CN220234572U - Simple photovoltaic bracket - Google Patents

Abstract

The utility model belongs to the technical field of photovoltaic equipment, and particularly relates to a simple photovoltaic bracket. The utility model comprises a cross beam, a longitudinal beam and a telescopic strut; the two cross beams are arranged in parallel; the longitudinal beams are arranged in a plurality, the longitudinal beams are parallel and detachably connected between the two cross beams, and the longitudinal beams are perpendicular to the cross beams; the telescopic support posts are four, and the bottom surfaces of the two ends of each cross beam are respectively connected with one telescopic support post. The utility model solves the problems that in the prior conventional technology, the angle of the photovoltaic panel cannot be adjusted along with the movement of the sun and the height of the stand column cannot be adjusted.

Description

Simple photovoltaic bracket

Technical Field

The utility model belongs to the technical field of photovoltaic equipment, and particularly relates to a simple photovoltaic bracket.

Background

Photovoltaic brackets are an integral part of photovoltaic engineering, and their primary function is to support and secure photovoltaic modules. However, the photovoltaic brackets commonly found in the prior art have more or less drawbacks, mainly represented by the following two aspects: on one hand, the common photovoltaic brackets are fixed with the angle of the photovoltaic panel, cannot be adjusted along with the movement track of the sun, and are not beneficial to the photovoltaic module to maximally absorb the light radiation; on the other hand, the common photovoltaic support is not adjustable in height, so that after the installation is finished, the photovoltaic support is often affected by the terrain, the problem of uneven fluctuation occurs, and the overall installation effect is affected.

Disclosure of Invention

The utility model provides a simple photovoltaic bracket, and aims to provide a photovoltaic module capable of carrying out direction adjustment along with a solar motion track so as to maximize the light radiation absorption amount; the second aim is to provide a photovoltaic support which can be adjusted in height, so that the photovoltaic support is installed, is not affected by terrain, and guarantees the overall installation effect.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a simple photovoltaic bracket, which comprises

The two cross beams are arranged in parallel;

the longitudinal beams are provided with a plurality of longitudinal beams, the longitudinal beams are parallel and detachably connected between the two cross beams, and the longitudinal beams are perpendicular to the cross beams;

the telescopic support columns are four, and the bottom surfaces of the two ends of each cross beam are respectively connected with one telescopic support column.

The beam is an integrated structure formed by a rectangular plate and an L-shaped plate; the L-shaped plate is vertically connected to the plate surface of the rectangular plate, the axis of the L-shaped plate is parallel to the axis of the rectangular plate, and the outer side of the vertical face of the L-shaped plate is flush with the outer edge of one long side of the rectangular plate; a photovoltaic plate limiting groove is formed between the L-shaped plate and the rectangular plate; an upper row of longitudinal beam connecting holes and a lower row of longitudinal beam connecting holes are formed in the plate surface of the rectangular plate, and the longitudinal beam connecting holes in the two rows are correspondingly arranged; two ends of the lower surface of the rectangular plate are fixedly connected with a node connector which is detachably connected with the telescopic support.

Each node connector comprises two semicircular plates; the plate surface of each semicircular plate is provided with a through hole for connection.

The longitudinal beam is of a cuboid structure, two ends of the cuboid are fixedly connected with connecting plates respectively, and the thickness of each connecting plate is smaller than that of the cuboid; the lower surface of the cuboid is coplanar with the lower surface of the connecting plate; a plurality of photovoltaic panel connecting holes are uniformly formed in the surface of the cuboid; the surface of the connecting plate is provided with a beam connecting hole.

The telescopic support column comprises a second upright column, a first upright column and a limiting mechanism; the second stand column is detachably connected to the first stand column through a limiting mechanism.

The second upright post is an integrated structure formed by a cylinder and a cuboid second upright post connector; the second upright post connector is fixedly connected to the top surface of one end of the cylinder, and the axial lead of the second upright post connector is collinear with the axial lead of the cylinder; the surface of the second upright post connector is provided with a through hole connected with the cross beam; the cylinder is uniformly provided with a plurality of second upright post limiting holes which are used for being connected with the first upright post along the axial direction; the axial lead of each second upright post limiting hole is perpendicular to and intersected with the axial lead of the cylinder, and each second upright post limiting hole penetrates through two opposite side surfaces of the cylinder.

The thickness of cuboid is less than the diameter of cylinder, and the width of cuboid equals the diameter of cylinder.

The first upright post is composed of a hollow cylinder and a fixed plate; the fixed plate is fixedly connected to the lower end face of the first upright post; the plate surface of the fixing plate is provided with a through hole for fixing; the hollow cylinder is uniformly provided with a plurality of first upright post limiting holes which are used for being connected with the second upright post along the axial direction; the axial lead of each first upright post limiting hole is perpendicular to and intersected with the axial lead of the hollow cylinder, and each first upright post limiting hole penetrates through two opposite side surfaces of the hollow cylinder.

The limiting mechanism comprises a limiting hoop and a connecting bolt; the two limiting hoops are connected through connecting bolts.

The limiting mechanism comprises a circular arc-shaped limiting hoop; a through hole for the passage of a connecting bolt is formed in the middle position of the circular arc plate; and a pull beam connector is fixedly connected to the outer side wall of the upper part of the first upright post, and a pull beam is connected between two telescopic support posts connected to the same cross beam.

The beneficial effects are that:

(1) The utility model is organically composed of a cross beam, a longitudinal beam and a telescopic strut. According to the utility model, through the height adjustment of the four telescopic support posts, the problems that in the prior art, the angle of the photovoltaic panel cannot be adjusted along with the movement of the sun and the height of the support posts cannot be adjusted are solved, and the level of the light radiation absorption amount of the photovoltaic module is improved.

(2) The first upright post and the second upright post are assembled in a detachable mode, so that manpower and material resources are greatly reduced during installation, and the problem of high potential safety hazard is solved.

(3) The height adjustability of the first upright post and the second upright post ensures that the photovoltaic bracket is not affected by terrain after being installed, ensures the overall installation effect and meets the overall aesthetic property.

(4) According to the utility model, through the height adjustability of the first upright post and the second upright post, the direction of the tubular office can be adjusted according to the angle of the sun, and the level of the light radiation absorption amount of the local photovoltaic module is improved.

The foregoing description is only an overview of the technical solution of the present utility model, and in order to make the technical means of the present utility model more clearly understood, it can be implemented according to the content of the specification, and the following detailed description of the preferred embodiments of the present utility model will be given with reference to the accompanying drawings.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a left side view of the utility model;

FIG. 3 is a schematic view of the structure of the first pillar according to the present utility model;

FIG. 4 is a schematic view of the stringer of the present utility model;

FIG. 5 is a schematic view of the cross beam structure of the present utility model;

FIG. 6 is a schematic view of a spacing clip according to the present utility model;

FIG. 7 is a schematic view of a second column structure according to the present utility model;

fig. 8 is a schematic view of the bottom surface structure of the cross beam in the present utility model.

In the figure: 1. a cross beam; 2. a second upright; 3. a longitudinal beam; 4. a limit hoop; 5. pulling a beam; 6. a first upright; 7. a pull beam connector; 8. a first upright post limiting hole; 9. a beam connection hole; 10. a photovoltaic panel connection hole; 11. a photovoltaic panel limit groove; 12. a stringer connecting hole; 13. a node connector; 14. a second column connector; 15. a second upright post limiting hole; 16. and a fixing plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

a simple photovoltaic bracket according to the figures 1-8, comprising

The two cross beams 1 are arranged, and the two cross beams 1 are arranged in parallel;

the longitudinal beams 3, the longitudinal beams 3 are provided with a plurality of longitudinal beams 3, the longitudinal beams 3 are parallel and detachably connected between the two cross beams 1, and the longitudinal beams 3 are perpendicular to the cross beams 1;

the telescopic support columns are four, and the bottom surfaces of the two ends of each cross beam 1 are respectively connected with one telescopic support column.

When in actual use, firstly, the telescopic support is fixed on a prefabricated pile foundation, and two cross beams 1 are connected on four telescopic supports in parallel; then a plurality of longitudinal beams 3 are respectively connected between the two cross beams 1, then a photovoltaic panel to be installed is inserted between the two cross beams 1, and the back of the photovoltaic panel is fixed on the longitudinal beams 3. Through the height of adjusting four scalable pillars, guarantee the overall effect of installation. When the direction adjustment is required according to the movement track of the sun, the photovoltaic module faces the solar surface by adjusting different heights of the four telescopic struts, so that the light radiation absorption amount is maximized.

Embodiment two:

a simple photovoltaic bracket according to the embodiment shown in fig. 1, 2, 5 and 8 is different from the embodiment in that: the beam 1 is an integrated structure formed by a rectangular plate and an L-shaped plate; the L-shaped plate is vertically connected to the plate surface of the rectangular plate, the axis of the L-shaped plate is parallel to the axis of the rectangular plate, and the outer side of the vertical face of the L-shaped plate is flush with the outer edge of one long side of the rectangular plate; a photovoltaic panel limiting groove 11 is formed between the L-shaped plate and the rectangular plate; an upper row of longitudinal beam connecting holes 12 and a lower row of longitudinal beam connecting holes 12 are formed in the plate surface of the rectangular plate, and the longitudinal beam connecting holes 12 on the two rows are correspondingly arranged; two ends of the lower surface of the rectangular plate are fixedly connected with a node connector 13 which is detachably connected with the telescopic support.

When in actual use, form photovoltaic board spacing groove 11 between L template in crossbeam 1 and the rectangular shaped plate, can guarantee the security of photovoltaic board with the stable joint of photovoltaic board of installation. The arrangement of the node connector 13 facilitates the connection with the telescopic strut. The upper longitudinal beam connecting holes 12 and the lower longitudinal beam connecting holes 12 are formed in the plate surface of the rectangular plate, and the longitudinal beams 3 can be connected in different through holes according to the actual width of the photovoltaic plate, so that the photovoltaic plate can be installed smoothly.

Embodiment III:

a simple photovoltaic bracket according to fig. 5 and 8 is different from the second embodiment in that: each node connector 13 comprises two semicircular plates; the plate surface of each semicircular plate is provided with a through hole for connection.

When in actual use, the node connector 13 adopts the technical scheme, so that the connection is convenient, the structure is simple, and the implementation is convenient.

Embodiment four:

a simple photovoltaic bracket according to the embodiment shown in fig. 1, 2 and 4 differs from the embodiment in that: the longitudinal beam 3 is of a cuboid structure, two ends of the cuboid are fixedly connected with connecting plates respectively, and the thickness of each connecting plate is smaller than that of the cuboid; the lower surface of the cuboid is coplanar with the lower surface of the connecting plate; a plurality of photovoltaic panel connecting holes 10 are uniformly formed in the surface of the cuboid; the surface of the connecting plate is provided with a beam connecting hole 9.

When in actual use, the longitudinal beam 3 adopts the technical scheme, and is convenient to be connected and fixed with the cross beam 1 and the photovoltaic panel.

Fifth embodiment:

a simple photovoltaic bracket according to fig. 1-3 and 7 is different from the embodiment in that: the telescopic support comprises a second upright post 2, a first upright post 6 and a limiting mechanism; the second upright post 2 is detachably connected to the first upright post 6 through a limiting mechanism.

In actual use, the height of the simple photovoltaic bracket is realized by adjusting the heights of the second upright post 2 and the first upright post 6. After the height is adjusted, the fixing is carried out through the limiting mechanism, and the fixing is simple and convenient.

Example six:

a simple photovoltaic bracket according to fig. 1, 2 and 7 is different from the fifth embodiment in that: the second upright post 2 is an integral structure formed by a cylinder and a cuboid second upright post connector 15; the second upright post connecting body 15 is fixedly connected to the top surface of one end of the cylinder, and the axial lead of the second upright post connecting body 15 is collinear with the axial lead of the cylinder; the surface of the second upright post connecting body 15 is provided with a through hole connected with the cross beam 1; a plurality of second upright post limiting holes 15 for connecting with the first upright post 6 are uniformly formed in the cylinder along the axial direction; the axial lead of each second upright post limiting hole 15 is perpendicular to and intersected with the axial lead of the cylinder, and each second upright post limiting hole 15 penetrates through two opposite side surfaces of the cylinder.

When in actual use, the second upright post 2 is inserted into the first upright post 6, and the limiting mechanism connects and fixes the second upright post 2 and the first upright post 6 through the second upright post limiting hole 15 on the second upright post 2 and the first upright post limiting hole 8 on the first upright post 6.

Embodiment seven:

a simple photovoltaic bracket according to the embodiment shown in fig. 1, 2 and 7 is different from the sixth embodiment in that: the thickness of cuboid is less than the diameter of cylinder, and the width of cuboid equals the diameter of cylinder.

When in actual use, the design of the technical scheme ensures that the parts have good appearance on the basis of realizing the basic functions of the parts, and avoids the scratches to operators in the use process.

Example eight:

a simple photovoltaic bracket according to fig. 1-3 is different from the fifth embodiment in that: the first upright 6 is formed by a hollow cylinder and a fixed plate 16; the fixed plate 16 is fixedly connected to the lower end face of the first upright post 6; the plate surface of the fixed plate 16 is provided with a through hole for fixing; the hollow cylinder is uniformly provided with a plurality of first upright post limiting holes 8 which are used for being connected with the second upright post 2 along the axial direction; the axial lead of each first upright post limiting hole 8 is perpendicular to and intersected with the axial lead of the hollow cylinder, and each first upright post limiting hole 8 penetrates through two opposite side surfaces of the hollow cylinder.

When in actual use, the hollow cylinder is adopted on the upper part of the first upright post 6, so that the second upright post 2 is conveniently inserted into the first upright post 6, the connection of the first upright post and the second upright post is conveniently realized, and the adjustment of the height is convenient. After the height adjustment, stop gear lug insert the through-hole that opens on the lateral wall of first stand 6 and second stand 2, realize the connection fixed with first stand 6 and second stand 2.

Example nine:

a simple photovoltaic bracket according to fig. 1, 2 and 6 is different from the fifth embodiment in that: the limiting mechanism comprises a limiting hoop 4 and a connecting bolt; the two limiting hoops 4 are arranged, and the two limiting hoops 4 are connected through connecting bolts.

When in actual use, the two limit hoops 4 are surrounded on the outer side wall of the first upright post 6, one end of the connecting bolt sequentially passes through the limit hoops 4, the side wall of the first upright post 6, the side wall of the second upright post 2, the side wall of the first upright post 6 and the limit hoops 4 and then locks the end by using nuts, so that the first upright post 6 and the second upright post 2 are stably connected.

Example ten:

a simple photovoltaic bracket according to fig. 1, 2 and 6 is different from the fifth embodiment in that: the limiting mechanism comprises a circular arc-shaped plate as the limiting hoop 4; a through hole for the passage of a connecting bolt is formed in the middle position of the circular arc plate; the upper and lower outer side walls of the first upright post 6 are also fixedly connected with a pull beam connector 7 respectively, and a pull beam 5 is connected between two telescopic struts connected on the same cross beam 1.

When in actual use, the limiting hoop 4 adopts the technical scheme, so that the first upright post 6 and the second upright post 2 can be stably connected, and no injury is caused to operators. The first upright 6 is provided with a pull beam connector 7 for facilitating the connection of the pull beam 5. The setting of the pull beam 5 makes the stability of the simple photovoltaic bracket better.

When the telescopic pile is specifically applied, firstly, the telescopic support is fixed on a prefabricated pile foundation, and two cross beams 1 are connected to four telescopic supports in parallel; and the pull beam 5 is obliquely connected to the first upright posts 6 of the two telescopic support posts, the longitudinal beams 3 are respectively connected between the two cross beams 1, the photovoltaic panel to be installed is inserted between the two cross beams 1, and the back of the photovoltaic panel is fixed on the longitudinal beams 3, so that the installation of one photovoltaic is completed.

Under the condition of no conflict, the technical features related to the examples can be combined with each other according to actual situations by a person skilled in the art so as to achieve corresponding technical effects, and specific details of the combination situations are not described in detail herein.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature.

While the utility model is susceptible of embodiments in accordance with the preferred embodiments, the utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein. Any simple modification, equivalent variation and modification of the above embodiments according to the technical substance of the present utility model still fall within the scope of the technical solution of the present utility model.

Claims (10)

1. A simple photovoltaic bracket, which is characterized in that: comprising

The cross beams (1), the number of the cross beams (1) is two, and the two cross beams (1) are arranged in parallel;

the longitudinal beams (3) are arranged, the longitudinal beams (3) are parallel and detachably connected between the two cross beams (1), and the longitudinal beams (3) are perpendicular to the cross beams (1);

the telescopic support columns are four, and the bottom surfaces of the two ends of each cross beam (1) are respectively connected with one telescopic support column.

2. A simplified photovoltaic module as claimed in claim 1, wherein: the cross beam (1) is an integrated structure formed by a rectangular plate and an L-shaped plate; the L-shaped plate is vertically connected to the plate surface of the rectangular plate, the axis of the L-shaped plate is parallel to the axis of the rectangular plate, and the outer side of the vertical face of the L-shaped plate is flush with the outer edge of one long side of the rectangular plate; a photovoltaic plate limit groove (11) is formed between the L-shaped plate and the rectangular plate; an upper row of longitudinal beam connecting holes (12) and a lower row of longitudinal beam connecting holes (12) are formed in the plate surface of the rectangular plate, and the longitudinal beam connecting holes (12) on the two rows are correspondingly arranged; two ends of the lower surface of the rectangular plate are fixedly connected with a node connector (13) which is detachably connected with the telescopic support.

3. A simplified photovoltaic module as claimed in claim 2, wherein: each node connector (13) comprises two semicircular plates; the plate surface of each semicircular plate is provided with a through hole for connection.

4. A simplified photovoltaic module as claimed in claim 1, wherein: the longitudinal beam (3) is of a cuboid structure, two ends of the cuboid are fixedly connected with connecting plates respectively, and the thickness of each connecting plate is smaller than that of the cuboid; the lower surface of the cuboid is coplanar with the lower surface of the connecting plate; a plurality of photovoltaic panel connecting holes (10) are uniformly formed in the surface of the cuboid; the surface of the connecting plate is provided with a beam connecting hole (9).

5. A simplified photovoltaic module as claimed in claim 1, wherein: the telescopic support comprises a second upright (2), a first upright (6) and a limiting mechanism; the second upright post (2) is detachably connected to the first upright post (6) through a limiting mechanism.

6. A simplified photovoltaic module as claimed in claim 5, wherein: the second upright post (2) is an integral structure formed by a cylinder and a cuboid-shaped second upright post connector (14); the second upright post connecting body (14) is fixedly connected to the top surface of one end of the cylinder, and the axial lead of the second upright post connecting body (14) is collinear with the axial lead of the cylinder; the surface of the second upright post connecting body (14) is provided with a through hole connected with the cross beam (1); a plurality of second upright post limiting holes (15) used for being connected with the first upright post (6) are uniformly formed in the cylinder along the axial direction; the axial lead of each second upright post limiting hole (15) is perpendicular to and intersected with the axial lead of the cylinder, and each second upright post limiting hole (15) penetrates through two opposite side surfaces of the cylinder.

7. A simplified photovoltaic module as claimed in claim 6, wherein: the thickness of cuboid is less than the diameter of cylinder, and the width of cuboid equals the diameter of cylinder.

8. A simplified photovoltaic module as claimed in claim 5, wherein: the first upright (6) consists of a hollow cylinder and a fixed plate (16); the fixed plate (16) is fixedly connected to the lower end face of the first upright post (6); the plate surface of the fixed plate (16) is provided with a through hole for fixing; the hollow cylinder is uniformly provided with a plurality of first upright post limiting holes (8) which are used for being connected with the second upright post (2) along the axial direction; the axial lead of each first upright post limiting hole (8) is perpendicular to and intersected with the axial lead of the hollow cylinder, and each first upright post limiting hole (8) penetrates through two opposite side surfaces of the hollow cylinder.

9. A simplified photovoltaic module as claimed in claim 5, wherein: the limiting mechanism comprises a limiting hoop (4) and a connecting bolt; the two limiting hoops (4) are arranged, and the two limiting hoops (4) are connected through connecting bolts.

10. A simplified photovoltaic module as claimed in claim 5, wherein: the limiting mechanism comprises a limiting hoop (4) which is an arc-shaped plate; a through hole for the passage of a connecting bolt is formed in the middle position of the circular arc plate; the upper outer side wall of the first upright post (6) is fixedly connected with a pull beam connecting body (7), and a pull beam (5) is connected between two telescopic struts connected on the same cross beam (1).