CN218633804U - Adjustable support of photovoltaic concrete - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic connecting supports, in particular to a photovoltaic concrete adjustable support.A connecting component is fixed on each embedded part; the connecting assembly comprises two connecting plates which are rotatably connected; the connecting plates are rotationally connected through a rotating shaft; two connecting plates of the connecting assembly are respectively connected to the embedded part and the photovoltaic assembly; the rod body of the screw rod is connected in the arc-shaped groove in a sliding manner; the screw rod is connected with a nut which clamps and fixes two connecting plates on the same connecting assembly; a plurality of connecting holes are formed in the connecting plate; the photovoltaic module is fixedly connected with the connecting plate after the connecting screw of the sandal strip penetrates through one of the connecting holes. When the utility model is used, the installation position and the installation angle of the connecting component can be adjusted by arranging a plurality of connecting holes and the screw rod can slide in the arc-shaped groove; even the embedded part is not enough in the position accuracy of the concrete pier, the photovoltaic module can be installed in place.

Description

Adjustable support of photovoltaic concrete

Technical Field

The utility model relates to a photovoltaic linking bridge technical field, in particular to adjustable support of photovoltaic concrete.

Background

With the development of photovoltaic power utilization, the use of photovoltaic panels laid on the roof of a house is a trend. The guide rail of the photovoltaic panel is connected to a cement pier of the house roof through a connecting support.

In order to improve the daylighting rate of the photovoltaic panel, the photovoltaic panel is generally arranged on a roof at a certain inclination angle, so that the heights of two concrete piers for mounting the photovoltaic panel are different; inserting embedded parts for connecting the brackets during molding;

after the concrete pier is cast and formed, the height of the concrete pier is difficult to accurately control; the embedded part is inaccurately positioned when being dried and fixed and inserted into the concrete; therefore, the position precision of the embedded part of the dried and solidified concrete is difficult to be accurately controlled; but the bracket for mounting the photovoltaic panel cannot be finely adjusted according to the height of the concrete; therefore, the bracket or the embedded part needs to be bent on the construction site, and the bracket is stably connected with the embedded part.

The field bending mode has high labor intensity and is easy to damage cement piers.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a photovoltaic concrete adjustable support to prior art's defect and not enough.

In order to achieve the above object, the utility model adopts the following technical scheme:

the utility model relates to a photovoltaic concrete adjustable bracket, which comprises an embedded part which is embedded and fixed on a concrete pier; the embedded parts are fixed with connecting components; the two connecting assemblies are arranged on the same vertical plane; the connecting assembly comprises two connecting plates which are rotatably connected; the connecting plates are rotationally connected through a rotating shaft; two connecting plates of the connecting assembly are respectively connected to the embedded part and the photovoltaic assembly;

two connecting plates in the same connecting assembly are respectively a first connecting plate and a second connecting plate; a screw is fixed on the first connecting plate; an arc-shaped groove is formed in the second connecting plate; the rod body of the screw rod is connected in the arc-shaped groove in a sliding manner; the screw rod is connected with a nut which clamps and fixes two connecting plates on the same connecting assembly; a plurality of connecting holes are formed in the connecting plate; the photovoltaic module is fixedly connected with the connecting plate after the connecting screw of the sandal strip penetrates through one of the connecting holes.

Further, the rotating shaft is a bolt; the bolt is connected with a nut in a threaded manner.

Further, the embedded parts are U-shaped parts; two ends of the U-shaped part extend out of the concrete pier; external threads are arranged at two ends of the U-shaped piece; the connecting plate is locked on the concrete pier after being connected on the external thread through a fastening nut thread.

Furthermore, the connecting plate consists of two semicircular plates which are arranged vertically to each other; the two semicircular plates are formed by bending a circular plate.

After the structure is adopted, the utility model discloses beneficial effect does: when the utility model is used, the sandal wood strips are fixedly connected on the connecting piece of the photovoltaic module; the sandal wood strips are fixed on the connecting plate; because the height of the concrete piers is inconsistent and the height difference of the two concrete piers connected to the photovoltaic module is also inconsistent, the two connecting plates can relatively rotate by loosening the nut on the screw rod, the screw rod slides in the arc-shaped groove to adjust the swing angle of the photovoltaic module, and after the angle is adjusted, the two connecting plates are inserted into and connected to corresponding positions through the sandal bar connecting screw; the photovoltaic module can be connected to two concrete piers with different height differences; the installation position and the installation angle of the connecting assembly can be adjusted by arranging the connecting holes and enabling the screw rods to slide in the arc-shaped grooves; even if the position accuracy of the embedded part on the concrete pier is not enough, the photovoltaic module can be installed in place.

Drawings

FIG. 1 is a schematic diagram of the present invention;

FIG. 2 is a schematic structural view of the present invention connected to a split concrete pier;

FIG. 3 is a schematic structural view of the integrated concrete pier of the present invention;

FIG. 4 is a block diagram of a connection plate;

description of the reference numerals:

A. concrete piers; 1. a connecting plate; 101. an arc-shaped slot; 102. a semicircular plate; 103. connecting holes; 2. fastening a nut; 3. embedding parts; 4. a connecting member; 5. sandal wood strips; 6. a photovoltaic module; 7. a screw; 8. a rotating shaft; 9. wingceltis strip connecting screw.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

As shown in fig. 1 to 4, the adjustable photovoltaic concrete support of the present invention comprises an embedded part 3 pre-embedded and fixed on a concrete pier a; the embedded parts 3 are all fixed with connecting components; the two connecting assemblies are arranged on the same vertical plane; the connecting assembly comprises two connecting plates 1 which are rotatably connected; the connecting plates 1 are rotationally connected through a rotating shaft 8; two connecting plates 1 of the connecting assembly are respectively connected to the embedded part 3 and the photovoltaic assembly 6;

two connecting plates 1 in the same connecting assembly are respectively a first connecting plate and a second connecting plate; a screw 7 is fixed on the first connecting plate; an arc-shaped groove 101 is formed in the second connecting plate; the rod body of the screw rod 7 is connected in the arc-shaped groove 101 in a sliding manner; the screw 7 is connected with a nut which clamps and fixes the two connecting plates 1 on the same connecting assembly; a plurality of connecting holes 103 are formed in the connecting plate 1; the photovoltaic module 6 is fixedly connected with the connecting plate 1 after the sandalwood strip connecting screw 9 passes through one of the connecting holes 103; the photovoltaic module 6 is not essentially different from the prior art, and therefore, it is not described in detail; the connecting piece 4 of the photovoltaic module 6 is fixedly connected with the sandal wood strip 5; the sandal wood strips 5 are fixed on the connecting plate 1; because the heights of the concrete piers A are not consistent, and the height difference of the two concrete piers A connected to the photovoltaic module 6 can also be inconsistent, the two connecting plates 1 relatively rotate by loosening the nuts on the screw rods 7, the screw rods 7 slide in the arc-shaped grooves 101 to adjust the swing angles of the photovoltaic module 6, and after the angles are adjusted, the connecting bolts are inserted into the corresponding positions through the sandal strip connecting screws 9; so that the photovoltaic module 6 can be connected to two concrete piers A with different height differences; the connecting holes 103 and the screw 7 can slide in the arc-shaped groove 101, so that the mounting position and the mounting angle of the connecting assembly can be adjusted; even if the position accuracy of the embedded part 3 on the concrete pier A is not enough, the photovoltaic module 6 can be installed in place.

As a preferred mode of the present invention, the rotating shaft 8 is a bolt; the bolt is in threaded connection with a nut; when the relative angle of the two connecting plates 1 needs to be adjusted, the connecting plates can be used as rotating shafts by loosening nuts and bolts; after the regulation finishes, lock the nut on the bolt again, fix two 1 centre gripping of connecting plate for after 6 location photovoltaic module, two more difficult relative rotations of connecting plate 1, two connection 1 are more stable.

As a preferred mode of the present invention, the embedded part 3 is a U-shaped part; two ends of the U-shaped part extend out of the concrete pier A; external threads are arranged at two ends of the U-shaped piece; the connecting plate 1 is connected to the external thread through a fastening nut 2 in a threaded manner and then locked on the concrete pier A; the embedded part 3 of the U-shaped structure is more firmly connected to the concrete pier A and is connected with the embedded part 3 at two points, so that the connection strength of the connecting plate 1 and the embedded part 3 is improved.

As a preferred mode of the present invention, the connecting plate 1 is composed of two semicircular plates 102 disposed perpendicular to each other; the two semicircular plates 102 are formed by bending a circular plate.

When the utility model is used, the sandal wood strips are fixedly connected on the connecting pieces of the photovoltaic module; the sandal wood strips are fixed on the connecting plate; because the heights of the concrete piers are inconsistent and the height difference of the two concrete piers connected to the photovoltaic module is also possibly inconsistent, the nuts on the screw rods are loosened, and the nuts on the rotating shafts are loosened;

the two connecting plates rotate relatively, the screw rod slides in the arc-shaped groove to adjust the swing angle of the photovoltaic module, and after the angle is adjusted, the two connecting plates are inserted into the corresponding positions through the sandalwood strip connecting screws; the photovoltaic module can be connected to two concrete piers with different height differences; the installation position and the installation angle of the connecting assembly can be adjusted by arranging the connecting holes and enabling the screw rods to slide in the arc-shaped grooves; even if the embedded part is not accurate enough in the concrete pier position, the photovoltaic module can be installed.

The above is only the preferred embodiment of the present invention, so all the equivalent changes or modifications made by the structure, features and principles in accordance with the claims of the present invention are included in the claims of the present invention.

Claims (4)

1. The utility model provides a photovoltaic concrete adjustable bracket which characterized in that: the device comprises an embedded part (3) which is embedded and fixed on a concrete pier (A); the embedded parts (3) are fixed with connecting components; the two connecting assemblies are arranged on the same vertical plane; the connecting assembly comprises two connecting plates (1) which are rotatably connected; the connecting plates (1) are rotationally connected through a rotating shaft (8); two connecting plates (1) of the connecting assembly are respectively connected to the embedded part (3) and the photovoltaic assembly (6);

two connecting plates (1) in the same connecting assembly are respectively a first connecting plate and a second connecting plate; a screw (7) is fixed on the first connecting plate; an arc-shaped groove (101) is formed in the second connecting plate; the rod body of the screw rod (7) is connected in the arc-shaped groove (101) in a sliding manner; the screw (7) is connected with a nut which clamps and fixes the two connecting plates (1) on the same connecting assembly; a plurality of connecting holes (103) are formed in the connecting plate (1); the photovoltaic module (6) is fixedly connected with the connecting plate (1) after the sandalwood strip connecting screw (9) penetrates through one connecting hole (103).

2. The adjustable photovoltaic concrete support of claim 1, wherein: the rotating shaft (8) is a bolt; the bolt is connected with a nut in a threaded manner.

3. The adjustable photovoltaic concrete support of claim 1, wherein: the embedded part (3) is a U-shaped part; the two ends of the U-shaped part extend out of the concrete pier (A); external threads are arranged at two ends of the U-shaped piece; the connecting plate (1) is connected to the external thread through a fastening nut (2) in a threaded mode and then locked on the concrete pier (A).

4. The adjustable photovoltaic concrete support of claim 1, wherein: the connecting plate (1) is composed of two semicircular plates (102) which are arranged vertically; the two semicircular plates (102) are formed by bending a circular plate.

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