CN220139482U - But angle regulation's photovoltaic support - Google Patents

Abstract

The utility model relates to an angle-adjustable photovoltaic bracket. Is applicable to the technical field of photovoltaic brackets. The technical scheme adopted by the utility model is as follows: an adjustable angle's photovoltaic support, its characterized in that: the photovoltaic module comprises a plurality of support columns and main beams arranged at the top ends of the support columns, wherein the support columns are connected with the main beams through bearing mechanisms, purlines for supporting the photovoltaic modules are arranged on the main beams, the purlines are vertically arranged with the main beams, and an angle adjusting mechanism is arranged between the support columns and the main beams; the angle adjusting mechanism is provided with a telescopic rod arranged on the supporting column and a limiting block sleeved on the main beam, the end part of the limiting block, which is in contact with the telescopic rod, is in a step shape, and the telescopic rod which stretches to each length can be matched with the step matched with the telescopic rod on the limiting block. Therefore, when the angle of the photovoltaic bracket needs to be adjusted, the angle of the photovoltaic bracket is adjusted by extending the telescopic rod to a corresponding length and moving the main beam to the contact position of the limiting block on the main beam and the telescopic rod.

Description

But angle regulation's photovoltaic support

Technical Field

The utility model relates to an angle-adjustable photovoltaic bracket. Is applicable to the technical field of photovoltaic brackets.

Background

In the technical field of solar photovoltaic, a photovoltaic panel is generally installed on a field, and the photovoltaic panel converts absorbed solar energy into electric energy and then transmits the electric energy. According to the principle of photovoltaic power generation, when sunlight vertically irradiates on a photovoltaic panel, the power generation efficiency of the photovoltaic panel is highest. However, the incident angle of sunlight changes with time and season due to the influence of rotation and revolution of the earth, so that the installation angle of the photovoltaic panel needs to be adjusted to have high power generation efficiency. Some devices capable of adjusting the photovoltaic support according to the incident angle of sunlight can adjust the installation angle of the photovoltaic panel in real time, so that the photovoltaic panel is always vertical to the incident angle of sunlight, however, the devices need to acquire the incident angle of sunlight in real time and adjust the angle of the photovoltaic panel according to the acquired incident angle of sunlight in real time, and the device has a complex structure and can continuously consume energy in the operation process.

Therefore, in the technical field of solar energy photovoltaics, the angle adjusting mechanism with a simple structure is arranged on the photovoltaic support, so that the photovoltaic electric plate arranged on the photovoltaic support changes and adjusts the position according to seasons, and the device is simplified and the energy consumption is reduced while the photovoltaic support has good power generation efficiency. However, the current angle adjusting mechanism is generally a bearing locking device installed at the position of a bearing mechanism between a support column and a main beam on a photovoltaic support, or a telescopic rod is installed between the support column and a purline, one end of the telescopic rod is hinged on the support column, and the other end of the telescopic rod is hinged on the purline. However, in the mode of bearing locking devices at the bearing mechanism positions between the support columns and the main beams, the bearing locking devices bear stress on the photovoltaic brackets, so that the bearing locking devices have higher stress resistance requirements and are easy to damage when used for a long time; the mode of installing the telescopic link between support column and purlin is stressed by the bearing in the hinge of telescopic link both ends, and the pivot in the hinge of telescopic link both ends takes place to fracture easily and damages when long-time use.

Disclosure of Invention

The utility model aims to solve the technical problems that: in order to solve the technical problems, the utility model provides an angle-adjustable photovoltaic bracket.

The technical scheme adopted by the utility model is as follows: an adjustable angle's photovoltaic support, its characterized in that: the photovoltaic module comprises a plurality of support columns and main beams arranged at the top ends of the support columns, wherein the support columns are connected with the main beams through bearing mechanisms, purlines for supporting the photovoltaic modules are arranged on the main beams, the purlines are vertically arranged with the main beams, and an angle adjusting mechanism is arranged between the support columns and the main beams;

the angle adjusting mechanism is provided with a telescopic rod arranged on the supporting column and a limiting block sleeved on the main beam, the end part of the limiting block, which is in contact with the telescopic rod, is in a step shape, and the telescopic rod which stretches to each length can be matched with the step matched with the telescopic rod on the limiting block. Therefore, when the angle of the photovoltaic bracket needs to be adjusted, the angle of the photovoltaic bracket is adjusted by extending the telescopic rod to a corresponding length and moving the main beam to the contact position of the limiting block on the main beam and the telescopic rod.

The telescopic rod is connected with a controller circuit, and the controller is used for controlling the telescopic rod to stretch and retract. Thus, a person can conveniently control the telescopic rod to stretch and retract through the operation controller.

An electric sliding rail is arranged on the bottom surface of the main beam along the purline arrangement direction, a sliding block is slidably arranged on the electric sliding rail, a balancing weight is arranged on the sliding block, the electric sliding rail is connected with a controller through a circuit, and the controller can control the sliding block on the electric sliding rail to move. So, the personnel of convenience pass through the removal of operation controller control slider on electronic slide rail to realize adjusting the incline direction of girder, the balancing weight can effectively avoid taking place relative rotation between girder and the support column when telescopic link and stopper cooperation simultaneously.

The telescopic rod is provided with a stress sensor at the contact part with the limiting block, the stress sensor is connected with a display circuit, and the display is provided with information of stress when the telescopic rod is contacted with the limiting block. Therefore, a person can conveniently adjust the position of the balancing weight on the electric sliding rail according to the stress information displayed on the display, so that small stress exists between the telescopic rod and the limiting block, and the service life of the photovoltaic bracket is prolonged.

The beneficial effects of the utility model are as follows: according to the utility model, the fixed end of the telescopic rod is fixedly arranged on the support column to adjust the extension length of the extension end of the telescopic rod, and the main beam is rotated to the contact position of the step on the limiting block, which is matched with the end part of the telescopic rod with the length, and the angle between the main beam and the support column is adjusted, so that the installation angle of a photovoltaic panel arranged on the main beam is adjusted; according to the utility model, the electric sliding rail arranged along the purline direction is arranged on the main beam, the sliding block is arranged on the electric sliding rail, and the balancing weight is arranged on the sliding block, so that the main beam can rotate towards the two sides of the support column by adjusting the position of the sliding block on the electric sliding rail, and the balancing weight also enables the limiting block on the main beam to keep fit with the telescopic rod on the support column, so that the main beam is prevented from rotating under the action of external force; according to the photovoltaic bracket, the stress sensor is arranged at the position, which is in contact with the limiting block, of the telescopic rod, information acquired by the stress sensor is displayed on the display, so that a person can conveniently adjust the position of the sliding block on the electric sliding rail according to the information displayed on the display, and therefore, the limiting block and the telescopic rod have smaller stress, and the service life of the photovoltaic bracket is prolonged.

Drawings

Fig. 1: the structure of the utility model is schematically shown.

Fig. 2: according to the utility model, a structural schematic diagram of the telescopic rod is constructed when the telescopic rod is overlapped with a first step on the limiting block.

Fig. 3: in the utility model, the telescopic rod is in a schematic structure when being overlapped with a second step on the limiting block.

Fig. 4: in the utility model, the telescopic rod is in a schematic structure when being overlapped with a third step on the limiting block.

Fig. 5: the connection structure of the electrical equipment is schematically shown in the utility model.

In the figure: 1. a support column; 2. a main beam; 3. a bearing mechanism; 4. purlin; 5. a limiting block; 5-1, a first step; 5-2, a second step; 5-3, a third step; 6. a telescopic rod; 7. an electric slide rail; 8. balancing weight; 9. a stress sensor; 10. a controller; 11. a display; 12. and a power supply.

Detailed Description

The present utility model will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present utility model and not limited to the following examples.

The embodiment is a photovoltaic bracket with adjustable angles, which is provided with a plurality of support columns 1 and a main beam 2, wherein the main beam 2 is installed on the top end of the support columns 1, purlines 4 perpendicular to the main beam 2 are installed on the main beam 2, photovoltaic electric plates are installed on the purlines 4, and the support columns 1 and the main beam 2 are connected through bearing mechanisms 3, so that the support columns 1 and the main beam 2 can rotate relatively.

In this embodiment, a limiting block 5 is sleeved at the end of the main beam 2, a telescopic rod 6 is fixedly installed on the supporting column 1, the end of the telescopic rod 6 can be in contact with the limiting block 5, and the end of the limiting block 5, which is in contact with the telescopic rod 6, is in a stepped shape. Wherein the telescopic rod 6 is in circuit connection with the controller 10, and the telescopic rod 6 can be controlled to stretch and retract through the controller 10. Thus, after the personnel operate the controller 10 to control the telescopic rod 6 to stretch out and draw back to a certain length, the main beam 2 is rotated to the contact position of the step corresponding to the telescopic rod 6 with the length on the limiting block 5 and the telescopic rod 6 is in lap joint with the limiting block 5. When the installation angle of the main beam 2 needs to be adjusted, the telescopic length of the telescopic rod 6 is adjusted through the controller 10, the main beam 2 is rotated to the contact position of the step corresponding to the telescopic rod 6 with the length on the limiting block 5 and the telescopic rod 6, and the adjustment of the installation angle of the main beam 2 is realized.

In this embodiment, an electric sliding rail 7 is disposed on the main beam 2 along the purline 4, a slidable slider is mounted on the electric sliding rail 7, and a counterweight 8 is mounted on the slider. Wherein the electric slide rail 7 is also in circuit connection with the controller 10. Therefore, a person can control the sliding blocks on the electric sliding rail 7 to move to the two sides of the main beam 2 through operating the controller 10, so that the main beam 2 rotates to the two sides of the supporting column 1. Meanwhile, the balancing weight 8 also enables the limiting block 5 on the main beam 2 to keep matching with the telescopic rod 6 on the supporting column 1, so that the main beam 2 is prevented from rotating under the action of external force.

Further, in this embodiment, a stress sensor 9 is provided on the telescopic link 6 at an end portion contacting the stopper 5, and the stress sensor 9 is electrically connected to a display 11. So, when need adjust the position of girder 2, personnel can look over the stress information between telescopic link 6 and the stopper 5 that show on the display 11 to the position of operation controller 10 regulation slider on electronic slide rail 7 makes the stress between stopper 5 and the telescopic link 6 be in less within range, thereby can prolong the life of this photovoltaic support.

In this embodiment, angle adjustment mechanisms are all arranged at the both ends of the main beam 2, so that the main beam 2, the purlines 4 and the photovoltaic panel installed on the purlines 4 can be conveniently rotated towards the two sides of the support column 1.

In this embodiment, the telescopic rod 6, the electric slide rail 7, the controller 10 and the display 11 are all powered by the power source 12.

The application method of the embodiment is as follows:

the controller 10 controls the sliding block and the balancing weight 8 to move to a position where the telescopic rod 6 is not matched with the limiting block 5 on the electric sliding rail 7;

the telescopic rod 6 is controlled by the controller 10 to stretch to the position matched with the first step 5-1 on the balancing weight 8, and the sliding block and the balancing weight 8 are controlled by the controller 10 to move on the electric sliding rail 7 to the overlapping position of the telescopic rod 6 and the first step 5-1, so that the angle of the photovoltaic bracket is adjusted to the position when the telescopic rod 6 is matched with the first step 5-1;

the sliding block and the balancing weight 8 are continuously moved by the controller 10, so that the stress value displayed on the display 11 is in a minimum state, the stress between the limiting block 5 and the telescopic rod 6 is in a small state, and the service life of the photovoltaic bracket is prolonged.

The angle of the photovoltaic bracket can also be adjusted to the position when the telescopic rod 6 is matched with the second step 5-2 or the position when the telescopic rod 6 is matched with the third step 5-3 by adopting the mode.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (4)

1. An adjustable angle's photovoltaic support, its characterized in that: the photovoltaic module comprises a plurality of support columns (1) and main beams (2) arranged at the top ends of the support columns (1), wherein the support columns (1) are connected with the main beams (2) through bearing mechanisms (3), purlines (4) for supporting photovoltaic modules are arranged on the main beams (2), the purlines (4) are vertically arranged with the main beams (2), and an angle adjusting mechanism is arranged between the support columns (1) and the main beams (2);

the angle adjusting mechanism is provided with a telescopic rod (6) arranged on the supporting column (1) and a limiting block (5) sleeved on the main beam (2), the end part of the limiting block (5) in contact with the telescopic rod (6) is in a stepped shape, and the telescopic rod (6) stretching to each length can be matched with the step matched with the telescopic rod (6) on the limiting block (5).

2. An adjustable angle photovoltaic bracket according to claim 1, wherein: the telescopic rod (6) is in circuit connection with the controller (10), and the controller (10) is used for controlling the telescopic rod (6) to stretch.

3. An adjustable angle photovoltaic bracket according to claim 1, wherein: an electric sliding rail (7) is arranged on the main beam (2) along the arrangement direction of the purlines (4), a sliding block is slidably arranged on the electric sliding rail (7), a balancing weight (8) is arranged on the sliding block, the electric sliding rail (7) is in circuit connection with a controller (10), and the controller (10) can control the movement of the sliding block on the electric sliding rail (7).

4. An adjustable angle photovoltaic bracket according to claim 3, wherein: the telescopic rod (6) is provided with a stress sensor (9) at a part contacted with the limiting block (5), the stress sensor (9) is in circuit connection with a display (11), and the display (11) is provided with information of stress when the telescopic rod (6) is contacted with the limiting block (5).