CN218492890U - Photovoltaic bicycle shed component mounting structure - Google Patents

Abstract

The utility model provides a photovoltaic bicycle shed subassembly mounting structure, include: the photovoltaic module is sequentially arranged in a plurality of rows on two sides of a gutter at the top of the photovoltaic car shed, a gap is formed between every two adjacent photovoltaic modules in each row, and the waterproof adhesive tape is clamped in the gap between every two adjacent photovoltaic modules in each row so as to enable the two adjacent photovoltaic modules in each row to be connected in a sealing mode; and a water guiding groove is arranged between every two adjacent rows of photovoltaic modules along the extending direction of the gutter, and the tail end of the water guiding groove is communicated with the gutter so as to guide the rainwater carried by the photovoltaic modules to the gutter. This photovoltaic bicycle shed subassembly mounting structure compares with current photovoltaic module horizontal dress structure, has cancelled horizontal guiding gutter, has adopted vertical guiding gutter mode, can unify the gutter at direction bicycle shed center with the rainwater, and set up waterproof stripe between photovoltaic module's horizontal gap, avoids the rainwater seepage, and this mounting structure has promoted the stability of photovoltaic bicycle shed effectively, and by a wide margin reduction installation cost.

Description

Photovoltaic bicycle shed component mounting structure

Technical Field

The utility model relates to a photovoltaic module installs technical field, especially relates to a photovoltaic bicycle shed subassembly mounting structure.

Background

At present, the existing photovoltaic car shed component generally adopts a horizontal installation mode (as shown in fig. 1), and a waterproof structure is composed of a horizontal and a vertical bidirectional water guiding grooves, and the waterproof and water guiding strategies are as follows: most of rainwater falling on the photovoltaic module flows into the gutter from top to bottom through the surface of the light plate or directly disperses water in the module, a small part of rainwater permeates into a joint between the modules and flows into the transverse water chute and the longitudinal water chute below the module, water in the transverse water chute finally converges into the longitudinal water chute, and finally converges into the gutter from the longitudinal water chute or is directly discharged to the ground.

However, as the size of the surface of the photovoltaic module is increased, the fixing form of the transverse short edge of the module is more and more restricted by the size of the module, and the short edge fixing has adverse effect on the stress of the photovoltaic module; but if only change the subassembly mounting means and do not change horizontal indulge the guiding gutter, can lead to waterproof structure cost to increase, be unfavorable for the popularization of photovoltaic bicycle shed.

SUMMERY OF THE UTILITY MODEL

The utility model provides a photovoltaic bicycle shed subassembly mounting structure for reduce the installation cost when promoting photovoltaic module installation stability, photovoltaic bicycle shed subassembly mounting structure includes photovoltaic bicycle shed, photovoltaic module, guiding gutter and waterproof stripe, wherein:

the photovoltaic modules are arranged on two sides of a gutter at the top of the photovoltaic shed in sequence, and a gap is formed between every two adjacent photovoltaic modules; the waterproof adhesive tape is clamped in a gap between every two adjacent photovoltaic assemblies in each row so as to enable the two adjacent photovoltaic assemblies in each row to be connected in a sealing mode; and one water guide groove is arranged between every two adjacent rows of photovoltaic modules and communicated with the gutter so as to guide rainwater borne by the photovoltaic modules to the gutter.

In a specific implementation, the short side of each photovoltaic module is arranged facing the gutter.

In specific implementation, the water chute is vertically lapped above the purline at the top of the photovoltaic car shed through the mounting seat.

In the specific implementation, the cross section of the water chute is arranged in an inverted-V shape, two sides are provided with turned edges; the mounting seat is L-shaped, and the top of the mounting seat is provided with a turned edge matched with the water chute; the mounting seats are respectively arranged on two sides of the lap joint of the water chute and the purline, the top of each mounting seat is clamped in the turned edge of the water chute, and the bottom of each mounting seat is connected to the purline in a fitting manner so as to fix the relative position of the water chute and the purline.

In specific implementation, the mounting seat is fixedly connected with the water chute and the purline through a first connecting piece.

In a specific implementation, the first connecting piece is a self-tapping screw.

In specific implementation, the gutter is arranged at the lower part of the symmetrical position of the photovoltaic bicycle shed, and the edge of the photovoltaic module is lapped in the frame of the photovoltaic module.

In specific implementation, the water chute is fixedly connected with the bottom of the photovoltaic assembly frame and the top of the mounting seat through a second connecting piece.

In specific implementation, the second connecting piece is connected by a bolt.

In specific implementation, the waterproof rubber strip is a foamed silica gel waterproof rubber strip.

The utility model provides a photovoltaic bicycle shed subassembly mounting structure, include: the photovoltaic module is sequentially arranged in a plurality of rows on two sides of a gutter at the top of the photovoltaic car shed, a gap is formed between every two adjacent photovoltaic modules in each row, and the waterproof adhesive tape is clamped in the gap between every two adjacent photovoltaic modules in each row so as to enable the two adjacent photovoltaic modules in each row to be connected in a sealing mode; and a water chute is arranged between every two adjacent rows of photovoltaic modules along the extending direction of the gutter, and the tail end of the water chute is communicated with the gutter so as to guide rainwater borne by the photovoltaic modules to the gutter. This photovoltaic bicycle shed subassembly mounting structure compares with current photovoltaic module horizontal dress structure, has cancelled horizontal guiding gutter, has adopted vertical guiding gutter mode, can unify the gutter at direction bicycle shed center with the rainwater, and set up waterproof stripe between photovoltaic module's horizontal gap, avoids the rainwater seepage, and this mounting structure has promoted the stability of photovoltaic bicycle shed effectively, and by a wide margin reduction installation cost.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without inventive efforts. In the drawings:

fig. 1 is a schematic view of a cross-mounted structure of a photovoltaic shed assembly according to an embodiment of the present invention;

fig. 2 is a schematic perspective view of a photovoltaic carport assembly mounting structure according to an embodiment of the present invention;

fig. 3 is a schematic view of a transverse node of a photovoltaic carport assembly mounting structure in accordance with an embodiment of the present invention;

fig. 4 is a schematic longitudinal node view of a photovoltaic carport assembly mounting structure in accordance with an embodiment of the present invention;

fig. 5 is a schematic perspective view of a water chute according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. The exemplary embodiments and descriptions of the present invention are provided to explain the present invention, but not to limit the present invention.

As shown in fig. 2, the utility model provides a photovoltaic bicycle shed component mounting structure for reduce the installation cost when promoting photovoltaic module 200 installation stability, photovoltaic bicycle shed component mounting structure includes photovoltaic bicycle shed 100, photovoltaic module 200, aqueduct 300 and waterproof stripe 400, wherein:

the rows of photovoltaic modules 200 are sequentially arranged on two sides of the gutter 110 at the top of the photovoltaic shed 100, and a gap is formed between every two adjacent photovoltaic modules 200; the waterproof adhesive tape 400 is clamped in a gap between two adjacent photovoltaic assemblies 200 in each row, so that the two adjacent photovoltaic assemblies 200 in each row are connected in a sealing manner; the water chute 300 is arranged between each two adjacent rows of photovoltaic modules 200, and the water chute 300 is communicated with the gutter 110 so as to guide rainwater received by the photovoltaic modules 200 to the gutter 110.

In particular implementations, the orientation of the photovoltaic module 200 when disposed can have a variety of embodiments. For example, as shown in fig. 2, the short side of each photovoltaic module 200 is disposed facing the gutter 110. The short edge of photovoltaic module 200 faces gutter 110 sets up, erects to adorn photovoltaic module 200 promptly, fixes through the long edge of frame 210 of photovoltaic module 200, can effectively guarantee the installation stability of photovoltaic bicycle shed.

In specific implementations, various embodiments of the fixing of the water chute 300 are provided. For example, as shown in fig. 2, 3 and 4, the gutter 300 may be perpendicular to the gutter 110 and the purlin 120, i.e., the gutter 300 may be vertically lapped over the purlin 120 on the top of the photovoltaic carport 100 through the mounting seat 310. Further, as shown in fig. 3, 4 and 5, in order to directly and stably connect the water chute 300 with the purline 120, the water chute 300 may be arranged in an inverted u-shaped cross section, and two sides of the water chute have curled edges; the mounting seat 310 may be L-shaped, and the top of the mounting seat has a curled edge matching with the water chute 300; the mounting seats 310 are respectively arranged on two sides of the lap joint of the water chute 300 and the purlin 120, the top of each mounting seat 310 is clamped in the turned edge of the water chute 300, and the bottom of each mounting seat is attached to the purlin 120 so as to fix the relative position of the water chute 300 and the purlin 120. The connection between the mounting seat 310 and the water chute 300 and the purlin 120 can be implemented in various ways, for example, the mounting seat 310 can be fixedly connected to the water chute 300 and the purlin 120 through the first connecting member 500. Further, various embodiments of the first connecting member 500 can be selected, for example, the first connecting member 500 can be a tapping screw because the tapping screw is stable in connection and convenient to install.

In particular implementations, the gutter 110 can be provided in a variety of embodiments. For example, as shown in fig. 2 and 3, the gutter 100 is disposed at a lower position of the symmetrical position of the photovoltaic carport 100, and the photovoltaic module 200 is overlapped at the edge in the photovoltaic module frame 210.

In the concrete implementation, the applicant considers that the existing car shed adopts a pressing block to fix the assembly, the assembly needs to be constructed from top to bottom, the assembly life is influenced by trampling the assembly inevitably in the construction process, and meanwhile, constructors need to carry out high-altitude operation and are not beneficial to the safety of constructors. Therefore, the applicant proposes a method of fixing the photovoltaic module 200 by connecting the bottom of the module frame 210 with the water chute 300, and in particular, as shown in fig. 3 and 4, the water chute 300 can be fixedly connected with the bottom of the photovoltaic module frame 210 and the top of the mounting seat 310 through the second connecting member 600. Further, the second connection member 600 may be a bolt connection. The water chute 300 can be pre-drilled with positioning fixing holes, the hole positions are matched with the mounting holes at the bottom of the frame of the photovoltaic module 200, and when the photovoltaic module is mounted on site, the relative positions of the photovoltaic module 200 and the water chute 300 can be effectively fixed only by sequentially penetrating bolts through the fixing holes and the mounting holes and fixing the bolts by nuts. The water chute 300 plays a role in draining and guiding water while fixing the photovoltaic module 200, and is a structural stressed member and a water guiding and draining structure.

In specific implementation, the waterproof strip 400 can be selected in various embodiments. For example, the waterproof tape 400 may be a foamed silicone waterproof tape since the foamed silicone has excellent sealability, is effective in preventing particles and rainwater, and has good durability.

To sum up, the utility model provides a photovoltaic bicycle shed subassembly mounting structure, include: the photovoltaic modules 200 are sequentially arranged in a plurality of rows on two sides of the gutter 110 at the top of the photovoltaic shed 100, a gap is formed between every two adjacent photovoltaic modules 200 in each row, and the waterproof rubber strip 40 is clamped in the gap between every two adjacent photovoltaic modules 200 in each row so as to enable every two adjacent photovoltaic modules 200 in each row to be connected in a sealing manner; along the extending direction of the gutter 110, a water chute 300 is arranged between two adjacent rows of the photovoltaic modules 200, and the tail end of the water chute 300 is communicated with the gutter 110 to guide the rainwater received by the photovoltaic modules 200 to the gutter 110. This photovoltaic bicycle shed subassembly mounting structure compares with current photovoltaic module 200 horizontal dress structure, has cancelled horizontal guiding gutter 300, has adopted vertical guiding gutter 300 mode, can be with the unified gutter 110 that leads the bicycle shed center of rainwater, and has set up waterproof stripe 400 between photovoltaic module 200's horizontal gap, avoids the rainwater seepage, and this mounting structure has promoted photovoltaic bicycle shed 100's stability effectively, and by a wide margin reduced installation cost.

The above-mentioned embodiments further describe the objects, technical solutions and advantages of the present invention in detail, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. The utility model provides a photovoltaic bicycle shed component mounting structure, a serial communication port, photovoltaic bicycle shed component mounting structure includes photovoltaic bicycle shed (100), photovoltaic module (200), guiding gutter (300) and waterproof stripe (400), wherein:

the photovoltaic modules (200) are arranged on two sides of a gutter (110) at the top of the photovoltaic shed (100) in a plurality of rows in sequence, and a gap is formed between every two adjacent photovoltaic modules (200) in each row; the waterproof adhesive tape (400) is clamped in a gap between every two adjacent photovoltaic assemblies (200) in each row, so that every two adjacent photovoltaic assemblies (200) in each row are connected in a sealing mode; the water chute (300) is arranged between every two adjacent rows of photovoltaic modules (200), and the water chute (300) is communicated with the gutter (110) so as to guide rainwater borne by the photovoltaic modules (200) to the gutter (110).

2. The photovoltaic shed assembly mounting structure as claimed in claim 1, wherein a short side of each photovoltaic module (200) is disposed facing the gutter (110).

3. The photovoltaic shed assembly mounting structure as recited in claim 1, wherein the gutter (300) is vertically lapped over the purlin (120) on top of the photovoltaic shed (100) by a mounting seat (310).

4. The photovoltaic carport assembly installation structure as claimed in claim 3, wherein the water chute (300) is provided with an inverted T-shaped cross section, two sides are provided with curled edges, the installation seat (310) is L-shaped, the top is provided with a curled edge matched with the water chute (300), the mounting seats (310) are respectively arranged on two sides of the lap joint of the water chute (300) and the purline (120), the top of each mounting seat (310) is clamped in the turned edge of the water chute (300), and the bottom of each mounting seat is connected to the purline (120) in a fitting manner so as to fix the relative position of the water chute (300) and the purline (120).

5. The photovoltaic carport assembly mounting structure as claimed in claim 4, wherein the mounting seat (310) is fixedly connected with the water chute (300) and the purlin (120) by a first connecting member (500), respectively.

6. The photovoltaic shed assembly mounting structure as recited in claim 5, wherein the first connector (500) is a self-tapping screw.

7. The photovoltaic carport assembly mounting structure as claimed in claim 1, wherein the gutter (110) is provided at a lower position of the photovoltaic carport (100) at a symmetrical position, and the photovoltaic module (200) is overlapped at an edge thereof in a photovoltaic module frame (210).

8. The photovoltaic shed assembly mounting structure as recited in claim 1, wherein the gutter (300) is fixedly connected to the bottom of the photovoltaic module rim (210) and the top of the mounting base (310) by a second connecting member (600).

9. The photovoltaic shed assembly mounting structure as recited in claim 8, wherein the second connector (600) is a bolted connection.

10. The photovoltaic shed assembly mounting structure as set forth in claim 1, wherein the flashing (400) is a foamed silicone flashing.

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