CN219627627U - High-performance photovoltaic support supporting structure - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic power generation, in particular to a high-performance photovoltaic support supporting structure, which comprises a fixed bottom plate, wherein a transverse plate mechanism which is convenient for a solar panel to receive light is arranged on the fixed bottom plate, the transverse plate mechanism comprises two movable plates, two supporting enclosing frames and a solar panel supporting frame, the two movable plates are respectively positioned at the upper end parts of the fixed bottom plate, the supporting enclosing frames are positioned above the fixed bottom plate, two supporting plates are fixedly arranged between the supporting enclosing frames and the fixed bottom plate, at least two retaining grooves are formed in the end parts of two sides of the inner side wall of the supporting enclosing frame, and the number of the solar panel supporting frames is at least two. According to the solar panel support frame, the driving motor is matched with the threaded rod, and the threaded rod is driven to rotate by starting the driving motor, so that each solar panel support frame is driven to be adjusted, manual adjustment is not needed, manpower is saved, the adjusting efficiency is high, and the practicability is high.

Description

High-performance photovoltaic support supporting structure

Technical Field

The utility model relates to the technical field of photovoltaic power generation, in particular to a high-performance photovoltaic bracket supporting structure.

Background

Solar photovoltaic systems, also known as photovoltaic, for short, refer to facilities that utilize the photovoltaic effect of photovoltaic semiconductor materials to convert solar energy into direct current electrical energy. At the heart of the photovoltaic installation is a solar panel.

The existing photovoltaic support has the following defects when in use, in the use of the existing photovoltaic support, the angle of the support can be singly adjusted, the adjustment of a photovoltaic array of a large photovoltaic power station is extremely difficult, the efficiency is low, and the light receiving efficiency of a solar panel is affected.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides a high-performance photovoltaic bracket supporting structure.

In order to solve the technical problems, the utility model provides the following technical scheme: the utility model provides a high performance photovoltaic support bearing structure, includes PMKD, be equipped with the diaphragm mechanism of being convenient for solar panel light-receiving on the PMKD, diaphragm mechanism includes fly leaf, support and encloses frame and solar panel support frame, the quantity of fly leaf is two, two the fly leaf all is located PMKD's upper end, the support encloses the frame and is located PMKD's top, fixed mounting has two backup pads between frame and the PMKD is enclosed in the support, the support encloses the both sides tip of frame inside wall and has seted up two at least fender grooves, the quantity of solar panel support frame is two at least, every the equal fixed mounting in both sides tip of solar panel support frame has the pivot, every the equal rotation of pivot installs the inside wall in fender groove, two rectangle spouts have been seted up to PMKD's upper end, two equal fixed mounting has the slide bar in the inside wall of rectangle spout, two the side tip has all run through the screw thread groove, two the both sides tip of rectangle spout inside wall has the equal fixed mounting in motor, and two equal fixed mounting screw thread groove has the equal both sides of each side of drive post.

As a preferable technical scheme of the utility model, the side end part of each connecting block is provided with a connecting rod, and the side end part of each connecting rod is provided with two hole slots in a penetrating way.

As a preferable technical scheme of the utility model, each movable column is rotatably arranged in a hole groove on the upper side of the connecting rod, and each fixed column is rotatably arranged in a hole groove on the lower side of the connecting rod.

Compared with the prior art, the utility model has the following beneficial effects:

1. the device is matched with the solar panel support frames, the connecting rods and the fixing columns, and can drive the plurality of solar panel support frames to adjust angles simultaneously, so that the device can adjust according to the angles of the sun, the light receiving power generation efficiency is guaranteed, and the adjustment is convenient.

2. This device cooperatees through having set up driving motor and threaded rod, drives the threaded rod through starting driving motor and rotates to drive every solar panel support frame and adjust, need not the manpower and adjust, use manpower sparingly, adjustment efficiency is high, and the practicality is higher.

Drawings

FIG. 1 is a schematic view of a structure of a fixing base plate of the present utility model;

FIG. 2 is a schematic diagram of a driving motor according to the present utility model;

FIG. 3 is a schematic view of the structure of the movable plate of the present utility model;

fig. 4 is a schematic structural view of the solar panel support frame of the present utility model.

Wherein: 1. a fixed bottom plate; 11. rectangular sliding grooves; 12. a cylindrical groove; 13. a driving motor; 14. a threaded rod; 2. a movable plate; 21. a slide bar; 22. a thread groove; 23. fixing the column; 40. supporting the surrounding frame; 41. a blocking groove; 42. a support plate; 5. a solar panel support; 51. a rotating shaft; 52. a connecting block; 53. a movable column; 54. a connecting rod; 55. and a hole groove.

Detailed Description

In order that the manner in which the above recited features, objects and advantages of the present utility model are obtained will become readily apparent, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Based on the examples in the embodiments, those skilled in the art can obtain other examples without making any inventive effort, which fall within the scope of the utility model. The experimental methods in the following examples are conventional methods unless otherwise specified, and materials, reagents, etc. used in the following examples are commercially available unless otherwise specified.

As shown in fig. 1, fig. 2, fig. 3 and fig. 4, a high-performance photovoltaic support structure comprises a fixed bottom plate 1, a transverse plate mechanism which is convenient for light receiving of a solar panel is arranged on the fixed bottom plate 1, the transverse plate mechanism comprises two movable plates 2, a supporting enclosing frame 40 and a solar panel support frame 5, the number of the movable plates 2 is two, the two movable plates 2 are all positioned at the upper end part of the fixed bottom plate 1, the supporting enclosing frame 40 is positioned above the fixed bottom plate 1, two support plates 42 are fixedly arranged between the supporting enclosing frame 40 and the fixed bottom plate 1, at least two baffle grooves 41 are formed at two side end parts of the inner side wall of the supporting enclosing frame 40, at least two side end parts of the solar panel support frame 5 are fixedly provided with rotating shafts 51, each rotating shaft 51 is rotatably arranged at the inner side wall of the baffle grooves 41, two rectangular sliding grooves 11 are formed at the upper end parts of the fixed bottom plate 1, the lower end parts of the two movable plates 2 are fixedly arranged with sliding bars 21, the two sliding bars 21 are slidably arranged at the inner side walls of the rectangular sliding grooves 11, along with the change of seasons, the irradiation angles of sunlight can always change at all right angles, a right angle of a user can drive a threaded rod 13 to rotate by a threaded rod 13 through a threaded rod 13, and the threaded rod 13 is driven by a threaded rod 13, and the threaded rod 13 can be driven by a driver and can rotate by a driver through the threaded rod 13;

the side end parts of the two sliding rods 21 are respectively provided with a threaded groove 22 in a penetrating way, the side end parts of the inner side walls of the two rectangular sliding grooves 11 are respectively provided with a cylindrical groove 12 in a penetrating way, the inner side walls of each two cylindrical grooves 12 are respectively provided with a connecting rod 14 in a rotating way, the two threaded rods 14 are respectively provided with a driving motor 13 in a penetrating way in the inner side walls of the two threaded grooves 22 in a rotating way, the side end parts of the two threaded rods 14 are respectively fixedly provided with a driving motor 13, the two driving motors 13 are respectively fixedly provided with a side end part of a fixed bottom plate 1, the side end parts of each movable plate 2 are respectively fixedly provided with at least two fixed columns 23, the lower end part of each solar plate support frame 5 is respectively fixedly provided with two connecting blocks 52, the side end parts of each connecting block 52 are respectively fixedly provided with a movable column 53, the side end parts of each connecting block 52 are respectively provided with a connecting rod 54, the side end parts of the connecting rod 54 are respectively provided with two hole grooves 55 in a penetrating way, each movable column 53 is rotatably installed in a hole slot 55 above the connecting rod 54, each fixed column 23 is rotatably installed in a hole slot 55 below the connecting rod 54, the movable plate 2 moves to drive each fixed column 23 to move, each fixed column 23 is located in each hole slot 55 below, each connecting rod 54 is driven to move and rotate by the movement of the fixed column 23 through the hole slot 55, the connecting rod 54 moves to drive the movable column 53 to move downwards, the movable column 53 moves downwards to drive the connecting block 52 to move downwards, the connecting block 52 moves downwards to drive one side of the solar panel support 5 to move downwards, at the moment, the solar panel support 5 rotates around the rotating shaft 51 as a circle center, the angle of the solar panel support 5 is changed, and after the solar panel support 5 is adjusted to a proper position, a user can switch off the driving motor 13.

Working principle:

with the change of seasons, the irradiation angle of sunlight is always changed, a user can adjust the angle of each solar panel support frame 5 according to the irradiation angle of the sun, the user can start the driving motor 13, the driving motor 13 starts to drive the threaded rod 14 to rotate, the threaded rod 14 rotates to drive the sliding rod 21 to slide in the rectangular sliding groove 11 towards one side against the driving motor 13 through the thread groove 22, the movable plate 2 moves to drive each fixed column 23 to move, each fixed column 23 is positioned in each hole groove 55 positioned below, the fixed column 23 moves to drive each connecting rod 54 to move and rotate through the hole groove 55, the connecting rod 54 moves to drive the movable column 53 to move downwards, the movable column 53 moves downwards to drive the connecting block 52 to move downwards, the connecting block 52 moves downwards to drive one side of the solar panel support frame 5 to move downwards, at the moment, the solar panel support frame 5 rotates around the rotating shaft 51 as the center of circle, the angle of the solar panel support frame 5 is changed, after the solar panel support frame 5 is adjusted to a proper position, a user can close the driving motor 13, in the use of the existing photovoltaic support frame, a plurality of photovoltaic arrays of a large photovoltaic power station can be singly adjusted for the angle of the support frame, the adjustment is extremely difficult, the efficiency is very low, the light receiving efficiency of the solar panel is influenced, the device can simultaneously drive a plurality of solar panel support frames 5 to adjust the angle by arranging the solar panel support frames 5, connecting rods 54 and fixing columns 23 to match, the device can adjust the angle according to the sun angle, the light receiving power generation efficiency is ensured, the adjustment is convenient, the device drives the threaded rods 14 to rotate by starting the driving motor 13 so as to drive each solar panel support frame 5 to adjust without manual adjustment, the manpower is saved, the regulating efficiency is high, and the practicality is higher.

The embodiments of the present utility model have been described in detail with reference to the drawings, but the present utility model is not limited thereto, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present utility model.

Claims (6)

1. The high-performance photovoltaic bracket supporting structure comprises a fixed bottom plate (1), and is characterized in that a transverse plate mechanism which is convenient for a solar panel to receive light is arranged on the fixed bottom plate (1);

the utility model provides a solar panel support frame, including fly leaf (2), support and enclose frame (40) and solar panel support frame (5), the quantity of fly leaf (2) is two, two fly leaf (2) all are located the upper end of PMKD (1), support and enclose frame (40) are located the top of PMKD (1), support and enclose between frame (40) and PMKD (1) fixed mounting have two backup pads (42), support and enclose the both sides tip of frame (40) inside wall and seted up two at least fender grooves (41), the quantity of solar panel support frame (5) is two at least, every the both sides tip of solar panel support frame (5) is equal fixed mounting have pivot (51), every pivot (51) are all rotated the inside wall of installing in fender groove (41).

2. The high-performance photovoltaic bracket supporting structure according to claim 1, wherein two rectangular sliding grooves (11) are formed in the upper end portion of the fixed bottom plate (1), sliding rods (21) are fixedly mounted at the lower end portions of the two movable plates (2), the two sliding rods (21) are slidably mounted on the inner side walls of the rectangular sliding grooves (11), and threaded grooves (22) are formed in the side end portions of the two sliding rods (21) in a penetrating mode.

3. The high-performance photovoltaic bracket supporting structure according to claim 2, wherein two side ends of the inner side walls of the rectangular sliding grooves (11) are respectively provided with a cylindrical groove (12) in a penetrating mode, each two inner side walls of the cylindrical grooves (12) are respectively provided with a threaded rod (14) in a rotating mode, each threaded rod (14) is respectively provided with an inner side wall of each threaded groove (22) in a penetrating and rotating mode, each side end of each threaded rod (14) is respectively provided with a driving motor (13) in a fixed mode, each driving motor (13) is respectively provided with a side end of a fixed bottom plate (1), and each side end of each movable plate (2) is respectively provided with at least two fixed columns (23).

4. A high performance photovoltaic bracket support structure according to claim 3, characterized in that two connection blocks (52) are fixedly mounted at the lower end of each solar panel support frame (5), and movable posts (53) are fixedly mounted at the side ends of each connection block (52).

5. The high-performance photovoltaic bracket supporting structure according to claim 4, wherein each connecting block (52) is provided with a connecting rod (54) at a side end, and two hole slots (55) are formed in the side end of each connecting rod (54) in a penetrating manner.

6. The high-performance photovoltaic bracket supporting structure according to claim 5, wherein each movable column (53) is rotatably mounted in a hole groove (55) of the connecting rod (54) located above, and each fixed column (23) is rotatably mounted in a hole groove (55) of the connecting rod (54) located below.