CN221502466U

CN221502466U - Modularized fast-assembling type photovoltaic integrated roof

Info

Publication number: CN221502466U
Application number: CN202323261718.XU
Authority: CN
Inventors: 黄东兴; 沈洪亮; 钮水建; 王宇; 高峰; 陆琦; 廖勇
Original assignee: Zhejiang Yongli Construction Co ltd
Current assignee: Zhejiang Yongli Construction Co ltd
Priority date: 2023-11-29
Filing date: 2023-11-29
Publication date: 2024-08-09
Anticipated expiration: 2033-11-29

Abstract

The utility model adopts a modularized fast-assembled photovoltaic integrated roof, which comprises the following components: the photovoltaic panel body is at least provided with two pieces, and the two opposite sides of each piece of photovoltaic panel body are respectively provided with a convex plate and a groove, and the convex plates are spliced with the grooves; the side edges of the convex plates are provided with slots, and plugboards which are spliced with the slots are also fixedly arranged in the grooves; and a locking mechanism is arranged between two adjacent photovoltaic panel bodies and used for fixing the relative positions of the two photovoltaic panel bodies. The utility model solves the problems of low installation efficiency and troublesome disassembly and assembly of the photovoltaic panel in the prior art.

Description

Modularized fast-assembling type photovoltaic integrated roof

Technical Field

The utility model relates to the technical field of photovoltaic roofs, in particular to a modularized fast-assembled photovoltaic integrated roof.

Background

Photovoltaic is a short term of solar photovoltaic power generation system, which is a technology for converting solar energy into electric energy by utilizing photovoltaic effect, and photovoltaic power generation is greatly popularized because solar energy is renewable clean energy.

But the existing photovoltaic integrated roof is not standard in laying, and most of the photovoltaic integrated roof is fixed by adopting an aluminum alloy frame to be matched with bolts, so that the efficiency of the photovoltaic panel is low when the photovoltaic panel is laid and installed, the later disassembly and maintenance are also more troublesome, and the adjacent photovoltaic panels are unstable in connection or are connected in error, so that the photovoltaic panel can not work normally.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model provides a modularized fast-assembled photovoltaic integrated roof, which solves the problems of low installation efficiency and troublesome disassembly and assembly of a photovoltaic panel existing in the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme that the modularized fast-assembled photovoltaic integrated roof comprises:

The photovoltaic panel body is at least provided with two pieces, and the two opposite sides of each piece of photovoltaic panel body are respectively provided with a convex plate and a groove, and the convex plates are spliced with the grooves; the side edges of the convex plates are provided with slots, and plugboards which are spliced with the slots are also fixedly arranged in the grooves;

And a locking mechanism is arranged between two adjacent photovoltaic panel bodies and used for fixing the relative positions of the two photovoltaic panel bodies.

Preferably, the locking mechanism is including fixedly setting up the buckle on the photovoltaic board body, and fixedly on the flange is equipped with articulated seat, rotates on the articulated seat and is connected with the bracing piece, rotates on the bracing piece and is connected with the locking frame, and the locking frame is fixedly in the one end of keeping away from the bracing piece and is equipped with joint port, joint port and buckle joint.

Preferably, the locking mechanism further comprises a connecting shaft, the locking frame is provided with a through hole at one end far away from the supporting rod, the connecting shaft is arranged in the through hole in a sliding mode, and a buffer spring is arranged between the connecting shaft and the locking frame.

Preferably, the connecting shaft is vertically and fixedly connected with a sliding plate at one end far away from the clamping port, sliding grooves are formed in two opposite side walls of the locking frame, two ends of the sliding plate are correspondingly and slidably connected in the two sliding grooves one by one, and the buffer spring is fixedly connected with the sliding plate.

Preferably, the photovoltaic panel body is also fixedly provided with a positioning buckle, and one end of the supporting rod, which is far away from the locking frame, is rotated and clamped with the positioning buckle.

Preferably, the top of the plugboard is fixedly provided with clamping strips at two opposite ends, two clamping grooves are correspondingly formed in the inner wall of the slot, and the clamping strips are in one-to-one corresponding sliding connection with the clamping grooves.

Compared with the prior art, the utility model has the following advantages:

1. The two photovoltaic panel bodies which are adjacently arranged are respectively provided with the convex plate and the groove, when in connection, the convex plates and the grooves are inserted at first, so that the relative positions are preliminarily fixed, and meanwhile, the clamping strips on the convex plates are in sliding connection with the clamping grooves in the slots, so that the connection of the photovoltaic panel bodies is more compact; further, be equipped with locking mechanism on two piece adjacent photovoltaic board bodies, can be on recess and flange, joint piece and joint groove's basis, strengthened the stability of being connected between the photovoltaic board body, make more firm, also be convenient for the workman more to mat formation the operation, improved the laying efficiency on photovoltaic roof, easily dismantle simultaneously.

Drawings

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

FIG. 2 is an enlarged schematic view of the structure shown at A in FIG. 1;

FIG. 3 is a schematic side view of a photovoltaic panel body according to the present utility model;

Fig. 4 is a schematic side view of a locking frame according to the present utility model.

In the figure: the photovoltaic panel comprises a photovoltaic panel body 1, a slot 2, a plugboard 3, a buckle 4, a hinge seat 5, a supporting rod 6, a locking frame 7, a connecting shaft 8, a clamping port 9, a sliding plate 10, a sliding groove 11, a buffer spring 12, a positioning buckle 13, a clamping strip 14, a clamping groove 15, a groove 16 and a convex plate 17.

Detailed Description

The technical scheme of the utility model is further described below with reference to the accompanying drawings and examples.

Referring to fig. 1-4, one embodiment of the present utility model provides a modular, fast-assembled photovoltaic integrated roof, comprising:

The photovoltaic panel comprises a photovoltaic panel body 1, wherein the photovoltaic panel body 1 is at least two, convex plates 17 and grooves 16 are respectively arranged on two opposite sides of each photovoltaic panel body 1, and the convex plates 17 are spliced with the grooves 16; the side edges of the convex plates 17 are provided with slots 2, and the grooves 16 are also internally and fixedly provided with plugboards 3 which are spliced with the slots 2;

A locking mechanism is arranged between two adjacent photovoltaic panel bodies 1 and used for fixing the relative positions of the two photovoltaic panel bodies.

It should be noted that, according to the actual requirement of laying, the number of the photovoltaic panel bodies 1 can be increased, and the device only uses two adjacent photovoltaic panel bodies 1 as an example for structural description.

In specific implementation, locking mechanism is including fixedly setting up buckle 4 on photovoltaic board body 1, and fixed being equipped with articulated seat 5 on the flange 17, and the last rotation of articulated seat 5 is connected with bracing piece 6, rotates on the bracing piece 6 and is connected with locking frame 7, and locking frame 7 is fixed being equipped with joint port 9 in the one end of keeping away from bracing piece 6, joint port 9 and buckle 4 joint.

In specific implementation, the locking mechanism further comprises a connecting shaft 8, the locking frame 7 is provided with a through hole at one end far away from the supporting rod 6, the connecting shaft 8 is slidably arranged in the through hole, and a buffer spring 12 is arranged between the connecting shaft 8 and the locking frame 7.

In specific implementation, the connecting shaft 8 is vertically and fixedly connected with a slide plate 10 at one end far away from the clamping port 9, sliding grooves 11 are formed in two opposite side walls of the locking frame 7, two ends of the slide plate 10 are correspondingly and slidably connected in the two sliding grooves 11 one by one, and a buffer spring 12 is fixedly connected with the slide plate 10.

It should be noted that, two adjacent photovoltaic board bodies 1 are mutually spliced through the structures of the convex plate 17 and the groove 16, then the supporting rod 6 is manually rotated, so that the supporting rod 6 is vertical relative to the photovoltaic board body 1, the whole locking frame 7 is driven to rotate at the moment, the clamping port 9 is close to the buckle 4 and is mutually clamped with the buckle 4, then the supporting rod 6 is reversely rotated, so that the supporting rod 6 is pressed and attached to the surface of the photovoltaic board body 1, at the moment, the sliding plate 10 slides leftwards and moves to the left end of the sliding groove 11 (the left and right direction words at the position correspond to fig. 4), the buffer spring 12 is stretched, the clamping port 9 and the buckle 4 are tightly clamped, and the positions between the two photovoltaic board bodies 1 are relatively fixed.

In specific implementation, the photovoltaic panel body 1 is also fixedly provided with a positioning buckle 13, and one end of the supporting rod 6 far away from the locking frame 7 rotates to be clamped with the positioning buckle 13.

It should be noted that, the positioning buckle 13 may fix the turning angle of the support rod 6.

In specific implementation, the top of the plugboard 3 is fixedly provided with clamping strips 14 at two opposite ends, two clamping grooves 15 are correspondingly formed in the inner wall of the slot 2, and the clamping strips 14 are in one-to-one corresponding sliding connection with the clamping grooves 15.

It should be noted that, when the plugboard 3 is plugged into the slot 2, the clamping strips 14 and the clamping grooves 15 are in one-to-one sliding fit, so that the connection stability of the two photovoltaic panel bodies 1 can be increased.

The detailed working process of the utility model is as follows:

When the photovoltaic roof is paved, two adjacent photovoltaic panel bodies 1 are connected through the structures of the convex plates 17 and the grooves 16, and meanwhile, the clamping strips 14 and the clamping grooves 15 are correspondingly connected in a sliding manner one by one, so that the positions of the two photovoltaic panel bodies 1 can be primarily fixed;

Then the supporting rod 6 is rotated to an angle perpendicular to the photovoltaic panel body 1, at the moment, the locking frame 7 also rotates by taking the supporting rod 6 as a fulcrum to drive the clamping port 9 to be close to the buckle 4, the clamping port 9 is clamped with the buckle 4, the supporting rod 6 is reversely rotated to be attached to the surface of the photovoltaic panel body 1, at the moment, the buffer spring 12 is stretched, the sliding block 10 slides in the sliding groove 11 along the direction away from the buckle 4, the connection between the clamping port 9 and the buckle 4 can be tensioned, the clamping of the clamping port 9 and the buckle 4 is realized, then the supporting rod 6 is clamped into the hole of the positioning buckle 13, and the relative positions of the two photovoltaic panel bodies 1 can be fixed;

With the steps as the reference, when two photovoltaic panel bodies 1 need to be disassembled, only the supporting rods 6 need to be pulled out and rotated to be perpendicular to the photovoltaic panel bodies 1 again, the connection between the clamping ports 9 and the buckles 4 can be loosened, the clamping ports 9 can be taken down, and the two photovoltaic panel bodies 1 are separated.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims

1. A modular, ready-to-install photovoltaic integrated roof, comprising:

The photovoltaic panel comprises a photovoltaic panel body (1), wherein the photovoltaic panel body (1) is at least two, convex plates (17) and grooves (16) are respectively arranged on two opposite sides of each photovoltaic panel body (1), and the convex plates (17) are spliced with the grooves (16); the side edges of the convex plates (17) are provided with slots (2), and the grooves (16) are internally and fixedly provided with plugboards (3) which are spliced with the slots (2);

A locking mechanism is arranged between two adjacent photovoltaic panel bodies (1) and used for fixing the relative positions of the two photovoltaic panel bodies.

2. The modularized fast-assembling type photovoltaic integrated roof according to claim 1, wherein the locking mechanism comprises a buckle (4) fixedly arranged on the photovoltaic panel body (1), a hinge seat (5) is fixedly arranged on the convex plate (17), a supporting rod (6) is rotatably connected to the hinge seat (5), a locking frame (7) is rotatably connected to the supporting rod (6), a clamping port (9) is fixedly arranged at one end, far away from the supporting rod (6), of the locking frame (7), and the clamping port (9) is clamped with the buckle (4).

3. The modularized fast-assembling type photovoltaic integrated roof according to claim 2, wherein the locking mechanism further comprises a connecting shaft (8), the locking frame (7) is provided with a through hole at one end far away from the supporting rod (6), the connecting shaft (8) is slidably arranged in the through hole, and a buffer spring (12) is arranged between the connecting shaft (8) and the locking frame (7).

4. A modular fast-assembling type photovoltaic integrated roof according to claim 3, characterized in that the connecting shaft (8) is vertically and fixedly connected with a slide plate (10) at one end far away from the clamping port (9), sliding grooves (11) are respectively formed in two opposite side walls of the locking frame (7), two ends of the slide plate (10) are correspondingly and slidably connected in the two sliding grooves (11), and the buffer spring (12) is fixedly connected with the slide plate (10).

5. The modularized fast-assembling type photovoltaic integrated roof according to claim 4, wherein the photovoltaic panel body (1) is further fixedly provided with a positioning buckle (13), and one end of the supporting rod (6) far away from the locking frame (7) is rotated to be clamped with the positioning buckle (13).

6. The modularized fast-assembling type photovoltaic integrated roof according to claim 1, wherein the top of the plugboard (3) is fixedly provided with clamping bars (14) at two opposite ends, two clamping grooves (15) are correspondingly formed in the inner wall of the slot (2), and the clamping bars (14) are in one-to-one sliding connection with the clamping grooves (15).