CN202906977U - A storage access system of electric energy using efficiency data - Google Patents

Abstract

The utility model provides a storage and access system for power consumption and energy efficiency data. By assigning priority levels to packaged data and optimizing the data storage strategy, the storage efficiency of power consumption and energy efficiency data is improved; synchronous storage improves the storage quality of power consumption and energy efficiency data. It also greatly increases the efficiency of extracting energy efficiency data, ensures the integrity of energy efficiency data, and ensures the smooth operation of the system.

Description

A storage and access system for energy efficiency data

technical field

The utility model belongs to the field of electric power data collection and storage, in particular to a storage and access system for power consumption and energy efficiency data.

Background technique

The power consumption energy efficiency management system is based on the data collection of power consumption information, realizes the monitoring, management, analysis and information release of energy consumption data within the jurisdiction, and provides users with diversified services such as energy use strategies and energy use auxiliary decision-making, and realizes A distributed database application system that promotes and applies energy-saving technologies to end users.

In such a large-scale database application system, there are various types of real-time data collected, and the total amount of data is huge, involving smart meter collection, smart home electricity consumption collection, distributed power supply data collection, charging pile charging data collection, etc. Generally, the system adopts a disordered data storage method. Due to the huge amount of data, the database runs under high load for a long time, resulting in slow response of real-time functions and poor user experience.

On the other hand, because the collection server, application server, and database server of the system are often deployed in different places, the network topology among them is relatively complicated. If the collection data is stored in the database according to the general process, once the network abnormality or application If there is a problem between modules and the data cannot be stored in the database normally, it will cause data loss, affect the data access efficiency of the system, and even affect the operation effect of the entire system. However, the compensatory collection and storage of missing data by the system after the network abnormality or software abnormality recovery reduces the operating efficiency of the system.

Therefore, how to meet the data access requirements of users for frequent use and other real-time functions while ensuring the efficiency of data information storage, improve data access efficiency, and enable users to obtain the best experience has become an urgent problem to be solved.

Utility model content

In order to overcome the deficiencies of the above-mentioned prior art, the utility model provides a storage and access system for power consumption and energy efficiency data. By assigning priority levels to packaged data and optimizing the data storage strategy, the storage efficiency of power consumption and energy efficiency data is improved; Storage improves the storage quality of energy efficiency data, and also greatly increases the efficiency of extracting energy efficiency data, ensuring the integrity of energy efficiency data and ensuring the smooth operation of the system.

In order to achieve the above object, the utility model takes the following scheme:

A storage and access system for power consumption efficiency data, the system includes a pre-acquisition server, an interface server, a control scheduling server, a distributed cache server, and a database server; the pre-acquisition server encapsulates the collected data in the collection subsystem , and call the interface server to input the packaged data into the control scheduling server, after the control scheduling server receives and analyzes the system event information, assigns the priority level of the packaged data, and stores the packaged data allocated according to the priority level to the distributed cache server at the same time and database server.

The acquisition subsystem uploads the acquisition data to the front-end acquisition server through the power optical fiber network, and the front-end acquisition server includes a data acquisition front-end server, a time synchronization front-end server and a control front-end server. The setting server receives the collection data, the time synchronization front-end server performs network time synchronization with the collection subsystem, and the control front-end server controls the data collection front-end server and the time synchronization front-end server.

The pre-acquisition server and the control scheduling server exchange encapsulation data through the interface server.

The system event information includes the type/frequency/size of access data, the overall operating status of the system and the load status of the database.

The collection subsystem includes an intelligent building energy efficiency management subsystem, an intelligent community management subsystem and a large user electricity consumption information collection subsystem.

The collected data includes energy efficiency data of intelligent buildings, energy efficiency data of intelligent communities and electricity consumption information of large users.

The smart building energy efficiency data includes measurement meter information, electricity information, demand information, event records and energy efficiency management evaluation information.

The energy efficiency data of the smart community includes information on the power consumption of household appliances, information on the operating status of household appliances, information on the power quality of smart home appliances, and charging information on charging piles in the community.

The power consumption information of large users includes internal power distribution information of large users, power quality information, power consumption information and operating status information of electric equipment.

The control scheduling server includes an interaction module, a processing module, a storage execution module and a cache execution module, and the interaction module reads the system event information stored in the local disk file or receives a control command input from the user to obtain the system event information and Control information, and send the system event information and control information to the processing module; at the same time, the interaction module receives and parses the packaged data or the data request from the client, and inputs the parsed data into the processing module; the processing The module receives the system event information and control information, forms correspondence information with the analysis data, and saves the correspondence information to the storage execution module or cache execution module; the database execution module receives the correspondence information, and encapsulates The data is stored in the database server, or the encapsulated data is obtained from the database server according to the data request; the cache execution module receives the corresponding relationship information, and stores and accesses the distributed cache.

Compared with the prior art, the utility model has the beneficial effects of:

1. The present invention optimizes the data storage strategy by assigning priority levels to packaged data, and improves the storage efficiency of power consumption and energy efficiency data;

2. The synchronous storage of the distributed cache server and the database server improves the storage quality of the energy efficiency data, and also greatly increases the efficiency of extracting the energy efficiency data, ensuring the integrity of the energy efficiency data and ensuring the smooth operation of the system;

3. The system for storing and accessing energy efficiency data provided by the present invention is simple, easy to implement, high in possibility and widely used.

Description of drawings

FIG. 1 is a structural diagram of a storage and access system for energy efficiency data in an embodiment of the present invention;

Fig. 2 is a functional structural diagram of the control scheduling server in the embodiment of the present invention.

Detailed ways

Below in conjunction with accompanying drawing, the utility model is described in further detail.

As shown in Fig. 1, a storage and access system of electricity energy efficiency data, the system includes a pre-acquisition server, an interface server, a control scheduling server, a distributed cache server, and a database server; Encapsulate in the system, and call the interface server to input the encapsulated data into the control scheduling server. After receiving and analyzing the system event information, the control scheduling server assigns the priority level of the encapsulated data, and simultaneously stores the encapsulated data allocated according to the priority level in the Distributed cache server and database server.

The acquisition subsystem uploads the acquisition data to the front-end acquisition server through the power optical fiber network, and the front-end acquisition server includes a data acquisition front-end server, a time synchronization front-end server and a control front-end server. The setting server receives the collection data, the time synchronization front-end server performs network time synchronization with the collection subsystem, and the control front-end server controls the data collection front-end server and the time synchronization front-end server.

The pre-acquisition server and the control scheduling server exchange encapsulation data through the interface server.

The system event information includes the type/frequency/size of access data, the overall operating status of the system and the load status of the database.

The collection subsystem includes an intelligent building energy efficiency management subsystem, an intelligent community management subsystem and a large user electricity consumption information collection subsystem.

The collected data includes energy efficiency data of intelligent buildings, energy efficiency data of intelligent communities and electricity consumption information of large users.

The smart building energy efficiency data includes measurement meter information, electricity information, demand information, event records and energy efficiency management evaluation information.

The energy efficiency data of the smart community includes information on the power consumption of household appliances, information on the operating status of household appliances, information on the power quality of smart home appliances, and charging information on charging piles in the community.

The power consumption information of large users includes internal power distribution information of large users, power quality information, power consumption information and operating status information of electric equipment.

As shown in Figure 2, the control scheduling server includes an interaction module, a processing module, a storage execution module and a cache execution module, and the interaction module reads the system event information stored in the local disk file or receives a control command input from the user to obtain System event information and control information, and send the system event information and control information to the processing module; at the same time, the interaction module receives and parses the encapsulated data or the data request from the client, and inputs the parsed data into the processing module The processing module receives the system event information and control information, forms correspondence information with the analysis data, and saves the correspondence information to the storage execution module or cache execution module; the database execution module receives the correspondence information , and store the encapsulated data in the database server, or obtain the encapsulated data from the database server according to the data request; the cache execution module receives the corresponding relationship information, and stores and accesses the distributed cache.

Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present utility model and not to limit them. Although the present utility model has been described in detail with reference to the above embodiments, those of ordinary skill in the art should understand that: it is still possible Any modification or equivalent replacement made to the specific implementation of the present utility model without departing from the spirit and scope of the present utility model shall be covered by the claims of the present utility model.

Claims (10)

1. A storage and access system for electricity energy efficiency data, characterized in that: the system includes a pre-acquisition server, an interface server, a control scheduling server, a distributed cache server, and a database server; the pre-acquisition server collects data in Encapsulation is carried out in the acquisition subsystem, and the interface server is called to input the encapsulated data into the control scheduling server. After the control scheduling server receives and analyzes the system event information, it assigns the priority level of the encapsulated data, and the encapsulated data allocated according to the priority level is simultaneously Stored in the distributed cache server and database server. the 2. The storage and access system for power consumption and energy efficiency data according to claim 1, wherein the collection subsystem uploads the collection data to the front-end collection server through the power optical fiber network, and the front-end collection server includes The data collection front-end server, the time synchronization front-end server and the control front-end server, the data collection front-end server receives the collected data, the time synchronization front-end server performs network time synchronization with the collection subsystem, and the The control front-end server controls the data collection front-end server and the time synchronization front-end server. the 3. The storage and access system for power consumption and energy efficiency data according to claim 1, characterized in that: said pre-acquisition server and control scheduling server exchange packaged data through said interface server. the 4. The storage and access system for power consumption and energy efficiency data according to claim 1, wherein the system event information includes the type/frequency/size of the access data, the overall operating status of the system and the load of the database. the 5. The storage and access system for electricity energy efficiency data according to claim 1 or 2, characterized in that: the collection subsystem includes an intelligent building energy efficiency management subsystem, an intelligent community management subsystem, and a large user electricity consumption information collection sub-system system. the 6. The system for storing and accessing power consumption and energy efficiency data according to claim 1 or 2, wherein the collected data includes energy efficiency data of smart buildings, energy efficiency data of smart communities and electricity consumption information of large users. the 7. The storage and access system for power consumption and energy efficiency data according to claim 6, wherein the energy efficiency data for smart buildings includes meter information, electricity information, demand information, event records, and energy efficiency management evaluation information. the 8. The storage and access system for power consumption energy efficiency data according to claim 6, characterized in that: said smart community energy efficiency data includes household appliance power consumption information, household appliance operating status information, smart home appliance power quality information and community charging Pile charging information. the 9. The storage and access system for power consumption energy efficiency data according to claim 6, characterized in that: the power consumption information of large users includes internal power distribution information of large users, power quality information, power consumption information and operation of electric equipment status information. the 10. The storage and access system of power consumption and energy efficiency data according to claim 1, characterized in that: the control scheduling server includes an interaction module, a processing module, a database execution module and a cache execution module, and the interaction module reads and saves in The system event information in the local disk file or the control command input from the user is received, the system event information and control information are obtained, and the system event information and control information are sent to the processing module; at the same time, the interaction module receives and analyzes the Encapsulate the data or the data request from the client, and input the analysis data into the processing module; the processing module receives the system event information and control information, forms correspondence information with the analysis data, and saves the correspondence information to the storage execution module or the cache execution module; the database execution module receives the corresponding relationship information, and stores the encapsulated data in the database server, or obtains the encapsulated data from the database server according to the data request; the cache execution module receives the corresponding relationship information, And store and access the distributed cache. the

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