CN219436903U - Distributed photovoltaic bracket - Google Patents

Abstract

The utility model provides a distributed photovoltaic bracket, which relates to the field of photovoltaic bracket devices and comprises a bottom beam, distributed counterweight pipes and an adjusting bracket, wherein a group of bottom beams are transversely arranged, mounting holes are uniformly formed in the bottom beam, the distributed counterweight pipes are uniformly and vertically fixed on the bottom beam, sliding covers are arranged at two ends of the distributed counterweight pipes, the adjusting bracket is uniformly arranged on the bottom beam between the distributed counterweight pipes, the compatibility of a flat roof and an inclined roof is good, the service life of the roof is affected by uneven stress of the roof, and the problems of multiple labor and long construction period of the traditional cast concrete counterweight are avoided.

Description

Distributed photovoltaic bracket

Technical Field

The utility model relates to the field of photovoltaic support devices, in particular to a distributed photovoltaic support.

Background

The distributed photovoltaic bracket is usually arranged on roofs of markets, factories, residences and the like, and has the characteristics of small scale, large quantity and scattered projects. Roofing of the distributed photovoltaic bracket can be divided into: concrete flat roof, color steel tile roof and glazed tile inclined roof. The traditional distributed photovoltaic support generally uses the concrete balancing weight to promote the flood control anti-wind effect, and the atress is reliable, does not destroy the cement roof, at first in the time of the installation at the concrete roof earlier water cement foundation and use chemical anchor bolt to be connected with the concrete roof and increase its stability, install standardized fixed connection spare on the basis, install the photovoltaic support on the fixed connection spare, perhaps directly pour support together with cement foundation.

The following problems exist with conventional distributed photovoltaic brackets: firstly, a concrete balancing weight is required to be cast before installation, and the required reinforced concrete is large in quantity, more in labor and long in construction period; secondly, the compatibility of the flat roof and the inclined roof is poor, and different photovoltaic brackets are required to be used for the flat roof and the inclined roof due to different irradiation angles and different supporting structures; thirdly, the concrete balancing weight can increase the load of a single point of the roof, and the service life of the roof is affected by uneven stress of the roof. The utility model provides a distributed photovoltaic bracket.

Disclosure of Invention

In order to overcome the problems in the background art, the utility model provides the distributed photovoltaic bracket which has good compatibility to a flat roof and an inclined roof, ensures that the uniform stress of the roof affects the service life of the roof, and avoids the problems of more labor and long construction period of the traditional cast concrete balancing weight.

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

the utility model provides a distributing type photovoltaic support, includes floorbar, distributing type counter weight pipe, adjusts the support, the floorbar transversely sets up a set of, evenly has seted up the mounting hole on the floorbar, and distributing type counter weight pipe is evenly vertical to be fixed on the floorbar, and distributing type counter weight pipe both ends are provided with the sliding closure, adjust the support and evenly install on the floorbar between the distributing type counter weight pipe.

Further, the adjusting support comprises a first triangular connecting piece, a telescopic supporting rod, a rotating supporting rod and an inclined beam, the first triangular connecting piece and the telescopic supporting rod are respectively correspondingly arranged on the two bottom beams, the second triangular connecting piece is rotatably arranged at the top of the telescopic supporting rod, one end of the rotating supporting rod is rotatably connected with a rotating shaft at the bottom of the telescopic supporting rod, the third triangular connecting piece is rotatably arranged at the other end of the rotating supporting rod, one end of the inclined beam is rotatably connected with the rotating shaft on the first triangular connecting piece, and a through hole connected with the second triangular connecting piece and the third triangular connecting piece is formed in the inclined beam.

Further, the telescopic supporting rod comprises a first embedded section steel and a second U-shaped steel, the first U-shaped steel and the second U-shaped steel are fixed through holes uniformly formed in two sides, and the second triangular connecting piece is arranged on the second U-shaped steel.

Further, the bottom beam and the inclined beam are of hollow steel structures.

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

the utility model has the advantages of flexible supporting rods and rotary supporting rods, good compatibility to flat roofs and inclined roofs according to different roof adjustment angles and supporting structures, simple installation and construction process, and can be simultaneously used for concrete flat roofs, colored steel tile roofs, glazed tile inclined roofs and the like. The distributed counterweight tube enables the photovoltaic support to be uniformly weighted, so that the service life of the roof is affected by uneven stress on the roof, and meanwhile, the problems of multiple labor and long construction period of the traditional cast concrete counterweight are avoided.

Drawings

For the purpose of clearly illustrating the technical solutions in the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be described.

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

FIG. 2 is a schematic view of a color steel tile roof mounting structure of the present utility model;

FIG. 3 is a schematic view of a concrete flat roof mounting structure of the present utility model.

1-bottom beam, 11-mounting hole, 2-distributed counterweight pipe, 21-sliding cover, 3-adjusting bracket, 4-triangle connecting piece I, 5-telescopic support rod, 51-triangle connecting piece II, 52-U-shaped steel I, 53-U-shaped steel II, 6-rotation support rod, 61-triangle connecting piece III, 7-sloping beam, 71-through hole, 8-color steel tile roof, 81-clamp, 9-concrete flat roof, 91-anchor pile and 10-photovoltaic panel.

Detailed Description

In order to make the objects, technical solutions and advantageous effects of the present utility model more apparent, preferred embodiments of the present utility model will be described in detail below with reference to the accompanying drawings, so as to facilitate understanding of the skilled person.

The utility model discloses a distributed photovoltaic bracket, referring to fig. 1-3, which comprises a bottom beam 1, distributed weight pipes 2 and an adjusting bracket 3, wherein the bottom beam 1 is transversely provided with a group, mounting holes 11 are uniformly formed in the bottom beam 1, the distributed weight pipes 2 are uniformly and vertically fixed on the bottom beam 1, sliding covers 21 are arranged at two ends of the distributed weight pipes 2, and the adjusting bracket 3 is uniformly arranged on the bottom beam 1 between the distributed weight pipes 2.

The adjusting bracket 3 comprises a first triangular connecting piece 4, a telescopic supporting rod 5, a rotating supporting rod 6 and an inclined beam 7, wherein the first triangular connecting piece 4 and the telescopic supporting rod 5 are respectively and correspondingly arranged on the two bottom beams 1, the top of the telescopic supporting rod 5 is rotationally provided with a second triangular connecting piece 51, one end of the rotating supporting rod 6 is rotationally connected with a rotating shaft at the bottom of the telescopic supporting rod 5, the other end of the rotating supporting rod is rotationally provided with a third triangular connecting piece 61, one end of the inclined beam 7 is rotationally connected with the rotating shaft on the first triangular connecting piece 4, and a through hole 71 connected with the second triangular connecting piece 51 and the third triangular connecting piece 61 is formed in the inclined beam.

During installation, the roof is fixed through the bottom beam 1, if the installation roof is the color steel tile roof 8, the installation fixture 81 is fixedly connected with the roof in the installation hole 11, if the installation roof is the concrete flat roof 9, the anchor pile 91 is installed in the installation hole 11 and is fixedly connected with the roof, after the bottom beam 1 is fixed, the sliding cover 21 on the upward side of the distributed counterweight pipe 2 is opened, sand is filled for counterweight, so that the photovoltaic support uniformly applies force on the roof, meanwhile, the distributed counterweight pipes 2 with different numbers can be selectively filled according to the condition of the roof to control counterweight, the problem that the traditional casting concrete counterweight is too much and the construction period is long is flexibly and conveniently avoided. If the installation roofing is concrete flat roofing 9, adjust support 3 stable little better, adjust support 3's angle is great, can use to rotate bracing piece 6 and support sloping 7 to install on photovoltaic board 10 at sloping 7, when distributed photovoltaic support dismantles or overhauls, open the sliding closure 21 of distributed counter weight pipe 2 towards one side down, discharge the grit of counter weight, convenient dismantlement removal.

Referring to fig. 1-3, the telescopic support rod 5 comprises a first U-shaped steel 52 and a second U-shaped steel 53 which are embedded, the first U-shaped steel 52 and the second U-shaped steel 53 are fixed through holes uniformly formed in two sides, and the second triangular connecting piece 51 is installed on the second U-shaped steel 53, so that the telescopic support rod is light in structure and capable of adjusting a certain height to support the inclined beam 7.

Referring to fig. 1-3, the bottom beam 1 and the inclined beam 7 are hollow steel structures, and are convenient to install.

The working process comprises the following steps:

the distributed photovoltaic support is fixed through the roof of the bottom beam 1, if the installation roof is a color steel tile roof 8, the accessible is at anchor clamps 81 and roofing fixed connection, if the installation roof is a concrete flat roof 9, accessible anchor pile 91 and roofing fixed connection fill in the grit and carry out the counter weight in distributed counter weight pipe 2, make the even application of force of photovoltaic support in the roofing, if the installation roof is a color steel tile roof, the required angle is less, fix sloping 7 and triangle connecting piece two 51, triangle connecting piece three 61 simultaneously, install photovoltaic board 10 on sloping 7, if the installation roof is concrete flat roof 9, support sloping 7 with rotating bracing piece 6.

The foregoing description is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical solution of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (4)

1. A distributed photovoltaic bracket, characterized in that: the distributed photovoltaic support comprises a bottom beam (1), distributed weight pipes (2) and an adjusting support (3), wherein the bottom beam (1) is transversely provided with a group of mounting holes (11) uniformly formed in the bottom beam, the distributed weight pipes (2) are uniformly and vertically fixed on the bottom beam (1), sliding covers (21) are arranged at two ends of the distributed weight pipes (2), and the adjusting support (3) is uniformly arranged on the bottom beam (1) between the distributed weight pipes (2).

2. The distributed photovoltaic bracket of claim 1, wherein: the adjusting support (3) comprises a first triangular connecting piece (4), a telescopic supporting rod (5), a rotating supporting rod (6) and an inclined beam (7), the first triangular connecting piece (4) and the telescopic supporting rod (5) are respectively correspondingly arranged on the two bottom beams (1), a second triangular connecting piece (51) is rotatably arranged at the top of the telescopic supporting rod (5), one end of the rotating supporting rod (6) is rotatably connected with a rotating shaft at the bottom of the telescopic supporting rod (5), a third triangular connecting piece (61) is rotatably arranged at the other end of the rotating supporting rod, one end of the inclined beam (7) is rotatably connected with a rotating shaft on the first triangular connecting piece (4), and a through hole (71) connected with the second triangular connecting piece (51) and the third triangular connecting piece (61) is formed in the inclined beam.

3. The distributed photovoltaic bracket of claim 2, wherein: the telescopic support rod (5) comprises a first U-shaped steel (52) and a second U-shaped steel (53) which are embedded, the first U-shaped steel (52) and the second U-shaped steel (53) are fixed through holes uniformly formed in the two sides, and the second triangular connecting piece (51) is arranged on the second U-shaped steel (53).

4. The distributed photovoltaic bracket of claim 2, wherein: the bottom beam (1) and the inclined beam (7) are hollow steel structures.