CN220732661U - Multi-surface solar photovoltaic panel with high conversion rate - Google Patents

Abstract

The utility model relates to the technical field of solar energy, in particular to a high-conversion-rate multi-surface solar photovoltaic panel, which comprises a fixed frame, wherein the inside of the fixed frame is symmetrically provided with placing grooves, the inside of each placing groove is fixedly provided with a rotating mechanism, each rotating mechanism comprises a first rotating part, each first rotating part is positioned above a threaded rod, each first sliding block is fixedly provided with a second rotating part on the side wall, each second sliding groove is internally provided with a second sliding block in a sliding manner, a supporting leg is communicated with the first sliding groove in the fixed frame, the second sliding blocks slide in the second sliding grooves, the photovoltaic panel assembly, a first connecting rod and the second connecting rod can be folded when the threaded rod is rotated anticlockwise, the occupied area is reduced, and the threaded rod is rotated to drive the rotating ring, so that the heights of the second sliding blocks and the first sliding blocks are controlled, the photovoltaic panel assembly rotates around the first rotating parts, and the angle adjustment is completed.

Description

Multi-surface solar photovoltaic panel with high conversion rate

Technical Field

The utility model relates to the technical field of solar energy, in particular to a high-conversion-rate multi-surface solar photovoltaic panel.

Background

Solar panels, also known as solar panels or solar modules, are devices capable of converting sunlight into electrical energy, which are the most central components in solar power generation systems, and are generally composed of a plurality of solar photovoltaic cells made of semiconductor materials, typically silicon. When sunlight irradiates the surface of the photovoltaic cell, photons excite electrons in the photovoltaic cell, generating an electric current.

Existing devices typically have only one sun-facing surface to receive sunlight when in use and are typically fixed in direction, which results in a photovoltaic panel with lower absorption and conversion efficiency as the direction and intensity of sunlight will vary with time, season and geographic location.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a high-conversion-rate multi-surface solar photovoltaic panel, which solves the technical problem that the absorption efficiency of the photovoltaic panel is lower because the existing device usually only absorbs sunlight and changes with time, but the angle of the photovoltaic panel assembly cannot be changed to adjust the photovoltaic panel.

(II) technical scheme

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

the utility model provides a multiaspect solar photovoltaic board of high conversion, includes the mount, mount lower tip symmetry fixed mounting has the supporting leg, every the supporting leg all has seted up first spout with the mount inside, first spout between mount and the supporting leg communicates with each other, the inside symmetry of mount has seted up the standing groove, every the standing groove all is located between the first spout, two the standing groove inner wall all has symmetrically seted up the second spout, two the standing groove is inside all to rotate and install the threaded rod;

a rotating mechanism is fixedly arranged in each of the two placing grooves;

the rotating mechanism comprises first rotating pieces, the two first rotating pieces are positioned above the threaded rod, and a first sliding block is slidably arranged in each first sliding groove;

and the side wall of each first sliding block is fixedly provided with a second rotating piece.

Preferably: a second sliding block is slidably arranged in each second sliding groove;

and each second sliding block is fixedly provided with a driving ring between every two sliding blocks, and the two driving rings are in threaded installation with the threaded rod.

Preferably: a third rotating piece is fixedly arranged on the side wall of each second sliding block;

wherein, two first rotation piece circumference surface all rotate and install photovoltaic board assembly.

Preferably: the lower end parts of the two photovoltaic panel assemblies are respectively fixedly provided with a first rotating column and a second rotating column;

the first connecting rods are symmetrically installed on the circumferential surfaces of the two first rotating columns in a rotating mode.

Preferably: each first connecting rod is rotatably installed with the third rotating piece;

and the second connecting rods are symmetrically and rotatably arranged on the circumferential surfaces of the two second rotating columns.

Preferably: each second connecting rod is rotatably installed with the second rotating piece;

wherein each first connecting rod is positioned between the second connecting rods.

(III) beneficial effects

1. Through setting up the photovoltaic board assembly in the mount both sides, can realize collecting a plurality of directions of sunshine to increase the light absorption area of photovoltaic board assembly and the received quantity of solar energy, simultaneously, come the angle of control photovoltaic board assembly respectively through adjusting the threaded rod, can carry out the regulation of a plurality of angles according to the sunlight, thereby improve photovoltaic board assembly and absorb conversion efficiency.

2. Through increase the second connecting rod in photovoltaic board assembly below for when using the threaded rod to adjust photovoltaic board assembly, can drive first slider simultaneously and slide in first spout, make provide extra support and spacing when the photovoltaic board assembly is carrying out angle change, thereby improve the stability when adjusting photovoltaic board assembly, and when passing through the threaded rod, can control the angle of both sides photovoltaic board assembly, thereby can carry out the folding of certain degree, reduce area.

Drawings

The foregoing description is only an overview of the present utility model, and is intended to provide a better understanding of the present utility model, as it is embodied in the following description, with reference to the preferred embodiments of the present utility model and the accompanying drawings.

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a perspective exploded view of the present utility model;

FIG. 3 is a schematic diagram of a connecting explosion of the placement tank of the present utility model;

fig. 4 is a schematic diagram of a connection explosion structure of the photovoltaic panel assembly of the present utility model.

Legend description: 11. a fixing frame; 12. support legs; 13. a first chute; 14. a placement groove; 15. a second chute; 16. a threaded rod; 17. a first rotating member; 18. a first slider; 19. a second rotating member; 21. a second slider; 22. a drive ring; 23. a third rotating member; 24. a photovoltaic panel assembly; 25. a first rotating column; 26. a second rotating column; 27. a first link; 28. and a second link.

Detailed Description

According to the multi-surface solar photovoltaic panel with high conversion rate, the technical problem that the absorption efficiency of the photovoltaic panel is low because the existing device is only one for absorbing sunlight and changing along with time and cannot change the angle of the photovoltaic panel assembly is solved, the photovoltaic panel assembly is arranged on two sides of the fixing frame, multiple directions of sunlight can be collected, the light absorption area of the photovoltaic panel assembly and the receiving amount of solar energy are increased, meanwhile, the angle of the photovoltaic panel assembly is controlled respectively through adjusting the threaded rod, multiple angles of adjustment can be carried out according to sunlight, the absorption conversion efficiency of the photovoltaic panel assembly is improved, the second connecting rod is arranged below the photovoltaic panel assembly, the first sliding block can be driven to slide in the first sliding groove at the same time when the threaded rod is used for adjusting the photovoltaic panel assembly, the additional support and the limit are provided when the angle of the photovoltaic panel assembly is changed, the stability of the photovoltaic panel assembly is improved, the side light absorption area of the photovoltaic panel assembly is controlled, the two photovoltaic panel assemblies can be reduced, and the occupied area of the photovoltaic panel assembly is reduced to a certain extent.

Examples

The technical scheme in this application embodiment is for effectively having solved current device and generally only has one to absorb and along with the change of time in the face of sunshine, and can not change the angle of photovoltaic board assembly and adjust the technical problem that leads to the lower absorption efficiency of photovoltaic board to the photovoltaic board, and the overall thinking is as follows:

aiming at the problems existing in the prior art, the utility model provides a high-conversion-rate multi-surface solar photovoltaic panel, which comprises a fixed frame 11, wherein supporting legs 12 are symmetrically and fixedly arranged at the lower end part of the fixed frame 11, each supporting leg 12 is communicated with a first sliding groove 13 formed in the fixed frame 11, each fixed frame 11 is communicated with the first sliding groove 13 formed between the supporting legs 12, each fixed frame 11 is internally and symmetrically provided with a placing groove 14, each placing groove 14 is positioned between the first sliding grooves 13, the inner walls of the two placing grooves 14 are symmetrically provided with second sliding grooves 15, and threaded rods 16 are rotatably arranged in the two placing grooves 14;

a rotating mechanism is fixedly arranged inside each of the two placing grooves 14;

the rotating mechanism comprises first rotating parts 17, two first rotating parts 17 are located above the threaded rods 16, first sliding blocks 18 are slidably mounted in each first sliding groove 13, second rotating parts 19 are fixedly mounted on the side walls of each first sliding block 18, second sliding blocks 21 are slidably mounted in each second sliding groove 15, driving rings 22 are fixedly mounted between every two second sliding blocks 21, the two driving rings 22 are in threaded mounting with the threaded rods 16, through the communication of supporting legs 12 and first sliding grooves 13 in the fixing frames 11 and the sliding of the second sliding blocks 21 in the second sliding grooves 15, the photovoltaic panel assembly 24, the first connecting rods 27 and the second connecting rods 28 can be folded when the threaded rods 16 are rotated anticlockwise, the occupied area is reduced, and through the rotation of the threaded rods 16, the driving rings 22 generate threaded transmission, the heights of the second sliding blocks 21 and the first sliding blocks 18 are controlled, the photovoltaic panel assembly 24 rotates around the first rotating parts 17, and therefore the angle adjustment is completed.

The side wall of each second sliding block 21 is fixedly provided with a third rotating piece 23, the circumferential surfaces of the two first rotating pieces 17 are rotatably provided with photovoltaic panel assemblies 24, the lower end parts of the two photovoltaic panel assemblies 24 are respectively fixedly provided with a first rotating column 25 and a second rotating column 26, the circumferential surfaces of the two first rotating columns 25 are symmetrically rotatably provided with first connecting rods 27, each first connecting rod 27 is rotatably provided with a third rotating piece 23, the circumferential surfaces of the two second rotating columns 26 are symmetrically rotatably provided with second connecting rods 28, each second connecting rod 28 is rotatably provided with a second rotating piece 19, each first connecting rod 27 is positioned between the second connecting rods 28, the first connecting rods 27 are arranged at the lower end parts of the photovoltaic panel assemblies 24, so that when the threaded rods 16 are rotated, the second sliding blocks 21 are driven to ascend to transmit the upward force to the photovoltaic panel assemblies 24 through the first connecting rods 27, and simultaneously the second connecting rods 28 are driven to ascend, and the first sliding blocks 18 are driven to slide in the first sliding grooves 13, so that when the photovoltaic panel assemblies 24 ascend, more support and more stability are provided.

Working principle:

in the first step, when the height of the photovoltaic panel assembly 24 (the photovoltaic panel assembly 24 is composed of a photovoltaic panel, a base and a connecting piece) needs to be adjusted, the threaded rod 16 can be rotated clockwise first, at this time, the threaded rod 16 and the transmission ring 22 will generate threaded transmission, and meanwhile, the second sliding block 21 is driven to slide upwards in the second sliding groove 15, and due to the sliding of the second sliding block 21, the second sliding block 21 will drive the third rotating piece 23 to rise, and due to the rising of the third rotating piece 23, at this time, the first connecting rod 27 installed under the photovoltaic panel assembly 24 through rotation with the first rotating post 25 will rotate anticlockwise on the first rotating post 25 and the third rotating piece 23.

In the second step, the second connecting rod 28 is driven to rotate counterclockwise on the second rotating post 26 and the second rotating member 19 respectively, so that the second slider 21 and the first slider 18 slide upward inside the second sliding slot 15 and the first sliding slot 13 respectively, and an upward thrust is generated on the photovoltaic panel assembly 24 through the first connecting rod 27 and the second connecting rod 28, and the photovoltaic panel assembly 24 and the first rotating member 17 are rotatably mounted, at this time, the photovoltaic panel assembly 24 rotates counterclockwise around the first rotating member 17 as a center of a circle, and after the position is adjusted to a proper position according to the angle of sunlight, the rotation of the threaded rod 16 can be stopped at this time.

Finally, it should be noted that: it is apparent that the above examples are only illustrative of the present utility model and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. And obvious variations or modifications thereof are contemplated as falling within the scope of the present utility model.

Claims (6)

1. The utility model provides a multiaspect solar photovoltaic board of high conversion, includes mount (11), the symmetrical fixed mounting of tip has supporting leg (12) under mount (11), its characterized in that, every supporting leg (12) all has seted up first spout (13) with the inside of mount (11), first spout (13) between mount (11) and supporting leg (12) communicate with each other, standing groove (14) have been seted up to the inside symmetry of mount (11), every standing groove (14) all are located between first spout (13), two second spout (15) have all been seted up to standing groove (14) inner wall symmetry, two threaded rod (16) have all been installed in the inside rotation of standing groove (14);

a rotating mechanism is fixedly arranged in each of the two placing grooves (14);

the rotating mechanism comprises first rotating pieces (17), the two first rotating pieces (17) are located above the threaded rods (16), and a first sliding block (18) is slidably arranged in each first sliding groove (13);

wherein, each first slider (18) lateral wall is all fixed mounting have second rotation piece (19).

2. A high conversion rate multi-faceted solar photovoltaic panel according to claim 1, characterized in that each of said second sliding grooves (15) has a second sliding block (21) slidingly mounted inside it;

and each second sliding block (21) is fixedly provided with a transmission ring (22) between every two, and the two transmission rings (22) are in threaded installation with the threaded rod (16).

3. A high conversion rate multi-faceted solar photovoltaic panel according to claim 2, characterized in that a third rotating member (23) is fixedly mounted on the side wall of each of said second sliders (21);

wherein, the photovoltaic panel assembly (24) is rotatably installed on the circumferential surfaces of the two first rotating members (17).

4. A high conversion rate multi-faceted solar photovoltaic panel according to claim 3, characterized in that the lower ends of the two photovoltaic panel assemblies (24) are each fixedly provided with a first rotating column (25) and a second rotating column (26);

wherein, the circumference surface of the two first rotating columns (25) is symmetrically and rotatably provided with a first connecting rod (27).

5. A high conversion rate multi-faceted solar photovoltaic panel according to claim 4, characterized in that each of said first links (27) is rotatably mounted with a third rotary member (23);

wherein, the circumference surface of the two second rotating columns (26) is symmetrically and rotatably provided with a second connecting rod (28).

6. A high conversion rate multi-faceted solar photovoltaic panel according to claim 5, characterized in that each of said second links (28) is rotatably mounted with a second rotating member (19);

wherein each of the first links (27) is located between the second links (28).