CN213186004U - Photovoltaic module installation mechanism, photovoltaic module and system thereof - Google Patents

Abstract

The utility model relates to a photovoltaic module installation mechanism, photovoltaic module and system thereof, wherein, the photovoltaic module installation mechanism comprises an integrally formed frame, the frame is provided with a laminating frame for installing a laminating piece, the laminating frame is provided with a laminating piece fixing cavity with a lateral opening, the photovoltaic module installation mechanism also comprises a bracket matched with the frame, and the frame and the bracket are mutually fixed by adopting a chute and a protrusion; the support integrated into one piece has the installing frame that is used for with the building fixed, the installing frame is formed with the installation cavity of downward opening in order to cooperate the fixed with the building. Through above-mentioned photovoltaic module installation mechanism for photovoltaic module passes through and realizes connecting fast, accurately between frame and the support, simplifies the installation flow simultaneously. Moreover, the photovoltaic array is more stable in overall structure due to the mutually nested design of the frame and the support.

Description

Photovoltaic module installation mechanism, photovoltaic module and system thereof

Technical Field

The utility model relates to a photovoltaic power generation technical field especially relates to a photovoltaic module installation mechanism, photovoltaic module and system thereof.

Background

Building Integrated Photovoltaic (BIPV) is a technology for integrating solar power (Photovoltaic) products into buildings. The photovoltaic module product is most commonly combined with a building roof, and under a general condition, a support is fixedly arranged on the building roof, and the photovoltaic module is fixed on the support. But can lay various steel tiles on some building roofs, various steel tiles generally are the ripple shape, if utilize the fixed photovoltaic module of conventional support to increase the degree of difficulty of installation on various steel tile roof, can not accurate butt joint installation moreover, influence the steadiness in later stage.

SUMMERY OF THE UTILITY MODEL

The utility model provides a novel photovoltaic module installation mechanism, photovoltaic module and system thereof solve above-mentioned problem.

In order to achieve the above object, the present invention provides the following technical solutions:

a photovoltaic module mounting mechanism comprises an integrally formed frame, wherein the frame is provided with a laminating frame for mounting a laminating piece, the laminating frame is provided with a laminating piece fixing cavity with a lateral opening, the photovoltaic module mounting mechanism further comprises a support matched with the frame, and the frame and the support are mutually fixed by adopting a sliding groove and a protrusion; the support integrated into one piece has the installing frame that is used for with the building fixed, the installing frame is formed with the installation cavity of downward opening in order to cooperate the fixed with the building.

Furthermore, the sliding groove is integrally formed at the bottom of the side frame and is of an inverted convex shape with a downward opening, and the protrusion protrudes upwards from the top of the mounting frame and is designed to be matched with the inverted convex sliding groove.

Furthermore, the frame is also provided with a pair of vertical frames extending downwards from two ends of the laminated frame and a limiting plate extending inwards from the end part of at least one vertical frame towards a sliding groove, and the sliding groove is formed among the laminated frame, the vertical frames and the limiting plate; the protrusion is provided with a connecting plate extending upwards from the mounting frame and a guide plate extending from the end part of the connecting plate at least towards one side of the connecting plate, and a limiting groove for the limiting plate to be inserted is formed among the guide plate, the connecting plate and the mounting frame.

Further, the mounting frame includes connect protruding diaphragm, certainly diaphragm both ends respectively the downward and a pair of mounting panel that outwards extend that inclines, the installation cavity is formed between diaphragm and a pair of mounting panel.

Furthermore, the mounting frame further comprises a pair of mounting edges extending outwards from the end part of each mounting plate, and each mounting edge is provided with a mounting hole.

Furthermore, grooves are respectively concavely arranged on the adjacent inner wall surfaces of the mounting frame and the transverse plate, and the grooves respectively extend to the transverse plate along the extending direction of the pair of mounting plates.

Furthermore, the laminating frame is provided with an upper frame, a lower frame and a side frame which is connected with the same side edge of the upper frame and the lower frame; and the lower part of the upper frame is provided with a glue overflow groove facing the fixed cavity.

The utility model also provides a photovoltaic module, including lamination piece and foretell frame, the lamination piece edge-mounting be in the fixed intracavity of frame.

The utility model also provides a photovoltaic system, which comprises the photovoltaic component and a building roof matched and fixed with the bracket; the building roof is provided with an upward convex mounting part which is embedded in the mounting cavity on the support, and the photovoltaic module is fixed on the building roof by utilizing the matching between the mounting frame and the mounting part.

Furthermore, the building roof is a color steel tile-shaped roof, and the mounting frame is matched with the raised mounting part of the color steel tile-shaped roof; the photovoltaic modules are arranged on the roof of the building at intervals in a matrix mode, and in the extending direction of the support, the intervals between the photovoltaic modules are 100-150 mm.

Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model provides a photovoltaic module installation mechanism makes photovoltaic module directly fixes on the building through the support, the frame with distinctive spout and prominent fixed mode between the support make the frame with realize connecting fast, accurately between the support, simplified the installation procedure between frame and the support. Moreover, the photovoltaic array is more stable in overall structure due to the mutually nested design of the frame and the support.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the photovoltaic module mounting mechanism of the present invention.

Fig. 2 is a schematic diagram of a frame structure in the embodiment of fig. 1.

Fig. 3 is a schematic view of the structure of the bracket in the embodiment of fig. 1.

Fig. 4 is a schematic view of a partial structure of the photovoltaic module of the present invention.

Fig. 5 is a schematic structural diagram of the photovoltaic system of the present invention.

Fig. 6 is a schematic view of a partial structure of a roof of the building in the photovoltaic system of fig. 5.

The solar photovoltaic module comprises 10-frames, 11-laminated frames, 111-upper frames, 112-lower frames, 113-side frames, 12-fixing cavities, 121-glue overflow grooves, 13-sliding grooves, 131-vertical frames, 132-limiting plates, 30-supports, 31-protrusions, 311-connecting plates, 312-guide plates, 313-limiting grooves, 32-mounting frames, 321-transverse plates, 322-mounting plates, 323-mounting edges, 33-mounting cavities, 331-grooves, 40-building roofs, 41-mounting parts, top plates-411, side plates-412, bottom plates-413, 50-laminated parts, 51-photovoltaic glass, 52-photovoltaic cell pieces and 53-isolation layers.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the technical solution of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts shall belong to the protection scope of the present invention.

It should be noted that the terms "upper", "lower", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are only used for convenience of simplifying the description of the present invention, and do not indicate or imply that the indicated devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the scope of the present invention. Specifically, in the present invention, the direction toward the ground is downward, and the opposite direction is upward.

In the various drawings of the present invention, certain dimensions of structures or portions may be exaggerated relative to other structural portions for ease of illustration and, thus, are provided only to illustrate the basic structure of the subject matter of the present invention.

As shown in fig. 1 to 3, the utility model provides a photovoltaic module installation mechanism, which is suitable for building photovoltaic integration and used for fixing a photovoltaic module on a building. The photovoltaic module mounting mechanism comprises an integrally formed frame 10, wherein the frame 10 is provided with a laminating frame 11 for mounting a laminating piece 50, the laminating frame 11 is provided with a laminating piece fixing cavity 12 with a lateral opening, the photovoltaic module mounting mechanism further comprises a bracket 30 matched with the frame 11, and the frame 11 and the bracket 30 are mutually fixed by adopting a sliding groove 13 and a protrusion 31; the bracket 30 is integrally formed with a mounting frame 32 for fixing with a building, and the mounting frame 32 is formed with a mounting cavity 33 which is opened downwards to be fixed in cooperation with the building. Through the utility model provides a photovoltaic module installation mechanism makes photovoltaic module directly fixes on the building through support 30, frame 10 with distinctive spout 13 and protruding 31's fixed mode between the support 30 makes frame 10 with realize connecting fast, accurately between the support 30, simplify the installation procedure between frame 10 and the support 30. Moreover, the design of nesting the frame 10 and the support 30 makes the overall structure of the photovoltaic array more stable.

Specifically, the lamination frame 11 is used to fix the lamination 50. The laminated frame 11 has an upper frame 111, a lower frame 112, and a side frame 113 connecting the same side edges of the upper frame 111 and the lower frame 112, and the fixing cavity 12 is formed between the upper frame 111, the lower frame 112, and the side frame 113. That is, the laminated member 50 is embedded in the fixing cavity 12, the upper frame 111 is adjacent to the light receiving surface of the laminated member 50, the lower frame 112 is adjacent to the backlight surface of the laminated member 50, the side frame 113 is adjacent to the side edge of the laminated member 50, the laminated member 50 is enclosed by three frames of the laminated frame 11 and is received in the fixing cavity 12, and the fixing cavity 12 is opened toward the extending direction of the laminated member 50.

The length of the lower frame 112 is greater than that of the upper frame 111, so that when the lamination frame 11 and the lamination 50 are matched, the lower frame 112 supports the lamination 50, and the structural stability of the photovoltaic module is further enhanced.

In general, in order to improve the stability and the sealing performance between the laminate 50 and the photovoltaic frame 10, the position where the edge of the laminate 50 is embedded inside the fixing cavity 12 is coated with adhesive, and when the laminate 50 and the lamination frame 11 are matched, the adhesive may overflow out of the lamination frame 11 or on the laminate 50, which may affect the overall appearance of the photovoltaic module on one hand, and may affect the output power of the photovoltaic module on the other hand by staining the light receiving surface of the laminate 50. Therefore, the lower part of the upper frame 111 of the fixed cavity 12 is provided with an overflow groove 121 facing the fixed cavity 12, when the lamination member 50 and the lamination frame 11 are matched, the excess sealant overflows into the overflow groove 121, thereby ensuring the overall appearance and power output of the photovoltaic module; meanwhile, the adhesive in the adhesive overflow groove 121 can effectively strengthen the fixation of the lamination frame 11. The adhesive is preferably a structural adhesive with strong adhesiveness and weather resistance so as to ensure the weather resistance of the adhesive.

As a preferred embodiment of the present invention, the sliding groove 13 is integrally formed at the bottom of the frame 10 and is an inverted convex shape with a downward opening, specifically, the frame 10 further has a pair of vertical frames 131 extending downward from both ends of the laminated frame 11, and a limiting plate 132 extending from at least one end of the vertical frame 131 toward the sliding groove 13, and the sliding groove 13 is formed between the laminated frame 11, the vertical frame 131, and the limiting plate 132. Preferably, a limit plate 132 is provided at the end of each mullion 131, so that the sliding chute 13 is of an inverted convex shape as a whole for cooperating with the bracket 30; meanwhile, due to the arrangement of the pair of limiting plates 132, the bottom of the frame 10 is tidy, and the photovoltaic module is convenient to package and transport.

Further, the bracket 30 is used to fix the photovoltaic module to a building. Therefore, the bracket 30 has a protrusion 31 fixed to the side frame 10 and an installation frame 32 fixed to the building under the protrusion 31.

Specifically, the protrusion 31 protrudes upward from the top of the mounting frame 32, and is designed to match with the inverted convex sliding groove 13, so that when the side frame 10 and the bracket 30 are matched, the protrusion 31 is embedded in the sliding groove 13, and the overall structure of the photovoltaic module mounting mechanism is more stable.

Further, the protrusion 31 has a connecting plate 311 extending upward from the mounting frame 32, and a guide plate 312 extending from an end of the connecting plate 311 at least toward one side of the connecting plate 311, wherein a limiting groove 313 into which the limiting plate 132 is inserted is formed among the guide plate 312, the connecting plate 311, and the mounting frame 32. When the photovoltaic frame 10 and the support 30 are matched, the guide plate 312 is embedded in the sliding groove 13, the connecting plate 311 is located in a pair of yielding space between the limiting plates 132, the limiting plates 132 are limited in the limiting grooves 313, and the protrusion 31 and the sliding groove 13 are nested with each other, so that the support 30 and the frame 10 are matched with each other and have stronger stability.

It is understood that the sliding groove 13 may also be disposed on the bracket 30, the protrusion 31 is disposed on the frame 10, and the frame 10 and the bracket 30 can be fixed by the cooperation of the sliding groove 13 and the protrusion 31. Of course, the shape of the protrusion 31 is not limited, and the protrusion can be matched with the corresponding sliding groove 13 to achieve the same purpose.

In this embodiment, the bracket 30 in the photovoltaic module installation mechanism is suitable for a building integrated photovoltaic roof, the building mainly refers to a building roof 40, and a color steel tile-shaped roof is used as a preferred embodiment, and of course, as long as the building roof 40 has the protruded installation portion 41, the bracket 30 of the present invention can be applied. The shape of the mounting frame 32 is configured to match with an upwardly protruding mounting portion 41 of the building roof 40, and the mounting portion 41 is embedded in the mounting cavity 33, so that the photovoltaic module and the building roof 40 are integrated.

As a preferred embodiment of the present invention, the mounting frame 32 includes a transverse plate 321 connecting the protrusion 31, and a pair of mounting plates 322 extending obliquely downward and outward from two ends of the transverse plate 321, respectively, and the mounting cavity 33 is formed between the transverse plate 321 and the pair of mounting plates 322; the mounting cavity 33 is used for accommodating the mounting part 41, and the photovoltaic module and the building are integrated into a whole, so that the building photovoltaic integrated roof is more attractive integrally.

Furthermore, grooves 331 are respectively recessed in the inner wall surfaces of the pair of mounting plates 322 adjacent to the transverse plate 321, and the grooves 331 are used for filling adhesive glue to further strengthen the fixation of the mounting frame 32 and the mounting portion 41.

Further, the concave portions 331 extend to the transverse plate 321 along the extending direction of the mounting plate 322, and preferably, the size of the concave portions 331 covers the transverse plate 321 and the upper portion of the mounting plate 322, that is, the size of the concave portions 331 can accommodate the upper portion of the mounting portion 41, so as to increase the area of the adhesive bonding between the mounting frame 32 and the mounting portion 41, thereby enhancing the stability of the connection between the mounting frame 32 and the mounting portion 41.

Preferably, the bracket 30 further includes a pair of mounting edges 323 extending outwardly from an end of each of the mounting plates 322, each of the mounting edges having a mounting hole.

When the mounting frame 32 is engaged with the mounting portion 41, the mounting edge 323 is positioned under the mounting portion 41. Preferably, the mounting edge 323 is provided with a plurality of screw holes (not shown), and the mounting frame 32 is further fixed to the mounting portion 41 by using bolt screw holes, which are also provided at corresponding positions of the building roof 40.

Of course, the screw holes may also be directly formed on the mounting plate 322, and correspondingly, the screw holes are also formed at corresponding positions of the building, so that the purpose of reinforcing and fixing the mounting frame 32 and the building roof 40 can be achieved.

It will be appreciated that the shape of the mounting frame 32 is designed according to the shape of the building roof 40, including but not limited to trapezoidal, triangular, rectangular, semicircular, etc., as long as the mounting frame 32 and the building roof 40 are matched to achieve the purpose of direct fitting and fixing with the building.

As shown in fig. 4, the present invention further relates to a photovoltaic module, which comprises a laminated member 50 and a photovoltaic frame 10, wherein the laminated member 50 is edge-mounted in the fixing cavity 12 of the photovoltaic frame 10 to ensure the mechanical strength and weather resistance of the photovoltaic module. In the present invention, the photovoltaic frame 10 is installed at two opposite edges of the laminated member 50, so that the connection between the photovoltaic module and the building is more stable.

Specifically, the laminated member 50 is formed by sequentially laminating the photovoltaic cell sheet 52 with glass, adhesive film, etc. at a high temperature, and therefore, the structure of the laminated member 50 sequentially comprises, from top to bottom: the photovoltaic solar cell comprises photovoltaic glass 51, an upper adhesive film, a photovoltaic cell piece 52, a lower adhesive film and an isolation layer 53, wherein the photovoltaic glass 51 is a light receiving surface, and the isolation layer 53 is a backlight surface; the isolation layer 53 may be glass as the light-receiving surface, or may be a waterproof back sheet. When the laminate 50 is secured within the fixture cavity 12, the photovoltaic glass 51 is adjacent the upper border 111 of the laminate frame 11, the spacer layer 53 is adjacent the lower border 112, and the edges of the laminate 50 are adjacent the side borders 113.

As shown in fig. 5 and 6, the present invention also relates to a photovoltaic system, which includes the above photovoltaic module, and a building roof 40 fixed with the bracket 30; the building roof 40 is provided with an installation part 41 protruding upwards, the installation part 41 is embedded in the installation cavity 33 of the bracket 30, and the photovoltaic module is fixed on the building roof 40 by the matching between the installation frame 32 and the installation part 41.

The building roof 40 is a color steel tile-shaped roof, and the mounting frame 32 is matched with the raised mounting part 41 of the color steel tile-shaped roof; the photovoltaic modules are arranged on the building roof 40 at intervals in a matrix manner.

Specifically, the mounting portion 41 has a top plate 411 facing the mounting cavity 14, and a pair of side plates 412 on both sides of the mounting portion 41, and the top plate 411 and the pair of side plates 412 form the mounting portion 41 with a downward opening; the installation locations 41 are spaced apart from each other on the roof 40 of the building, and a bottom plate 413 is provided between the two installation locations 41.

When the mounting frame 32 is engaged with the mounting portion 41, the pair of side plates 412 are respectively positioned below the mounting plate 322, and the top plate 411 is positioned below the horizontal plate 321; meanwhile, the mounting edge 323 is erected on the bottom plate 413 of the building roof 40, the same screw holes are arranged at corresponding positions of the bottom plate 413, and the fixing of the mounting frame 32 and the mounting portion 41 is further enhanced by using the bolt screw holes.

In order to satisfy the demand of photovoltaic system output end electric current or voltage size, will be a plurality of photovoltaic module is fixed through establishing ties or parallelly connected back matrix on the building roofing 40, adopt the utility model discloses a photovoltaic module installation mechanism for when photovoltaic module utilizes support 30 to fix on building roofing 40, photovoltaic module is higher than building roofing 40 does benefit to photovoltaic module's heat dissipation and ventilation.

Preferably, in the extending direction of the support 30, the interval between the photovoltaic modules is 100-150mm, so that a gap exists between the photovoltaic modules, natural wind conveniently passes through the gap along the passage between the building roof 40 and the photovoltaic modules, a good ventilation effect can be formed, and the heat dissipation effect of the modules is improved.

To sum up, the utility model provides a photovoltaic module installation mechanism utilizes the utility model discloses a photovoltaic module installation mechanism makes photovoltaic module directly fixes on building roofing 40 through support 30, frame 10 with distinctive spout 13 and protruding 31's fixed mode between the support 30 makes frame 10 with realize connecting fast, accurately between the support 30, simplified the installation flow between frame 10 and the support 30. Moreover, the design of nesting the frame 10 and the support 30 makes the overall structure of the photovoltaic array more stable.

It should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art will be able to make the description as a whole, and the embodiments may be appropriately combined to form other embodiments as will be appreciated by those skilled in the art.

The above detailed description of a series of embodiments is only for the purpose of illustration, and is not intended to limit the scope of the invention, which is intended to include all equivalent embodiments or modifications that do not depart from the spirit of the invention.

Claims (10)

1. A photovoltaic module mounting mechanism comprising an integrally formed bezel having a lamination frame for mounting a lamination member, the lamination frame being formed with a lamination member fixing cavity that is laterally open, characterized in that: the photovoltaic module mounting mechanism further comprises a support matched with the frame, and the frame and the support are mutually fixed by adopting a sliding groove and a protrusion; the support integrated into one piece has the installing frame that is used for with the building fixed, the installing frame is formed with the installation cavity of downward opening in order to cooperate the fixed with the building.

2. The photovoltaic module mounting mechanism of claim 1, wherein: the sliding groove is integrally formed at the bottom of the frame and is of an inverted convex shape with a downward opening, and the protrusion protrudes upwards from the top of the mounting frame and is matched with the inverted convex sliding groove.

3. The photovoltaic module mounting mechanism of claim 2, wherein: the frame is also provided with a pair of vertical frames extending downwards from two ends of the laminating frame and a limiting plate extending inwards from the end part of at least one vertical frame towards a sliding groove, and the sliding groove is formed among the laminating frame, the vertical frames and the limiting plate; the protrusion is provided with a connecting plate extending upwards from the mounting frame and a guide plate extending from the end part of the connecting plate at least towards one side of the connecting plate, and a limiting groove for the limiting plate to be inserted is formed among the guide plate, the connecting plate and the mounting frame.

4. The photovoltaic module mounting mechanism of claim 1, wherein: the installing frame is including connecting bellied diaphragm, certainly diaphragm both ends respectively down and the pair of mounting panel that leans out the extension, the installation cavity forms between diaphragm and the pair of mounting panel.

5. The photovoltaic module mounting mechanism of claim 4, wherein: the mounting frame still includes from each a pair of installation limit of the tip of mounting panel outwards extension, each be equipped with the mounting hole on the installation limit.

6. The photovoltaic module mounting mechanism of claim 4, wherein: the mounting frame and the adjacent inner wall of diaphragm department are recessed respectively and are equipped with the recess, the recess extends to respectively along a pair of mounting panel extending direction the diaphragm.

7. The photovoltaic module mounting mechanism of claim 1, wherein: the laminating frame is provided with an upper frame, a lower frame and a side frame which is connected with the same side edge of the upper frame and the lower frame; and the lower part of the upper frame is provided with a glue overflow groove facing the fixed cavity.

8. A photovoltaic module, characterized by: a surround comprising a laminate and the photovoltaic assembly mounting mechanism of any one of claims 1 to 7, the laminate edge being mounted within a fixing cavity of the surround.

9. A photovoltaic system, characterized by: a building roof comprising the photovoltaic module of claim 8 and secured in cooperation with the support; the building roof is provided with an upward convex mounting part which is embedded in the mounting cavity on the support, and the photovoltaic module is fixed on the building roof by utilizing the matching between the mounting frame and the mounting part.

10. The photovoltaic system of claim 9, wherein: the building roof is a color steel tile-shaped roof, and the mounting frame is matched with the raised mounting part of the color steel tile-shaped roof; the photovoltaic modules are arranged on the roof of the building at intervals in a matrix mode, and in the extending direction of the support, the intervals between the photovoltaic modules are 100-150 mm.

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