CN113644872A - Solar cell supporting assembly and solar cell device - Google Patents

Abstract

The invention relates to the technical field of solar cells, in particular to a solar cell support assembly and a solar cell device, which comprise a support base, a mounting seat erected on the support base, and a basic support erected on the mounting seat, wherein the basic support is provided with: a solar cell frame plate; the axis of the solar cell frame plate is arranged on the base supporting frame in a turnover way; a turnover assembly; the power input end of the overturning assembly is arranged on the basic supporting frame, and the power output end of the overturning assembly is arranged at the axis of the solar cell frame plate; the orientation tracking assembly is connected with the power input end of the overturning assembly and used for tracking the orientation of the sun and controlling the shaft transmission angle of the overturning assembly so as to control the steering angle of the solar cell frame plate. This application design upset subassembly is used for driving solar cell frame board and rotates to can judge steering angle to pursuing the sun orientation.

Description

Solar cell supporting assembly and solar cell device

Technical Field

The invention relates to the technical field of solar cells, in particular to a solar cell support assembly and a solar cell device.

Background

A solar cell is also called a "solar chip" or a "photovoltaic cell", and is a photoelectric semiconductor sheet that directly generates electricity by using sunlight, and can output voltage and generate current under the condition of a loop instantly only when being irradiated by light satisfying a certain illumination condition, and is physically called a solar photovoltaic, which is called a photovoltaic for short.

At present, most of solar modules are arranged on the same plane support or supporting piece through pressing blocks, and the pressing blocks press the solar modules on a bottom support or supporting plate on the side surfaces of the solar modules; most of the support structures are inconvenient to use, and the inclination angle of the solar cell cannot be adjusted according to the use condition, so that the solar cell cannot be completely irradiated by sunlight, the power generation efficiency is lowered, and unnecessary troubles are caused.

Disclosure of Invention

The present invention is directed to a solar cell support assembly and a solar cell device to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a solar cell supporting component, includes the supporting pedestal, erects the mount pad on the supporting pedestal to and erect the basic support frame in the mount pad, basic support frame is provided with:

a solar cell frame plate; the solar cell frame plate is erected on the supporting side of the base supporting frame, the axis of the solar cell frame plate is installed on the base supporting frame in a turnover mode, and the supporting surfaces on the two sides of the solar cell frame plate are installed on the base supporting frame in a supporting mode through supporting folding rods;

a turnover assembly; the power input end of the overturning assembly is arranged on the basic supporting frame, and the power output end of the overturning assembly is arranged at the axis of the solar cell frame plate;

the direction tracking assembly is connected with the power input end of the overturning assembly and used for tracking the direction of the sun and controlling the shaft transmission angle of the overturning assembly so as to control the steering angle of the solar cell frame plate;

a solar cell loading frame; the solar cell frame plate is arranged on the loading surface of the solar cell frame plate and is used for being installed on the solar cell panel.

As a further scheme of the invention: the power take off end of upset subassembly is including the upset linkage frame, the support end of basic support frame is erect to the upset linkage frame, be provided with the upset main shaft on the upset linkage frame, the upset main shaft sets up in solar cell frame plate's axis department, the both ends of upset main shaft are provided with the transmission frame plate, the transmission frame plate is fixed mounting through the vertically fixed frame plate with it again and solar cell frame plate.

As a further scheme of the invention: the power input end of the turnover assembly is provided with a belt transmission assembly, the belt transmission assembly comprises a power transmission shaft, a driving wheel arranged on the power transmission shaft, a driven wheel arranged on the turnover main shaft, and a synchronous belt used for connecting the driving wheel and the driven wheel.

As a further scheme of the invention: the frame plate of the basic support frame is provided with a bearing support plate, a bearing support notch is formed in the bearing support plate, and the overturning main shaft is erected in the bearing support notch.

As a further scheme of the invention: the subassembly is tracked to orientation includes the detection frame plate of perpendicular to power transmission axle, installs the spotlight frame on detecting the frame plate, be provided with convex lens in the spotlight frame, spotlight frame orientation sunshine side and with the installation of detection frame plate with corresponding angle slope, be provided with the positioning disk on the detection frame plate, the positioning disk is coiled along being provided with the high temperature response piece, the axis department of positioning disk is provided with the internal drive axle, internal drive axle department is provided with the high temperature response needle.

As a further scheme of the invention: the orientation tracking assembly is further provided with a processing device, the steering angle of the high-temperature induction needle is recorded in the processing device, and the processing device transmits angle data to a driving system of the power transmission shaft.

As a further scheme of the invention: the solar cell loading frame comprises a plurality of loading single frames which are arranged side by side, the loading single frames comprise outer frame edges fixed on the solar cell frame plates and inner cavity grooves used for installing solar cells, a plurality of fixing pieces are arranged between the outer frame edges and the solar cell frame plates, linking notches are arranged between the adjacent outer frame edges, and fixing insertion blocks are arranged between the adjacent linking notches.

As a still further scheme of the invention: the mounting base comprises a base supported on a supporting base, a vertical rotating shaft is arranged on the base, a transmission chassis is arranged at the bearing end of the base, and the transmission chassis is rotatably limited on the base by taking the vertical rotating shaft as a central axis.

The application also discloses a solar cell device, which comprises the solar cell supporting component and a solar cell arranged on the solar cell supporting component; the solar cell comprises a solar cell body and is characterized in that the solar cell body is matched with an inner cavity groove, positioning notches are arranged at four corners of the inner cavity groove, and a shell bulge matched with the positioning notches is arranged on the solar cell body.

Compared with the prior art, the invention has the beneficial effects that:

the overturning assembly is designed to drive the solar cell frame plate to rotate, so that the position of the solar cell frame plate is adjusted along with the position movement of the sun, and the sunlight contact angle of the solar cell frame plate is more suitable; the orientation tracking assembly is used for judging the steering angle of the tracked sun, so that the shaft transmission angle of the turnover assembly is adjusted.

The power input end of the turnover assembly is arranged on the basic support frame, and the power output end of the turnover assembly is arranged at the axis of the solar cell frame plate, so that during power output, vibration of a driving motor and other related power supply assemblies has smaller influence on displacement of the solar cell frame plate, and the steering precision is improved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present application and together with the description, serve to explain the principles of the application. Also, the drawings and the description are not intended to limit the scope of the present concepts in any way, but rather to illustrate the concepts of the present disclosure to those skilled in the art by reference to specific embodiments.

Fig. 1 is a schematic view of an overall structure of a solar cell support assembly according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a solar cell shelf board according to an embodiment of the present invention.

FIG. 3 is a schematic structural diagram of the area A in FIG. 2 according to the present invention.

Fig. 4 is a schematic structural diagram of a belt driving assembly according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an orientation tracking assembly according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a mounting base according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a solar cell loading frame according to an embodiment of the present invention.

In the figure: 11. a support base; 12. a mounting seat; 13. a base support frame; 14. a solar cell frame plate; 15. a turnover assembly; 16. positioning the clamping plate; 17. a solar cell loading frame; 18. an orientation tracking component; 21. turning over the linkage frame; 22. turning over the main shaft; 23. a transmission frame plate; 24. fixing the frame plate; 25. a locking frame; 26. a limiting sleeve; 31. a driven wheel; 32. a synchronous belt; 33. a drive wheel; 34. a belt drive assembly; 35. a power transmission shaft; 36. a bearing support plate; 41. detecting the frame plate; 42. positioning a plate; 43. a high-temperature induction sheet; 44. a light-gathering frame; 45. a convex lens; 46. an inner drive shaft; 47. a high temperature induction needle; 51. loading the single frame; 52. an outer frame edge; 53. an inner cavity groove; 54. a fixing sheet; 55. a joining notch; 56. fixing the insert block; 57. positioning the notch; 61. a turnover bolt; 62. pressing a plate; 71. a vertical rotating shaft; 72. a base; 73. a transmission chassis.

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, examples of which are shown in the drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements, unless otherwise indicated.

It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. 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.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

In one embodiment;

referring to fig. 1 and 2, a solar cell support assembly is provided, which includes a support base 11, a mounting base 12 erected on the support base 11, and a base support frame 13 erected on the mounting base, wherein the base support frame 13 is provided with:

a solar cell frame plate 14; the solar cell frame plate 14 is erected on the supporting side of the base supporting frame 13, the axis of the solar cell frame plate 14 is installed on the base supporting frame 13 in a turnover mode, and the supporting surfaces on the two sides of the solar cell frame plate 14 are installed on the base supporting frame 13 in a supporting mode through supporting folding rods;

a flip assembly 15; the power input end of the turnover assembly 15 is arranged on the basic support frame 13, and the power output end of the turnover assembly 15 is arranged at the axis of the solar cell frame plate 14;

the orientation tracking assembly 18 is connected to the power input end of the turning assembly 15 for tracking the orientation of the sun and controlling the shaft transmission angle of the turning assembly 15, thereby controlling the turning angle of the solar cell frame plate 14.

A solar cell loading frame 17; a mounting surface provided on the solar cell panel 14 for mounting on a solar cell panel;

in this embodiment, the solar cell panel is mounted on the solar cell loading frame 17, the solar cell loading frame 17 is mounted on the upper surface of the solar cell frame plate 14, and the solar cell frame plate 14 is an overturning adjusting mechanism of the solar cell; the overturning assembly 15 is used for driving the solar cell frame plate 14 to rotate, so that the position of the solar cell frame plate 14 is adjusted along with the position movement of the sun, and the sunlight contact angle of the solar cell frame plate 14 is more suitable; the orientation tracking assembly 18 is used for tracking the orientation of the sun, judging a steering angle, and adjusting a shaft transmission angle of the turnover assembly 15.

Wherein, the power input end of the turnover component 15 is arranged on the basic support frame 13, and the power output end of the turnover component 15 is arranged at the axis of the solar cell frame plate 14, so that during power output, the vibration of the driving motor and other related power supply components has less influence on the displacement of the solar cell frame plate 14, thereby improving the steering precision.

The embodiment is also provided with a positioning splint 16; and a solar cell frame plate 14 for holding and fixing the solar cell loading frame 17.

In one embodiment;

referring to fig. 2 and 3, the power output end of the turning assembly 15 includes a turning linkage frame 21, the turning linkage frame 21 is erected at the supporting end of the base support frame 13, a turning spindle 22 is arranged on the turning linkage frame 21, the turning spindle 22 is arranged at the axis of the solar cell frame plate 14, transmission frame plates 23 are arranged at two ends of the turning spindle 22, and the transmission frame plates 23 are fixedly mounted on the solar cell frame plate 14 through fixing frame plates 24 perpendicular to the transmission frame plates 23.

The overturning linkage frame 21 is supported between the base support frame 13 and the solar cell frame plate 14, the overturning main shaft 22 is a power shaft which directly drives the solar cell frame plate 14 to overturn, so that the orientation of the solar cell frame plate 14 is adjusted, and the bottom plane of the solar cell frame plate 14 is installed with the base support frame 13 through a folding support rod, so that the supporting force can be ensured along with the solar cell frame plate 14; the turnover main shaft 22 drives the transmission frame plate 23, and the transmission frame plate 23 is integrated with the solar cell frame plate 14, so that the solar cell frame plate 14 rotates along with the rotation.

In one case of the embodiment, the carrier plate 23 is fixedly mounted to the tilting spindle 22 by means of a locking frame 25, ensuring a degree of stability.

In a case of this embodiment, the two sides of the driving frame plate 23 are provided with the stop collar 26, the turning main shaft 22 penetrates through the stop collar 26, and the stop collar 26 is installed on the basic support frame 13 to limit the movement of the turning main shaft 22, so as to reduce the risk of shaking the turning main shaft 22 itself when the turning main shaft 22 rotates.

In one case of the present embodiment,

referring to fig. 4, a belt transmission assembly 34 is disposed at a power input end of the flipping unit 15, and the belt transmission assembly 34 includes a power transmission shaft 35, a driving wheel 33 mounted on the power transmission shaft 35, a driven wheel 31 mounted on the flipping main shaft 22, and a synchronous belt 32 for connecting the driving wheel 33 and the driven wheel 31. For the transmission of the turnover assembly 15, the belt transmission driving mode is adopted in the present embodiment, and the turnover main shaft 22 is indirectly driven to move, so that the vibration factor generated by the power driving end is reduced, and the influence on the rotation of the turnover main shaft 22 is reduced.

In one aspect of this embodiment, the driving wheel 33 and the driven wheel 31 are provided with insections on their wheel faces, the synchronous belt 32 is also provided with insections on its inner belt face, and the driving wheel 33, the driven wheel 31 and the synchronous belt 32 are in insection transmission connection, so that the risk of insection slip can be effectively reduced, and the manner of gear connection further limits the driving wheel 33, the driven wheel 31 and the synchronous belt 32, thereby reducing the influence of vibration.

In one aspect of the present embodiment, a bearing support plate 36 is disposed on the frame plate of the base support frame 13, a bearing support notch 36 is disposed in the bearing support plate 36, and the turnover spindle 22 is erected in the bearing support notch 36.

In one embodiment;

referring to fig. 5, the orientation tracking assembly 18 includes a detection frame plate 41 perpendicular to the power transmission shaft 35, and a light gathering frame 44 mounted on the detection frame plate 41, wherein a convex lens 45 is disposed on the light gathering frame 44, the light gathering frame 44 faces the sunshine side and is obliquely mounted at a corresponding angle with the detection frame plate 41, a positioning plate 42 is disposed on the detection frame plate 41, a high temperature sensing sheet 43 is disposed along the positioning plate 42, an inner driving shaft 46 is disposed at an axis of the positioning plate 42, and a high temperature sensing needle 47 is disposed at the inner driving shaft 46.

The orientation tracking assembly 18 is further provided with a processing device, the steering angle of the high temperature sensing needle 47 is recorded in the processing device, and the processing device transmits the angle data to the driving system of the power transmission shaft 35.

For the orientation tracking assembly 18, the light gathering frame 44 is arranged towards the sky, the convex lens 45 is used for light gathering operation, light rays are refracted in the arc area where the high temperature sensing piece 43 is located, and along with the movement of the sun, the refracted and gathered light rays also move along the arc area where the high temperature sensing piece 43 is located, so that the emission points on the high temperature sensing piece 43 are different; the high temperature induction needle 47 swings along the arc area where the high temperature induction sheet 43 is located, so as to induce a change angle, and then deduct the displacement angle of the sun; the processing device transmits the angle data to the driving system of the power transmission shaft 35, thereby controlling the power transmission shaft 35 to rotate by a corresponding angle, so that the solar cell frame plate 14 can move along with the direction of sunshine.

In one embodiment;

referring to fig. 1 and 6, the mounting base 12 includes a base 72 supported on the supporting base 11, a vertical rotating shaft 71 is disposed on the base 72, a transmission chassis 73 is disposed at a carrying end of the base 72, and the transmission chassis 73 is rotatably limited on the base 72 by using the vertical rotating shaft 71 as a middle axis.

The mounting mode of the support base 11 can be mounted on an elevated upright post or a roof of a high-rise building; therefore, the transmission chassis 73 can rotate through the vertical rotating shaft 71, and the positions of the solar cell frame plate 14 and the basic supporting frame 13 are adjusted when the solar cell frame plate is installed, so that the solar cell frame plate is suitable for different installation terrain environments.

In one embodiment;

referring to fig. 7, the solar cell loading frame 17 includes a plurality of loading single frames 51 arranged in parallel, the loading single frames 51 include outer frame edges 52 fixed on the solar cell frame plate 14, and inner cavity grooves 53 for mounting the solar cells, a plurality of fixing pieces 54 are disposed between the outer frame edges 52 and the solar cell frame plate 14, linking notches 55 are disposed between adjacent outer frame edges 52, and fixing insertion blocks 56 are disposed between adjacent linking notches 55.

The solar cell mounting frame 17 is composed of a plurality of mounting frames 51; each solar cell is mounted in the cavity groove 53, the loading single frames 51 are respectively fixed on the solar cell frame plate 14, and the adjacent loading single frames 51 are connected with each other to form the whole integrated structure.

In one aspect of the present embodiment, the positioning clamp plate 16 includes a folding bolt 61 and a pressing plate 62 mounted on the folding bolt 61, and the positioning clamp plate 16 is disposed at the position of the outer frame edge 52 of the loading single frame 51, so as to secure the solar cell loading frame 17 and avoid shielding the solar cell.

The embodiment also discloses a solar cell device, which comprises the solar cell supporting component and a solar cell arranged on the solar cell supporting component; the solar cell comprises a solar cell body and is characterized in that the solar cell body is matched with an inner cavity groove 53, positioning notches 57 are formed in the four corners of the inner cavity groove 53, and a shell bulge matched with the positioning notches 57 is arranged on the solar cell body, so that the solar cell body is embedded in the inner cavity groove 53.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. The utility model provides a solar cell supporting component, includes the supporting pedestal, erects the mount pad on the supporting pedestal to and erect the basic support frame in the mount pad, its characterized in that, basic support frame is provided with:

a solar cell frame plate; the solar cell frame plate is erected on the supporting side of the base supporting frame, the axis of the solar cell frame plate is installed on the base supporting frame in a turnover mode, and the supporting surfaces on the two sides of the solar cell frame plate are installed on the base supporting frame in a supporting mode through supporting folding rods;

a turnover assembly; the power input end of the overturning assembly is arranged on the basic supporting frame, and the power output end of the overturning assembly is arranged at the axis of the solar cell frame plate;

an orientation tracking component; the power input end of the turnover assembly is connected with the power input end of the turnover assembly and used for tracking the direction of the sun and controlling the shaft transmission angle of the turnover assembly so as to control the steering angle of the solar cell frame plate;

a solar cell loading frame; the solar cell frame plate is arranged on the loading surface of the solar cell frame plate and is used for being installed on the solar cell panel.

2. The solar cell support assembly according to claim 1, wherein the power output end of the turnover assembly comprises a turnover linkage frame, the turnover linkage frame is erected at the supporting end of the base support frame, a turnover spindle is arranged on the turnover linkage frame, the turnover spindle is arranged at the axis of the solar cell frame plate, transmission frame plates are arranged at two ends of the turnover spindle, and the transmission frame plates are fixedly mounted with the solar cell frame plate through fixing frame plates perpendicular to the transmission frame plates.

3. The solar cell support assembly of claim 2, wherein the power input end of the turnover assembly is provided with a belt transmission assembly, the belt transmission assembly comprises a power transmission shaft, a driving wheel mounted on the power transmission shaft, a driven wheel mounted on the turnover main shaft, and a synchronous belt for connecting the driving wheel and the driven wheel.

4. The solar cell support assembly according to claim 3, wherein the orientation tracking assembly comprises a detection frame plate perpendicular to the power transmission shaft, and a light focusing frame mounted on the detection frame plate, wherein a convex lens is arranged on the light focusing frame, the light focusing frame faces the sunshine side and is obliquely mounted at a corresponding angle with the detection frame plate, a positioning disc is arranged on the detection frame plate, a high temperature sensing sheet is arranged on the positioning disc, an inner driving shaft is arranged at the axis of the positioning disc, and a high temperature sensing needle is arranged at the inner driving shaft.

5. The solar cell support assembly of claim 4, wherein a processing device is further disposed at the orientation tracking assembly, the steering angle of the high temperature sensing pin is recorded in the processing device, and the processing device transmits the angle data to a driving system of the power transmission shaft.

6. The solar cell support assembly according to claim 1, wherein the solar cell loading frame comprises a plurality of loading single frames arranged side by side, each loading single frame comprises an outer frame edge fixed on the solar cell frame plate and an inner cavity groove for mounting the solar cell, a plurality of fixing pieces are arranged between the outer frame edge and the solar cell frame plate, linking notches are arranged between adjacent outer frame edges, and fixing insertion blocks are arranged between adjacent linking notches.

7. The solar cell support assembly of claim 1, wherein the mounting base comprises a base supported on a support base, the base is provided with a vertical rotating shaft, a bearing end of the base is provided with a transmission chassis, and the transmission chassis is rotatably limited on the base by taking the vertical rotating shaft as a central axis.

8. A solar cell device, which comprises the solar cell support assembly as claimed in any one of claims 1 to 7, and a solar cell mounted on the solar cell support assembly, wherein an outer shell of the solar cell is matched with an inner cavity groove, positioning notches are arranged at four corners of the inner cavity groove, and an outer shell of the solar cell is provided with shell protrusions matched with the positioning notches.

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