CN220139485U - Tracking type photovoltaic bracket - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic supports, and aims to solve the problems of complex structure, difficult installation and troublesome maintenance and replacement of the existing tracking type photovoltaic support; the automatic rope winding assembly and the carrier rope guiding assembly are arranged on the upright post, a carrier rope is connected between the automatic rope winding assembly and the inclined beam, the carrier rope is arranged across the carrier rope guiding assembly, and the inclined beam is respectively connected with the carrier rope at two sides of the upright post; the tracking type photovoltaic bracket disclosed by the utility model is simple in structure, convenient to install, convenient to maintain and replace, strong in durability, small in steel consumption, capable of improving daily average power generation amount and reducing construction and operation and maintenance costs.

Description

Tracking type photovoltaic bracket

Technical Field

The utility model relates to the technical field of photovoltaic supports, in particular to a tracking type photovoltaic support.

Background

The photovoltaic power generation needs to adapt to the angle of the sun, so that a photovoltaic support is arranged on the photovoltaic panel, and the photovoltaic panel is in an inclined state, so that a better photoelectric conversion effect is achieved. The existing conventional photovoltaic module support is fixed in orientation and angle, so that the solar energy utilization efficiency is low. The existing tracking type photovoltaic bracket is provided with a tracking system, and can be used for angle adjustment, but has the defects of complex structure, difficult installation and troublesome maintenance and replacement. For example, the chinese patent publication No. CN110825125B discloses a curved surface type revolving pitch integrated double-shaft tracking photovoltaic bracket, which has complex structure, multiple components and is inconvenient to install and replace.

Disclosure of Invention

The utility model aims to provide a tracking type photovoltaic bracket so as to solve the problems of complex structure, difficult installation and troublesome maintenance and replacement of the existing tracking type photovoltaic bracket.

The utility model is realized by adopting the following technical scheme:

the utility model provides a tracking type photovoltaic bracket which comprises a bracket main body, an automatic rope winding assembly and a carrier rope guiding assembly, wherein the bracket main body comprises an upright post and an inclined beam, and the inclined beam is rotationally connected to the upright post;

the automatic rope winding assembly and the carrier rope guiding assembly are mounted on the upright post, a carrier rope is connected between the automatic rope winding assembly and the inclined beam, the carrier rope is arranged across the carrier rope guiding assembly, and the inclined beam is respectively connected with the carrier rope at two sides of the upright post.

As a preferable technical scheme:

two carrier cable anchoring assemblies are arranged on the inclined beam, the two carrier cable anchoring assemblies are respectively positioned on two sides of the upright post, one end of the carrier cable is connected with the carrier cable anchoring assemblies, and the other end of the carrier cable is connected with the automatic rope winding assembly.

As a preferable technical scheme:

the automatic rope winding assembly and the carrier rope guiding assembly are fixedly connected to the upright posts, and the carrier rope anchoring assembly is fixedly connected to the oblique beam.

As a preferable technical scheme:

the automatic rope winding assembly comprises a photoelectric sensor and an intelligent mechanical assembly for providing the tensile force of the carrier rope, the photoelectric sensor is used for sensing the light intensity change, the photoelectric sensor converts the sensed light intensity change into an electric signal to be transmitted to the intelligent mechanical assembly, a rotating wheel is arranged in the intelligent mechanical assembly and is connected with the carrier rope, the intelligent mechanical assembly changes the movement mode of the rotating wheel in the intelligent mechanical assembly according to the electric signal, releases or retracts the connected carrier rope, and changes the length of the carrier rope outside.

As a preferable technical scheme:

the carrier cable anchoring assembly comprises a supporting plate and a carrier cable anchoring wire clamp, the supporting plate and the carrier cable anchoring wire clamp are connected, the supporting plate is connected to the inclined beam, and the carrier cable anchoring wire clamp is used for clamping one end of the carrier cable.

As a preferable technical scheme:

the supporting plate is fixedly connected with the inclined beam through bolts.

As a preferable technical scheme:

the supporting plate is connected with the carrier cable anchoring wire clamp through a connecting bolt, a bearing is arranged between the connecting bolt and the supporting plate, the connecting bolt can rotate, and the carrier cable anchoring wire clamp can rotate around the connecting bolt.

As a preferable technical scheme:

the carrier cable guiding assembly comprises a guiding bearing and a fixed lug plate, wherein the guiding bearing is connected to the fixed lug plate through a limiting shaft, and the fixed lug plate is fixedly connected to the upright post.

As a preferable technical scheme:

the guide bearing is provided with a groove which is used for limiting the position of the carrier rope.

As a preferable technical scheme:

the inclined beam is connected to the upright post through an inclined beam rotating assembly, and the inclined beam rotating assembly comprises a rotating bearing, and the rotating bearing is connected between the upright post and the inclined beam.

In summary, due to the adoption of the technical scheme, the beneficial effects of the utility model are as follows:

1. the tracking type photovoltaic support realizes electric control rotation according to sunlight intensity, has few required precise parts, simple structure, convenient installation, convenient maintenance and replacement, strong durability and small steel consumption, improves daily power generation, improves the related problems of complex structure, difficult installation and troublesome maintenance and replacement of the tracking type photovoltaic support, and reduces construction and operation and maintenance costs.

2. The carrier cable anchoring assembly is in a modularized design, and can be conveniently detached and used as an independent functional module or added on other equipment for use.

3. According to the utility model, the free rotation around the shaft of the inclined beam is realized by changing the tension and the length of the carrier ropes at the two sides of the inclined beam and matching with the inclined beam rotating assembly, so that the tracking of higher illumination quantity is realized.

4. The carrier cords of the present utility model are not limited in number and length.

Drawings

Fig. 1 is a schematic partial structure of a tracking photovoltaic support according to the present utility model.

Fig. 2 is a schematic structural diagram of the tracking photovoltaic bracket according to the present utility model.

Fig. 3 is an elevation view of a messenger anchor assembly according to the present utility model.

Fig. 4 is a side view of a messenger anchor assembly according to the present utility model.

Fig. 5 is a front view of a carrier cable guide assembly according to the present utility model.

Fig. 6 is a side view of a carrier cable guide assembly according to the present utility model.

Fig. 7 is a perspective view of fig. 6.

Fig. 8 is a schematic structural view of the oblique beam rotating assembly according to the present utility model.

Icon: the device comprises a 1-automatic rope winding assembly, a 2-carrier rope anchoring assembly, a 201-supporting plate, a 202-carrier rope anchoring wire clamp, 203-connecting bolts, a 3-carrier rope guiding assembly, 301-guiding bearings, 302-fixed lug plates, a 4-inclined beam rotating assembly, 401-rotating bearings, a 5-bracket main body, 501-inclined beams, 502-upright posts and 6-carrier ropes.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

As shown in fig. 1 and 2, the present embodiment proposes a tracking type photovoltaic support, which includes a support body 5, an automatic rope winding assembly 1, a carrier rope anchoring assembly 2, a carrier rope guiding assembly 3, and a diagonal beam rotating assembly 4.

The support body 5 comprises inclined beams 501, purlines, upright columns 502 and other structural bodies for supporting photovoltaic modules, specifically, the upright columns 502 are vertically arranged and arranged at intervals, the inclined beams 501 are rotationally connected to the upright columns 502, and the purlines are connected between every two adjacent inclined beams 501.

The automatic rope winding assembly 1 and the carrier rope guiding assembly 3 are fixedly connected to the upright post 502, and the carrier rope anchoring assembly 2 is fixedly connected to the inclined beam 501. In this embodiment, two carrier cable anchoring assemblies 2 are installed on the oblique beam 501, two carrier cable anchoring assemblies 2 are located at two sides of the upright 502 respectively, two automatic rope winding assemblies 1 and carrier cable guiding assemblies 3 are installed on the upright 502, a carrier cable 6 is arranged between each carrier cable anchoring assembly 2 and a corresponding automatic rope winding assembly 1, each carrier cable 6 is a flexible cable, each carrier cable 6 is arranged across the corresponding carrier cable guiding assembly 3 respectively, and the automatic rope winding assemblies 1 are used for adjusting the tension and length of the carrier cables 6 at two sides, so that the oblique beam 501 rotates around the upright 502 to track a higher illumination amount.

The automatic rope winding assembly 1 is adjustably arranged at various positions of the upright 502, in this embodiment the automatic rope winding assembly 1 is arranged above the oblique beam 501. The automatic rope winding assembly 1 comprises a photoelectric sensor and an intelligent mechanical assembly for providing the tensile force of the carrier rope 6. The photoelectric sensor is used for sensing light intensity change, and converts the sensed light intensity change into an electric signal to be transmitted to the intelligent mechanical component. The intelligent mechanical assembly is internally provided with a rotating wheel, the rotating wheel is connected with the carrier rope 6, the intelligent mechanical assembly changes the movement mode of the rotating wheel inside according to an electric signal, releases or retracts the connected carrier rope 6, and changes the length of the carrier rope 6 outside.

The messenger anchor assemblies 2 are adjustably positioned at various locations on the diagonal beam 501, but one messenger anchor assembly 2 on each side of the upright 502 is required. As shown in fig. 3 to fig. 4, the carrier cable anchoring assembly 2 includes a pallet 201 and a carrier cable anchoring clip 202, the carrier cable anchoring clip 202 is used for clamping one end of the carrier cable 6, the pallet 201 is fixedly connected with the diagonal member 501 through a bolt, the pallet 201 is connected with the carrier cable anchoring clip 202 through a connecting bolt 203, a bearing is disposed between the connecting bolt 203 and the pallet 201, the connecting bolt 203 can rotate, when the automatic rope winding assembly 1 works, the force applied to the carrier cable 6 is changed, so that the displacement of the carrier cable 6 is changed, the direction of the carrier cable 6 is changed, and the carrier cable anchoring clip 202 rotates around the connecting bolt 203, so that the direction of the carrier cable 6 is always kept consistent with that of the carrier cable anchoring clip 202.

The carrier guide assemblies 3 are adjustably positioned at various locations of the upright 502, in this embodiment the carrier guide assemblies 3 are positioned at the top ends of the upright 502. As shown in fig. 5-7, the carrier cable guiding assembly 3 includes a guiding bearing 301 and a fixed lug plate 302, the guiding bearing 301 is connected to the fixed lug plate 302 through a limiting shaft, the fixed lug plate 302 is fixedly connected to the upright 502, and a groove on the guiding bearing 301 is used for limiting the position of the carrier cable 6. When the automatic rope winding assembly 1 works, the carrier rope 6 is connected to the carrier rope anchoring wire clamp 202 after being limited by the carrier rope guiding assembly 3.

The oblique beam 501 is connected with the upright 502 through the oblique beam rotating assembly 4, as shown in fig. 8, the oblique beam rotating assembly 4 includes a rotating bearing 401 and parts corresponding to and fixed on the rotating bearing 401, where the parts corresponding to and fixed on the rotating bearing 401 may be bolts, pins or other shaft parts, the rotating bearing 401 is mounted on the upright 502 through bolts, pins or other shaft parts, and the oblique beam 501 is fixedly connected on an outer ring of the rotating bearing 401. When the automatic rope winding assembly 1 works, different forces are applied to the two carrier rope anchoring assemblies 2 through the carrier ropes 6, so that the forces generate different moments on two sides of the inclined beam 501, the inclined beam rotating assembly 4 rotates, the inclined beam 501 rotates around the inclined beam rotating assembly 4 according to the moments, and electric control rotation is realized according to sunlight intensity sensed by the photoelectric sensor.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A tracking photovoltaic support, characterized in that:

the automatic rope winding device comprises a bracket main body, an automatic rope winding assembly and a carrier rope guiding assembly, wherein the bracket main body comprises an upright post and an inclined beam, and the inclined beam is rotationally connected to the upright post;

the automatic rope winding assembly and the carrier rope guiding assembly are mounted on the upright post, a carrier rope is connected between the automatic rope winding assembly and the inclined beam, the carrier rope is arranged across the carrier rope guiding assembly, and the inclined beam is respectively connected with the carrier rope at two sides of the upright post.

2. The tracking photovoltaic support of claim 1, wherein:

two carrier cable anchoring assemblies are arranged on the inclined beam, the two carrier cable anchoring assemblies are respectively positioned on two sides of the upright post, one end of the carrier cable is connected with the carrier cable anchoring assemblies, and the other end of the carrier cable is connected with the automatic rope winding assembly.

3. The tracking photovoltaic support of claim 2, characterized in that:

the automatic rope winding assembly and the carrier rope guiding assembly are fixedly connected to the upright posts, and the carrier rope anchoring assembly is fixedly connected to the oblique beam.

4. The tracking photovoltaic support of claim 1, wherein:

the automatic rope winding assembly comprises a photoelectric sensor and an intelligent mechanical assembly for providing the tensile force of the carrier rope, the photoelectric sensor is used for sensing the light intensity change, the photoelectric sensor converts the sensed light intensity change into an electric signal to be transmitted to the intelligent mechanical assembly, a rotating wheel is arranged in the intelligent mechanical assembly and is connected with the carrier rope, the intelligent mechanical assembly changes the movement mode of the rotating wheel in the intelligent mechanical assembly according to the electric signal, releases or retracts the connected carrier rope, and changes the length of the carrier rope outside.

5. The tracking photovoltaic support of claim 2, characterized in that:

the carrier cable anchoring assembly comprises a supporting plate and a carrier cable anchoring wire clamp, the supporting plate and the carrier cable anchoring wire clamp are connected, the supporting plate is connected to the inclined beam, and the carrier cable anchoring wire clamp is used for clamping one end of the carrier cable.

6. The tracking photovoltaic support of claim 5, wherein:

the supporting plate is fixedly connected with the inclined beam through bolts.

7. The tracking photovoltaic support of claim 5, wherein:

the supporting plate is connected with the carrier cable anchoring wire clamp through a connecting bolt, a bearing is arranged between the connecting bolt and the supporting plate, the connecting bolt can rotate, and the carrier cable anchoring wire clamp can rotate around the connecting bolt.

8. The tracking photovoltaic support of claim 1, wherein:

the carrier cable guiding assembly comprises a guiding bearing and a fixed lug plate, wherein the guiding bearing is connected to the fixed lug plate through a limiting shaft, and the fixed lug plate is fixedly connected to the upright post.

9. The tracking photovoltaic support of claim 8, wherein:

the guide bearing is provided with a groove which is used for limiting the position of the carrier rope.

10. The tracking photovoltaic support of claim 1, wherein:

the inclined beam is connected to the upright post through an inclined beam rotating assembly, and the inclined beam rotating assembly comprises a rotating bearing, and the rotating bearing is connected between the upright post and the inclined beam.