CN215484173U - Horizontal mounting structure for photovoltaic module roof power generation system - Google Patents

Abstract

The utility model relates to a transverse mounting structure for a photovoltaic module roof power generation system, which comprises two groups of photovoltaic modules which are transversely arranged, wherein a transverse gap is formed between the two groups of photovoltaic modules, the two groups of photovoltaic modules are connected in a matched manner through a transverse supporting mounting module, a module back frame is arranged at the bottom of each photovoltaic module, the upper surface position of the module back frame is lower than or equal to the upper surface position of each photovoltaic module, each transverse supporting mounting module comprises an auxiliary water tank and a sealing rubber strip which are transversely paved, the bottom of each photovoltaic module is supported on the auxiliary water tank through the module back frame, and the sealing rubber strips are arranged between two adjacent groups of module back frames in a matched manner and used for sealing the transverse gap. The photovoltaic module adopts the module back frame, so that the problem of dust accumulation on the surface of the photovoltaic module is solved, the edge sealing requirement of the photovoltaic module can be met, and the transverse gap is sealed by the sealing rubber strip, so that the sealing effect is good, and the installation is convenient.

Description

Horizontal mounting structure for photovoltaic module roof power generation system

Technical Field

The utility model belongs to the technical field of photovoltaics, and particularly relates to a transverse mounting structure for a photovoltaic module roof power generation system.

Background

A photovoltaic module roof power generation system is a novel building roof combining a traditional roof and a photovoltaic technology. The solar energy power generation device is a novel green energy technology which mainly utilizes solar energy to generate power.

The photovoltaic modules are generally arranged according to an array, a longitudinal gap and a transverse gap can be formed, and the prior art has two defects, namely, although the prior art can realize the sealing of the transverse gap, the prior sealing structure is troublesome to install; and secondly, the photovoltaic component is a component with a frame, and the surface of the frame is higher than that of the photovoltaic component, so that the dust deposition effect is generated.

SUMMERY OF THE UTILITY MODEL

In order to make up the defects of the prior art, the utility model provides a technical scheme of a transverse mounting structure for a photovoltaic module roof power generation system.

A photovoltaic module roof power generation system use horizontal mounting structure, including two sets of photovoltaic module of transversely arranging, form horizontal clearance between two sets of photovoltaic module, connect through the horizontal support installation component cooperation that sets up between two sets of photovoltaic module, its characterized in that photovoltaic module's bottom sets up subassembly back of the body frame, the upper surface position of subassembly back of the body frame is less than or equal to photovoltaic module upper surface position, horizontal support installation component includes along horizontal laid auxiliary flume and joint strip, photovoltaic module's bottom pass through subassembly back of the body frame support in on the auxiliary flume, the joint strip cooperation is installed between two sets of adjacent subassembly back of the body frames and is used for right horizontal clearance seals.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the module back frame comprises two longitudinal frames which are arranged oppositely and two transverse frames which are arranged oppositely, the four frames are connected end to end, and the sealing rubber strips are mounted between the two transverse frames in a matched mode.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the transverse frame comprises a transverse frame packaging part and a transverse frame supporting part which are connected in a matched mode, and the transverse frame packaging part is used for being tightly attached to the side part and the edge bottom of the photovoltaic module and fixedly supporting the photovoltaic module.

The transverse mounting structure for the photovoltaic assembly roof power generation system is characterized in that the transverse frame is connected with the photovoltaic assembly through structural sealant, the transverse frame packaging part comprises a transverse frame packaging part horizontal section corresponding to the bottom of the photovoltaic assembly and a transverse frame packaging part vertical section corresponding to the side part of the photovoltaic assembly, and a second positioning reinforcing part which protrudes upwards and corresponds to the structural sealant is arranged on the transverse frame packaging part horizontal section.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the whole transverse frame is of a U-shaped structure with an opening at the side edge.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the transverse frame is of a single-layer plate-shaped structure.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the sealing rubber strips are mounted with the module back frame on one side at least in a matched mode through the arranged plastic rivets.

The transverse installation structure for the photovoltaic module roof power generation system is characterized in that a second glue overflow groove corresponding to structural sealant is arranged on one side, facing the photovoltaic module, of the vertical section of the transverse frame packaging part.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the transverse frame supporting part is provided with a caulking groove which is used for being connected with a sealing rubber strip in a matched mode.

The transverse mounting structure for the photovoltaic module roof power generation system is characterized in that the transverse frame supporting part is of a tubular structure with a second corner joint cavity.

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

1) the photovoltaic module adopts the module back frame, so that the problem of dust accumulation on the surface of the photovoltaic module is solved, and the edge sealing requirement of the photovoltaic module can be met;

2) the transverse gap is sealed through the sealing rubber strip, so that the sealing effect is good;

3) the transverse frame is provided with a second positioning reinforcing part, and the second positioning reinforcing part can control the thickness of structural sealant when the assembly back frame is installed on the photovoltaic assembly, so that the adhesion quality of the assembly back frame and the photovoltaic assembly is ensured, and the rigidity of the assembly back frame can be improved;

4) the second glue overflow groove is formed in the transverse frame, so that structural sealant cannot overflow to the surface of the photovoltaic assembly when the assembly back frame is installed on the photovoltaic assembly, the appearance tidiness of the photovoltaic assembly is guaranteed, and the glue scraping workload of framing is reduced;

5) the horizontal frame is provided with an embedded rubber groove, so that the installation with the sealing rubber strip is convenient.

Drawings

FIG. 1 is a schematic structural view of a use state of embodiment 1;

FIG. 2 is a schematic cross-sectional view of a lateral frame in embodiment 1;

FIG. 3 is a schematic structural view of a use state of embodiment 2;

fig. 4 is a schematic cross-sectional view of a lateral frame in embodiment 2.

In the figure: the photovoltaic module 1, a transverse frame 201, a transverse frame packaging part 2010, a transverse frame packaging part horizontal section 20100, a transverse frame packaging part vertical section 20101, a transverse frame supporting part 2011, a second positioning reinforcing part 2012, a second glue overflow groove 2013, a glue embedding groove 2014, a second corner code cavity 2015, an auxiliary water tank 12 and a sealing rubber strip 13.

Detailed Description

In the description of the present invention, it is to be understood that the terms "one end", "the other end", "outside", "upper", "inside", "horizontal", "coaxial", "central", "end", "length", "outer end", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention.

The utility model will be further explained with reference to the drawings.

Example 1

As shown in fig. 1 and 2, a transverse mounting structure for a photovoltaic module roof power generation system comprises two groups of photovoltaic modules which are transversely arranged, a transverse gap is formed between the two groups of photovoltaic modules, the two groups of photovoltaic modules 1 are connected in a matched mode through a transverse supporting mounting module, a module back frame 2 is arranged at the bottom of each photovoltaic module 1, the upper surface position of the module back frame 2 is lower than or equal to the upper surface position of each photovoltaic module 1, each transverse supporting mounting module comprises an auxiliary water tank 12 and a sealing rubber strip 13 which are transversely laid, the bottom of each photovoltaic module 1 is supported on the auxiliary water tank 12 through the module back frame 2, and the sealing rubber strip 13 is arranged between the two groups of adjacent module back frames 2 in a matched mode and used for sealing the transverse gap.

As an optimization: the assembly back frame 2 comprises two longitudinal frames which are oppositely arranged and two transverse frames 201 which are oppositely arranged, the four frames are connected end to end, and the sealing rubber strips 13 are arranged between the two transverse frames 201 in a matched mode. The transverse frame 201 is a U-shaped structure with an opening on a side, and the transverse frame 201 is a single-layer plate-shaped structure.

Further, the transverse frame 201 comprises a transverse frame packaging part 2010 and a transverse frame supporting part 2011 which are connected in a matching mode, and the transverse frame packaging part 2010 is used for being tightly attached to the side part and the bottom of the edge of the photovoltaic assembly 1 and fixedly supporting the photovoltaic assembly 1. The longitudinal frame comprises a longitudinal frame packaging part and a longitudinal frame supporting part which are connected in a matched mode, the longitudinal frame packaging part is used for being tightly attached to the side part and the bottom of the edge of the photovoltaic assembly 1 and fixedly supporting the photovoltaic assembly 1, and the longitudinal frame supporting part 2001 is used for being connected with the longitudinal support mounting assembly in a matched mode. The transverse frame 201 is connected with the photovoltaic assembly 1 through a structural sealant, the transverse frame packaging part 2010 comprises a transverse frame packaging part horizontal section 20100 corresponding to the bottom of the photovoltaic assembly 1 and a transverse frame packaging part vertical section 20101 corresponding to the side of the photovoltaic assembly 1, and a second positioning reinforcing part 2012 protruding upwards and corresponding to the structural sealant is arranged on the transverse frame packaging part horizontal section 20100.

Further, the second positioning reinforcement 2012 is a raised structure formed by bending the horizontal section 20100 of the horizontal bezel packaging part. Second location rib 2012 can be when photovoltaic module 1 installation subassembly back of the body frame, and the sealed gluey thickness of control structure has guaranteed subassembly back of the body frame and photovoltaic module bonding quality and can improve the rigidity of subassembly back of the body frame.

As an optimization: the sealing rubber strip 13 is installed in cooperation with the transverse frame supporting part 2011 on one side through the arranged plastic rivets.

Example 2

As shown in fig. 3 and 4, a transverse mounting structure for a photovoltaic module roof power generation system comprises two groups of photovoltaic modules which are transversely arranged, a transverse gap is formed between the two groups of photovoltaic modules, the two groups of photovoltaic modules 1 are connected in a matched mode through a transverse supporting mounting module, a module back frame 2 is arranged at the bottom of each photovoltaic module 1, the upper surface position of the module back frame 2 is lower than or equal to the upper surface position of each photovoltaic module 1, each transverse supporting mounting module comprises an auxiliary water tank 12 and a sealing rubber strip 13 which are transversely laid, the bottom of each photovoltaic module 1 is supported on the auxiliary water tank 12 through the module back frame 2, and the sealing rubber strip 13 is arranged between the two groups of adjacent module back frames 2 in a matched mode and used for sealing the transverse gap.

As an optimization: the assembly back frame 2 comprises two longitudinal frames which are oppositely arranged and two transverse frames 201 which are oppositely arranged, the four frames are connected end to end, and the sealing rubber strips 13 are arranged between the two transverse frames 201 in a matched mode. The transverse frame 201 is a U-shaped profile structure with an opening on the side.

Further, the transverse frame 201 comprises a transverse frame packaging part 2010 and a transverse frame supporting part 2011 which are connected in a matching mode, and the transverse frame packaging part 2010 is used for being tightly attached to the side part and the bottom of the edge of the photovoltaic assembly 1 and fixedly supporting the photovoltaic assembly 1. The photovoltaic module comprises a photovoltaic module 1, a longitudinal frame and a longitudinal frame supporting part, wherein the longitudinal frame comprises a longitudinal frame packaging part and a longitudinal frame supporting part which are connected in a matched mode, the longitudinal frame packaging part is used for being tightly attached to the side part and the bottom of the edge of the photovoltaic module 1 and fixedly supporting the photovoltaic module 1, and the longitudinal frame supporting part is used for being connected with a longitudinal supporting and installing assembly in a matched mode. The transverse frame 201 is connected with the photovoltaic assembly 1 through a structural sealant, the transverse frame packaging part 2010 comprises a transverse frame packaging part horizontal section 20100 corresponding to the bottom of the photovoltaic assembly 1 and a transverse frame packaging part vertical section 20101 corresponding to the side of the photovoltaic assembly 1, and a second positioning reinforcing part 2012 protruding upwards and corresponding to the structural sealant is arranged on the transverse frame packaging part horizontal section 20100.

Further, the second positioning reinforcement 2012 is a rib structure on the horizontal section 20100 of the horizontal frame packaging part. Second location rib 2012 can be when photovoltaic module 1 installation subassembly back of the body frame, and the sealed gluey thickness of control structure has guaranteed subassembly back of the body frame and photovoltaic module bonding quality and can improve the rigidity of subassembly back of the body frame.

Furthermore, a second glue overflow groove 2013 corresponding to the structural sealant is formed in one side, facing the photovoltaic module 1, of the vertical section 20101 of the transverse frame packaging part. The design of the second glue overflow groove 2013 ensures that the structural sealant cannot overflow to the surface of the photovoltaic assembly when the assembly back frame is installed on the photovoltaic assembly 1, thereby ensuring the appearance neatness of the photovoltaic assembly and reducing the glue scraping workload of the frame installation.

Furthermore, an embedding groove 2014 for being connected with the sealing rubber strip 13 in a matching manner is arranged on the transverse frame supporting portion 2011, and the embedding groove 2014 is convenient to mount with the sealing rubber strip 13.

As an optimization: the lateral frame support 2011 is tubular with a second corner brace 2015.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides a photovoltaic module roof power generation system is with horizontal mounting structure, includes two sets of photovoltaic module who transversely arranges, forms horizontal clearance between two sets of photovoltaic module, connects through the cooperation of the horizontal support installation component that sets up between two sets of photovoltaic module (1), its characterized in that the bottom of photovoltaic module (1) sets up the subassembly back of the body frame, the upper surface position of subassembly back of the body frame is less than or equal to photovoltaic module (1) upper surface position, transversely support the installation component and include along horizontal laying water channel (12) and joint strip (13), the bottom of photovoltaic module (1) support through the subassembly back of the body frame in on water channel (12), joint strip (13) cooperation is installed between two sets of adjacent subassembly back of the body frames and is used for right horizontal clearance seals.

2. The transverse mounting structure for the photovoltaic module roof power generation system according to claim 1, wherein the module back frame comprises two opposite longitudinal frames and two opposite transverse frames (201), the four frames are connected end to end, and the sealing rubber strip (13) is fittingly mounted between the two sets of transverse frames (201).

3. The transverse mounting structure for the photovoltaic assembly roof power generation system according to claim 2, wherein the transverse frame (201) comprises a transverse frame packaging part (2010) and a transverse frame supporting part (2011) which are connected in a matching manner, and the transverse frame packaging part (2010) is used for clinging to the side part and the edge bottom of the photovoltaic assembly (1) and fixedly supporting the photovoltaic assembly (1).

4. The transverse mounting structure for the photovoltaic component roof power generation system according to claim 3, wherein the transverse frame (201) is connected with the photovoltaic component (1) through a structural sealant, the transverse frame packaging part (2010) comprises a transverse frame packaging part horizontal section (20100) corresponding to the bottom of the photovoltaic component (1) and a transverse frame packaging part vertical section (20101) corresponding to the side of the photovoltaic component (1), and a second positioning reinforcing part (2012) which protrudes upwards and corresponds to the structural sealant is arranged on the transverse frame packaging part horizontal section (20100).

5. The transverse mounting structure for the photovoltaic module roof power generation system as claimed in claim 2, wherein the transverse frame (201) is a U-shaped structure with side openings as a whole.

6. The transverse mounting structure for the photovoltaic module roof power generation system as claimed in any one of claims 2-5, wherein the transverse frame (201) is a single-layer plate-shaped structure.

7. The transverse mounting structure for the photovoltaic module roof power generation system according to claim 6, wherein the sealing rubber strip (13) is mounted with at least one module back frame on one side through a plastic rivet.

8. The transverse installation structure for the photovoltaic module roof power generation system as claimed in claim 4, wherein a second glue overflow groove (2013) corresponding to the structural sealant is arranged at one side of the vertical section (20101) of the transverse frame packaging part facing the photovoltaic module (1).

9. The transverse installation structure for the photovoltaic module roof power generation system as claimed in claim 3, 4 or 8, wherein the transverse frame support part (2011) is provided with a caulking groove (2014) for being matched and connected with the sealing rubber strip (13).

10. The lateral mounting structure for photovoltaic module roof power generation system according to claim 3, 4 or 8, characterized in that the lateral frame support (2011) is a tubular structure with a second corner-code cavity (2015).

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