CN220915191U - Anti-slip device for photovoltaic bracket - Google Patents

Abstract

The utility model belongs to the technical field of photovoltaic power generation, and particularly relates to an anti-slip device for a photovoltaic bracket. The photovoltaic device comprises a support and a photovoltaic plate, wherein the support comprises a support base, a support upright post and a support oblique beam which are fixedly connected with a concrete buttress, at least two pressing blocks are fixedly arranged on the photovoltaic plate, each pressing block is respectively and fixedly connected to a cross beam, and the bottom end of the cross beam is fixedly connected with the support oblique beam through bolts; at least one anti-skid block is fixedly arranged on the bracket inclined beam, and the anti-skid block is positioned below one of the cross beams and is abutted against the cross beam. Through set up the non slipping block between crossbeam and support sloping, the non slipping block can produce the deformability of restraint crossbeam top flange, can prevent effectively that photovoltaic module from following the sloping gliding, plays fine protection photovoltaic module's effect, reduces photovoltaic panel's damage, improves photovoltaic power generation efficiency.

Description

Anti-slip device for photovoltaic bracket

Technical Field

The utility model belongs to the technical field of photovoltaic power generation, and particularly relates to an anti-slip device for a photovoltaic bracket.

Background

In the existing photovoltaic power generation system, a photovoltaic panel is usually fixed on a cross beam through a pressing block, and the cross beam is arranged on a bracket oblique beam, so that the photovoltaic panel can incline to better receive sunlight, and the power generation efficiency is improved. However, because there is a gap between the photovoltaic panel and the diagonal beam at the height of the cross beam, and the cross beam is fixed only at the bottom end with the diagonal beam, there is a height difference between the center of gravity of the photovoltaic panel and the center line of the diagonal beam, and there is an eccentric moment due to the gravity effect of the height difference between the photovoltaic panel and the diagonal beam. Under the long-term load action, the eccentric moment can cause the phenomenon that the cross beam slides downwards along the oblique beam, so that the photovoltaic panel is damaged, and the benefit of photovoltaic power generation is seriously influenced.

Disclosure of utility model

In order to solve the technical problems, the utility model aims to provide the anti-slip device for the photovoltaic bracket, which has a simple structure and can improve the installation stability and the safety.

In order to achieve the technical purpose, the utility model adopts the following technical scheme: the photovoltaic support anti-slip device comprises a support and a photovoltaic plate, wherein the support comprises a support base, a support upright post and a support oblique beam which are fixedly connected with a concrete buttress, at least two pressing blocks are fixedly arranged on the photovoltaic plate, each pressing block is respectively and fixedly connected to a cross beam, and the bottom end of the cross beam is fixedly connected with the support oblique beam through bolts; at least one anti-skid block is fixedly arranged on the bracket inclined beam, and the anti-skid block is positioned below one of the cross beams and is abutted against the cross beam.

As the preferable technical scheme, the anti-skid block comprises a groove type attaching part and a retaining piece, the groove type attaching part and the retaining piece form a saddle-shaped structure, the groove type attaching part is attached to the bracket oblique beam, and the retaining piece is abutted to the cross beam.

As one of the preferable technical schemes, a fixed hole is reserved on the groove-shaped attaching part of the anti-skid block, and the anti-skid block is tightly attached and connected with the bracket oblique beam through a self-tapping screw.

As another preferable technical scheme, screw holes are reserved on the groove-shaped attaching part of the anti-skid block and the bracket oblique beam respectively, and the anti-skid block is tightly attached and connected with the bracket oblique beam through a butt-penetrating screw rod.

As an optimal technical scheme, the anti-skid block is made of stainless steel sheets.

By adopting the technical scheme, the utility model has at least the following beneficial effects:

(1) Through set up the non slipping block between crossbeam and support sloping, the non slipping block can produce the deformability of restraint crossbeam top flange, can prevent effectively that photovoltaic module from following the sloping gliding, plays fine protection photovoltaic module's effect, reduces photovoltaic panel's damage, improves photovoltaic power generation efficiency.

(2) Through the inseparable laminating of saddle shaped non-slip mass and support sloping, there is not extra part and clearance between the two, can effectively avoid the problem such as becoming flexible and corruption that probably appears, can increase its frictional force with the support sloping between, prevent to take place to slide, improve anti-skidding effect.

(3) The antiskid block comprises a groove type attaching part and a retaining piece, the groove type attaching part and the retaining piece form a saddle-shaped structure, the groove type attaching part is attached to the bracket oblique beam, the groove type attaching part of the antiskid block is tightly attached to the bracket oblique beam through a self-tapping screw or a threading screw, and the antiskid block has the advantages of being firm in fixation, convenient to assemble and disassemble, difficult to rust, free from corrosion and the like, can prolong the service life of the antiskid block and the oblique beam, and improves the stability and safety of the solar bracket.

Drawings

The following drawings are only for purposes of illustration and explanation of the present utility model and are not intended to limit the scope of the utility model. Wherein:

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

FIG. 2 is an enlarged view of a portion of FIG. 1 at I;

FIG. 3 is a schematic cross-sectional view of an anti-skid block according to an embodiment of the present utility model;

Fig. 4 is a schematic perspective view of an anti-skid block according to an embodiment of the present utility model.

Detailed Description

The utility model is further illustrated in the following, in conjunction with the accompanying drawings and examples. In the following detailed description, certain exemplary embodiments of the present utility model are described by way of illustration only. It is needless to say that the person skilled in the art realizes that the described embodiments may be modified in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive in scope.

As shown in fig. 1 and 2, the anti-slip device for a photovoltaic support comprises a support 1 and a photovoltaic panel 2, wherein the support 1 comprises a support base 11, support upright posts 12 and support diagonal beams 13, and when in installation, the support base 11 is fixedly connected with a concrete buttress 3, the support upright posts 12 are fixedly connected with the support base 11, and the support diagonal beams 13 are fixedly connected with two support upright posts 12 and a triangular connecting piece 14 positioned at the lowest point. The bracket diagonal 13 is preferably made of Q235B grade steel.

At least two pressing blocks 4 are fixedly arranged on the photovoltaic panel 2, each pressing block 4 is fixedly connected to a cross beam 5, fixing holes are respectively formed in the cross beams 5 and the bracket oblique beams 13, and the bottom ends of the cross beams 5 are fixedly connected with the bracket oblique beams 13 through bolts 6; at least one anti-skid block 7 is fixedly arranged on the bracket inclined beam 13, and the anti-skid block 7 is positioned below one of the cross beams 5 and is abutted against the cross beam 5. Through set up non slipping block 7 between crossbeam 5 and support sloping 13, non slipping block 7 can produce the deformability of restraint crossbeam 5 top flange, can prevent effectively that photovoltaic module from following the sloping gliding, plays fine protection photovoltaic module's effect, reduces photovoltaic panel's damage, improves photovoltaic power generation efficiency.

Referring to fig. 3 and 4, the anti-skid block 7 includes a slot-shaped attaching portion 71 and a retaining piece 72, and a fixing hole 73 through which the self-tapping screw passes is reserved on the slot-shaped attaching portion 71. The groove-shaped attaching part 71 and the retaining piece 72 form a saddle-shaped structure, and the anti-skid block 7 is preferably made of stainless steel sheets. Referring to fig. 2, when the bracket is mounted, the groove-shaped attaching portion 71 is attached to the bracket oblique 13, and the retaining piece 72 is abutted to the cross beam 5; the groove-shaped attaching part 71 is tightly attached and connected with the bracket oblique beam 13 through the self-tapping screw 8. Because no extra parts or gaps exist between the anti-slip block 7 and the bracket oblique beam 13, the problems of looseness, corrosion and the like which possibly occur can be effectively avoided, the friction force between the anti-slip block and the bracket oblique beam can be increased, the sliding is prevented, and the anti-slip effect is improved.

When the material of the anti-skid block 7 is different from that of the bracket oblique beam 13, or the surface treatment modes of the oblique beam are different, for example, when the surface of the oblique beam is subjected to paint spraying or galvanization and the like, the self-tapping screw fixing mode is adopted to fix more conveniently and flexibly. In the field construction process, the self-tapping screw fixing mode is used, so that the construction period can be greatly shortened, and the construction cost is reduced. The self-tapping screw fixing mode needs simpler equipment and tools, only a hand drill is needed, and large-scale mechanical equipment or other special tools are not needed. Therefore, when the anti-skid block is installed on site, the self-tapping screw fixing mode is a very economical and practical choice.

Of course, as another fixing method, the following method may be adopted: that is, screw holes are reserved on the groove-shaped attaching part 71 of the anti-skid block 7 and the bracket oblique beam 13 respectively, and when the anti-skid block is installed, only the screw holes reserved on the two members are needed to pass through by the opposite screw rods, and the anti-skid block is screwed. Such means should also fall within the scope of the present utility model.

The foregoing is illustrative of the present utility model and is not to be construed as limiting thereof. Any equivalent changes and modifications can be made by those skilled in the art without departing from the spirit and principles of this utility model, and are intended to be within the scope of this utility model.

Claims (5)

1. The utility model provides a photovoltaic support antiskid device, includes support and photovoltaic board, the support include with concrete buttress fixed connection's support base, support stand and support sloping, its characterized in that: at least two pressing blocks are fixedly arranged on the photovoltaic panel, each pressing block is fixedly connected to the cross beam, and the bottom end of the cross beam is fixedly connected with the inclined beam of the bracket through bolts; at least one anti-skid block is fixedly arranged on the bracket inclined beam, and the anti-skid block is positioned below one of the cross beams and is abutted against the cross beam.

2. The photovoltaic bracket anti-slip device of claim 1, wherein: the anti-skid block comprises a groove type attaching part and a retaining baffle plate, the groove type attaching part and the retaining baffle plate form a saddle-shaped structure, the groove type attaching part is attached to the bracket oblique beam, and the retaining baffle plate is abutted to the cross beam.

3. The photovoltaic bracket anti-slip device of claim 2, wherein: the groove type jointing part of the anti-skid block is reserved with a fixing hole, and the anti-skid block is closely jointed and connected with the bracket oblique beam through a self-tapping screw.

4. The photovoltaic bracket anti-slip device of claim 2, wherein: screw holes are reserved on the groove type attaching part of the anti-skid block and the bracket oblique beam respectively, and the anti-skid block is tightly attached and connected with the bracket oblique beam through a butt screw.

5. The photovoltaic bracket anti-slip device of any one of claims 1 to 4, wherein: the anti-skid block is made of stainless steel sheets.