CN220067291U - Steel construction roofing and photovoltaic module coupling assembling - Google Patents

Abstract

The utility model aims to provide a connecting component of a steel structure roof and a photovoltaic module, which comprises a clamp, wherein a supporting frame is fixedly connected to the top of the clamp, and the fixing position can be transversely adjusted along the top of the clamp; the main beam is assembled on the top panel of the supporting frame and is vertically adjusted on the supporting frame through the screw rod assembly; and the fixing component can move along the longitudinal direction of the main beam and is fixed on the main beam, and the fixing component is used for fixing the photovoltaic component. The utility model relates to the technical field of photovoltaic solar energy, in particular to a design of a supporting frame, a main beam and a fixing component, wherein the supporting frame can be transversely moved and adjusted on a clamp through a strip-shaped hole and a bolt component, the main beam can be adjusted to the height of the supporting frame through an adjusting screw rod and a nut pair, and the fixing component can be longitudinally moved on the main beam through a sliding block, so that the multidirectional adjustment of a connecting component is realized, and the installation precision of the photovoltaic component is improved.

Description

Steel construction roofing and photovoltaic module coupling assembling

Technical Field

The utility model relates to the technical field of photovoltaic solar energy, in particular to a steel structure roof and photovoltaic module connecting assembly.

Background

The photovoltaic module is installed on the steel structure roof, besides the installation fixity and the weight, sunlight and shadows are also required to be considered, so that the sunlight intensity can be effectively improved in a tiled installation mode, and wind resistance is reduced. The flat mounting mode needs to ensure the mounting level and avoid disorder or uneven height.

The manually adjustable support of the photovoltaic module comprises a clamp, a main beam, a secondary beam and a pressing piece, and when the manually adjustable support is installed, gaskets can be added or reduced at the positions of bolts to adjust the flatness of the photovoltaic module. The bolt is loosened due to the fact that the gasket deforms easily due to vibration or heat and cold shrinkage, the height adjusting process is complex, and the number of the gaskets needs to be adjusted repeatedly. And the casting die can only carry out the adjustment that removes on the secondary beam, and the adjustment direction of adjustable support is limited, and it is poor to finally easily cause photovoltaic module installation back planarization.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a steel structure roof and photovoltaic module connecting assembly, which solves the problem that an adjustable bracket is not easy to adjust when the existing photovoltaic module is installed.

In order to achieve the above purpose, the present utility model is realized by the following technical scheme: a steel structure roofing and photovoltaic module coupling assembling, coupling assembling includes:

a clamp;

the support frame is fixedly connected to the top of the clamp and can transversely adjust the fixing position along the top of the clamp;

the main beam is assembled on the top panel of the supporting frame and is vertically adjusted on the supporting frame through the screw rod component;

and the fixing component can move along the longitudinal direction of the main beam and is fixed on the main beam, and the fixing component is used for fixing the photovoltaic component.

Preferably, a strip-shaped groove is formed in the bottom panel of the supporting frame, a bolt component is fixedly connected to the top surface of the clamp, and the bolt component penetrates through the strip-shaped groove to fixedly connect the supporting frame to the top of the clamp;

the bolt assembly can move in the strip-shaped groove to adjust the fixing position of the supporting frame on the clamp.

Preferably, the bolt assembly comprises a bolt fixedly connected with the clamp and a nut screwed on the bolt, and the nut is pressed on the top of the strip-shaped groove.

Preferably, the screw assembly comprises an adjusting screw fixedly connected with the main beam and a nut pair screwed on the adjusting screw; the adjusting screw rod penetrates through the top panel of the supporting frame and can move up and down, the nut pair comprises a plurality of nuts, and the nuts clamp the top panel of the supporting frame to fix the adjusting screw rod.

Preferably, the bottom four corners of girder downwards vertical extension is formed with the leading truck, the leading truck runs through the top surface of braced frame, makes the girder is not twisted when being adjusted the height by adjusting component.

Preferably, grooves are formed in two side faces of the supporting frame, and the grooves can be penetrated by a tool to enable the bolt assembly and the nut pair to be screwed.

Preferably, one or both ends of the main beam are outwardly extended to form an extension beam to extend the fixing position of the fixing assembly.

Preferably, the fixing assembly includes:

the sliding block is fixed on the main beam;

a press, the press comprising:

a lower pressing sheet fixed on the sliding block;

and the upper pressing piece is connected above the lower pressing piece through a bolt rod.

Preferably, the upper pressing piece is connected with one end of the lower pressing piece, an opening is formed at the other end of the upper pressing piece, and the opening clamps the photovoltaic module.

Preferably, openings are formed at two ends of the upper pressing sheet and the lower pressing sheet, and the openings clamp the photovoltaic module.

Advantageous effects

Through the design of the steel structure roof and photovoltaic module connecting assembly, the supporting frame, the main beam and the fixing assembly, the supporting frame can be transversely moved and adjusted on the clamp through the strip-shaped holes and the bolt assemblies, the main beam can be adjusted in height on the supporting frame through the adjusting screw rod and the nut pair, and the fixing assembly can longitudinally move on the main beam through the sliding block, so that the multidirectional adjustment of the connecting assembly is realized, and the installation accuracy of the photovoltaic module is improved.

Drawings

FIG. 1 is a schematic view of a connection assembly of the present utility model;

FIG. 2 is a schematic view of a press according to the present utility model;

FIG. 3 is a front view of FIG. 2 of the present utility model;

FIG. 4 is a diagram of the exploded view of FIG. 2 of the present utility model;

FIG. 5 is a schematic view of a second embodiment of the present utility model;

fig. 6 is a front view of fig. 5 of the present utility model.

Description of the symbols in the drawings

1. The clamping device comprises a clamp, 2, a supporting frame, 3, a main beam, 4, a pressing tool, 41, an upper pressing piece, 42, a lower pressing piece, 5, a sliding block, 6, an extension beam, 7, a guide frame, 8, an adjusting screw, 9, a slot, 10, a strip-shaped slot, 11, a nut pair, 12 and a bolt component.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. Various modifications can be made to the embodiments as long as the effects of the present utility model can be exerted.

The components in the present case are sequentially connected by a person skilled in the art, and specific connection and operation sequence should be referred to the following working principle, and the detailed connection means thereof are known in the art, and the following working principle and process are mainly described.

The steel structure roofing and photovoltaic module connection assembly of the present embodiment will be described with reference to fig. 1 to 6, and the connection assembly includes:

a clamp 1; is matched with and fixedly connected with the steel structure roof.

The support frame 2 is fixedly connected to the top of the clamp 1 and can transversely adjust the fixing position along the top of the clamp 1;

a strip-shaped groove 10 is formed in the bottom panel of the supporting frame 2, a bolt component 12 is fixedly connected to the top surface of the clamp 1, and the bolt component 12 penetrates through the strip-shaped groove 10 to fixedly connect the supporting frame 2 to the top of the clamp 1. The supporting frame 2 is transversely adjusted, so that the strip-shaped groove 10 on the bottom panel of the supporting frame 2 is adjusted according to the bolt assembly 12, the transverse adjustment of the supporting frame 2 is realized, and the transverse position adjustment of the connecting assembly is further realized.

Wherein the bolt assembly 12 is movable within the bar-shaped groove 10 to adjust the fixing position of the support frame 2 on the jig 1.

The bolt assembly 12 comprises a bolt fixedly connected with the clamp 1 and a nut screwed on the bolt, and the nut is pressed on the top of the strip-shaped groove 10.

After the position of the supporting frame 2 is adjusted, the bolts are fastened by screwing the nuts to fix the supporting frame 2.

And the main beam 3 is assembled on the top panel of the supporting frame 2 and is vertically adjusted on the supporting frame 2 through a screw rod assembly.

The screw assembly comprises an adjusting screw rod 8 fixedly connected with the main beam 3 and a nut pair 11 screwed on the adjusting screw rod 8; the adjusting screw 8 penetrates through the top panel of the supporting frame 2 and can move up and down, and the nut pair 11 comprises a plurality of nuts which clamp the top panel of the supporting frame 2 to fix the adjusting screw 8.

The height adjustment method of the main beam 3 comprises the following steps: all nuts of the nut pair 11 are loosened, the height of the adjusting screw rod 8 is adjusted, and all nuts are screwed until the main beam 3 is positioned at the proper height.

In order to improve the stability when adjusting the girder 3, the bottom four corners of the girder 3 are vertically extended downwards to form a guide frame 7, and the guide frame 7 penetrates through the top surface of the supporting frame 2, so that the girder 3 is not twisted when being adjusted in height by the adjusting component.

By adopting the design, the height adjustment of the connecting component can be realized, and the screw rod 8 can ensure that the main beam 3 cannot rotate when the height of the main beam 3 is adjusted.

One or both ends of the main beam 3 are outwardly extended to form an extension beam 6 to lengthen the fixing position of the fixing assembly. The length of the main beam 3 can be prolonged through the extension beam 6, so that the fixing component can have longer adjustment distance and is clamped and fixed at multiple points of the photovoltaic component.

The two side surfaces of the supporting frame 2 are provided with grooves 9, and the grooves 9 can be penetrated by a tool to enable the bolt component 12 and the nut pair 11 to be screwed. The supporting frame 2 forms a hollowed-out frame through the grooves 9, so that the main beam 3 can be supported, the weight of the main body is reduced, and meanwhile, the tool can be conveniently used for the bolt assembly 12 and the nut pair 11.

And the fixing component can move along the longitudinal direction of the main beam 3 and is fixed on the main beam 3, and is used for fixing the photovoltaic component.

The fixed subassembly includes:

the sliding block 5 is fixed on the main beam 3;

in one embodiment, the top surface of the main beam 3 is a plane, and the slider 5 is mounted on the plane of the main beam 3 and is fixed by bolts.

In another embodiment, as shown in fig. 2, a groove is formed on the top surface of the main beam 3 longitudinally, the sliding block 5 slides in the groove, a bolt is installed on the sliding block 5, and the bolt is screwed tightly against the bottom of the groove to fix the sliding block 5.

With this design, a longitudinal direction adjustment of the connection assembly can be achieved.

The presser 4, the presser 4 includes:

a lower pressing piece 42 fixed on the slide block;

the upper presser 41 is connected to the upper side of the lower presser 42 by a bolt rod.

In one embodiment, the bolt rod is sleeved with a spring disc, and the top surface and the bottom surface of the spring disc respectively prop against the upper pressing piece 41 and the lower pressing piece 42. The upper pressing piece 41 can be supported, an opening is formed between the upper pressing piece 41 and the lower pressing piece 42, and the looseness of the bolt rod caused by vibration of the photovoltaic module can be prevented.

In one embodiment, as shown in fig. 6, the upper press piece 41 of the press 4 is connected to one end of the lower press piece 42, and the other end forms an opening, and the opening sandwiches the photovoltaic module. In this embodiment, the presser 4 sandwiches the photovoltaic module when a new photovoltaic module is not required to be mounted on the side surface of the outermost photovoltaic module.

In one embodiment, as shown in fig. 3, the upper and lower press sheets 41 and 42 are formed with openings at both ends, and the openings sandwich the photovoltaic module. In this embodiment, when two photovoltaic modules are tiled, the openings at both ends can sandwich the photovoltaic modules by using the press 4.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A steel construction roofing and photovoltaic module coupling assembling, its characterized in that: the connection assembly includes:

a clamp (1);

the support frame (2) is fixedly connected to the top of the clamp (1) and can transversely adjust the fixing position along the top of the clamp (1);

the main beam (3) is assembled on the top panel of the supporting frame (2) and is vertically adjusted on the supporting frame (2) through the screw rod assembly;

and the fixing component can move along the longitudinal direction of the main beam (3) and is fixed on the main beam (3), and the fixing component is used for fixing the photovoltaic component.

2. The steel structure roof and photovoltaic module connection assembly of claim 1, wherein: the bottom panel of the supporting frame (2) is provided with a strip-shaped groove (10), the top surface of the clamp (1) is fixedly connected with a bolt component (12), and the bolt component (12) penetrates through the strip-shaped groove (10) to fixedly connect the supporting frame (2) to the top of the clamp (1);

wherein the bolt assembly (12) can move in the strip-shaped groove (10) to adjust the fixing position of the supporting frame (2) on the clamp (1).

3. The steel structure roof and photovoltaic module connection assembly of claim 2, wherein: the bolt assembly (12) comprises a bolt fixedly connected with the clamp (1) and a nut screwed on the bolt, and the nut is pressed on the top of the strip-shaped groove (10).

4. A steel structure roofing and photovoltaic module connection assembly according to claim 3, wherein: the screw assembly comprises an adjusting screw (8) fixedly connected with the main beam (3) and a nut pair (11) screwed on the adjusting screw (8); the adjusting screw (8) penetrates through the top panel of the supporting frame (2) and can move up and down, the nut pair (11) comprises a plurality of nuts, and the nuts clamp the top panel of the supporting frame (2) to fix the adjusting screw (8).

5. The steel structure roof and photovoltaic module connection assembly of claim 4, wherein: the four corners of the bottom of the main beam (3) vertically extend downwards to form a guide frame (7), and the guide frame (7) penetrates through the top surface of the supporting frame (2) so that the main beam (3) is not twisted when the height of the main beam is adjusted by the adjusting component.

6. A steel structure roofing and photovoltaic module connection assembly according to any one of claims 3 or 4, wherein: the two side surfaces of the supporting frame (2) are provided with grooves (9), and the grooves (9) can be penetrated by a tool to enable the bolt component (12) and the nut pair (11) to be screwed.

7. The steel structure roof and photovoltaic module connection assembly of claim 1, wherein: one end or two ends of the main beam (3) extend outwards to form an extension beam (6) so as to prolong the fixing position of the fixing assembly.

8. The steel structure roof and photovoltaic module connection assembly of claim 1, wherein: the fixing assembly includes:

the sliding block (5) is fixed on the main beam (3);

a presser (4), the presser (4) comprising:

a lower pressing piece (42) fixed on the sliding block;

the upper pressing piece (41) is connected above the lower pressing piece (42) through a bolt rod.

9. The steel structure roof and photovoltaic module connection assembly of claim 8, wherein: the upper pressing piece (41) is connected with one end of the lower pressing piece (42), an opening is formed in the other end of the upper pressing piece, and the opening clamps the photovoltaic module.

10. The steel structure roof and photovoltaic module connection assembly of claim 8, wherein: openings are formed at two ends of the upper pressing sheet (41) and the lower pressing sheet (42), and the openings clamp the photovoltaic module.