CN115291635A - High-efficient solar energy conversion photovoltaic power generation system - Google Patents

Abstract

The invention relates to a high-efficiency solar-to-photovoltaic power generation system in the technical field of photovoltaic power generation, which comprises a solar panel, wherein a temperature sensor is arranged on the outer surface of the solar panel, the signal output end of the temperature sensor is connected with one end of a signal wire, the other end of the signal wire is connected with a PLC (programmable logic controller), the signal output end of the PLC is connected with one end of a control wire, and the other end of the control wire is connected with a double-shaft motor; a first supporting plate is installed on the outer wall of one side of the solar panel, a rack is installed at the bottom of the first supporting plate, and the rack is used for adjusting the angle of the solar panel; the double-shaft motor is used for driving the rack to move, transmitting a temperature measurement result to the PLC control panel, judging and processing the temperature measurement result by the PLC control panel, controlling the double-shaft motor to rotate forwards or backwards, and adjusting the angle of the solar panel, so that the solar panel can be always kept at the optimal angle to perform power generation operation, and the photoelectric conversion efficiency is improved.

Description

High-efficient solar energy conversion photovoltaic power generation system

Technical Field

The invention relates to the technical field of photovoltaic power generation, in particular to a high-efficiency solar-to-photovoltaic power generation system.

Background

The solar energy-to-photovoltaic power generation system, also called photovoltaic, referred to as photovoltaic for short, refers to a facility for converting solar energy into direct current electrical energy by using the photovoltaic effect of a photovoltaic semiconductor material, and the core of the photovoltaic facility is a solar photovoltaic panel.

When the existing solar power generation system is used, the angle of a solar panel needs to be adjusted manually, maximum power point tracking is achieved, and the workload is large, so that a high-efficiency solar-to-photovoltaic power generation system is provided.

Disclosure of Invention

Aiming at the problems, the invention provides a high-efficiency solar-energy conversion photovoltaic power generation system, which is characterized in that a PLC control panel is used for judging and processing, a double-shaft motor is controlled to rotate forwards or backwards, and the angle of a solar panel is adjusted, so that the solar panel can be always kept at the optimal angle for power generation operation, and the photoelectric conversion efficiency is improved.

The technical scheme of the invention is as follows: a high-efficiency solar-to-photovoltaic power generation system comprises a solar panel, wherein a temperature sensor is mounted on the outer surface of the solar panel, the signal output end of the temperature sensor is connected with one end of a signal wire, the other end of the signal wire is connected with a PLC control panel, the signal output end of the PLC control panel is connected with one end of a control wire, and the other end of the control wire is connected with a double-shaft motor;

a first supporting plate is mounted on the outer wall of one side of the solar panel, a rack is mounted at the bottom of the first supporting plate, and the rack is used for adjusting the angle of the solar panel;

the double-shaft motor is used for driving the rack to move.

In a further technical scheme, install dwang one on one of them output of biax motor, the gear is installed to the one end of dwang one, gear and rack toothing.

In a further technical scheme, the internally mounted of rack has a slide bar one, the one end of slide bar one runs through the rack setting, the support column is installed to the one end of slide bar one, the externally mounted of support column has the PLC control panel, the externally mounted of support column has the motor case, the internally mounted of motor case has the double-shaft motor.

In a further technical scheme, install the worm on one of them output of double-shaft motor, the outside of worm is provided with the worm wheel, worm wheel and worm meshing, the internally mounted of worm wheel has dwang two, the worm wheel setting is run through to the one end of dwang two.

In a further technical scheme, backup pad two is installed to the one end of dwang two, one side outer wall of backup pad two is installed on the outer wall of support column, the rolling wheel is installed to the one end of dwang two, around being equipped with on the outer wall of rolling wheel and connecting the rope, sliding block one is installed to the one end of connecting the rope, the externally mounted of sliding block one has the brush, the brush is connected with solar panel.

In a further technical scheme, install spring one on one side outer wall of sliding block one, sliding block two is installed to the one end of spring one, sliding block one is connected with sliding block two, the one end of sliding block one runs through the setting of sliding block two, the internally mounted of sliding block two has slide bar two, the one end of slide bar two runs through the setting of sliding block two, the one end of slide bar two is installed on the outer wall of support column.

In a further technical scheme, spring two is installed to one side outer wall of sliding block two, the one end of spring two is installed on the outer wall of support column, install dwang three on the outer wall of support column, the externally mounted of dwang three has solar panel, solar panel setting is run through to the one end of dwang three, the base is installed to the bottom of support column.

In a further technical scheme, a third supporting plate is installed on the outer wall of one side of the solar panel, a supporting rod is installed on the outer wall of one side of the third supporting plate, an array plate is installed on the outer wall of one side of the supporting rod, semicircular small lenses are installed inside the array plate, a high-performance solar cell area is arranged on the outer surface of the solar panel, and the area is matched with the array plate.

In a further technical scheme, the efficient solar-to-photovoltaic power generation system comprises all the components and a power generation system, wherein the power generation system comprises a detection unit, an adjusting unit and an auxiliary unit, the detection unit comprises a temperature detection module, an angle detection module and a time detection module, the adjusting unit comprises an angle adjusting module, a light gathering module and a conversion module, and the auxiliary unit comprises a control module, a power module and a cleaning module.

In a further technical scheme, a signal output end of the temperature checking module is connected with a signal receiving end of the angle detecting module, a signal output end of the angle detecting module is connected with a signal receiving end of the time detecting module, a signal output end of the angle adjusting module is connected with a signal receiving end of the light condensing module, a signal output end of the light condensing module is connected with a signal receiving end of the converting module, a signal output end of the control module is connected with a signal receiving end of the power module, and a signal output end of the power module is connected with a signal receiving end of the cleaning module.

The invention has the beneficial effects that:

1. by arranging the solar panel, the double-shaft motor, the rotating rod I, the gear, the rack, the sliding rod I, the supporting plate I, the temperature sensor, the signal wire and the PLC control panel, the temperature change on the surface of the solar panel is sensed by the temperature sensor and is transmitted to the PLC control panel, the PLC control panel carries out judgment processing to control the double-shaft motor to rotate forwards or backwards and adjust the angle of the solar panel, so that the solar panel can always keep the optimal angle to carry out power generation operation, thereby improving the photoelectric conversion efficiency,

2. by arranging the worm, the worm wheel, the rotating rod II, the supporting plate II, the rolling wheel, the connecting rope, the sliding block I, the spring I, the sliding rod II, the sliding block II, the brush, the rotating rod III, the supporting column, the base, the spring II and the array plate, when the double-shaft motor adjusts the angle of the solar panel, the rolling wheel can be simultaneously driven to rotate, the rolling wheel drives the connecting rope to move, the connecting rope can drive the brush to move, and dust attached to the surface of the solar panel is brushed away, so that the photoelectric conversion efficiency is improved, meanwhile, by installing the array plate, a plurality of small lenses are arranged on the array plate, a small semicircular high-performance solar cell area on the solar panel is aligned to focus light, so that the photoelectric conversion efficiency is improved,

3. through setting up power generation system, carry out overall control to whole power generation system through the control panel, need not be controlled by the manual work, adjust solar panel's angle automatically, alleviate artificial operation intensity, only need regularly look over power generation system the operation conditions can, simple convenient easily operation.

Drawings

FIG. 1 is a schematic view of the overall structure of an embodiment of the present invention;

FIG. 2 is a front cross-sectional view of an embodiment of the present invention;

FIG. 3 is a side view structural diagram of a gear according to an embodiment of the present invention;

FIG. 4 is a top view of a solar panel according to an embodiment of the present invention;

FIG. 5 is an enlarged view of example A of the present invention;

FIG. 6 is a block diagram of a second slider according to an embodiment of the present invention;

FIG. 7 is a block diagram of an array plate according to an embodiment of the present invention;

fig. 8 is a system diagram of an embodiment of the invention.

Description of the reference numerals:

1. a solar panel; 2. a double-shaft motor; 3. rotating the rod I; 4. a gear; 5. a rack; 6. a first sliding rod; 7. a first support plate; 8. a temperature sensor; 9. a signal line; 10. a PLC control panel; 11. a worm; 12. a worm gear; 13. rotating the second rod; 14. a second support plate; 15. a winding wheel; 16. connecting ropes; 17. a first sliding block; 18. a first spring; 19. a second sliding rod; 20. a second sliding block; 21. a brush; 22. rotating the rod III; 23. a support column; 24. a base; 25. a second spring; 26. an array plate.

Detailed Description

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

The embodiment is as follows:

as shown in fig. 1-8, an efficient solar-to-photovoltaic power generation system comprises a solar panel 1, wherein the outer surface of the solar panel 1 is fixedly connected with the outer wall of one side of a temperature sensor 8, the signal output end of the temperature sensor 8 is in signal connection with one end of a signal line 9, the other end of the signal line 9 is in signal connection with the signal receiving end of a PLC control board 10, the signal output end of the PLC control board 10 is in signal connection with one end of a control line, and the other end of the control line is in signal connection with the signal receiving end of a double-shaft motor 2;

the outer wall of one side of the solar panel 1 is fixedly connected with the outer wall of one side of the first supporting plate 7, the bottom of the first supporting plate 7 is hinged to the top of the rack 5 through a hinge, and the rack 5 is used for adjusting the angle of the solar panel 1;

the double-shaft motor 2 is used for driving the rack 5 to move.

The working principle of the technical scheme is as follows:

measure the temperature of 1 surface of solar panel through temperature sensor 8, make solar panel 1 on, in, the temperature in the lower three region can obtain real-time supervision, through signal line 9 with measured temperature numerical value transmission to PLC control panel 10 department, judge by PLC control panel 10, transmit control signal to biax motor 2 department through the control line, control biax motor 2 is opened, make biax motor 2 drive rack 5 and remove, make rack 5 upwards or move down through driving backup pad 7, thereby drive solar panel 1 upwards or move down, make solar panel 1 can use dwang three 22 to rotate as the axle center, make solar panel 1 be in best sunshine angle all the time, thereby improve photoelectric conversion efficiency.

In another embodiment, as shown in fig. 2 and 3, one of the output ends of the dual-shaft motor 2 is fixedly connected with one end of the rotating rod one 3 through a coupler, one end of the rotating rod one 3 is fixedly connected with one side outer wall of the gear 4, and the gear 4 is engaged with the rack 5.

Make biax motor 2 can drive dwang 3 and rotate, dwang 3 can drive gear 4 and rotate, and gear 4 drives rack 5 and removes for rack 5 can be according to the corresponding removal that moves of rotation of gear 4.

In another embodiment, as shown in fig. 1 to 4, an inner wall of the rack 5 is slidably connected to an outer wall of the sliding rod one 6, one end of the sliding rod one 6 penetrates through the outer wall of the rack 5 and extends into the rack 5, one end of the sliding rod one 6 is fixedly connected to an outer wall of the supporting column 23, the outer wall of the supporting column 23 is fixedly connected to an outer wall of one side of the PLC control board 10, the outer wall of the supporting column 23 is fixedly connected to an outer wall of the motor cabinet, and the double-shaft motor 2 is fixedly mounted in the motor cabinet.

Make support column 23 can provide holding power for a slide bar 6 can provide holding power for rack 5, and a slide bar 6 can carry on spacingly to rack 5 simultaneously, makes rack 5 when removing, can be linear motion, can not take place the skew in the position, and support column 23 can provide holding power for PLC control panel 10, and support column 23 can provide holding power for the motor case.

In another embodiment, as shown in fig. 2 and 4, one of the output ends of the dual-shaft motor 2 is fixedly connected with one end of the worm 11 through a coupler, a worm wheel 12 is arranged outside the worm 11, the worm wheel 12 is meshed with the worm 11, the inner wall of the worm wheel 12 is fixedly connected with the outer wall of the rotating rod two 13, and one end of the rotating rod two 13 penetrates through the outer wall of the worm wheel 12 and extends to the outside of the worm wheel 12.

The double-shaft motor 2 can drive the worm 11 to rotate while driving the gear 4 to rotate, so that the worm 11 drives the worm wheel 12 to rotate, and the rotating rod two 13 rotates.

In another embodiment, as shown in fig. 2 and 4, one end of the rotating rod two 13 is movably connected with the top of the supporting plate two 14 through the bearing one, one side outer wall of the supporting plate two 14 is fixedly installed on the outer wall of the supporting column 23, one end of the rotating rod two 13 is fixedly connected with one side outer wall of the winding wheel 15, the connecting rope 16 is wound on the outer wall of the winding wheel 15 in a sliding manner, one end of the connecting rope 16 is fixedly connected with one side outer wall of the sliding block one 17, the outer wall of the sliding block one 17 is fixedly connected with the outer wall of the brush 21, one side outer wall of the brush 21 is slidably connected with the outer wall of the solar panel 1, the worm 11 drives the worm wheel 12 to rotate ten times, and the gear 4 rotates one time.

Make two 13 dwang can obtain the holding power that two backup pad 14 provided, two 13 dwang can drive wind-up pulley 15 simultaneously and rotate, wind-up pulley 15 can drive and connect 16 removal of rope, make the rolling of connection rope 16 on wind-up pulley 15, it drives a 17 removal of sliding block to connect rope 16, make a 17 drive brush 21 of sliding block remove, make brush 21 brush the lime of solar panel 1 surface, thereby make the conversion effect better, the rotational speed through worm wheel 12 sets up faster than the rotational speed of gear 4, make brush 21 can be quick brush the lime of solar panel 1 surface.

In another embodiment, as shown in fig. 2, 4-6, an outer wall of one side of the first sliding block 17 is fixedly connected to one end of the first spring 18, one end of the first spring 18 is fixedly connected to an inner wall of the second sliding block 20, an outer wall of the first sliding block 17 is slidably connected to an inner wall of the second sliding block 20, one end of the first sliding block 17 penetrates through the outer wall of the second sliding block 20 and extends into the second sliding block 20, an inner wall of the second sliding block 20 is slidably connected to an outer wall of the second sliding rod 19, one end of the second sliding rod 19 penetrates through the outer wall of the second sliding block 20 and extends out of the second sliding block 20, and one end of the second sliding rod 19 is fixedly mounted on an outer wall of the supporting column 23.

Make two 20 of sliding block can carry on spacingly to sliding block 17, two 19 of slide bars can carry on spacingly to two 20 of sliding block, and spring 18 can provide elasticity for one 17 of sliding block for sliding block 17 can slide from top to bottom in two 20 of sliding block, and simultaneously, two 20 of sliding blocks can carry out the skew of certain angle on two 19 of slide bars, make solar panel 1 carry out the in-process of angle modulation, brush board 21 can laminate with solar panel 1's surface all the time.

In another embodiment, as shown in fig. 2 and 4, an outer wall of one side of the second sliding block 20 is fixedly connected with one end of the second spring 25, one end of the second spring 25 is fixedly installed on an outer wall of the supporting pillar 23, the outer wall of the supporting pillar 23 is movably connected with one end of the third rotating rod 22 through the second bearing, the outer wall of the third rotating rod 22 is fixedly connected with an inner wall of the solar panel 1, one end of the third rotating rod 22 penetrates through the outer wall of the solar panel 1 and extends to the outside of the solar panel 1, and the bottom of the supporting pillar 23 is fixedly connected with the top of the base 24.

Make base 24 can provide the holding power for support column 23, support column 23 can provide the holding power for dwang three 22, dwang three 22 can provide the holding power for solar panel 1, solar panel 1 can use dwang three 22 to rotate as the axle center under the effect of external force simultaneously, when biaxial motor 2 counter-rotation adjusted solar panel 1's angle, connecting rope 16 was emitted from rolling wheel 15, make sliding block 17 lose the pulling force of connecting rope 16, sliding block 17 resets to the position that fig. 4 shows under the effect of spring two 25 this moment, brush except that the lime on solar panel 1 surface once more.

In another embodiment, as shown in fig. 2, 4 and 7, an outer wall of one side of the solar panel 1 is fixedly connected with an outer wall of one side of the third supporting plate, a supporting rod is fixedly installed on the outer wall of one side of the third supporting plate, an array plate 26 is fixedly installed on the outer wall of one side of the supporting rod, a plurality of semicircular small lenses are installed inside the array plate 26, and a high-performance solar cell region is arranged on the outer surface of the solar panel 1 and is matched with the array plate 26.

Make backup pad three can obtain holding power, and backup pad three can provide holding power for the bracing piece, and the bracing piece provides holding power for array board 26, through the internally mounted polylith semicircle little lens at array board 26 for these lenses can be with the directional this high performance solar cell region of sunlight, improve photoelectric conversion efficiency.

In another embodiment, as shown in fig. 1 to 8, an efficient solar-to-photovoltaic power generation system includes all the foregoing components and a power generation system, the power generation system includes a detection unit, an adjustment unit, and an auxiliary unit, the detection unit includes a temperature detection module, an angle detection module, and a time detection module, the adjustment unit includes an angle adjustment module, a light gathering module, and a conversion module, the auxiliary unit includes a control module, a power module, and a cleaning module, a signal output end of the temperature detection module is in signal connection with a signal receiving end of the angle detection module, a signal output end of the angle detection module is in signal connection with a signal receiving end of the time detection module, a signal output end of the angle adjustment module is in signal connection with a signal receiving end of the light gathering module, a signal output end of the light gathering module is in signal connection with a signal receiving end of the conversion module, a signal output end of the control module is in signal connection with a signal receiving end of the power module, and a signal output end of the power module is in signal connection with a signal receiving end of the cleaning module.

Make the control panel can be through the power generation system of inside setting, through the detecting element, the temperature to solar panel 1 surface, the angle, and the time zone in solar panel 1 place, carry out real-time detection in season, thereby according to the different time zones, calculate solar panel 1's best angle season, the angle of reunion current solar panel 1 predicts the regulation trend in the back, then provide power for angle modulation by power module, clean solar panel 1's surface through clean module, do not need the manual work to adjust, save the manpower, and the efficiency is improved.

The above examples only express the specific embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention.

Claims (10)

1. An efficient solar-to-photovoltaic power generation system, comprising a solar panel (1), characterized in that: the solar panel is characterized in that a temperature sensor (8) is mounted on the outer surface of the solar panel (1), the signal output end of the temperature sensor (8) is connected with one end of a signal wire (9), the other end of the signal wire (9) is connected with a PLC (programmable logic controller) control panel (10), the signal output end of the PLC control panel (10) is connected with one end of a control wire, and the other end of the control wire is connected with a double-shaft motor (2);

a first supporting plate (7) is mounted on the outer wall of one side of the solar panel (1), a rack (5) is mounted at the bottom of the first supporting plate (7), and the rack (5) is used for adjusting the angle of the solar panel (1);

the double-shaft motor (2) is used for driving the rack (5) to move.

2. An efficient solar-to-photovoltaic power generation system as described in claim 1 wherein: install dwang one (3) on one of them output of biax motor (2), gear (4) are installed to the one end of dwang one (3), gear (4) and rack (5) meshing.

3. An efficient solar-to-photovoltaic power generation system as recited in claim 1, wherein: the utility model discloses a rack, including rack (5), support column (23), the internally mounted of rack (5) has slide bar (6), the one end of slide bar (6) runs through rack (5) and sets up, support column (23) are installed to the one end of slide bar (6), the externally mounted of support column (23) has PLC control panel (10), the externally mounted of support column (23) has the motor case, the internally mounted of motor case has double-shaft motor (2).

4. An efficient solar-to-photovoltaic power generation system as recited in claim 1, wherein: install worm (11) on one of them output of biaxial motor (2), the outside of worm (11) is provided with worm wheel (12), worm wheel (12) and worm (11) meshing, the internally mounted of worm wheel (12) has dwang two (13), worm wheel (12) setting is run through to the one end of dwang two (13).

5. An efficient solar-to-photovoltaic power generation system as recited in claim 4, wherein: backup pad two (14) are installed to the one end of dwang two (13), one side outer wall of backup pad two (14) is installed on the outer wall of support column (23), wind-up wheel (15) are installed to the one end of dwang two (13), around being equipped with on the outer wall of wind-up wheel (15) and connecting rope (16), sliding block (17) are installed to the one end of connecting rope (16), the externally mounted of sliding block (17) has brush (21), brush (21) are connected with solar panel (1).

6. An efficient solar-to-photovoltaic power generation system as described in claim 5 wherein: install spring (18) on the one side outer wall of sliding block (17), sliding block two (20) are installed to the one end of spring (18), sliding block (17) are connected with sliding block two (20), the one end of sliding block (17) runs through sliding block two (20) and sets up, the internally mounted of sliding block two (20) has sliding rod two (19), the one end of sliding rod two (19) runs through sliding block two (20) and sets up, the one end of sliding rod two (19) is installed on the outer wall of support column (23).

7. An efficient solar-to-photovoltaic power generation system as recited in claim 6, wherein: spring two (25) are installed to one side outer wall of sliding block two (20), the one end of spring two (25) is installed on the outer wall of support column (23), install dwang three (22) on the outer wall of support column (23), the externally mounted of dwang three (22) has solar panel (1), solar panel (1) setting is run through to the one end of dwang three (22), base (24) are installed to the bottom of support column (23).

8. An efficient solar-to-photovoltaic power generation system as described in claim 1 wherein: the solar cell comprises a solar panel (1), and is characterized in that a supporting plate III is installed on the outer wall of one side of the solar panel (1), a supporting rod is installed on the outer wall of one side of the supporting plate III, an array plate (26) is installed on the outer wall of one side of the supporting rod, a semicircular small lens is installed inside the array plate (26), a high-performance solar cell area is arranged on the outer surface of the solar panel (1), and the area is matched with the array plate (26).

9. An efficient solar-to-photovoltaic power generation system, comprising all the components as claimed in claims 1 to 8 and a power generation system, wherein the power generation system comprises a detection unit, an adjustment unit and an auxiliary unit, the detection unit comprises a temperature detection module, an angle detection module and a time detection module, the adjustment unit comprises an angle adjustment module, a light condensation module and a conversion module, and the auxiliary unit comprises a control module, a power module and a cleaning module.

10. An efficient solar-to-photovoltaic power generation system as described in claim 9 wherein: the signal output end of the temperature detection module is connected with the signal receiving end of the angle detection module, the signal output end of the angle detection module is connected with the signal receiving end of the time detection module, the signal output end of the angle adjustment module is connected with the signal receiving end of the light condensation module, the signal output end of the light condensation module is connected with the signal receiving end of the conversion module, the signal output end of the control module is connected with the signal receiving end of the power module, and the signal output end of the power module is connected with the signal receiving end of the cleaning module.

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