CN220139451U - Full-capacity flexible solar photovoltaic bracket - Google Patents

Abstract

The full-capacity flexible solar photovoltaic bracket comprises side uprights, a middle upright, a base plate, side girders, a middle girder, a triangular truss, an upper chord cable, a lower chord cable and diagonal lacing wires; the side stand columns are vertically arranged at two side edges of the full-capacity flexible solar photovoltaic support, the middle stand columns are vertically arranged at the middle parts of the transverse directions of the side stand columns at two sides, the triangular trusses are uniformly distributed and vertically arranged between the middle stand columns and the side stand columns, the upper corners of the triangular trusses are pulled by the upper chord ropes, the lower chord ropes are pulled by the lower corners of the triangular trusses, the triangular trusses are fixed in the upper space between the middle stand columns and the side stand columns after the inclined angle of the triangular trusses pulls the inclined lacing wires, the bottom surfaces of the base plates are fixed at the tops of the triangular trusses, and the solar photovoltaic modules are paved on the base plates after the installation is completed. Under the condition of not influencing structural stability, the steel structure material consumption and cost can be reduced, the construction difficulty is reduced, the mounting labor time is reduced, the steel structure is widely applicable to terrains, the structure is simple and flexible to mount, and no influence is caused on crop planting and fishery cultivation.

Description

Full-capacity flexible solar photovoltaic bracket

Technical Field

The utility model relates to the field of photovoltaic power generation assemblies, in particular to a full-capacity flexible solar photovoltaic bracket.

Background

Photovoltaic power generation is a technology that uses the photovoltaic effect of a semiconductor interface to directly convert light energy into electrical energy.

However, the use condition has certain limitations, such as small energy distribution density of irradiation, namely, large occupied area; the obtained energy is related to weather conditions such as four seasons, day and night, yin and Qing. Therefore, in order to make more full use of the irradiation space, people can install and use the solar photovoltaic module in sewage treatment plants, mountains with complicated topography, roofs with lower bearing, forest light complementary places, water light complementary places, operation places and the like, but the span and the height of the larger places are limited, so that the traditional support structure cannot be installed, and even the support installed and used in places with small areas in the past can have the defects of more steel consumption, limitation on installation places and the like.

In view of the above, the present inventors have made intensive studies to solve the above-mentioned drawbacks of the prior art.

Disclosure of Invention

In order to solve the technical problems, the full-capacity flexible solar photovoltaic bracket is provided, the consumption and cost of steel structure materials can be reduced under the condition that the structural stability is not affected, the safety is high, the construction difficulty is reduced, the installation labor time and cost are reduced, the full-capacity flexible solar photovoltaic bracket is wide in adaptation terrain, simple in structure and flexible in installation, and no influence is caused on crop planting and fishery cultivation.

In order to achieve the above purpose, the technical scheme of the utility model is as follows:

a full-capacity flexible solar photovoltaic bracket comprises side uprights, a middle upright, a base plate, side girders, a middle girder, a triangular truss, an upper chord, a lower chord and diagonal lacing wires; the side upright posts and the middle upright posts are made of H-shaped steel, the side beams and the middle beams are made of square steel, and the upper chord rope, the lower chord rope and the diagonal lacing wire are made of steel cables; the side stand columns are vertically arranged at two side edges of the full-capacity flexible solar photovoltaic support, the middle stand columns are vertically arranged at the middle parts of the transverse directions of the side stand columns at two sides, the side beams are transversely arranged at the side edges of the top of the full-capacity flexible solar photovoltaic support, the middle beams are transversely arranged at the middle parts of the top of the full-capacity flexible solar photovoltaic support, the triangular trusses are uniformly distributed and vertically arranged between the middle stand columns and the side stand columns, the triangular trusses are fixedly pulled between the middle stand columns and the side stand columns in the upper space through upper chord ropes at the upper corners of the triangular trusses, the lower chord ropes fixedly pulled between the middle stand columns and the side stand columns in the upper space at the lower corners of the triangular trusses, diagonal lacing wires fixedly pull the triangular trusses in the upper space between the middle stand columns and the side stand columns at the bevel angles of the triangular trusses, the bottom surfaces of the bottom plates are fixedly arranged at the tops of the triangular trusses, and the solar photovoltaic modules are paved on the bottom plates after the installation is completed.

Preferably, the two side edges of the full-capacity flexible solar photovoltaic bracket are longitudinally provided with component edge presses, and a middle pressure component is longitudinally arranged in the middle between the two side edge press components.

Preferably, the steel wire rope buckles are fixedly arranged at the tops of the side stand columns, concrete fixing piles are buried underground outside the side stand columns, fixing buckles are arranged at the tops of the concrete fixing piles, and inhaul cable steel wires are connected between the steel wire rope buckles at the tops of the side stand columns and the fixing buckles at the tops of the concrete fixing piles.

Preferably, the three corners of the triangular truss are provided with lock catches.

Through the technical scheme, the utility model has the following beneficial effects:

(1) The main structure of the photovoltaic support adopts the H-shaped steel upright post, the square pipe main beam and the steel cable are main steel structures, so that the steel consumption is reduced, the structure is simple, the installation time is shortened, and the safety is improved.

(2) The application scope is extensive, can use in large-span areas such as valley, thereby increase the generated energy through reducing sunshine and shelter from, and the support height of this scheme is high, and the span is big, does not influence crops and plants and the fishery is bred.

(3) The full-capacity flexible solar photovoltaic bracket can greatly utilize land resources and air resources under the condition of not damaging the original ecological environment, can realize full-capacity installation in planned land, saves land space and protects mountain vegetation.

(4) The main component is mainly a steel cable, and the large wind speed can be resisted without too much engineering machinery vehicle during installation, and the support can swing back and forth under the condition of snowy weather blowing because of the flexible steel cable, so that the snow can obviously drop, and the snow can not generate large precipitation and backlog conditions for the photovoltaic module.

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 side view of a full capacity flexible solar photovoltaic support disclosed in an embodiment of the present utility model;

FIG. 2 is a top view of a full capacity flexible solar photovoltaic support according to an embodiment of the present utility model after mounting a solar photovoltaic module;

fig. 3 is a schematic diagram of a connection structure of a triangular truss in a full-capacity flexible solar photovoltaic bracket according to an embodiment of the present utility model.

Corresponding part names indicated by numerals in the drawings:

1. side column 2, center column 3, backing plate 4, side beam 5, center beam 6, triangular truss 7, upper chord rope 8, lower chord rope 9, diagonal lacing 10, solar photovoltaic module 11, side pressure module 12, medium pressure module 13, steel wire rope buckle 14, concrete fixing pile 15, fixing buckle 16, guy rope 17, lock buckle

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.

The present utility model will be described in further detail with reference to examples and embodiments.

Examples.

As shown in fig. 1, 2 and 3, a full-capacity flexible solar photovoltaic bracket comprises side uprights 1, a middle upright 2, a base plate 3, side girders 4, a middle girder 5, a triangular truss 6, an upper chord 7, a lower chord 8 and diagonal lacing wires 9; the side upright posts 1 and the middle upright posts 2 are made of H-shaped steel, the side beams 4 and the middle beams 5 are made of square steel, and the upper chord rope 7, the lower chord rope 8 and the diagonal lacing wire 9 are made of steel cables; the side stand column 1 is vertically arranged at two side edges of the full-capacity flexible solar photovoltaic support, the middle stand column 2 is vertically arranged at the middle part of the two side stand columns 1 in the transverse direction, the side beams 4 are horizontally arranged at the side edges of the top of the full-capacity flexible solar photovoltaic support, the middle beams 5 are horizontally arranged at the middle part of the top of the full-capacity flexible solar photovoltaic support, the triangular trusses 6 are uniformly distributed and vertically arranged between the middle stand column 2 and the side stand columns 1, the triangular trusses 6 are fixedly pulled in the upper space between the middle stand column 2 and the side stand columns 1 at the upper corners of the triangular trusses 6 through upper chords 7, the lower chords 8 fixedly pull the triangular trusses 6 in the upper space between the middle stand column 2 and the side stand columns 1 at the lower corners of the triangular trusses 6, the diagonal lacing bars 9 fixedly pull the triangular trusses 6 in the upper space between the middle stand column 2 and the side stand columns 1 at the bevel angles of the triangular trusses 6, the bottom surfaces of the base plates 3 are fixedly arranged at the tops of the triangular trusses 6, and the solar photovoltaic modules 10 are paved on the base plates 3 after installation is completed.

In order to further fix the full-capacity flexible solar photovoltaic support from the upper side of the full-capacity flexible solar photovoltaic support, component side presses 11 are longitudinally arranged on two side edges of the full-capacity flexible solar photovoltaic support, and a middle pressure component 12 is longitudinally arranged in the middle of the two side pressing components 11.

Simultaneously, wire rope knot 13 has been set firmly at limit stand 1 top, and limit stand 1 outside underground has buried concrete pile 14, and concrete pile 14 top is equipped with the fixed knot 15, be connected with cable wire rope 16 between limit stand 1 top wire rope knot 13 and the fixed knot 15 in concrete pile 14 top.

In addition, the three corners of the triangular truss 6 are respectively provided with a lock catch 17, so that the upper chord rope 7, the lower chord rope 8 and the diagonal lacing 9 are conveniently fixed through the lock catches 17 when being connected with the triangular truss 6.

In the embodiment, the full-capacity flexible solar photovoltaic bracket comprises side columns 1, a middle column 2, a base plate 3, side beams 4, a middle beam 5, a triangular truss 6, an upper chord rope 7, a lower chord rope 8, diagonal lacing wires 9 and other parts; the side columns 1 are vertically arranged at two side edges of the full-capacity flexible solar photovoltaic support, the middle columns 2 are vertically arranged at the middle positions of the two side columns 1 in the transverse direction, the triangular trusses 6 are uniformly distributed and vertically arranged between the middle columns 2 and the side columns 1, the triangular trusses 6 are fixedly pulled in an upper space between the middle columns 2 and the side columns 1 at upper corners of the triangular trusses 6 through upper chords 7, the lower chords 8 fixedly pulled in an upper space between the middle columns 2 and the side columns 1 at lower corners of the triangular trusses 6, diagonal lacing wires 9 fixedly pulled in an upper space between the middle columns 2 and the side columns 1 at the oblique angles of the triangular trusses 6, the bottom surfaces of the base plates 3 are fixed at the tops of the triangular trusses 6, and solar photovoltaic modules 10 are paved on the base plates 3 after installation is completed.

The full-capacity flexible solar photovoltaic bracket adopts a mode of stretching a prestressed steel strand between two fixed points, and the two fixed points adopt a rigid foundation to provide counter force, so that a large distance of 10-50 m can be realized. The full-capacity flexible solar photovoltaic bracket is arranged between mountain bodies, so that mountain vegetation can be effectively protected, the bracket belongs to a flexible steel cable as a main material, has obvious unloading effect on external load, can resist larger wind speed at present, has no damage effect on a photovoltaic module, and has certain snow pressure bearing capacity.

In practical application, the method has the following advantages:

(1) The main structure of the photovoltaic support adopts the H-shaped steel upright post, the square pipe main beam and the steel cable are main steel structures, so that the steel consumption is reduced, the structure is simple, the installation time is shortened, and the safety is improved.

(2) The solar energy power generation device has wide application range, can be used in large-span areas such as valleys and the like, and can increase the generated energy by reducing sunlight shielding.

(3) The bracket of the scheme has high height and large span, and does not influence crop planting and fishery cultivation.

(4) The full-capacity flexible solar photovoltaic bracket can greatly utilize land resources and air resources under the condition of not damaging the original ecological environment, can realize full-capacity installation in planned land, saves land space and protects mountain vegetation.

(5) The main component is mainly a steel cable, and too many engineering machinery vehicles are not needed during installation.

(6) The device can resist larger wind speed, and the support can swing back and forth under the condition of snowy sky wind blowing because the device belongs to a flexible steel cable, so that the device can play a remarkable falling phenomenon on snow, and the snow can not generate larger precipitation and backlog conditions on the photovoltaic module. The purposes of novel design, reasonable structure and good application effect are achieved.

The foregoing is merely a preferred embodiment of a full-capacity flexible solar photovoltaic support of this utility model, and it should be noted that modifications and improvements can be made by those skilled in the art without departing from the inventive concept, which falls within the scope of this utility model.

Claims (4)

1. The full-capacity flexible solar photovoltaic bracket is characterized by comprising side uprights, middle uprights, base plates, side girders, middle girders, triangular trusses, upper chord ropes, lower chord ropes and diagonal lacing wires; the side upright posts and the middle upright posts are made of H-shaped steel, the side beams and the middle beams are made of square steel, and the upper chord rope, the lower chord rope and the diagonal lacing wire are made of steel cables; the side stand columns are vertically arranged at two side edges of the full-capacity flexible solar photovoltaic support, the middle stand columns are vertically arranged at the middle parts of the transverse directions of the side stand columns at two sides, the side beams are transversely arranged at the side edges of the top of the full-capacity flexible solar photovoltaic support, the middle beams are transversely arranged at the middle parts of the top of the full-capacity flexible solar photovoltaic support, the triangular trusses are uniformly distributed and vertically arranged between the middle stand columns and the side stand columns, the triangular trusses are fixedly pulled between the middle stand columns and the side stand columns in the upper space through upper chord ropes at the upper corners of the triangular trusses, the lower chord ropes fixedly pulled between the middle stand columns and the side stand columns in the upper space at the lower corners of the triangular trusses, diagonal lacing wires fixedly pull the triangular trusses in the upper space between the middle stand columns and the side stand columns at the bevel angles of the triangular trusses, the bottom surfaces of the bottom plates are fixedly arranged at the tops of the triangular trusses, and the solar photovoltaic modules are paved on the bottom plates after the installation is completed.

2. The full-capacity flexible solar photovoltaic bracket according to claim 1, wherein component side presses are further arranged on two side edges of the full-capacity flexible solar photovoltaic bracket longitudinally, and a middle pressure component is further arranged in the middle between the two side press components longitudinally.

3. The full-capacity flexible solar photovoltaic bracket according to claim 2, wherein the steel wire rope buckle is fixedly arranged at the top of the side stand column, the concrete fixing pile is buried underground outside the side stand column, the fixing buckle is arranged at the top of the concrete fixing pile, and a guy rope is connected between the steel wire rope buckle at the top of the side stand column and the fixing buckle at the top of the concrete fixing pile.

4. A full capacity flexible solar photovoltaic support according to claim 3, wherein three corners of said triangular truss are provided with catches.