CN110675071A - Large-scale enterprise comprehensive energy consumption visual information control system - Google Patents
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Abstract
The invention discloses a large-scale enterprise comprehensive energy consumption visual information control system, which comprises: the system comprises a building energy consumption system, a transmission network and a data acquisition subsystem, wherein the data acquisition subsystem is connected with the building energy consumption system through the transmission network; the building energy consumption system comprises an energy consumption data center, an energy consumption application system, an application programming interface gateway and a terminal, wherein the terminal is connected with the energy consumption application system; the energy consumption application system comprises a monitoring module and a structural energy-saving module, wherein the monitoring module monitors a building or an area in the building by taking the building as a unit; the structure energy-saving module takes equipment in a building as a unit and compares the equipment, raw materials, tasks and energy consumption conditions; and the data acquisition subsystem comprises intelligent communication equipment and acquisition equipment, wherein the acquisition equipment is connected with the intelligent communication equipment, and the intelligent communication equipment is connected with the energy consumption data center.
Description
Technical Field
The invention relates to an energy consumption information control system, in particular to a control system for comprehensive energy consumption visual information of a large enterprise.
Background
With the development of economy in China, the phenomenon of industrial energy consumption is not ignored, and various comprehensive visual energy consumption systems developed therewith realize energy conservation and emission reduction by acquiring and processing various classified energy consumption data such as electric power, gas, water and the like and analyzing energy consumption conditions. However, for a large enterprise, it is difficult for a manager to comprehensively and intuitively know the conditions of each branch factory, each workshop and large energy consumption equipment of the enterprise, for example, the manager cannot know the relationship between the material consumption of a production workshop, the product completion rate and the energy consumption, so that the energy consumption is caused by equipment problems such as equipment idling, equipment aging and the like, and the energy consumption is indirectly caused by the problems of material waste, low yield and the like caused by the material problems such as material quality, material quantity and the like; the manager can not well control the energy consumption through the production, use and other links, and can not reversely deduce the rationality of the production, use and other links from the energy consumption.
Finally, in the management process, a manager cannot decompose the energy consumption planning task of the enterprise to each production department and workshop, so that the responsibility of energy-saving work is clear, the energy cost proportion of the enterprise cannot be known, and the development trend of energy consumption cannot be mastered.
Disclosure of Invention
In order to solve the defects of the prior art and realize the aim of comprehensive energy consumption control of large enterprises, the invention adopts the following technical scheme:
the visual information control system of large-scale enterprise's comprehensive energy consumption includes: the system comprises a building energy consumption system, a transmission network and a data acquisition subsystem, wherein the data acquisition subsystem is connected with the building energy consumption system through the transmission network.
The building energy consumption system comprises an energy consumption data center, an energy consumption application system, an Application Programming Interface (API) gateway and a terminal, wherein the terminal is connected with the energy consumption application system, the API gateway is connected between the building energy consumption system and the energy consumption data center, and the energy consumption data center is connected with the data acquisition subsystem.
The energy consumption application system comprises a monitoring module and a structural energy-saving module, wherein the monitoring module monitors a building or an area in the building by taking the building or the area as a unit; the manager can know the energy consumption of each branch factory, each department and even each post. The structural energy-saving module takes equipment in a building as a unit and compares the relation between the equipment, raw materials, tasks and energy consumption; the manager can well control the energy consumption through the production, use and other links, and the rationality of the production, use and other links is also deduced from the energy consumption.
The data acquisition subsystem comprises intelligent communication equipment and acquisition equipment, wherein the acquisition equipment is connected with the intelligent communication equipment, and the intelligent communication equipment is connected with the energy consumption data center.
The API gateway is configured to control the energy consumption application system to call a WebApi (Web application programming Interface), where the WebApi is a corresponding Interface that is called when the energy consumption application system obtains different data from the energy consumption data center.
The transmission network comprises a wired network and a wireless network.
The energy consumption data center adopts a fault transfer cluster and is used for hot standby of the database.
The dual-computer hot standby adopts the separation of database reading and writing, the main database only performs writing operation, and the slave data only performs reading operation. The server pressure is balanced, the logic complexity is reduced, and the server performance is improved.
The energy consumption data center adopts remote dictionary service as a cache layer to accelerate application access. The data buffer function is realized when the data volume is large.
The energy consumption data center adopts data table partitioning. The efficiency of data retrieval is improved, the total amount of data reading and writing is reduced so as to shorten the response time, and data management and maintenance are facilitated.
The energy consumption data center is erected at the cloud end. The energy consumption data center can be matched with different business systems in a large enterprise or business personnel systems of related units outside the enterprise to realize the reusability of data; one energy consumption data center can provide data for a plurality of service systems, and the plurality of service systems can acquire the data from the energy consumption data center.
The energy consumption application system is erected at the cloud end. When the energy consumption application system is large, the cloud server can be erected on a plurality of cloud servers at the cloud end, and the expandability, stability and reliability of the cloud technology are utilized.
The architecture of the energy consumption application system comprises a UI (User Interface) Layer, a BLL (Business logic Layer), a DAL (Data Access Layer), a DBUtility (Data Access abstraction class) and a Model (entity) Layer, wherein the BLL is connected between the UI Layer and the DAL, and the DBUtility is connected between the DAL and the database.
The DAL is an operation method on data, and provides data services to the BLL through operations on the database.
The BLL is used for processing and exchanging data between the UI layer and the DAL.
And the UI layer is used for displaying information and receiving the information of the user.
The DBUtility comprises a universal code for accessing the database, and the universal code is called by the DAL to access the database.
And the Model layer is used for data transmission among the layers.
When the BLL calls the DAL, an object of the DAL needs to be instantiated, and a method for operating the database returned by the DAL is obtained through the object of the DAL; and the UI layer instantiates the object of the BLL, and calls the method obtained by the BLL through the object of the BLL so as to obtain the value returned by the method. The layered structure is used for decoupling, is convenient for finding and modifying problems, simplifies complex problems, is convenient for maintaining and upgrading, and is beneficial to cooperative development of the system.
The architecture of the energy consumption application system further includes an Interface Data Access Layer (IDAL) and a Data Access Layer (Data Access Factory class).
The IDAL is an interface layer of the DAL abstracted out, the IDAL being connected between the BLL and the DAL.
The DALFactual is a factory that creates an object of the DAL, and is connected to the BLL, the IDAL, and the DAL, respectively.
And when the BLL calls the DAL, directly declaring an interface of the IDAL, and the DALFactual acquires an object of the DAL according to the interface and returns the object to the BLL. In complex logic, modification and maintenance are facilitated.
The DALFactual creates the object of the DAL by reflection, at which time the DALFactual connects to the BLL, IDAL.
The reflection is to dynamically load the program set of the DAL through the name of the program set to complete dynamic object creation; when the database is replaced, the database is convenient to modify and maintain.
The assembly name is written in a configuration file, and the DALFactual acquires the assembly name from the configuration file. When the database is replaced, the name of the program set in the DALFactual is not required to be modified, and only the configuration file is required to be modified.
The invention has the advantages and beneficial effects that:
through the large-scale enterprise comprehensive energy consumption visual information control system, a manager can know the energy consumption conditions of each branch factory, each department and even each individual post; can well control the energy consumption through links such as production, use and the like, and also reversely deduces the rationality of the links such as production, use and the like from the energy consumption. The database read-write separation adopted by the system can balance the pressure of the server, reduce the logic complexity and improve the performance of the server; the data table partition adopted by the system improves the efficiency of data retrieval, reduces the total amount of data reading and writing to shorten the response time, and facilitates data management and maintenance. The system adopts a layered structure for decoupling, is convenient for finding and modifying problems, simplifying complex problems, being convenient for maintaining and upgrading and being beneficial to the cooperative development of the system.
Drawings
FIG. 1 is a diagram showing the construction of the system of the present invention.
Fig. 2 is a diagram of the architecture of the energy consuming application system of the present invention.
FIG. 3 is a diagram of the architecture of the energy consuming application system with the addition of IDAL and DALFacotry in accordance with the present invention.
Fig. 4 is a diagram of the architecture of the energy consuming application system after reflection is used by the DALFacotry in the present invention.
Detailed Description
The invention is described in detail below with reference to the figures and the embodiments.
As shown in fig. 1, the visualized information control system for the comprehensive energy consumption of the large-scale enterprise of the present invention includes: the system comprises a building energy consumption system, a transmission network and a data acquisition subsystem, wherein the data acquisition subsystem is connected with the building energy consumption system through the transmission network.
The building energy consumption system comprises an energy consumption data center, an energy consumption application system, an API gateway and a terminal, wherein the terminal is connected with the energy consumption application system, the API gateway is connected between the building energy consumption system and the energy consumption data center, and the energy consumption data center is connected with the data acquisition subsystem.
The terminal comprises a display device, a computer, a mobile intelligent terminal and the like, and is connected with the energy consumption application system through an intranet, wherein the intranet is a wired or wireless network based on a Transmission Control Protocol (TCP).
The energy consumption application system comprises a monitoring module and a structural energy-saving module, wherein the monitoring module monitors a building or an area in the building by taking the building or the area as a unit; the manager can know the energy consumption of each branch factory, each department and even each post. The structural energy-saving module takes equipment in a building as a unit and compares the relation between the equipment, raw materials, tasks and energy consumption; the manager can well control the energy consumption through the production, use and other links, and the rationality of the production, use and other links is reversely deduced from the energy consumption; for example, a manager can know the relation between the energy consumption of the production equipment and the production task, so that the energy consumption indirectly caused by the problems of equipment idling, equipment aging and the like, material waste caused by material problems such as material quality, material quantity and the like, low yield and the like can be found.
The data acquisition subsystem, including intelligent communication machine, collection equipment with the intelligent communication machine passes through the RS-485 interface, adopts the Modbus communication protocol to carry out the communication connection, and the Modbus communication protocol supports wired, wireless, carrier communication, has adopted the odd-even check code, the intelligent communication machine with energy consumption data center carries out the communication through wired net or GPRS and connects.
The collecting equipment comprises a remote transmission gas meter, a remote transmission water meter, a temperature integrating instrument, a cold/heat meter, a steam flow meter and an electric power meter.
The API gateway is used for controlling the energy consumption application system to call a WebApi, and the WebApi is a corresponding interface called when the energy consumption application system obtains different data from the energy consumption data center.
The transmission network comprises a wired network and a wireless network.
The energy consumption data center adopts an always fault transfer cluster and is used for hot standby of the database.
The dual-computer hot standby adopts the separation of database reading and writing, the main database only performs writing operation, and the slave data only performs reading operation. The server pressure is balanced, the logic complexity is reduced, and the server performance is improved. When the two servers are in hot standby, if the database of the master server is operated, the database of the slave server is unidirectionally and synchronously fed, the pressure of the master server is high, and the slave server has free resources; if the databases of the master and slave servers are synchronized bi-directionally, the logic is very complex and performance is also greatly reduced.
The energy consumption data center adopts Redis (REmote DIctionary Server) as a cache layer to accelerate application access. The data buffer function is realized when the data volume is large.
The energy consumption data center adopts data table partitioning. The method mainly partitions a data table with a plurality of data records and frequent operation, such as: and collecting a real-time meter, a water flow meter, an hour meter, a day meter and a month meter. The efficiency of data retrieval is improved, the total amount of data reading and writing is reduced so as to shorten the response time, and data management and maintenance are facilitated.
The energy consumption data center is erected at the cloud end. The energy consumption data center can be matched with different business systems in a large enterprise or business personnel systems of related units outside the enterprise to realize the reusability of data; one energy consumption data center can provide data for a plurality of service systems, and the plurality of service systems can acquire the data from the energy consumption data center.
The energy consumption application system is erected at the cloud end. When the energy consumption application system is large, the cloud server can be erected on a plurality of cloud servers in the cloud, and the expandability, stability and reliability of the cloud technology, such as capacity expansion, performance expansion, load balancing, data backup and the like, are utilized.
As shown in fig. 2, the architecture of the energy consumption application system includes a UI (User Interface) Layer, a BLL (Business Logic Layer), a DAL (Data Access Layer), a DBUtility (Data Access abstract class), and a Model (entity) Layer, where the BLL is connected between the UI Layer and the DAL, and the DBUtility is connected between the DAL and the database.
The DAL is an operation method on data, and provides data services to the BLL through operations on the database.
The BLL is used for processing and exchanging data between the UI layer and the DAL.
And the UI layer is used for displaying information and receiving the information of the user.
The DBUtility comprises a universal code for accessing the database, and the universal code is called by the DAL to access the database. DBUtility contains a SqlHelper class, which is called by the data access class in the DAL to access the database.
The Model layer is used for data transmission among the layers; the Model can store complex data.
When the BLL calls the DAL, an object of the DAL needs to be instantiated, and a method for operating the database returned by the DAL is obtained through the object of the DAL; and the UI layer instantiates the object of the BLL, and calls the method obtained by the BLL through the object of the BLL so as to obtain the value returned by the method. The layered structure is used for decoupling, and the problem is convenient to find and modify; simplifying the complex problem; the maintenance and the upgrade are convenient; and the cooperative development of the system is facilitated.
As shown in fig. 3, the architecture of the energy consumption application system further includes an Interface Data Access Layer (IDAL) and a Data Access Layer (dalfactiory).
The IDAL is an interface layer of the DAL abstracted out, the IDAL being connected between the BLL and the DAL.
The DALFactual is a factory that creates an object of the DAL, and is connected to the BLL, the IDAL, and the DAL, respectively.
And when the BLL calls the DAL, directly declaring an interface of the IDAL, and the DALFactual acquires an object of the DAL according to the interface and returns the object to the BLL. In a complex logic, when the DAL object changes, the object of the DAL instantiated in the BLL needs to be modified, and once the object of the DAL is modified, the objects of the DAL at all positions need to be modified, which is inconvenient; after adding IDAL, when DAL has change, only need to modify the object returned in DALFactual.
The dalfacory creates the objects of the DAL by reflection, at which point the dalfacory connects to the BLL, IDAL as shown in fig. 4.
The reflection is to dynamically load the program set of the DAL through the name of the program set to complete dynamic object creation; when the database is changed, the DAL is also changed, the reference needs to be added again, and the codes in the DALFactual are modified again, so that the database is inconvenient; after the DALFactual adopts reflection, the database can be changed only by modifying the name of the dynamically loaded program set in the DALFactual.
The assembly name is written in a configuration file, and the DALFactual acquires the assembly name from the configuration file. When the database is replaced, the name of the program set in the DALFactual is not required to be modified, and only the configuration file is required to be modified.
Claims (10)
1. The visual information control system of large-scale enterprise's comprehensive energy consumption includes: building energy consumption system, transmission network, data acquisition subsystem, its characterized in that: the data acquisition subsystem is connected with the building energy consumption system through the transmission network;
the building energy consumption system comprises an energy consumption data center, an energy consumption application system, an application programming interface gateway and a terminal, wherein the terminal is connected with the energy consumption application system, the application programming interface gateway is connected between the building energy consumption system and the energy consumption data center, and the energy consumption data center is connected with the data acquisition subsystem;
the energy consumption application system comprises a monitoring module and a structural energy-saving module, wherein the monitoring module monitors a building or an area in the building by taking the building or the area as a unit; the structural energy-saving module takes equipment in a building as a unit and compares the relation between the equipment, raw materials, tasks and energy consumption;
the data acquisition subsystem comprises intelligent communication equipment and acquisition equipment, wherein the acquisition equipment is connected with the intelligent communication equipment, and the intelligent communication equipment is connected with the energy consumption data center;
the application programming interface gateway is used for controlling the energy consumption application system to call a webpage application programming interface, and the webpage application programming interface is a corresponding interface called when the energy consumption application system acquires different data from the energy consumption data center;
the transmission network comprises a wired network and a wireless network.
2. The visual information control system for the comprehensive energy consumption of the large-scale enterprise according to claim 1, wherein the energy consumption data center adopts a failover cluster for dual-computer hot standby.
3. The visual information control system for the comprehensive energy consumption of the large-scale enterprise as claimed in claim 2, wherein the dual-computer hot standby adopts the separation of database reading and writing, the main database only performs writing operation, and the slave data only performs reading operation.
4. The visual information control system of the large-scale enterprise integrated energy consumption according to claim 1, wherein the energy consumption data center employs a remote dictionary service as a cache layer for access by an acceleration application.
5. The visual information control system for the integrated energy consumption of the large enterprise according to claim 1, wherein the energy consumption data center is partitioned by a data table.
6. The visual information control system of the comprehensive energy consumption of the large enterprise according to claim 1, wherein the energy consumption data center is erected in the cloud.
7. The visual information control system of the comprehensive energy consumption of the large enterprise according to claim 1, wherein the energy consumption application system is erected in the cloud.
8. The large-scale enterprise integrated energy consumption visualization information control system according to any one of claims 1-7, wherein the architecture of the energy consumption application system includes a user interface layer, a business logic layer, a data access abstraction class, and a physical layer, the business logic layer is connected between the user interface layer and the data access layer, and the data access abstraction class is connected between the data access layer and the database;
the data access layer is a data operation method and provides data service for the business logic layer through the operation of the database;
the service logic layer is used for processing and exchanging data between the user interface layer and the data access layer;
the user interface layer is used for displaying information and receiving the information of a user;
the data access abstract class comprises a general code for accessing the database, and is called by the data access layer to access the database;
the physical layer is used for data transmission among the layers;
when the business logic layer calls the data access layer, an object of the data access layer needs to be instantiated, and a method for operating the database returned by the data access layer is obtained through the object of the data access layer; and the user interface layer instantiates the object of the service logic layer, and calls the method obtained by the service logic layer through the object of the service logic layer so as to obtain the value returned by the method.
9. The visual information control system for the integrated energy consumption of the large-scale enterprise according to claim 8, wherein the architecture of the energy consumption application system further comprises a data access interface layer, a data access factory class;
the data access interface layer is an abstracted interface layer of the data access layer and is connected between the service logic layer and the data access layer;
the data access factory class is a factory for creating an object of the data access layer and is respectively connected with the business logic layer, the data access interface layer and the data access layer;
and when the service logic layer calls the data access layer, directly declaring an interface of the data access interface layer, and the data access factory class acquires an object of the data access layer according to the interface and returns the object to the service logic layer.
10. The visual information control system for the integrated energy consumption of the large enterprise according to claim 9, wherein the data access factory class creates the object of the data access layer through reflection, and at this time, the data access factory class is connected with the business logic layer and the data access interface layer;
the reflection is to dynamically load the program set of the data access layer through the name of the program set to complete dynamic object creation;
the assembly name is written in a configuration file, and the data access factory class obtains the assembly name from the configuration file.
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Application publication date: 20200110 |