CN113595238A - Low-carbon polymerization regulation and control system and method for intelligent power distribution cabinet (box) and terminal device - Google Patents

Abstract

The invention discloses a low-carbon polymerization regulation and control system, method and terminal device for an intelligent power distribution cabinet (cabinet), which are used for analyzing the running characteristics of all resources in a regional energy system and forming an optimized management control function suitable for the intelligent power distribution cabinet (cabinet). The system comprises modules such as non-invasive load identification, low-carbon polymerization regulation and control, new energy power transmission, equipment facility intelligent control, data center station and the like. The invention can accurately identify the load information by a non-invasive identification technology, and can reduce the use of a large number of sensors. The method comprises the steps of constructing a regional multi-resource collaborative optimization model by taking economy and environmental protection as target conditions, solving the model through a double-quantum differential calculation, Pareto optimal and non-inferior sequencing and a maximum satisfaction degree decision algorithm, and then carrying out online solving based on a prediction control model to realize low-carbon and energy-saving utilization of energy. And by utilizing the internet technology, the power distribution cabinet (box) is hierarchically interacted with the upper-layer power distribution center and the edge server, the energy conservation and carbon reduction of a regional system are promoted, and a brand-new energy conservation and carbon reduction optimization management function is provided for the power distribution cabinet (box).

Description

Low-carbon polymerization regulation and control system and method for intelligent power distribution cabinet (box) and terminal device

Technical Field

The invention relates to an energy internet, in particular to a low-carbon polymerization regulation and control system, method and terminal device for an intelligent power distribution cabinet (box), and belongs to the technical field of energy intelligent management and control.

Background

Energy is one of important powers for promoting social development and progress, and along with the increasing total energy consumption, the environmental problem is increasingly serious, and the problem of energy shortage is increasingly prominent, so that the energy is a global problem, and for this reason, all countries in the world continuously explore measures for realizing environmental protection, energy conservation and emission reduction.

With the continuous development of social economy, the regional power load is continuously increased, equipment is developed towards the direction of high capacity and high current, the energy consumption is continuously increased, and the stability of a power grid is continuously impacted. In the process of optimizing and controlling the equipment, the intelligent power grid plays an important role. In the development process of recent years, the computer technology, the information collection technology, the sensor technology, the mobile communication technology and the like in China are rapidly pushed forward, and the speed of the construction and development of the smart power grid in China is promoted. In the intelligent arrangement process of the intelligent power grid, an intelligent power distribution cabinet (box) is a very important link. The intelligent power distribution cabinet (box) can comprehensively improve the power supply working quality of the intelligent power grid in normal power supply work, and simultaneously has good protection effect on the power supply working safety of the whole distribution network. The intelligent power distribution cabinet (box) ensures that the used equipment has higher intelligent control performance, comprehensively improves the intelligent operation of the power distribution cabinet (box), fully exerts the intelligent control effect of the power distribution cabinet (box), ensures the real-time exchange and transmission of power supply and distribution data parameters, reduces the energy consumption of the equipment, and improves the energy utilization rate.

Currently, researchers are working on multifunctional power distribution cabinets (cabinets), wherein a patent document with a research bulletin number of CN112701587A discloses a power distribution cabinet with a temperature monitoring function, but no specific regulation and control measures are taken for the power distribution cabinet according to the collected temperature information; although patent document with publication number CN112736677A has the function of controlling fan power heat dissipation for temperature rise, there are no various terminals connected with the power distribution cabinet, and it is difficult to satisfy the new requirement of intelligent management interaction, and the above multifunctional power distribution cabinet (box) has the problem of single and simple function, and there is only a function of optimally controlling and scheduling the devices in the jurisdiction of the power distribution cabinet (box). Therefore, under the large background of energy conservation and emission reduction and smart power grids, it is necessary to research a smart power distribution cabinet (box) with intelligent control and optimization functions.

In order to solve the problems, the invention provides a low-carbon polymerization regulation and control system and method for an intelligent power distribution cabinet (box) and a terminal device. On the basis of a traditional intelligent power distribution cabinet (box), a fused non-invasive load identification module is constructed, various types of load information and power consumption of the load information are accurately identified through analysis of regional power data, the use of a large number of sensors can be reduced, and the intelligent power distribution cabinet has the characteristics of safety and high efficiency; by constructing a low-carbon aggregation regulation and control module, on the premise of preferentially consuming distribution network distributed energy, the low-carbon and high-efficiency cooperation of regional distributed electric energy and flexible load is promoted, an optimal power transmission plan and a load optimal energy efficiency report are generated, the efficient and energy-saving use of equipment is promoted, and the energy utilization efficiency is improved; the intelligent control module of the equipment facilities is fused for intelligently and integrally controlling the public power utilization facilities of the distribution network, such as lighting equipment, a central air conditioner, a central hot water system and an intelligent socket, so that the energy conservation and carbon reduction of the regional system are promoted.

Disclosure of Invention

In order to solve the technical problems, the invention provides a low-carbon polymerization regulation and control system, a low-carbon polymerization regulation and control method and a terminal device for an intelligent power distribution cabinet (box), aiming at the defects of the prior art.

In order to achieve the technical purpose and achieve the technical effect, the invention is realized by the following technical scheme:

a low-carbon polymerization regulation and control system, a low-carbon polymerization regulation and control method and a terminal device for an intelligent power distribution cabinet (box) are established by taking an optimized management control function suitable for the intelligent power distribution cabinet (box) as a core and considering the operation characteristics of various distributed power generation, electric vehicle charging piles, energy storage, adjustable flexible loads and other equipment in a regional scene.

The utility model provides an intelligent power distribution cabinet (case) low carbon polymerization regulation and control system includes: the system comprises a data acquisition module, a data storage module, a non-invasive load identification module, a multi-dimensional feature extraction module, an artificial intelligence classification aggregation module, an intelligent index prediction module, a low-carbon aggregation regulation and control module, a new energy power transfer module, an equipment facility intelligent control module, a data center module and a communication module. The specific functions are as follows:

the data acquisition module carries out data perception and transmission through Ethernet TCP/IP communication protocol and regional temperature sensor, luminance sensor, distributed energy monitor terminal, energy storage system monitor terminal to and multi-functional intelligent ammeter of each floor building, smart jack, is used for regional distributed power generation system, fills electric pile, energy storage, load electric power data acquisition, and to regional scene temperature, luminance environmental data acquisition.

And the data storage module is used for storing the regional power data and the environmental data and generating a historical data query library.

The non-invasive load identification module is used for processing the original power data of the area, accurately identifying various types of load information and power consumption of the load information, reducing the use of a large number of sensors, and being safe and efficient.

And the multi-dimensional feature extraction module is used for mining the multi-dimensional features of the regional power data and extracting various regional power supplies and load active power, running states and adjustable values in multiple periods.

And the artificial intelligence classification and aggregation module is used for realizing the classification and aggregation of the regional multi-class power supply and the load similar characteristics by using an artificial intelligence algorithm and comprehensively evaluating the processed data.

The intelligent index prediction module is used for accurately predicting output information data, energy storage state information, charging pile state information, user energy utilization rules, flexible load period information, weather information and energy price information of the distributed power supply in a future period of time in the region.

The low-carbon aggregation regulation and control module is used for promoting low-carbon and high-efficiency cooperation of the regional distributed electric energy and the flexible load on the premise of preferentially consuming the regional distributed energy, obtaining an optimal power transmission plan, generating a regional optimal energy efficiency report based on predicted regional environment data, promoting efficient and energy-saving use of equipment, and improving energy utilization efficiency.

And the new energy electric power retransfer module is used for retransferring the surplus new energy generated energy which is not completely consumed in the region to an upper layer dispatching center so as to realize the bidirectional interaction between the region and the upper layer.

And the equipment facility intelligent control module is used for intelligently and integrally controlling regional electric equipment facilities, performing disaggregation analysis through the edge server based on the optimal energy efficiency report, and decomposing and issuing a scheduling instruction to each resource, namely intelligently controlling regional public facilities such as lighting equipment, a central air conditioner, a central hot water system and an intelligent socket.

And the data center module is used for realizing the convergence and integration of regional energy efficiency data, the visualization of data and the manifestation of data value.

And the communication module is used for information transmission among the modules, information interaction between a power distribution cabinet (box) system and a power distribution dispatching center, and information interaction between the power distribution system and customer mobile equipment.

A low-carbon polymerization regulation and control method for an intelligent power distribution cabinet (box) comprises the following steps:

step 1: acquiring power data and environmental data in an area through a data acquisition module, wherein the power data and the environmental data comprise a distributed power supply, a charging pile, energy storage, load power data, environmental temperature and brightness data;

step 2: accurately identifying various types of load information and power consumption thereof through a non-invasive load identification module, and performing similar characteristic classification and aggregation on various types of power supplies and loads in an area through a multi-dimensional characteristic extraction module and a classification and aggregation module;

and step 3: performing ultra-short term prediction on distributed power output information, user energy usage rule, flexible load period information, weather information and energy price information based on classified and aggregated data information;

and 4, step 4: on the premise of preferential consumption of the distributed power supply, a regional source load storage cooperative optimization model is established, then, through a prediction control model, the real-time data information and the prediction information in the step 3 are obtained through a data acquisition module, the relevant parameters of the system are updated, online solution is carried out, and a control sequence is obtained through solution.

And 5: and repeating the steps at each sampling moment, transmitting the power transmission information to an upper-layer power distribution center and a new energy power transmission module through a communication module, generating an optimal energy efficiency report, and transmitting the optimal energy efficiency report to an equipment facility intelligent control module through the communication module.

Step 6: the optimal power transmission plan is sent to an upper power distribution center and a new energy power transmission module through a communication module, bidirectional interaction between a regional system and the upper power distribution center is promoted, an optimal energy efficiency report is transmitted to an edge server through the communication module, the edge server sends a decomposition instruction through depolymerization, and intelligent regulation and control are carried out on a regional intelligent light modulator, a central air-conditioning controller, a central hot water system intelligent controller and an intelligent socket.

Finally, various data and energy efficiency management information are transmitted to a data center station through a communication module, and the data visualization is realized through a power distribution cabinet (box) door display unit.

The intelligent power distribution cabinet (cabinet) low-carbon polymerization regulation and control terminal device comprises a processor and a storage module for storing a program, wherein the processor is configured to execute the intelligent power distribution cabinet (cabinet) low-carbon polymerization regulation and control method.

The invention has the following beneficial effects: on the basis of a traditional intelligent power distribution cabinet (box), by fusing a non-invasive load identification module, various types of load information and power consumption of the load information are accurately identified through analysis of regional power data, so that the use of a large number of sensors can be reduced, and the intelligent power distribution cabinet has the characteristics of safety and high efficiency; by constructing a low-carbon aggregation regulation module, on the premise of preferentially absorbing distribution network distributed energy, the low-carbon and high-efficiency cooperation of regional distributed electric energy and flexible load is promoted, an optimal power transmission plan and a load optimal energy efficiency report are generated, the efficient and energy-saving use of equipment is promoted, and the energy utilization efficiency is improved; the intelligent control module of the integrated equipment facilities is used for intelligently and integrally controlling the public power utilization facilities of the distribution network, such as lighting equipment, a central air conditioner, a central hot water system and an intelligent socket, so that the energy conservation and carbon reduction of the regional system are promoted.

Drawings

Fig. 1 is a structural block diagram of a low-carbon aggregation regulation and control system of an intelligent power distribution cabinet (box).

FIG. 2 is a flow chart of a low-carbon polymerization regulation and control method for an intelligent power distribution cabinet (box) of the invention.

Detailed Description

The present invention will be described in further detail by the following specific embodiments, which are illustrative only and not limiting, and the scope of the present invention is not limited thereby. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

The embodiment is a low-carbon aggregation regulation and control system, method and terminal device for an intelligent power distribution cabinet (box), and combines with fig. 1, and the system comprises a data acquisition module 101, a data storage module 102, a non-invasive load identification module 103, a multi-dimensional feature extraction module 104, an artificial intelligence classification aggregation module 105, an intelligent index prediction module 106, a low-carbon aggregation regulation and control module 107, a new energy power reverse delivery module 108, an equipment facility intelligent control module 109 and a data center platform module 110.

The data acquisition module 101 is connected with the multifunctional intelligent electric meter, the intelligent socket, the temperature sensor, the brightness sensor, the distributed energy monitoring terminal and the energy storage system monitoring terminal through an Ethernet RCP/IP communication protocol, and is used for acquiring regional distributed power generation systems, charging piles, energy storage and load electric power data and acquiring regional scene temperature and brightness environment data.

And the data storage module 102 is connected with the data acquisition module 101 through the ethernet, and is used for storing the distribution network power data and the regional scene environment data and generating a historical data query library.

The non-invasive load identification module 103 is connected with the data acquisition module 101 through the communication module, and is used for processing the regional original power data, accurately identifying various types of load information and power consumption thereof, reducing the use of a large number of sensors, and being safe and efficient.

And the multidimensional feature extraction module 104 is connected with the non-invasive load identification module 103 through a communication module and is used for mining multidimensional features of electric power data in the region and extracting active power, running state and adjustable value of various electric power sources and loads in the region in multiple time periods.

And the artificial intelligence classification and aggregation module 105 is connected with the multi-dimensional feature extraction module 104 through a communication module, is based on a k-means cluster analysis algorithm, and is used for realizing the classification and aggregation of similar features of regional multi-class power supplies and loads and comprehensively evaluating the processed data.

And the intelligent index prediction module 106 is connected with the classification aggregation module 105 through a communication module and is used for accurately predicting the distributed power output information data, the user energy utilization rule, the flexible load time period information, the weather information and the energy price information of the region in a future period.

The low-carbon aggregation control module 107 is connected with the intelligent index prediction module 106 through the communication module, and is used for promoting low-carbon and efficient coordination of regional distributed electric energy and load on the premise of preferentially consuming regional distributed energy, obtaining an optimal power transmission plan, and generating a regional flexible load optimal energy efficiency report based on predicted regional environment data.

And the new energy electric power retransfer module 108 is connected with the low-carbon aggregation regulation and control module through the communication module, and is used for retransferring surplus new energy generated energy which is not completely consumed in the area to an upper-layer dispatching center according to an optimized optimal power transmission plan result so as to realize bidirectional interaction between the area and an upper layer.

The equipment facility intelligent control module 109 is connected with the low-carbon aggregation regulation and control module 107 through the communication module and used for intelligently and integrally controlling regional electric equipment facilities, transmitting the optimal energy efficiency report to the edge server through the communication module, and issuing a decomposition instruction through the edge server to perform energy-saving regulation on a building intelligent dimmer, a central air-conditioning intelligent controller, a central hot water system intelligent controller and an intelligent socket.

The data center station module 110 is connected with the low-carbon polymerization regulation and control module 107 through the communication module and used for achieving regional energy efficiency data aggregation integration, data visualization and data value reappearance, the data center station module 110 is connected with the cabinet door display unit through the communication module, and visualization of low-carbon polymerization functions of the power distribution cabinet (box) is achieved through the cabinet door display unit.

As a specific implementation method, a low-carbon polymerization regulation and control method for an intelligent power distribution cabinet (box) mainly includes the following steps in combination with fig. 2:

step 1: the method comprises the steps that data collection is carried out on a multifunctional intelligent electric meter, an intelligent socket, a distributed energy monitoring terminal, an energy storage system monitoring terminal, a brightness sensor and a temperature sensor, main collected data comprise distributed power supply active power output information, charging pile output power information, energy storage system state information, electric quantity information for load equipment, environment temperature and brightness information, and the data information is transmitted to a memory;

step 2: aiming at the power consumption information of load equipment, fitting a daily load curve according to sampling points, identifying various types of load information and power consumption thereof by using a non-invasive load identification method, extracting multidimensional characteristics of various types of data based on a target area marking method, and performing similar characteristic classification and aggregation on regional mass data information based on a K-means artificial intelligence algorithm;

and step 3: performing ultra-short term prediction on distributed power output information, user energy usage rule, flexible load period information, environment information and energy price information based on classified and aggregated data information;

and 4, step 4: considering economy and environmental protection as target conditions, a distributed energy, charging pile, energy storage and load collaborative optimization model is constructed, the model comprises the operation cost, energy consumption cost, electricity purchasing cost and carbon emission penalty cost of equipment, and the model is solved through parallel computation, a dual-quantum differential computation algorithm, Pareto optimal non-inferior ranking and a maximum satisfaction degree decision algorithm to obtain an optimal energy management day-ahead scheduling plan. And then based on the prediction control model, obtaining real-time data information and the prediction information in the step 3 according to the data acquisition module, updating relevant parameters of the system, carrying out online solving, and solving to obtain a control sequence.

And 5: and repeating the steps at each sampling moment to obtain an optimal real-time power transmission plan, sending the optimal power transmission plan to the new energy power transmission module through the communication module, generating an optimal energy efficiency report of the flexible load according to the optimal scheduling plan and the environmental parameters, and sending the optimal energy efficiency report to the intelligent control module of the equipment facility through the communication module.

Step 6: the optimal power transmission plan is sent to an upper power distribution center and a new energy power transmission module through a communication module, bidirectional interaction between a regional system and the upper power distribution center is promoted, an optimal energy efficiency report is transmitted to an edge server through the communication module, the edge server sends a decomposition instruction through depolymerization, energy-saving adjustment is carried out on an intelligent light modulator, a central air-conditioning intelligent controller, a central hot water system intelligent controller and an intelligent socket of a regional scene, and an intelligent energy utilization scheme aiming at energy conservation and carbon reduction is generated.

Finally, various data and energy efficiency management information are transmitted to a data center station through a communication module, and the data visualization is realized through a power distribution cabinet (box) door display unit.

The embodiment of the present disclosure further provides an intelligent power distribution cabinet (cabinet) low-carbon aggregation regulation and control terminal device, which includes a processor and a storage module for storing a program, where the processor is configured to execute the intelligent power distribution cabinet (cabinet) low-carbon aggregation regulation and control method described in any one of the above implementations, and the storage module may store a computer program so that the processor executes an instruction.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (9)

1. The utility model provides an intelligent power distribution cabinet (case) low carbon polymerization regulation and control system which characterized in that, the system includes:

the data acquisition module is used for acquiring data of a distributed power generation system, a charging pile, energy storage and load power in a region and acquiring data of the temperature and brightness of the environment in the region;

the data storage module is used for storing regional power data and environmental data and generating a historical data query library;

the non-invasive load identification module is used for processing the original power data collected in the area and accurately identifying various types of load information and power consumption thereof;

the multi-dimensional feature extraction module is used for mining the multi-dimensional features of the regional power data and extracting various regional power supplies and load active power, running states and adjustable values in multiple periods;

the artificial intelligence classification and aggregation module is used for realizing the classification and aggregation of similar characteristics of regional multi-class power supplies and loads and carrying out comprehensive evaluation on the processed data;

the intelligent index prediction module is used for accurately predicting distributed power output information data, energy storage state information, charging pile state information, user energy utilization rules, flexible load period information, weather information and energy price information of a region in a future period of time;

the low-carbon polymerization regulation and control module is used for acquiring an optimal power transmission plan and an optimal energy efficiency report of a region, promoting efficient and energy-saving use of equipment and improving energy utilization efficiency;

the new energy electric power retransfer module is used for retransferring the surplus new energy generated energy which is not completely consumed in the area to an upper-layer dispatching center;

the intelligent control module of the equipment facilities is used for intelligently and integrally controlling the regional electric equipment facilities, namely intelligently controlling regional public facilities such as lighting equipment, a central air conditioner, a central hot water system and an intelligent socket;

the data center module is used for realizing the convergence and integration of regional energy efficiency data, the visualization of data and the reappearance of data value;

and the communication module is used for information transmission among the modules, information interaction between a power distribution cabinet (box) system and a power distribution dispatching center, and information interaction between the power distribution system and customer mobile equipment.

2. A low-carbon polymerization regulation and control method for an intelligent power distribution cabinet (cabinet) is characterized by comprising the following steps:

step 1: carrying out data acquisition;

step 2: according to a non-invasive identification method, carrying out feature extraction and classification aggregation on the data;

and step 3: performing ultra-short term prediction on distributed power output information, user energy utilization rules, flexible load period information, weather information and energy price information based on the classification and aggregation result;

and 4, step 4: establishing a regional source load storage cooperative optimization model based on the ultra-short term prediction result, then updating relevant parameters of the system according to the data information and the ultra-short term prediction result through a prediction control model, and performing online solution to obtain a control sequence;

and 5: repeating the steps at each sampling moment to generate an optimal power transmission information and an optimal energy efficiency report;

step 6: and respectively sending the optimal power transmission plan and the most energy efficiency report to an upper power distribution center, a new energy power back-off module and an edge server through a communication module, and interacting with the upper power distribution center and the regional intelligent controller.

3. The low-carbon polymerization regulation and control method for the intelligent power distribution cabinet (cabinet) according to claim 2, characterized in that: the method comprises the following steps that 1, distribution network power data and environment data are obtained through a data acquisition module, and data sensing and transmission are carried out through an Ethernet TCP/IP communication protocol, a region temperature sensor, a brightness sensor, a distributed energy monitoring terminal and an energy storage system monitoring terminal, as well as a multifunctional intelligent electric meter and an intelligent socket of each layer of building.

4. The low-carbon polymerization regulation and control method for the intelligent power distribution cabinet (cabinet) according to claim 2, characterized in that: and 2, accurately identifying various types of load information and power consumption thereof through a non-invasive load identification module, and performing similar characteristic classification and aggregation on various types of power supplies and loads of the distribution network through a multi-dimensional characteristic extraction module and a classification and aggregation module.

5. The low-carbon polymerization regulation and control method for the intelligent power distribution cabinet (cabinet) according to claim 2, characterized in that: and 3, performing ultra-short-term prediction on the distributed power output information, the user energy utilization rule, the flexible load time period information, the weather information and the energy price information based on the classified and aggregated data information.

6. The low-carbon polymerization regulation and control method for the intelligent power distribution cabinet (cabinet) according to claim 2, characterized in that: and 4, on the premise of preferential consumption of the distributed power supply, establishing a regional source load storage cooperative optimization model, then updating relevant parameters of the system according to the real-time data information acquired by the data acquisition module and the prediction information in the step 3 through the prediction control model, and performing online solution to obtain a control sequence.

7. The low-carbon polymerization regulation and control method for the intelligent power distribution cabinet (cabinet) according to claim 2, characterized in that: and 5, repeating the steps at each sampling moment, transmitting the power transmission information to an upper-layer power distribution center and a new energy power transmission module through a communication module, generating an optimal energy efficiency report, and transmitting the optimal energy efficiency report to an equipment facility intelligent control module through the communication module.

8. The low-carbon polymerization regulation and control method for the intelligent power distribution cabinet (cabinet) according to claim 2, characterized in that: the step 6: the optimal power transmission plan is sent to an upper power distribution center and a new energy power transmission module through a communication module, bidirectional interaction between a regional system and the upper power distribution center is promoted, an optimal energy efficiency report is transmitted to an edge server through the communication module, the edge server sends a decomposition instruction through depolymerization, and intelligent regulation and control are carried out on a regional intelligent light modulator, a central air-conditioning controller, a central hot water system intelligent controller and an intelligent socket.

9. An intelligent power distribution cabinet (cabinet) low-carbon polymerization regulation terminal device, characterized in that the terminal device comprises a processor and a storage module for storing programs, wherein the processor is configured to implement the method of any one of claims 2 to 8.

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