Distributed resource aggregation apparatus
The distributed resource aggregation device, designed in a unitized and modular manner, solves the problems of insufficient functional coverage and compatibility of existing devices, realizes flexible assembly forms and reduces deployment costs, and provides a distributed resource aggregation and control system that can adapt to different engineering needs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- GLOBAL ENERGY INTERCONNECTION RES INST CO LTD
- Filing Date
- 2022-11-18
- Publication Date
- 2026-07-10
AI Technical Summary
Existing distributed resource aggregation devices have shortcomings in terms of functional coverage and compatibility, resulting in high deployment costs and difficulty in adapting to newly built and renovated distributed resource aggregation projects.
The distributed resource aggregation device, which adopts a unitized and modular design, includes an aggregation control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit. The combination of these units enables flexible assembly and enhances the applicability of the device.
It has improved the functional coverage and compatibility of the device, reduced deployment costs, adapted to different application scenarios and engineering needs, and achieved a smooth evolution of the distributed resource aggregation and control system.
Smart Images

Figure CN115733250B_ABST
Abstract
Description
Technical Field
[0001] The embodiments of the present invention relate to the field of distributed resource processing, and more particularly to a distributed resource aggregation device. Background Technology
[0002] Against the backdrop of "dual carbon" goals and the construction of a new power system dominated by new energy sources, the effective aggregation and allocation of large-scale, flexible resources can fundamentally solve the problem of insufficient flexibility in the power system. Virtual power plants, as the convergence point of energy supply and consumption, utilize advanced information and communication technologies to aggregate distributed resources such as distributed power sources, electric vehicles, energy storage, and adjustable loads. Through a higher-level software architecture, they achieve coordinated and optimized operation of distributed resources, internally enabling proactive coordination and comprehensive consumption of clean energy, and externally exhibiting output characteristics similar to traditional power plants.
[0003] The paper "Wang Wanqiao, Su Jian, Pan Juan, Zhang Hui, Gao Kaiqiang, Liu Chuan. Research Prospect of Virtual Power Plant Communication Network Architecture and Key Technologies [J / OL]. Automation of Electric Power Systems. https: / / kns.cnki.net / kcms / detail / 32.1180.TP.20220824.1123.004.html" designs a virtual power plant communication architecture, proposing to set up centralized control equipment at the edge of the virtual power plant to aggregate distributed resources. Data is accessed through 4G / 5G wireless public network or power wireless private network to the virtual power plant management and control platform, which then connects with the power dispatch control / electricity consumption information collection / distribution cloud master station. This architecture does not consider large users (such as super high-rise commercial buildings, high-density smart parks) that can directly connect to the power dispatch control master station. Their centralized control equipment and virtual power plant management and control platform can be deployed in the same device, which can reduce the uncertainty brought by network transmission of 4G / 5G wireless public network or power wireless private network. Moreover, the paper does not involve the functional design of the centralized control equipment and the virtual power plant management and control platform.
[0004] The invention patent "A Distributed Flexible Resource Aggregation Control Device and Control Method - ZL202210401812.1" proposes a distributed flexible resource aggregation control device comprising a processing control unit and a communication unit. The communication unit is used for uplink and downlink connections between the device and edge self-organizing networks of different devices. The processing control unit supports scheduling and control services to achieve real-time demand response, low-power massive-scale deployment, and intelligent microgrid connection / deactivation. Its processing and communication units are highly coupled, and the functions of each module are highly correlated with the control method proposed in the patent. The distributed flexible resource aggregation control device proposed in the patent requires overall application and has poor compatibility with existing systems. Actual deployment would lead to high costs, making it unsuitable for newly built or renovated distributed resource aggregation projects with low budgets.
[0005] The invention patent "A Method for Aggregating and Evaluating the Adjustable Capacity of Massive Distributed Adjustable Resources-202210322508.8" proposes a method to improve the accuracy of adjustable capacity evaluation by clustering, modeling, and optimizing massive distributed adjustable resources. This patent focuses on optimizing the external power characteristics of virtual power plants and does not involve the internal composition and communication methods of virtual power plants.
[0006] The distributed resources involved in the invention patents "Method and Apparatus for Distributed Resource Scheduling, Storage Medium and Electronic Equipment-202210822646.2" and "A Cluster Distributed Resource Scheduling Method, Apparatus, Equipment and Storage Medium-ZL202010567625.1" are server computing resources and CPU utilization of host or virtual machine, respectively, not power resources, and belong to the field of information and communication. Summary of the Invention
[0007] In view of this, in order to solve the above-mentioned technical problems or some of the technical problems, embodiments of the present invention provide a distributed resource aggregation device.
[0008] In a first aspect, embodiments of the present invention provide a distributed resource aggregation device, comprising: an aggregation control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit;
[0009] The aggregation and control platform unit is used to determine the scheduling strategy based on the received scheduling task and send it to the edge IoT agent unit;
[0010] The edge IoT agent unit is used to parse the scheduling strategy into control commands and send them to the distributed resource control terminal.
[0011] The network communication unit is used to control the normal communication of the distributed resource aggregation device;
[0012] The device management unit is used for the system management of the distributed resource aggregation device;
[0013] The power supply unit of the device is used to supply power to the distributed resource aggregation device.
[0014] In one possible implementation, the aggregation and control platform unit includes a scheduling parsing module, a resource management module, a data acquisition module, a model prediction module, and a first state management module;
[0015] The scheduling parsing module is used to receive scheduling tasks and, based on the power generation strategy information provided by the resource management module, parse the scheduling tasks into scheduling strategies and send them to the edge IoT agent unit.
[0016] The resource management module is used to obtain the power generation capacity prediction information of each terminal reported by the model prediction module, the terminal status information of the edge IoT agent unit and the downstream terminal reported by the first status management module, determine the target power generation strategy set, and report it to the scheduling parsing module.
[0017] In one possible implementation, the model prediction module is used to complete data modeling of the downstream distributed resource control terminal based on the terminal energy flow data in the data acquisition module, and predict the power generation capacity of the downstream distributed resource control terminal and the connected distributed resources.
[0018] The first status management module is used to manage the status of the downstream edge IoT agent unit, the distributed resource control terminal, and the distributed resources based on the terminal information stream data in the data acquisition module.
[0019] In one possible implementation, the data acquisition module is used to receive all downstream terminal data reported by the edge IoT agent unit, collect terminal energy flow data from the downstream terminal data, and send the terminal energy flow data to the model prediction module.
[0020] The data acquisition module is also used to acquire terminal information stream data from the downstream terminal data and send the terminal information stream data to the first status management module.
[0021] In one possible implementation, the edge IoT agent unit includes at least a policy parsing module, a second state management module, a rule engine module, a terminal configuration module, and a data acquisition module;
[0022] The strategy parsing module is used to monitor and receive the scheduling strategy issued by the aggregation and control platform unit, and to parse the scheduling strategy into control instructions based on the distributed resource control terminal information and the status information of the distributed resources provided by the second status management module, and to issue them to the corresponding distributed resource control terminal through the network communication unit.
[0023] The second status management module is used for status management of all downstream distributed resource control terminals and distributed resources.
[0024] In one possible implementation, the rule engine module is used to compare existing rules with the collection rules obtained by the terminal configuration module. If the existing rules do not include the collection rules obtained by the terminal configuration module, the rule adaptation script for the required collection rules is downloaded from the rule base and the script is configured.
[0025] The terminal configuration module is used for the initial configuration of all downstream distributed resource control terminals and the management of configuration data of downstream distributed resource control terminals.
[0026] In one possible implementation, the data acquisition module is used to obtain the configuration information of the terminal data acquisition protocol and the terminal data acquisition point table in the terminal configuration module, and to obtain the rule adaptation script issued by the rule engine module.
[0027] The data acquisition module is also used to acquire raw data from the downstream distributed resource control terminal through the network communication unit, upload the raw data to the aggregation and control platform unit, and upload the terminal information flow data to the second state management module.
[0028] In one possible implementation, the network communication unit is used to control the data transmission and reception and communication interface protocol conversion between the aggregation and control platform unit and the scheduling system, and between the edge IoT agent unit and the distributed resource control terminal;
[0029] The network communication unit is also used to control the data transmission and reception and communication interface protocol conversion between the aggregation and control platform unit and the edge IoT agent unit, between the aggregation and control platform and the device system management unit, and between the edge IoT agent unit and the device system management unit.
[0030] In one possible implementation, the system management of the distributed resource aggregation device includes at least: security authentication, system configuration, operating system version management, operation logs, fault monitoring and alarms.
[0031] In one possible implementation, the device power supply unit is used to control AC / DC conversion, voltage conversion, power isolation, and voltage regulation and filtering.
[0032] The distributed resource aggregation device provided in this embodiment of the invention includes: an aggregation control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit. The aggregation control platform unit determines a scheduling strategy based on received scheduling tasks and sends it to the edge IoT agent unit. The edge IoT agent unit parses the scheduling strategy into control commands and sends them to a distributed resource control terminal. The network communication unit controls the normal communication of the distributed resource aggregation device. The device management unit manages the system of the distributed resource aggregation device. The device power supply unit supplies power to the distributed resource aggregation device. Compared to existing distributed resource aggregation methods that suffer from limited coverage, limited functionality, and poor compatibility, this device performs distributed resource aggregation using a unitized and modular design. The low coupling between units and modules allows for flexible assembly and enhances the device's applicability. Attached Figure Description
[0033] Figure 1 This is a schematic diagram of the structure of a distributed resource aggregation device provided in an embodiment of the present invention;
[0034] Figure 2 A functional diagram illustrating the aggregation control platform unit of a distributed resource aggregation device provided in an embodiment of the present invention;
[0035] Figure 3 This is a schematic diagram of the functional modules of a distributed resource aggregation device provided in an embodiment of the present invention;
[0036] Figure 4 This is a schematic diagram of a type I assembly of a distributed resource aggregation device provided in an embodiment of the present invention;
[0037] Figure 5 This is a schematic diagram of a type II assembly configuration of a distributed resource aggregation device provided in an embodiment of the present invention;
[0038] Figure 6 This is a schematic diagram illustrating the deployment configuration of a distributed resource aggregation device according to an embodiment of the present invention;
[0039] Figure 7 This is a schematic diagram illustrating another deployment configuration of a distributed resource aggregation device provided in an embodiment of the present invention. Detailed Implementation
[0040] To make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0041] To facilitate understanding of the embodiments of the present invention, further explanations and descriptions will be provided below with reference to the accompanying drawings and specific embodiments. These embodiments do not constitute a limitation on the embodiments of the present invention.
[0042] Figure 1 This is a schematic diagram of the structure of a distributed resource aggregation device provided in an embodiment of the present invention, as shown below. Figure 1 As shown, the functional modules of the distributed resource aggregation device include an aggregation control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit.
[0043] The aggregation and control platform unit includes, but is not limited to, modules for scheduling parsing, resource management, data acquisition, model prediction, and state management, such as... Figure 2 This is a functional diagram illustrating the aggregation control platform unit of a distributed resource aggregation device provided in an embodiment of the present invention.
[0044] Combination Figure 2The scheduling parsing module monitors and receives scheduling tasks from the scheduling system online. Based on the power generation strategy information provided by the resource management module, it parses the scheduling tasks into scheduling strategies and sends them to the edge IoT agent unit.
[0045] The resource management module obtains the power generation capacity prediction information of each terminal reported by the model prediction module, and the terminal status information of the edge IoT agent unit and downstream terminals reported by the status management module. It then analyzes and calculates the currently available power generation strategy set and reports it to the scheduling and parsing module.
[0046] The model prediction module completes data modeling of the downstream distributed resource control terminal based on the terminal energy flow data in the data acquisition module, and realizes the prediction of the power generation capacity of the downstream distributed resource control terminal and the connected distributed resources.
[0047] The status management module manages the status of the downstream edge IoT agent unit, distributed resource control terminal, and distributed resources based on the terminal information stream data in the data acquisition module. This includes, but is not limited to: the deployment method, geographical location, online status, and fault information of the edge IoT agent unit; the terminal type, terminal model, online status, and fault information of the distributed resource control terminal; and the type, model, power, voltage, current, and frequency of the distributed resources.
[0048] The data acquisition module receives all downstream terminal data reported by the edge IoT agent unit. After cleaning and storing the data, it collects the terminal energy flow data from the downstream terminal data and sends it to the model prediction module. It also collects the terminal information flow data from the downstream terminal data and sends it to the status management module.
[0049] Edge IoT agent units include, but are not limited to, policy parsing, state management, rule engine, terminal configuration, and data collection modules, combined with Figure 3 A detailed description of the functional modules of a distributed resource aggregation device provided in an embodiment of the present invention is as follows:
[0050] The strategy parsing module monitors and receives the scheduling strategy issued by the aggregation and control platform unit. Based on the status information of the distributed resource control terminal and distributed resources provided by the status management module, it parses the scheduling strategy into control commands and sends them to the corresponding distributed resource control terminal through the network communication unit.
[0051] The status management module completes the status management of all downstream distributed resource control terminals and distributed resources, including but not limited to: terminal type, terminal model, terminal online status, terminal fault information, etc. of distributed resource control terminals; and information such as type, model, power, voltage, current, and frequency of distributed resources.
[0052] The rules engine module compares existing rules with the collection rules obtained by the terminal configuration module (such as the conventions and standards to be followed). If the existing rules do not include the collection rules obtained by the terminal configuration module, it downloads the rule adaptation script for the required collection rules from the rule library (which can be deployed in the cloud system, local firmware, etc.) and configures the script parameters, parameter rules, service parameters and other information.
[0053] The terminal configuration module completes the initial configuration of all downstream distributed resource control terminals (including but not limited to terminal registration, unique terminal identification, terminal communication function verification, terminal data acquisition protocol input, and terminal data acquisition point table configuration), and completes the configuration data management of the downstream distributed resource control terminals.
[0054] The data acquisition module obtains the configuration information of the terminal data acquisition protocol and terminal data acquisition point table from the terminal configuration module, and obtains the rule adaptation script issued by the rule engine module. Through the network communication unit, it collects the raw data from the downstream distributed resource control terminals according to the specified communication protocol, communication interface, and acquisition frequency. It also completes the cleaning, classification, and storage of the raw data, and uploads the downstream terminal data to the aggregation and control platform unit, and uploads the terminal information flow data to the status management module.
[0055] The network communication unit enables external and internal communication for the distributed resource aggregation device, wherein:
[0056] External communication for the distributed resource aggregation device includes, but is not limited to, data transmission and reception and communication interface protocol conversion between the aggregation control platform unit and the scheduling system, and between the edge IoT agent unit and the distributed resource control terminal. Communication between the aggregation control platform unit and the scheduling system supports, but is not limited to, 4G / 5G, FTTB, power wired private networks, and power wireless private networks. Communication between the edge IoT agent unit and the distributed resource control terminal supports, but is not limited to, PLC, Ethernet, RS-485, and low-power wireless communication.
[0057] Internal communication within the distributed resource aggregation device includes, but is not limited to, data transmission and reception and communication interface protocol conversion between the aggregation control platform unit and the edge IoT agent unit, between the aggregation control platform and the device system management unit, and between the edge IoT agent unit and the device system management unit. Internal communication supports, but is not limited to, I2C, UART, SPI, PLC, Ethernet, RS-485, and low-power wireless communication methods.
[0058] The device management unit implements the management functions of the distributed resource aggregation device, including but not limited to security authentication, system configuration, operating system version management, operation logs, fault monitoring and alarms.
[0059] The device's power supply unit ensures safe power supply for the entire unit and its modules, including but not limited to AC / DC conversion, voltage conversion, power isolation, voltage regulation, and filtering.
[0060] The distributed resource aggregation device provided in this embodiment of the invention includes: an aggregation control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit. The aggregation control platform unit determines a scheduling strategy based on received scheduling tasks and sends it to the edge IoT agent unit. The edge IoT agent unit parses the scheduling strategy into control commands and sends them to a distributed resource control terminal. The network communication unit controls the normal communication of the distributed resource aggregation device. The device management unit manages the system of the distributed resource aggregation device. The device power supply unit supplies power to the distributed resource aggregation device. Compared to existing distributed resource aggregation methods that suffer from limited coverage, limited functionality, and poor compatibility, this device performs distributed resource aggregation using a unitized and modular design. The low coupling between units and modules allows for flexible assembly and enhances the device's applicability.
[0061] Furthermore, the distributed resource aggregation device provided in this embodiment of the invention includes two assembly forms, such as... Figure 4 This is a schematic diagram of a distributed resource aggregation device type I assembly provided by an embodiment of the present invention. The distributed resource aggregation device type I assembles an aggregation control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit in the same device, that is, they share the same device structural components. The aggregation control platform unit and the edge IoT agent unit share the network communication unit and the device management unit, and are assembled in the same PCB. The device power supply unit is an independent PCB.
[0062] like Figure 5 This is a schematic diagram of the assembly form of a distributed resource aggregation device type II provided in an embodiment of the present invention. Before assembly, the distributed resource aggregation device type II first divides and integrates the shared network communication unit and device management unit into a first network communication subunit, a second network communication subunit, a first device management subunit, and a second device management subunit according to the needs of the aggregation control platform unit, the edge IoT agent unit, and the functions of the dedicated equipment or server.
[0063] The aggregation control platform unit, the first network communication subunit, and the first device management subunit are then assembled in a dedicated device or server, sharing the structural components of the dedicated device or server. During assembly, the aggregation control platform unit, the first network communication subunit, and the first device management subunit can be assembled in the form of a hardware PCB (with relevant programs burned into the firmware of the PCB); alternatively, only pure software can be provided and installed in the firmware of an existing PCB on the dedicated device or server.
[0064] The Distributed Resource Aggregation Device Type II integrates the edge IoT agent unit, the second network communication subunit, the second device management subunit, and the device power supply unit within the same device, meaning they share the same structural components. The edge IoT agent unit, the second network communication subunit, and the second device management subunit are assembled on the same PCB. The device power supply unit has a separate PCB.
[0065] Furthermore, the distributed resource aggregation device provided in this embodiment of the invention includes two deployment forms. Figure 6 This is a schematic diagram illustrating the deployment of a distributed resource aggregation device according to an embodiment of the present invention. This deployment involves a scheduling system connected to n Type I distributed resource aggregation devices. The Type I distributed resource aggregation devices have three connection methods with the distributed resource control terminal and the existing resource management system. Among them:
[0066] In the first connection method, the distributed resource aggregation device type I is directly connected to the distributed resource control terminal, and the distributed resource aggregation device type I realizes northward data acquisition and southward terminal control command issuance.
[0067] In the second connection method, the Type I distributed resource aggregation device connects directly to the existing resource management system, which then handles data collection from the terminals. The aggregation and control platform unit of the Type I distributed resource aggregation device parses the scheduling tasks issued by the scheduling system and generates scheduling policies. If the existing resource management system has the functionality of an edge IoT agent unit, the aggregation and control platform unit directly issues the scheduling policy to the existing resource management system, which then performs policy parsing and control command issuance. If the existing resource management system does not have the functionality of an edge IoT agent unit, the edge IoT agent unit still handles policy parsing and control command generation, while the existing resource management system acquires control commands, performs security checks, protocol adaptation, and finally issues control commands.
[0068] In the third connection method, the distributed resource aggregation device type I can simultaneously connect to some terminals and existing resource management systems. For specific functions, please refer to the first and second connection methods.
[0069] Figure 7 This is a schematic diagram illustrating another deployment configuration of the distributed resource aggregation device provided in an embodiment of the present invention. In this configuration, a scheduling system is connected to n dedicated devices or servers equipped with aggregation and control platform units. The dedicated devices or servers can be connected to the Type II distributed resource aggregation device in three ways. Among them:
[0070] In the first connection method, the first dedicated device or server is connected to several distributed resource aggregation devices (Type II), and the distributed resource aggregation devices (Type II) are connected to several distributed resource control terminals. The aggregation and control platform unit in the first dedicated device or server receives scheduling tasks from the scheduling system, parses them into scheduling strategies, and distributes them to the first to nth distributed resource aggregation devices (Type II). The corresponding edge IoT agent unit in the distributed resource aggregation device (Type II) parses the scheduling strategies into terminal control commands and distributes them to the terminals.
[0071] In the second connection method, the second dedicated device or server connects to the existing resource management system. The aggregation and control platform unit in the second dedicated device or server parses the scheduling tasks issued by the scheduling system, sends scheduling strategies to the existing resource management system, and the existing resource management system parses them into terminal control instructions and sends them to the connected terminals.
[0072] In the third connection method, the distributed resource aggregation device type I can simultaneously connect to the distributed resource aggregation device type II and the existing resource management system. For specific functions, please refer to the first and second connection methods.
[0073] The assembly and deployment method of the distributed resource device provided in this invention, by dividing and integrating the functions of the internal modules of the device, designs distributed resource device type I and distributed resource device type II. Six connection methods are designed to address different application scenarios resulting from different device types, different distributed resource control terminals, and different connections to existing resource management systems. This allows for adaptation to new distributed resource aggregation projects with varying costs, maximizes compatibility with the modification needs of existing distributed resource aggregation projects, and enables the smooth evolution of the distributed resource aggregation control system.
Claims
1. A distributed resource aggregation device, characterized in that, include: The system comprises an aggregation and control platform unit, an edge IoT agent unit, a network communication unit, a device management unit, and a device power supply unit. The aggregation and control platform unit is used to determine the scheduling strategy based on the received scheduling task and send it to the edge IoT agent unit; The edge IoT agent unit is used to parse the scheduling strategy into control commands and send them to the distributed resource control terminal. The network communication unit is used to control the normal communication of the distributed resource aggregation device; The device management unit is used for the system management of the distributed resource aggregation device; The power supply unit of the device is used to supply power to the distributed resource aggregation device; The distributed resource aggregation device includes Type I assembly form and Type II assembly form; The Type I assembly configuration integrates the aggregation control platform unit, edge IoT agent unit, network communication unit, device management unit, and device power supply unit into the same device. The aggregation control platform unit and the edge IoT agent unit share the network communication unit and the device management unit, and are assembled in the same PCB. The device power supply unit is an independent PCB. The Type II assembly configuration divides and integrates the shared network communication unit and device management unit into a first network communication subunit, a second network communication subunit, a first device management subunit, and a second device management subunit. The aggregation control platform unit, the first network communication subunit, and the first device management subunit are assembled in a dedicated device or server, sharing the structural components of the dedicated device or server. The aggregation control platform unit, the first network communication subunit, and the first device management subunit are assembled in the form of a hardware PCB. The edge IoT agent unit, the second network communication subunit, the second device management subunit, and the device power supply unit are assembled in the same device; The edge IoT agent unit, the second network communication subunit, and the second device management subunit are assembled in the same PCB. The power supply unit of the device is a separate PCB.
2. The apparatus according to claim 1, characterized in that, The aggregation and control platform unit includes a scheduling and parsing module, a resource management module, a data acquisition module, a model prediction module, and a first state management module; The scheduling parsing module is used to receive scheduling tasks and, based on the power generation strategy information provided by the resource management module, parse the scheduling tasks into scheduling strategies and send them to the edge IoT agent unit. The resource management module is used to obtain the power generation capacity prediction information of each terminal reported by the model prediction module, the terminal status information of the edge IoT agent unit and the distributed resource control terminal reported by the first status management module, determine the target power generation strategy set, and report it to the scheduling parsing module.
3. The apparatus according to claim 2, characterized in that, The model prediction module is used to complete the data modeling of the distributed resource control terminal based on the terminal energy flow data in the data acquisition module, and to predict the power generation capacity of the distributed resource control terminal and the distributed resources connected to it. The first status management module is used to manage the status of the edge IoT agent unit, the distributed resource control terminal, and the distributed resources based on the terminal information stream data in the data acquisition module.
4. The apparatus according to claim 3, characterized in that, The data acquisition module is used to receive all downstream terminal data reported by the edge IoT agent unit, collect terminal energy flow data from the downstream terminal data, and send the terminal energy flow data to the model prediction module. The data acquisition module is also used to acquire terminal information stream data from the downstream terminal data and send the terminal information stream data to the first status management module.
5. The apparatus according to claim 1, characterized in that, The edge IoT agent unit includes at least a policy parsing module, a second state management module, a rule engine module, a terminal configuration module, and a data acquisition module; The strategy parsing module is used to monitor and receive the scheduling strategy issued by the aggregation and control platform unit, and to parse the scheduling strategy into control instructions based on the distributed resource control terminal information and the status information of the distributed resources provided by the second status management module, and to issue them to the corresponding distributed resource control terminal through the network communication unit. The second status management module is used for status management of all distributed resource control terminals and distributed resources.
6. The apparatus according to claim 5, characterized in that, The rule engine module is used to compare existing rules with the collection rules obtained by the terminal configuration module. If the existing rules do not include the collection rules obtained by the terminal configuration module, the rule adaptation script for the required collection rules is downloaded from the rule library and the script is configured. The terminal configuration module is used for the initial configuration of all distributed resource control terminals and the management of configuration data of distributed resource control terminals.
7. The apparatus according to claim 6, characterized in that, The data acquisition module is used to obtain the configuration information of the terminal data acquisition protocol and the terminal data acquisition point table in the terminal configuration module, and to obtain the rule adaptation script issued by the rule engine module. The data acquisition module is also used to acquire raw data from the distributed resource control terminal through the network communication unit, upload the raw data to the aggregation and control platform unit, and upload the terminal information flow data to the second state management module.
8. The apparatus according to claim 1, characterized in that, The network communication unit is used to control the data transmission and reception and communication interface protocol conversion between the aggregation and control platform unit and the scheduling system, and between the edge IoT agent unit and the distributed resource control terminal. The network communication unit is also used to control the data transmission and reception and communication interface protocol conversion between the aggregation and control platform unit and the edge IoT agent unit, between the aggregation and control platform and the device system management unit, and between the edge IoT agent unit and the device system management unit.
9. The apparatus according to claim 1, characterized in that, The system management of the distributed resource aggregation device includes at least: security authentication, system configuration, operating system version management, operation logs, fault monitoring and alarms.
10. The apparatus according to claim 1, characterized in that, The power supply unit of the device is used to control AC / DC conversion, voltage conversion, power isolation, and voltage regulation and filtering.