CN211089574U

CN211089574U - Mounting structure for solar photovoltaic panel for photovoltaic energy storage

Info

Publication number: CN211089574U
Application number: CN202020041553.2U
Authority: CN
Inventors: 刘赫; 赵红东; 董晨名; 孙毅; 郝群鹤
Original assignee: Tianjin Jinwo Energy Technology Co Ltd
Current assignee: Tianjin Jinwo Energy Technology Co Ltd
Priority date: 2020-01-09
Filing date: 2020-01-09
Publication date: 2020-07-24
Anticipated expiration: 2030-01-09

Abstract

The utility model discloses a mounting structure for solar photovoltaic board for photovoltaic energy storage, including support, installing frame main part and sleeve, the installing frame main part is installed at the top of support, the one end that the installing frame main part was kept away from in spacing storehouse is fixed with spacing frame, the inside top in spacing storehouse is fixed with the second spring, set up flutedly in the installing frame main part of through-hole below, the avris of installing frame main part is fixed with the device storehouse, the outside of first pivot is fixed with first gear, the second pivot is installed to the avris bearing in device storehouse, telescopic inside is provided with the fourth spring, the telescopic outside is fixed with the second gear. This solar photovoltaic mounting structure for board for photovoltaic energy storage, it is very convenient when the installation is dismantled, and the installation is accomplished the back, has certain buffering space between photovoltaic board and the support for when receiving unexpected striking, the photovoltaic board is difficult for receiving the damage.

Description

Mounting structure for solar photovoltaic panel for photovoltaic energy storage

Technical Field

The utility model relates to a photovoltaic energy storage technical field specifically is a mounting structure for solar photovoltaic board for photovoltaic energy storage.

Background

Along with the constantly reinforcing of people's environmental protection consciousness and the constantly developing of science and technology, more and more enterprises or mechanism begin to pay close attention to and impel the collection and the utilization to renewable resources, photovoltaic energy storage is exactly one of them comparatively common mode, what photovoltaic energy storage mainly utilized when collecting is the solar photovoltaic board, need install the solar photovoltaic board on the support when using, however current for the photovoltaic energy storage mounting structure for the solar photovoltaic board there is following problem:

1. The existing solar photovoltaic panel for photovoltaic energy storage is usually directly adhered by glue or screwed by a screw, so that time is consumed during installation, and the solar photovoltaic panel is very troublesome to disassemble, maintain or clean;

2. The existing solar photovoltaic panel for photovoltaic energy storage is often directly and completely fixed with a support after being installed, so that the photovoltaic panel does not have a certain buffer space when being accidentally impacted, impact force and reaction force of the support are completely applied to an installation position, and the photovoltaic panel is easily damaged.

In order to solve the problems, innovative design is urgently needed on the basis of the existing mounting structure for the solar photovoltaic panel for photovoltaic energy storage.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a mounting structure for solar photovoltaic board for photovoltaic energy storage to solve above-mentioned background art and provide some mounting structure for solar photovoltaic board for photovoltaic energy storage, comparatively troublesome when dismantling the installation, be unfavorable for the maintenance of photovoltaic board or wash etc. and do not have certain buffering space between photovoltaic board and the support, the photovoltaic board is receiving unexpected striking, the problem of very easy damage.

In order to achieve the above object, the utility model provides a following technical scheme: a mounting structure for a solar photovoltaic panel for photovoltaic energy storage comprises a support, a mounting frame main body and a sleeve, wherein the mounting frame main body is mounted at the top of the support, a through hole is formed in the inner side of the mounting frame main body, a limiting bin is mounted inside the through hole, a limiting frame is fixed at one end, away from the mounting frame main body, of the limiting bin, a first spring is mounted at the side of the limiting frame, one end, away from the limiting frame, of the first spring is connected with the mounting frame main body, a second spring is fixed at the top inside the limiting bin, a first fixing block is connected at one end, away from the limiting bin, of the second spring and penetrates through the limiting bin, a groove is formed in the mounting frame main body below the through hole, a third spring is fixed at the bottom inside the groove, a second fixing block is connected at one end, away from the mounting frame main body, of the third spring, the side of the mounting frame main body is fixed, and the inside bearing in device storehouse installs first pivot, the outside of first pivot is fixed with first gear, and is provided with the rack in the support of first gear avris to the rack runs through the device storehouse, the avris bearing in device storehouse installs the second pivot, and the second pivot runs through the device storehouse to install the sleeve in the outside that device storehouse one end was kept away from in the second pivot, telescopic inside is provided with the fourth spring, and the fourth spring keeps away from telescopic one end and is connected with the second pivot, telescopic outside is fixed with the second gear, and installs the third gear on the device storehouse of second gear below.

Preferably, the first fixed block is trapezoidal in side cross-sectional shape, and the first fixed block and the limiting bin form a relative sliding structure.

Preferably, the horizontal central axis of the second fixed block is parallel to the horizontal central axis of the limiting bin, and the second fixed block and the groove form a relative sliding structure.

Preferably, the rack is connected with the first gear in a meshed mode, a relative sliding structure is formed by the rack and the device bin, and one end, far away from the device bin, of the rack is arranged in a bevel edge mode.

Preferably, the second rotating shaft and the sleeve form a relative sliding structure, and the second rotating shaft is connected with the first rotating shaft through a belt pulley mechanism.

Preferably, the third gear is fixedly connected with the device bin, and the third gear is in meshed connection with the second gear.

Compared with the prior art, the beneficial effects of the utility model are that: the mounting structure for the solar photovoltaic panel for photovoltaic energy storage is very convenient to mount and dismount, and after mounting is completed, a certain buffer space exists between the photovoltaic panel and the support, so that the photovoltaic panel is not easily damaged when the photovoltaic panel is accidentally impacted;

1. Through the sliding connection between the limiting bin and the through hole, the sliding connection between the first fixing block and the limiting bin and the bevel edges of the limiting bin and the first fixing block, when the photovoltaic panel is installed, the photovoltaic panel can be directly placed on the inner side of the installing frame body and pressed, the installation of the photovoltaic panel can be completed, and through the matching of the bevel edge on the rack and the limiting frame and the transmission connection between the sleeve and the rack, the fixing of the photovoltaic panel can be released by pulling the sleeve and rotating, so that the photovoltaic panel installation frame is very convenient;

2. Through the sliding connection between first fixed block and the spacing storehouse, the sliding connection between second fixed block and the recess to and the elastic action of second spring and third spring, when can making the support receive accidental collision, the vibrations that the photovoltaic board received reduce, and when the photovoltaic board itself received the collision, certain buffer space had, avoided the photovoltaic board because vibrations or collision just take place to damage very easily.

Drawings

FIG. 1 is a schematic sectional view of the front view of the present invention;

FIG. 2 is a schematic top sectional view of the present invention;

Fig. 3 is a schematic front sectional view of the mounting frame main body of the present invention;

FIG. 4 is a schematic side sectional view of the limiting bin of the present invention;

FIG. 5 is a schematic side view of the device chamber of the present invention;

Fig. 6 is a schematic side view of the device chamber of the present invention.

In the figure: 1. a support; 2. installing a frame main body; 3. a through hole; 4. a limiting bin; 5. a limiting frame; 6. a first spring; 7. a second spring; 8. a first fixed block; 9. a groove; 10. a third spring; 11. a second fixed block; 12. a device bin; 13. a first rotating shaft; 14. a first gear; 15. a rack; 16. a second rotating shaft; 17. a sleeve; 18. a fourth spring; 19. a second gear; 20. a third gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: a mounting structure for a solar photovoltaic panel for photovoltaic energy storage comprises a support 1, a mounting frame main body 2, a through hole 3, a limiting bin 4, a limiting frame 5, a first spring 6, a second spring 7, a first fixing block 8, a groove 9, a third spring 10, a second fixing block 11, a device bin 12, a first rotating shaft 13, a first gear 14, a rack 15, a second rotating shaft 16, a sleeve 17, a fourth spring 18, a second gear 19 and a third gear 20, wherein the mounting frame main body 2 is mounted at the top of the support 1, the through hole 3 is formed in the inner side of the mounting frame main body 2, the limiting bin 4 is mounted in the through hole 3, the limiting frame 5 is fixed at one end of the limiting bin 4, which is far away from the mounting frame main body 2, the first spring 6 is mounted on the side of the limiting frame 5, one end of the first spring 6, which is far away from the limiting frame 5, is connected with the mounting frame main body 2, the second spring 7 is fixed at the top of, a first fixing block 8 is connected to one end of the second spring 7 far away from the limiting bin 4, the first fixing block 8 penetrates through the limiting bin 4, a groove 9 is formed in the mounting frame body 2 below the through hole 3, a third spring 10 is fixed to the bottom inside the groove 9, a second fixing block 11 is connected to one end of the third spring 10 far away from the mounting frame body 2, a device bin 12 is fixed to the side of the mounting frame body 2, a first rotating shaft 13 is mounted on an inner bearing of the device bin 12, a first gear 14 is fixed to the outer side of the first rotating shaft 13, a rack 15 is arranged in a support 1 on the side of the first gear 14, the rack 15 penetrates through the device bin 12, a second rotating shaft 16 is mounted on a side bearing of the device bin 12, the second rotating shaft 16 penetrates through the device bin 12, a sleeve 17 is mounted on the outer side of the second rotating shaft 16 far away from one end of the device bin 12, a fourth spring 18 is arranged inside the, and one end of the fourth spring 18 far away from the sleeve 17 is connected with the second rotating shaft 16, a second gear 19 is fixed on the outer side of the sleeve 17, and a third gear 20 is installed on the device bin 12 below the second gear 19.

The side section of the first fixing block 8 is trapezoidal, the first fixing block 8 and the limiting bin 4 form a relative sliding structure, the transverse central axis of the second fixing block 11 is parallel to the transverse central axis of the limiting bin 4, and the second fixing block 11 and the groove 9 form a relative sliding structure, so that when the limiting bin 4 slides, the first fixing block 8 can slide towards the inside of the limiting bin 4 without blocking the sliding of the limiting bin 4, and after the photovoltaic panel is pressed below the limiting bin 4, the first fixing block 8 and the second fixing block 11 can be matched with each other to clamp and fix the photovoltaic panel;

The rack 15 is connected with the first gear 14 in a meshed mode, the rack 15 and the device bin 12 form a relative sliding structure, one end, far away from the device bin 12, of the rack 15 is arranged in a bevel edge mode, the second rotating shaft 16 and the sleeve 17 form the relative sliding structure, the second rotating shaft 16 and the first rotating shaft 13 are connected through a belt pulley mechanism, the third gear 20 and the device bin 12 are fixedly connected, the third gear 20 and the second gear 19 are connected in a meshed mode, an operator can pull the sleeve 17 to remove the meshed third gear 20 and the second gear 19 and then rotate the sleeve 17 to drive the second rotating shaft 16 to rotate, further the first rotating shaft 13 and the first gear 14 rotate, further the rack 15 slides in the direction far away from the device bin 12, the limiting bin 4 is driven to slide in the direction far away from the mounting frame body 2, and fixing of the photovoltaic panel is removed.

The working principle is as follows: when the mounting structure for the solar photovoltaic panel for photovoltaic energy storage is used, as shown in fig. 1 and 2, the photovoltaic panel is aligned to the inner side of the mounting frame main body 2 and is placed on the limiting bin 4, as shown in fig. 3 and 4, the four corners of the photovoltaic panel are pressed downwards, the inclined edge of the limiting bin 4 is contacted with the bottom of the photovoltaic panel, the limiting bin 4 is in sliding connection with the through hole 3, and the elasticity of the first spring 6 enables the limiting bin 4 to be driven to slide towards the direction far away from the mounting frame main body 2 when the photovoltaic panel is pressed downwards manually, meanwhile, the inclined edge of the first fixing block 8 is contacted with the edge of the through hole 3, the sliding connection between the first fixing block 8 and the limiting bin 4 is achieved, and the elasticity of the second spring 7 enables the first fixing block 8 to slide towards the inner part of the limiting bin 4 towards the direction far away from the mounting frame main body 2 without blocking the sliding of the limiting bin 4, so that the photovoltaic panel can be pressed onto the second fixed block 11, and at the same time, the photovoltaic panel is continuously pressed, through the sliding connection between the second fixed block 11 and the groove 9 and the elasticity of the third spring 10, the photovoltaic panel can be continuously pressed downwards until the third spring 10 is compressed to a certain extent, at the moment, the side edge of the photovoltaic panel is not contacted with the limiting bin 4, under the elastic action of the first spring 6, the limiting bin 4 slides to the initial state, meanwhile, under the elastic action of the third spring 10, the first fixed block 8 restores to the initial state, the photovoltaic panel is loosened, under the elastic action of the third spring 10, the photovoltaic panel is driven to move upwards, in the moving process, the top of the photovoltaic panel is contacted with the first fixed block 8, the photovoltaic panel continuously moves upwards, until the elasticity of the third spring 10 and the second spring 7 reaches a balance point, and the photovoltaic panel is fixedly clamped between the first fixed block 8 and the second fixed block 11, can accomplish the installation, when support 1 receives accidental collision, because the photovoltaic board is fixed between first fixed block 8 and second fixed block 11, the deformation that makes support 1's vibrations pass through second spring 7 and third spring 10 when transmitting on second spring 7 and third spring 10 is reduced, thereby the vibrations that make the photovoltaic board receive are reduced, when the photovoltaic board itself receives the collision, the photovoltaic board can drive second spring 7 or third spring 10 and compress under the effect of pressure, thereby obtain certain buffer space, and then can make the photovoltaic be difficult for consequently receiving the damage and damaging

As shown in fig. 1 and fig. 6, when the photovoltaic panel needs to be disassembled, the sleeve 17 is pulled, the sleeve 17 can slide in a direction away from the device bin 12 through the sliding connection between the sleeve 17 and the second rotating shaft 16 and the elasticity of the fourth spring 18, so that the second gear 19 is disengaged from the third gear 20, the rotation limitation of the second rotating shaft 16 is released, the sleeve 17 and the second rotating shaft 16 are rotated counterclockwise, the first rotating shaft 13 and the first gear 14 thereon can be driven to rotate counterclockwise through the connection of the pulley mechanism between the second rotating shaft 16 and the first rotating shaft 13, as shown in fig. 2 and fig. 5, through the engagement connection between the rack 15 and the first gear 14 and the sliding connection between the rack 15 and the device bin 12, so that at this time, the two sets of racks 15 respectively slide in a direction away from the device bin 12, through the mutual cooperation of the hypotenuse of the first spring 6 and the limiting frame 5, when the rack 15 slides in the direction away from the device bin 12, the limiting frame 5 and the limiting bin 4 can be driven to slide in the direction away from the mounting frame main body 2 by extrusion until the limiting bin 4 completely slides out from the top of the photovoltaic panel, the limitation of the photovoltaic panel is removed, at the moment, along the elastic direction of the fourth spring 18, the sleeve 17 slides to the position where the second gear 19 and the third gear 20 are re-meshed under the condition that the second rotating shaft 16 does not rotate, the rotation of the second rotating shaft 16 is limited, the position of the rack 15 is fixed, the position of the limiting bin 4 is fixed, and an operator can conveniently take out the photovoltaic panel from the mounting frame main body 2.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a solar photovoltaic is mounting structure for board for photovoltaic energy storage, includes support (1), installing frame main part (2) and sleeve (17), its characterized in that: the mounting frame is characterized in that a mounting frame main body (2) is installed at the top of the support (1), a through hole (3) is formed in the inner side of the mounting frame main body (2), a limiting bin (4) is installed inside the through hole (3), a limiting frame (5) is fixed at one end, away from the mounting frame main body (2), of the limiting bin (4), a first spring (6) is installed on the side of the limiting frame (5), one end, away from the limiting frame (5), of the first spring (6) is connected with the mounting frame main body (2), a second spring (7) is fixed at the top inside of the limiting bin (4), one end, away from the limiting bin (4), of the second spring (7) is connected with a first fixing block (8), the first fixing block (8) penetrates through the limiting bin (4), a groove (9) is formed in the mounting frame main body (2) below the through hole (3), and a third spring (10) is fixed at the bottom inside of the groove (9), and one end of the third spring (10) far away from the mounting frame main body (2) is connected with a second fixed block (11), the side of the mounting frame main body (2) is fixed with a device bin (12), the internal bearing of the device bin (12) is provided with a first rotating shaft (13), the outer side of the first rotating shaft (13) is fixed with a first gear (14), a rack (15) is arranged in a bracket (1) at the side of the first gear (14), the rack (15) penetrates through the device bin (12), the side bearing of the device bin (12) is provided with a second rotating shaft (16), the second rotating shaft (16) penetrates through the device bin (12), the outer side of one end of the second rotating shaft (16) far away from the device bin (12) is provided with a sleeve (17), the inside of the sleeve (17) is provided with a fourth spring (18), and one end of the fourth spring (18) far away from the sleeve (17) is connected with the second rotating shaft (16), a second gear (19) is fixed on the outer side of the sleeve (17), and a third gear (20) is installed on the device bin (12) below the second gear (19).

2. The mounting structure for a solar photovoltaic panel for photovoltaic energy storage according to claim 1, characterized in that: the side cross-sectional shape of first fixed block (8) is trapezoidal, and first fixed block (8) and spacing storehouse (4) constitution relative sliding structure.

3. The mounting structure for a solar photovoltaic panel for photovoltaic energy storage according to claim 1, characterized in that: the transverse central axis of the second fixing block (11) is parallel to the transverse central axis of the limiting bin (4), and the second fixing block (11) and the groove (9) form a relative sliding structure.

4. The mounting structure for a solar photovoltaic panel for photovoltaic energy storage according to claim 1, characterized in that: the rack (15) is connected with the first gear (14) in a meshed mode, the rack (15) and the device bin (12) form a relative sliding structure, and one end, far away from the device bin (12), of the rack (15) is arranged in a bevel edge mode.

5. The mounting structure for a solar photovoltaic panel for photovoltaic energy storage according to claim 1, characterized in that: the second rotating shaft (16) and the sleeve (17) form a relative sliding structure, and the second rotating shaft (16) is connected with the first rotating shaft (13) through a belt pulley mechanism.

6. The mounting structure for a solar photovoltaic panel for photovoltaic energy storage according to claim 1, characterized in that: the third gear (20) is fixedly connected with the device bin (12), and the third gear (20) is in meshed connection with the second gear (19).