CN221240283U - Component mounting structure of photovoltaic building integrated system - Google Patents

Abstract

The utility model discloses a component mounting structure of a photovoltaic building integrated system, which comprises a mounting frame fixed on the top of a building layer by layer, wherein the periphery of a photovoltaic component is provided with a frame; the upper end of the mounting frame is provided with a wedge-shaped groove, the bottom end of a frame of the photovoltaic module is provided with a wedge-shaped block penetrating the wedge-shaped groove and matched with the wedge-shaped groove, and the lower part of the mounting frame is provided with a mounting groove; the guide groove that a plurality of intercommunication mounting groove has evenly been seted up to the lower part of installing frame, wears to be equipped with the dead lever in the guide groove, is provided with the fixed block on the dead lever that is located the mounting groove, has seted up the fixed slot that is used for penetrating the fixed block on penetrating the lateral wall of the frame in the mounting groove. According to the component mounting structure of the photovoltaic building integrated system, the photovoltaic component is fixed through the combination of the wedge-shaped block and the fixed block, so that the photovoltaic component is convenient to mount and dismount, bolts are not required to be used for fixing, the mounting procedure is reduced, and the mounting efficiency of the photovoltaic component is improved.

Description

Component mounting structure of photovoltaic building integrated system

Technical Field

The utility model relates to the technical field of photovoltaic buildings, in particular to a component mounting structure of a photovoltaic building integrated system.

Background

Photovoltaic power generation is a technology that uses the photovoltaic effect of a semiconductor interface to directly convert light energy into electrical energy. The solar energy power generation system mainly comprises three parts of a solar panel (assembly), a controller and an inverter, wherein the main parts are composed of electronic components. The solar cells are packaged and protected after being connected in series to form a large-area solar cell module, and then the solar cell module is matched with components such as a power controller and the like to form the photovoltaic power generation device.

Along with the continuous expansion of urban building construction, photovoltaic building integration is increasingly applied, photovoltaic power generation is combined with a building, light Fu Waan is arranged on a roof of the building, a photovoltaic module is combined with the roof of the building by utilizing a solar photoelectric conversion principle, and the conversion from solar energy to electric energy is realized.

When the existing photovoltaic tiles are installed, the supporting bracket is required to be installed on the roof, the photovoltaic tiles are installed on the supporting bracket one by one, the photovoltaic tiles are fixed through bolts, the installation process is complex, the construction period is longer, and the installation efficiency is low.

Disclosure of utility model

The utility model aims to solve the technical problem of providing a component mounting structure of a photovoltaic building integrated system, which is convenient for mounting a photovoltaic component, reduces mounting procedures and improves mounting efficiency.

In order to solve the technical problems, the technical scheme adopted by the utility model is as follows.

The component mounting structure of the photovoltaic building integrated system comprises a mounting frame which is fixed on the top of a building layer by layer and used for mounting a photovoltaic component, and a frame is wrapped on the periphery of the photovoltaic component; the upper end of the mounting frame is provided with a wedge-shaped groove, the bottom end of a frame of the photovoltaic module is provided with a wedge-shaped block penetrating the wedge-shaped groove and matched with the wedge-shaped groove, and the lower part of the mounting frame is provided with a mounting groove for penetrating the frame; the photovoltaic module fixing device is characterized in that a plurality of guide grooves communicated with the mounting grooves are uniformly formed in the lower portion of the mounting frame, fixing rods used for fixing the photovoltaic module in the mounting grooves are arranged in the guide grooves in a penetrating mode, fixing blocks are arranged on the fixing rods located in the mounting grooves, and fixing grooves used for penetrating the fixing blocks are formed in the side walls of frames penetrating the mounting grooves.

Further optimizing technical scheme, the tip of dead lever that is located the guide way outside is provided with the operation piece that is used for operating the dead lever, and the diameter of operation piece is greater than the diameter of guide way.

According to the technical scheme, the diameter of the fixed block is larger than that of the guide groove.

According to the further optimized technical scheme, a spring for supporting the fixed block is sleeved on the fixed rod between the fixed block and the inner wall of the mounting groove.

Further optimizing technical scheme, be provided with the rubber pad that is used for protecting photovoltaic module in the mounting groove.

By adopting the technical scheme, the utility model has the following technical progress.

According to the component mounting structure of the photovoltaic building integrated system, the photovoltaic component is fixed through the combination of the wedge-shaped block and the fixed block, so that the photovoltaic component is convenient to mount and dismount, bolts are not required to be used for fixing, the mounting procedure is reduced, and the mounting efficiency of the photovoltaic component is improved.

Drawings

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

Fig. 2 is a schematic structural diagram of the present utility model a.

Wherein: 1. the photovoltaic module comprises a photovoltaic module body, a frame 2, a mounting frame 3, a fixing rod 4, a wedge-shaped groove 5, a wedge-shaped block 6, a rubber pad 7, an operating block 8, a guide groove 9, a spring 10, a fixing block 11 and a fixing groove 12.

Detailed Description

The utility model will be described in further detail with reference to the drawings and the specific embodiments.

The utility model provides a subassembly mounting structure of photovoltaic building integration system, combines the fig. 1 to 2 to show, includes photovoltaic module 1 and installing frame 3, and installing frame 3 layer by layer fixes on the building roof, and photovoltaic module 1 passes through frame 2 setting on installing frame 3.

The frame 2 is wrapped on the periphery of the photovoltaic module 1, and protects the photovoltaic module 1, so that the photovoltaic module is prevented from being knocked at the edge during installation.

The upper end of the mounting frame 3 is provided with a wedge-shaped groove 5, the bottom end of a frame 2 of the photovoltaic module 1 is provided with a wedge-shaped block 6, and the wedge-shaped block 6 penetrates into the wedge-shaped groove 5 and is assembled with the wedge-shaped groove in a matched manner so as to be used for fixing the lower end of the photovoltaic module. The mounting groove is arranged at the lower part of the mounting frame 3 and used for penetrating through the frame 2 to fix the upper end of the photovoltaic module.

A plurality of guide way 9 has been seted up to the lower part of installing frame 3, and guide way 9 intercommunication mounting groove wears to be equipped with dead lever 4 in the guide way 9 for fix photovoltaic module in the mounting groove, be provided with fixed block 11 on the dead lever 4 that is located the mounting groove, has seted up fixed slot 12 on penetrating the lateral wall of frame 2 in the mounting groove, and fixed block 11 penetrates in the fixed slot 12, plays fixed effect to photovoltaic module.

The end of dead lever 4 that is located the guide way 9 outside is provided with operation piece 8, and the diameter of operation piece 8 is greater than the diameter of guide way 9, not only can be used for operating the dead lever, can also play spacing effect to the outer end of dead lever 4, prevents that the dead lever from entering into the inside of guide way 9.

The diameter of the fixed block 11 inside the mounting groove is larger than that of the guide groove 9, and the fixed block 11 is prevented from sliding out of the guide groove due to the limiting effect on the inner end of the fixed rod 4.

The spring 10 is sleeved on the fixing rod 4 between the fixing block 11 and the inner wall of the mounting groove and is used for supporting the fixing block 11, so that the fixing block 11 is positioned in the fixing groove 12 and the photovoltaic module is fixed without external force.

Be provided with rubber pad 7 in the mounting groove, play the effect of protection to photovoltaic module, at the in-process of installation, play the effect of photovoltaic module border protection through the rubber pad, at the in-process of use simultaneously, can play the effect of buffering to photovoltaic module's tiny rocking.

When the photovoltaic module is installed, one side with the wedge-shaped blocks at the bottom of the frame of the photovoltaic module is positioned below, one side with the fixing groove is positioned above, then the photovoltaic module is transversely pushed into the space between the upper installation frame and the lower installation frame, the wedge-shaped blocks at the lower end of the photovoltaic module are pushed in through the wedge-shaped grooves, the upper end of the photovoltaic module is pushed in through the installation grooves, in the pushing process, an operator is required to pull up the operation blocks outwards, the fixing rod is pulled out outwards, after the photovoltaic module is pushed in place, the operation blocks are released, and under the action of the springs, the fixing blocks extend into the fixing grooves to fix the photovoltaic module. When the photovoltaic module is disassembled, the operation block is pulled outwards, the fixing groove is released, and the photovoltaic module is pulled outwards, so that the photovoltaic module can be disassembled.

Claims (5)

1. The component mounting structure of the photovoltaic building integrated system comprises a mounting frame (3) which is fixed on the top of a building layer by layer and used for mounting a photovoltaic component (1), wherein a frame (2) is wrapped on the periphery of the photovoltaic component (1); the method is characterized in that: the upper end of the mounting frame (3) is provided with a wedge-shaped groove (5), the bottom end of one side frame (2) of the photovoltaic component (1) is provided with a wedge-shaped block (6) penetrating the wedge-shaped groove and matched with the wedge-shaped groove, and the lower part of the mounting frame (3) is provided with a mounting groove for penetrating the side frame (2); guide slots (9) communicated with the mounting slots are uniformly formed in the lower portion of the mounting frame (3), fixing rods (4) used for fixing the photovoltaic modules in the mounting slots are arranged in the guide slots (9) in a penetrating mode, fixing blocks (11) are arranged on the fixing rods (4) located in the mounting slots, and fixing slots (12) used for penetrating the fixing blocks (11) are formed in the side walls of the frames (2) penetrating the mounting slots.

2. The component mounting structure of a photovoltaic building integrated system according to claim 1, wherein: the end part of the fixed rod (4) positioned outside the guide groove (9) is provided with an operation block (8) for operating the fixed rod (4), and the diameter of the operation block (8) is larger than that of the guide groove (9).

3. The component mounting structure of a photovoltaic building integrated system according to claim 1, wherein: the diameter of the fixed block (11) is larger than that of the guide groove (9).

4. The component mounting structure of a photovoltaic building integrated system according to claim 1, wherein: a spring (10) for supporting the fixed block (11) is sleeved on the fixed rod (4) between the fixed block (11) and the inner wall of the mounting groove.

5. The component mounting structure of a photovoltaic building integrated system according to claim 1, wherein: a rubber pad (7) for protecting the photovoltaic module is arranged in the mounting groove.