A quick assembly type photovoltaic panel mounting support device for mountainous areas

By combining the design of the column, electric push rod and flexible clamping components, the problem of installation efficiency and stability of photovoltaic panels in mountainous and windy environments is solved, enabling rapid installation and angle adjustment, and improving the wind resistance and power generation efficiency of photovoltaic panels.

CN121567036BActive Publication Date: 2026-07-10CHINA THREE GORGES GRP SICHUAN ENERGY INVESTMENT CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
CHINA THREE GORGES GRP SICHUAN ENERGY INVESTMENT CO LTD
Filing Date
2025-11-25
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing photovoltaic panel mounting brackets suffer from low installation efficiency and poor stability in mountainous environments, especially under strong wind conditions. Traditional bolt tightening methods affect installation speed, while press-fit fixing cannot provide sufficient wind resistance under strong winds, leading to photovoltaic panel displacement or loosening.

Method used

The design incorporates a combination of columns, electric push rods, flexible adhesive strips, adjustment components, stabilization components, and auxiliary components. Through rapid assembly, electric adjustment, and flexible clamping, it enables quick installation and angle adjustment of photovoltaic panels, enhancing wind resistance.

Benefits of technology

This improves the installation efficiency and stability of photovoltaic panels in mountainous environments, ensures that the panels do not shift under strong wind conditions, and optimizes power generation efficiency.

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Abstract

This invention belongs to the field of photovoltaic support technology and discloses a rapid assembly photovoltaic panel installation support device for mountainous areas. It includes a column. When the support frame deflects to the side wall of the column, the sliding frame, flexible rubber strip, and the weight of the photovoltaic panel cause the sliding frame to slide down inside the groove. At this time, one end of the sliding frame at a higher position gradually moves away from the top of the support frame, causing the telescopic rotating component to drive the sliding sleeve block to slide on the outer wall of the limiting rod. The sliding sleeve block drives the square plate and elastic frame rod to move, and the elastic frame rod drives the flexible clamping plate to move. During the movement of the flexible clamping plate, it will contact one side of the photovoltaic panel at the top, squeezing the top side wall of the photovoltaic panel. The flexible clamping plate and the locking rod together clamp the side wall of the photovoltaic panel, preventing the top photovoltaic panel from being blown away by the wind when the wind force is too strong. This improves the stability of the photovoltaic panel after angle adjustment and effectively enhances the anti-interference ability of the photovoltaic panel in windy environments.
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Description

Technical Field

[0001] This invention belongs to the field of photovoltaic support technology, specifically a rapid assembly photovoltaic panel installation support device for mountainous areas. Background Technology

[0002] The primary purpose of a rapid-assembly photovoltaic (PV) panel installation support device for mountainous terrain is to provide a stable and adjustable support structure for PV panels, enabling rapid and safe installation on irregular terrains such as mountains. This device adapts to different terrains and angles, ensuring the PV panels maintain optimal performance in mountainous environments and achieve the best PV power generation results. Its design typically includes features such as lightweight construction, robustness, and ease of installation and disassembly, allowing for rapid assembly and providing sufficient support to cope with complex terrain and harsh weather conditions.

[0003] The prior art document CN217984903U discloses a photovoltaic support bracket that is easy to disassemble. This application discloses a photovoltaic support bracket that is easy to disassemble, including a base plate and photovoltaic panel components. A placement plate is provided on the top of the base plate. Both ends of the base plate and the placement plate are equipped with assembly / disassembly mechanisms. A rotating bracket is fixed to the top side of the assembly plate b, and the top of the rotating bracket is rotatably connected to the assembly plate d. An angle adjustment mechanism is provided between the top of the assembly plate a and the bottom of the assembly plate c. This utility model adjusts the tilt angle of the photovoltaic panel components through the angle adjustment mechanism, making angle adjustment convenient. The assembly / disassembly mechanism allows for quick installation and disassembly of the entire support bracket, resulting in high assembly / disassembly efficiency. After disassembly, the entire support bracket can be broken down into multiple individual parts, thereby effectively reducing the overall volume of the support bracket and facilitating storage and transportation.

[0004] While the aforementioned applications effectively reduce the overall size of the support structure, facilitating disassembly and transportation, the traditional bolt-tightening method is still used to reinforce the photovoltaic panels during installation. Although this method ensures installation stability, it significantly reduces installation efficiency and requires more manual operation and tool coordination, thus increasing overall installation time and complexity. In contrast, using a pressing method to fix the photovoltaic panels via adhesive strips and interlocking points improves installation efficiency, allowing the panels to be fixed to the support structure more quickly. However, the stability of this method is significantly affected by external environmental factors. Especially in strong winds, pressing fixation may not provide sufficient wind resistance, causing the photovoltaic panels to shift or loosen in strong winds, thereby affecting their stability and lifespan. Therefore, in practical applications, a balance needs to be struck between installation efficiency and wind resistance to ensure that the photovoltaic panels can operate stably and reliably under various environmental conditions. Summary of the Invention

[0005] To address the problem of excessive wind force mentioned in the background art, strong winds in mountainous environments can cause photovoltaic panel mounting brackets to shift or loosen, especially when using press-fit or other relatively fragile fixing methods. This can lead to displacement of the photovoltaic panels, affecting their original tilt angle and position, resulting in decreased light absorption efficiency. This invention provides a rapid assembly photovoltaic panel mounting support device for mountainous areas.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a rapid-assembly photovoltaic panel installation support device for mountainous areas, comprising a column, a fixing sleeve fixedly connected to one end of the column, an electric push rod hinged to the side wall of the fixing sleeve, a top sleeve fixedly connected to the top of the column, a fixing block fixedly connected to the top of the top sleeve, and further comprising an installation adjustment mechanism, the installation adjustment mechanism comprising a crossbeam rotatably connected to the inner wall of the fixing block, square sleeves fixedly connected to the outer walls of both ends of the crossbeam, diagonal strips fixedly connected to both sides of the square sleeves, and an adjustment component provided at the top of the diagonal strips for tilting the device.

[0007] Preferably, the adjustment assembly includes a support frame fixedly connected to the top of the inclined bar, and two support frames are provided. The top of the electric push rod is rotatably connected to a fixing plate, and the top of the fixing plate is fixedly connected to the bottom of the support frame.

[0008] Preferably, the inner wall of the support frame is provided with sliding grooves on both sides, the inner wall of the sliding groove is slidably connected to a sliding frame, the inner wall of the sliding frame is fixedly connected to a flexible rubber strip, and the inner wall of the flexible rubber strip is movably connected to a photovoltaic panel.

[0009] Preferably, a locking rod is slidably connected through both sides of the sliding frame, a wedge is fixedly connected to one end of the locking rod, and a tension spring is fixedly connected to one side of the wedge.

[0010] Preferably, one end of the tension spring is fixedly connected to one side of the outer wall of the sliding frame, and both sides of the sliding frame near the locking rod are fixedly connected to a fixing shell. One side of the fixing shell is fixedly connected to a first compression spring, and one end of the first compression spring is fixedly connected to one side of the inner wall of the support frame.

[0011] Preferably, the inner wall of the support frame is provided with a stabilizing component, the stabilizing component including a telescopic rotating member hinged to the side of the support frame near the inner wall of the first compression spring, and a sliding sleeve block is hinged to the top of the telescopic rotating member.

[0012] Preferably, a limiting rod is slidably connected to the inner wall of the sliding sleeve, the bottom of the limiting rod is fixedly connected to the top of the sliding frame, and a square plate is fixedly connected to one end of the sliding sleeve.

[0013] Preferably, an elastic frame rod is slidably connected through the top of the square plate, a flexible clamping plate is fixedly connected to the bottom of the elastic frame rod, and a fixing clamping rod is fixedly connected to both ends of one side of the flexible clamping plate.

[0014] Preferably, an auxiliary component is provided on one side of the sliding sleeve block. The auxiliary component includes a connecting plate fixedly connected between the two sliding sleeve blocks. A telescopic rod is fixedly connected to the bottom of the connecting plate. The fixed end of the telescopic rod passes through the fixed shell and extends into the interior of the fixed shell.

[0015] Preferably, a piston plate is fixedly connected to the bottom of the telescopic rod, the outer wall of the piston plate is slidably connected to the inner wall of the fixed shell, a second compression spring is fixedly connected to the bottom of the piston plate, the bottom of the second compression spring is fixedly connected to the bottom of the inner wall of the fixed shell, and exhaust pipes are connected to both ends of one side of the fixed shell.

[0016] Compared with the prior art, the beneficial effects of the present invention are as follows:

[0017] This invention utilizes an adjustment assembly to insert a column into the ground. The top sleeve is then bolted to the top of the column. The middle end of the crossbeam rotates inside a fixed block, which is fixedly connected to the top sleeve. Both ends of the crossbeam are bolted to a square sleeve, whose sidewalls are bolted to two diagonal strips, which in turn are bolted to a support frame. This allows for rapid assembly of the support device. Workers place the photovoltaic panel inside the flexible adhesive strip for quick installation, reducing installation time and manpower. Due to the elastic deformation of the tension spring, the spring drives the locking rods to slide along the inner wall of the sliding frame, securing the photovoltaic panel and preventing it from falling off. After installation, an electric push rod is activated, causing the fixed plate to extend and retract. The fixed plate then drives the support frame to extend and retract, indirectly causing the crossbeam in the adjustment mechanism to rotate along the inner wall of the fixed block. This allows for angle adjustment of the photovoltaic panel, facilitating optimal illumination and optimizing power generation efficiency.

[0018] This invention, through the coordination of adjustment and stabilization components, allows the sliding frame to slide down inside the groove when the support frame deflects to the side wall of the column. The sliding frame, flexible rubber strip, and the photovoltaic panel's own weight cause the sliding frame to move further away from the top of the support frame. This causes the telescopic rotating component to slide the sliding sleeve block against the outer wall of the limiting rod. The sliding sleeve block moves the square plate and elastic frame rod, which in turn moves the flexible clamping plate. During this movement, the flexible clamping plate contacts one side of the photovoltaic panel at the top, compressing the top side wall of the photovoltaic panel. The flexible clamping plate and the locking rod together clamp the side wall of the photovoltaic panel, preventing it from being blown away by strong winds. This improves the stability of the photovoltaic panel after angle adjustment, effectively enhancing its anti-interference capability in windy environments and ensuring its performance. When the flexible clamp moves closer to the photovoltaic panel, it moves the fixed clamp rod. During the movement, the fixed clamp rod comes into contact with the side wall of the inclined block and is squeezed and locked in place. This causes the inclined block to move the locking rod towards the photovoltaic panel, further improving the locking effect of the locking rod on the photovoltaic panel.

[0019] This invention, through the coordinated arrangement of adjustment, stabilization, and auxiliary components, ensures that when the support frame rotates to a position perpendicular to the column, it is subjected to the elastic deformation of two first compression springs. These springs compress the fixed shells, causing them to slide a photovoltaic panel to the middle of the support frame. At this point, the multiple flexible clamps in the stabilization component cease clamping and pressing on one side wall of the photovoltaic panel, preventing curved bulges at the middle of the panel and maintaining its flatness and uniform stress distribution. Simultaneously, the elastic deformation of a second compression spring inside the fixed shell causes a piston plate to slide within the shell, allowing airflow from the rod area of ​​the fixed shell to enter the exhaust pipe. This airflow is then discharged outwards through the exhaust pipe, effectively purging the groove at the support frame. This prevents excessive dust particles from accumulating inside the groove and avoids jamming during sliding, thus improving the stability of the device's operation. Attached Figure Description

[0020] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0021] Figure 1 This is a schematic diagram of the overall bottom view of the present invention;

[0022] Figure 2 This is a schematic diagram of the cross-sectional structure of the column of the present invention;

[0023] Figure 3 For the present invention Figure 2 Enlarged view of A in the middle;

[0024] Figure 4 This is a schematic diagram of the oblique strip cross-sectional structure of the present invention;

[0025] Figure 5 This is a schematic diagram of the cross-sectional structure of the beam of the present invention;

[0026] Figure 6 This is a schematic cross-sectional view of the support frame structure of the present invention;

[0027] Figure 7 For the present invention Figure 6 Enlarged view of B in the middle;

[0028] Figure 8 This is a schematic diagram of the side structure of the first compression spring of the present invention;

[0029] Figure 9 This is a schematic diagram of the side structure of the flexible clamping plate of the present invention;

[0030] Figure 10 This is a top view of the exhaust pipe structure of the present invention.

[0031] In the diagram: 1. Column; 2. Fixing sleeve; 3. Electric push rod; 4. Top sleeve; 5. Fixing block; 6. Installation and adjustment mechanism; 61. Crossbeam; 62. Square sleeve; 63. Diagonal strip; 64. Adjustment component; 65. Stabilizing component; 66. Auxiliary component; 641. Support frame; 642. Fixing plate; 643. Slide groove; 644. Sliding frame; 645. Flexible rubber strip; 646. Photovoltaic panel; 647. Positioning rod; 648. Diagonal block; 649. Tension spring; 6410. Fixing shell; 6411. First compression spring; 651. Telescopic rotating component; 652. Sliding sleeve block; 653. Limiting rod; 654. Square plate; 655. Elastic frame rod; 656. Flexible clamping plate; 657. Fixing rod; 661. Connecting plate; 662. Telescopic rod; 663. Piston plate; 664. Second compression spring; 665. Exhaust pipe. 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] like Figures 1 to 10 As shown, the present invention provides a rapid assembly photovoltaic panel installation support device for mountainous areas, including a column 1, a fixing sleeve 2 fixedly connected to one end of the column 1, an electric push rod 3 hinged to the side wall of the fixing sleeve 2, a top sleeve 4 fixedly connected to the top of the column 1, a fixing block 5 fixedly connected to the top of the top sleeve 4, and also includes;

[0034] The installation adjustment mechanism 6 includes a crossbeam 61 rotatably connected to the inner wall of the fixed block 5. Square sleeves 62 are fixedly connected to the outer walls of both ends of the crossbeam 61. Diagonal strips 63 are fixedly connected to both sides of the square sleeves 62. An adjustment component 64 is provided on the top of the diagonal strips 63 for tilting the device.

[0035] The adjustment assembly 64 includes a support frame 641 fixedly connected to the top of the inclined bar 63. Two support frames 641 are provided. The top of the electric push rod 3 is rotatably connected to a fixing plate 642. The top of the fixing plate 642 is fixedly connected to the bottom of the support frame 641.

[0036] The inner wall of the support frame 641 is provided with sliding grooves 643 on both sides. The inner wall of the sliding groove 643 is slidably connected to a sliding frame 644. The inner wall of the sliding frame 644 is fixedly connected to a flexible rubber strip 645. The inner wall of the flexible rubber strip 645 is movably connected to a photovoltaic panel 646.

[0037] The above-mentioned solution involves inserting column 1 into the ground and connecting top sleeve 4 to the top of column 1 with bolts. The middle end of crossbeam 61 is rotatably connected to fixing block 5, which is then fixedly connected to top sleeve 4. Both ends of crossbeam 61 are bolted to square sleeve 62. The sidewalls of square sleeve 62 are bolted to two diagonal strips 63, which are then connected to support frame 641, thus enabling rapid assembly of the support device. Workers place photovoltaic panels 646 within flexible adhesive strips 645, quickly completing the installation of photovoltaic panels 646, significantly reducing installation time and manpower.

[0038] Both sides of the sliding frame 644 are slidably connected with locking rods 647. One end of the locking rod 647 is fixedly connected with a wedge block 648, and one side of the wedge block 648 is fixedly connected with a tension spring 649.

[0039] The above solution is adopted: under the action of elastic deformation of tension spring 649, tension spring 649 drives locking rod 647 to slide on the inner wall of sliding frame 644, so that multiple locking rods 647 lock the photovoltaic panel 646, thereby achieving the initial stable installation of photovoltaic panel 646.

[0040] One end of the tension spring 649 is fixedly connected to one side of the outer wall of the sliding frame 644. Both sides of the sliding frame 644 near the locking rod 647 are fixedly connected to the fixing shell 6410. One side of the fixing shell 6410 is fixedly connected to the first compression spring 6411. One end of the first compression spring 6411 is fixedly connected to one side of the inner wall of the support frame 641.

[0041] Using the above scheme: After installation, the electric push rod 3 is activated. The electric push rod 3 drives the fixed plate 642 to extend and retract, which in turn drives the support frame 641 to extend and retract. The support frame 641 indirectly drives the crossbeam 61 in the installation adjustment mechanism 6 to rotate along the inner wall of the fixed block 5, thereby realizing the adjustment of the angle of the photovoltaic panel 646, ensuring that the photovoltaic panel 646 obtains the best irradiation angle and optimizing its power generation efficiency.

[0042] like Figures 1 to 10 As shown, the inner wall of the support frame 641 is provided with a stabilizing component 65. The stabilizing component 65 includes a telescopic rotating member 651 hinged to the inner wall of the support frame 641 near the first compression spring 6411. A sliding sleeve block 652 is hinged to the top of the telescopic rotating member 651.

[0043] The inner wall of the sliding sleeve 652 is slidably connected to a limit rod 653. The bottom of the limit rod 653 is fixedly connected to the top of the sliding frame 644. One end of the sliding sleeve 652 is fixedly connected to a square plate 654.

[0044] The top of the square plate 654 is slidably connected to an elastic support rod 655, the bottom of the elastic support rod 655 is fixedly connected to a flexible clamping plate 656, and both ends of one side of the flexible clamping plate 656 are fixedly connected to a fixing rod 657.

[0045] Using the above scheme: When the support frame 641 deflects to the side wall of the column 1, the sliding frame 644 slides down in the slide groove 643 under the influence of the photovoltaic panel 646's own weight. The sliding frame 644 gradually moves away from the support frame 641, causing the telescopic rotating component 651 and the sliding sleeve block 652 to slide along the limiting rod 653. The sliding sleeve block 652 drives the square plate 654 and the elastic frame rod 655 to move, thereby causing the flexible clamping plate 656 to press against the top side wall of the photovoltaic panel 646.

[0046] An auxiliary component 66 is provided on one side of the sliding sleeve 652. The auxiliary component 66 includes a connecting plate 661 fixedly connected between the two sliding sleeves 652. A telescopic rod 662 is fixedly connected to the bottom of the connecting plate 661. The fixed end of the telescopic rod 662 passes through the fixed shell 6410 and extends into the interior of the fixed shell 6410.

[0047] A piston plate 663 is fixedly connected to the bottom of the telescopic rod 662. The outer wall of the piston plate 663 is slidably connected to the inner wall of the fixed shell 6410. A second compression spring 664 is fixedly connected to the bottom of the piston plate 663. The bottom of the second compression spring 664 is fixedly connected to the bottom of the inner wall of the fixed shell 6410. Both ends of one side of the fixed shell 6410 are connected to exhaust pipes 665.

[0048] The above solution involves the second compression spring 664, under its elastic deformation, driving the piston plate 663 to slide within the fixed housing 6410. This allows airflow from the rod-side area of ​​the fixed housing 6410 to enter the exhaust pipe 665 and be discharged outwards. The airflow is then sprayed into the slide groove 643, effectively removing dust particles and preventing the sliding frame 644 from getting stuck within it, thereby improving the operational stability of the device.

[0049] Working principle and usage process of this invention:

[0050] The column 1 is inserted into the ground, and then the top sleeve 4 is bolted to the top of the column 1. The middle end of the crossbeam 61 rotates inside the fixing block 5, and the fixing block 5 is fixedly connected to the top sleeve 4. The two ends of the crossbeam 61 are bolted to the square sleeve 62, and the side wall of the square sleeve 62 is bolted to two diagonal strips 63. The diagonal strips 63 are bolted to the support frame 641, thereby enabling the rapid assembly of the support device. The workers place the photovoltaic panel 646 inside the flexible adhesive strip 645 to quickly install the photovoltaic panel 646, reducing the installation time and manpower. Due to the elastic deformation of the tension spring 649, the tension spring 649 drives the locking rod 647 to slide on the inner wall of the sliding frame 644, so that multiple locking rods 647 lock the photovoltaic panel 646, initially stabilizing the installation of the photovoltaic panel 646 and preventing the photovoltaic panel 646 from falling off. After the installation is completed, the electric push rod 3 is activated. The electric push rod 3 drives the fixing plate 642 to move telescopically. The fixing plate 642 drives the support frame 641 to move telescopically. The support frame 641 indirectly drives the crossbeam 61 in the installation adjustment mechanism 6 to rotate along the inner wall of the fixing block 5, thereby enabling the angle adjustment of the photovoltaic panel 646, so that the photovoltaic panel 646 can obtain the best irradiation angle and optimize the power generation efficiency of the photovoltaic panel 646.

[0051] When the support frame 641 deflects to the side wall of the column 1, the weight of the sliding frame 644, the flexible rubber strip 645, and the photovoltaic panel 646 causes the sliding frame 644 to slide down inside the slide groove 643. At this time, one end of the higher-positioned sliding frame 644 gradually moves away from the top of the support frame 641, causing the telescopic rotating component 651 to drive the sliding sleeve block 652 to slide on the outer wall of the limiting rod 653. The sliding sleeve block 652 drives the square plate 654 and the elastic frame rod 655 to move, and the elastic frame rod 655 drives the flexible clamping plate 6 When the flexible clamp 656 moves, it contacts one side of the top photovoltaic panel 646, squeezing the top side wall of the photovoltaic panel 646. The flexible clamp 656 and the locking rod 647 together clamp the side wall of the photovoltaic panel 646, preventing it from being blown away by strong winds. This improves the stability of the photovoltaic panel 646 after angle adjustment and effectively enhances its anti-interference ability in windy environments, ensuring its performance. As the flexible clamp 656 moves closer to the photovoltaic panel 646, it moves the fixing rod 657. During this movement, the fixing rod 657 contacts the side wall of the inclined block 648, squeezing and locking it. This causes the inclined block 648 to move the locking rod 647 towards the photovoltaic panel 646, further improving the locking effect of the locking rod 647 on the photovoltaic panel 646.

[0052] When the support frame 641 rotates to a position perpendicular to the column 1, it is subjected to the elastic deformation of the two first compression springs 6411. The first compression springs 6411 compress the fixed shell 6410, causing the two fixed shells 6410 to slide a photovoltaic panel 646 to the middle of the support frame 641. At this time, the multiple flexible clamps 656 in the stabilizing component 65 no longer clamp and press one side wall of the photovoltaic panel 646, avoiding the phenomenon of curved bulge at the middle of the photovoltaic panel 646, and maintaining the flatness and uniform stress state of the photovoltaic panel 646. Simultaneously, due to the elastic deformation of the second compression spring 664 inside the fixed housing 6410, the second compression spring 664 drives the piston plate 663 to slide inside the fixed housing 6410, allowing the airflow in the rod area of ​​the fixed housing 6410 to enter the interior of the exhaust pipe 665. The airflow is discharged outward through the exhaust pipe 665, which can spray air into the slide groove 643 at the support frame 641, preventing excessive dust particles from accumulating inside the slide groove 643, avoiding jamming when the sliding frame 644 slides inside the slide groove 643, and improving the stability of the device operation.

[0053] 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.

[0054] 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 rapid-assembly photovoltaic panel installation support device for mountainous areas, comprising a column (1), a fixing sleeve (2) fixedly connected to one end of the column (1), an electric push rod (3) hinged to the side wall of the fixing sleeve (2), a top sleeve (4) fixedly connected to the top of the column (1), and a fixing block (5) fixedly connected to the top of the top sleeve (4), characterized in that: Also includes; The installation adjustment mechanism (6) includes a crossbeam (61) rotatably connected to the inner wall of the fixed block (5). Both ends of the crossbeam (61) are fixedly connected to square sleeves (62). Both sides of the square sleeves (62) are fixedly connected to diagonal strips (63). The top of the diagonal strips (63) is provided with an adjustment component (64) for tilting the device. The adjustment assembly (64) includes a support frame (641) fixedly connected to the top of the inclined bar (63). There are two support frames (641). The top of the electric push rod (3) is rotatably connected to a fixing plate (642). The top of the fixing plate (642) is fixedly connected to the bottom of the support frame (641). The inner wall of the support frame (641) is provided with sliding grooves (643) on both sides. The inner wall of the sliding groove (643) is slidably connected to a sliding frame (644). The inner wall of the sliding frame (644) is fixedly connected to a flexible rubber strip (645). The inner wall of the flexible rubber strip (645) is movably connected to a photovoltaic panel (646). Both sides of the sliding frame (644) are slidably connected with locking rods (647), one end of the locking rod (647) is fixedly connected with a wedge (648), and one side of the wedge (648) is fixedly connected with a tension spring (649). One end of the tension spring (649) is fixedly connected to one side of the outer wall of the sliding frame (644). The sliding frame (644) is fixedly connected to two sides near the locking rod (647) with fixed shells (6410). One side of the fixed shell (6410) is fixedly connected to a first compression spring (6411). One end of the first compression spring (6411) is fixedly connected to one side of the inner wall of the support frame (641). The inner wall of the support frame (641) is provided with a stabilizing component (65), the stabilizing component (65) includes a telescopic rotating member (651) hinged to the inner wall of the support frame (641) near the first compression spring (6411), and a sliding sleeve block (652) is hinged to the top of the telescopic rotating member (651). The inner wall of the sliding sleeve (652) is slidably connected to a limiting rod (653), the bottom of the limiting rod (653) is fixedly connected to the top of the sliding frame (644), and a square plate (654) is fixedly connected to one end of the sliding sleeve (652). The top of the square plate (654) is slidably connected to an elastic support rod (655), the bottom of the elastic support rod (655) is fixedly connected to a flexible clamping plate (656), and both ends of one side of the flexible clamping plate (656) are fixedly connected to a fixing rod (657).

2. The rapid assembly photovoltaic panel installation support device for mountainous areas according to claim 1, characterized in that: An auxiliary component (66) is provided on one side of the sliding sleeve (652). The auxiliary component (66) includes a connecting plate (661) fixedly connected between the two sliding sleeves (652). A telescopic rod (662) is fixedly connected to the bottom of the connecting plate (661). The fixed end of the telescopic rod (662) passes through the fixed shell (6410) and extends into the interior of the fixed shell (6410).

3. The rapid assembly photovoltaic panel installation support device for mountainous areas according to claim 2, characterized in that: A piston plate (663) is fixedly connected to the bottom of the telescopic rod (662). The outer wall of the piston plate (663) is slidably connected to the inner wall of the fixed shell (6410). A second compression spring (664) is fixedly connected to the bottom of the piston plate (663). The bottom of the second compression spring (664) is fixedly connected to the bottom of the inner wall of the fixed shell (6410). Both ends of one side of the fixed shell (6410) are connected to exhaust pipes (665).