A solar power supply network controller

By using the installation mechanism and control system of the solar power grid controller, the problems of unscientific layout, lack of remote control support, and slow data transmission of water level and water quality monitoring equipment have been solved, realizing convenient installation and efficient monitoring of the equipment.

CN115912617BActive Publication Date: 2026-06-09中科长星(安徽)科技有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
中科长星(安徽)科技有限公司
Filing Date
2022-08-26
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing water level and quality monitoring equipment and systems suffer from problems such as lack of scientific layout, lack of support for remote control, and slow data transmission speed, resulting in poor monitoring results and inconvenient equipment installation.

Method used

A solar power grid controller was designed, comprising an installation mechanism and a control system. The installation mechanism enables convenient installation through components such as arc plates, fixed plates, and bolts. The control system integrates a power supply unit, a control unit, and a power consumption unit, including an information acquisition module and a 4G networking module, supporting remote monitoring and efficient data transmission.

Benefits of technology

It has enabled the scientific layout and remote control of water level and water quality monitoring equipment, improved data transmission speed and connection range, and enhanced the ease of equipment installation and back-end management capabilities.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The application discloses a solar power supply network controller, and an installation mechanism comprises a connecting plate and symmetrically arranged arc plates, the outer surface of the connecting plate is fixedly connected with the outer surface of the controller, the outer surfaces of the two arc plates are mutually adhered on one side close to each other, the outer part of the arc plate is provided with a shielding assembly, the outer surfaces of the two arc plates are fixedly connected with fixed plates on the left and right sides, the outer surfaces of the two fixed plates are mutually adhered on one side close to each other, and the application relates to the technical field of controllers. The solar power supply network controller is provided with the installation mechanism, the controller and the carried equipment are arranged first, the improvement of the limitation of water level and water quality monitoring is facilitated, the arc plate is connected with the equipment mounting rod to install the controller, the connection between the controller and the carried equipment is facilitated, and thus the improvement of the prior art is facilitated. The combination of the above structure solves the problem that the existing water level and water quality monitoring equipment and system have certain limitations when used.
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Description

Technical Field

[0001] This invention relates to the field of controller technology, specifically to a solar power grid controller. Background Technology

[0002] Environmental monitoring refers to the activities of environmental monitoring agencies in monitoring and measuring the status of environmental quality. Environmental monitoring determines the level of environmental pollution and quality by monitoring and measuring indicators reflecting environmental quality. The content of environmental monitoring mainly includes the monitoring of physical indicators, chemical indicators, and ecosystems. It is the foundation for scientific environmental management and environmental law enforcement supervision, and an indispensable basic task for environmental protection. The core objective of environmental monitoring is to provide data on the current status and trends of environmental quality, assess environmental quality, evaluate current major environmental problems, and serve environmental management.

[0003] Existing systems and equipment for monitoring water level and quality have the following limitations in use:

[0004] 1) The equipment lacks a scientific layout;

[0005] 2) The equipment does not support remote control;

[0006] 3) Poor data transmission speed when connecting devices to the network;

[0007] The above limitations result in poor monitoring of water level and quality, and the monitoring equipment is constrained by the power grid, leading to inconvenient installation and reduced scientific operation in the wiring layout of the equipment and power grid connection, making the monitoring work inconvenient. Therefore, it is necessary to solve the above problems. Summary of the Invention

[0008] To address the shortcomings of existing technologies, this invention provides a solar-powered grid controller, which solves the limitations of existing water level and water quality monitoring equipment and systems.

[0009] To achieve the above objectives, the present invention provides the following technical solution: a solar power grid controller, comprising a controller, a display screen embedded in the outer surface of the controller, control buttons embedded in the outer surface of the controller, a connection hole on the outer surface of the controller, two signal antennas on the outer surface of the controller, and an installation mechanism on the outside of the controller.

[0010] The installation mechanism includes a connecting plate and symmetrically arranged arc plates. The outer surface of the connecting plate is fixedly connected to the outer surface of the controller. The outer surfaces of the two arc plates are close to each other on one side. A shielding component is provided on the outside of the arc plates. Fixed plates are fixedly connected to the left and right sides of the outer surfaces of the two arc plates. The outer surfaces of the two fixed plates are close to each other on one side. A through groove is opened inside the fixed plate. A bolt is movably connected to the inner surface of the left connecting groove. A nut is threaded to the outer surface of the bolt. The outer surfaces of the bolt and the nut are movably connected to the outer surface of the left fixed plate. A sliding groove is opened on the outer surface of the connecting plate. The inner surface of the sliding groove is slidably connected to the outer surface of the right fixed plate. The inner surface of the sliding groove is connected to the inner surface of the right connecting groove. A lead screw is rotatably connected to the inner surface of the sliding groove. The outer surface of the lead screw is threaded to the inner surface of the right connecting groove. The outer surface of the lead screw is rotatably connected to the interior of the connecting plate. A rotating plate is fixedly connected to the outer surface of the lead screw.

[0011] Preferably, the shielding assembly includes symmetrically arranged fixed strips and shielding plates. The outer surfaces of the two fixed strips that are close to each other are fixedly connected to the outer surface of the arc plate. The shielding plates are disposed outside the controller, and the outer surfaces of the two shielding plates that are close to each other are in contact with each other.

[0012] Preferably, a vertical bar is fixedly connected to the top of each of the two fixed bars, a fastening unit is provided on the outside of the vertical bar, and a vertical groove is provided on the side of the outer surface of each of the two vertical bars that is far apart from each other, and a slider is slidably connected to the inner surface of each of the two vertical grooves.

[0013] Preferably, each of the two sliders has a diagonal rod fixedly connected to the side of its outer surface that is far from each other, and one end of each diagonal rod is fixedly connected to the outer surface of the baffle.

[0014] Preferably, the fastening unit includes a square groove and a threaded groove. The square groove is formed at the top of the vertical bar, and the threaded groove is formed on the left and right sides of the outer surface of the vertical bar. The inner surfaces of the threaded grooves on both sides are connected to the inner surface of the square groove.

[0015] Preferably, a square strip is slidably connected to the inner surface of the square groove, the top end of the square strip is fixedly connected to the outer surface of the baffle, and a through groove is opened inside the square strip, the inner surface of the through groove is connected to the inner surface of the square groove.

[0016] Preferably, a screw is movably connected to the inner surface of the through groove, the outer surface of the screw is threadedly connected to the inner surface of the two side screw grooves respectively, and the outer surface of the screw is movably connected to the outer surface of the vertical bar.

[0017] This invention also discloses a control system for a solar power grid controller, comprising a control system including a power supply unit, a control unit, and a power consumption unit. The output terminal of the power supply unit is connected to the input terminal of the control unit, and the output terminal of the control unit is connected to the input terminal of the power consumption unit. The control unit includes an information acquisition module, an external access module, a circuit control module, a 4G network module, and a signal transceiver module. The output terminal of the information acquisition module is connected to the input terminal of the external access module. The external access module and the circuit control module are bidirectionally connected. The circuit control module and the 4G network module are bidirectionally connected. The 4G network module and the signal transceiver module are bidirectionally connected.

[0018] Beneficial effects

[0019] This invention provides a solar power grid controller. Compared with the prior art, it has the following advantages:

[0020] (1) The solar power grid controller has an installation mechanism including a connecting plate and symmetrically arranged arc plates. The outer surface of the connecting plate is fixedly connected to the outer surface of the controller. The outer surfaces of the two arc plates are close to each other on one side. A shielding component is provided on the outside of the arc plates. Fixed plates are fixedly connected to the left and right sides of the outer surfaces of the two arc plates. The outer surfaces of the two fixed plates are close to each other on one side. A through groove is opened inside the fixed plate. A bolt is movably connected to the inner surface of the left connecting groove. A nut is threaded on the outer surface of the bolt. The outer surfaces of the bolt and the nut are movably connected to the outer surface of the left fixed plate. A sliding groove is opened on the outer surface of the connecting plate. The inner surface of the sliding groove is slidably connected to the outer surface of the right fixed plate. The inner surface of the sliding groove is connected to the inner surface of the right connecting groove. A lead screw is rotatably connected to the inner surface of the sliding groove. The outer surface of the lead screw is threadedly connected to the inner surface of the right connecting groove, and the outer surface of the lead screw is rotatably connected to the interior of the connecting plate. A rotating plate is fixedly connected to the outer surface of the lead screw. By setting up the installation mechanism, firstly, by setting up the controller and the mounted equipment, the limitations of water level and water quality monitoring are facilitated. Secondly, through the connection between the arc plate and the equipment mounting rod, and the connection between the lead screw and the right fixed plate through the connecting groove, and the connection between the right fixed plate and the connecting plate through the sliding groove, and with the clamping of the left fixed plate by bolts and nuts, the arc plate tightly clamps the mounting rod for the installation of the controller, and facilitates the connection between the controller and the mounted equipment. This facilitates the improvement of the existing technology. The combination of the above structures solves the problem that the existing water level and water quality monitoring equipment and systems have certain limitations in use.

[0021] (2) The solar power grid controller includes a shading component comprising symmetrically arranged fixed strips and shading plates. The outer surfaces of the two fixed strips, on their closest sides, are fixedly connected to the outer surface of the arc plate. The shading plates are located outside the controller, with the outer surfaces of the two shading plates close together. Vertical strips are fixedly connected to the tops of the two fixed strips, and fastening units are provided on the outside of the vertical strips. Vertical grooves are provided on the outer surfaces of the two vertical strips, on their furthest sides. Sliding blocks are slidably connected to the inner surfaces of the two vertical grooves. Diagonal rods are fixedly connected to the outer surfaces of the two sliding blocks, on their furthest sides. One end of each diagonal rod is fixedly connected to the outer surface of the shading plate. The fastening unit includes a square groove and a screw groove. The square groove is located at the top of the vertical strip, and the screw grooves are located on the left and right sides of the outer surface of the vertical strip. The inner surfaces of the screw grooves on both sides are connected to the inner surface of the square groove. A square strip is slidably connected to the inner surface of the square groove, and the top of the square strip is connected to the shading plate. The outer surface is fixedly connected, and the inside of the square bar has a through groove. The inner surface of the through groove is connected to the inner surface of the square groove. A screw is movably connected to the inner surface of the through groove. The outer surface of the screw is threaded to the inner surface of the screw groove on both sides. The outer surface of the screw is movably connected to the outer surface of the vertical bar. By setting a shielding component, the controller can be shielded by clamping the mounting rod by closing the shielding plates on both sides, avoiding wind and sun exposure that would reduce the lifespan of the controller and affect the monitoring of water level and water quality. The shielding plates are supported and limited to the left and right by connecting the diagonal rod, slider and vertical groove, as well as the vertical bar and fixed bar to the arc plate. At the same time, the height of the shielding plates can be adjusted to protect the controller. The connection between the square groove and the square bar also facilitates the adjustment and limitation of the shielding plates. At the same time, the connection between the screw and the through groove and screw groove can fix the shielding plates to enhance their stability.

[0022] (3) The solar power grid controller includes a control system, which comprises a power supply unit, a control unit, and a power consumption unit. The output of the power supply unit is connected to the input of the control unit, and the output of the control unit is connected to the input of the power consumption unit. The control unit includes an information acquisition module, an external access module, a circuit control module, a 4G network module, and a signal transceiver module. The output of the information acquisition module is connected to the input of the external access module. The external access module and the circuit control module are bidirectionally connected. The circuit control module and the 4G network module are bidirectionally connected. The 4G network module and the signal transceiver module are bidirectionally connected. By setting up the control system, the power supply unit, control unit, and power consumption unit are connected to the power consumption unit. The combination of the components and power supply unit can form an integrated and autonomous monitoring equipment system for monitoring water level and quality. Through the combination of information acquisition module, external access module, circuit control module, 4G networking module, and signal transceiver module, the controller can be equipped with external devices, making the equipment layout more scientific and improving water level and quality monitoring. At the same time, the use of 4G network function not only improves data transmission speed but also increases the connection range of the equipment, allowing connection to back-end terminals, mobile PCs, and other devices, facilitating visual management in the back-end and enhancing remote control capabilities. The combination of the above structures solves the problem that existing water level and quality monitoring equipment and systems have certain limitations in use. Attached Figure Description

[0023] Figure 1 This is a perspective view of the external structure of the present invention.

[0024] Figure 2 This is an exploded view of the external structure of the controller of the present invention;

[0025] Figure 3 This is a perspective view of the external structure of the arc plate of the present invention;

[0026] Figure 4 This is a cross-sectional view of the external structure of the mounting plate of the present invention;

[0027] Figure 5 This is an exploded view of the external structure of the folding plate of the present invention;

[0028] Figure 6 This is a cross-sectional view of the internal structure of the vertical strip of the present invention;

[0029] Figure 7 This is a system schematic diagram of the control system of the present invention;

[0030] Figure 8 This is a system schematic diagram of the control unit of the present invention.

[0031] In the diagram: 1-Controller, 2-Display screen, 3-Control button, 4-Connecting hole, 5-Signal antenna, 6-Mounting mechanism, 61-Connecting plate, 62-Arc plate, 63-Shielding component, 631-Fixing strip, 632-Shielding plate, 633-Vertical strip, 634-Fastening unit, 6341-Square groove, 6342-Screw groove, 6343-Square strip, 6344-Through groove, 6345-Screw, 635-Vertical groove, 636-Slider, 637-Diagonal rod, 64-Fixing plate, 65-Connecting groove, 66-Bolt, 67-Nut, 68-Sliding groove, 69-Lead screw, 610-Rotating plate, 7-Control system, 71-Power supply unit, 72-Control unit, 721-Information acquisition module, 722-External access module, 723-Circuit control module, 724-4G networking module, 725-Signal transceiver module, 73-Power consumption unit. Detailed Implementation

[0032] 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, and 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.

[0033] Please see Figure 1-5This invention provides a technical solution: a solar-powered grid controller, including a controller 1 with indicator lights. The controller 1 is externally equipped with power supply equipment, monitoring equipment, and a backend transceiver. The power supply equipment includes a combination of a solar power generation device or a wind power generation device and a battery, which solves the problem of inconvenient wiring in remote areas and avoids the constraints of the power grid. The monitoring equipment includes modules such as cameras, voice communication devices, and sensors. Sensor types include, but are not limited to: water liquid parameter sensing layer: ultrasonic open channel flow meter, Doppler velocity meter, ultrasonic level gauge, ultrasonic sludge interface meter, etc.; water quality parameter sensing layer: fluorescence dissolved oxygen sensor, intelligent pH sensor, intelligent ammonia nitrogen ion sensor, intelligent turbidity sensor, etc. The sensor layer for parameters such as moisture and air includes intelligent wind direction sensors, intelligent rainfall sensors, intelligent rain and snow sensors, and intelligent PM2.5 / 1.0 sensors. Users can flexibly customize the sensors required for their functions and connect them to the terminal for data collection and interaction. The backend transceiver supports both wired transmission and wireless communication, enabling real-time monitoring and querying on mobile devices, PCs, the cloud, backend terminals, and portable computers. A display screen 2 and control buttons 3 are embedded in the outer surface of controller 1. Connection holes 4 are also provided on the outer surface of controller 1, allowing connection to devices compliant with RS232 and RS485 communication protocols. Two signal antennas 5 are located on the outer surface of controller 1 for signal data reception. The transmission adopts a more efficient SOCKET communication mode, effectively supporting tens of thousands of RTUs online simultaneously and thousands of RTUs sending and receiving data simultaneously. It can write more than 500 data records to the database per second, which is stable and efficient. The controller 1 is externally equipped with a mounting mechanism 6. The mounting mechanism 6 includes a connecting plate 61 and symmetrically arranged arc plates 62. The inner diameter of the arc plates 62 is adapted to the outer diameter of the mounting rod. The outer surface of the connecting plate 61 is fixedly connected to the outer surface of the controller 1. The outer surfaces of the two arc plates 62 are close to each other on one side. The arc plates 62 are externally equipped with shielding components 63. The left and right sides of the outer surfaces of the two arc plates 62 are fixedly connected with fixed plates 64. The outer surfaces of the two fixed plates 64 are close to each other on one side. The interior of the fixed plates 64 is... A through-slot 65 is provided. A bolt 66 is movably connected to the inner surface of the left connecting slot 65, and a nut 67 is threadedly connected to the outer surface of the bolt 66. The outer surfaces of both the bolt 66 and the nut 67 are movably connected to the outer surface of the left fixed plate 64. A sliding groove 68 is provided on the outer surface of the connecting plate 61. The inner surface of the sliding groove 68 is slidably connected to the outer surface of the right fixed plate 64. The inner surface of the sliding groove 68 is connected to the inner surface of the right connecting slot 65. A lead screw 69 is rotatably connected to the inner surface of the sliding groove 68. The threads on both sides of the lead screw 69 are arranged in opposite directions to facilitate the synchronous movement of the two left fixed plates 64 and the two arc plates 62. The outer surface of the lead screw 69 is threadedly connected to the inner surface of the right connecting slot 65, and the outer surface of the lead screw 69 is rotatably connected to the interior of the connecting plate 61.The connection between the lead screw 69 and the connecting plate 61 has a limit setting (not shown in the figure) and can be connected via a bearing. One end of the lead screw 69 extends to the outside of the connecting plate 61 and is flush with one side of the connecting plate 61. A rotating plate 610 is fixedly connected to the outer surface of the lead screw 69, which facilitates the rotation of the lead screw 69. The shielding assembly 63 includes symmetrically arranged fixed strips 631 and shielding plates 632. The shielding plates 632 are made of pressure-resistant, corrosion-resistant, and aging-resistant materials to better shield and protect the controller 1. The sides of the outer surfaces of the two fixed strips 631 that are close to each other are both connected to the arc plate 62. The outer surfaces are fixedly connected, and the cover plate 632 is set outside the controller 1. The outer surfaces of the two cover plates 632 are close to each other on their respective sides. The tops of the two fixed strips 631 are fixedly connected to vertical strips 633. Fastening units 634 are provided on the outside of the vertical strips 633. Vertical grooves 635 are opened on the outer surfaces of the two vertical strips 633 on their respective sides. Slider blocks 636 are slidably connected to the inner surfaces of the two vertical grooves 635. The cross-sections of the sliders 636 and the vertical grooves 635 are T-shaped or dovetail-shaped to facilitate sliding and adjustment of the cover plate 632, and to allow for the adjustment of the cover plate 632. Lateral limiting is provided. Two sliders 636 have diagonal rods 637 fixedly connected to the outer surfaces of their respective outer edges. One end of each diagonal rod 637 is fixedly connected to the outer surface of the cover plate 632. The fastening unit 634 includes a square groove 6341 and a screw groove 6342. The square groove 6341 is located at the top of the vertical bar 633, and the screw grooves 6342 are located on the left and right sides of the outer surface of the vertical bar 633. The inner surfaces of both screw grooves 6342 are connected to the inner surface of the square groove 6341. A square bar 6343 is slidably connected to the inner surface of the square groove 6341. The square bar 6343 and the square groove 6341... The rectangular structure facilitates the adjustment of the cover plate 632, while also limiting the movement direction of the cover plate 632. The top of the square bar 6343 is fixedly connected to the outer surface of the cover plate 632. A through groove 6344 is formed inside the square bar 6343, and its inner surface communicates with the inner surface of the square groove 6341. A screw 6345 is movably connected to the inner surface of the through groove 6344, and the outer surface of the screw 6345 is threaded into the inner surfaces of the screw grooves 6342 on both sides. The outer surface of the screw 6345 is also movably connected to the outer surface of the vertical bar 633.

[0034] This invention also discloses a control system for a solar power grid controller, including a control system 7. The control system 7 integrates a 12V regulated power supply, a TTL level interface, a 232 communication interface, a 485 communication interface, a USB communication interface, a wired network interface, 2.4G wireless radio frequency communication, a mobile WiFi hotspot, a temperature compensation probe, a large-size LCD segment display screen, three LED indicator lights, and four control buttons. The control system 7 includes a power supply unit 71, a control unit 72, and a power consumption unit 73. The power supply unit 71 consists of power supply equipment, and the power consumption unit 73 consists of a camera and a voice communication module in the monitoring equipment. The output of the power supply unit 71 is connected to the input of the control unit 72, and the output of the control unit 72 is connected to the input of the power consumption unit 73. The control unit 72 includes an information acquisition module 721, an external access module 722, a circuit control module 723, a 4G networking module 724, and a signal transceiver module 725. The information acquisition module 721 consists of sensor modules in the onboard monitoring equipment. The external access module 722 facilitates the connection between the controller 1 and external power supply and monitoring equipment. The connection hole 4 is included in the external access module 722. The 4G network module 724 is a Nano IoT card that can activate the terminal's routing function, support 2.4G wireless radio frequency and cloud communication for online management, provide a wireless WiFi hotspot for mobile devices and other devices to access the Internet, provide a wired network for portable computers to interact with the Internet, and can be equipped with modules such as cameras and voice communication devices. The signal transceiver module 725 consists of a signal antenna 5, which facilitates the transmission and reception of data and signals. The output end of the information acquisition module 721 is connected to the input end of the external access module 722. The external access module 722 is bidirectionally connected to the circuit control module 723. The circuit control module 723 is bidirectionally connected to the 4G network module 724. The 4G network module 724 is bidirectionally connected to the signal transceiver module 725.

[0035] Furthermore, any content not described in detail in this specification is existing technology known to those skilled in the art.

[0036] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0037] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A solar power grid controller, comprising a controller (1), wherein a display screen (2) is embedded in the outer surface of the controller (1), control buttons (3) are embedded in the outer surface of the controller (1), a connection hole (4) is provided on the outer surface of the controller (1), and two signal antennas (5) are provided on the outer surface of the controller (1), and the controller (1) is network-controlled through a built-in control system (7), characterized in that: The controller (1) is externally provided with a mounting mechanism (6); The mounting mechanism (6) includes a connecting plate (61) and symmetrically arranged arc plates (62). The outer surface of the connecting plate (61) is fixedly connected to the outer surface of the controller (1). The outer surfaces of the two arc plates (62) are close to each other on one side. A shielding component (63) is provided on the outside of the arc plates (62). Fixed plates (64) are fixedly connected to the left and right sides of the outer surfaces of the two arc plates (62). The outer surfaces of the two fixed plates (64) are close to each other on one side. A through groove (65) is opened inside the fixed plate (64). A bolt (66) is movably connected to the inner surface of the left groove (65). A nut is threaded onto the outer surface of the bolt (66). (67) The outer surfaces of the bolt (66) and nut (67) are movably connected to the outer surface of the left fixed plate (64). The outer surface of the connecting plate (61) is provided with a sliding groove (68). The inner surface of the sliding groove (68) is slidably connected to the outer surface of the right fixed plate (64). The inner surface of the sliding groove (68) is connected to the inner surface of the right connecting groove (65). The inner surface of the sliding groove (68) is rotatably connected with a lead screw (69). The outer surface of the lead screw (69) is threadedly connected to the inner surface of the right connecting groove (65). The outer surface of the lead screw (69) is rotatably connected to the interior of the connecting plate (61). The outer surface of the lead screw (69) is fixedly connected with a rotating plate (610).

2. A solar power grid controller according to claim 1, characterized in that: The shielding component (63) includes symmetrically arranged fixed strips (631) and shielding plates (632). The outer surfaces of the two fixed strips (631) that are close to each other are fixedly connected to the outer surface of the arc plate (62). The shielding plates (632) are arranged outside the controller (1), and the outer surfaces of the two shielding plates (632) that are close to each other are attached to each other.

3. A solar power grid controller according to claim 2, characterized in that: The top of each of the two fixed strips (631) is fixedly connected to a vertical strip (633), and a fastening unit (634) is provided on the outside of the vertical strip (633). A vertical groove (635) is provided on the side of the outer surface of each of the two vertical strips (633) that is far away from each other, and a slider (636) is slidably connected to the inner surface of each of the two vertical grooves (635).

4. A solar power grid controller according to claim 3, characterized in that: Both of the two sliders (636) have a diagonal rod (637) fixedly connected to the side of their outer surfaces that are far apart from each other, and one end of each diagonal rod (637) is fixedly connected to the outer surface of the cover plate (632).

5. A solar power grid controller according to claim 3, characterized in that: The fastening unit (634) includes a square groove (6341) and a threaded groove (6342). The square groove (6341) is formed at the top of the vertical bar (633), and the threaded groove (6342) is formed on the left and right sides of the outer surface of the vertical bar (633). The inner surfaces of the threaded grooves (6342) on both sides are connected to the inner surface of the square groove (6341).

6. A solar power grid controller according to claim 5, characterized in that: A square strip (6343) is slidably connected to the inner surface of the square groove (6341). The top end of the square strip (6343) is fixedly connected to the outer surface of the baffle (632). A through groove (6344) is opened inside the square strip (6343), and the inner surface of the through groove (6344) is connected to the inner surface of the square groove (6341).

7. A solar power grid controller according to claim 6, characterized in that: The inner surface of the through groove (6344) is movably connected to a screw (6345), the outer surface of the screw (6345) is threadedly connected to the inner surface of the two side screw grooves (6342), and the outer surface of the screw (6345) is movably connected to the outer surface of the vertical bar (633).

8. A control system for the solar power grid controller according to any one of claims 1-7, characterized in that: The system includes a control system (7), which includes a power supply unit (71), a control unit (72), and a power consumption unit (73). The output of the power supply unit (71) is connected to the input of the control unit (72), and the output of the control unit (72) is connected to the input of the power consumption unit (73). The control unit (72) includes an information acquisition module (721), an external access module (722), a circuit control module (723), a 4G networking module (724), and a signal transceiver module (725). The output of the information acquisition module (721) is connected to the input of the external access module (722). The external access module (722) and the circuit control module (723) are bidirectionally connected. The circuit control module (723) and the 4G networking module (724) are bidirectionally connected. The 4G networking module (724) and the signal transceiver module (725) are bidirectionally connected.