CN112713849A

CN112713849A - Ready-package solar cell panel subassembly

Info

Publication number: CN112713849A
Application number: CN202011632008.1A
Authority: CN
Inventors: 钮嘉玺; 钮阿兴; 豆燕伟; 徐婷; 李艳; 杨光
Original assignee: Yixing Jinshang Solar Energy Technology Co ltd
Current assignee: Yixing Jinshang Solar Energy Technology Co ltd
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2021-04-27
Anticipated expiration: 2040-12-31
Also published as: CN112713849B

Abstract

The invention relates to the technical field of solar panels, in particular to a quick-mounting type solar panel assembly, which comprises a solar panel, a connecting column, a telescopic frame, a base, a locking arm and a supporting rod, wherein the connecting column is arranged on the base; a plurality of locking grooves are distributed on the base at intervals, the telescopic frame comprises an upper ring and a lower ring, through holes are distributed on the upper ring in the circumferential direction, a pre-tightening table is arranged on the upper ring, deformation pieces are arranged between the upper ring and the lower ring, and a transmission column is arranged on one of the deformation pieces; the connecting column is provided with a positioning groove, the upper end of the positioning groove is provided with a locking surface, and the support rod is inserted into the inner cavity of the connecting column through a ratchet structure; be equipped with the track on the bracing piece, the track has the slope section, and when less wind acted on solar cell panel suddenly, through the elastic deformation of deformation piece and the effect of ratchet structure for the pretension pulling force of pretension platform to the locking surface is greater than initial pretension pulling force, and then prevents that wind from changeing and when great, and wind drives solar cell panel vibration from time to time and causes the destruction to solar cell panel assembly's structure.

Description

Ready-package solar cell panel subassembly

Technical Field

The invention relates to the technical field of solar panels, in particular to a quick-mounting type solar panel assembly.

Background

Solar power generation is an emerging renewable energy source, and solar energy in a broad sense is a source of many energies on the earth, such as wind energy, chemical energy and potential energy of water. Solar energy resources are abundant, a solar panel is a main mode for generating power by using solar energy, and the solar energy creates a new life form for human beings, so that the society and the human beings enter an era in which additional renewable energy can be used. The utility model discloses a solar cell panel, including solar cell panel, the installation of solar cell panel, the wind that should avoid building and trees etc. as far as possible when solar cell panel uses shelters from, and this just causes large-scale solar cell panel to receive the destruction of the impact force of wind easily, and solar cell panel's installation is loaded down with trivial details, and the wind of different wind directions is long-time to solar cell panel effect simultaneously, probably makes the mounting not hard up for connect the unstability, solar cell panel receives the influence of vibration.

Disclosure of Invention

The invention provides a quick-mounting solar panel assembly, which aims to solve the problems that the conventional solar panel is easily damaged due to the impact force of wind, and meanwhile, due to the fact that wind in different wind directions acts on the solar panel for a long time, a fixing piece is possibly loosened, connection is unstable, the solar panel is damaged due to the influence of vibration, and the installation process of the solar panel is complicated.

The invention relates to a quick-mounting solar panel component which adopts the following technical scheme:

a quick-mounting solar panel assembly comprises a solar panel, a connecting column, a telescopic frame, a base, a locking arm and a supporting rod, wherein the axis of the base extends along the vertical direction;

a plurality of locking grooves extending along the radial direction of the base are distributed at intervals in the circumferential direction of the base, the telescopic frame comprises an upper ring and a lower ring which are arranged at intervals up and down, through holes for the supporting rod to pass through are distributed in the circumferential direction of the upper ring, a pre-tightening table is arranged on the upper ring, deformation pieces which are arranged in pairs are arranged between the upper ring and the lower ring at positions corresponding to the through holes, and a transmission column is arranged on one of the deformation pieces;

the connecting column is of a hollow structure with an inner cavity, a positioning groove which is in up-and-down sliding fit with the pre-tightening table is arranged on the connecting column, a locking surface is arranged at the upper end of the positioning groove, the supporting rod is inserted into the inner cavity of the connecting column through a ratchet structure, a pressure spring is arranged between the supporting rod and the connecting column, and the ratchet structure can limit the supporting rod upwards;

the support rod is provided with a track matched with the transmission column, the track is provided with an inclined section capable of driving the telescopic frame to rotate in the circumferential direction, when the telescopic frame rotates, the pre-tightening table is separated from the upper end of the positioning groove and clamped on the locking surface, the deformation sheet can drive the support rod to separate from the connecting column and support on the lower ring, and the locking arm is inserted into the locking groove to block the lower ring downwards.

The lower extreme outside from the top down of bracing piece includes third curved surface, second curved surface and first curved surface, and the second curved surface is outside protrusion for the outside of dysmorphism body forms the outside convex structure in middle part, and the inboard of the lower extreme of bracing piece is the structure corresponding with the outside.

The track comprises a first track, a second track and a third track, wherein the first track vertically extends on the first curved surface, the second track obliquely extends on the second curved surface to form the inclined section, and the third track vertically extends on the third curved surface.

Each pair of deformation pieces are arranged in a bending mode, and the bending directions of the deformation pieces are opposite to each other in the radial direction of the telescopic frame.

The transmission column is arranged at the middle position of the inner side of the deformation sheet positioned outside.

The upper ring is provided with an inverted L-shaped arm which comprises a vertical section extending along the axis of the upper ring and a horizontal section extending towards the axis of the upper ring, the lower end of the vertical section is fixedly connected with the upper ring, and the horizontal section forms the pre-tightening table.

The invention has the beneficial effects that:

when wind power is small, wind blows to the solar cell panel, when upward acting force of the solar cell panel is larger than downward pre-tightening pulling force of the pre-tightening table on the locking surface, the solar cell panel drives the connecting column to move upwards, the connecting column drives the pre-tightening table to move upwards through the locking surface, the deformation sheet is further stretched, pulling force of the pre-tightening table on the locking surface is increased to balance acting force of the wind, so that the connecting column and the supporting rod move relatively between two ratchet teeth on the ratchet structure, and when the wind suddenly acts on the solar cell panel, the deformation sheet is elastically deformed to buffer the solar cell panel, so that the solar cell panel is prevented from being damaged; when wind power is large, the solar cell panel drives the upper ring to move upwards through the connecting column, the upper ring drives the deformation sheet to stretch, the ratchet structure moves the distance of one or more ratchets at the moment, and after the acting force of wind disappears, the ratchet structure cannot reset, so that the pre-tightening tension of the pre-tightening table on the locking surface is greater than the initial pre-tightening tension, and further, when the wind is variable and large, the wind drives the solar cell panel to vibrate continuously up and down to damage the structure of the solar cell panel assembly.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic overall structure diagram of an embodiment of a ready-package solar panel assembly according to the present invention.

Fig. 2 is a perspective view of the partial fastening structure of fig. 1 before being installed.

Fig. 3 is a schematic view showing an installation process (a first state) of the fastening structure of fig. 1.

Fig. 4 is a schematic view (second state) of the fastening structure of fig. 1 during the installation process.

Fig. 5 is a schematic view (third state) of the installation process of the fastening structure of fig. 1.

Fig. 6 is a schematic view of a state in which the fastening structure of fig. 1 is mounted (final state).

Fig. 7 is a perspective view of the support rod 6 in fig. 2.

Fig. 8 is a perspective view of the connecting column 2 in fig. 1.

Fig. 9 is an internal schematic view of the connecting column 2 of fig. 1.

Fig. 10 is a perspective view of the expansion frame 3 in fig. 1.

Fig. 11 is a partial enlarged view a of fig. 10.

Fig. 12 is a perspective view of the base 4 in fig. 1.

In the figure: 1. a solar panel; 2. connecting columns; 3. a telescopic frame; 301. ring fitting; 302. a lower ring; 4. a base; 5. a locking arm; 6. a support bar; 7. deformation sheets; 8. a pre-tightening table; 9. positioning a groove; 10. a locking surface; 11. a wedge-shaped table; 1201. a first track; 1202. a second track; 1203. a third track; 13. a ratchet; 14. a wedge-shaped groove; 15. a brake groove; 17. a pawl; 18. an elastic pad; 19. a spring case; 20. a through hole; 21. a drive post; 22. a locking groove; 23. positioning plates; 24. a roller; 25. a third curved surface; 26. a first curved surface; 27. a second curved surface.

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.

In an embodiment of the present invention, as shown in fig. 1 to 12, a ready-to-mount solar panel assembly includes: solar cell panel 1, spliced pole 2, flexible frame 3, base 4, locking arm 5 and bracing piece 6.

As shown in fig. 8, the connecting column 2 is a hollow structure, and wedge-shaped platforms 11 are provided on both sides of the lower end. As shown in fig. 7, the upper half part of the support rod 6 is a ratchet bar composed of ratchets 13, the lower half part is a special-shaped body, the upper end of the special-shaped body is provided with a wedge-shaped groove 14, and the connecting column 2 and the support rod 6 are buckled with the wedge-shaped table 11 through the wedge-shaped groove 14. Three pressure springs (not shown in the figure) and three spring cylinders 19 are arranged in a one-to-one correspondence manner, three circular grooves are correspondingly arranged at the upper ends of the supporting rods 6, the upper ends of the pressure springs are inserted into the spring cylinders 19, and the lower ends of the pressure springs are inserted into the circular grooves at the upper ends of the supporting rods 6. When the connecting column 2 and the supporting rod 6 are buckled with the wedge-shaped table 11 through the wedge-shaped groove 14, the elastic force of the pressure spring is slightly smaller than the fastening force of the wedge-shaped groove 14 and the wedge-shaped table 11, namely, the connecting column 2 and the supporting rod 6 can be separated by applying smaller external force after being fixedly connected with the wedge-shaped table 11 through the wedge-shaped groove 14. And the connecting columns 2 are fixedly connected with the solar cell panel 1 through screws. The telescopic frame 3 can be rotatably installed on the base 4, the telescopic frame 3 and the base 4 are limited by the locking arm 5 to be incapable of moving relatively along the axial direction of the telescopic frame 3 and the base 4, and the base 4 is fixedly connected with the ground through screws.

As shown in fig. 10, the expansion frame 3 includes: deformation sheet 7, pretensioning table 8, through hole 20, upper ring 301 and lower ring 302. The upper ring 301 and the lower ring 302 are circular rings evenly provided with a plurality of through holes 20 in the circumferential direction, the upper ring 301 and the lower ring 302 are parallel and concentric, the upper ring 301 is positioned above the lower ring 302, and the through holes 20 on the upper ring 301 and the lower ring 302 are overlapped when viewed from top to bottom. The deformation pieces 7 are a pair of arc-shaped elastic pieces, the bending directions of each pair of deformation pieces are opposite, and each pair of deformation pieces are opposite. As shown in fig. 11, a transmission column 21 extending toward the inside is provided at a middle position of the inner side surface of the deformation plate 7 at the outer side. The upper end of going up ring 301 is equipped with type of falling L arm, and type of falling L arm includes the vertical section that extends along the axis of going up ring 301 and the horizontal segment that extends towards ring 301 axis, and the lower extreme of vertical section and the rigid coupling of going up ring 301, the horizontal segment forms pretension platform 8. The inverted-L-shaped arm, the through hole 20, and the deformation piece 7 are located at the same position in the circumferential direction of the telescopic frame 3.

As shown in fig. 12, the base 4 includes a locking groove 22, a positioning piece 23, and a roller 24. The base 4 is a circular disc-shaped structure, the axis of the base 4 coincides with the axis of the telescopic frame 3, a plurality of locking grooves 22 are uniformly distributed in the circumferential direction of the base 4, and the locking grooves 22 extend along the radial direction. The locking groove 22 is adapted to slidably engage with the L-shaped locking arm 5 to limit the axial movement of the telescopic frame 3. A plurality of rollers 24 are uniformly distributed in the inner axial direction of the base 4, and the upper sides of the rollers 24 are in contact with the telescopic frame 3, so that the telescopic frame 3 and the base 4 can rotate relatively more easily. The positioning piece 23 is a spring piece extending in the radial direction. In the installation process, the positioning piece 23 is attached to one side of the deformation piece 7, and after the telescopic frame 3 and the base 4 rotate relatively, the locking groove 22 is located between the two adjacent deformation pieces 7, so that the locking arm 5 can be pushed into a gap between the two adjacent deformation pieces 7.

As shown in fig. 8 and 9, the connecting column 2 is a hollow cylindrical structure, and has a top cover at the upper end and an opening at the lower end. The axis one side of spliced pole 2 keeping away from flexible frame 3 is equipped with two bosss, and the interval between two bosss forms constant head tank 9, and its direction extends along the axis direction of flexible frame 3. A pawl 17 is arranged on one side of the inner side of the bottom of the connecting column 2, which is far away from the axis of the telescopic frame 3. The side of the pawl 17 away from the axis of the telescopic frame 3 is provided with an elastic pad 18, and the elastic pad 18 is a compressible elastic gasket for applying elastic resetting force to the pawl 17.

As shown in fig. 7, the ratchets 13 face the outside of the telescopic frame 3, and the profile bodies at the lower ends of the plurality of support rods 6 are uniformly distributed on the same circumference which is coaxial with the telescopic frame 3 so as to facilitate the relative rotation between the support rods 6 and the telescopic frame 3. One side of the special-shaped body, which is far away from the axis of the telescopic frame 3, comprises a third curved surface 25, a second curved surface 27 and a first curved surface 26 from top to bottom, the second curved surface 27 protrudes outwards, so that the outer side of the special-shaped body forms a structure with the middle protruding outwards, the inner side of the special-shaped body is a structure corresponding to the outer side, and the middle position of the special-shaped body protrudes inwards. The first track 1201 extends in the vertical direction on the first curved surface 26, and the third track 1203 extends in the vertical direction on the third curved surface 25. The second track 1202 extends obliquely on the second curved surface 27, and the upper end and the lower end of the second track are correspondingly connected with the first track 1201 and the third track 1203. After the supporting rod 6 and the telescopic frame 3 rotate relatively, the braking groove 15 can be clamped on the lower ring 302, so that the telescopic frame 3 can support the supporting rod 6, the supporting rod 6 supports the connecting column 2 through the ratchet 13, and the connecting column 2 supports the solar cell panel 1.

The installation process is as follows: as shown in fig. 3, the whole of the connection post 2, the support rod 6 and the solar cell panel 1 is inserted into the through hole 20 of the telescopic frame 3, and the first curved surface 26 contacts the upper half of the deformable sheet 7 first.

As shown in fig. 4, the solar panel 1 is pushed by a person to carry the connecting column 2, the connecting column 2 pushes the telescopic frame 3 to move downwards, the pre-tightening table 8 enters the positioning groove 9 and slides along the positioning groove 9, and the transmission column 21 enters the first rail 1201 and slides along the first rail 1201, so that the support rod 6 is aligned with the deformable sheet 7 to be squeezed. The deformation sheet 7 is expanded under the action force of the support rod 6, the deformation sheet 7 extends, the upper ring 301 is far away from the lower ring 302, and the pre-tightening table 8 moves upwards relative to the ground.

As shown in fig. 5, the driving post 21 enters the second track 1202 and slides along the second track 1202, the whole of the connecting post 2 and the supporting rod 6 and the deformable piece 7 rotate relatively, the deformable piece 7 is not expanded any more, the side of the pre-tightening table 8 rotates relatively with respect to the ground ascending side and the connecting post 2, and when the driving post 21 moves to the end of the second track 1202, the pre-tightening table 8 moves above the locking surface 10.

As shown in fig. 6, the connecting post 2 pushes the supporting post 6 to continue moving downward, when the driving post 21 is separated from the second track 1202 and enters the third track 1203, the deformation sheet 7 recovers deformation and pushes the third curved surface 25 downwards so as to separate the wedge-shaped table 11 from the wedge-shaped groove 14, the support rod 6 is separated from the connecting column 2, the pressure spring between the spring cylinder 19 and the circular groove at the upper end of the support rod 6 is released, and has downward acting force on the support rod 6, the upward acting force on the connecting column 2, the braking groove 15 is quickly attached to the lower ring 302 before the deformation sheet 7 is completely restored to be deformed, the connecting column 2 is subjected to the gravity of the solar panel 1 and the downward thrust of a person, the upward acting force on the connecting column 2 when the pressure spring is released enables the connecting column 2 to slightly move upwards, the locking surface 10 is attached to the pre-tightening table 8, and the upper side of one ratchet 13 and the lower side of the pawl 17 are tightly attached, so that the support rod 6 supports the connecting column 2 and the solar cell panel 1 thereon. At this time, the deformed portion of the deformable piece 7 is restored, and the pretightening table 8 applies a downward pretightening force to the locking surface 10, thereby completing the installation.

In the use, when wind-force is less, wind blows to solar cell panel 1, solar cell panel 1 receives ascending effort to be greater than the below pretension pulling force of pretension platform 8 to locking surface 10, solar cell panel 1 drives spliced pole 2 rebound, spliced pole 2 drives pretension platform 8 rebound through locking surface 10 again, shape deformation piece 7 is further stretched, the pulling force grow of pretension platform 8 to locking surface 10 is balanced with the effort of wind, and pawl 17 breaks away from one of them ratchet 13 up end, reciprocal luffing motion between the up end of two ratchet 13, after the effort of wind disappears, pawl 17 pastes the up end of same ratchet 13 again, when wind acts on solar cell panel 1 suddenly, through the elastic deformation of shape deformation piece 7, cushion, prevent that solar cell panel 1 from being destroyed.

When wind power is large, the pawl 17 is separated from the upper end face of one of the ratchets 13 and then passes over the last one or more ratchets 13 of the ratchets 13, after the acting force of the wind disappears, the pawl 17 is tightly attached to the upper end face of one of the ratchets 13, the deformation of the deformation sheet 7 is increased and then is not reset, the pre-tightening tension of the pre-tightening table 8 on the locking face 10 is larger than the initial pre-tightening tension, and therefore the solar panel 1 is prevented from being continuously vibrated up and down to damage the structure of the solar panel assembly due to the wind.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A ready-package solar panel assembly characterized in that: the solar cell panel fixing device comprises a solar cell panel, a connecting column, a telescopic frame, a base, a locking arm and a supporting rod, wherein the axis of the base extends in the vertical direction;

2. The ready-to-mount solar panel assembly of claim 1, wherein: the lower extreme outside from the top down of bracing piece includes third curved surface, second curved surface and first curved surface, and the second curved surface is outside protrusion for the outside of dysmorphism body forms the outside convex structure in middle part, and the inboard of the lower extreme of bracing piece is the structure corresponding with the outside.

3. The ready-to-mount solar panel assembly of claim 2, wherein: the track comprises a first track, a second track and a third track, wherein the first track vertically extends on the first curved surface, the second track obliquely extends on the second curved surface to form the inclined section, and the third track vertically extends on the third curved surface.

4. A ready-to-mount solar panel assembly according to any of claims 1-3, wherein: each pair of deformation pieces are arranged in a bending mode, and the bending directions of the deformation pieces are opposite to each other in the radial direction of the telescopic frame.

5. The ready-to-mount solar panel assembly of claim 4, wherein: the transmission column is arranged at the middle position of the inner side of the deformation sheet positioned outside.

6. The ready-to-mount solar panel assembly of claim 1, wherein: the upper ring is provided with an inverted L-shaped arm which comprises a vertical section extending along the axis of the upper ring and a horizontal section extending towards the axis of the upper ring, the lower end of the vertical section is fixedly connected with the upper ring, and the horizontal section forms the pre-tightening table.