the accident lines, carrying out digital twinning on spatial topological relations of various pipelines and environmental protection facilities of enterprises in actual production, and combining operation states of the pipelines and the environmental protection facilities to obtain a water body prevention and control comprehensive graph.

And obtaining a water body prevention and control comprehensive diagram through the process shown in fig. 12.

In some implementations, when the environmental protection monitoring includes the monitoring of the comprehensive index, the environmental protection monitoring is performed based on the acquired environmental protection monitoring data of the refinery enterprise, including:

acquiring standard-reaching rate calculation parameters, transmission rate calculation parameters and equipment integrity rate calculation parameters of each environmental protection monitoring point from monitoring service data of the environmental protection monitoring points, and calculating the total standard-reaching rate, transmission rate and equipment integrity rate of each enterprise respectively; and

and generating an enterprise comprehensive ranking view according to a preset sorting rule.

Specifically, in the example of the integrated indicator monitoring process shown in fig. 13, in combination with real-time monitoring data of pollution sources such as wastewater and waste gas, according to requirements of parameters calculated by standard-reaching rate, transmission rate and equipment integrity rate, standard-reaching rate calculation parameters (effective standard-reaching flow received by each discharge port and effective flow received by each discharge port), transmission rate calculation parameters (number of data received by each discharge port, number of data to be received by each discharge port and number of data stopped by each discharge port), and equipment integrity rate calculation parameters (normal operation time of respective monitoring equipment, total operation time of respective monitoring equipment, and stop operation time of respective monitoring equipment) are obtained from monitoring service data of an environmental protection monitoring point, and the total standard-reaching rate, transmission rate and equipment integrity rate of an enterprise are calculated respectively according to the following calculation formulas:

the standard reaching rate = sum of actual received effective standard reaching flow/sum of actual received effective flow of the enterprise;

the transmission rate = the number of data actually received by the enterprise/(the number of data to be received-outage data);

equipment integrity = enterprise automatic monitoring equipment uptime/(total uptime-down time).

And the enterprise sets a sequencing rule according to the comprehensive index, and generates an enterprise comprehensive ranking graph by combining the calculation index.

And S130, outputting the content of the environmental protection monitoring to the terminal equipment for displaying.

In some implementations, a Web browser and Android operating system based mobile terminal presentation scheme is provided. The results output by the comprehensive environment-friendly monitoring and analyzing system mainly comprise a GIS map, a graph, a data table and a video, and output display solutions of the four results are respectively provided, as shown in fig. 14.

First, GIS map display technology

(1) Dividing a GIS map into layers according to the types of point elements, line elements and surface elements;

(2) Extracting and analyzing longitude and latitude information of different types of layer elements;

(3) Converting the longitude and latitude into Web mercator projection;

(4) Transforming longitude and latitude into Web mercator projection;

(5) Converting world plane points into tile pixel coordinates;

(6) Converting tile pixel coordinates into tile row and column numbers;

(7) And obtaining the tile picture corresponding to the row and column number of the corresponding tile.

Secondly, the graphic display technology

(1) Extracting an X and Y value sequence of a graph to be drawn;

(2) The two-dimensional graphic canvas draws the positions of x and y points one by one;

(3) And configuring canvas colors, coordinate axis labels, styles, grid lines and the like.

Third, data table display technology

(1) Extracting two-dimensional data information;

(2) Drawing a data table head item;

(3) Drawing forms such as table width, frame, color and the like;

(4) Fill data into the table.

Fourthly, video display technology

(1) Acquiring video streaming media data through a path;

(2) Loading a video playing plug-in;

(3) And displaying and playing the streaming media data.

The four achievements are combined with HTML5, javaScript and CSS conventional Web development technologies to realize the conversion and size adaptation of computer graphic data and PC terminal pixel data and complete the output display and application at the PC terminal; native JAVA and C + + development technologies are combined, conversion and size adaptation of computer graphics data and pixel data of the mobile terminal are achieved, and output display and application of the mobile terminal are completed.

In practical application, the method can be implemented as an environment-friendly monitoring platform for an refinery enterprise as shown in fig. 15, environment-friendly monitoring data of the refinery enterprise is accessed to the platform through an integrated access module, various environment-friendly monitoring services are performed based on the obtained environment-friendly monitoring data of the refinery enterprise, and the content of environment-friendly monitoring is output to terminal devices such as a mobile phone and a PC terminal for displaying, so that the purpose of providing a monitoring scheme for the environment-friendly comprehensive supervision of the refinery enterprise is achieved.

The method provided by the embodiment realizes the unified management and monitoring of the multi-source pollution source data, changes the disorder of data management through a unified geographic information system platform and a unified data standard, and realizes the applications of pollution source data query, statistics, thematic map making, spatial analysis and the like. The geographic information space service is provided, the geographic information sharing services such as navigation, visualization, space analysis, decision support and the like are realized through the interface function of a geographic information system, the information communication and business cooperation among departments and enterprises are enhanced, and the aim of improving the efficiency is fulfilled. And part of typical service application functions are supported, and spatial information support is provided for service work and management decisions through comprehensive analysis and display of spatial data and service data, so that part of typical service application functions are realized.

Example two

Correspondingly to the embodiment, this embodiment provides an environmental protection monitoring system for an refining enterprise, which in practical application can be implemented as an environmental protection monitoring platform for an refining enterprise as shown in fig. 15, as shown in fig. 16, and the system includes:

the integrated access module 210 is used for integrated access to the environmental protection monitoring data of the refinery enterprise; the environmental protection monitoring data of the refinery enterprise comprises the following data: at least one of national image data, factory production device and tank area vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data;

the environmental protection monitoring and analyzing module 220 is used for carrying out environmental protection monitoring and analyzing based on the acquired environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring analysis comprises the following steps: at least one of waste water online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring;

and a terminal display module 230, configured to output the results of the environmental monitoring analysis to the terminal device for display.

The integrated access module 210 realizes unified data integration, and specifically obtains national common precision image data, factory high precision image data, factory production device and tank field vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data, and environmental protection monitoring video data. The national common precision image data is accessed from the existing Chinese petrochemical geographic information service platform by adopting a Restful standard protocol, the plant area high precision image data, the plant area production device and the tank area vector data are integrated and accessed from the existing Chinese petrochemical environmental protection geographic information service platform by adopting an OGC standard protocol (an international map standard protocol), the environmental protection monitoring point spatial position data and the environmental protection monitoring point monitoring service data are acquired from the existing Chinese petrochemical environmental protection service database by adopting a WebService protocol, the environmental protection monitoring video data is accessed from the existing Chinese petrochemical video monitoring platform by adopting the Restful standard protocol, and the schematic diagram of the integrated access of the environmental protection monitoring data of the refinery enterprises is shown in figure 2.

It should be understood that the chinese petrochemical geographic information service platform provides a national common precision image data service, the chinese petrochemical environmental protection geographic information service platform provides a plant area high precision image data service, a plant area production device and a tank area vector data service, the chinese petrochemical environmental protection service database provides an environmental protection monitoring point spatial position data service and an environmental protection monitoring point monitoring service data service, and the chinese petrochemical video monitoring platform provides an environmental protection monitoring video data service.

Further, comprehensive monitoring analysis is carried out on the basis of integrating and accessing environmental protection monitoring data of the refinery enterprises, services such as map-based wastewater online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis, comprehensive index monitoring technology and the like are provided, and a user cockpit configuration solution is provided.

In some implementations, the system provides a user cockpit configuration solution, obtains a current login user name, and determines a functional organization to which the current login user belongs; if the function organization to which the user currently logged in belongs is a group, providing a menu function view corresponding to the group user, so as to obtain the code of each enterprise belonging to the group, the name of the enterprise and the map boundary range summarized by all the enterprises; and if the function mechanism of the currently logged-in user is an enterprise, acquiring the enterprise code, the enterprise name and a map boundary range in the enterprise map boundary range.

In this embodiment, a solution for configuring a user cockpit as shown in fig. 3 is provided, a menu customization technology based on a role authority authentication function is adopted, a unified identity authentication system is adopted to determine whether a function organization to which a current user belongs is identified as a group user or an enterprise user by obtaining a current login user name, a customized configuration function of a function view is provided according to a user role, and a menu view is dynamically configured according to different roles. Specifically, for the group user role, the enterprise codes, the enterprise names and the map boundary ranges summarized by all enterprises belonging to the group can be obtained, and for the enterprise users, the current enterprise codes and the enterprise names can be automatically obtained, and the current enterprise map boundary ranges can be automatically positioned and obtained.

Further, the environmental monitoring analysis module 220 performs unified projection and superposition on the environmental monitoring data of various refining enterprises according to the coordinates of the map boundary range, so as to generate a plant production plane visual monitoring view.

In some implementations, when environmental protection monitoring analysis includes waste water on-line monitoring, waste gas on-line monitoring, solid useless storage site management, VOCs control, air quality control, factory boundary noise control, environmental risk source control, soil and groundwater monitoring, dirty rainwater pipeline integrated analysis at least one, carry out environmental protection monitoring analysis based on the environmental protection monitoring data of the refinery enterprise who acquires, still include:

filtering and extracting longitude and latitude data of each environment-friendly monitoring point from the space position data of the environment-friendly monitoring points, and performing coordinate projection to obtain a visual monitoring view of each environment-friendly monitoring point;

extracting a real-time monitoring value from the monitoring service data of the environment-friendly monitoring point, inputting an early warning threshold parameter, judging a normal point, an alarm point and/or a standard exceeding point according to logic, and obtaining an early warning monitoring view based on a visual monitoring view.

In some implementations, the method may further include:

a graph, a list, and/or a video is generated based on the monitoring values in the early warning monitoring view.

In some implementation manners, the video is generated based on the monitoring value in the early warning monitoring view, and corresponding video playing and displaying are performed based on the video path address provided in the environmental protection monitoring video data.

It should be understood that the apparatus of the present embodiment provides all of the benefits of the method embodiments.

Those skilled in the art will appreciate that the modules or steps described above can be implemented using a general purpose computing device, that they can be centralized on a single computing device or distributed across a network of computing devices, and that they can alternatively be implemented using program code executable by a computing device, such that the program code is stored in a memory device and executed by a computing device, and the program code is then separately fabricated into various integrated circuit modules, or multiple modules or steps are fabricated into a single integrated circuit module. The present invention is not limited to any specific combination of hardware and software.

EXAMPLE III

Embodiments of the present invention provide a storage medium, where a computer program is stored, and when the computer program is executed by one or more processors, the method of the first embodiment is implemented.

In this embodiment, the storage medium may be implemented by any type of volatile or nonvolatile storage device or combination thereof, such as a Static Random Access Memory (SRAM), an Electrically Erasable Programmable Read-Only Memory (EEPROM), an Erasable Programmable Read-Only Memory (EPROM), a Programmable Read-Only Memory (PROM), a Read-Only Memory (ROM), a magnetic Memory, a flash Memory, a magnetic disk, or an optical disk. The content of the method is described in the first embodiment, and is not described herein again.

Example four

The present embodiment provides an electronic device, which includes a memory and one or more processors, where the memory stores thereon a computer program, and the computer program, when executed by the one or more processors, implements the method of the first embodiment.

In practical application, the electronic device may be a mobile phone, a tablet computer, or other terminal device. In this embodiment, the Processor may be an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a controller, a microcontroller, a microprocessor, or other electronic components, and is configured to perform the method in the above embodiments. The method implemented when the computer program running on the processor is executed may refer to the specific embodiment of the method provided in the foregoing embodiment of the present invention, and details thereof are not described herein.

The embodiment of the invention aims at the environment-friendly comprehensive supervision requirement of refining enterprises, adopts geographic information and multidimensional visualization technical means, presents two-stage leading cockpit application of groups and enterprises through data unified integration, meets the data-based business scene customization and index management and control analysis of users, realizes the classification monitoring of three wastes, environmental risks, emergency and the like of enterprises based on geographic information distribution, comprises pollutant emission monitoring and video monitoring of pollutant such as pollutant distribution, waste water, waste gas, solid waste, VOCs and the like, monitors the flow direction and indexes of the sewage/rainwater/accident water of the enterprises, monitors major environmental risk sources, dynamically monitors emergency resources and the like, and supports the management and decision of implementing the process management and control of environment-friendly business.

According to the comprehensive environment-friendly data monitoring scheme based on the Geographic Information System (GIS) technology, disclosed by the embodiment of the invention, a model of each topic space database for environment-friendly monitoring is established, environment-friendly monitoring space data is combined with the Geographic position of a related enterprise entity, and space position Information is combined with environment-friendly monitoring service data. By means of the GIS space analysis technology, environment-friendly monitoring space data imaging and informatization are achieved, data analysis efficiency is improved, and comprehensive early warning alarm information is pushed quickly. The method can support the visualization and digitization of real-time monitoring on environmental management by enterprises, improve the environmental risk pre-alarm disposal rate, help to schedule environmental resources by using the audio and video technology, can be further popularized to the process industry with petrochemical industry similar production backgrounds, and has higher commercial popularization value.

In the embodiments provided in the present invention, it should be understood that the disclosed system and method can be implemented in other ways. The system and method embodiments described above are merely illustrative.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising one of 8230; \8230;" 8230; "does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

Although the embodiments of the present invention have been described above, the above descriptions are only for the convenience of understanding the present invention, and are not intended to limit the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. An environmental protection monitoring method for refining and chemical enterprises is characterized by comprising the following steps:

integrating and accessing environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring data of the refining enterprise comprises the following data: at least one of national image data, factory production device and tank field vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data;

performing environmental protection monitoring analysis based on the acquired environmental protection monitoring data of the refining enterprise; the environmental protection monitoring comprises: at least one of waste water online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring;

and outputting the results of the environmental protection monitoring analysis to the terminal equipment for display.

2. The environmental protection monitoring method for refining enterprises according to claim 1, wherein the environmental protection monitoring analysis based on the obtained environmental protection monitoring data for refining enterprises comprises:

acquiring a currently logged-in user name, and determining a function mechanism to which the currently logged-in user belongs;

if the function organization to which the user currently logged in belongs is a group, providing a menu function view corresponding to the group user, so as to obtain the code of each enterprise belonging to the group, the name of the enterprise and the map boundary range summarized by all the enterprises;

and if the function mechanism of the currently logged-in user is an enterprise, acquiring the enterprise code, the enterprise name and a map boundary range in the enterprise map boundary range.

3. The environmental protection monitoring method for the refining enterprise according to claim 2, wherein the environmental protection monitoring analysis is performed based on the obtained environmental protection monitoring data for the refining enterprise, further comprising:

and performing unified projection superposition on various refinery enterprise environment protection monitoring data according to the coordinates of the map boundary range to generate a plant production plane visual monitoring view.

4. The refinery enterprise environmental protection monitoring method of claim 3, wherein the environmental protection monitoring analysis comprises: waste water on-line monitoring, waste gas on-line monitoring, solid useless storage site management, VOCs control, air quality control, factory boundary noise control, environmental risk source control, soil and groundwater monitoring, dirty rainwater pipeline integrated analysis when at least one, carry out environmental protection monitoring analysis based on the refinery enterprise environmental protection monitored data who acquires, still include:

filtering and extracting longitude and latitude data of each environmental protection monitoring point from the environmental protection monitoring point spatial position data, and performing coordinate projection to obtain a visual monitoring graph of each environmental protection monitoring point;

and extracting a monitoring value from the monitoring service data of the environment-friendly monitoring point, and combining the visual monitoring graph to realize visual monitoring of the monitoring service data.

5. The environmental monitoring method of refining enterprises according to claim 4,

aiming at online wastewater monitoring, online waste gas monitoring or VOCs monitoring, the steps of extracting a monitoring value from monitoring service data of an environment-friendly monitoring point and combining the visual monitoring graph to realize visual monitoring of the monitoring service data comprise: extracting real-time monitoring values from monitoring service data of the environment-friendly monitoring points, judging normal points, alarm points and superscript points by combining early warning values, and obtaining visual monitoring graphs of the alarm points by combining visual monitoring graphs of the environment-friendly monitoring points;

aiming at the management of solid waste storage points, the steps of extracting monitoring values from the monitoring service data of the environment-friendly monitoring points and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprise: extracting detailed data of solid waste storage points from monitoring service data of the environment-friendly monitoring points, judging normal points and alarm points by combining solid waste storage design capacity, and obtaining visual monitoring graphs of the alarm points by combining the visual monitoring graphs of the environment-friendly monitoring points;

aiming at the air quality monitoring, the step of extracting the monitoring value from the monitoring service data of the environmental protection monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprises the following steps: extracting the current latest air quality monitoring value from the environmental protection monitoring point monitoring service data, and combining the visual monitoring graph of each environmental protection monitoring point to realize visual monitoring of the air quality data;

aiming at the monitoring of the factory boundary noise, the steps of extracting the monitoring value from the monitoring service data of the environment-friendly monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprise: extracting a current latest factory boundary noise monitoring value from the environmental protection monitoring point monitoring service data, combining the noise standard value to judge a noise normal point and an abnormal point, and combining the visual monitoring graph of each environmental protection monitoring point to realize the visual monitoring of the factory boundary noise data;

aiming at the monitoring of the environmental risk source, the steps of extracting the monitoring value from the monitoring service data of the environmental protection monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprise: extracting coordinate point longitude and latitude and flow direction data of an emergency material inventory point, an accident point position and an emergency command center from the monitoring service data of the environment-friendly monitoring points, and obtaining an emergency material visual monitoring graph by combining visual monitoring graphs of all the environment-friendly monitoring points;

aiming at soil and underground water monitoring, the steps of extracting monitoring values from monitoring service data of environment-friendly monitoring points and combining the visual monitoring graph to realize visual monitoring of the monitoring service data comprise: extracting soil and underground water monitoring values from the environmental protection monitoring point monitoring service data, determining whether normal points and superscript points exceed standards by combining standard values of all indexes corresponding to the soil and underground water monitoring values, and obtaining a visual monitoring graph of the soil and the underground water by combining a judgment result of whether the normal points and the superscript points exceed the standards and a visual monitoring graph of each environmental protection monitoring point;

aiming at the comprehensive analysis of the sewage and rainwater pipeline, the step of extracting the monitoring value from the monitoring service data of the environment-friendly monitoring point and combining the visual monitoring graph to realize the visual monitoring of the monitoring service data comprises the following steps: and extracting the longitude and latitude and flow direction data of continuous coordinate points of all pipelines from the monitoring service data of the environment-friendly monitoring points, drawing dynamic flow charts of sewage lines, rain lines and accident lines by adopting a coordinate projection mode and different classification colors, and combining the visual monitoring views and the dynamic flow charts of all the pipelines to obtain a water body prevention and control comprehensive graph.

6. The refinery enterprise environment-friendly monitoring method according to claim 5, wherein the step of extracting the monitoring value from the monitoring service data of the environment-friendly monitoring point and implementing the visual monitoring of the monitoring service data by combining the visual monitoring graph further comprises:

and generating at least one of a list of the monitoring service data, a monitoring curve graph and a video of the environment-friendly monitoring point based on the visual monitoring content of the monitoring service data.

7. The environmental protection monitoring method for refining enterprises according to claim 1, wherein when the environmental protection monitoring analysis includes comprehensive index monitoring, the environmental protection monitoring analysis based on the obtained environmental protection monitoring data for refining enterprises includes:

acquiring standard-reaching rate calculation parameters, transmission rate calculation parameters and equipment integrity rate calculation parameters of each environmental protection monitoring point from monitoring service data of the environmental protection monitoring points, and calculating the total standard-reaching rate, transmission rate and equipment integrity rate of each enterprise respectively;

and generating an enterprise comprehensive ranking view according to a preset ordering rule.

8. An environmental protection monitoring system for refining and chemical enterprises is characterized by comprising:

the integrated access module is used for integrated access to environmental protection monitoring data of the refining enterprise; the environmental protection monitoring data of the refinery enterprise comprises the following data: at least one of national image data, factory production device and tank area vector data, environmental protection monitoring point spatial position data, environmental protection monitoring point monitoring service data and environmental protection monitoring video data;

the environmental protection monitoring and analyzing module is used for carrying out environmental protection monitoring and analysis based on the acquired environmental protection monitoring data of the refinery enterprises; the environmental protection monitoring comprises: at least one of waste water online monitoring, waste gas online monitoring, solid waste storage point management, VOCs monitoring, air quality monitoring, factory noise monitoring, environmental risk source monitoring, soil and underground water monitoring, sewage and rainwater pipeline comprehensive analysis and comprehensive index monitoring;

and the terminal display module is used for outputting the results of the environmental protection monitoring analysis to the terminal equipment for display.

9. A storage medium having stored thereon a computer program which, when executed by one or more processors, implements a method as claimed in any one of claims 1 to 7.

10. An electronic device comprising one or more processors and memory having stored thereon a computer program that, when executed by the one or more processors, implements the method of any of claims 1-7.

Images