CN221263708U - Multi-row photovoltaic power generation plate fixed mounting bearing structure - Google Patents

Abstract

The utility model discloses a multi-row photovoltaic power generation plate fixed mounting bearing structure which comprises a bottom plate frame, a first adjusting structure, a second adjusting structure, a photovoltaic plate and a bearing frame, wherein the first adjusting structure and the second adjusting structure are respectively hinged to the upper wall of the bottom plate frame, the bearing frame is arranged at the upper ends of the first adjusting structure and the second adjusting structure, and the photovoltaic plate is mounted on the bearing frame; the upper end of the first adjusting structure is arranged on the lower wall of the bearing frame in a sliding way, and the lengths of the first adjusting structure and the second adjusting structure can be adjusted and fixed; the first and second adjustment structures are adjustable and fixed in angle relative to the floor frame. The utility model not only can adjust the installation angle of the photovoltaic bracket in a large range, is suitable for areas with complex terrains in the installation area, has high practicability and strong universality, but also is beneficial to accurately adjusting the light receiving angle of the photovoltaic panel, and greatly improves the photoelectric conversion efficiency.

Description

Multi-row photovoltaic power generation plate fixed mounting bearing structure

Technical Field

The utility model relates to the technical field of photovoltaic brackets, in particular to a bearing structure for fixing and installing a plurality of rows of photovoltaic power generation plates.

Background

The photovoltaic bracket is a space structure for supporting the photovoltaic solar panel, and is used for connecting the photovoltaic solar panel with the mechanical support frame and bearing dead weight load, wind load, rain and snow load and the like transmitted by the photovoltaic solar panel.

At present, the shape of the photovoltaic support is fixed and not adjustable, and the photovoltaic support is generally only suitable for being installed to level and pave the ground, or is only suitable for being installed on a roof or a slope within a certain inclination angle range, and is often not suitable for being installed in a concentrated mode in a region with winding and undulating of the ground of a topography, so that a plurality of rows of photovoltaic power generation plates are concentrated and are installed in batches to bring certain difficulty, in addition, the light receiving angle of the photovoltaic plates cannot be finely adjusted, the error of the light receiving angle is large, and the photoelectric conversion efficiency is to be improved.

In view of the foregoing, it is highly desirable to design a multi-row photovoltaic panel mounting and supporting structure to solve the foregoing problems.

Disclosure of utility model

Aiming at the technical defects, the utility model aims to provide the multi-row photovoltaic power generation plate fixed mounting bearing structure, which not only can adjust the mounting angle of the photovoltaic bracket in a large range, but also is suitable for areas with complex mounting area topography, has high practicability and strong universality, is beneficial to accurately adjusting the light receiving angle of the photovoltaic plate, and greatly improves the photoelectric conversion efficiency.

In order to solve the technical problems, the utility model adopts the following technical scheme.

The utility model provides a multi-row photovoltaic power generation plate fixed mounting bearing structure which comprises a bottom plate frame, a first adjusting structure, a second adjusting structure, a photovoltaic plate and a bearing frame, wherein the first adjusting structure and the second adjusting structure are respectively and hinged to the upper wall of the bottom plate frame, the bearing frame is arranged at the upper ends of the first adjusting structure and the second adjusting structure, and the photovoltaic plate is mounted on the bearing frame; the upper end of the second adjusting structure is fixed on the lower wall of the bearing frame, the upper end of the first adjusting structure is arranged on the lower wall of the bearing frame in a sliding manner, and the lengths of the first adjusting structure and the second adjusting structure can be adjusted and fixed; the first and second adjustment structures are adjustable and fixed in angle relative to the floor frame.

As a further description of the above technical solution:

The upper wall of the bottom plate frame is provided with two groups of connecting plates, each group of connecting plates is provided with two connecting plates, the lower end of the first adjusting structure and the lower end of the second adjusting structure are respectively connected with the two groups of connecting plates through fastening bolts, and the two fastening bolts are parallel to each other.

As a further description of the above technical solution:

The first adjusting structure comprises a first hinge plate, a first expansion plate, two sliding blocks and two sliding rails, wherein the first hinge plate is hinged to the connecting plate, the first hinge plate is hollow, the upper end of the first hinge plate is provided with an opening, the first expansion plate penetrates through the opening at the upper end of the first hinge plate and is slidably arranged in the first hinge plate, the two sliding rails are symmetrically arranged on the lower wall of the bearing frame, the sliding rails are mutually perpendicular to the fastening bolts, the two sliding blocks are respectively hinged to the upper end of the first expansion plate, and the two sliding blocks are respectively slidably arranged in the two sliding rails.

As a further description of the above technical solution:

The telescopic plate comprises a first telescopic plate body and is characterized in that a plurality of first fixing holes which are distributed at equal intervals are formed in the side wall of the first telescopic plate in the vertical direction, a first through hole which is matched with the first fixing hole is formed in the side wall of the first hinge plate body, and a first fixing bolt which can be connected with the first through hole and the first fixing hole is arranged in the first through hole.

As a further description of the above technical solution:

Two first regulating grooves are formed in the top end of the first expansion plate, a first regulating bolt is rotatably arranged on the top end of the first expansion plate, the first regulating bolt is in threaded connection with the first regulating groove, a first movable rod is rotatably arranged at the top of the first regulating bolt through a bearing, the first movable rod is identical to the first regulating bolt in axial direction, and the first movable rod is hinged to the sliding block.

As a further description of the above technical solution:

The second adjusting structure comprises a second hinge plate, a second expansion plate and two fixing blocks, wherein the second hinge plate is hinged to a group of connecting plates, the second hinge plate is hollow, the upper end of the second hinge plate is provided with an opening, the second expansion plate penetrates through the opening at the upper end of the second hinge plate and is slidably arranged in the second hinge plate, the two fixing blocks are fixed on the lower wall of the bearing frame, and the two fixing blocks are respectively hinged to the upper end of the second expansion plate.

As a further description of the above technical solution:

The second telescopic plate is characterized in that a plurality of second fixing holes which are distributed at equal intervals are formed in the side wall of the second telescopic plate in the vertical direction, a second through hole matched with the second fixing hole is formed in the side wall of the second hinge plate, and a second fixing bolt which can be connected with the second through hole and the second fixing hole is arranged in the second through hole.

As a further description of the above technical solution:

Two second regulating grooves are formed in the top end of the second expansion plate, a second regulating bolt is rotatably arranged on the top end of the second expansion plate, the second regulating bolt is in threaded connection with the second regulating groove, a second movable rod is rotatably arranged at the top of the second regulating bolt through a bearing, the second movable rod is identical to the second regulating bolt in axial direction, and the second movable rod is hinged to the fixed block.

As a further description of the above technical solution:

The two ends of the floor frame are respectively provided with a first splicing piece and a second splicing piece, the shapes and the sizes of the first splicing piece and the second splicing piece are the same, the thicknesses of the first splicing piece and the second splicing piece are half of the thickness of the floor frame, the height of the upper wall of the first splicing piece is the same as that of the upper wall of the floor frame, and the height of the lower wall of the second splicing piece is the same as that of the lower wall of the floor frame; the first splice and the second splice are provided with a plurality of mutually matched splice holes, and the two baseplate frames can be spliced into a whole through the first splice and the second splice.

The multi-row photovoltaic power generation plate fixed mounting bearing structure has the following advantages that:

1. The two ends of the first adjusting structure and the second adjusting structure are hinged with the bearing frame and the baseplate frame, the upper end of the first adjusting structure can slide on the bearing frame, and the first adjusting structure and the second adjusting structure can stretch and retract and be fixed, so that the mounting angles of the bearing frame and the baseplate frame can be adjusted in a large range, and the device is suitable for a region with a flat or inclined mounting position, high in practicability and strong in universality;

2. According to the utility model, after the first adjusting structure and the second adjusting structure are adjusted to preliminarily determine the telescopic length, the first adjusting structure and the second adjusting structure can be finely adjusted through the structures such as the first adjusting bolt, the first movable rod, the second adjusting bolt and the second movable rod, so that the light receiving angle of the photovoltaic panel can be accurately adjusted, and the photoelectric conversion efficiency is greatly improved;

3. According to the utility model, the first splicing piece and the second splicing piece are matched with each other, so that the splicing is rapid and convenient, the method is suitable for installing multiple rows of photovoltaic panels in different terrains, the installation effect is good, and the construction efficiency is high.

Drawings

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

FIG. 1 is a cross-sectional view of an embodiment of the present utility model;

FIG. 2 is a schematic diagram of the overall structure of an embodiment of the present utility model 1;

Fig. 3 is an enlarged view of a portion a in fig. 2;

fig. 4 is a schematic diagram of the overall structure of an embodiment of the present utility model 2.

Reference numerals illustrate:

1. The photovoltaic panel comprises a substrate frame, 2, a first adjusting structure, 3, a second adjusting structure, 4, a photovoltaic panel, 5, a bearing frame, 6, a connecting plate, 7, a fastening bolt, 8, a first hinge plate, 9, a first telescopic plate, 10, a sliding block, 11, a sliding rail, 12, a first fixing hole, 13, a first fixing bolt, 14, a first adjusting groove, 15, a first adjusting bolt, 16, a first movable rod, 17, a second hinge plate, 18, a second telescopic plate, 19, a fixed block, 20, a second fixing hole, 21, a second fixing bolt, 22, a second adjusting groove, 23, a second adjusting bolt, 24, a second movable rod, 25, a first splicing piece, 26 and a second splicing piece.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. 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.

Examples:

As shown in fig. 1 to 4, the utility model provides a multi-row photovoltaic power generation panel fixed mounting bearing structure, which comprises a baseplate frame 1, a first adjusting structure 2, a second adjusting structure 3, a photovoltaic panel 4 and a bearing frame 5, wherein the first adjusting structure 2 and the second adjusting structure 3 are respectively hinged on the upper wall of the baseplate frame 1, the bearing frame 5 is arranged at the upper ends of the first adjusting structure 2 and the second adjusting structure 3, and the photovoltaic panel 4 is mounted on the bearing frame 5; the upper end of the second adjusting structure 3 is fixed on the lower wall of the bearing frame 5, the upper end of the first adjusting structure 2 is slidably arranged on the lower wall of the bearing frame 5, and the lengths of the first adjusting structure 2 and the second adjusting structure 3 can be adjusted and fixed; the angle of the first and second adjustment structures 2, 3 relative to the floor frame 1 can be adjusted and fixed.

Specifically, the upper wall of the floor frame 1 is provided with four connecting plates 6, each connecting plate 6 is a group, the lower end of the first adjusting structure 2 and the lower end of the second adjusting structure 3 are respectively connected with the two groups of connecting plates 6 through fastening bolts 7, and the two fastening bolts 7 are parallel to each other.

As still further aspects of the utility model:

As shown in fig. 1, the first adjusting structure 2 includes a first hinge plate 8, a first expansion plate 9, two sliding blocks 10 and two sliding rails 11, the first hinge plate 8 is hinged on a group of connecting plates 6, a user can adjust and fix an included angle between the first hinge plate 8 and the bottom plate frame 1 by screwing a fastening bolt 7, the first hinge plate 8 is in a hollow arrangement with an open upper end, the first expansion plate 9 penetrates through the open upper end of the first hinge plate 8 and is slidably arranged in the first hinge plate 8, two sliding rails 11 are symmetrically arranged on the lower wall of the bearing frame 5, the sliding rails 11 are mutually perpendicular to the fastening bolts 7, two sliding blocks 10 are respectively hinged at the upper ends of the first expansion plate 9, and the two sliding blocks 10 are respectively slidably arranged in the two sliding rails 11.

As still further aspects of the utility model:

The side wall of the first expansion plate 9 is provided with a plurality of first fixing holes 12 which are distributed at equal intervals in the vertical direction, the side wall of the first hinge plate 8 is provided with a first through hole matched with the first fixing holes 12, and a first fixing bolt 13 which can be connected with the first through hole and the first fixing holes 12 is arranged in the first through hole.

As still further aspects of the utility model:

The top of the first expansion plate 9 is provided with a first adjusting groove 14, the top of the first expansion plate 9 is rotatably provided with a first adjusting bolt 15, the first adjusting bolt 15 is in threaded connection with the first adjusting groove 14, the top of the first adjusting bolt 15 is rotatably provided with a first movable rod 16 through a bearing, the first movable rod 16 is identical with the axial direction of the first adjusting bolt 15, and the first movable rod 16 is hinged with the sliding block 10.

As still further aspects of the utility model:

The second adjusting structure 3 comprises a second hinge plate 17, a second expansion plate 18 and two fixing blocks 19, the second hinge plate 17 is hinged on a group of connecting plates 6, the second hinge plate 17 is in a hollow arrangement with an open upper end, the second expansion plate 18 penetrates through the open upper end of the second hinge plate 17 to be slidably arranged in the second hinge plate 17, the two fixing blocks 19 are fixed on the lower wall of the bearing frame 5, and the two fixing blocks 19 are respectively hinged on the upper ends of the second expansion plates 18.

As still further aspects of the utility model:

A plurality of second fixing holes 20 which are distributed at equal intervals are formed in the side wall of the second expansion plate 18 in the vertical direction, a second through hole matched with the second fixing holes 20 is formed in the side wall of the second hinge plate 17, and a second fixing bolt 21 which can be connected with the second through hole and the second fixing holes 20 is arranged in the second through hole.

As still further aspects of the utility model:

Two second adjusting grooves 22 are formed in the top end of the second telescopic plate 18, a second adjusting bolt 23 is rotatably arranged on the top end of the second telescopic plate 18, the second adjusting bolt 23 is in threaded connection with the second adjusting groove 22, a second movable rod 24 is rotatably arranged at the top of the second adjusting bolt 23 through a bearing, the second movable rod 24 is identical to the second adjusting bolt 23 in the axial direction, and the second movable rod 24 is hinged to the fixed block 19.

In the first adjusting structure 2 and the second adjusting structure 3, when adjusting the lengths of the first adjusting structure 2 and the second adjusting structure 3 and the angles of the first adjusting structure and the second adjusting structure relative to the floor frame 1 and the photovoltaic panel 4, the sliding block 10 passively slides on the sliding rail 11, so as to ensure the stability of the structure.

Both ends of the first adjusting structure 2 and the second adjusting structure 3 are hinged with the bearing frame 5 and the baseplate frame 1, the upper end of the first adjusting structure 2 can slide on the bearing frame 5, and the first adjusting structure 2 and the second adjusting structure 3 can stretch out and draw back and fix, so that the installation angles of the bearing frame 5 and the baseplate frame 1 can be adjusted in a large range, and the device is suitable for areas with flat or inclined installation positions, high in practicability and strong in universality; after the first adjusting structure 2 and the second adjusting structure 3 are adjusted to preliminarily determine the telescopic length, the fine adjustment of the lengths of the first adjusting structure 2 and the second adjusting structure 3 can be realized through the structures of the first adjusting bolt 15, the first movable rod 16, the second adjusting bolt 23, the second movable rod 24 and the like, the precise adjustment of the light receiving angle of the photovoltaic panel 4 is facilitated, and the photoelectric conversion efficiency is greatly improved.

As still further aspects of the utility model:

The two ends of the floor frame 1 are respectively provided with a first splicing piece 25 and a second splicing piece 26, the shapes and the sizes of the first splicing piece 25 and the second splicing piece 26 are the same, the thicknesses of the first splicing piece 25 and the second splicing piece 26 are half of the thickness of the floor frame 1, the height of the upper wall of the first splicing piece 25 is the same as that of the upper wall of the floor frame 1, and the height of the lower wall of the second splicing piece 26 is the same as that of the lower wall of the floor frame 1; the first splicing piece 25 and the second splicing piece 26 are provided with a plurality of mutually matched splicing holes, and the two baseplate frames 1 can be spliced into a whole through the first splicing piece 25 and the second splicing piece 26.

As shown in fig. 2 and 4, the first splicing member 25 and the second splicing member 26 are matched with each other, so that the splicing is fast and convenient, the installation of the multi-row photovoltaic panels 4 suitable for different terrains is realized, the installation effect is good, and the construction efficiency is high.

Working principle:

The user screws the bolt 7 through construction tool, under the prerequisite of guaranteeing photovoltaic board 4 optimum light receiving angle as far as possible, the user is according to construction topography slope size, adjust the flexible volume of first expansion plate 9 in first articulated slab 8 through screwing first dead bolt 13, adjust the flexible volume of second expansion plate 18 in second articulated slab 17 through screwing second dead bolt 21, confirm the angle size between first articulated slab 8 and the second articulated slab 17 for floor frame 1, then screw fastening bolt 7, when carrying out multirow photovoltaic board 4 installation, splice through first splice 25 on floor frame 1 and the second splice 26 on adjacent floor frame 1, pass the splice hole on first splice 25 and the second splice 26 with the bolt and fix with ground.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (9)

1. The utility model provides a multirow photovoltaic power generation board fixed mounting bears structure, its characterized in that includes bottom plate frame (1), first regulation structure (2), second regulation structure (3), photovoltaic board (4) and bears frame (5), first regulation structure (2) and second regulation structure (3) articulated set up respectively in bottom plate frame (1) upper wall, bear frame (5) set up in first regulation structure (2) and second regulation structure (3) upper end, photovoltaic board (4) are installed bear frame (5); the upper end of the second adjusting structure (3) is fixed on the lower wall of the bearing frame (5), the upper end of the first adjusting structure (2) is slidably arranged on the lower wall of the bearing frame (5), and the lengths of the first adjusting structure (2) and the second adjusting structure (3) can be adjusted and fixed; the angle of the first adjusting structure (2) and the second adjusting structure (3) relative to the bottom plate frame (1) can be adjusted and fixed.

2. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 1, wherein two groups of connecting plates (6) are arranged on the upper wall of the bottom plate frame (1), two connecting plates (6) are arranged in each group, the lower ends of the first adjusting structure (2) and the lower ends of the second adjusting structure (3) are respectively connected with the two groups of connecting plates (6) through fastening bolts (7), and the two fastening bolts (7) are parallel to each other.

3. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 2, wherein the first adjusting structure (2) comprises a first hinge plate (8), a first telescopic plate (9), two sliding blocks (10) and two sliding rails (11), the first hinge plate (8) is hinged on a group of connecting plates (6), the first hinge plate (8) is in a hollow arrangement with an open upper end, the first telescopic plate (9) penetrates through the open upper end of the first hinge plate (8) and is slidably arranged in the first hinge plate (8), the two sliding rails (11) are symmetrically arranged on the lower wall of the bearing frame (5), the sliding rails (11) are mutually perpendicular to the fastening bolts (7), the two sliding blocks (10) are hinged on the upper ends of the first telescopic plate (9) respectively, and the two sliding blocks (10) are slidably arranged in the two sliding rails (11) respectively.

4. The multi-row photovoltaic power generation plate fixed mounting bearing structure according to claim 3, wherein a plurality of first fixing holes (12) which are distributed at equal intervals are formed in the side wall of the first telescopic plate (9) in the vertical direction, first through holes matched with the first fixing holes (12) are formed in the side wall of the first hinge plate (8), and first fixing bolts (13) which can be used for connecting the first through holes with the first fixing holes (12) are arranged in the first through holes.

5. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 4, wherein two first adjusting grooves (14) are formed in the top end of the first telescopic plate (9), a first adjusting bolt (15) is rotatably arranged on the top end of the first telescopic plate (9), the first adjusting bolt (15) is in threaded connection with the first adjusting groove (14), a first movable rod (16) is rotatably arranged on the top of the first adjusting bolt (15) through a bearing, the axial direction of the first movable rod (16) is the same as that of the first adjusting bolt (15), and the first movable rod (16) is hinged with the sliding block (10).

6. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 2, wherein the second adjusting structure (3) comprises a second hinge plate (17), a second telescopic plate (18) and two fixing blocks (19), the second hinge plate (17) is hinged on a group of connecting plates (6), the second hinge plate (17) is in a hollow arrangement with an open upper end, the second telescopic plate (18) penetrates through the open upper end of the second hinge plate (17) and is slidably arranged in the second hinge plate (17), the two fixing blocks (19) are fixed on the lower wall of the bearing frame (5), and the two fixing blocks (19) are respectively hinged at the upper end of the second telescopic plate (18).

7. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 6, wherein a plurality of second fixing holes (20) which are distributed at equal intervals are formed in the side wall of the second telescopic plate (18) in the vertical direction, second through holes matched with the second fixing holes (20) are formed in the side wall of the second hinge plate (17), and second fixing bolts (21) which can be used for connecting the second through holes with the second fixing holes (20) are arranged in the second through holes.

8. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 7, wherein two second adjusting grooves (22) are formed in the top end of the second telescopic plate (18), a second adjusting bolt (23) is rotatably arranged on the top end of the second telescopic plate (18), the second adjusting bolt (23) is in threaded connection with the second adjusting groove (22), a second movable rod (24) is rotatably arranged on the top of the second adjusting bolt (23) through a bearing, the axial direction of the second movable rod (24) is the same as that of the second adjusting bolt (23), and the second movable rod (24) is hinged with the fixed block (19).

9. The multi-row photovoltaic power generation panel fixed mounting bearing structure according to claim 1, wherein a first splicing piece (25) and a second splicing piece (26) are respectively arranged at two ends of the bottom plate frame (1), the first splicing piece (25) and the second splicing piece (26) are identical in shape and size, the thickness of the first splicing piece (25) and the thickness of the second splicing piece (26) are half of that of the bottom plate frame (1), the upper wall of the first splicing piece (25) is identical in height to the upper wall of the bottom plate frame (1), and the lower wall of the second splicing piece (26) is identical in height to the lower wall of the bottom plate frame (1); a plurality of mutually matched splicing holes are formed in the first splicing piece (25) and the second splicing piece (26), and the two baseplate frames (1) can be spliced into a whole through the first splicing piece (25) and the second splicing piece (26).