CN219477894U - An auxiliary support for the installation of solar photovoltaic panels on the sea - Google Patents

Abstract

The invention relates to an auxiliary support for installing solar photovoltaic panels on the sea, belonging to the technical field of solar panel installation. The solar photovoltaic panel is installed on the top of the column, and it is characterized in that: an auxiliary bracket for assisting the installation of the solar photovoltaic panel is installed on the column, and the auxiliary bracket includes a support frame fixed on the column, and the support frame The platform includes a horizontal platform supporting beam, and a sliding platform is installed on the platform supporting beam, so that workers can flexibly and laterally transfer between multiple columns when installing solar photovoltaic panels. Advantages: greatly reduce the difficulty of installing solar photovoltaic panels, greatly improve the work efficiency of workers, and save time and effort.

Description

An auxiliary support for the installation of solar photovoltaic panels on the sea

technical field

The utility model belongs to the technical field of solar panel installation, and in particular relates to an auxiliary support for installing solar photovoltaic panels on the sea.

Background technique

Solar energy is a clean, sustainable and renewable energy source. With the continuous pollution of the earth's environment and the shortage of energy sources, solar energy has been paid more and more attention to by human beings. Solar photovoltaic panels can be seen everywhere in life, but solar photovoltaic panels have an area of The disadvantage of large and small power generation is that a large area of land is often required to install solar panels to achieve a large amount of power generation. This not only wastes land resources, but also easily causes light pollution, so offshore solar power generation came into being. Not only does offshore solar power not take up land, but it also makes remote oceans free of light pollution. Solar photovoltaic panels at sea are usually installed on the upper end of a column standing on the seabed in advance. The column is usually about 7 meters above sea level to cope with changes in sea level caused by tidal phenomena. In order to meet the needs of large-scale solar power generation, it is necessary to set There are many columns and solar photovoltaic panels. At this time, facing the columns above sea level, it is difficult to install the solar photovoltaic panels on the top of the columns. Many workers need to continuously climb, cooperate with each other, and support the lifting equipment to complete large-scale The installation work is very time-consuming and labor-intensive.

In view of the above prior art, it is necessary to reasonably improve the installation structure of the existing offshore solar photovoltaic panels. For this reason, the applicant has made a beneficial design, and the technical solution to be introduced below is produced under this background.

Utility model content

The task of the utility model is to provide an auxiliary support for installation of solar photovoltaic panels at sea, which can greatly reduce the difficulty of installing solar photovoltaic panels, greatly improve the work efficiency of workers, and save time and effort.

The task of the utility model is accomplished in this way, an auxiliary support for the installation of solar photovoltaic panels on the sea, the solar photovoltaic panel is installed on the top of the column, and the feature is: the auxiliary solar photovoltaic panel is installed on the column Auxiliary bracket installed, the auxiliary bracket includes a support frame fixed on the column, the support frame includes a horizontal platform support beam, a sliding platform is installed on the platform support beam, and the workers are installing solar photovoltaic The board can be flexibly and laterally transferred between multiple columns by means of a sliding platform.

In a specific embodiment of the present invention, a roller installation shaft is installed on the platform support beam, and a roller is rotatably arranged on the roller installation shaft, and a sliding platform is installed on the roller.

In another specific embodiment of the present invention, a plurality of roller shaft fixing seats protrude from the platform support beam, and roller installation shafts are installed between the plurality of roller shaft fixing seats, or the A plurality of roller shaft fixing seats are jointly installed with a roller installation shaft, and a plurality of rollers are rotatably arranged on the roller installation shaft.

In yet another specific embodiment of the present utility model, platform ribs are folded down on both sides of the width of the sliding platform. between sides.

In yet another specific embodiment of the present utility model, the support frame further includes a vertical platform support rod, and one end of the platform support beam is fixedly connected to one end of the platform support rod and arranged at right angles.

In yet another specific embodiment of the present utility model, the support frame further includes a reinforcement bar whose two ends are respectively connected to the platform support beam and the platform support rod.

In a further specific embodiment of the present utility model, the support frame is fixed on the column by a hoop tightened on the column, the platform support rod is welded to the hoop, and the hoop includes a The upper hoop on the upper part of the platform support rod and the lower hoop located on the lower part of the platform support rod.

In a further specific embodiment of the present utility model, a pair of symmetrical and spaced welding legs of the support rods are welded at the positions corresponding to the installation platform support rods on the upper hoop and the lower hoop, and the platform supports The bar clamp is arranged between each pair of support bar welding feet arranged up and down and fixed by welding.

In yet another specific embodiment of the present utility model, when the upright columns are installed in a row, the supporting frames on the upright columns in a row are installed in the same direction, and sliding platforms are installed on a plurality of supporting frames.

In yet another specific embodiment of the present utility model, when the uprights are installed in multiple rows, the support frames on each row of uprights are installed in the same direction, and the support between the corresponding uprights on two adjacent rows of uprights The frames are installed opposite to each other, and at least one connecting plate is connected between the sliding platforms installed on two adjacent rows of columns, thereby forming an I-shaped or ladder-shaped sliding platform assembly.

Because the utility model adopts the above-mentioned structure, it has beneficial effects: first, by using the auxiliary support, workers can use the sliding platform to transfer flexibly and horizontally between multiple columns when installing solar photovoltaic panels, without the need to climb up and down , thereby greatly reducing the difficulty of installation, saving time and effort; second, connecting plates are connected between the sliding platforms installed on two adjacent rows of columns between multiple rows of columns, thereby forming a sliding platform assembly, the sliding platform assembly It can complete the installation of solar photovoltaic panels on two rows or even multiple rows of columns, thereby greatly improving the efficiency of workers in installing solar photovoltaic panels; third, the structure is simple, easy to manufacture, with obvious auxiliary functions and high cost performance.

Description of drawings

Figure 1 is a schematic diagram of the installation of the auxiliary bracket described in the present invention.

Fig. 2 is a schematic diagram of the utility model for installing auxiliary brackets for single-row columns.

Fig. 3 is a schematic diagram of the utility model for installing auxiliary brackets for multi-row columns.

In the figure: 1. support frame, 11. platform support beam, 111. roller shaft fixing seat, 112. roller installation shaft, 113. roller, 12. platform support rod, 13. reinforcing rod; 2. hoop, 21. upper Hoop, 22. Lower hoop, 23. Welding foot of support rod; 3. Sliding platform assembly, 31. Sliding platform, 311. Platform rib, 32. Connecting plate; 10. Column.

Detailed ways

Below in conjunction with accompanying drawing, the specific embodiment of the present utility model is described in detail, but the applicant's description of the embodiment is not a limitation to the technical solution, and any change in form but not in substance according to the concept of the present utility model should be regarded as the embodiment of the utility model protected range.

In the following descriptions, all the concepts related to the directionality or orientation of up, down, left, right, front and back are based on the position shown in the corresponding drawings, so it cannot be interpreted as a reference to the present utility model. Special limitations of the technical solutions provided.

Please refer to Figure 1, the utility model relates to an auxiliary bracket for installation of solar photovoltaic panels on the sea, the solar photovoltaic panels described here are products well known to those skilled in the art, and can be installed on land or at sea. In the utility model, the installation on the sea is taken as an example, the solar photovoltaic panel is installed on the top of the column 10, and the column 10 stands on the seabed in advance.

In order to facilitate the installation of solar photovoltaic panels on the top of the column 10, the utility model proposes an auxiliary bracket, which includes a support frame 1 and a hoop 2 for installing the support frame 1 on the column 10. The support frame 1 includes Horizontal platform support beams 11, vertical platform support rods 12 and reinforcing rods 13 connecting the platform support beams 11 and platform support rods 12 at both ends. In this embodiment, the support frame 1 is triangular, and the platform support beam 11 is at right angles to the platform support bar 12. Further, one end of the platform support beam 11 and one end of the platform support bar 12 Phase fixed connection. The two ends of the reinforcing bar 13 are respectively connected to the middle part of the platform supporting beam 11 and the platform supporting bar 12. Of course, the two ends of the reinforcing bar 13 are respectively connected to the other end of the platform supporting beam 11 and the platform supporting bar 12. of.

A plurality of roller shaft fixing seats 111 are protrudingly provided on the upper plane of the platform support beam 11, and a roller installation shaft 112 is installed between the plurality of roller shaft fixing seats 111, or the plurality of roller shaft fixing seats 111 111 are jointly installed with a roller installation shaft 112, and a plurality of rollers 113 are rotatably arranged on the roller installation shaft 112.

The platform support bar 12 is welded on the hoop 2, and the hoop 2 includes an upper hoop 21 positioned on the upper part of the platform support bar 12 and a lower hoop 22 located at the lower part of the platform support bar 12. The upper hoop 21 and the lower hoop 22 are tightened on a certain height of the column 10 to realize the fixed installation of the support frame 1. A pair of symmetrical and spaced support rod welding feet 23 are welded on the upper hoop 21 and the lower hoop 22 corresponding to the positions where the platform support rod 12 is installed, and the platform support rod 12 is clamped on each pair of upper and lower support rods. Between the welding legs 23 of the support rods, welding is carried out for fixing.

As shown in Figure 2, when the columns 10 are installed in a row, the support frame 1 on the column 10 of a row is installed in the same direction, and the sliding platform 31 can be installed on the rollers 113 of a plurality of support frames 1, and the sliding The platform 31 moves smoothly under the rolling cooperation of the rollers 113 . The two sides of the width of the sliding platform 31 are folded downwards with platform ribs 311 that act as a limiter. The platform support beam 11 and the roller mounting shaft 112 and rollers 113 are embedded between the platform ribs 311 on both sides. between, to prevent the sliding platform 31 from slipping off the support frame 1. Using the auxiliary bracket, workers can flexibly and laterally transfer between multiple columns 10 by means of the sliding platform 31 when installing the solar photovoltaic panel, without climbing up and down, thereby greatly reducing the difficulty of installation.

As shown in Figure 3, when the columns 10 are installed in multiple rows, the support frames 1 on each row of columns 10 are installed in the same direction, and the support frames 1 between the corresponding columns 10 on the adjacent two rows of columns 10 are installed oppositely, so that At least one connecting plate 32 is connected between the sliding platforms 3 installed on two adjacent rows of uprights 10 , thereby forming an I-shaped or ladder-shaped sliding platform assembly 3 . In this embodiment, one connecting plate 32 is shown, and the sliding platform assembly 3 is in an I-shaped structure. In this way, compared with installing the sliding platform 31 on one side, the sliding platform assembly 3 can improve the efficiency of workers installing solar photovoltaic panels. This structure can complete the installation of solar photovoltaic panels on two rows or even multiple rows of columns 10 together.

Claims (10)

1. An auxiliary bracket for installing solar photovoltaic panels on the sea, the solar photovoltaic panel is installed on the top of the column (10), it is characterized in that: the auxiliary solar photovoltaic panel is installed on the column (10) Auxiliary support, the auxiliary support includes a support frame (1) fixed on the column (10), the support frame (1) includes a horizontal platform support beam (11), and the platform support beam A sliding platform (31) is installed on (11), and workers can flexibly and laterally transfer between multiple columns (10) by means of the sliding platform (31) when installing solar photovoltaic panels. 2. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 1, characterized in that: said platform support beam (11) is equipped with a roller installation shaft (112), and said roller installation A roller (113) is rotatably arranged on the shaft (112), and a sliding platform (31) is installed on the roller (113). 3. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 2, characterized in that: said platform support beam (11) is protruded with a plurality of roller shaft fixing seats (111), so A roller installation shaft (112) is installed between the plurality of roller shaft fixing seats (111), or a roller installation shaft (112) is installed on the plurality of roller shaft fixing seats (111), and the roller A plurality of rollers (113) are rotatably arranged on the installation shaft (112). 4. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 3, characterized in that: platform ribs (311) are folded down on both sides of the width of the sliding platform (31), and the The platform support beam (11) and the roller mounting shaft (112) on it, and the rollers (113) are embedded between the platform ribs (311) on both sides. 5. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 1, characterized in that: the support frame (1) also includes a vertical platform support rod (12), and the platform supports One end of the beam (11) is fixedly connected with one end of the platform support rod (12) and arranged at right angles. 6. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 5, characterized in that: said support frame (1) also includes two ends respectively connected to platform support beams (11) and platform support rods The reinforcing bar (13) of (12). 7. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 5, characterized in that: the support frame (1) is fixed by a hoop (2) tightened on the column (10) On the column (10), the platform support bar (12) is welded on the hoop (2), and the hoop (2) includes an upper hoop (21) on the upper part of the platform support bar (12) and a The lower hoop (22) of the platform support bar (12) bottom. 8. An auxiliary bracket for installation of offshore solar photovoltaic panels according to claim 7, characterized in that: the upper hoop (21) and the lower hoop (22) are correspondingly installed with platform support rods (12) A pair of symmetrical and spaced support rod welding feet (23) are welded at the position, and the platform support rod (12) is clamped between each pair of support rod welding feet (23) arranged up and down and fixed by welding. 9. The auxiliary support for installing solar photovoltaic panels on the sea according to claim 1, characterized in that: when the columns (10) are installed in a row, the support on the columns (10) in a row Frames (1) are installed in the same direction, and sliding platforms (31) are installed on multiple support frames (1). 10. An auxiliary bracket for installing solar photovoltaic panels on the sea according to claim 1, characterized in that: when the columns (10) are installed in multiple rows, the support frame ( 1) Installed in the same direction, the support frames (1) between the corresponding columns (10) on the two adjacent rows of columns (10) are installed facing each other, and the sliding platform (31) installed on the adjacent two rows of columns (10) At least one connecting plate (32) is connected between them, thereby forming an I-shaped or ladder-shaped sliding platform assembly (3).