CN220273606U - Photovoltaic support that sun position and then adjust is followed to developments - Google Patents

Abstract

The utility model discloses a photovoltaic bracket capable of dynamically following the sun azimuth to adjust, which comprises a photovoltaic assembly, a bracket main body, a dynamic following angle adjusting mechanism, a control center and an energy supply system, wherein the dynamic following angle adjusting mechanism comprises a dynamic monitoring assembly, a first hydraulic telescopic adjuster and a second hydraulic telescopic adjuster, and the first hydraulic telescopic adjuster and the second hydraulic telescopic adjuster are electrically connected with the dynamic monitoring assembly. According to the photovoltaic module inclination adjustment device, the supporting mechanism, the inclined beam, the inclined stay bar, the control center, the dynamic monitoring module, the first hydraulic telescopic adjuster and the second hydraulic telescopic adjuster are arranged, so that the photovoltaic module inclination adjustment device is convenient to automatically follow the sun direction, the effect of dynamically following sunlight to adjust the inclination angle is provided, the photovoltaic collection effect can be exerted to the greatest extent on the premise of guaranteeing the basic function, and the photovoltaic power generation efficiency is improved.

Description

Photovoltaic support that sun position and then adjust is followed to developments

Technical Field

The utility model relates to the technical field of photovoltaic supports, in particular to a photovoltaic support capable of dynamically following the sun azimuth to adjust.

Background

At present, a panel is fixed on a ground support or a roof support, and the photovoltaic panel is fixed in an angle, so that the inclination angle cannot be converted along with the sun azimuth after the sun changes the angle, the illumination receiving time and the efficiency are low, and the power generation efficiency is low; therefore, in order to overcome the above-mentioned drawbacks, it is necessary to provide a photovoltaic bracket that dynamically follows the sun's azimuth and adjusts.

Disclosure of Invention

The utility model aims to provide a photovoltaic bracket which dynamically follows the sun azimuth and is adjusted, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a photovoltaic support that sun position and then adjust is followed to developments, includes photovoltaic module, support main part, developments angle adjustment mechanism, control center and energy supply system are followed to developments, angle adjustment mechanism is followed to developments includes dynamic monitoring subassembly, first hydraulic telescoping regulator and second hydraulic telescoping regulator all with dynamic monitoring subassembly electric connection, first hydraulic telescoping regulator, second hydraulic telescoping regulator and dynamic monitoring subassembly and control center communication connection, dynamic monitoring subassembly is used for monitoring sun position and photovoltaic module's gradient and transmits to control center position value and inclination value;

the photovoltaic module is obliquely arranged, the support main body comprises two pre-buried steel pipes, the top ends of the pre-buried steel pipes positioned on the left side are fixedly connected with a front upright, the top ends of the pre-buried steel pipes positioned on the right side are fixedly connected with a rear upright, a diagonal bracing hoop is fixedly arranged on the rear upright, a diagonal bracing rod is rotatably arranged on the left side of the diagonal bracing hoop, a diagonal beam is rotatably arranged on the top end of the front upright, a plurality of supporting mechanisms are arranged between the photovoltaic module and the diagonal beam, the top ends of the rear upright are fixedly connected with the bottom of the first hydraulic telescopic regulator, the top ends of the diagonal bracing rods are fixedly connected with the bottom of the second hydraulic telescopic regulator, the extending ends of the first hydraulic telescopic regulator and the second hydraulic telescopic regulator are rotatably arranged on the bottom of the diagonal beam, and the supporting mechanisms are used for supporting and fixing the photovoltaic module, and the first hydraulic telescopic regulator and the second hydraulic telescopic regulator are controlled by utilizing azimuth values received by the control center to adjust the inclination of the photovoltaic module;

the energy supply system comprises an energy generating device and an energy receiving device, the energy receiving device and the photovoltaic module are electrically connected with the energy generating device, a power supply electrically connected with the energy receiving device is arranged in the dynamic monitoring module, and the energy receiving device is used for supplying power to the power supply of the dynamic monitoring module.

Preferably, the supporting mechanism comprises a back-shaped aluminum alloy supporting block movably arranged between the photovoltaic module and the oblique beam, a plurality of mounting holes are formed in the top of the photovoltaic module, supporting rods are fixedly connected between inner walls of two sides of the mounting holes, first threaded holes are formed in the tops of the supporting rods, first bolts are sleeved in the first threaded holes in a threaded mode, the corresponding first bolts are sleeved with the back-shaped aluminum alloy supporting block in a threaded mode, bolt through holes are formed in inner walls of the bottoms of the back-shaped aluminum alloy supporting block, second bolts are movably sleeved in the bolt through holes in a sleeved mode, the oblique beam is movably sleeved on the plurality of second bolts, nuts are sleeved on the second bolts in a threaded mode, and the tops of the nuts are in movable contact with the bottoms of the oblique beam; the support rod, the first threaded hole, the first bolt, the rectangular aluminum alloy support block, the second bolt and the nut are matched, the rectangular aluminum alloy support block is fixed between the photovoltaic module and the oblique beam in a threaded mode, and the rectangular aluminum alloy support block is used for supporting and fixing the photovoltaic module.

Preferably, the rear upright post is fixedly sleeved with an inclined pull rod hoop, and an inclined pull rod is fixedly connected between the rear side of the inclined pull rod hoop and the ground.

Preferably, the extending end of the first hydraulic telescopic adjuster, the extending end of the second hydraulic telescopic adjuster and the top end of the front upright post are fixedly connected with rotating wheels, the front sides of the rotating wheels are rotationally connected with triangular plates, and the tops of the triangular plates are fixedly connected with the bottoms of the oblique beams.

Preferably, the energy generating device is a solar energy controller, the energy receiving device is a storage battery, the solar energy controller is electrically connected with the electric energy output end of the photovoltaic module, the electric energy output end of the solar energy controller is electrically connected with the storage battery, and the first hydraulic telescopic regulator, the second hydraulic telescopic regulator and the control center are electrically connected with the storage battery.

Preferably, the control center is fixedly arranged on the front side of the rear upright post, and the control center is positioned below the diagonal draw bar hoop.

Preferably, the bottom of the dynamic monitoring component is fixedly connected with the right side of the top of the photovoltaic component.

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

1. according to the photovoltaic bracket capable of dynamically following the sun azimuth and adjusting the sun azimuth, the sun azimuth can be monitored by matching the supporting mechanism, the oblique beam, the oblique stay rod, the control center, the dynamic monitoring component, the first hydraulic telescopic regulator and the second hydraulic telescopic regulator, and the first hydraulic telescopic regulator and the second hydraulic telescopic regulator are automatically controlled to stretch according to the sun azimuth, so that the inclination of the oblique beam is adjusted, the inclination angle of the photovoltaic component is adjusted, the photovoltaic collecting effect can be exerted to the greatest extent, and the photovoltaic power generation efficiency is improved;

2. this kind of developments follow sun position and then photovoltaic support of regulation through photovoltaic module, solar controller and the battery cooperation that sets up, can store solar energy conversion into electric energy to for dynamic monitoring subassembly, control center, first hydraulic telescoping regulator and the power supply of second hydraulic telescoping regulator.

According to the photovoltaic module inclination adjustment device, the supporting mechanism, the inclined beam, the inclined stay bar, the control center, the dynamic monitoring module, the first hydraulic telescopic adjuster and the second hydraulic telescopic adjuster are arranged, so that the photovoltaic module inclination adjustment device is convenient to automatically follow the sun direction, the effect of dynamically following sunlight to adjust the inclination angle is provided, the photovoltaic collection effect can be exerted to the greatest extent on the premise of guaranteeing the basic function, and the photovoltaic power generation efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

fig. 2 is an enlarged schematic view of a portion a in fig. 1 according to the present utility model.

In the figure: 1. a front upright; 2. a rear pillar; 3. a diagonal brace; 4. a sloping beam; 5. a support rod; 6. a rectangular aluminum alloy support block; 7. a first bolt; 8. a first hydraulic telescopic regulator; 9. a second hydraulic telescopic regulator; 10. a dynamic monitoring component; 11. a diagonal draw bar hoop; 12. a second bolt; 13. a diagonal bracing hoop; 14. triangular plates; 15. a photovoltaic module; 16. and (5) embedding the steel pipe.

Detailed Description

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. 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.

As shown in fig. 1 to 2, the photovoltaic support provided by the embodiment dynamically following the sun azimuth and further adjusting the sun azimuth comprises a photovoltaic module 15, a support main body, a dynamic following angle adjusting mechanism, a control center and an energy supply system, wherein the dynamic following angle adjusting mechanism comprises a dynamic monitoring module 10, a first hydraulic telescopic adjuster 8 and a second hydraulic telescopic adjuster 9, the first hydraulic telescopic adjuster 8 and the second hydraulic telescopic adjuster 9 are electrically connected with the dynamic monitoring module 10, the first hydraulic telescopic adjuster 8, the second hydraulic telescopic adjuster 9 and the dynamic monitoring module 10 are in communication connection with the control center, and the dynamic monitoring module 10 is used for monitoring the sun azimuth and the inclination of the photovoltaic module 15 and transmitting the inclination value and the inclination value to the control center;

the photovoltaic module 15 is obliquely arranged, the support main body comprises two embedded steel pipes 16, the top end of each embedded steel pipe 16 positioned on the left side is fixedly connected with a front upright 1, the top end of each embedded steel pipe 16 positioned on the right side is fixedly connected with a rear upright 2, an inclined strut hoop 13 is fixedly arranged on each rear upright 2, an inclined strut 3 is rotatably arranged on the left side of each inclined strut hoop 13, an inclined beam 4 is rotatably arranged on the top end of each front upright 1, a plurality of supporting mechanisms are arranged between each photovoltaic module 15 and each inclined beam 4, the top end of each rear upright 2 is fixedly connected with the bottom of each first hydraulic telescopic regulator 8, the top ends of each inclined strut 3 are fixedly connected with the bottom of each second hydraulic telescopic regulator 9, the extending ends of each first hydraulic telescopic regulator 8 and each second hydraulic telescopic regulator 9 are rotatably arranged on the bottom of each inclined beam 4, each supporting mechanism is used for supporting and fixing the photovoltaic module 15, and the first hydraulic telescopic regulator 8 and the second hydraulic telescopic regulator 9 are controlled to stretch by using azimuth values received by the control center to realize the adjustment of inclination of the photovoltaic module 15;

the energy supply system comprises an energy generating device and an energy receiving device, the energy receiving device and the photovoltaic module 15 are electrically connected with the energy generating device, a power supply electrically connected with the energy receiving device is arranged in the dynamic monitoring module 10, the energy receiving device is used for supplying power to the power supply of the dynamic monitoring module 10, the bottom of the dynamic monitoring module 10 is fixedly connected with the right side of the top of the photovoltaic module 15, and the effect of supporting the dynamic monitoring module 10 is achieved.

Specifically, the supporting mechanism comprises a back-shaped aluminum alloy supporting block 6 movably arranged between the photovoltaic module 15 and the inclined beam 4, a plurality of mounting holes are formed in the top of the photovoltaic module 15, a supporting rod 5 is fixedly connected between the inner walls of the two sides of the mounting holes, a first threaded hole is formed in the top of the supporting rod 5, a first bolt 7 is sleeved on the first threaded hole in a threaded mode, the back-shaped aluminum alloy supporting block 6 is sleeved on the corresponding first bolt 7 in a threaded mode, a second threaded hole in threaded mode is formed in the top of the back-shaped aluminum alloy supporting block 6, the back-shaped aluminum alloy supporting block 6 is sleeved on the corresponding first bolt 7 in a threaded mode through the second threaded hole, a second bolt 12 is movably sleeved on the inner wall of the bottom of the back-shaped aluminum alloy supporting block 6, a plurality of second bolts 12 are movably sleeved in the threaded holes, a plurality of movable through holes which are respectively in movable contact with the outer sides of the corresponding second bolts 12 are formed in the top of the inclined beam 4, the inclined beam 4 is movably sleeved on the plurality of second bolts 12 through the movable through the plurality of holes, the movable through holes is in a threaded hole 12, and the movable through the effect of the inclined beam 4 is provided with the movable nuts on the top of the second bolts 12; the support rod 5, the first threaded hole, the first bolt 7, the square aluminum alloy support block 6, the second bolt 12 and the nut are matched, the square aluminum alloy support block 6 is fixed between the photovoltaic module 15 and the inclined beam 4 in a threaded mode, and the square aluminum alloy support block 6 is used for supporting and fixing the photovoltaic module 15.

Further, the rear upright 2 is fixedly sleeved with the diagonal draw bar hoop 11, a diagonal draw bar is fixedly connected between the rear side of the diagonal draw bar hoop 11 and the ground, and the diagonal draw bar hoop 11 are utilized to strengthen the supporting effect of the rear upright 2.

Further, the end that stretches out of first hydraulic telescoping regulator 8, the end that stretches out of second hydraulic telescoping regulator 9 and the top of front column 1 are all fixedly connected with runner, the front side of runner rotates and is connected with triangular plate 14, the top of triangular plate 14 and the bottom fixed connection of sloping 4, wherein the front side fixedly connected with round pin axle of runner, the rotation hole has been seted up to the front side of triangular plate 14, the fixed cover in rotation hole is equipped with supporting bearing, supporting bearing's inner circle and the fixed suit of the outside of corresponding round pin axle play the effect of rotating the installation to the runner, through the triangular plate 14 that sets up, supporting bearing, round pin axle and runner cooperation, play the effect of rotating the sloping 4 with front column 1, first hydraulic telescoping regulator 8 and second hydraulic telescoping regulator 9 and be connected.

Further, the energy generating device is a solar controller, the energy receiving device is a storage battery, the solar controller is electrically connected with the electric energy output end of the photovoltaic module 15, the electric energy output end of the solar controller is electrically connected with the storage battery, the first hydraulic telescopic regulator 8, the second hydraulic telescopic regulator 9 and the control center are electrically connected with the storage battery, and the solar controller is utilized to convey the electric energy converted by the solar module 15 to the storage battery for storage.

Further, the control center is fixedly arranged on the front side of the rear upright post 2, is positioned below the diagonal draw bar hoop 11 and is supported and fixed by the rear upright post 2.

The application method of the embodiment is as follows: the dynamic monitoring assembly 10 monitors the sun azimuth and the inclination value of the photovoltaic assembly 15 and transmits the sun azimuth and the inclination value to the control center, the control center controls the first hydraulic telescopic adjuster 8 and the second hydraulic telescopic adjuster 9 to be correspondingly started according to the received azimuth value and inclination value, the first hydraulic telescopic adjuster 8 and the second hydraulic telescopic adjuster 9 drive the inclined beam 4 to rotate at the top of the front upright 1, so that the inclination of the inclined beam 4 is changed, the inclined beam 4 drives the inclined beam 3 to rotate at the left side of the rear upright 2 through the second hydraulic telescopic adjuster 9 when the inclined beam 4 rotates obliquely, the inclined beam 4 drives the photovoltaic assembly 15 to rotate obliquely through the plurality of back-shaped aluminum alloy support blocks 6, the inclination of the inclined beam 4 is changed, and when the inclination value received by the control center reaches a preset value, the first hydraulic telescopic adjuster 8 and the second hydraulic telescopic adjuster 9 are controlled to be automatically closed, the effect of automatically adjusting the inclination of the photovoltaic assembly 15 along with the sun azimuth is achieved, the photovoltaic collection effect can be played to the greatest extent on the premise that the basic function is ensured, and the photovoltaic power generation efficiency is improved;

the photovoltaic module 15 converts solar energy into electric energy and transmits the electric energy to the storage battery for storage through the solar energy controller, and the storage battery supplies power for the dynamic monitoring module 10, the control center, the first hydraulic telescopic regulator 8 and the second hydraulic telescopic regulator 9.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. 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 (7)

1. The utility model provides a photovoltaic support that sun position and then adjust is followed to developments, includes photovoltaic module (15), support main part, developments angle adjustment mechanism, control center and energy supply system, its characterized in that: the dynamic following angle adjusting mechanism comprises a dynamic monitoring component (10), a first hydraulic telescopic adjuster (8) and a second hydraulic telescopic adjuster (9), wherein the first hydraulic telescopic adjuster (8) and the second hydraulic telescopic adjuster (9) are electrically connected with the dynamic monitoring component (10), and the first hydraulic telescopic adjuster (8), the second hydraulic telescopic adjuster (9) and the dynamic monitoring component (10) are in communication connection with a control center;

the photovoltaic module (15) is obliquely arranged, the support body comprises two pre-buried steel pipes (16), the top end of each pre-buried steel pipe (16) positioned on the left side is fixedly connected with a front upright (1), the top end of each pre-buried steel pipe (16) positioned on the right side is fixedly connected with a rear upright (2), an inclined strut hoop (13) is fixedly arranged on each rear upright (2), an inclined strut (3) is rotatably arranged on the left side of each inclined strut hoop (13), an inclined beam (4) is rotatably arranged on the top end of each front upright (1), a plurality of supporting mechanisms are arranged between each photovoltaic module (15) and each inclined beam (4), the top ends of the rear uprights (2) are fixedly connected with the bottom of each first hydraulic telescopic adjuster (8), and the top ends of the inclined struts (3) and the extending ends of the second hydraulic telescopic adjusters (9) are rotatably arranged on the bottom of the inclined beams (4);

the energy supply system comprises an energy generating device and an energy receiving device, the energy receiving device and the photovoltaic module (15) are electrically connected with the energy generating device, and a power supply electrically connected with the energy receiving device is arranged in the dynamic monitoring module (10).

2. A photovoltaic bracket dynamically adjusted to follow the solar azimuth as set forth in claim 1, wherein: supporting mechanism is including the activity setting up the shape aluminum alloy piece (6) that returns between photovoltaic module (15) and sloping (4), the top of photovoltaic module (15) is provided with a plurality of mounting holes, fixedly connected with branch (5) between the both sides inner wall of mounting hole, first screw hole has been seted up at the top of branch (5), first screw hole internal thread cover is equipped with first bolt (7), shape aluminum alloy piece (6) thread cover is established on corresponding first bolt (7), bolt perforation has been seted up on the bottom inner wall of shape aluminum alloy piece (6), bolt perforation internal activity cover is equipped with second bolt (12), sloping (4) movable sleeve is established on a plurality of second bolts (12), the last thread cover of second bolt (12) is equipped with the nut, the top of nut and the bottom movable contact of sloping (4).

3. A photovoltaic bracket dynamically adjusted to follow the solar azimuth as set forth in claim 1, wherein: the rear upright post (2) is fixedly sleeved with an inclined pull rod hoop (11), and an inclined pull rod is fixedly connected between the rear side of the inclined pull rod hoop (11) and the ground.

4. A photovoltaic bracket dynamically adjusted to follow the solar azimuth as set forth in claim 1, wherein: the telescopic hydraulic lifting device is characterized in that the extending end of the first hydraulic telescopic regulator (8), the extending end of the second hydraulic telescopic regulator (9) and the top end of the front upright post (1) are fixedly connected with rotating wheels, the front sides of the rotating wheels are rotationally connected with triangular plates (14), and the tops of the triangular plates (14) are fixedly connected with the bottoms of the oblique beams (4).

5. A photovoltaic bracket dynamically adjusted to follow the solar azimuth as set forth in claim 1, wherein: the energy generating device is a solar controller, the energy receiving device is a storage battery, the solar controller is electrically connected with the electric energy output end of the photovoltaic module (15), the electric energy output end of the solar controller is electrically connected with the storage battery, and the first hydraulic telescopic regulator (8), the second hydraulic telescopic regulator (9) and the control center are electrically connected with the storage battery.

6. A photovoltaic bracket dynamically adjustable following the azimuth of the sun according to claim 3, wherein: the control center is fixedly arranged on the front side of the rear upright post (2), and is positioned below the diagonal draw bar hoop (11).

7. A photovoltaic bracket dynamically adjusted to follow the solar azimuth as set forth in claim 1, wherein: the bottom of the dynamic monitoring assembly (10) is fixedly connected with the right side of the top of the photovoltaic assembly (15).