CN113765476B

CN113765476B - Three-dimensional solar power generation device

Info

Publication number: CN113765476B
Application number: CN202111316630.6A
Authority: CN
Inventors: 曾奇
Original assignee: Shenzhen Yifeng Digital Technology Co ltd
Current assignee: Shenzhen Yifeng Digital Technology Co ltd
Priority date: 2021-11-09
Filing date: 2021-11-09
Publication date: 2022-02-08
Anticipated expiration: 2041-11-09
Also published as: CN113765476A

Abstract

The invention relates to the technical field of new energy, in particular to a three-dimensional solar power generation device; utilize the intensity of the solar energy of solar detection unit real-time detection each position, input water to the inside of two tip supporting units and middle part supporting unit through the input pipeline, discharge the inside water of tip supporting unit and middle part supporting unit to the storage water tank in through the output pipeline, change the inside water yield of tip supporting unit and middle part supporting unit, thereby adjust the whole height of two tip supporting units and middle part supporting unit, every link all with installation frame swing joint, thereby adjust the inclination of installation framework, make solar cell panel can be better the absorption solar energy, compare and adopt the motor in traditional mode, the mode of the inclination of solar energy frame is adjusted, adopt the consumption of above-mentioned structure can reduce the energy.

Description

Three-dimensional solar power generation device

Technical Field

The invention relates to the technical field of new energy, in particular to a three-dimensional solar power generation device.

Background

A solar power generation device is a common photoelectric device, which uses a solar panel to receive sunlight and convert light energy into electric energy. The solar power generation capacity is in proportion to the light energy received by the solar panel, and the power generation capacity is strongest when the incident sunlight is vertical to the solar panel.

For realizing the location tracking of the sun, the existing solar power generation device is generally provided with a solar sensor and an angle adjusting unit, the angle adjusting unit is started according to the solar intensity detected by the solar sensor, the inclination angle of a solar cell panel is adjusted, but the angle adjusting unit of the existing solar power generation device mostly adopts a motor to adjust, and the consumption of electric energy is large.

Disclosure of Invention

The invention aims to provide a three-dimensional solar power generation device, and solves the problem that in the prior art, most angle adjusting units of the conventional solar power generation device are adjusted by a motor, so that the consumption of electric energy is high.

In order to achieve the above object, the present invention provides a three-dimensional solar power generation device, which comprises two end support units, a middle support unit, an installation frame, a solar panel, a solar detection unit, a water storage tank, a plurality of input pipelines, a plurality of output pipelines and a master controller, wherein the solar panel and the master controller are arranged on the installation frame, two end support units and a middle support unit are arranged between the installation frame and the ground, the two end support units are respectively located at two ends of the installation frame, the middle support unit is located in the middle of the installation frame, one ends of the two end support units and the middle support unit, which are far away from the ground, are movably provided with a connecting frame, and each connecting frame is movably connected with the installation frame, the underground water storage tank is provided with a plurality of input pipelines and output pipelines, the output ends of the output pipelines are respectively corresponding to the end supporting units and the middle supporting unit, the underground water storage tank is arranged, the end supporting units and the middle supporting unit are respectively provided with the output pipelines and the output ends of the output pipelines are corresponding to the water storage tank, the installation frame is further provided with the solar detection unit, and the solar detection unit is electrically connected with the master controller.

The solar panel can better absorb solar energy by utilizing the solar detection unit to detect the intensity of the solar energy in each direction in real time, water is input into the two end supporting units and the middle supporting unit through the input pipeline, water in the end supporting units and the middle supporting unit is discharged into the water storage tank through the output pipeline, the integral heights of the two end supporting units and the middle supporting unit are respectively adjusted by changing the water amount in the end supporting units and the middle supporting unit, because the ends, far away from the ground, of the two end supporting units and the middle supporting unit are movably provided with connecting frames, each connecting frame is movably connected with the installation frame, so that the inclination angle of the installation frame is adjusted, and compared with a motor adopted in the traditional mode, the mode of the inclination angle of the solar energy frame is adjusted, and the structure can reduce the energy consumption.

The utility model discloses a telescopic bag box, including the tip supporting unit, the bottom plate is connected with ground dismantlement, the bottom plate is connected with the bottom plate dismantlement, the one end of telescopic bag box with the bottom plate is dismantled and is connected, the other end of telescopic bag box with the mounting panel is dismantled and is connected, the activity is provided with on the mounting panel the link, the both sides of telescopic bag box are provided with water inlet and delivery port respectively, the water inlet with the input pipeline is corresponding, be provided with on the delivery port output pipeline.

Through the water inlet to the inside water delivery of bellows case, thereby improve the height of bellows case, through the water inlet discharge the inside water of bellows case, thereby reduce the height of bellows case, through the water yield regulation of bellows incasement portion the tip supporting element with the overall height of middle part supporting element.

Wherein, every input pipeline all includes first connecting pipe, first automatically controlled valve and conveyer pipe, the one end of first automatically controlled valve is provided with first connecting pipe, the other end of first automatically controlled valve is provided with the conveyer pipe, first automatically controlled valve with master controller electric connection, first connecting pipe with the play water end of water storage box is corresponding, the conveyer pipe with the water inlet is corresponding.

When the height of the telescopic bag box needs to be increased, the master controller controls the first electric control valve to be opened, so that water in the water storage box is conveyed to the corresponding inner part of the telescopic bag box through the first connecting pipe and the conveying pipe.

Each output pipeline comprises a second connecting pipe, a second electric control valve and a water discharging pipe, wherein one end of the second electric control valve is provided with the second connecting pipe, the other end of the second electric control valve is provided with the water discharging pipe, the second electric control valve is electrically connected with the main controller, the water discharging pipe corresponds to the water outlet, and the second connecting pipe corresponds to the water inlet end of the water storage tank.

When the water in the bellows box needs to be discharged, the master controller controls the second electric control valve to be opened, so that the water in the bellows box is discharged into the water storage tank through the water discharge pipe and the second connecting pipe.

Wherein, every the link all includes support body, first stabilizer blade and second stabilizer blade, the both ends of the bottom of installation frame all are provided with the connecting frame, the one end of support body is provided with first stabilizer blade, the other end of support body is provided with the second stabilizer blade, first stabilizer blade with mounting panel swing joint, the second stabilizer blade with connecting frame swing joint.

The both ends of support body set up respectively first stabilizer blade with the second stabilizer blade, will first stabilizer blade movable mounting be in on the mounting panel, will second stabilizer blade movable mounting be in on the connecting frame, thereby make the connecting frame with installation frame swing joint is located both ends through the change the height of bellows case, thereby adjusts the inclination of installation frame.

The three-dimensional solar power generation device further comprises a circulating pipeline, the circulating pipeline comprises a water pump, a first communicating pipe and a second communicating pipe, one end of the water pump is provided with the first communicating pipe, the other end of the water pump is provided with the second communicating pipe, one end of the first communicating pipe, far away from the water pump, corresponds to the water outlet end of the water storage tank, and one end of the second communicating pipe, far away from the water pump, corresponds to the water inlet end of the water storage tank.

And starting the water pump, and conveying the water in the water storage tank to the inside of the water storage tank through the first communicating pipe and the second communicating pipe, so that water circulation is completed, and the consumption of water resources is reduced.

The invention relates to a three-dimensional solar power generation device, wherein a plurality of input pipelines are arranged on a water storage tank, the output end of each output pipeline corresponds to two end supporting units and a middle supporting unit respectively, a water storage tank is arranged underground, the output pipelines are arranged on the two end supporting units and the middle supporting unit respectively, the output end of each output pipeline corresponds to the water storage tank, the solar detection units are used for detecting the intensity of solar energy in each direction in real time, water is input into the two end supporting units and the middle supporting unit through the input pipelines, water in the end supporting units and the middle supporting unit is discharged into the water storage tank through the output pipelines, and the water in the end supporting units and the middle supporting unit is changed, thereby adjust two respectively the tip supporting element with the overall height of middle part supporting element, because two the tip supporting element with the equal activity of the one end that ground was kept away from to the middle part supporting element is provided with the link, every the link all with installation frame swing joint, thereby adjust the inclination of installation framework makes solar cell panel can be better absorbs solar energy, adopts the motor in comparing in traditional mode, adjusts the mode of the inclination of solar energy frame, adopts the consumption of above-mentioned structure can reduce the energy.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a three-dimensional solar power generation device provided by the present invention.

Fig. 2 is a schematic partial structural diagram of a three-dimensional solar power generation device provided by the invention.

Fig. 3 is an enlarged view of a portion of the structure of fig. 2 a according to the present invention.

Fig. 4 is a schematic structural view of an end support unit provided in the present invention.

Fig. 5 is a schematic view of the internal structure of the mounting seat provided by the invention.

1-end supporting unit, 11-connecting frame, 111-frame body, 112-first supporting leg, 113-second supporting leg, 12-bottom plate, 13-telescopic bag box, 14-mounting plate, 15-water inlet, 16-water outlet, 2-middle supporting unit, 3-mounting frame, 31-main controller, 32-connecting frame, 4-solar panel, 5-solar detection unit, 51-mounting seat, 511-groove, 52-rotating component, 521-servo motor, 522-output shaft, 523-output gear, 53-rotating plate, 531-driven tooth part, 54-bracket, 55-fixing plate, 56-mounting component, 561-mounting frame, 562-mounting body, 563-driving motor, V-gear, V-, 564-a gear reduction box, 565-a clamping block, 566-a clamping groove, 57-a solar sensor, 6-a water storage tank, 61-a circulating pipeline, 62-a water pump, 63-a first connecting pipe, 64-a second connecting pipe, 7-a water storage tank, 8-an input pipeline, 81-a first connecting pipe, 82-a first electric control valve, 83-a conveying pipe, 9-an output pipeline, 91-a second connecting pipe, 92-a second electric control valve and 93-a water discharge pipe.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 5, the invention provides a three-dimensional solar power generation device, which includes two end supporting units 1, a middle supporting unit 2, a mounting frame 561 frame 3, a solar panel 4, a solar detection unit 5, a water storage tank 6, a water storage tank 7, a plurality of input pipelines 8, a plurality of output pipelines 9 and a main controller 31, wherein the solar panel 4 and the main controller 31 are arranged on the mounting frame 561 frame 3, two end supporting units 1 and the middle supporting unit 2 are arranged between the mounting frame 561 frame 3 and the ground, the two end supporting units 1 are respectively located at two ends of the mounting frame 561 frame 3, the middle supporting unit 2 is located in the middle of the mounting frame 561 frame 3, and a connecting frame 11 is movably arranged at one end of each of the two end supporting units 1 and the middle supporting unit 2 away from the ground, every the link 11 all with installing frame 561 frame 3 swing joint, subaerial being provided with water storage tank 6, be provided with a plurality ofly on the water storage tank 6 input pipeline 8, every output 9 the output respectively with two tip supporting unit 1 with middle part supporting unit 2 is corresponding, the underground is provided with storage water tank 7, two all be provided with on tip supporting unit 1 with middle part supporting unit 2 output pipeline 9, every output of output pipeline 9 all with storage water tank 7 is corresponding, still be provided with on the installing frame 561 frame 5 solar energy detecting element 5, solar energy detecting element 5 and master controller 31 electric connection.

In this embodiment, the solar detection unit 5 is used to detect the intensity of solar energy in each direction in real time, water is input into the two end supporting units 1 and the middle supporting unit 2 through the input pipeline 8, the water in the end supporting units 1 and the middle supporting unit 2 is discharged into the water storage tank 7 through the output pipeline 9, the total heights of the two end supporting units 1 and the middle supporting unit 2 are respectively adjusted by changing the water amounts in the end supporting units 1 and the middle supporting unit 2, because the ends of the two end supporting units 1 and the middle supporting unit 2 far away from the ground are movably provided with the connecting frames 11, each connecting frame 11 is movably connected with the frame 3 of the mounting frame 561, so as to adjust the inclination angle of the mounting frame 561, the solar panel 4 can better absorb solar energy, and compared with a traditional mode in which a motor is adopted and the inclination angle of the solar frame is adjusted, the solar frame can reduce energy consumption by adopting the structure.

Referring to fig. 1 to 5, further, each of the two end supporting units 1 and the middle supporting unit 2 includes a bottom plate 12, a bellows box 13 and a mounting plate 14, the bottom plate 12 is detachably connected to the ground, one end of the bellows box 13 is detachably connected to the bottom plate 12, the other end of the bellows box 13 is detachably connected to the mounting plate 14, the mounting plate 14 is movably provided with the connecting frame 11, two sides of the bellows box 13 are respectively provided with a water inlet 15 and a water outlet 16, the water inlet 15 corresponds to the input pipeline 8, and the water outlet 16 is provided with the output pipeline 9.

In the present embodiment, the height of the bellows box 13 is increased by supplying water into the bellows box 13 through the water inlet 15, the height of the bellows box 13 is decreased by discharging water from the bellows box 13 through the water inlet 15, and the overall height of the end support unit 1 and the middle support unit 2 is adjusted by the amount of water in the bellows box 13.

Referring to fig. 1 to 5, further, each of the input pipelines 8 includes a first connection pipe 81, a first electronic control valve 82 and a delivery pipe 83, the first connection pipe 81 is disposed at one end of the first electronic control valve 82, the delivery pipe 83 is disposed at the other end of the first electronic control valve 82, the first electronic control valve 82 is electrically connected to the main controller 31, the first connection pipe 81 corresponds to the water outlet end of the water storage tank 6, and the delivery pipe 83 corresponds to the water inlet 15.

In this embodiment, when the height of the bellows tank 13 needs to be increased, the main controller 31 controls the first electrically controlled valve 82 to open, so that the water in the water storage tank 6 is delivered to the inside of the corresponding bellows tank 13 through the first connecting pipe 81 and the delivery pipe 83.

Referring to fig. 1 to 5, further, each of the output pipelines 9 includes a second connecting pipe 91, a second electronic control valve 92 and a water discharging pipe 93, the second connecting pipe 91 is disposed at one end of the second electronic control valve 92, the water discharging pipe 93 is disposed at the other end of the second electronic control valve 92, the second electronic control valve 92 is electrically connected to the main controller 31, the water discharging pipe 93 corresponds to the water outlet 16, and the second connecting pipe 91 corresponds to the water inlet end of the water storage tank 7.

In this embodiment, when the water in the bellows box 13 needs to be discharged, the opening of the second electronic control valve 92 is controlled by the main controller 31, so that the water in the bellows box 13 is discharged to the inside of the water storage tank 7 through the water discharge pipe 93 and the second connection pipe 91.

Referring to fig. 1 to 5, further, each of the connection frames 11 includes a frame body 111, a first support leg 112 and a second support leg 113, the connection frame 32 is disposed at two ends of the bottom of the installation frame, the first support leg 112 is disposed at one end of the frame body 111, the second support leg 113 is disposed at the other end of the frame body 111, the first support leg 112 is movably connected to the installation plate 14, and the second support leg 113 is movably connected to the connection frame 32.

In this embodiment, the first leg 112 and the second leg 113 are respectively disposed at two ends of the frame body 111, the first leg 112 is movably mounted on the mounting plate 14, and the second leg 113 is movably mounted on the connecting frame 32, so that the connecting frame 11 is movably connected with the mounting frame, and the inclination angle of the mounting frame is adjusted by changing the heights of the bellows boxes 13 at the two ends.

Referring to fig. 1 to 5, further, the three-dimensional solar power generation device further includes a circulation pipeline 61, the circulation pipeline 61 includes a water pump 62, a first communication pipe 63 and a second communication pipe 64, the first communication pipe 63 is disposed at one end of the water pump 62, the second communication pipe 64 is disposed at the other end of the water pump 62, one end of the first communication pipe 63, which is far away from the water pump 62, corresponds to a water outlet end of the water storage tank 7, and one end of the second communication pipe 64, which is far away from the water pump 62, corresponds to a water inlet end of the water storage tank 6.

In this embodiment, the water pump 62 is activated to transfer the water in the water storage tank 7 to the inside of the water storage tank 6 through the first communication pipe 63 and the second communication pipe 64, thereby completing water circulation and reducing the consumption of water resources.

Referring to fig. 1 to 5, further, the solar detection unit 5 includes an installation base 51, a rotating assembly 52, a rotating plate 53, a bracket 54, a fixing plate 55, an installation assembly 56, and a solar sensor 57, the installation base 51 is detachably connected to the installation frame 561, one end of the installation base 51 away from the installation frame 561 is provided with a groove 511, the rotating assembly 52 is disposed inside the groove 511, the rotating plate 53 is movably connected to a port of the groove 511, one end of the rotating plate 53 close to the groove 511 is provided with a driven tooth portion 531, an output end of the rotating assembly 52 corresponds to the driven tooth portion 531, one end of the rotating plate 53 away from the groove 511 is provided with the bracket 54, one end of the bracket 54 away from the rotating plate 53 is provided with the fixing plate 55, the fixing plate 55 is provided with the installation assembly 56, the solar sensor 57 is disposed on the mounting assembly 56.

In this embodiment, the rotating assembly 52 is started, and the driven tooth portion 531 drives the rotating plate 53 to rotate on the mounting base 51, so as to drive the bracket 54 to rotate, and further drive the solar sensor 57 to rotate, so that the solar sensor 57 can detect the solar intensity around.

Referring to fig. 1 to 5, further, the rotating assembly 52 includes a servo motor 521, an output shaft 522 and an output gear 523, the servo motor 521 is detachably connected to the mounting seat 51 and is located at the bottom of the groove 511, the output shaft 522 is disposed at an output end of the servo motor 521, the output gear 523 is disposed on the output shaft 522, and the output gear 523 is engaged with the driven tooth portion 531.

In the present embodiment, the servo motor 521 is activated to rotate the output shaft 522, and the output gear 523 is engaged with the driven gear portion 531 to rotate the rotating plate 53.

Referring to fig. 1 to 5, further, the mounting assembly 56 includes a mounting frame 561, a mounting body 562, a driving motor 563, and a gear reducer 564, the mounting frame 561 and the driving motor 563 are disposed on the fixing plate 55, one end of the mounting body 562 is movably connected to the mounting frame 561, the other end of the mounting body 562 is provided with the solar sensor 57, an output end of the driving motor 563 is provided with the gear reducer 564, an output end of the gear reducer 564 is provided with a fixture block 565, the mounting body 562 is provided with a fixture groove 566, and the fixture block 565 is adapted to the fixture groove 566.

In this embodiment, the driving motor 563 is started, and the gear reduction box 564 is utilized to slow down the output rotation speed of the driving motor 563, and then drive the fixture block 565 to rotate, so that the fixture block 565 is adapted to the fixture groove 566, and thus the mounting body 562 is driven to rotate on the mounting frame 561, the inclination angle of the solar sensor 57 is adjusted, and the monitoring range of the solar sensor 57 is further expanded.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A three-dimensional solar power generation device is characterized in that,

the three-dimensional solar power generation device comprises two end supporting units (1), a middle supporting unit (2), an installation frame (3), a solar panel (4), a solar detection unit (5), a water storage tank (6), a water storage tank (7), a plurality of input pipelines (8), a plurality of output pipelines (9) and a master controller (31), wherein the solar panel (4) and the master controller (31) are arranged on the installation frame (3), two end supporting units (1) and the middle supporting unit (2) are arranged between the installation frame (3) and the ground, the two end supporting units (1) are respectively arranged at two ends of the installation frame (3), the middle supporting unit (2) is arranged at the middle part of the installation frame (3), and one ends, far away from the ground, of the two end supporting units (1) and one end, far away from the ground, of the middle supporting unit (2) are both movably provided with a connecting frame (11), each connecting frame (11) is movably connected with the mounting frame (3), the water storage tank (6) is arranged on the ground, the water storage tank (6) is provided with a plurality of input pipelines (8), the output end of each output pipeline (9) is respectively corresponding to the two end supporting units (1) and the middle supporting unit (2), the water storage tank (7) is arranged underground, the output pipelines (9) are respectively arranged on the two end supporting units (1) and the middle supporting unit (2), the output end of each output pipeline (9) is corresponding to the water storage tank (7), the mounting frame (3) is further provided with the solar detection unit (5), and the solar detection unit (5) is electrically connected with the master controller (31);

two tip supporting unit (1) with middle part supporting unit (2) all include bottom plate (12), flexible bag case (13) and mounting panel (14), bottom plate (12) are dismantled with ground and are connected, the one end of flexible bag case (13) with bottom plate (12) are dismantled and are connected, the other end of flexible bag case (13) with mounting panel (14) are dismantled and are connected, the activity is provided with on mounting panel (14) link (11), the both sides of flexible bag case (13) are provided with water inlet (15) and delivery port (16) respectively, water inlet (15) with input pipeline (8) are corresponding, be provided with on delivery port (16) output pipeline (9).

2. The stereoscopic solar power generation apparatus of claim 1,

every input pipeline (8) all includes first connecting pipe (81), first automatically controlled valve (82) and conveyer pipe (83), the one end of first automatically controlled valve (82) is provided with first connecting pipe (81), the other end of first automatically controlled valve (82) is provided with conveyer pipe (83), first automatically controlled valve (82) with master controller (31) electric connection, first connecting pipe (81) with the play water end of water storage box (6) is corresponding, conveyer pipe (83) with water inlet (15) are corresponding.

3. The stereoscopic solar power generation apparatus of claim 2,

every output line (9) all includes second connecting pipe (91), second automatically controlled valve (92) and drain pipe (93), the one end of second automatically controlled valve (92) is provided with second connecting pipe (91), the other end of second automatically controlled valve (92) is provided with drain pipe (93), second automatically controlled valve (92) with master controller (31) electric connection, drain pipe (93) with delivery port (16) are corresponding, second connecting pipe (91) with the end of intaking of storage water tank (7) is corresponding.

4. The stereoscopic solar power generation apparatus of claim 1,

every link (11) all includes support body (111), first stabilizer blade (112) and second stabilizer blade (113), the both ends of the bottom of installation frame (3) all are provided with connecting frame (32), the one end of support body (111) is provided with first stabilizer blade (112), the other end of support body (111) is provided with second stabilizer blade (113), first stabilizer blade (112) with mounting panel (14) swing joint, second stabilizer blade (113) with connecting frame (32) swing joint.

5. The stereoscopic solar power generation apparatus of claim 1,

three-dimensional solar power system still includes circulating line (61), circulating line (61) includes water pump (62), first communicating pipe (63) and second communicating pipe (64), the one end of water pump (62) is provided with first communicating pipe (63), the other end of water pump (62) is provided with second communicating pipe (64), first communicating pipe (63) are kept away from the one end of water pump (62) with the play water end of storage water tank (7) is corresponding, second communicating pipe (64) are kept away from the one end of water pump (62) with the end of intaking of storage water tank (6) is corresponding.