CN113659926A

CN113659926A - Solar energy equipment of high-efficient energy storage

Info

Publication number: CN113659926A
Application number: CN202110965938.7A
Authority: CN
Inventors: 董海婷
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-08-23
Filing date: 2021-08-23
Publication date: 2021-11-16

Abstract

The invention discloses a high-efficiency energy-storage solar device which comprises a device mounting plate, wherein a solar panel for solar power generation is fixedly arranged at the middle position in the device mounting plate, a heat exchange plate is fixedly arranged in the device mounting plate and below the solar panel, turnover plates are distributed in a matrix arrangement at the lower end in the heat exchange plate, and cooling cavities which are symmetrical about the two sides of the solar panel and have outward openings are arranged at the two sides of the device mounting plate; in the working process of the solar panel, external air flows into the heat exchange pipeline in a one-way mode, so that the overall heat exchange in the device is improved, then the light is refracted through the light-gathering plate in the device, the effect of refracting the light source to the surface of the solar panel is achieved, the light intensity on the surface of the solar panel is improved through light-gathering refraction while the light intensity is increased, the power generation efficiency of the solar panel is improved, and the energy storage efficiency is improved.

Description

Solar energy equipment of high-efficient energy storage

Technical Field

The invention relates to the field of solar equipment, in particular to solar equipment with high-efficiency energy storage.

Background

Solar energy equipment collects and generates electricity through energy released by the sun, and solar energy electricity generation as a novel energy source is increasingly emphasized by people, and with the deep research of the solar energy electricity generation technology, the improvement of the efficiency of solar power generation and energy storage is gradually paid attention by researchers, and in the process of long-time solar irradiation and power generation of a common solar power generation panel, the increase in temperature causes the storage conversion efficiency of the cell to decrease, and the solar power generation is affected by the weather and the intensity of the illumination radiation, in an environment with weak illumination intensity, the power generation efficiency of the solar panel is reduced, if the light beam is condensed by the light condensing component, the internal temperature of the solar panel is further increased, therefore, the energy storage and power generation efficiency of the solar panel cannot be well improved.

Disclosure of Invention

The invention aims to provide a solar device with high-efficiency energy storage, and solves the problem that when the solar panel adopts light gathering for ending the illumination intensity problem, the working temperature is increased, so that the energy storage of the solar panel cannot be effectively improved.

The invention is realized by the following technical scheme.

The invention relates to a high-efficiency energy-storage solar device, which comprises a device mounting plate, wherein a solar panel for solar power generation is fixedly arranged at the middle position in the device mounting plate, a heat exchange plate is fixedly arranged in the device mounting plate and below the solar panel, turnover plates are distributed in a matrix arrangement at the lower end in the heat exchange plate, cooling cavities which are symmetrical about two sides of the solar panel and have outward openings are arranged at two sides of the device mounting plate, two sides of all the turnover plates are communicated with the cooling cavities, turnover plates capable of being turned over are arranged in the cooling cavities at two sides, a light-gathering component is arranged in each turnover plate, the light-gathering component can directionally refract solar light through light gathering after the turnover plates are turned over and improve the light intensity received by the solar panel, a fixing plate is fixedly arranged on the lower end face of the device mounting plate, and a storage cavity is arranged in each fixing plate and is used for storing high-pressure air, the storage cavity is close to solar panel one side is equipped with the inside gas outlet of opening, equipment mounting panel lateral wall is fixed and is equipped with the subassembly that flows, the subassembly that flows can promote the air flow in the heat exchange tube.

Preferably, both sides it is equipped with the axis of rotation to rotate between the two walls in cooling chamber, both sides the returning face plate is close to solar panel a side end face respectively with the outer disc fixed connection of axis of rotation, both sides a cooling chamber lateral wall internal fixation is equipped with the rotation motor, axis of rotation one end power connect in rotate the motor.

Preferably, the spotlight component is including being located in the roll-over panel and the ascending upset chamber of opening, it is equipped with the back shaft to rotate between two walls in the upset intracavity, the outer disc fixedly connected with solar panel of back shaft, an upset chamber lateral wall internal fixation is equipped with the trip shaft, back shaft one end power connect in the trip shaft.

Preferably, the upset chamber is kept away from establish the line wheel chamber in the trip shaft lateral wall, the back shaft is close to line wheel chamber a side end extends to line wheel intracavity and fixedly connected with rotate the line wheel, the outer disc fixedly connected with of rotation line wheel connects the stay cord, rotate the line wheel with fixedly connected with torsion spring between a lateral wall of line wheel chamber.

Preferably, a closed cavity is communicated between the two walls of the upper wall of the air outlet, a closed plate capable of moving up and down is arranged in the closed cavity, a closed spring is fixedly connected between the upper end face of the closed plate and the end face of the upper wall of the closed cavity, a connecting pull rope is fixedly connected to the upper end face of the closed plate, and the connecting pull rope is connected with the connecting pull rope.

Preferably, the subassembly that flows include with a lateral wall fixed connection's of equipment fixing panel backup pad, backup pad upper end fixedly connected with uses the working plate that the heat conduction material made to conveniently carry out the heat exchange, be equipped with the ascending ponding chamber of opening in the backup pad, ponding chamber bottom side is equipped with the inclined plane of slope, all the intercommunication is equipped with same rotation motor between the heat exchange pipeline, rotate the motor with the ponding chamber is close to a lateral wall intercommunication of equipment fixing panel, the ponding chamber is kept away from a lateral wall intercommunication of equipment fixing panel is equipped with the decurrent outlet conduit of opening.

Preferably, the opening part above the water accumulation cavity is provided with a circular supporting disc, the outer circular surface of the supporting disc is annularly distributed with supporting connecting rods which are fixedly connected, and the supporting connecting rods are far away from one side end face of the supporting disc and fixedly connected with the inner wall of the water accumulation cavity so as to play a role in stable support.

Preferably, ponding intracavity rotates and is equipped with the transmission shaft, the support disc that the transmission shaft runs through and with the support disc rotates and connects, the outer disc of transmission shaft just is located the ponding intracavity is from last to matrix arrangement distribution down and has rotated the fan, the outer disc of transmission shaft just is located support disc top fixedly connected with wind vane.

Preferably, the heat exchange plate adopts the heat conduction material preparation, the heat exchange plate with the working plate is close to equipment mounting panel side end face offsets, the storage intracavity has high-pressure gas, the elastic plate has elasticity and ductility.

The invention has the beneficial effects that: in the working process of the solar panel, external air flows into the heat exchange pipeline in a one-way mode, so that the overall heat exchange in the device is improved, then the light is refracted through the light collecting plate in the device, the effect of refracting a light source to the surface of the solar panel is achieved, the light intensity on the surface of the solar panel is improved through light-gathering refraction while the light intensity is increased, the power generation efficiency of the solar panel is improved, the energy storage efficiency is improved, the working temperature of the solar panel is increased after the light-gathering work is carried out through the light collecting plate for a period of time, meanwhile, the heat exchange efficiency of the solar panel and the heat exchange plate is improved through improving the air flow in the heat exchange pipeline, and the effect of improving the solar energy storage is achieved through stabilizing the working temperature of the solar panel.

Drawings

In order to more clearly illustrate the embodiments of the 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, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic diagram of the working state of an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of B-B in FIG. 1 according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of C-C in FIG. 1 according to an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the embodiment of the present invention at D in FIG. 1;

FIG. 7 is an enlarged schematic view of the embodiment of the present invention at E in FIG. 3;

FIG. 8 is an enlarged schematic view at F of FIG. 5 according to an embodiment of the present invention;

fig. 9 is a schematic perspective view of the flow assembly shown in fig. 3 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-9, wherein for ease of description the orientations described below are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The solar energy equipment with high-efficiency energy storage, which is described in conjunction with the attached drawings 1-9, comprises an equipment mounting plate 11, a solar panel 21 for solar power generation is fixedly arranged at the middle position in the equipment mounting plate 11, a heat exchange plate 20 is fixedly arranged in the equipment mounting plate 11 and below the solar panel 21, turnover plates 14 are distributed in the heat exchange plate 20 in a matrix arrangement manner at the lower end, cooling cavities 19 which are symmetrical about the two sides of the solar panel 21 and have outward openings are arranged at the two sides of the equipment mounting plate 11, the two sides of all the turnover plates 14 are communicated with the cooling cavities 19, turnover plates 14 which can be turned over are arranged in the cooling cavities 19 at the two sides, a light gathering component is arranged in the turnover plates 14, the light gathering component can directionally refract solar light through light gathering after the turnover plates 14 are turned over and improve the light intensity received by the solar panel 21, the fixed plate 13 that is equipped with of terminal surface under the equipment mounting panel 11, be equipped with in the fixed plate 13 and store chamber 12 and be used for saving high-pressure air, storage chamber 12 is close to solar panel 21 one side is equipped with the inside gas outlet 39 of opening, the fixed subassembly that flows that is equipped with of equipment mounting panel 11 lateral wall, the subassembly that flows can promote air flow in the heat exchange pipeline 24.

Beneficially, a rotating shaft 18 is rotatably arranged between two walls of the cooling cavity 19 on two sides, one end surface of the turning plate 14 on one side close to the solar panel 21 on two sides is respectively and fixedly connected with an outer circular surface of the rotating shaft 18, a rotating motor 33 is fixedly arranged in one side wall of the cooling cavity 19 on two sides, and one end of the rotating shaft 18 is dynamically connected to the rotating motor 33.

Beneficially, the light condensing assembly comprises a turnover cavity 17 which is located in the turnover plate 14 and has an upward opening, a support shaft 15 is rotatably arranged between two walls in the turnover cavity 17, a light condensing plate 16 is fixedly connected to an outer circumferential surface of the support shaft 15, a turnover shaft 34 is fixedly arranged in one side wall of the turnover cavity 17, and one end of the support shaft 15 is dynamically connected to the turnover shaft 34.

Beneficially, a wire wheel cavity 44 is arranged in one side wall of the overturning cavity 17 far away from the overturning shaft 34, one side end face of the supporting shaft 15 near the wire wheel cavity 44 extends into the wire wheel cavity 44 and is fixedly connected with a rotating wire wheel 43, a connecting pull rope 46 is fixedly connected to the outer circular surface of the rotating wire wheel 43, and a torsion spring 45 is fixedly connected between the rotating wire wheel 43 and one side wall of the wire wheel cavity 44.

Beneficially, a closed cavity 36 is communicated between the two walls of the upper wall of the air outlet 39, a closing plate 38 capable of moving up and down is arranged in the closed cavity 36, a closing spring 37 is fixedly connected between the upper end face of the closing plate 38 and the end face of the upper wall of the closed cavity 36, a connecting pull rope 35 is fixedly connected to the upper end face of the closing plate 38, and the connecting pull rope 35 is connected to the connecting pull rope 46.

Advantageously, the flow assembly comprises a support plate 27 fixedly connected with a side wall of the equipment mounting plate 11, a working plate 30 made of heat conducting material is fixedly connected to the upper end of the support plate 27 for facilitating heat exchange, a water accumulation cavity 26 with an upward opening is arranged in the support plate 27, an inclined plane 28 is arranged at the bottom side of the water accumulation cavity 26, the same rotating motor 33 is communicated with all the heat exchange pipelines 24, the rotating motor 33 is communicated with the water accumulation cavity 26 close to the side wall of the equipment mounting plate 11, and a water outlet pipeline 29 with a downward opening is communicated with a side wall of the water accumulation cavity 26 far away from the equipment mounting plate 11.

Beneficially, a circular supporting disk 41 is arranged at an upper opening in the water collecting cavity 26, supporting connecting rods 42 which are fixedly connected are distributed on an outer circular surface of the supporting disk 41 in an annular arrangement, and an end surface of one side of the supporting connecting rod 42, which is far away from the supporting disk 41, is fixedly connected with an inner wall of the water collecting cavity 26, so that a stable supporting effect is achieved.

Beneficially, the water collecting cavity 26 is provided with a transmission shaft 32 rotatably therein, the transmission shaft 32 penetrates through a support disc 41 and is rotatably connected with the support disc 41, the rotating fans 31 are distributed on the outer circular surface of the transmission shaft 32 and located in the water collecting cavity 26 in a matrix arrangement from top to bottom, and the wind vane 40 is fixedly connected on the outer circular surface of the transmission shaft 32 and located above the support disc 41.

Advantageously, the heat exchange plate 20 is made of a heat-conducting material, the heat exchange plate 20 is in abutment with an end face of the working plate 30 on the side close to the equipment mounting plate 11, the storage chamber 12 stores high-pressure gas therein, and the elastic plate 25 is elastic and malleable.

In the initial state, the two side turning plates 14 are in the horizontal position, the two side light-gathering plates 16 are in the horizontal position, the closing plate 38 is in the lower limit position and closes the left and right sides of the air outlet 39

When the solar cooling device works, the device mounting plate 11 is integrally mounted on the roof of a house, solar power generation and energy storage are carried out by illumination through the solar panel 21, at the same time, when solar power generation is carried out, temperature difference is generated between the cooling cavity 19 and the outside because of light energy blockage of the turnover plates 14 on the two sides and the solar panel 21, at the same time, the inside of the cooling cavity 19 is not illuminated by illumination in the solar power generation process of the solar panel 21 in the daytime, meanwhile, in the process of wind blowing generated by the circulation of outside air through the wind vane 40, the wind vane 40 is driven by outside air flow and rotates and drives the transmission shaft 32 to rotate, at the same time, the transmission shaft 32 rotates and drives all the rotating fans 31 to rotate, at the same time, air in the water accumulation cavity 26 is driven by the rotating fans 31 and is discharged upwards, at the same time, in the process of guiding and discharging the air in the water accumulation cavity 26, the air in the connecting pipeline 23 is guided to be discharged into the water accumulation cavity 26 due to air pressure difference and is discharged outwards through the subsequent rotation of the rotating fans 31, at this time, the air pressure in the connecting pipeline 23 is reduced due to the exhaust, at this time, the air in all the heat exchange pipelines 24 enters the connecting pipeline 23 through flowing, the air with lower temperature in the cooling cavity 19 is sucked into the heat exchange pipeline 24, and the heat exchange of the air is performed through the heat exchange plate 20, so as to perform cooling heat exchange in the process of performing solar power generation work on the solar panel 21, further enable the temperature of the energy storage panel in the solar panel 21 to be relatively proper, further reduce the energy storage efficiency reduction of the solar panel 21 due to temperature increase, further improve the energy storage efficiency of the solar panel 21, at this time, if the solar position changes due to weather problems or due to time, the illumination intensity received by the solar energy is reduced, at this time, the rotating motor 33 is controlled to start, at this time, the rotating motor 33 is started and drives the rotating shaft 18 to rotate, the rotating shaft 18 drives the turnover plate 14 to rotate through fixed connection, at the moment, the turnover plates 14 on two sides are turned upwards to a proper angle, meanwhile, the turnover plates 14 drive the elastic plates 25 on two sides to deform and extend, the cavity volume of the cooling cavity 19 is further enlarged, and then, through increasing a unidirectional opening, the outside air can flow into the heat exchange pipeline 24 only in a unidirectional way, so that the whole heat exchange in the device is improved, then, the light is refracted through the light-gathering plate 16 in the device, the effect of refracting the light source to the surface of the solar panel 21 is achieved, further, the illumination intensity on the surface of the solar panel 21 is improved through light-gathering refraction at the same time of the illumination intensity, the power generation efficiency of the solar panel 21 is improved, so that the energy storage efficiency is improved, and meanwhile, when the illumination position of refraction is changed due to the change of the light source position, the control supporting shaft 15 is started to rotate through the turnover shaft 34, at the moment, the supporting shaft 15 rotates and drives the light gathering plate 16 to turn over through fixed connection, at the moment, the angle of light refraction is changed through the turning over of the light gathering plate 16, so that the effect of always keeping light gathering and refraction on the surface of the solar panel 21 is achieved, meanwhile, the supporting shaft 15 drives the rotating wire wheel 43 to rotate by overcoming the elastic force of the torsion spring 45 in the process of rotating the turning shaft 34, at the moment, the rotating wire wheel 43 rotates and pulls the connecting pull rope 46 to wind on the surface of the rotating wire wheel 43, at the moment, the connecting pull rope 46 pulls the connecting pull rope 35 through connection, at the moment, the closing plate 38 connected with the connecting pull rope 35 moves upwards by overcoming the elastic force of the closing spring 37, at the moment, the closing plate 38 moves upwards and opens the left side and the right side of the air outlet 39, at the moment, high-pressure air stored in the storage cavity 12 is discharged through the air outlet 39 and enters the heat exchange pipeline 24, and further drives the air in the heat exchange pipeline 24 to flow with the connecting pipeline 23, further, the heat exchange between the heat exchange plate 20 and the solar panel 21 is improved, so that the temperature of the solar panel 21 for solar energy work is kept stable, the working temperature of the solar panel 21 is increased after the light condensing work is performed for a period of time through the light condensing plate 16, meanwhile, the heat exchange efficiency between the solar panel 21 and the heat exchange plate 20 is improved by improving the air flow in the heat exchange pipeline 24, the effect of improving solar energy storage is further achieved by stabilizing the working temperature of the solar panel 21, meanwhile, in rainy days, part of rainwater is collected through the water accumulation cavity 26, and the excessive rainwater is discharged through the water outlet pipeline 29 so as not to enter the connecting pipeline 23, when the solar power generation work is performed in the next sunny day, the rainwater stored at the bottom of the water accumulation cavity 26 is accelerated to be vaporized and discharged due to the temperature increase in the water accumulation cavity 26 through the connection between the working plate 30 and the surface of the heat exchange plate 20, further, the air in the water accumulating cavity 26 is promoted to be discharged outwards, so that the flow velocity of the air flow in the connecting pipeline 23 and the water accumulating cavity 26 is increased, and the heat exchange between the solar panel 21 and the heat exchange plate 20 is improved.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a solar energy equipment of high-efficient energy storage, includes equipment mounting panel, its characterized in that: a solar panel for solar power generation is fixedly arranged in the middle of the equipment mounting plate, a heat exchange plate is fixedly arranged in the equipment mounting plate and below the solar panel, turnover plates are distributed in the heat exchange plate in a matrix arrangement manner, cooling cavities which are symmetrical about the two sides of the equipment mounting plate and have outward openings are arranged on the two sides of the equipment mounting plate, the two sides of each turnover plate are communicated with the cooling cavities, turnover plates capable of being turned over are arranged in the cooling cavities on the two sides, light-gathering components are arranged in the turnover plates and can be used for directionally refracting sunlight and improving the illumination intensity received by the solar panel through light gathering after the turnover plates are turned over, a fixing plate is fixedly arranged on the lower end face of the equipment mounting plate, a storage cavity is arranged in the fixing plate and is used for storing high-pressure air, and an air outlet with an inward opening is arranged on one side, close to the solar panel, a flowing component is fixedly arranged on one side wall of the equipment mounting plate and can promote the air flow in the heat exchange pipeline.

2. An efficient energy storage solar power plant as in claim 1, wherein: two sides rotate between the two walls of cooling chamber and be equipped with the axis of rotation, both sides the returning face plate is close to solar panel a side terminal surface respectively with the outer disc fixed connection of axis of rotation, both sides a cooling chamber lateral wall internal fixation is equipped with the rotation motor, axis of rotation one end power connect in the rotation motor.

3. An efficient energy storage solar power plant as in claim 1, wherein: the light condensation component comprises a turnover cavity which is positioned in the turnover plate and has an upward opening, a support shaft is arranged between two walls in the turnover cavity in a rotating mode, the outer circular surface of the support shaft is fixedly connected with a light condensation plate, a turnover shaft is fixedly arranged in one side wall of the turnover cavity, and one end of the support shaft is in power connection with the turnover shaft.

4. A high efficiency energy storing solar energy apparatus as claimed in claim 3, wherein: the wire wheel cavity is arranged in the side wall of the turnover shaft and is far away from the turnover cavity, the supporting shaft is close to one side end face of the wire wheel cavity and extends to the wire wheel cavity and the fixedly connected wire wheel, the outer circular face of the wire wheel is fixedly connected with a connection stay cord, and the wire wheel is rotated and the torsion spring is fixedly connected between the side walls of the wire wheel cavity.

5. An efficient energy storage solar power plant as in claim 1, wherein: the gas outlet structure is characterized in that a closed cavity is communicated between the two walls of the upper wall of the gas outlet, a closed plate capable of moving up and down is arranged in the closed cavity, a closed spring is fixedly connected between the upper end face of the closed plate and the end face of the upper wall of the closed cavity, a connecting pull rope is fixedly connected to the upper end face of the closed plate, and the connecting pull rope is connected with the connecting pull rope.

6. An efficient energy storage solar power plant as in claim 1, wherein: the subassembly that flows include with equipment fixing panel lateral wall fixed connection's backup pad, backup pad upper end fixedly connected with uses the working plate that the heat conduction material was made to conveniently carry out the heat exchange, be equipped with the ascending ponding chamber of opening in the backup pad, ponding chamber bottom side is equipped with the inclined plane of slope, all the intercommunication is equipped with same rotation motor between the heat exchange pipeline, rotate the motor with the ponding chamber is close to equipment fixing panel lateral wall intercommunication, the ponding chamber is kept away from equipment fixing panel lateral wall intercommunication is equipped with the decurrent outlet conduit of opening.

7. An efficient energy storage solar power plant as in claim 1, wherein: the water collecting device is characterized in that a supporting disc is arranged at an opening at the upper part in the water collecting cavity, supporting connecting rods fixedly connected are distributed on the outer circular surface of the supporting disc in an annular arrangement mode, and the supporting connecting rods are far away from one side end face of the supporting disc and fixedly connected with the inner wall of the water collecting cavity so as to play a role in stable supporting.

8. An efficient energy storage solar power plant as in claim 7 wherein: the ponding intracavity rotates and is equipped with the transmission shaft, the support disc that the transmission shaft runs through and with the support disc rotates and connects, the outer disc of transmission shaft just is located the ponding intracavity is from last to distributing down the matrix arrangement and has the rotation fan, the outer disc of transmission shaft just is located support disc top fixedly connected with wind vane.

9. An efficient energy storage solar power plant as in claim 1, wherein: the heat exchange plate adopts the heat conduction material preparation, the heat exchange plate with the working plate is close to equipment mounting panel side end face offsets, the storage intracavity has high-pressure gas, the elastic plate has elasticity and ductility.