TW202205783A - One is an parallel energy equipment system and method suitable for multiple different types (or capacities) portable energy storage devices. - Google Patents

Abstract

The invention relates a parallel energy equipment management system and method suitable for multiple different types (or capacities) portable energy storage devices, providing operators can effectively manage and monitor (multiple different types) parallel energy equipment.

It contains a cloud server, which contains a network connection device; One (or more) energy equipment which energy equipment Mater and parallel energy equipment. The energy equipment Master contains a network interface device, a central processing unit, at least one output device and at least one input device; Both the energy equipment master and the parallel energy equipment include at least one (or more) control device unit and one (or more) one power supply unit; one (or more) portable energy storage device, which can be put into or taken out from energy equipment slot. The control device unit can save multiple different task parameters to manage the optimal charging behavior and safety situation for different types and different capacity portable energy storage devices, especially the task parameters stored by the control device unit are: The default parameters and reference parameters of the cloud data are generated and can be dynamically downloaded and updated by the cloud server.

The invention provides an Integrated Management System and method for multiple different types (or capacities) portable energy storage devices, it solves the problem that multiple different types (or capacities) portable energy storage devices, are setup the same indoor (or outdoor) environmental, Further resolve problem of different installation time of parallel energy equipment, the purpose is to simplify management complexity, reduce long-term management costs, and keep the safety of charging function, in order to get the goal of power saving and remote management.

Description

One is a parallel energy equipment management system and method suitable for portable energy storage devices of different types and capacities.

The present invention relates to a parallel energy equipment management system and method for portable energy storage devices of different types and capacities. A cloud server is used to perform remote synchronous management of parallel energy equipment. Multiple management parameters of portable energy storage devices of different types and capacities are stored in the control devices of different energy equipment. In this way, it is further solved that each portable energy storage device of different types and different capacities has different usage periods. Individual problems that require different charging behaviors or task management due to differences, and are not limited by the influence of energy equipment installations in the early and late stages at different times, greatly reducing the complexity of system management and creating more ideal "two-way interactive" information The delivery mode achieves the service system goals of cloud management, portable energy storage charging safety, dynamic update, real-time monitoring and parallel energy equipment for shared power saving.

In recent years, the development of green environmental protection policies in countries around the world has accelerated the development of global electric vehicles. The demand for energy equipment for electric vehicles is also increasing. The charging mode of traditional energy equipment (such as charging (recharging) equipment) mostly provides a simple power supply for charging portable electric energy devices, or a single power supply for multiple batteries. Portable electrical energy storage device for charging, this traditional way is to use "single type" portable electrical energy storage device for fixed charging mode or to provide "single type" energy device tube for charging. management services.

The current energy equipment is mainly based on the low-cost constant voltage charging (CV) and constant current (CC) charging in the early stage or the constant current/constant voltage (CC/CV MODE) charging method in the later stage, and most of them ignore different periods of use, or different charging methods. Due to the individual differences in the characteristics of portable energy storage devices, poor charging methods are more likely to cause charging failures, accelerated aging, capacity reduction... or even lead to user safety problems.

The "single type" energy equipment management method can no longer meet the requirements for the common management of intelligent charging of portable energy storage devices of different sizes, types and capacities, which are developing rapidly in the future. On the other hand, "single type" Portable electrical energy storage devices may limit the development space of different electric vehicle industries.

Today, the present invention is based on the pragmatic and innovative spirit in view of the fact that the energy equipment management of the aforementioned "single-type" portable energy storage device has many deficiencies in implementation and cannot meet the practical needs of rapid industrial development and the derived use problems. And based on years of practical experience in energy equipment, we have developed a "two-way interactive" information transmission mode and application method.

The technical goal is to use the cloud server to issue management instructions, including different tasks and situations to manage the parallel energy equipment of different types and different capacities of portable energy storage devices, so as to achieve remote joint management, dynamic update, and portable energy storage device charging safety. Service objectives of parallel-type energy equipment with power saving.

The present invention is a parallel energy equipment management system and method suitable for portable energy storage devices of different types and capacities. In order to achieve the above purpose, at least it includes a cloud server, which includes a network connecting device; One (or more) energy equipment, and is divided into energy equipment mainframe and parallel energy equipment; wherein, the energy equipment mainframe is provided with a network connection device, a central processing device, at least one output device and at least one input device device; energy equipment host and parallel energy equipment, both of which include at least one (or more) control device unit, one (or more) one power supply; one (or more) portable energy storage device to It can be inserted or taken out of the parallel energy equipment in the following way: the cloud server can issue commands (different tasks, different situations) to the single (or multiple different types) parallel energy equipment of the portable energy storage device, The central processing unit of the energy equipment host can notify each group of control device units at the same time, and then the control device unit sends parameters that match the task situation to the power supply corresponding to the portable energy storage device, so as to complete the output of the power supply to the power supply. The charging behavior of the connected portable energy storage device; each control device unit can read and upload the status information of the connected portable energy storage device to the central processing unit, and the central processing unit can upload (or can Receive) to the cloud server, the cloud server directly processes the status information and issues the execution task situation parameters to meet the charging behavior of the portable energy storage device. Finally, the parallel energy equipment can complete the power distribution and real-time charging behavior adjustment, so as to achieve remote Diversified service goals of parallel energy equipment with terminal joint management, dynamic update, portable energy storage charging safety and power saving.

The characteristics of the present invention can be based on the difference in the usage status of portable electrical energy storage devices with different usage periods and different characteristics, and can generate different tasks or Management parameters required by different situations (which may include identification code, type, capacity, charging voltage value, charging current value, time value, temperature value, etc., or information on increased management requirements) to manage each portable electrical energy storage charger's charging line performance, safety monitoring, cycle life and adapt to changes in weather conditions.

The present invention solves the long-term development needs of portable electric energy accumulators in the future, and provides portable electric energy accumulators of different sizes, types and capacities according to the actual power level difference, and differentiated portable electric energy accumulators are provided. The method of managing a single (or a plurality of different types) parallel energy equipment systems can be shared in different periods and different usage conditions of the type electric energy storage device, and the parallel type energy equipment can be further installed (or moved) to meet the needs of users. The same location, to service users for the maximum flexibility of flexible scheduling of operational services.

Another effect of the present invention is that when developing a new generation of portable electrical energy storage devices, portable electrical energy storage devices of different sizes, types, and capacities that conform to later development can be directly configured without changing the current system and method. The power supply of the device can be connected in parallel with the existing energy equipment system, which can greatly shorten the on-line time of the new generation of portable energy storage devices.

The current operation mode of energy equipment (such as general charging (replacing) equipment) only provides general charging for portable electrical appliances, but cannot provide real-time management functions for the power demand supply status of the regional mains; when the mains power decreases When (or increasing), the present invention can provide optimized power configuration management for parallel energy equipment, such as the cloud server issues instructions to manage the number of portable energy storage devices and adjust portable energy storage devices of different types and capacities The power consumption mode of the parallel-connected energy devices of the parallel-connected energy device immediately requires the charging of individual (or all) portable energy devices of the parallel-connected energy devices to stop or reduce the charging current, thereby increasing the flexibility of regional mains management; The time period can relieve the power supply pressure and reduce the power supply doubt caused by the abnormal power supply due to power reasons; compared with the regional mains at night, the 100% full-load charging mode can be adjusted during the off-peak period. With stable power supply at night and low ambient temperature conditions, The portable energy storage device can be charged with larger power to facilitate the service of users during the daytime peak hours of the next day.

(1): Cloud server

(6): Input device, logged in by the user

(7): Output device, displayed to the user

(21): The first type of equipment energy equipment host, the first type of portable energy storage can be inserted and taken out in a removable way

(22): The second type of parallel energy equipment, the second type of portable energy storage device can be inserted and taken out in a removable way

(23): The third type of parallel energy equipment, the third type of portable energy storage can be inserted and taken out in a removable way

(51): The first type of portable accumulator

(51a): The first type of portable accumulator connection group

(51b): Information on the current situation of the first type of portable energy storage device

(52): The second type of portable accumulator

(52a): The second type of portable accumulator connection group

(52b): Information on the current situation of the second type of portable energy storage device

(53): The first type of portable accumulator

(53a): The third type of portable accumulator connection group

(53b): Information on the current situation of the third type of portable energy storage device

(101): Default standard parameters, stored in the cloud server database

(102): Reference usage parameters, stored in the cloud server database

(151): The first type of portable energy storage task situation parameters, which are generated by the cloud server

(152): Task context parameters of the second type of portable energy storage, generated by the cloud server

(153): Task situation parameters of the third type of portable energy storage device, which are generated by the cloud server

(11): Network connection device

(2): Central processing unit

(3): Control device unit

(41): Power supply, the first type of portable energy storage use

(42): power supply, the second type of portable energy storage use

(43): Power supply, the third type of portable energy storage use

The features and effects of the present invention will be presented in the embodiments with reference to the drawings.

FIG. 1 is a three-dimensional schematic diagram illustrating an embodiment of a parallel energy equipment management system for portable energy storage devices of different types and capacities according to the present invention.

FIG. 2 is a block diagram illustrating an embodiment of a parallel energy equipment management system for portable energy storage devices of different types and capacities according to the present invention.

FIG. 3 is a flow chart illustrating the process of changing the portable energy storage device by the user.

FIG. 4 is a flowchart illustrating the details of the process of performing portable energy storage identification, cloud information, and charging behavior.

FIG. 5 is a flow chart illustrating the method of the present invention to generate management parameters through the dynamic algorithm of the cloud server by using the status information of the portable electrical energy storage device.

FIG. 6 is a flow chart illustrating a parallel-type energy equipment management procedure for implementing a portable energy storage device.

The purpose of the present invention and the advantages of the design function of the energy equipment will be described in conjunction with the specific embodiments according to the drawings.

First, referring to FIG. 1 and FIG. 2 , which are respectively a three-dimensional schematic diagram and a block schematic diagram of a parallel energy equipment management system for portable energy storage devices of different types and capacities according to the present invention, the present invention includes:

a cloud server (1) comprising a network connection device (11); One (or more) energy equipment, and is divided into an energy equipment host (21) and one (or more) parallel energy equipment (22), (23); wherein, the energy equipment host (21) is provided with a A network connection device (11), a central processing device (2), and at least one output device (7) (UOD, User Output Unit), the output device of the energy equipment host is used for user output, and can be configured as follows; It is a touch screen panel; it can be a Bluetooth transmission device; when the second group (or more) of energy devices installed in the same position are connected in parallel, the energy The device host can be used; and at least one input device (6) (UID, User Input Unit); the input device of the energy device host is used for user input and can be configured as follows; it can be a radio frequency identification device (Radio Frequency Identification Device) , RFID); can be a near field communication device (Near Field Communication, NFC); can be a barcode reader (Barcode reader or Barcode scanner); can be a Bluetooth transmission device (Bluetooth transmission device); When the second group (or more) of energy equipment installed in the same position are connected in parallel, they can be used by the main energy equipment at the same time; There are, one (or more) control device unit (3), one (or more) same (or different) power supply (41), (42), (43), corresponding to different portable energy storage devices (51), (52), (53) are used; wherein, the main energy device (21) or the parallel energy devices (22), (23) provide at least one group of different portable energy storage devices (51), (52) ), (53) in and out of the space in a removable manner. Wherein, the energy equipment host (21) can be connected with at least one cloud server (1) through the network connection device (11);

Among them, the parallel energy devices (22) and (23) of the second group (or above) are connected in parallel can be connected to each other simultaneously through the network connection device (11) of the energy equipment host (21) and at least one cloud server (1); wherein the cloud server (1) and the central processing device of the energy equipment host (21) (2), which are connected to each other by a network connection device (11); the network connection device (11) is connected in one of the following ways: it can be a wired network (asymmetric digital subscriber loop ADSL), it can be a wireless network The network (4G mobile network, 5G digital cellular network), can be a wireless local area network (Wi-Fi, IEEE 802.11 standard or above). Wherein, the central processing unit (2) of the energy equipment host (21) and the control unit (3) of one (or more) parallel energy equipments (22) and (23) are connected to each other in one of the following ways: It can be connected by a communication control line (Cable or Wired connection); it can be a wireless local area network (Wi-Fi, IEEE 802.11 standard or above).

The central processing device (2) of the energy equipment host (21) has a built-in data storage function for storing, accessing, recording and managing all corresponding control device units (3), so as to connect to the cloud server (1). ) Online work (Work On-Line) mode; in case of poor environmental communication, it can immediately work offline (Work Off-Line) mode, the default use of the central processing device (2) data execution management functions; wherein, the control device unit (3) Built-in data storage function to correspond to one group (or multiple groups) of power supplies (41), (42), (43) to provide a connected portable energy storage device (51) , (52), (53) Charging function: In addition, the first type of portable energy storage device (51) is attached with a connection group (51a), and the second type of portable energy storage device (52) is attached with a connection group (51a). 52a), the third type of portable accumulator (53) is attached with a connection group (53a), a control device unit (3) and portable accumulators (51), (52), (53) They are connected to each other, and can be connected in one of the following ways; it can be a wired way to connect the group by power communication (Cable or Wired connection) connection, the portable energy storage is equipped with a power communication connection group; it is a wireless connection by Near-field communication (NFC, Near-field communication), and the portable energy storage is equipped with a near field communication module .

According to the above description, the system is actually used. Please refer to FIG. 1 and FIG. 3. Each group of portable energy storage devices (51), (52), (53) is a portable energy storage device with corresponding memory. Status information (51b), (52b), (52b) of the energy storage device, this description takes the user operating the portable energy storage device (51) on the main body of the energy equipment (21) as an example, the use process and steps (please refer to Figure 3) The description is as follows, the user (301) should use the input device to log in (302) and after the user inserts the portable energy storage #1 (303), the corresponding control device unit reads and recognizes the portable energy storage device #1 (304), and send it to the cloud server (1) through the central processing unit (2) of the energy equipment host (21); if it cannot be recognized (No), the output device will display a message to notify the user to retrieve the portable Group #1 of the energy storage device (305); if it can be identified (yes), the identification code of the #1 group of the portable energy storage device is correct (306), and the output device displays a display to notify the user to take out the portable energy storage device of the same type The user program (308) is completed in the #2 group (307) of the device, so that the user operates the portable energy storage device (51) in this process to complete the retrieval and use.

Next, please refer to FIG. 4 and FIG. 5 , the process description is as follows: the same as the previous description, taking the user operating the portable energy storage device ( 51 ) on the main body of the energy equipment ( 21 ) as an example, the portable energy storage device identifies And the charging process (401) can control the device unit to read the (51b) status information (402) of the portable energy storage device #1, and then control the device unit to identify the current state information of the portable energy storage device #1 (403). ), then upload the data of the portable energy storage #1, the central processing device is connected to the cloud server, the cloud server confirms the data and replies correctly (404), the cloud server executes the dynamic algorithm parameter reset, and the cloud server The device generates different tasks or different tasks according to the status information of the portable energy storage device #1 (51). Management parameters of the same situation (405); the task of the portable energy storage device #1 is sent back by the data of the cloud server, and the control device unit starts to charge the portable energy storage device #1 (406), and then the control device The unit executes the management program to record and monitor the charging status and safety status of the portable energy storage device #1 (407), so that the portable energy storage device #1 is identified and the charging process is completed;

Among them, referring to FIG. 5, the description of the dynamic algorithm generating management parameters, after the cloud server receives the status information of the portable energy storage device #1 (51b), the dynamic algorithm is executed to generate the management parameters; the preset standard parameters are compared The portable energy storage device has used the value of the current information (405a), and executes the parameter reset of the dynamic algorithm, calculates the difference of the reference used parameters (405b), and generates different tasks or tasks for the portable energy storage device #1. Management parameters (405c) in different situations, the cloud server (1) sends the management parameters to the control device unit (3) for real-time charging of the portable energy storage device #1 (51) and completes dynamic information storage and management;

For others, please refer to the description of the method of real-time power management provided by the cloud server to the parallel energy equipment in real time as shown in FIG. When the program starts, connect and confirm the number of control device units of all energy equipment (602), execute the control device unit programming a, log in according to the cloud server and configure the service number of different types of portable energy storage devices serving the energy equipment (603), and then execute the control device unit programming b in turn, and periodically update the control device unit configuration and available power management mechanism according to the cloud server (604), and then execute the management program execution and monitor the execution management program and report the information, and immediately notify the available power The abnormal state of the portable energy storage device is stored in the cloud server, and the records can be stored in the central processing device (605), and finally, the parallel energy equipment management procedure is completed (606);

From the above description of the implementation of the parallel energy equipment management system and method suitable for portable energy storage devices of different types and capacities, it can be seen that the present invention has the following advantages:

Advantages 1. The present invention is to solve the long-term development needs of portable electric energy storage devices in the future. According to the actual power level difference, portable electric energy storage devices of different sizes, different types and different capacities will be provided for integration. Practical parallel energy equipment with systematic management, so as to solve the problem of setting up and managing portable energy storage devices of different types and capacities in the same indoor service location (or the same outdoor service location), and further solve the problem of service providers installing at different times. The problem of parallel energy equipment and the flexible installation (or movement) of parallel energy equipment at the same location as the user's needs, in order to serve the user and provide the most flexible and flexible scheduling of operational services.

Advantage 2. The present invention mainly provides parallel energy equipment with portable energy storage devices of different types and capacities, and pays more attention to the individual differences of portable electric energy storage devices of different use periods or different characteristics, and directly The cloud server executes the dynamic algorithm and issues management parameters (identification code, type, capacity, charging voltage value, charging current value, time value, temperature value, etc. of the portable energy storage device for different tasks or different situations, etc., or manage projects with increased demand) to manage the charging behavior, safety monitoring, cycle life and management of each portable energy storage device in response to weather and environmental changes to avoid charging failures of portable energy storage devices and slow down aging. and capacity drops...or security issues.

Advantage 3. The present invention provides a new generation of portable electrical energy storage devices for future industrial development, which can be directly configured with portable energy storage devices of different sizes, types, and capacities that meet later development without changing the current system and method. The power supply of the electric energy storage device can be connected in parallel with the existing energy equipment system, which can greatly shorten the on-line time of the new generation of portable electric energy storage devices.

Advantage 4 The present invention provides a design method that does not change the current "single type" energy equipment unit, and the present invention can be used for parallel energy equipment to support the development of next-generation equipment. Flexibility in the management of "single-type" energy equipment for portable electrical energy storage devices of different sizes, types and capacities. The parallel energy equipment can complete the power distribution and real-time charging behavior adjustment, and achieve the service goals of the diversified energy equipment of remote joint management, dynamic update, portable energy storage charging safety and power saving.

Advantage 5. The present invention provides a function of real-time management of the power demand and supply status of the regional mains. When the mains power is lowered (or increased), the power supply pressure can be relieved compared to the use of the regional mains during the peak hours during the day. On the one hand, with stable power supply at night and low ambient temperature, the large-power charging behavior of portable energy storage can save electricity costs, provide parallel energy equipment to optimize power configuration management, and increase future smart city areas. Dispatch, maneuver and resiliency of electricity.

The present invention is based on the efforts of practical development accumulated over many years of industrial experience. We sincerely hope that the patent of the present invention will be approved. If the technical person in the industry develops other equivalent changes or amendments according to the characteristics and scope of the present invention , should be regarded as not departing from the scope of the patent application of the present invention.

(1): Cloud server

(6): Input device, logged in by the user

(7): Output device, displayed to the user

(21): The first type of energy equipment host

(22): The second type of parallel energy equipment

(23): The third type of parallel energy equipment

(51): The first type of portable accumulator

(51a): The first type of portable accumulator connection group

(51b): Information on the current situation of the first type of portable energy storage device

(52): The second type of portable accumulator

(52a): The second type of portable accumulator connection group

(52b): Information on the current situation of the second type of portable energy storage device

(53): The first type of portable accumulator

(53a): The third type of portable accumulator connection group

(53b): Information on the current situation of the third type of portable energy storage device

(101): Default standard parameters, stored in the cloud server database

(102): Reference usage parameters, stored in the cloud server database

(151): Task Situation Parameters of Type 1 Portable Accumulator

(152): Task Situation Parameters of the Second Type Portable Accumulator

(153): Task Situation Parameters of the Third Type Portable Accumulator

Claims (16)

One is a parallel energy equipment management system and method suitable for portable energy storage devices of different types and capacities, at least including: a cloud server including a network connection device; One (or more) energy equipment, which is divided into the main energy equipment and one (or more) parallel energy equipment; Wherein, the energy equipment host is provided with a network connection device, a central processing device, at least one output device and at least one input device; Among them, the main energy equipment and the parallel energy equipment include at least one (or more) control device unit, and one (or more) same (or different) power supply, corresponding to the use of different portable energy storage devices ; Wherein, the host of the energy equipment or the parallel energy equipment provides at least one or more different portable energy storage spaces that can be inserted and taken out in a removable manner; The control device unit stores a plurality of task context parameters for management to manage the optimal charging behavior and safety status of portable energy storage devices of different types and capacities, and can be dynamically downloaded and updated by the cloud server. The method of claim 1, wherein the energy equipment host can be connected to at least one (or more) cloud servers through a network connection device; Among them, the second group (or more) of parallel energy equipment connections can be connected to each other through the network connection device of the energy equipment host and at least one cloud server at the same time; the cloud server and the central processing device of the energy equipment host are connected to each other. They are connected to each other by means of network connection devices. The network connection devices can be connected in one of the following ways: It can be a wired network (Asymmetric Digital Subscriber Loop ADSL); It can be a wireless network (4G mobile network, 5G digital cellular network); The system can be a wireless local area network (Wi-Fi, IEEE 802.11 standard or above). The method of claim 1, wherein the energy equipment host is provided with at least one output device (UOD, User Output Unit), and the output device of the energy equipment host is used for user output, and can be configured as follows; The system can be a touch screen panel; The system can be a Bluetooth transmission device; The method of claim 1, wherein the energy equipment host is provided with at least one input device (UID, User Input Unit); the input device of the energy equipment host is used for user input and can be configured as follows; The system can be a radio frequency identification device (Radio Frequency Identification, RFID); The system can be a near field communication device (Near Field Communication, NFC); It can be a barcode reader (Barcode reader or Barcode scanner); The system can be a Bluetooth transmission device The method of claim 1, wherein the central processing unit of the energy equipment host and the control unit (3) units of one (or more) parallel energy equipment are connected to each other, and the connection can be in one of the following ways: The system can be connected by a communication control line (Cable or Wired connection); The system can be a wireless local area network (Wi-Fi, IEEE 802.11 standard or above). According to the method of claim 1, wherein the central processing unit of the energy equipment host has a built-in data storage function, the method can be as follows: It is an online work (Work On-Line) method that can directly connect to the cloud server; It is an offline work (Work Off-Line) method that can occur in poor environment communication. The method of claim 1, wherein the control device unit (3) has a built-in data storage function for managing a corresponding group (or groups) of power supplies to provide the connected portable energy storage device for charging Function. The method of claim 1, wherein the control device unit and the portable energy storage units of different types and capacities are connected to each other, and can be connected in one of the following ways: The system can be connected by a cable or wired connection in a wired manner, and the portable energy storage device can be configured with a power communication connection group; The portable energy storage device is equipped with a near field communication module in order to be connected wirelessly by Near-field communication (NFC, Near-field communication). The method of claim 1, wherein the main energy device and the parallel energy device include at least one (or more) same (or different) power supply, corresponding to different portable energy storage devices; further including The configuration of the power supply varies according to the portable energy storage device. A power supply of the same power size. One is a parallel energy equipment management system and method suitable for portable energy storage devices of different types and capacities. The cloud server is used to provide the parallel energy device management real-time-portable energy storage task situation in real time through a cloud server. The parameter method includes the following steps: The user inserts a portable energy storage device into the parallel energy device in a removable manner; Use the control device unit of the parallel energy equipment to read the status information of the portable energy storage device and send it back to a cloud server; the cloud server executes the dynamic algorithm to reset the task situation parameters, download and store it in the control device device unit. The method of claim 10, wherein the cloud server executes a dynamic algorithm, which includes the following steps: After receiving the status information of the portable energy storage device, the cloud server compares the value of the current status information of the portable energy storage device with the preset standard parameters; furthermore, it calculates the difference between the reference parameters and executes the dynamic algorithm. The parameters of the reset behavior, so that can generate different tasks or different context management task context parameters. The method of claim 10, wherein the cloud server executes a dynamic algorithm for managing task context parameters for different tasks or different contexts, including the following information: The identification code, type, capacity, charging voltage value, charging current value, time value, temperature value, etc. of the portable energy storage device, or items with increased management requirements. The method of claim 10, wherein the control device unit of the parallel energy equipment is used to read the status information of the portable energy storage device, so as to execute the task situation parameter reset of the cloud server to execute a dynamic algorithm, and restore it In the control device unit, it is a method of "two-way interactive" information transmission mode. One is a parallel energy equipment management system and method suitable for portable energy storage devices of different types and capacities, providing a method for real-time power management of parallel energy equipment, which includes the following steps: The number of control device units managed by the cloud server using parallel energy equipment: Regularly update the management mechanism of the available power for the configuration of the control device unit according to the cloud server; Execution management procedures Execute and monitor execution management procedures and report information. The method of claim 14, wherein a method for real-time power management of parallel-connected energy equipment is provided, comprising: Set the maximum power consumption value of individual (or all) power demand supply of parallel energy equipment; Individual (or total) electricity consumption of parallel-connected energy equipment at different time periods. The method of claim 14, wherein a method for real-time power management of parallel-connected energy equipment is provided, comprising: The range of setting the charging stop or reducing the charging current (or charging voltage) of the portable electrical appliances managed by the individual (or all) of the parallel energy equipment can be 0%-100%.

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