CN111384891A

CN111384891A - Solar panel support structure based on rotary centrifugal force

Info

Publication number: CN111384891A
Application number: CN202010206433.8A
Authority: CN
Inventors: 曾贵
Original assignee: Hangzhou Cuice Technology Co ltd
Current assignee: Xiamen Kesheng New Energy Co.,Ltd.
Priority date: 2020-03-23
Filing date: 2020-03-23
Publication date: 2020-07-07
Anticipated expiration: 2040-03-23
Also published as: CN111384891B

Abstract

The invention provides a solar panel support structure based on a rotating centrifugal force, and relates to the technical field of solar photovoltaic. This solar energy electroplax supporting structure based on rotatory centrifugal force, including the stand, the top fixed mounting of stand has the ball, the top parcel of ball has the stop collar, the top fixed mounting of stop collar has the carriage, the top fixed mounting of carriage has places the board, the left and right sides sliding connection who places the board has the slider, the slider is close to the first spring of one end fixedly connected with who places the board center. This solar energy electroplax supporting structure based on rotatory centrifugal force has reduced the solar energy electroplax and the installation and the working strength when changing, has improved the efficiency that the solar energy electroplax was erect, can adjust orientation and inclination of solar energy electroplax, and no matter meet with the wind-force of any direction, the homoenergetic makes the solar energy electroplax tend to the horizontality to the damage of wind-force to the solar energy electroplax has been reduced.

Description

Solar panel support structure based on rotary centrifugal force

Technical Field

The invention relates to the technical field of solar photovoltaics, in particular to a solar panel support structure based on a rotary centrifugal force.

Background

The solar photovoltaic power generation is based on the principle of the photovoltaic effect, solar energy is directly converted into electric energy by using a solar cell, and a photovoltaic power generation system mainly comprises a solar cell panel, a controller and an inverter no matter the photovoltaic power generation system is used independently or is connected with a grid for power generation, so that the solar cell panel is firstly erected in a specified area when the photovoltaic power generation system is required to utilize solar energy for power generation.

And traditional solar cell panel's support all utilizes steel pipe and various fastener cooperation bolt combination to form, then fix solar cell panel on the support again, therefore no matter be the installation, still when changing solar cell panel, all need cooperate the fastener elasticity bolt repeatedly, high working strength, low efficiency, and in order to improve the efficiency of electricity generation, solar cell panel's area can be very big, and the slope is placed, consequently, suffer the damage of wind-force more easily, and some present prevent wind the support and can only lie flat when solar cell panel openly suffers the wind-blowing, reduce the damage of wind-force, nevertheless can't reduce the damage that the solar cell panel back suffered the wind-blowing.

In order to solve the above problems, the inventor provides a solar panel support structure based on a rotational centrifugal force, which reduces the working strength of a solar panel and installation and replacement of the solar panel, improves the efficiency of erecting the solar panel, can adjust the orientation and inclination angle of the solar panel, and can make the solar panel tend to be horizontal no matter the solar panel is subjected to wind in any direction, thereby reducing the damage of the wind to the solar panel.

Disclosure of Invention

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a solar energy electroplax supporting structure based on rotatory centrifugal force, includes stand, ball, stop collar, carriage, places board, slider, first spring, bending pole, cylinder, lifter, stop device, accepts board, slide bar, connection rope, chute board, rotary drum, first telescopic link, cylinder frame, rotation axis, flabellum, second telescopic link, connecting rod, counter weight ball, second spring, solar energy electroplax.

Wherein:

the top end of the upright post is fixedly provided with a round ball, the top of the round ball is wrapped with a limit sleeve, the top end of the limit sleeve is fixedly provided with a support frame, the top end of the support frame is fixedly provided with a placing plate, the left side and the right side of the placing plate are connected with a slide block in a sliding manner, one end of the slide block close to the center of the placing plate is fixedly connected with a first spring, the top end of the slide block is fixedly provided with a bending rod, one end of the bending rod close to the center of the placing plate is rotatably connected with a roller, the center of the placing plate is slidably connected with a lifting rod, a limiting device is arranged between the lifting rod and the placing plate, the top end of the lifting rod is rotatably connected with a bearing plate, the inner part of the bearing plate is connected with a slide rod in a limiting and sliding manner, a connecting rope is fixedly connected, the solar photovoltaic panel placing device is characterized in that a first telescopic rod is fixedly mounted at the right end of the rotary drum, a cylindrical frame is fixedly mounted at the left end of the rotary drum, a rotary shaft is rotatably connected to the bottom of the cylindrical frame, fan blades are fixedly mounted at the bottom of the rotary shaft, a second telescopic rod is slidably connected to the top of the cylindrical frame, a connecting rod is rotatably connected to the second telescopic rod and the periphery of the rotary shaft, a counterweight ball is fixedly connected to the periphery of the connecting rod, a second spring is fixedly connected between the second telescopic rod and the rotary shaft, and a solar photovoltaic panel is placed at the top of the placing plate.

Preferably, the stop collar is fixedly installed at the bottom end of the center of the support frame, and the diameter of the bottom end opening of the stop collar is larger than that of the stand column and smaller than that of the ball, so that the support frame can rotate and incline at any angle.

Preferably, the top of the bending rod is bent perpendicularly towards the center of the placing plate, a gap is reserved between the bent bottom end and the top end of the placing plate, and the bending rod is matched with the thickness of the solar panel, so that the solar panel is attached to the top of the placing plate, and the bending rod can wrap the one end of the solar panel to be limited.

Preferably, the number of the bearing plates is two, the bearing plates are symmetrically and rotatably connected to the left side and the right side of the top end of the lifting rod, and when the lifting rod descends, the bearing plates on the two sides can rotate towards the middle under the action of the solar panel.

Preferably, the top of the first telescopic link of left and right sides and the equal spacing sliding connection in the inside of chute board in second telescopic link, consequently, can adjust the inclination of placing the board through adjusting the length of first telescopic link and second telescopic link.

Preferably, the rotation axis passes through the bottom of bearing spacing rotation connection at the cylinder frame, the spacing sliding connection of second telescopic link is at the top of cylinder frame for the rotation axis can rotate steadily, can not reciprocate, makes the second telescopic link can not rotate, only can slide from top to bottom.

Preferably, the connecting rod is formed by connecting two bull sticks, bottom and rotation axis fixed mounting, and the top is rotated with the bottom of second telescopic link and is connected for the rotation axis can drive the connecting rod and rotate, and the connecting rod can not drive the second telescopic link at the pivoted in-process and rotate.

The invention provides a solar panel support structure based on a rotary centrifugal force. The method has the following beneficial effects:

1. this solar energy electroplax supporting structure based on rotatory centrifugal force, through the design of placing board top left and right sides bending pole and central lifter top bearing plate, place the solar energy electroplax symmetry behind the bending pole and the bearing plate, just can realize the installation to the solar energy electroplax through pressing down the solar energy electroplax, and upwards promote the lifter and just can make the solar energy electroplax upwards overturn, and remove spacing to the solar energy electroplax, greatly reduced the solar energy electroplax and the working strength when installing and changing, the efficiency that the solar energy electroplax erect has been improved.

2. This solar energy electroplax supporting structure based on rotatory centrifugal force, design through the first telescopic link of the rotary drum left and right sides and second telescopic link, and the design of the inside connecting rod of second telescopic link bottom cylinder frame, when can adjusting orientation and inclination to solar energy electroplax, no matter meet with the wind-force of any direction, the homoenergetic makes the flabellum rotate, and then drive the second telescopic link and move down, it moves down to make the higher one side of placing the board, make and place board and solar energy electroplax and tend to the horizontality, thereby the damage of wind-force to solar energy electroplax has been reduced.

Drawings

FIG. 1 is a cross-sectional view of a structure of the present invention;

FIG. 2 is a cross-sectional view of a placement plate structure of the present invention;

FIG. 3 is a cross-sectional view of the mounting plate structure of the present invention;

FIG. 4 is a cross-sectional view of a bearing plate structure according to the present invention;

fig. 5 is a cross-sectional view of a cylindrical frame structure of the present invention.

In the figure: 1. a column; 2. a ball; 3. a limiting sleeve; 4. a support frame; 5. placing the plate; 6. a slider; 7. a first spring; 8. bending the rod; 9. a drum; 10. a lifting rod; 11. a limiting device; 12. a bearing plate; 13. a slide bar; 14. connecting ropes; 15. a chute plate; 16. a rotating drum; 17. a first telescopic rod; 18. a cylindrical frame; 19. a rotating shaft; 20. a fan blade; 21. a second telescopic rod; 22. a connecting rod; 23. a counterweight ball; 24. a second spring; 25. solar panel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

An embodiment of the solar panel support structure based on rotational centrifugal force is as follows:

referring to fig. 1 to 5, a solar panel support structure based on rotational centrifugal force includes an upright post 1, a ball 2, a limiting sleeve 3, a supporting frame 4, a placing plate 5, a sliding block 6, a first spring 7, a bending rod 8, a roller 9, a lifting rod 10, a limiting device 11, a receiving plate 12, a sliding rod 13, a connecting rope 14, a sliding chute plate 15, a rotating drum 16, a first telescopic rod 17, a cylindrical frame 18, a rotating shaft 19, a fan blade 20, a second telescopic rod 21, a connecting rod 22, a counterweight ball 23, a second spring 24, and a solar panel 25.

Wherein:

the top end of the upright post 1 is fixedly provided with a ball 2, the top of the ball 2 is wrapped with a limit sleeve 3, the limit sleeve 3 is fixedly arranged at the bottom end of the center of the support frame 4, the diameter of the opening at the bottom end of the limit sleeve 3 is larger than that of the upright post 1 and smaller than that of the ball 2, so that the support frame 4 can rotate and incline at any angle, the top end of the limit sleeve 3 is fixedly provided with the support frame 4, the top end of the support frame 4 is fixedly provided with a placing plate 5, the left side and the right side of the placing plate 5 are slidably connected with sliders 6, one end of each slider 6 close to the center of the placing plate 5 is fixedly connected with a first spring 7, the top end of each slider 6 is fixedly provided with a bending rod 8, the top of each bending rod 8 is vertically bent towards the center of the placing plate 5, a gap is reserved between the bent bottom end and the top end of the placing plate 5 and is matched with the thickness of, the bending rod 8 can pack and limit one end of a solar panel 25, one end of the bending rod 8, which is close to the center of a placing plate 5, is rotatably connected with a roller 9, the center of the placing plate 5 is slidably connected with a lifting rod 10, a limiting device 11 is arranged between the lifting rod 10 and the placing plate 5, the top end of the lifting rod 10 is rotatably connected with a bearing plate 12, the number of the bearing plates 12 is two, the two bearing plates are symmetrically and rotatably connected with the left side and the right side of the top end of the lifting rod 10, when the lifting rod 10 descends, the bearing plates 12 on the two sides can rotate towards the middle under the action of the solar panel 25, the inner part of the bearing plate 12 is in limited sliding connection with a sliding rod 13, a connecting rope 14 is fixedly connected between the sliding rods 13, the left side and the right side of the bottom end of the placing plate 5 are fixedly provided with a sliding chute plate 15, and the design, place the solar energy electroplax 25 symmetry behind bending rod 8 and accept board 12, just can realize the installation to solar energy electroplax 25 through pressing down solar energy electroplax 25, and upwards promote lifter 10 and just can make solar energy electroplax 25 upwards overturn to remove spacing to solar energy electroplax 25, greatly reduced solar energy electroplax 25 and installation and working strength when changing, improved the efficiency that solar energy electroplax 25 erect.

The periphery of the upright post 1 is rotatably connected with a rotary drum 16, the right end of the rotary drum 16 is fixedly provided with a first telescopic rod 17, the top ends of the first telescopic rod 17 and the second telescopic rod 21 at the left side and the right side are both in limited sliding connection with the inside of the chute plate 15, therefore, the inclined angle of the placing plate 5 can be adjusted by adjusting the lengths of the first telescopic rod 17 and the second telescopic rod 21, the left end of the rotary drum 16 is fixedly provided with a cylindrical frame 18, the bottom of the cylindrical frame 18 is rotatably connected with a rotating shaft 19, the rotating shaft 19 is rotatably connected with the bottom of the cylindrical frame 18 through a bearing in a limited sliding manner, the top of the cylindrical frame 18 is connected with a second telescopic rod 21 in a limited sliding manner, the rotating shaft 19 can stably rotate and cannot move up and down, the second telescopic rod 21 cannot rotate and can only slide up and down, the bottom end of the rotating shaft 19 is fixedly provided, the second expansion link 21 is rotatably connected with a connecting rod 22 with the periphery of the rotating shaft 19, the connecting rod 22 is formed by connecting two rotating rods, the bottom end of the connecting rod 22 is fixedly installed with the rotating shaft 19, the top end of the connecting rod 22 is rotatably connected with the bottom end of the second expansion link 21, so that the rotating shaft 19 can drive the connecting rod 22 to rotate, the connecting rod 22 cannot drive the second expansion link 21 to rotate in the rotating process, the periphery of the connecting rod 22 is fixedly connected with a counterweight ball 23, a second spring 24 is fixedly connected between the second expansion link 21 and the rotating shaft 19, a solar panel 25 is placed on the top of the placing panel 5, the fan blades 20 can be rotated by the design of the first expansion link 17 and the second expansion link 21 on the left side and the right side of the rotating drum 16 and the design of the connecting rod 22 inside the cylindrical frame 18 at the bottom of the second expansion link 21, the orientation and the inclination angle of, and then the second telescopic rod 21 is driven to move downwards to move the higher side of the placing plate 5 downwards, so that the placing plate 5 and the solar panel 25 tend to be in a horizontal state, and the damage of wind power to the solar panel 25 is reduced.

When in use, the upright post 1 is fixedly arranged in a designated area by using a cement column, then the lifting rod 10 is inserted into the center of the placing plate 5, the solar panel 25 is taken out, the bottom end of the solar panel 25 is clamped under the roller 9 of the bending rod 8, then the height of the lifting rod 10 is adjusted, the other end of the solar panel 25 falls on the bearing plate 12, then a solar panel 25 is symmetrically placed between the bending rod 8 and the bearing plate 12 on the other side, then the solar panel 25 is pressed downwards at the same time, the lifting rod 10 moves downwards, meanwhile, the solar panel 25 also pushes the bending rod 8 to stretch the first spring 7 to move towards two sides, the bearing plate 12 on the top end of the lifting rod 10 also rotates towards the middle, so that the sliding rod 13 on the adjacent side of the bearing plate 12 is contacted with the sliding rod 13 on the adjacent side of the bearing plate 25, and when the solar panel 25 is pressed to be attached to the placing plate 5, the bending rod 8 can contract towards one side close to the solar electric plate 25 under the action of the restoring force of the first spring 7, one end of the solar electric plate 25 is wrapped and fixed, meanwhile, the sliding rod 13 also extends to the top of the other end of the solar electric plate 25 to limit and fix the other end of the solar electric plate 25, and then the lifting rod 10 is limited, so that the solar electric plate 25 is stably placed, when the solar electric plate 25 needs to be replaced, the lifting rod 10 is only required to be pushed upwards, the solar electric plate 25 can be upwards overturned, the limitation on the solar electric plate 25 is removed, the rotation of the rotary drum 16 is utilized, the orientation and the inclination angle of the solar electric plate 25 can be adjusted through the adjustment of the first telescopic rod 17 and the second telescopic rod 21 on the left side and the right side of the rotary drum 16, and when strong wind blows, the wind power can drive the fan blades 20 to rotate, and then drive rotation axis 19 and connecting rod 22 and rotate, at the rotatory in-process of connecting rod 22, utilize the effect of the peripheral counter weight ball 23 centrifugal force of connecting rod 22, can make connecting rod 22 fold and contract, thereby it moves down to drive second telescopic link 21 compression second spring 24, and then reduced and placed the higher one side of board 5, make and place board 5 and tend to the horizontality, and then reduced wind-force to the effect of placing board 5 and solar energy electroplax 25, the damage of wind-force to solar energy electroplax 25 has been reduced, and resume initial inclination after wind-force reduces.

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

Claims

1. The utility model provides a solar energy electroplax supporting structure based on rotatory centrifugal force, includes stand (1), its characterized in that: the top end of the upright post (1) is fixedly provided with a ball (2), the top of the ball (2) is wrapped with a limiting sleeve (3), the top end of the limiting sleeve (3) is fixedly provided with a supporting frame (4), the top end of the supporting frame (4) is fixedly provided with a placing plate (5), the left side and the right side of the placing plate (5) are slidably connected with a sliding block (6), one end of the sliding block (6) close to the center of the placing plate (5) is fixedly connected with a first spring (7), the top end of the sliding block (6) is fixedly provided with a bending rod (8), one end of the bending rod (8) close to the center of the placing plate (5) is rotatably connected with a roller (9), the center of the placing plate (5) is slidably connected with a lifting rod (10), a limiting device (11) is arranged between the lifting rod (10) and the placing plate (5), and the top end of the lifting rod (10) is rotatably, the bearing plate (12) is internally and slidably connected with a sliding rod (13) in a limiting manner, a connecting rope (14) is fixedly connected between the sliding rods (13), sliding groove plates (15) are fixedly installed on the left side and the right side of the bottom end of the placing plate (5), a rotary drum (16) is rotatably connected with the periphery of the upright post (1), a first telescopic rod (17) is fixedly installed at the right end of the rotary drum (16), a cylindrical frame (18) is fixedly installed at the left end of the rotary drum (16), a rotary shaft (19) is rotatably connected with the bottom of the cylindrical frame (18), fan blades (20) are fixedly installed at the bottom end of the rotary shaft (19), a second telescopic rod (21) is slidably connected with the top of the cylindrical frame (18), a connecting rod (22) is rotatably connected with the periphery of the rotary shaft (19) through the second telescopic rod (21), and a counterweight ball (23) is, a second spring (24) is fixedly connected between the second telescopic rod (21) and the rotating shaft (19), and a solar panel (25) is placed on the top of the placing plate (5).

2. A solar-electric panel support structure based on rotational centrifugal force according to claim 1, wherein: stop collar (3) fixed mounting is in the bottom at carriage (4) center, just stop collar (3) bottom open-ended diameter is greater than the diameter of stand (1), is less than the diameter of ball (2).

3. A solar-electric panel support structure based on rotational centrifugal force according to claim 1, wherein: the top of the bending rod (8) is vertically bent towards the center of the placing plate (5), a gap is reserved between the bent bottom end and the top end of the placing plate (5), and the thickness of the bending rod is matched with that of the solar panel (25).

4. A solar-electric panel support structure based on rotational centrifugal force according to claim 1, wherein: the number of the bearing plates (12) is two, and the bearing plates are symmetrically and rotatably connected to the left side and the right side of the top end of the lifting rod (10).

5. A solar-electric panel support structure based on rotational centrifugal force according to claim 1, wherein: the top ends of the first telescopic rod (17) and the second telescopic rod (21) on the left side and the right side are both in limited sliding connection inside the chute plate (15).

6. A solar-electric panel support structure based on rotational centrifugal force according to claim 1, wherein: the rotating shaft (19) is connected to the bottom of the cylindrical frame (18) in a limiting and rotating mode through a bearing, and the second telescopic rod (21) is connected to the top of the cylindrical frame (18) in a limiting and sliding mode.

7. A solar-electric panel support structure based on rotational centrifugal force according to claim 1, wherein: the connecting rod (22) is formed by connecting two rotating rods, the bottom end of the connecting rod is fixedly installed with the rotating shaft (19), and the top end of the connecting rod is rotatably connected with the bottom end of the second telescopic rod (21).