WO2021185252A1 - Purlin and solar tracking support frame - Google Patents

Abstract

Disclosed are a purlin and a solar tracking support frame. The purlin is installed on a photovoltaic main beam and used for installing photovoltaic panels, and comprises: two trapezoidal side plate parts, the two trapezoidal side plate parts being arranged correspondingly; a flat plate connection part, upper bottom edges of the two trapezoidal side plate parts being connected by the flat plate connection part and being located on the side facing the photovoltaic main beam; two inclined plate connection parts, corresponding oblique sides of the two trapezoidal side plate parts being respectively connected by the two inclined plate connection parts; and two installation parts, respectively connected to lower bottom edges of the trapezoidal side plate parts and extending along the arrangement direction of photovoltaic panels to install the photovoltaic panels. The structure of the present solution meets the requirements of load differentiation of the purlin in actual application and can reduce purlin production and material costs.

Description

A purlin and a solar tracking bracket Technical field

The utility model relates to the technical field of purlins for photovoltaic module installation, in particular to a purlin and a solar tracking bracket.

Background technique

Currently, photovoltaic power generation has become a trend and is widely used in various places. Photovoltaic power generation is based on the principle of photovoltaic effect to directly convert solar energy into electrical energy. Regardless of whether it is used independently or connected to the grid, the photovoltaic power generation system is mainly composed of photovoltaic modules, controllers and inverters. In order to ensure that photovoltaic modules maintain high power generation efficiency, photovoltaic tracking brackets have been developed, and photovoltaic modules need to pass through purlins. Installed on the main beam, the main beam drives the photovoltaic module to rotate with the movement of the sun through the purlin.

Most of the purlins on the photovoltaic brackets on the market adopt a few-shaped or C-shaped structure to ensure the strength of the purlins. However, in practical applications, the amount of purlins is very large, and the load requirements of the purlins are not the same for each part. When analyzing the load, the purlin receives concentrated force in the area close to the main axis, while the outermost edge receives less force. The purlin of the traditional single structure does not consider the difference in the load requirements of each part of the purlin, which wastes materials and costs too much.

Therefore, whether or not to conceive a purlin product that can accurately meet the requirements of the actual load differentiation of the purlin at various positions, and reduce the generation of purlins and the cost of materials used has always been a problem that ordinary technicians in the art expect to solve.

Utility model content

The purpose of the utility model is to provide a purlin and a solar tracking support, which can meet the requirements for the load differentiation of the purlin in actual use, and can reduce the generation and material cost of the purlin.

The technical scheme provided by the utility model is as follows:

A purlin, which is installed on the photovoltaic main beam and used to install photovoltaic panels, includes:

Two trapezoidal side plate parts, the two trapezoidal side plate parts are arranged correspondingly;

A flat plate connecting portion, the upper bottom edges of the two trapezoidal side plate portions are connected by the flat plate connecting portion, and are located on the side facing the photovoltaic main beam;

Two inclined plate connecting parts, the corresponding oblique sides of the two trapezoidal side plate parts are respectively connected by the two inclined plate connecting parts;

The two mounting parts are respectively connected with the lower bottom edge of the trapezoidal side plate part and extend along the arrangement direction of the photovoltaic panels to install the photovoltaic panels.

The purlin structure in this scheme can maintain the traditional channel steel purlin mid-section structure, reduce the channel steel depth near the two ends, significantly reduce the material used for the purlin under the premise of ensuring the load requirements of the purlin, and reduce the cost.

Further preferably, the plate connecting portion is provided with two first mounting holes.

In this solution, by providing the first mounting hole, the connecting piece can be matched with the mounting hole to connect the plate connecting portion with the main beam.

Further preferably, a second mounting hole is opened on the mounting portion.

In this solution, by providing the second mounting hole, the photovoltaic module can be installed on the mounting part.

Further preferably, both ends of the flat plate connecting portion are respectively connected to the two inclined plate connecting portions.

The flat connection part and the inclined plate connection part of this scheme are connected to form an integrated structure, which increases the overall firmness and increases the load.

Further preferably, the purlin is a stamped and integrally formed part.

This scheme adopts stamping and integral forming parts, which is convenient to manufacture and has a stable structure.

Further preferably, the two trapezoidal side plate portions are arranged parallel to each other, and the two trapezoidal side plate portions are both perpendicular to the flat plate connecting portion and the two inclined plate connecting portions.

In this scheme, the components are arranged vertically to further increase the stability of the structure and improve the load capacity of each part.

A solar tracking support, including:

A plurality of uprights, photovoltaic main beams, one of the above-mentioned purlins, and a photovoltaic module main body, wherein:

The photovoltaic main beam is installed on the top of the plurality of uprights, and the photovoltaic component main body is connected to the photovoltaic main beam through the purlin.

The main body of the photovoltaic module of this scheme is connected to the photovoltaic main beam through the purlin, which can increase the overall stability of the photovoltaic module and ensure the continuous and stable power generation of the photovoltaic module.

Further preferably, the upper end of the photovoltaic main beam and the flat plate connecting portion are vertically connected, a U-shaped clamp is fixedly connected to the flat plate connecting portion, and the photovoltaic main beam is clamped between the two. The installation part is fixedly connected with the frame of the photovoltaic module main body.

The photovoltaic modules of this scheme are firmly installed and stable in use.

Further preferably, the U-shaped clamp is a U-shaped bolt.

By setting U-shaped bolts, this solution can be directly fastened with a nut, which is easy to install and has a stable structure.

This solution has at least one of the following beneficial effects:

1. In this scheme, the two trapezoidal side plate parts are connected by the flat plate connection part and the inclined plate connection part to form a channel steel structure in the middle section, and the channel steel depth is gradually reduced to the two ends, which can meet the height of the middle section. Load requirements, low load requirements on both sides, saving materials.

2. This scheme adopts a stamping integrated forming structure, which is convenient for processing and manufacturing.

3. In this solution, mounting holes are provided on the plate connection part and the mounting part, and the installation method is flexible.

Description of the drawings

The following describes the utility model in further detail with reference to the drawings and specific implementations:

Figure 1 is a schematic diagram of the three-dimensional structure of the purlin of the utility model;

Figure 2 is a schematic diagram of the structure of the photovoltaic module of the present invention.

Attached icon number description:

1. Purlin, 11. Trapezoidal side plate part, 12. Flat plate connection part, 121. First mounting hole, 13. Inclined plate connection part, 14 Mounting part, 141. Second mounting hole, 2. Photovoltaic main beam, 3. Photovoltaic panel/photovoltaic module main body, 4. Clamp.

Detailed ways

In order to more clearly describe the technical solutions in the embodiments of the present utility model or the prior art, the following will briefly introduce the drawings that need to be used in the description of the embodiments or the prior art. Obviously, the drawings in the following description These are just some embodiments of the present invention. For those of ordinary skill in the art, other drawings can be obtained based on these drawings without creative work.

As a specific embodiment, as shown in FIGS. 1 and 2, a purlin 1 is installed on the photovoltaic main beam 2 through an installation part 4, and a photovoltaic panel 3 is installed on the top of the purlin 1. The purlin 1 includes two trapezoidal side plate parts 11, a flat plate connecting part 12, two inclined plate connecting parts 13 and two mounting parts 14. Among them, the two trapezoidal side plate portions 11 are correspondingly arranged; the upper bottom edges of the two trapezoidal side plate portions 11 are connected by a flat plate connecting portion 12 and are located on the side facing the photovoltaic main beam 2; the two trapezoidal side plate portions 11 correspond to The oblique sides are respectively connected by two oblique plate connecting portions 13; the two mounting portions 14 are respectively connected to the upper bottom edge of the trapezoidal side plate portion 11 and extend along the photovoltaic module arrangement direction to install the photovoltaic panel 3. In the actual application of purlin 1, the load requirement for the middle section is the highest, and the load requirement for the two ends is the lowest. Therefore, in this embodiment, the two trapezoidal side plate portions 11, the flat plate connecting portion 12 and the two inclined plate connecting portions 13 are connected to form a trapezoid-shaped purlin 1 structure, so that the height dimension of the middle section of the purlin 1 is the largest , The corresponding load here is also the largest. Along the direction away from the middle section, the height dimension gradually decreases, the material used decreases, and the corresponding load gradually decreases. The arrangement of this embodiment can meet the requirements for the load of the middle section of the purlin 1 to be higher than the two ends in practical applications, and the height of the two ends is small, and the most edge is not easy to open. In addition, because the height dimension of the two ends of the purlin 1 is reduced, the production materials of the purlin 1 are reduced, and a large amount of cost is saved.

So far, those of ordinary skill in the art can understand that the overall structure of the purlin 1 in this solution is actually the key invention of this solution. The purlin 1 of this scheme maintains the channel steel purlin structure of the traditional structure in the middle section to ensure the load capacity of the middle section of the purlin 1. On this basis, according to the actual load requirements of other parts of the purlin 1, the corresponding size can be customized. In this embodiment, it is preferable to adopt a linearly decreasing change in height from the middle section to the two ends, and other structures with decreasing heights such as arcs and broken lines are conventional changes by those of ordinary skill in the art.

As another embodiment, as shown in FIG. 1, the plate connecting portion 12 is provided with a first mounting hole 121, and the mounting portion 14 is provided with a second mounting hole 141. By providing the first mounting hole 121 and the second mounting hole 141, the flat panel connecting portion 12 can be connected to the photovoltaic main beam 2 and the photovoltaic panel 3 can be installed on the mounting portion 14. In this embodiment, the first mounting hole 121 and the second mounting hole 141 can cooperate with threaded connectors and the like for connection and installation. The first mounting hole 121 and the second mounting hole 141 are preferably configured as waist-shaped holes with a high degree of size adaptation.

In addition, the two ends of the flat plate connecting portion 12 are respectively connected to the two inclined plate connecting portions 13, the purlin 1 is a stamped and integrally formed part, and the two trapezoidal side plate portions 11 are arranged parallel to each other. The connecting portion 12 is perpendicular to the two inclined plate connecting portions 13. In this embodiment, the purlin 1 is integrally formed by stamping, and the adjacent parts are arranged vertically, which is convenient for processing, has good structural stability, and has strong load capacity at various parts.

This solution also has a solar tracking support, as shown in FIG. 2, which includes: a plurality of uprights (not shown in the figure), a photovoltaic main beam 2, the aforementioned purlin 1 and a photovoltaic module main body 3. Among them, the photovoltaic main beam 2 is installed on the top of a plurality of columns, and the photovoltaic module main body 3 is connected to the photovoltaic main beam 2 through the purlin 1. Specifically, the upper end of the photovoltaic main beam 2 and the flat panel connection portion 12 are vertically connected, and the U-shaped clamp 4 is fixedly connected to the flat panel connection portion 12. Specifically, the two top ends of the clamp 4 pass through the two first mounting holes 121 , And fastened by a bolt and nut structure, so that the clamp 4 hugs the photovoltaic main beam 2 so that the purlin 1 is fixed on the photovoltaic main beam 2. The mounting portion 14 is fixedly connected to the frame of the photovoltaic module main body 3. The photovoltaic module main body 3 of this scheme is connected to the photovoltaic main beam 2 through the purlin 1, which can increase the overall stability of the photovoltaic module and ensure the continuous and stable power generation of the photovoltaic module. In this embodiment, the U-shaped clamp 4 is a U-shaped bolt.

The above are only the preferred embodiments of the present utility model. It should be pointed out that for those of ordinary skill in the art, without departing from the principle of the present utility model, several improvements and modifications can be made. These improvements and Retouching should also be regarded as the protection scope of this utility model.

Claims (9)

A purlin is installed on a photovoltaic main beam for installing photovoltaic panels, and is characterized in that it includes: Two trapezoidal side plate parts, the two trapezoidal side plate parts are arranged correspondingly; A flat plate connecting portion, the upper bottom edges of the two trapezoidal side plate portions are connected by the flat plate connecting portion and are located on the side facing the photovoltaic main beam; Two inclined plate connecting parts, the corresponding oblique sides of the two trapezoidal side plate parts are respectively connected by the two inclined plate connecting parts; The two mounting parts are respectively connected with the lower bottom edge of the trapezoidal side plate part and extend along the arrangement direction of the photovoltaic panels to install the photovoltaic panels. The purlin according to claim 1, wherein the plate connecting portion is provided with two first mounting holes. The purlin according to claim 1, wherein a second mounting hole is opened in the mounting portion. The purlin according to claim 1, wherein the two ends of the flat plate connecting portion are respectively connected to the two inclined plate connecting portions. The purlin according to claim 4, characterized in that, the purlin is a stamped and integrally formed part. A purlin according to any one of claims 1-5, wherein the two trapezoidal side plate portions are arranged parallel to each other, and the two trapezoidal side plate portions are connected to the flat plate connecting portion and the two The connecting part of the inclined plate is vertical. A solar tracking support, which is characterized in that it comprises: A plurality of uprights, a photovoltaic main beam, a purlin according to claims 1-6, and a photovoltaic module main body, wherein: The photovoltaic main beam is installed on the top of the plurality of uprights, and the photovoltaic component main body is connected to the photovoltaic main beam through the purlin. The solar tracking bracket according to claim 7, wherein the upper end of the photovoltaic main beam is connected to the flat panel connection part, and the U-shaped clamp is fixedly connected to the flat panel connection part to connect the photovoltaic The main beam is clamped between the two, and the mounting part is fixedly connected with the frame of the photovoltaic module main body. The solar tracking bracket according to claim 8, wherein the U-shaped clamp is a U-shaped bolt.

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