TW202022778A - Intelligent energy management off-grid solar inverter energy storage system - Google Patents

Abstract

This disclosure is related to an intelligent energy management off-grid solar inverter energy storage system which comprise a solar inverter energy storage device and a user interface controller. The solar inverter energy storage device includes a first signal hole and an accommodating space, further the solar inverter energy storage device internally has a plurality of circuit components. The user interface controller can not only be inserted into the accommodating space, but also be separated from solar inverter energy storage device to control the operation of the solar inverter energy storage device. This disclosure is provided with an energy priority level management for controlling the different power source in real time. Furthermore, this disclosure also provides an operation system for the user to configure the intelligent energy management off-grid solar inverter energy storage system in a one-click manner. This disclosure improves the efficiency of power energy using and optimizes the processing steps of energy management to reduce the unnecessary consumption of the different power energy.

Description

Intelligent energy management off-grid solar inverter energy storage system

The invention relates to an intelligent energy management off-grid solar inverter energy storage system, in particular to an intelligent energy management off-grid solar energy inverter energy storage system capable of distinguishing energy priority levels for different power supplies.

The existing traditional solar inverter energy storage device does not have the function of intelligent energy management, that is, when different power sources such as mains power, solar (photovoltaic) power and battery power are supplied to the load, the existing solar inverter Energy storage devices are designed to manually set energy priority according to the conditions and needs of the electricity environment. With regard to the usage conditions of different electricity tariff pricing methods, it is impossible to achieve intelligent energy management, and it needs to be improved.

The invention discloses an intelligent energy management off-grid solar inverter energy storage system, which is used in the circuit of the inverter energy storage system of different power sources such as city power, photovoltaic energy and batteries to supply electric energy required by a load. The present invention is equipped with real-time control of the energy priority levels for the use of these different power supplies; at the same time, the present invention provides an operating system that allows users to intelligently set the intelligent energy management off-grid solar inverter energy storage system with one key , Can cooperate when the main circuit device or the circuit system is revised, the operating system can also be followed by a simple one-click insertion method to perform the update or setting of the operating system, effectively improve the efficiency of energy use, and optimize energy management The process and steps can reduce unnecessary consumption of different sources of electrical energy and achieve the economic benefits of green energy and carbon reduction.

The intelligent energy management off-grid solar inverter energy storage system of the present invention includes a solar inverter energy storage device and a man-machine interface controller; the solar energy inverter energy storage device includes: a first signal hole arranged in One front end of the solar inverter energy storage device; and an accommodating space set above the other front end of the solar inverter energy storage device; wherein a plurality of circuit elements are arranged inside the solar inverter energy storage device to perform Different operation of different power supply to load. The man-machine interface controller can be inserted into the accommodating space and is electrically coupled to the plurality of circuit elements in the solar inverter energy storage device; the man-machine interface controller includes: a central computing unit; a real-time The control module is coupled to the central arithmetic unit, and controls the energy priority level of the power supply in the solar inverter energy storage device; a one-key setting unit is coupled to the central arithmetic unit, and the one-key setting unit enables An external component can perform the operating system update/setting in the intelligent energy management off-grid solar inverter energy storage system; a wireless communication module, coupled to the central computing unit, executes the man-machine interface controller and the Wireless communication between solar energy inverter energy storage devices; and a USB interface unit, coupled to the central processing unit and the one-key setting unit, for electrically connecting the external component. Wherein, the man-machine interface controller can be pulled out of the accommodating space when the intelligent energy management off-grid solar inverter energy storage device is operating, and can be installed to be different from the intelligent energy management off-grid solar energy storage device. The operation is performed based on the location of the inverter energy storage device, and the solar inverter energy storage device is controlled by wireless communication; at the same time, the man-machine interface controller can also be used with other types of off-grid solar inverters, and the upgrade does not originally have intelligence Inverter with integrated energy management function.

10‧‧‧Solar inverter energy storage device

11‧‧‧The first signal hole

12‧‧‧accommodation space

13‧‧‧Wireless communication module

14‧‧‧Interface Transmission Unit

15‧‧‧Main circuit controller

16‧‧‧Drive circuit

17‧‧‧Inverter circuit module

18‧‧‧Power output module

19‧‧‧Power Input Module

20‧‧‧Human Machine Interface Controller

21‧‧‧Jack

22‧‧‧Second signal hole

24‧‧‧Signal cable

25‧‧‧Screen

30‧‧‧Central Computing Unit

31‧‧‧Button unit

32‧‧‧Contact pressure unit

33‧‧‧USB Interface Unit

34‧‧‧Wired communication interface

35‧‧‧Wireless communication module

36‧‧‧Bluetooth Module

37‧‧‧WiFi Module

38‧‧‧Display Module

40‧‧‧Real-time control module

41‧‧‧Morning, middle and evening setting module

42‧‧‧Month setting module

43‧‧‧Season Setting Module

44‧‧‧Installation of regional sunshine database

45‧‧‧Installation of regional monthly temperature database

46‧‧‧Installation of regional rainy season distribution database

47‧‧‧Installation of regional special weather database

50‧‧‧One-key setting unit

52‧‧‧External port interface

54‧‧‧Judgment update/setting unit

56‧‧‧Select update/set unit

58‧‧‧Update/Set Control Module

Fig. 1 is a perspective schematic diagram of the first embodiment of the present invention; Fig. 2 is a schematic diagram of an operating state in the first embodiment of the present invention; Fig. 3 is a schematic diagram of internal circuit connections in the first embodiment of the present invention; Fig. 4 is the present invention The schematic diagram of the circuit connection of the real-time control module in the first embodiment; Figure 5 is the schematic diagram of the circuit connection of the one-key setting unit in the first embodiment of the present invention; Figs. 6A~6J are the contents displayed on the screen in operation of the first embodiment of the present invention The schematic diagram.

The invention discloses an intelligent energy management off-grid solar inverter energy storage system, which is used in the circuits of the inverter energy storage system with three different power sources such as mains, photovoltaic energy (solar energy), and batteries to supply loads The power required. The present invention is particularly capable of intelligent real-time control of different power supplies such as utility power, photovoltaic energy (solar energy), and batteries. It can distinguish energy priority levels in use; at the same time, the present invention provides users with one-key intelligent setting of the intelligent energy The operating system that manages the off-grid solar energy inverter energy storage system can cooperate with the main circuit device or the circuit system revision, the operating system can also be inserted in a simple one-click way to perform the operating system update or set up. That is, the present invention provides a solar inverter energy storage system with intelligent energy priority level, which effectively improves the efficiency of energy use, and optimizes the processes and procedures of energy management, reduces unnecessary consumption of different power sources, and achieves green energy Economic benefits of carbon reduction.

In the following, reference will be made to the accompanying drawings to more fully describe various exemplary embodiments, and some exemplary embodiments are shown in the accompanying drawings. However, the concept of the present invention may be embodied in many different forms and should not be interpreted as being limited to the exemplary embodiments set forth herein. Rather, the provision of these exemplary embodiments makes the invention detailed and complete, and will fully convey the scope of the inventive concept to those skilled in the art. In the drawings, the corresponding connection relationship between circuit blocks and circuit elements, various signal lines, various devices and various controllers can be exaggerated for clarity. For similar English labels or numbers, similar elements are always indicated.

It should be understood that although the term “switching element” may be used in this article, including the term “inverter”, it refers to an expression term of Converter or Inventor, but it is not limited to the use of inverter, converter, converter or Different nouns such as converters, that is, these terms should not be restricted by the actual product terms of these electronic circuits. As well as the first, second, third... etc. appearing in this article, these terms are used to clearly distinguish one element from another, and do not have a certain sequence of elements, that is, there may be a first element , The implementation of the third element without the second element is not necessarily There are consecutive serial numbers as the marking relationship of the component symbols.

As the terms used in this article, the left (right) side and right (left) side, input (or output) and output (or input), input (or output) and output (or input), etc., etc. The term is used to clearly distinguish a transmission point of a component from another transmission point of the component, or to distinguish the corresponding connection relationship between a component (device) and another component (device), or an end point and The difference between the other end points is a difference or a difference in relative position, which is not used to limit the sequence relationship or absolute position relationship presented by the character serial number, and it does not necessarily have a certain continuous relationship in numbers. Also, the term "update/set" may be used to include any one of the associated listed items and all combinations of one or more. Furthermore, the term "plurality" or "at least one" may be used herein to describe the number of more than one, and it is not limited to the implementation of one, two, or more than three numbers to represent the implemented technology.

As shown in FIGS. 1 and 2, the intelligent energy management off-grid solar inverter energy storage system of the present invention includes a solar inverter energy storage device 10 and a human-machine interface controller 20. The solar inverter energy storage device 10 includes a first signal hole 11 and an accommodating space 12. The first signal hole 11 is provided at one front end of the solar inverter energy storage device 10, as shown in the right front end of FIG. 1, and the accommodation space 12 is provided above the other front end of the solar inverter energy storage device 10, as shown in FIG. Above the left front as shown. In addition, the solar energy inverter energy storage device 10 is provided with a plurality of circuit elements to perform different operations of supplying different power to the load. The description of the related circuit elements will be detailed in FIG. 3. The man-machine interface controller 20 can be inserted into the accommodating space 12 and is electrically coupled to the plurality of circuit elements in the solar inverter energy storage device 10. A jack 21, a second signal hole 22 and a screen 25 are provided on the man-machine interface controller 20. The jack 21 is arranged on a front side of the human-machine interface controller 20, the second signal hole 22 is arranged on a side of the human-machine interface controller 20, and the screen 25 is arranged on the upper surface of the human-machine interface controller 20.

The above-mentioned human-machine interface controller 20 can extract the solar inverter energy storage device 10 when the intelligent energy management off-grid solar inverter energy storage device of the present invention is operating. In the accommodating space 12, it can be installed at a location different from the intelligent energy management off-grid solar inverter energy storage device to perform operations, and perform control of the solar inverter through wireless communication or wired communication. Variable energy storage device 10. That is, in the embodiment of the present invention, the communication between the human-machine interface controller 20 and the solar inverter energy storage device 10 can be communicated in a wireless transmission mode, and can also be communicated in a wired connection transmission mode of a signal connection line 24. When performing wired communication, the second signal hole 22 is used to provide the signal connection line 24 for plugging, and is connected to the first signal hole 11 in the solar inverter energy storage device 10 by wire to perform wired communication operations control.

As shown in FIG. 3, the internal circuit connection diagram of the man-machine interface controller 20 and the solar inverter energy storage device 10 is disclosed. The human-machine interface controller 20 includes: a central computing unit 30, a real-time control module 40, a key setting unit 50, a wireless communication module 35, and a USB interface unit 33. The central computing unit 30 is the core of the main operation and control of the man-machine interface controller 20. In practice, it can be implemented by a CPU module or a graphics accelerated processor (GPU) as the main processor. The real-time control module 40 is electrically coupled to the central arithmetic unit 30, and its function is to control the energy priority levels of different power sources connected to the solar inverter energy storage device 10 in use. The one-key setting unit 50 is also coupled to the central arithmetic unit 30. The technical function of the one-key setting unit 50 is to enable an external component to perform the whole of the off-grid solar inverter energy storage system. Operating system update/setup, including but not limited to operating system update, operating system settings, or simultaneous update and settings. In practice, the external component can be a USB dongle adapter or a USB copyright key as the external component, so that the man-machine interface controller 20 can perform the operation system update/setting operation of the solar inverter energy storage device 10.

As shown in FIG. 3, the wireless communication module 35 inside the human-machine interface controller 20 is coupled to the central processing unit 30, and executes the signal for wireless communication between the human-machine interface controller 20 and the solar inverter energy storage device 10. Transmission; in practical application, the implementation of the wireless communication module 35 includes but not limited to the Bluetooth module 36 and/or WiFi module 37. That is, the wireless communication module 35 can perform wireless communication in a Bluetooth communication method or a WiFi communication method.

The USB interface unit 33 is coupled to the central computing unit 30 and the one-key setting unit 50, and is mainly used to electrically connect the aforementioned external components; on the other hand, the jack provided on the front side of the aforementioned human-machine interface controller 20 21 is first electrically connected to the USB interface unit 33 for plugging in the aforementioned external component, and then transmitting the signal of the external component to the central processing unit 30 to perform related calculations and operations. In addition, in the man-machine interface controller 20, the second signal hole 22 further includes a wired communication interface 34 to perform wired communication transmission with the solar inverter energy storage device 10, and then the wired communication interface 34 It is connected to the central processing unit 30 to transmit the signal by wired transmission.

The human-machine interface controller 20 also includes a display module 38, which is mainly electrically coupled to the central processing unit 30 for displaying the current status of different power sources and loads on the screen 25 in the human-machine interface controller 20. Screen display of power consumption status or circuit operation status. In addition, the man-machine interface controller 20 also includes a button unit 31 and a touch-press unit 32. The button unit 31 is coupled to the central arithmetic unit 30, and its function is to provide a user with key input control. The man-machine interface controller 20 controls the circuit operation of the solar inverter energy storage device 10. The touch pressure unit 32 is also coupled to the central processing unit 10, and its main function is to provide the user with touch pressure input to the solar inverter energy storage device 10 to control the operation of the circuit.

In the embodiment shown in FIG. 3, the plurality of circuit elements in the aforementioned solar inverter energy storage device 10 include a wireless communication module 13, an interface transmission unit 14, a main circuit controller 15, and a driving circuit. 16. At least one inverter circuit module 17, a power input module 19, and a power output module 18. The interface transmission unit 14 is coupled to the aforementioned first signal hole 11 to serve as an interface for wired signal transmission; the wireless communication module 13 is also coupled to the interface transmission unit 14 to implement the solar inverter energy storage device 10 Perform wireless communication with the man-machine interface controller 20 transmission. The main circuit controller 15 is coupled to the interface transmission unit 14 and mainly functions as the main controller, or main control circuit, and main control module in the solar energy inverter energy storage device 10. The driving circuit 16 is coupled to the main circuit controller 15 and functions to drive the circuit coupled to the back end, that is, to drive at least one inverter circuit module 17 electrically coupled to the back end. The at least one inverter circuit module 17 is coupled to the drive circuit 16 to form a circuit topology of the power inverter circuit; in actual circuit application, the inverter circuit module 17 can be of different types State Converters or Inverters and other single components, or a circuit topology structure composed of different Converters or Inverters.

The power input module 19 is coupled to the aforementioned at least one inverter circuit module 17 for performing high frequency control operations related to the inverter circuit; in practical application, the intelligent energy management of the present invention is off-grid The power input module 19 of the solar inverter energy storage system includes at least one photovoltaic power source, at least one mains power source, and at least one battery power source connected to it to provide different power sources for loads. The power output module 18 is coupled to the at least one inverter circuit module 17, and is mainly used to output the power or power required by the load.

As shown in FIG. 4, the composition structure of the internal circuit components of the real-time control module 40 of the present invention is disclosed, which includes a morning, midnight and evening setting module 41, a January setting module 42, an installation area sunshine database 44, and a Install regional monthly temperature database 45. Among them, the morning, noon, and evening setting module 41 is mainly used to set the energy priority status of the load power supply in the morning, noon, and evening. Furthermore, the morning, noon, and evening setting module 41 can provide load power and battery at any time. The operation of charging and discharging refers to the time-sharing setting of the energy priority of load power supply and battery charging and discharging according to the energy status of different time periods; the month setting module 42 is used to set the load power supply and battery charging and discharging of different months The energy priority status of the The installation area sunshine database 44 is electrically coupled to the morning, midnight and evening setting module 41 and the month setting module 42 at the same time. The installation area sunshine database 44 provides the intelligent energy management of the present invention. The geographical environment and climate of the area where the off-grid solar inverter energy storage system is installed The day's sunshine time data enables the morning, midnight and evening setting module 41 and the month setting module 42 to optimize the energy priority status. The monthly temperature database 45 of the installation area is electrically coupled to the morning, middle and evening setting module 41 and the month setting module 42 at the same time, and its function is to provide the intelligent energy management off-grid solar inverter energy storage system of the present invention. The average temperature data of each month in a year of the installation area enables the morning, midnight and evening setting module 41 and the month setting module 42 to optimize the energy priority status.

For example, if the present invention is installed in the Taipei area, the average sunshine time in Taipei will be shorter than that in the Kaohsiung area, and the energy priority in the Taipei area should be compared with the priority in the Kaohsiung area. Or battery is the main power source. On the other hand, for the month setting module 42 in the Taipei area, since the summer months in the Taipei area are from June to August, and the winter months are from December to February, compared to the winter months in the Taipei area, the summer months in Taipei are The priority of energy from June to August should be photovoltaic (solar energy) as the main priority.

In one embodiment, the real-time control module 40 of the present invention further includes a season setting module 43 and a rainy season distribution database 46 in the installation area; the season setting module 43 is used to set the energy for the load power supply in different seasons. Priority status, in which the season setting module 43 is coupled with the monthly temperature database 45 of the installation area. The rainy season distribution database 46 of the installation area is electrically coupled to the month setting module 42 and the season setting module 43 at the same time to provide the intelligent energy management off-grid solar inverter energy storage system of the present invention in the installation area Information about the distribution of the rainy season during the year. For example, if the installation area is Taipei, the rainy season in Taipei is from April to May. At this time, compared to other months, the priority of energy during the rainy season in Taipei should be utility power or battery. Mainly the power supply.

In another embodiment, the real-time control module 40 further includes an installation area special weather database 47, which is electrically coupled to the season setting module 43 to provide the intelligent energy management off-grid solar inverter storage Data about the month with a higher frequency of typhoons in a year in the area where the energy system is installed. For example, the frequency of typhoons in Taipei area is higher from July to September, and when typhoons make landfall, power outages often occur. Therefore, compared with other months, the priority of energy in the month of typhoon occurrence in Taipei area should be photovoltaic energy or battery energy.

Figure 5 is a schematic diagram of the internal circuit implementation of the one-key setting unit 50. The one-key setting unit 50 includes an external port interface 52, a judgment update/setting unit 54, a selection update/setting unit 56 and an update/setting control module 58. The external port interface 52 is electrically coupled to the USB interface unit 33 for receiving internal signals of the external component. The determining update/setting unit 54 is electrically coupled to the external port interface 52 for determining whether the external component is used to perform the update or setting of the operating system of the intelligent energy management off-grid solar inverter energy storage system. The selection update/setting unit 56 is electrically coupled to the determination update/setting unit 54 to allow a user to select whether the operating system of the intelligent energy management off-grid solar inverter energy storage system needs to be updated or set . The update/setting control module 58 is electrically coupled to the selection update/setting unit 56 for executing the update or setting of the operating system of the intelligent energy management off-grid solar inverter energy storage system.

For example, when the aforementioned solar inverter energy storage device 10 is upgraded to version 2.0 (the 2.0 version is only an example, it means that the solar inverter energy storage device 10 meets the actual needs of different environments, and the circuit content When making an adjusted inverter energy storage device), the external component contains an operating system suitable for the 2.0 version of the solar inverter energy storage device 10, and the user inserts the external component into the jack 21 After that, the screen 25 will display and ask if the operating system update is to be performed. At this time, the user only needs to press a button unit 31 or touch a touch unit 32 to update the 2.0-upgraded solar inverter energy storage device The operating system of 10 is updated. In addition, if users require different function settings of the solar inverter energy storage device 10, the function of the one-key setting unit 50 can also be used to set special functions or external processing energy for the solar inverter energy storage device 10.

The present invention has practical implementation results. Please refer to the schematic diagrams showing different energy states on the screen 25 of the man-machine interface controller 20 disclosed in FIGS. 6A to 6J. Figure 6A shows the energy produced by photovoltaic energy (solar energy) today; Figure 6B shows the photovoltaic energy this month The energy produced; Figure 6C shows the energy produced by photovoltaic energy this year; Figure 6D shows the total energy produced by the photovoltaic energy. Figure 6E shows the energy consumed by the load today; Figure 6F shows the energy consumed by the load this month; Figure 6G shows the energy consumed by the load this year; Figure 6H shows the total energy consumed by the load. Fig. 6I shows the power consumption status of a single date or today; Fig. 6I shows the power consumption status of a single time or the present moment. Obviously, the present invention has great industrial applicability and practicality.

In summary, the present invention proposes an intelligent energy management off-grid solar inverter energy storage system, which can be used in the circuit of the mains, photovoltaic (solar) and battery inverter energy storage system to supply the load. The power required. The present invention can be particularly used for intelligent real-time control of the energy priority levels of different power supplies such as mains, photovoltaic (solar) and batteries. In addition, the present invention provides users with a one-click intelligent setting of the operating system of the intelligent energy management off-grid solar inverter energy storage system. When the overall circuit system is revised, the operating system can also follow Simple one-click operation to perform operating system updates or settings. Therefore, the present invention effectively improves the efficiency of energy use, optimizes the process and steps of energy management, reduces unnecessary consumption of energy sources of different electric energy, and achieves the economic benefits of green energy and carbon reduction. Obviously, this invention patent case has the requirements for patent application.

However, the contents of the description of the present invention are only examples of preferred embodiments. When they cannot be used to limit the scope of protection of the present invention, any partial changes, modifications or additions to the technology still do not depart from the scope of protection of the present invention. in.

10‧‧‧Solar inverter energy storage device

11‧‧‧The first signal hole

12‧‧‧accommodation space

20‧‧‧Human Machine Interface Controller

21‧‧‧Jack

22‧‧‧Second signal hole

24‧‧‧Signal cable

25‧‧‧Screen

Claims (10)

An intelligent energy management off-grid solar inverter energy storage system includes a solar inverter energy storage device and a man-machine interface controller; the solar energy inverter energy storage device includes: a first signal hole arranged in the solar energy One front end of the inverter energy storage device; and an accommodating space arranged above the other front end of the solar inverter energy storage device; wherein the solar inverter energy storage device is provided with a plurality of circuit elements to implement different power sources Different operations supplied to the load; the man-machine interface controller can be inserted into the accommodating space and electrically coupled to the plurality of circuit elements in the solar inverter energy storage device; the man-machine interface controller includes: A central processing unit; a real-time control module, coupled to the central processing unit, which executes and controls the energy priority level of the power supply used in the solar inverter energy storage device; a one-key setting unit, coupled to the central processing unit , The one-key setting unit enables an external component to perform the operating system update/setting in the intelligent energy management off-grid solar inverter energy storage system; a wireless communication module, coupled to the central computing unit, executes the Wireless communication between the man-machine interface controller and the solar energy inverter energy storage device; and a USB interface unit, coupled to the central arithmetic unit and the one-key setting unit, for electrically connecting the external component; wherein, the When the intelligent energy management off-grid solar inverter energy storage device is operating, the human-machine interface controller can be pulled out of the accommodating space and installed to be different from the intelligent energy management off-grid solar inverter energy storage device. The operation is performed based on the location of the energy device, and the solar inverter energy storage device is controlled by wireless communication. At the same time, the man-machine interface controller can be used with different models of off-grid solar inverters. The upgrade does not originally have intelligent energy management. Functional inverter. The intelligent energy management off-grid solar inverter energy storage system according to claim 1, wherein a second signal hole is provided on one side of the man-machine interface controller, and the second signal hole is used to provide wired connection The first signal hole of the solar inverter energy storage device performs wired communication operation control; and the second signal hole is connected to a wired communication interface, and then the wired communication interface is connected to the central processing unit. The intelligent energy management off-grid solar inverter energy storage system according to claim 1, wherein a jack is provided on the front side of the man-machine interface controller, and the jack is used to plug in the external component to make the man-machine interface The controller can perform update/setting operations. The intelligent energy management off-grid solar inverter energy storage system according to claim 1, wherein the man-machine interface controller includes a display module, and the display module is coupled to the central processing unit to allow A screen in the man-machine interface controller executes screen display. The intelligent energy management off-grid solar inverter energy storage system according to claim 1, wherein the human-machine interface controller includes a button unit and a touch-press unit, and the button unit is coupled to the central computing unit for To provide a user with control for performing key input; the touch-pressing unit is coupled to the central processing unit to provide the user with control for performing touch-press input. The intelligent energy management off-grid solar inverter energy storage system described in claim 4, wherein the real-time control module includes: a morning, noon, and evening setting module for setting the morning, noon, and evening according to different time periods Energy status, time-sharing setting of the energy priority status of load power supply and battery charging and discharging; January setting module, used to set the energy priority status of load power supply and battery charging and discharging in different months; a regional sunshine database At the same time, it is electrically coupled to the morning, midnight and evening setting module and the month setting module. The installation area sunshine database provides the geographical environment of the area where the intelligent energy management off-grid solar inverter energy storage system is installed. The sunshine time data of each day, month and season in the environment, so that the morning, midnight and evening setting module and the month setting module can optimize the energy priority status; and a regional monthly temperature database is installed, and the It is sexually coupled to the morning, midnight and evening setting module and the month setting module to provide the average temperature data for each month of the year in the area where the intelligent energy management off-grid solar inverter energy storage system is installed. The intelligent energy management off-grid solar inverter energy storage system according to claim 1, wherein the one-key setting unit includes: an external port interface electrically coupled to the USB interface unit; and a decision update/setting The unit is electrically coupled to the external port interface for determining whether the external component is used to perform the update or setting of the operating system of the intelligent energy management off-grid solar inverter energy storage system; a select update/set unit , Electrically coupled to the determination update/setting unit, to allow a user to choose whether to update or set the operating system of the intelligent energy management off-grid solar inverter energy storage system; and an update/ The setting control module is electrically coupled to the selection update/setting unit for performing the update or setting of the operating system of the intelligent energy management off-grid solar inverter energy storage system. The intelligent energy management off-grid solar inverter energy storage system of claim 1, wherein the plurality of circuit elements in the solar inverter energy storage device include: an interface transmission unit coupled to the first The signal hole is used as an interface for signal transmission; a wireless communication module is coupled to the interface transmission unit for performing wireless communication transmission with the man-machine interface controller; a main circuit controller, coupled The interface transmission unit is the main controller in the solar inverter energy storage device; a driving circuit, coupled to the main circuit controller, is used to drive the circuit coupled to the back end; At least one inverter circuit module is coupled to the drive circuit to form a circuit topology of the power inverter circuit; a power input module is coupled to the at least one inverter circuit module, the power supply The input module includes a photovoltaic power source, a mains power source and at least one battery power source; and a power output module, coupled to the at least one inverter circuit module, for outputting the power required by the load. The intelligent energy management off-grid solar inverter energy storage system according to claim 6, wherein the real-time control module includes: a season setting module for setting the energy priority status of load power supply in different seasons; And an installation area rainy season distribution database, and at the same time, it is electrically coupled to the month setting module and the season setting module to provide one of the areas where the intelligent energy management off-grid solar inverter energy storage system is installed Information about the distribution of the rainy season in the middle of the year. The intelligent energy management off-grid solar inverter energy storage system according to claim 9, wherein the real-time control module includes a special weather database in the installation area, which is electrically coupled to the season setting module for Provide information on the month of the year where typhoons occur frequently in the area where the intelligent energy management off-grid solar inverter energy storage system is installed.

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