CN215772987U - High-strength anti-deformation aluminum solar support - Google Patents

Abstract

The utility model discloses a high-strength anti-deformation aluminum solar support which comprises a base, wherein an adjusting assembly is movably mounted at the top of the base, a movable plate is fixedly mounted at the top of the adjusting assembly, compression-resisting assemblies are movably mounted at the top of the movable plate, supporting assemblies are movably mounted among the compression-resisting assemblies, and a limiting assembly is movably mounted at the top of the compression-resisting assemblies. According to the utility model, the compression-resistant assembly is movably arranged at the top of the movable plate, the arc-shaped buffer plate can be deformed under stress, the sliding sleeves connected with the two ends of the arc-shaped buffer plate can slide on the sliding rod, the second spring connected between the pair of sliding sleeves can further increase the buffer performance of the arc-shaped buffer plate and can also assist the arc-shaped buffer plate to reset, meanwhile, when wind power is vertically downward, the connecting rod can be used for moving to drive the sliding block in the sliding groove to move, the sliding block moves to drive the moving block to extrude the first spring, and effective buffering effect can be achieved by the acting force and the reacting force of the first spring.

Description

High-strength anti-deformation aluminum solar support

Technical Field

The utility model relates to the technical field of solar supports, in particular to a high-strength anti-deformation aluminum solar support.

Background

The unique design structure of solar rack makes the subassembly have can be according to different regions and the angularly adjustable, thereby can make full use of local solar energy resource, reach the generating efficiency of biggest solar energy subassembly, simultaneously to photovoltaic module's connected mode, material selection and support load atress analysis add detailed analysis and practice, make it have good antidetonation, anti-wind, anti-snow, resistance to compression, physical properties such as corrosion-resistant, make photovoltaic module be applied to more extensive region, wherein the performance of the solar rack of aluminium system is better, it is more extensive to use, and in the use, there are many problems or defects in current aluminium system solar rack:

traditional aluminium system solar rack does not possess the anti function of deformation of high strength in-service use for deformation or even fracture can appear after the long-time use of solar rack, influences solar rack's normal use, and solar rack can not carry out the direction regulation simultaneously, is unfavorable for improving the work efficiency of solar photovoltaic board.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a high-strength anti-deformation aluminum solar bracket to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides an anti aluminium system solar rack that deforms of high strength, includes the base, the top movable mounting of base has adjusting part, adjusting part's top fixed mounting has the fly leaf, the top movable mounting of fly leaf has the resistance to compression subassembly, movable mounting has supporting component between the resistance to compression subassembly, the top movable mounting of resistance to compression subassembly has spacing subassembly, the inside movable mounting of spacing subassembly has the solar photovoltaic board.

As a further scheme of the utility model: the resistance to compression subassembly includes the slide rail, the inside fixed mounting of slide rail has the slide bar, the surface cup joints and installs the sliding sleeve of slide bar, movable mounting has the second spring between the sliding sleeve.

As a further scheme of the utility model: the sliding rail is characterized in that a sliding groove is fixedly formed in the bottom of the sliding rail, a sliding block is movably mounted inside the sliding groove, a mounting cavity is fixedly formed in the bottom of the sliding groove, a moving block is movably mounted inside the mounting cavity, and a first spring is movably mounted on one side of the moving block.

As a further scheme of the utility model: the adjusting component comprises support columns, pulleys are fixedly mounted at the bottoms of the support columns, annular grooves are fixedly formed in the bottoms of the pulleys, a mounting frame is fixedly mounted between the support columns, threaded rods are installed inside the mounting frame in a penetrating mode, and anti-slip pads are fixedly arranged at the bottoms of the threaded rods.

As a further scheme of the utility model: the supporting component comprises an arc-shaped buffer plate, the bottom of the arc-shaped buffer plate is fixedly provided with an installation block, a stand column is movably arranged between the installation blocks, the bottom of the installation block is fixedly provided with a second connecting block, the bottom of the second connecting block is fixedly provided with a first connecting block, and a connecting rod is movably arranged between the first connecting block and the second connecting block.

As a further scheme of the utility model: the limiting assembly comprises an installation frame, limiting supports are fixedly installed on two sides of the installation frame, vertical plates are fixedly installed inside the installation frame, and horizontal plates are installed between the vertical plates in a penetrating mode.

Compared with the prior art, the utility model has the beneficial effects that: this high strength anti-deformation aluminium system solar rack has following advantage:

(1) the compression-resistant assembly is movably mounted at the top of the movable plate, the arc-shaped buffer plate can be stressed and deformed, the sliding sleeves connected with the two ends of the sliding sleeve can slide on the sliding rod, the second spring connected between the pair of sliding sleeves can further increase the buffering performance of the arc-shaped buffer plate and can also assist the arc-shaped buffer plate to reset, meanwhile, when wind power vertically faces downwards, the connecting rod can be used for moving to drive the sliding block in the sliding groove to move, the sliding block moves to drive the moving block to extrude the first spring, the effective buffering effect can be achieved by the acting force and the reacting force of the first spring, the traditional function of no high-strength deformation resistance is solved, the solar support can be deformed or even broken after being used for a long time, and the normal use of the solar support is influenced;

(2) the adjusting assembly is movably mounted at the top of the base, the anti-slip mat is driven to move upwards by rotating the threaded rod and the threaded rod, the movable plate is rotated at the same time, and the pulley is matched with the movable plate to rotate in the annular groove, so that the aim of driving the solar photovoltaic panel to adjust the direction is fulfilled, and the problems that the traditional solar bracket cannot adjust the direction and is not beneficial to improving the working efficiency of the solar photovoltaic panel are solved;

(3) have spacing subassembly through the top movable mounting at resistance to compression subassembly, can utilize the installing frame both sides all spacing support, carry on spacingly to the solar photovoltaic board, prevent solar photovoltaic board roll-off installing frame, install vertical board and horizontal plate simultaneously and provide the supporting role, the gap of vertical board and horizontal plate also is favorable to the rainwater drainage moreover to the live time of extension solar photovoltaic board.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a side view of a partial structure of the compression resistant assembly of the present invention;

FIG. 3 is a schematic top view of a portion of the spacing assembly of the present invention;

FIG. 4 is a side view of a partial structure of the support assembly of the present invention.

In the figure: 1. a solar photovoltaic panel; 2. a movable plate; 3. an adjustment assembly; 301. a support pillar; 302. a pulley; 303. a mounting frame; 304. a threaded rod; 305. a non-slip mat; 306. an annular groove; 4. a limiting component; 401. installing a frame; 402. a limiting support; 403. a vertical plate; 404. a horizontal plate; 5. a support assembly; 501. a column; 502. mounting blocks; 503. a first connection block; 504. an arc-shaped buffer plate; 505. a second connecting block; 506. a connecting rod; 6. a base; 7. a compression resistant assembly; 701. a slide rail; 702. a slide bar; 703. a chute; 704. a first spring; 705. a moving block; 706. a second spring; 707. a sliding sleeve; 708. a slider; 709. and (7) installing a cavity.

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.

Referring to fig. 1-4, an embodiment of the present invention is shown: a high-strength anti-deformation aluminum solar support comprises a base 6, an adjusting component 3 is movably mounted at the top of the base 6, the adjusting component 3 comprises support columns 301, pulleys 302 are fixedly mounted at the bottoms of the support columns 301, annular grooves 306 are fixedly formed in the bottoms of the pulleys 302, mounting frames 303 are fixedly mounted between the support columns 301, threaded rods 304 penetrate through the insides of the mounting frames 303, anti-skidding pads 305 are fixedly arranged at the bottoms of the threaded rods 304, and a movable plate 2 is fixedly mounted at the top of the adjusting component 3;

specifically, as shown in fig. 1, when the solar photovoltaic panel support is used, the adjusting assembly 3 is movably mounted at the top of the base 6, the anti-slip mat 305 is driven to move upwards by rotating the threaded rod 304 and the threaded rod 304, the movable plate 2 is rotated at the same time, and the pulley 302 is matched to rotate in the annular groove 306, so that the purpose of driving the solar photovoltaic panel 1 to adjust the direction is achieved, and the problems that the traditional solar support cannot adjust the direction and is not beneficial to improving the working efficiency of the solar photovoltaic panel 1 are solved;

the top of the movable plate 2 is movably provided with a compression-resistant assembly 7, the compression-resistant assembly 7 comprises a sliding rail 701, a sliding rod 702 is fixedly arranged inside the sliding rail 701, a sliding sleeve 707 is sleeved on the surface of the sliding rod 702, a second spring 706 is movably arranged between the sliding sleeves 707, the bottom of the sliding rail 701 is fixedly provided with a sliding groove 703, a sliding block 708 is movably arranged inside the sliding groove 703, the bottom of the sliding groove 703 is fixedly provided with a mounting cavity 709, a moving block 705 is movably arranged inside the mounting cavity 709, one side of the moving block 705 is movably provided with a first spring 704, a supporting assembly 5 is movably arranged between the compression-resistant assemblies 7, the supporting assembly 5 comprises an arc-shaped buffer plate 504, the bottom of the arc-shaped buffer plate 504 is fixedly provided with a mounting block 502, a vertical column 501 is movably arranged between the mounting blocks 502, the bottom of the mounting block 502 is fixedly provided with a second connecting block 505, and the bottom of the second connecting block 505 is fixedly provided with a first connecting block 503, a connecting rod 506 is movably arranged between the first connecting block 503 and the second connecting block 505;

specifically, as shown in fig. 2 and 4, when in use, the compression-resistant assembly 7 is movably mounted on the top of the movable plate 2, so that the arc-shaped buffer plate 504 can be deformed under stress, the sliding sleeves 707 connected with the two ends of the sliding rod can slide on the sliding rod 702, the second spring 706 connected between the pair of sliding sleeves 707 can further increase the buffering performance of the arc-shaped buffering plate 504 and can also assist the arc-shaped buffering plate 504 to reset, meanwhile, when wind power is vertical downwards, the connecting rod 506 can be used for moving to drive the sliding block 708 in the sliding groove 703 to move, the sliding block 708 moves to drive the moving block 705 to extrude the first spring 704, an effective buffering effect can be achieved by using the acting force and the reacting force of the first spring 704, the problem that the traditional wind power does not have the function of high-strength deformation resistance is solved, the solar bracket can deform or even break after being used for a long time, and the normal use of the solar bracket is influenced;

the top of the compression-resistant component 7 is movably provided with a limiting component 4, the limiting component 4 comprises an installation frame 401, two sides of the installation frame 401 are fixedly provided with limiting supports 402, a vertical plate 403 is fixedly arranged inside the installation frame 401, a horizontal plate 404 is arranged between the vertical plates 403 in a penetrating manner, and a solar photovoltaic panel 1 is movably arranged inside the limiting component 4;

specifically, as shown in fig. 1 and 3, during the use, through the top movable mounting at resistance to compression subassembly 7 there is spacing subassembly 4, can utilize installing frame 401 both sides all spacing support 402, it is spacing to solar photovoltaic board 1, prevent solar photovoltaic board 1 roll-off installing frame 401, install vertical board 403 and horizontal plate 404 simultaneously and provide the supporting role, the gap of vertical board 403 and horizontal plate 404 also is favorable to the rainwater drainage moreover to the live time of extension solar photovoltaic board 1.

The working principle is as follows: when the wind power generation device is used, firstly, the compression-resistant assembly 7 is movably mounted at the top of the movable plate 2, the arc-shaped buffer plate 504 can deform under stress, the sliding sleeves 707 connected at the two ends of the arc-shaped buffer plate can slide on the sliding rod 702, the second spring 706 connected between the pair of sliding sleeves 707 can further increase the buffer performance of the arc-shaped buffer plate 504 and can also assist the arc-shaped buffer plate 504 to reset, meanwhile, when wind power is vertically downward, the connecting rod 506 can be used for moving to drive the sliding block 708 in the sliding groove 703 to move, the sliding block 708 moves to drive the moving block 705 to extrude the first spring 704, and effective buffering can be achieved by the acting force and the reacting force of the first spring 704;

secondly, the adjusting component 3 is movably mounted at the top of the base 6, the anti-slip mat 305 is driven to move upwards by rotating the threaded rod 304 and the threaded rod 304 to move upwards, the movable plate 2 is rotated at the same time, and the pulley 302 is matched to rotate in the annular groove 306, so that the purpose of driving the solar photovoltaic panel 1 to adjust the direction is achieved;

finally, there is spacing subassembly 4 through the top movable mounting at resistance to compression subassembly 7, can utilize installing frame 401 both sides all spacing support 402, carry on spacingly to solar photovoltaic board 1, prevent solar photovoltaic board 1 roll-off installing frame 401, install vertical board 403 and horizontal plate 404 simultaneously and provide the supporting role, the gap of vertical board 403 and horizontal plate 404 also is favorable to the rainwater drainage moreover to the live time of extension solar photovoltaic board 1.

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

Claims (6)

1. The utility model provides an anti deformation aluminium system solar rack of high strength, includes base (6), its characterized in that: the top movable mounting of base (6) has adjusting part (3), the top fixed mounting of adjusting part (3) has fly leaf (2), the top movable mounting of fly leaf (2) has resistance to compression subassembly (7), movable mounting has supporting component (5) between resistance to compression subassembly (7), the top movable mounting of resistance to compression subassembly (7) has spacing subassembly (4), the inside movable mounting of spacing subassembly (4) has solar photovoltaic board (1).

2. The high strength, deformation resistant aluminum solar rack of claim 1, wherein: the compression-resistant assembly (7) comprises a sliding rail (701), a sliding rod (702) is fixedly mounted inside the sliding rail (701), a sliding sleeve (707) is sleeved on the surface of the sliding rod (702), and a second spring (706) is movably mounted between the sliding sleeve (707).

3. The high strength, deformation resistant aluminum solar rack of claim 2, wherein: the bottom of the sliding rail (701) is fixedly provided with a sliding groove (703), a sliding block (708) is movably mounted in the sliding groove (703), a mounting cavity (709) is fixedly arranged at the bottom of the sliding groove (703), a moving block (705) is movably mounted in the mounting cavity (709), and a first spring (704) is movably mounted on one side of the moving block (705).

4. The high strength, deformation resistant aluminum solar rack of claim 1, wherein: adjusting part (3) include support column (301), the bottom fixed mounting of support column (301) has pulley (302), the fixed annular groove (306) that is provided with in bottom of pulley (302), fixed mounting has mounting bracket (303) between support column (301), the inside of mounting bracket (303) is run through and is installed threaded rod (304), the fixed slipmat (305) that is provided with in bottom of threaded rod (304).

5. The high strength, deformation resistant aluminum solar rack of claim 1, wherein: support assembly (5) include arc buffer board (504), the bottom fixed mounting of arc buffer board (504) has installation piece (502), movable mounting has stand (501) between installation piece (502), the bottom fixed mounting of installation piece (502) has second connecting block (505), the bottom fixed mounting of second connecting block (505) has first connecting block (503), movable mounting has connecting rod (506) between first connecting block (503) and second connecting block (505).

6. The high strength, deformation resistant aluminum solar rack of claim 1, wherein: spacing subassembly (4) are including installing frame (401), the both sides of installing frame (401) are all fixed mounting have spacing support (402), the inside fixed mounting of installing frame (401) has vertical board (403), it installs horizontal plate (404) to run through between vertical board (403).

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