A strong wind resistant mountain photovoltaic panel mounting device and method

By designing a wind-resistant mountain photovoltaic panel installation device, the structural fatigue problem of photovoltaic supports under strong winds is solved by using rotating rods and wind-resistant components to disperse wind force, thereby improving the stability and power generation efficiency of photovoltaic panels.

CN121567032BActive 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 (PV) mounting systems are prone to structural fatigue under strong wind conditions, which can lead to loosening or damage of the PV panels, affecting their service life and increasing maintenance costs.

Method used

A wind-resistant mountain photovoltaic panel installation device is designed. By cooperating with a rotating rod and wind-resistant components, the windward area of ​​the photovoltaic panel is reduced. Components such as gears, toothed plates, and compression springs are used to disperse wind force, stabilize the rotation of the photovoltaic panel, and enhance the stability of the support structure.

Benefits of technology

It effectively reduces the pressure on photovoltaic panels and support systems, prevents loosening or damage, extends the life of the device, improves the stability and power generation efficiency of photovoltaic panels, and reduces the impact of wind on the device.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN121567032B_ABST
    Figure CN121567032B_ABST
Patent Text Reader

Abstract

This invention belongs to the field of photovoltaic support technology and discloses a wind-resistant mountain photovoltaic panel installation device and method. It includes a photovoltaic support base, with crossbeams rotatably connected to both sides of the top of the support base. An arc-shaped beam is fixedly connected to the bottom of each crossbeam. When encountering strong winds, due to the large windward area of ​​the photovoltaic panel, the initial velocity of the strong wind causes the photovoltaic panel to drive the support shell and rotating rod to rotate around the connecting beams. This rotation of the photovoltaic panel under wind force effectively reduces the pressure on the photovoltaic panel and support system, preventing loosening or damage caused by excessive pressure when fastening the photovoltaic panel. This reduces the risk of damage and extends the device's service life. The rotation mechanism reduces the windward area of ​​the photovoltaic panel, preventing wind force from concentrating in one direction or location, thus reducing pressure on the photovoltaic support base and the potential risk of wind disasters. Compared to static supports, the rotational design effectively disperses the impact of wind force on the entire device.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention belongs to the field of photovoltaic support technology, specifically a wind-resistant mountain photovoltaic panel installation device and method. Background Technology

[0002] With the development of solar energy application technology, photovoltaic power generation is receiving increasing attention and application. Photovoltaic power generation projects require a large amount of land resources for photovoltaic panels, but as the number of projects increases, available land resources are decreasing, leading to a significant increase in mountainous photovoltaic projects. Currently, photovoltaic power generation devices typically use adjustable arc-shaped photovoltaic brackets to support the photovoltaic panels. This type of bracket is an innovative photovoltaic support system; its adjustable design allows for adjustment of the photovoltaic panel angle according to different sunlight and wind conditions.

[0003] Existing technologies typically use high-strength fasteners and connectors for adjustable arc-shaped photovoltaic (PV) mounting systems to ensure that the PV panels and mounting systems are not loosened or damaged in strong winds. However, during prolonged exposure to strong winds, the large surface area of ​​the PV panels results in them being subjected to widespread wind movement, causing structural fatigue in the connecting brackets and fasteners. This affects the lifespan of the installed PV system and increases maintenance costs. Summary of the Invention

[0004] To address the structural fatigue issue of brackets and fasteners mentioned in the background art, this invention provides a wind-resistant mountain photovoltaic panel installation device and method.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a strong wind-resistant mountain photovoltaic panel installation device, comprising a photovoltaic support base, with crossbeams rotatably connected to both sides of the top of the photovoltaic support base, an arc-shaped beam fixedly connected to the bottom of the crossbeams, one side of the arc-shaped beam fixedly connected to the side wall of the photovoltaic support base, and a connecting beam fixedly connected to the top of the crossbeams; further comprising a photovoltaic panel installation mechanism, the photovoltaic panel installation mechanism comprising a rotating rod rotatably connected to the side wall of the connecting beam, one end of the rotating rod fixedly connected to a support shell, the inner wall of the support shell contacting the photovoltaic panel, and a wind-resistant component provided at the end of the rotating rod to reduce damage to the photovoltaic panel caused by strong winds.

[0006] Preferably, the wind-resistant component includes a gear fixedly connected to the outer wall of one end of the rotating rod, the gear being disposed inside the connecting beam, a toothed plate being meshed with the bottom of the outer wall of the gear, and the bottom of the toothed plate being slidably connected to the bottom of the inner wall of the connecting beam.

[0007] Preferably, both ends of the toothed plate are in contact with square plates, a round rod is fixedly connected to one side of the square plate, a connecting plate is fixedly connected to one end of the round rod, the connecting plate is disposed outside the connecting beam, and a compression spring is fixedly connected to the side of the square plate near the round rod.

[0008] Preferably, one end of the compression spring is fixedly connected to one side of the inner wall of the connecting beam, a fixing frame is fixedly connected to the top of the square plate, elastic slides are slidably connected to both sides of the top of the fixing frame, a semi-circular block is fixedly connected to the bottom of the elastic slide, the bottom of the semi-circular block contacts an irregularly shaped clip, and the bottom of the irregularly shaped clip is fixedly connected to the top of the connecting beam.

[0009] Preferably, the side wall of the connecting plate is provided with a stabilizing component, the stabilizing component including a strip box fixedly connected to the side of the connecting plate near the round rod, and a flexible positioning block fixedly connected to one side of the outer wall of the strip box.

[0010] Preferably, the sidewall of the flexible positioning block contacts one side of the outer wall of the support shell, and three round frame rods are slidably connected to one side of the inner wall of the strip box. One end of each round frame rod passes through the flexible positioning block and extends to the outside of the flexible positioning block.

[0011] Preferably, an auxiliary component is provided at the end of the connecting plate. The auxiliary component includes a fixed rod fixedly connected to one end of the connecting plate, a rotating plate rotatably connected to the outer wall of one end of the fixed rod, and a square box fixedly connected to one side of the outer wall of the rotating plate.

[0012] Preferably, a piston plate is slidably connected to one end of the inner wall of the square box, a tension spring is fixedly connected to one side of the piston plate, one end of the tension spring is fixedly connected to one side of the inner wall of the square box, and a sliding bracket rod is fixedly connected to the side of the piston plate away from the tension spring.

[0013] Preferably, one end of the sliding frame rod is hinged to a connector, the connector is fixedly installed on the outside of the square box, one end of the connector is fixedly connected to one side of the outer wall of the support shell, the top of the square box is connected to a flexible hose, one end of the flexible hose is connected to the top of the strip box; the square box has an opening on the side near the support shell.

[0014] A method for using a wind-resistant mountain photovoltaic panel installation device;

[0015] S1. Install the photovoltaic support base in the mountainous area, and then splice and install the device. When encountering strong winds, due to the large windward area of ​​the photovoltaic panel, the initial speed of the strong wind causes the photovoltaic panel to drive the support shell and rotating rod to rotate around the connecting beam. Due to the rotation of the photovoltaic panel under the action of wind, the pressure on the photovoltaic panel and the support system can be effectively reduced.

[0016] S2. When the rotating rod rotates, it drives the gear to rotate. When the gear rotates, it contacts the toothed plate, causing the toothed plate to move along the inner wall of the connecting beam. During the movement of the toothed plate, it squeezes the square plate, causing the square plate to move the fixed frame. The fixed frame drives the elastic slide and the semicircular block to move. During the movement of the semicircular block, it will contact the top of the irregularly shaped card strip. It is blocked by multiple oblique concave blocks opened on the top of the irregularly shaped card strip, which reduces the rotation speed of the photovoltaic panel when subjected to impact force.

[0017] S3. When the square plate moves to its reset position, it drives the round rod and the connecting plate to move to their reset positions. The connecting plate gradually moves toward the photovoltaic panel. The connecting plate drives the strip box and the flexible positioning block to move. Due to the flexible deformation material of the flexible positioning block, as the flexible positioning block moves toward the support shell, it can gradually insert and squeeze multiple support shells, so that the photovoltaic panel can rotate together with the connecting beam when it does not encounter strong winds.

[0018] Compared with the prior art, the beneficial effects of the present invention are as follows:

[0019] This invention utilizes a photovoltaic panel installation mechanism to install the photovoltaic support frame in mountainous terrain. The assembly of the device is then completed. When encountering strong winds, the large windward area of ​​the photovoltaic panels causes the support shell and rotating rod to rotate around the connecting beam due to the initial velocity of the wind. This rotation of the photovoltaic panels under wind force effectively reduces the pressure on the photovoltaic panels and support system, preventing loosening or damage caused by excessive pressure during panel fastening. This reduces the risk of damage and extends the device's lifespan. The rotation mechanism reduces the windward area of ​​the photovoltaic panels, preventing wind force from concentrating in one direction or area, thus reducing pressure on the photovoltaic support frame and the potential risk of wind damage. Compared to static supports, the rotational design effectively disperses the impact of wind on the entire device, reducing the impact force on the photovoltaic panels when encountering strong winds. When the rotating rod rotates, it drives the gear to rotate as well. The gear contacts the toothed plate as it rotates, causing the toothed plate to move along the inner wall of the connecting beam. During the movement of the toothed plate, it presses against the square plate, causing the square plate to move the fixing frame. The fixing frame then moves the elastic slide and the semicircular block. During the movement of the semicircular block, it comes into contact with the top of the irregularly shaped clip. The multiple oblique recesses on the top of the irregularly shaped clip reduce the rotation speed of the photovoltaic panel when subjected to impact, preventing violent rotation of the photovoltaic panel and ensuring that the photovoltaic panel will not rotate out of control in strong winds.

[0020] This invention employs a photovoltaic panel installation mechanism. When the toothed plate presses against the square plate, the square plate moves the round rod. At this point, it is subjected to elastic compression by a compression spring. If the elastic deformation of the compression spring is too large, it will hinder the toothed plate from continuing to move within the connecting beam. The photovoltaic panel, having experienced the initial velocity of a strong wind, can smoothly withstand the wind's force. Under the elastic compression of the compression spring, the photovoltaic panel slowly and smoothly resets. During the reset movement, the square plate moves the round rod and the connecting plate, which gradually moves towards the photovoltaic panel. The connecting plate also moves the strip box and the flexible positioning block. Due to the flexible deformation material of the flexible positioning block, as the block approaches the support shell, it gradually inserts and compresses multiple support shells. This allows the photovoltaic panel to rotate together with the connecting beam when not encountering strong winds, facilitating the adjustment of the photovoltaic panel's angle of sunlight and improving the photovoltaic power generation efficiency.

[0021] This invention, through the design of a photovoltaic panel installation mechanism, allows the piston plate to slide inside the square box as the connecting plate approaches the supporting shell. This compresses the airflow in the spring area of ​​the square box, drawing it into the flexible hose and then into the strip box. This causes the circular frame rod inside the strip box to slide outwards. As the circular frame rod moves outwards, it compresses the side wall of the supporting shell, improving the stability of the supporting shell and connecting beam during operation. In strong winds, the supporting shell rotates slightly, causing the connecting parts and sliding frame rod to rotate. The sliding frame rod pulls the piston plate to slide inside the square box, allowing the airflow inside the strip box to flow back into the square box. At this point, the airflow no longer compresses the circular frame rod, and the circular frame rod no longer compresses the supporting shell. This allows the supporting shell to rotate the photovoltaic panel with the strong wind, improving the stability of the device. Furthermore, the structure of the auxiliary components further prevents the supporting shell from causing the photovoltaic panel to rotate excessively. Attached Figure Description

[0022] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0023] Figure 1 This is a schematic diagram of the overall side structure of the present invention;

[0024] Figure 2 This is a schematic diagram of the overall rear structure of the present invention;

[0025] Figure 3 This is a top view schematic diagram of the photovoltaic panel structure of the present invention;

[0026] Figure 4 For the present invention Figure 3 Enlarged view of A in the middle;

[0027] Figure 5 This is a schematic cross-sectional view of the connecting beam structure of the present invention;

[0028] Figure 6 This is a top view of the support shell structure of the present invention;

[0029] Figure 7 For the present invention Figure 6 Enlarged view of B in the middle;

[0030] Figure 8 This is a schematic cross-sectional view of the flexible tube structure of the present invention.

[0031] In the diagram: 1. Photovoltaic support base; 2. Crossbeam; 3. Arc beam; 4. Connecting beam; 5. Photovoltaic panel installation mechanism; 51. Rotating rod; 52. Support shell; 53. Photovoltaic panel; 54. Wind-resistant component; 55. Stabilizing component; 56. Auxiliary component; 541. Gear; 542. Toothed plate; 543. Square plate; 544. Round rod; 545. Compression spring; 546. Connecting plate; 547. Fixing frame; 548. Elastic slide; 549. Semicircular block; 5410. Irregularly shaped clip; 551. Strip box; 552. Flexible positioning block; 553. Round frame rod; 561. Fixing rod; 562. Rotating plate; 563. Square box; 564. Piston plate; 565. Tension spring; 566. Sliding frame rod; 567. Connector; 568. Hoses. 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 8 As shown, the present invention provides a strong wind resistant mountain photovoltaic panel installation device, including a photovoltaic support base 1, with crossbeams 2 rotatably connected to both sides of the top of the photovoltaic support base 1, an arc beam 3 fixedly connected to the bottom of the crossbeams 2, one side of the arc beam 3 fixedly connected to the side wall of the photovoltaic support base 1, and a connecting beam 4 fixedly connected to the top of the crossbeams 2, and also includes;

[0034] The photovoltaic panel installation mechanism 5 includes a rotating rod 51 rotatably connected to the side wall of the connecting beam 4. One end of the rotating rod 51 is fixedly connected to a support shell 52. The inner wall of the support shell 52 contacts the photovoltaic panel 53. The end of the rotating rod 51 is provided with a wind-resistant component 54 to reduce the damage caused by strong winds blowing on the photovoltaic panel 53.

[0035] The above solution involves installing the photovoltaic support base 1 in a mountainous area, followed by assembling and installing the device. When encountering strong winds, due to the large windward area of ​​the photovoltaic panel 53, the initial velocity of the strong wind causes the photovoltaic panel 53 to drive the support shell 52 and the rotating rod 51 to rotate around the connecting beam 4. This rotation of the photovoltaic panel 53 under wind force effectively reduces the pressure on the photovoltaic panel 53 and the support system.

[0036] The wind-resistant component 54 includes a gear 541 fixedly connected to the outer wall of one end of the rotating rod 51. The gear 541 is disposed inside the connecting beam 4. A toothed plate 542 is meshed with the bottom of the outer wall of the gear 541. The bottom of the toothed plate 542 is slidably connected to the bottom of the inner wall of the connecting beam 4.

[0037] Both ends of the toothed plate 542 are in contact with square plates 543. A round rod 544 is fixedly connected to one side of the square plate 543. A connecting plate 546 is fixedly connected to one end of the round rod 544. The connecting plate 546 is located outside the connecting beam 4. A compression spring 545 is fixedly connected to the side of the square plate 543 near the round rod 544.

[0038] Using the above scheme: When the toothed plate 542 presses against the square plate 543, the square plate 543 drives the round rod 544 to move. At this time, it is elastically compressed by the compression spring 545. When the elastic deformation of the compression spring 545 is too large, it will hinder the toothed plate 542 from continuing to move inside the connecting beam 4. At this time, the photovoltaic panel 53 can withstand the strong wind blowing smoothly after the initial velocity of the strong wind.

[0039] One end of the compression spring 545 is fixedly connected to one side of the inner wall of the connecting beam 4. A fixing frame 547 is fixedly connected to the top of the square plate 543. Elastic slides 548 are slidably connected to both sides of the top of the fixing frame 547. A semi-circular block 549 is fixedly connected to the bottom of the elastic slide 548. The bottom of the semi-circular block 549 contacts a shaped clip 5410. The bottom of the shaped clip 5410 is fixedly connected to the top of the connecting beam 4.

[0040] Using the above scheme: When the rotating rod 51 rotates, the rotating rod 51 drives the gear 541 to rotate. When the gear 541 rotates, it comes into contact with the toothed plate 542, causing the toothed plate 542 to move along the inner wall of the connecting beam 4. During the movement of the toothed plate 542, it squeezes the square plate 543, causing the square plate 543 to drive the fixed frame 547 to move. The fixed frame 547 drives the elastic slide 548 and the semicircular block 549 to move. During the movement of the semicircular block 549, it will come into contact with the top of the irregularly shaped card strip 5410 and be blocked by the multiple oblique concave blocks opened on the top of the irregularly shaped card strip 5410.

[0041] like Figures 1 to 8As shown, a stabilizing component 55 is provided on the side wall of the connecting plate 546. The stabilizing component 55 includes a strip box 551 fixedly connected to the side of the connecting plate 546 near the round rod 544. A flexible positioning block 552 is fixedly connected to one side of the outer wall of the strip box 551.

[0042] The sidewall of the flexible positioning block 552 contacts the outer wall of the support shell 52. Three round frame rods 553 are slidably connected to the inner wall of the strip box 551. One end of the round frame rod 553 passes through the flexible positioning block 552 and extends to the outside of the flexible positioning block 552.

[0043] Using the above scheme: When the square plate 543 moves to reset, the square plate 543 drives the round rod 544 and the connecting plate 546 to move to reset. The connecting plate 546 gradually moves towards the photovoltaic panel 53. The connecting plate 546 drives the strip box 551 and the flexible positioning block 552 to move. Due to the flexible deformation material of the flexible positioning block 552, as the flexible positioning block 552 approaches the support shell 52, it can gradually insert and squeeze multiple support shells 52, so that the photovoltaic panel 53 can rotate together with the connecting beam 4 when it does not encounter strong wind.

[0044] An auxiliary component 56 is provided at the end of the connecting plate 546. The auxiliary component 56 includes a fixing rod 561 fixedly connected to one end of the connecting plate 546. A rotating plate 562 is rotatably connected to the outer wall of one end of the fixing rod 561. A square box 563 is fixedly connected to one side of the outer wall of the rotating plate 562.

[0045] A piston plate 564 is slidably connected to one end of the inner wall of the square box 563. A tension spring 565 is fixedly connected to one side of the piston plate 564. One end of the tension spring 565 is fixedly connected to one side of the inner wall of the square box 563. A sliding bracket rod 566 is fixedly connected to the side of the piston plate 564 away from the tension spring 565.

[0046] One end of the sliding frame rod 566 is hinged to a connector 567, which is fixedly installed on the outside of the square box 563. One end of the connector 567 is fixedly connected to one side of the outer wall of the support shell 52. The top of the square box 563 is connected to a flexible hose 568, one end of which is connected to the top of the strip box 551. The square box 563 has an opening on the side near the support shell 52.

[0047] The above scheme works as follows: When the connecting plate 546 gradually approaches the support shell 52, the piston plate 564 slides inside the square box 563, compressing the airflow in the spring area of ​​the square box 563. The airflow enters the inside of the hose 568 and then enters the inside of the strip box 551, causing the circular frame rod 553 sliding outward inside the strip box 551. During the outward movement of the circular frame rod 553, it compresses the side wall of the support shell 52, thereby improving the stability of the support shell 52 and the connecting beam 4 when operating together. The purpose of the opening on the side of the square box 563 near the support shell 52 is to avoid limiting interference when the sliding frame rod 566 moves.

[0048] Working principle and usage process of this invention:

[0049] The photovoltaic support base 1 is installed in the mountainous area, and then the device is assembled. When encountering strong winds, due to the large windward area of ​​the photovoltaic panel 53, the initial velocity of the strong wind causes the photovoltaic panel 53 to drive the support shell 52 and the rotating rod 51 to rotate around the connecting beam 4. This rotation of the photovoltaic panel 53 under the action of wind effectively reduces the pressure on the photovoltaic panel 53 and the support system, preventing excessive pressure during the fastening of the photovoltaic panel 53, which could lead to loosening or damage. This reduces the risk of damage to the device and extends its service life. The rotation mechanism reduces the windward area of ​​the photovoltaic panel 53, preventing wind from concentrating in one direction or location, thus reducing the pressure on the photovoltaic support base 1 and the potential risk of wind damage. Compared with a static support, the rotational design effectively disperses the impact of wind on the entire device, reducing the impact force on the photovoltaic panel 53 when encountering strong winds. When the rotating rod 51 rotates, it drives the gear 541 to rotate. When the gear 541 rotates, it comes into contact with the toothed plate 542, causing the toothed plate 542 to move along the inner wall of the connecting beam 4. During the movement of the toothed plate 542, it squeezes the square plate 543, causing the square plate 543 to drive the fixed frame 547 to move. The fixed frame 547 drives the elastic slide 548 and the semi-circular block 549 to move. During the movement of the semi-circular block 549, it comes into contact with the top of the irregularly shaped clip 5410. It is blocked by the multiple oblique concave blocks on the top of the irregularly shaped clip 5410, which reduces the rotation speed of the photovoltaic panel 53 when subjected to impact force, avoids violent rotation of the photovoltaic panel 53, and ensures that the photovoltaic panel 53 will not rotate out of control in strong winds.

[0050] When the toothed plate 542 presses against the square plate 543, the square plate 543 drives the round rod 544 to move. At this time, it is subjected to elastic compression by the compression spring 545. When the elastic deformation of the compression spring 545 is too large, it will hinder the toothed plate 542 from continuing to move inside the connecting beam 4. At this time, the photovoltaic panel 53 can withstand the strong wind blowing smoothly after passing the initial velocity of the strong wind. When subjected to elastic compression by the compression spring 545, the photovoltaic panel 53 slowly and smoothly performs the reset work. When the square plate 543 moves to its reset position, it drives the round rod 544 and the connecting plate 546 to move to their reset positions. The connecting plate 546 gradually moves toward the photovoltaic panel 53. The connecting plate 546 also drives the strip box 551 and the flexible positioning block 552 to move. Due to the flexible deformation material of the flexible positioning block 552, as the flexible positioning block 552 approaches the support shell 52, it can gradually insert and squeeze multiple support shells 52. This allows the photovoltaic panel 53 to rotate together with the connecting beam 4 when there is no strong wind, which facilitates the adjustment of the angle of the photovoltaic panel 53 with the sun and improves the photovoltaic power generation efficiency of the photovoltaic panel 53.

[0051] As the connecting plate 546 gradually approaches the support shell 52, the piston plate 564 slides inside the square box 563, compressing the airflow in the spring area of ​​the square box 563. The airflow enters the inside of the hose 568 and then enters the inside of the strip box 551, causing the circular frame rod 553 sliding outward inside the strip box 551. During the outward movement of the circular frame rod 553, it compresses the side wall of the support shell 52, thereby improving the stability of the support shell 52 and the connecting beam 4 when operating together. When encountering strong winds, the support shell 52 rotates slightly. 52 drives the connecting piece 567 and the sliding frame rod 566 to rotate. The sliding frame rod 566 pulls the piston plate 564 to slide inside the square box 563, causing the airflow inside the strip box 551 to flow back into the square box 563. At this time, the airflow no longer compresses the round frame rod 553, and the round frame rod 553 no longer compresses the support shell 52. This allows the support shell 52 to drive the photovoltaic panel 53 to rotate with the strong wind, improving the stability of the device operation. Furthermore, due to the structure of the auxiliary component 56, it can further prevent the support shell 52 from driving the photovoltaic panel 53 to rotate at an excessive angle.

[0052] 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.

[0053] 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 wind-resistant mountain photovoltaic panel installation device, comprising a photovoltaic support base (1), wherein crossbeams (2) are rotatably connected to both sides of the top of the photovoltaic support base (1), an arc-shaped beam (3) is fixedly connected to the bottom of the crossbeams (2), one side of the arc-shaped beam (3) is fixedly connected to the side wall of the photovoltaic support base (1), and a connecting beam (4) is fixedly connected to the top of the crossbeams (2), characterized in that: Also includes; A photovoltaic panel installation mechanism (5) includes a rotating rod (51) rotatably connected to the side wall of the connecting beam (4). One end of the rotating rod (51) is fixedly connected to a support shell (52). A photovoltaic panel (53) is installed on the inner wall of the support shell (52). A wind-resistant component (54) is provided at the end of the rotating rod (51) to reduce the damage caused by strong winds blowing on the photovoltaic panel (53). The wind-resistant component (54) includes a gear (541) fixedly connected to the outer wall of one end of the rotating rod (51). The gear (541) is located inside the connecting beam (4). A toothed plate (542) is meshed with the bottom of the outer wall of the gear (541). The bottom of the toothed plate (542) is slidably connected to the bottom of the inner wall of the connecting beam (4). Both ends of the toothed plate (542) are in contact with square plates (543). A round rod (544) is fixedly connected to one side of the square plate (543). A connecting plate (546) is fixedly connected to one end of the round rod (544). The connecting plate (546) is located outside the connecting beam (4). A compression spring (545) is fixedly connected to the side of the square plate (543) near the round rod (544). One end of the compression spring (545) is fixedly connected to one side of the inner wall of the connecting beam (4). A fixing frame (547) is fixedly connected to the top of the square plate (543). An elastic slide (548) is slidably connected to both sides of the top of the fixing frame (547). A semi-circular block (549) is fixedly connected to the bottom of the elastic slide (548). A shaped clip (5410) contacts the bottom of the semi-circular block (549). The bottom of the shaped clip (5410) is fixedly connected to the top of the connecting beam (4). The side wall of the connecting plate (546) is provided with a stabilizing component (55), the stabilizing component (55) includes a strip box (551) fixedly connected to the side of the connecting plate (546) near the round rod (544), and a flexible positioning block (552) is fixedly connected to one side of the outer wall of the strip box (551). The sidewall of the flexible positioning block (552) contacts one side of the outer wall of the support shell (52), and three round frame rods (553) are slidably connected to one side of the inner wall of the strip box (551). One end of the round frame rod (553) passes through the flexible positioning block (552) and extends to the outside of the flexible positioning block (552).

2. The wind-resistant mountain photovoltaic panel installation device according to claim 1, characterized in that: An auxiliary component (56) is provided at the end of the connecting plate (546). The auxiliary component (56) includes a fixing rod (561) fixedly connected to one end of the connecting plate (546). A rotating plate (562) is rotatably connected to the outer wall of one end of the fixing rod (561). A square box (563) is fixedly connected to one side of the outer wall of the rotating plate (562).

3. The wind-resistant mountain photovoltaic panel installation device according to claim 2, characterized in that: A piston plate (564) is slidably connected to one end of the inner wall of the square box (563). A tension spring (565) is fixedly connected to one side of the piston plate (564). One end of the tension spring (565) is fixedly connected to one side of the inner wall of the square box (563). A sliding bracket rod (566) is fixedly connected to the side of the piston plate (564) away from the tension spring (565).

4. The wind-resistant mountain photovoltaic panel installation device according to claim 3, characterized in that: One end of the sliding frame rod (566) is hinged to a connector (567), which is fixedly installed on the outside of the square box (563). One end of the connector (567) is fixedly connected to one side of the outer wall of the support shell (52). The top of the square box (563) is connected to a flexible hose (568), one end of which is connected to the top of the strip box (551). The square box (563) has an opening on the side near the support shell (52).

5. A method of using a wind-resistant mountain photovoltaic panel installation device, employing the wind-resistant mountain photovoltaic panel installation device as described in claim 1, characterized in that: S1. The photovoltaic panel (53) has a large windward area. When the initial speed of the strong wind blows, the photovoltaic panel (53) drives the support shell (52) and the rotating rod (51) to rotate around the connecting beam (4). The rotation of the photovoltaic panel (53) under the action of wind is used to reduce the pressure on the photovoltaic panel (53) and the support system. S2. When the rotating rod (51) rotates, the rotating rod (51) drives the gear (541) to rotate. When the gear (541) rotates, it comes into contact with the toothed plate (542), causing the toothed plate (542) to move along the inner wall of the connecting beam (4). During the movement of the toothed plate (542), it squeezes the square plate (543), causing the square plate (543) to drive the fixed frame (547) to move. The fixed frame (547) drives the elastic slide (548) and the semicircular block (549) to move. During the movement of the semicircular block (549), it will come into contact with the top of the irregularly shaped card strip (5410). It is blocked by multiple oblique concave blocks opened on the top of the irregularly shaped card strip (5410), which reduces the rotation speed of the photovoltaic panel (53) when subjected to impact force. S3. When the square plate (543) is in the reset movement, the square plate (543) drives the round rod (544) and the connecting plate (546) to reset and move. The connecting plate (546) gradually moves towards the photovoltaic panel (53). The connecting plate (546) drives the strip box (551) and the flexible positioning block (552) to move. Due to the flexible deformation material of the flexible positioning block (552), the flexible positioning block (552) can gradually insert and squeeze multiple support shells (52) as it approaches the support shell (52), so that the photovoltaic panel (53) can rotate together with the connecting beam (4) when it does not encounter strong wind.