CN220915205U - Split BIPV bracket system - Google Patents

Abstract

The utility model relates to a split BIPV bracket system which comprises a longitudinal water tank, a transverse water tank and pressing blocks, wherein the pressing blocks are used for being positioned in the transverse gaps of two adjacent photovoltaic modules, the longitudinal water tank is uniformly and vertically arranged on a guide rail, and the transverse water tank is arranged right below the longitudinal gaps of the two adjacent photovoltaic modules; the longitudinal water tank comprises a bottom plate, two ends of the bottom plate are respectively connected with outwards inclined side plates, the top ends of the side plates are provided with outwards bent turnover edges, and the side plates at the two ends of the bottom plate are symmetrically arranged; the water tank pressing plate comprises a top plate and a supporting plate vertically connected with two ends of the top plate, and a right-angle flanging which is bent outwards is arranged at the bottom end of the supporting plate; the top plate is provided with a left concave part and a right concave part which are concave downwards. The utility model reduces the weight of the water tank, is convenient for installation and construction, is safe and reliable, and meets the requirements of thermal expansion and cold contraction of buildings.

Description

Split BIPV bracket system

Technical Field

The utility model relates to the technical field of photovoltaic brackets, in particular to a split BIPV bracket system.

Background

BIPV, namely Building INTEGRATED PV, is a Photovoltaic Building integrated, PV, namely Photoshop. BIPV technology is a technology that integrates solar power generation (photovoltaic) products into a building. In order to facilitate drainage, the existing BIPV photovoltaic support effectively drains water permeated by the transverse gaps of the solar photovoltaic panel into the longitudinal water tank through the arrangement of the transverse water tank, and the water drained by the transverse water tank and the water permeated by the longitudinal gaps of the solar photovoltaic panel are effectively drained through the longitudinal water tank.

Many water tanks in the current market are fixed through self-tapping nails, and the risk of water leakage exists. Most bracket systems use a water tank as a stress member, and the weight of the bracket cannot be greatly reduced. Among the prior art, chinese patent CN202123350542.6 provides a photovoltaic building integration waterproof system, mainly uses vertical guiding gutter as main atress component, and the basin is heavier than photovoltaic module relatively, is not suitable for the factory building that bears the demand, and the installation is inconvenient simultaneously, and is efficient.

Disclosure of Invention

The present utility model aims to overcome the above-mentioned disadvantages and provide a split BIPV support system which reduces the weight of the BIPV support system and simplifies the installation process.

The purpose of the utility model is realized in the following way:

The split BIPV bracket system comprises a longitudinal water tank, a transverse water tank and a pressing block used for being positioned in a transverse gap of two adjacent photovoltaic modules, wherein the longitudinal water tank is uniformly and vertically arranged on a guide rail, the longitudinal water tank is arranged right below the transverse gap of the two adjacent photovoltaic modules, and a water tank pressing plate is arranged above the longitudinal water tank; the transverse water tank is arranged right below the longitudinal gaps of the two adjacent photovoltaic modules;

The longitudinal water tank comprises a bottom plate, two ends of the bottom plate are respectively connected with outwards inclined side plates, the top ends of the side plates are provided with outwards bent turnover edges, and the side plates at the two ends of the bottom plate are symmetrically arranged; the water tank pressing plate comprises a top plate and a supporting plate vertically connected with two ends of the top plate, and a right-angle flanging which is bent outwards is arranged at the bottom end of the supporting plate; the top plate is provided with a left concave part and a right concave part, so that a clamping groove is formed between the top plate and the supporting plates on two sides respectively, the clamping grooves are arranged corresponding to the turnover edges at the top ends of the side plates, and the top ends of the side plates for the longitudinal water tank extend into and are limited.

Further, the pressing block is connected to the upper side of the water tank pressing plate through a fastening piece.

Further, a waterproof cover is arranged above the pressing block.

Further, a connecting hole is formed in the right-angle turning edge of the bottom end of the supporting plate, and a self-tapping screw is inserted to fix the water tank pressing plate on the guide rail.

Further, the height of the water tank pressing plate is matched with that of the longitudinal water tank, and the folding edge of the side plate is attached to the clamping groove of the water tank pressing plate.

Further, the transverse water tank comprises a U-shaped tank body, and the top of the U-shaped tank body is provided with a right-angle flanging bent towards the same side.

Further, an adhesive tape for sealing a longitudinal gap between adjacent photovoltaic modules is arranged right above the transverse water tank.

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

The split BIPV bracket system provided by the utility model adopts the water tank pressing plate as a main stress member, and the water tank only conducts water and is not used as the main stress member, so that the weight of the split BIPV bracket system is greatly reduced, and the split BIPV bracket system is convenient to install and construct, and is safe and reliable; the water tank is fixed by adopting the water tank pressing plate, and is reliably connected with the original building structure when the thermal expansion and cold contraction of the building are met, and the installation is convenient.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic cross-sectional view of a longitudinal trough of the present utility model at a cross-section.

FIG. 3 is a schematic cross-sectional view of the transverse trough of the present utility model at a cross-section.

Fig. 4 is a schematic structural view of the longitudinal water tank of the present utility model.

Fig. 5 is a schematic structural view of the water tank pressing plate of the present utility model.

Wherein:

the solar photovoltaic module comprises a guide rail 1, a longitudinal water tank 2, a bottom plate 21, side plates 22, a water tank pressing plate 3, a top plate 31, a supporting plate 32, a clamping groove 33, a transverse water tank 4, a photovoltaic module 5, a pressing block 6, a waterproof cover 7, an adhesive tape 8, a fastening piece 9 and a self-tapping screw 10.

Description of the embodiments

In order to better understand the technical solution of the present utility model, the following detailed description will be made with reference to the accompanying drawings. It should be understood that the following embodiments are not intended to limit the embodiments of the present utility model, but are merely examples of embodiments that may be employed by the present utility model. It should be noted that, the description herein of the positional relationship of the components, such as the component a being located above the component B, is based on the description of the relative positions of the components in the drawings, and is not intended to limit the actual positional relationship of the components.

Example 1

Referring to fig. 1-5, fig. 1 depicts a schematic structural diagram of a split BIPV rack system. As shown in the figure, the split BIPV bracket system comprises a longitudinal water tank 2, a transverse water tank 4 and a pressing block 6 used for being positioned at the longitudinal gap of two adjacent photovoltaic modules 5, wherein the longitudinal water tank 2 is uniformly and vertically arranged on a guide rail 1, the longitudinal water tank 2 is arranged right below the transverse gap of the two adjacent photovoltaic modules 5, a water tank pressing plate 3 is arranged above the longitudinal water tank 2, the pressing block 6 is connected above the water tank pressing plate 3 through a fastening piece 9, the photovoltaic modules 5 are arranged above the water tank pressing plate 3, and the photovoltaic modules 5 are clamped and fixed through the water tank pressing plate 3 and the pressing block 6; a waterproof cover 7 is arranged above the pressing block 6.

The longitudinal water tank 2 comprises a bottom plate 21, two ends of the bottom plate 21 are respectively connected with outwards inclined side plates 22, the top ends of the side plates 22 are provided with outwards bent turnover edges, and the side plates 22 at the two ends of the bottom plate 21 are symmetrically arranged.

The water tank pressing plate 3 comprises a top plate 31 and a supporting plate 32 vertically connected with two ends of the top plate 31, a right-angle flanging which is bent outwards is arranged at the bottom end of the supporting plate 32, a connecting hole is arranged on the flanging, and a self-tapping screw 10 is inserted to fix the water tank pressing plate 3 on the guide rail 1; the top plate 31 is provided with a left concave recess and a right concave recess, so that a clamping groove 33 is formed between the top plate 31 and the supporting plates 32 on two sides respectively, the clamping grooves are correspondingly arranged with the turnover edges at the top ends of the side plates 22, the top ends of the side plates 22 for the longitudinal water tank 2 extend into and are limited, the height of the water tank pressing plate 3 is matched with that of the longitudinal water tank 2, the turnover edges of the side plates 22 are attached to the clamping grooves 33 of the water tank pressing plate 3, and the supporting function of the water tank pressing plate 3 is realized.

The transverse water tank 4 is arranged right below the longitudinal gap between two adjacent photovoltaic modules 5, the transverse water tank 4 comprises a U-shaped tank body, and the top of the U-shaped tank body is provided with a right-angle flanging bent towards the same side, so that limit of a ridge cover is conveniently achieved through the right-angle flanging. The photovoltaic module comprises a frame and a photovoltaic plate, and the U-shaped groove body of the transverse water tank is sleeved on the outer side of the adjacent side of the frame of the adjacent photovoltaic module, so that water seepage between the photovoltaic modules can be conveniently collected and discharged.

And an adhesive tape 8 for sealing a longitudinal gap between adjacent photovoltaic modules is arranged right above the transverse water tank 4, and the length direction of the adhesive tape 8 is parallel to the length direction of the transverse water tank.

Working principle:

The utility model provides a split BIPV bracket system, which is characterized in that a longitudinal water tank is fixed on a guide rail (purline) through a water tank pressing block and a self-tapping screw; sticking an adhesive tape on a transverse frame of the photovoltaic module, installing a transverse water tank below the photovoltaic module, pushing the module upwards tightly (enabling the adhesive tape to be in a compressed state and to be better waterproof), and fixing the module on a water tank pressing block by using a pressing block; installing the next photovoltaic module according to the steps; finally, the waterproof cover is clamped into the pressing block to play a waterproof role.

The foregoing is merely a specific application example of the present utility model, and the protection scope of the present utility model is not limited in any way. All technical schemes formed by equivalent transformation or equivalent substitution fall within the protection scope of the utility model.

Claims (7)

1.A split BIPV rack system, characterized in that: the photovoltaic module comprises a longitudinal water tank (2), a transverse water tank (4) and a pressing block (6) used for being positioned at the transverse gap of two adjacent photovoltaic modules (5), wherein the longitudinal water tank (2) is uniformly and vertically arranged on a guide rail (1), the longitudinal water tank (2) is arranged right below the transverse gap of two adjacent photovoltaic modules (5), and a water tank pressing plate (3) is arranged above the longitudinal water tank (2); the transverse water tank (4) is arranged right below the longitudinal gaps of the two adjacent photovoltaic modules (5);

The longitudinal water tank (2) comprises a bottom plate (21), two ends of the bottom plate (21) are respectively connected with outwards inclined side plates (22), the top ends of the side plates (22) are provided with outwards bent turnover edges, and the side plates (22) at the two ends of the bottom plate (21) are symmetrically arranged; the water tank pressing plate (3) comprises a top plate (31) and a supporting plate (32) vertically connected with two ends of the top plate (31), and a right-angle flanging which is bent outwards is arranged at the bottom end of the supporting plate (32); the top plate (31) is provided with a left concave recess and a right concave recess, a clamping groove (33) is respectively formed between the top plate (31) and the supporting plates (32) on two sides, the clamping grooves are correspondingly arranged with the turnover edges at the top ends of the side plates (22), and the top ends of the side plates (22) for the longitudinal water tank (2) extend into and are limited.

2. A split BIPV rack system according to claim 1, wherein: the upper part of the water tank pressing plate (3) is connected with the pressing block (6) through a fastening piece (9).

3. A split BIPV rack system according to claim 1, wherein: a waterproof cover (7) is arranged above the pressing block (6).

4. A split BIPV rack system according to claim 1, wherein: the right-angle turnup at the bottom end of the supporting plate (32) is provided with a connecting hole, and the self-tapping screw (10) is inserted to fix the water tank pressing plate (3) on the guide rail (1).

5. A split BIPV rack system according to claim 1, wherein: the height of the water tank pressing plate (3) is matched with that of the longitudinal water tank (2), and the folding edge of the side plate (22) is attached to the clamping groove (33) of the water tank pressing plate (3).

6. A split BIPV rack system according to claim 1, wherein: the transverse water tank (4) comprises a U-shaped groove body, and the top of the U-shaped groove body is provided with a right-angle flanging bent towards the same side.

7. A split BIPV rack system according to claim 1, wherein: and an adhesive tape (8) for sealing a longitudinal gap between adjacent photovoltaic modules is arranged right above the transverse water tank (4).