CN112377977A

CN112377977A - Recycling auxiliary device based on solar radiation

Info

Publication number: CN112377977A
Application number: CN202011382212.2A
Authority: CN
Inventors: 郭碧水
Original assignee: Ningbo Ouge Electronic Technology Co ltd
Current assignee: Ningbo Ouge Electronic Technology Co ltd
Priority date: 2020-12-01
Filing date: 2020-12-01
Publication date: 2021-02-19

Abstract

The invention discloses a recycling auxiliary device based on solar radiation, which comprises a solar panel box, wherein a solar panel cavity with an upward opening is arranged in the solar panel box, the upper end surface of the solar panel box is fixedly connected with transparent glass, the transparent glass can seal the solar panel cavity, a solar panel is fixedly arranged on the inner wall of the lower end in the solar panel cavity, a clear water pipe is arranged in the solar panel in an array manner, and an annular gas circulation cavity is arranged in the clear water pipe in an array manner. The utilization rate of the high-temperature air is improved.

Description

Recycling auxiliary device based on solar radiation

Technical Field

The invention relates to the technical field of solar radiation collecting or absorbing devices, in particular to a solar radiation-based recycling auxiliary device.

Background

In our daily life, sunlight is visible everywhere, and devices for collecting or absorbing solar radiation are gradually widely applied, but the existing devices only absorb solar energy through a solar panel to generate electric energy for daily use, and the devices can generate heat during working, the performance of the devices can be affected by overhigh temperature, the service life of the devices can be shortened under long-term use.

Disclosure of Invention

In order to solve the problems, the embodiment designs a recycling auxiliary device based on solar radiation, the recycling auxiliary device based on solar radiation comprises a solar panel box, a solar panel cavity with an upward opening is arranged in the solar panel box, the upper end surface of the solar panel box is fixedly connected with transparent glass, the inner wall of the inner lower end of the solar panel cavity can be sealed by the transparent glass, a solar panel is fixedly arranged on the inner wall of the inner lower end of the solar panel cavity, a clear water pipe is arranged in the solar panel inner array, an annular gas circulation cavity is arranged in the clear water pipe inner array, the upper wall and the lower wall of the gas circulation cavity are symmetrical and communicated with through holes, air at the upper side of the solar panel and at the upper end of the solar panel cavity can enter the gas circulation cavity through the through holes at the upper side, and then, the solar panel comprises a solar panel cavity, wherein the left wall and the right wall of the upper end in the solar panel cavity are symmetrically and fixedly provided with air inlet check valves, the air inlet check valves can bring clean air into the upper end in the solar panel cavity, the lower end in the solar panel cavity is provided with a fan cavity with an upward opening and communicated with the lower wall in the solar panel cavity, a rotatable fan is arranged in the fan cavity, a temperature measuring box is fixedly arranged at the left side of the lower side of the air inlet check valve and positioned at the left end in the solar panel cavity, the right end of the temperature measuring box extends rightwards to the transparent glass and is fixedly provided with a temperature sensing plate, a helium cavity with a rightward opening is arranged in the temperature measuring box, helium is arranged in the helium cavity, and when the temperature of the upper end in the transparent glass rises through solar radiation, the temperature sensing plate enters the helium cavity through transferring the temperature of the temperature, when the fan rotates, the fan can drive the high-temperature gas at the upper end in the transparent glass to enter the lower end in the transparent glass and then enter the fan cavity, the connecting pipe communicated with the rear wall in the fan cavity is fixedly arranged on the left side of the lower end in the solar panel box, the connecting pipe is connected with an indoor heat circulation system, an inner heat-insulating material is arranged on the outer circular surface of the connecting pipe in a sliding mode, and when the high-temperature gas flows in the connecting pipe, the inner heat-insulating material slides downwards and then contacts with the outer circular surface of the lower end of the connecting pipe, so that the heat-insulating effect is achieved.

Preferably, a light sliding plate capable of sliding left and right is arranged in the helium cavity, the left wall in the helium cavity is communicated with a light sliding rod cavity, a light sliding rod is fixedly arranged at the center of the left end face of the light sliding plate, the left end of the light sliding rod extends leftwards to the light sliding rod cavity, a light sliding rod pull rope is fixedly connected in the light sliding rod cavity, and a light sliding rod spring is fixedly arranged between the left wall in the light sliding rod cavity and the left end face of the light sliding rod.

Preferably, the lower end of the solar panel is located at the lower side of the fan cavity, a power cavity is formed in the left side of the power cavity and located in a circulating motor box fixedly arranged in the solar panel box, a circulating motor is fixedly arranged in the circulating motor box, a circulating motor cavity is formed in the upper end face of the circulating motor box, a sliding plate is arranged in the circulating motor cavity in a sliding mode, contact switches are symmetrically and fixedly arranged between the lower end face of the sliding plate and the upper end face of the circulating motor box, a sliding plate spring is fixedly arranged between the upper end face of the sliding plate and the upper wall of the circulating motor cavity, and a sliding plate pull rope connected with the light sliding rod pull rope is fixedly arranged in the center of the upper end face.

Preferably, the left wall and the right wall of the power cavity are symmetrically provided with power shafts in a rotatable manner, the power shafts on the left side and the right side are positioned in the power cavity and are respectively and fixedly provided with power bevel gears, the left end of the power shaft on the left side extends into the circulating motor box to be in power connection with the right end face of the circulating motor, the lower end of the fan extends downwards to the inside of the power cavity and is fixedly provided with a fan bevel gear meshed with the power bevel gear, and the inner wall of the upper end of the fan cavity is fixedly provided with a fan cavity filter plate.

Preferably, a piston plate cavity is arranged at the lower end in the solar panel box and positioned on the right side of the fan cavity, a driven cavity is arranged at the lower end in the solar panel box and positioned on the lower side of the piston plate cavity, a piston plate cavity filter plate is fixedly arranged on the inner wall of the left end in the piston plate cavity, a piston plate capable of sliding left and right is arranged in the piston plate cavity, a sliding sleeve rod is fixedly arranged at the upper end of the right wall in the piston plate cavity, a sliding shaft fixedly connected with the upper side of the right end face of the piston plate is arranged in the sliding sleeve rod in a sliding manner, a driven bevel gear is fixedly arranged in the driven cavity by extending the right end of the power shaft on the right side rightwards, a rotating rod bevel gear meshed with the driven bevel gear is arranged at the upper end in the driven cavity in a rotating manner, a rotating rod is fixedly arranged at the lower end in the piston plate cavity by extending, the left end of the connecting rod is hinged with the right end face of the piston plate, and a piston cavity one-way valve connected with the air inlet one-way valve is fixedly arranged in the center of the left wall in the cavity of the piston plate.

Preferably, the outer circular surface of the inner heat-insulating material is fixedly connected with a meshing rack, an inner friction wheel cavity with an opening facing one side of the connecting pipe is symmetrically arranged at the lower end of the outer circular surface of the meshing rack in a left-right mode, an inner friction wheel shaft is arranged on the inner rear wall of the inner friction wheel cavity in a rotating mode, an inner friction wheel is fixedly arranged on the outer circular surface of the inner friction wheel shaft and located in the inner friction wheel cavity, the outer circular surface of the inner friction wheel is connected with the outer circular surface of the meshing rack in a friction mode, lower friction wheel cavities with openings facing one side away from the fan cavity are symmetrically arranged on the left side and the right side of the inner friction wheel cavity and located in the solar panel box in a left-right mode, a lower friction wheel shaft is arranged on the center of the inner rear wall of the lower friction.

Preferably, the rear side of the inner friction wheel cavity is located at the center of the rear end in the solar panel box, a sliding motor is fixedly arranged at the center of the rear end in the solar panel box, the left side and the right side of the inner friction wheel cavity are located at the rear end in the solar panel box and are respectively provided with a driving cavity, the left end and the right end of the sliding motor are symmetrically and dynamically connected with a sliding motor shaft, the left end of the sliding motor shaft extends leftwards and penetrates through the left side and the right side of the inner wall of the driving cavity, driving bevel gears are fixedly arranged on the inner wall of the driving cavity, the rear end of the inner friction wheel shaft extends backwards to the left side and the right.

Preferably, the rear side of the lower friction wheel cavity is provided with a meshing cavity, one end of the sliding motor shaft at the left side and the right side, which is far away from the sliding motor, extends to the left side and the right side respectively, a transmission bevel gear is fixedly arranged in the meshing cavity, the rear end of the lower friction wheel shaft at the left side and the right side extends backwards to the left side and the right side, a meshing bevel gear meshed with the transmission bevel gear is fixedly arranged in the meshing cavity at the left side and the right side, belt wheel cavities are respectively arranged in the inner walls of the lower friction wheel cavity at the left side and the right side, the upper end and the lower end of the belt wheel cavity are symmetrically and rotatably provided with belt wheels, a synchronous belt is wound between the belt wheels at the upper side and the lower side, the shaft center of the belt wheel at the lower side is fixedly connected with the lower friction wheel shaft, the shaft center of the belt wheel at the, the front end of the upper friction wheel shaft extends forwards to the upper friction wheel cavity, and an upper friction wheel is fixedly arranged in the upper friction wheel cavity.

Preferably, the left end and the right end of the solar panel box are symmetrically and slidably provided with outer heat insulation materials, and the outer heat insulation materials are in friction connection with the outer circular surface of the lower friction wheel and the outer circular surface of the upper friction wheel.

The invention has the beneficial effects that: according to the invention, low-temperature clean water is heated by circulating air in the cavity of the solar panel, high-temperature gas is fed into a house to form hot gas circulation, the solar panel is cooled while the house is heated, the service life of the solar panel is prolonged, and the solar panel is insulated by the insulation material, so that the heat loss is reduced, and the utilization rate of high-temperature air is improved.

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.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the structure a-a in fig. 1.

FIG. 3 is a schematic diagram of B-B in FIG. 1.

Fig. 4 is a schematic view of the structure of C-C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 1.

Fig. 6 is an enlarged schematic view of E in fig. 1.

Fig. 7 is an enlarged schematic view of F in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-7, 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 invention relates to a solar radiation-based recycling auxiliary device, which comprises a solar panel box 11, wherein a solar panel cavity 27 with an upward opening is arranged in the solar panel box 11, the upper end surface of the solar panel box 11 is fixedly connected with transparent glass 26, the transparent glass 26 can seal the solar panel cavity 27, a solar panel 28 is fixedly arranged on the inner wall of the lower end in the solar panel cavity 27, a clear water pipe 69 is arranged in the solar panel 28 in an array manner, an annular gas circulation cavity 71 is arranged in the clear water pipe 69 in an array manner, the upper wall and the lower wall in the gas circulation cavity 71 are symmetrical and are communicated with through holes 70, air at the upper end of the solar panel 28 and positioned in the solar panel cavity 27 can enter the gas circulation cavity 71 through the upper side through the through holes 70 and then enter the lower end in the solar panel cavity 27 through the lower side through the through holes 70, the upper end in the solar panel cavity 27 is symmetrical and is fixedly provided, the air inlet check valve 31 can bring clean air into the inner upper end of the solar panel cavity 27, the inner lower end of the solar panel box 11 is provided with a fan cavity 24 with an upward opening and communicated with the inner lower wall of the solar panel cavity 27, a rotatable fan 22 is arranged in the fan cavity 24, a temperature measurement box 51 is fixedly arranged at the left side of the lower side of the air inlet check valve 31 and is positioned at the left end in the solar panel box 11, the right end of the temperature measurement box 51 extends rightwards to the inner part of the transparent glass 26 and is fixedly provided with a temperature sensing plate 55, a helium cavity 56 with a rightward opening is arranged in the temperature measurement box 51, helium is arranged in the helium cavity 56, when the temperature of the inner upper end of the transparent glass 26 is raised through solar radiation, the temperature sensing plate 55 enters the helium cavity 56 through transferring the temperature thereof, and the helium cavity 56 is internally subjected to thermal expansion and contraction reaction through the helium, when the fan 22 rotates, the high-temperature gas at the upper end in the transparent glass 26 can be driven to enter the lower end in the transparent glass 26 and then enter the fan cavity 24, a connecting pipe 72 communicated with the rear wall in the fan cavity 24 is fixedly arranged on the left side of the lower end in the solar panel box 11, the connecting pipe 72 is connected with an indoor heat circulation system, an inner heat insulation material 73 is arranged on the outer circular surface of the connecting pipe 72 in a sliding manner, and when the high-temperature gas flows in the connecting pipe 72, the inner heat insulation material 73 slides downwards and then contacts with the outer circular surface of the lower end of the connecting pipe 72, so that the heat insulation effect is achieved.

Beneficially, a light sliding plate 54 capable of sliding left and right is arranged in the helium chamber 56, a light sliding rod chamber 52 is communicated with the left wall in the helium chamber 56, a light sliding rod 53 is fixedly arranged in the center of the left end face of the light sliding plate 54, the left end of the light sliding rod 53 extends leftwards to the inside of the light sliding rod chamber 52 and is fixedly connected with a light sliding rod pull rope 49, and a light sliding rod spring 50 is fixedly arranged between the left wall in the light sliding rod chamber 52 and the left end face of the light sliding rod 53.

Beneficially, a power cavity 20 is arranged at the lower end in the solar panel box 11 and at the lower side of the fan cavity 24, a circulating motor box 14 is fixedly arranged at the left side of the power cavity 20 and in the solar panel box 11, a circulating motor 15 is fixedly arranged in the circulating motor box 14, a circulating motor cavity 16 is arranged at the upper end face of the circulating motor box 14, a sliding plate 12 is slidably arranged in the circulating motor cavity 16, contact switches 13 are symmetrically and fixedly arranged between the lower end face of the sliding plate 12 and the upper end face of the circulating motor box 14, a sliding plate spring 17 is fixedly arranged between the upper end face of the sliding plate 12 and the upper wall in the circulating motor cavity 16, and a sliding plate pull rope 25 connected with the light sliding rod pull rope 49 is fixedly arranged at the center of the upper end face of the sliding plate 12.

Beneficially, a power shaft 18 is symmetrically and rotatably arranged on the left wall and the right wall in the power chamber 20, a power bevel gear 19 is fixedly arranged in the power chamber 20 on the left side and the right side of the power shaft 18 respectively, the left end of the power shaft 18 on the left side extends leftwards into the circulating motor box 14 to be in power connection with the right end face of the circulating motor 15, a fan bevel gear 21 meshed with the power bevel gear 19 is fixedly arranged in the power chamber 20 and the lower end of the fan 22 extends downwards, and a fan chamber filter plate 23 is fixedly arranged on the inner wall of the upper end in the fan chamber 24.

Beneficially, a piston plate cavity 59 is arranged at the right side of the fan cavity 24 and at the lower end in the solar panel box 11, a driven cavity 68 is arranged at the lower side of the piston plate cavity 59 and at the lower end in the solar panel box 11, a piston plate cavity filter plate 60 is fixedly arranged on the inner wall of the left end in the piston plate cavity 59, a piston plate 58 capable of sliding left and right is arranged in the piston plate cavity 59, a sliding sleeve rod 65 is fixedly arranged at the upper end of the right wall in the piston plate cavity 59, a sliding shaft 62 fixedly connected with the upper side of the right end face of the piston plate 58 is slidably arranged in the sliding sleeve rod 65, the right end of the power shaft 18 at the right side extends rightwards to the driven cavity 68 and is fixedly provided with a driven bevel gear 67, a rotating rod bevel gear 64 meshed with the driven bevel gear 67 is rotatably arranged at the upper end in the driven cavity 68, the power at the upper end face of the rotating rod bevel gear 64 extends upwards to the, the end, far away from the rotation center, of the rotating rod 63 is hinged with a connecting rod 66, the left end of the connecting rod 66 is hinged with the right end face of the piston plate 58, and a piston cavity one-way valve 57 connected with the air inlet one-way valve 31 is fixedly arranged at the center of the left wall in the piston plate cavity 59.

Advantageously, the outer circumferential surface of the inner thermal insulation material 73 is fixedly connected with an engaging rack 74, the lower end of the outer circumferential surface of the engaging rack 74 is symmetrically provided with an inner friction wheel chamber 41 with an opening facing to one side of the connecting pipe 72, the inner back wall of the inner friction wheel cavity 41 is rotationally provided with an inner friction wheel shaft 75, the outer circular surface of the inner friction wheel shaft 75 is fixedly provided with an inner friction wheel 40 positioned in the inner friction wheel cavity 41, the outer circular surface of the inner friction wheel 40 is in friction connection with the outer circular surface of the meshing rack 74, the left and right sides of the inner friction wheel cavity 41 and the left and right ends in the solar panel box 11 are symmetrically provided with lower friction wheel cavities 76 with openings facing away from one side of the fan cavity 24, a lower friction wheel shaft 78 is rotatably arranged at the center of the inner rear wall of the lower friction wheel cavity 76, and a lower friction wheel 77 is fixedly arranged on the outer circular surface of the lower friction wheel shaft 78 and positioned in the lower friction wheel cavity 76.

Beneficially, a sliding motor 42 is fixedly arranged at the rear side of the inner friction wheel cavity 41 and at the center of the rear end in the solar panel box 11, driving cavities 35 are respectively arranged at the rear side of the inner friction wheel cavity 41 and at the rear end in the solar panel box 11 at the left and right sides, sliding motor shafts 36 are symmetrically and dynamically connected at the left and right ends of the sliding motor 42, a driving bevel gear 38 is fixedly arranged on the inner wall of the driving cavity 35 at the left side and extends leftwards and penetrates the left and right sides, and a driven bevel gear 37 engaged with the driving bevel gear 38 is fixedly arranged in the driving cavity 35 and extends backwards and extends leftwards and right sides respectively at the rear end of the inner friction wheel shaft 75 at the left and right sides.

Beneficially, the rear side of the lower friction wheel cavity 76 is provided with an engaging cavity 39, the ends of the left and right sides of the sliding motor shaft 36 far away from the sliding motor 42 respectively extend to the left and right sides of the engaging cavity 39, the transmission bevel gears 34 are fixedly arranged in the engaging cavity 39, the rear ends of the left and right sides of the lower friction wheel shaft 78 extend backwards to the left and right sides of the engaging cavity 39, the engaging bevel gears 33 engaged with the transmission bevel gears 34 are fixedly arranged in the engaging cavity 39, the inner walls of the left and right sides of the engaging cavity 39 and the lower friction wheel cavity 76 are respectively provided with a belt wheel cavity 47, the upper and lower ends of the belt wheel cavity 47 are symmetrically and rotatably provided with belt wheels 48, a synchronous belt 46 is wound between the upper and lower belt wheels 48, the axis of the lower belt wheel 48 is fixedly connected with the lower friction wheel shaft 78, the axis of the upper belt wheel 48 is fixedly provided with an upper friction wheel shaft 44, the left and right An upper friction wheel cavity 45 is arranged at one side of the cavity 24, and the front end of the upper friction wheel shaft 44 extends forwards to the upper friction wheel cavity 45 and is fixedly provided with an upper friction wheel 43.

Advantageously, the solar panel box 11 is provided with outer heat insulating materials 32 at the left and right ends symmetrically and slidably, and the outer heat insulating materials 32 are connected with the outer circular surface of the lower friction wheel 77 and the outer circular surface of the upper friction wheel 43 in a friction manner.

The following describes in detail the use steps of a solar radiation-based recycling aid herein with reference to fig. 1 to 7:

in the initial state, the clean water chamber 61 is filled with low-temperature clean water, the lower end face of the outer heat insulation material 32 is flush with the lower end face of the solar panel box 11, the upper and lower side contact switches 13 are separated, the circulation motor 15 and the sliding motor 42 stop working, the helium gas chamber 56 is filled with helium gas, and the light sliding rod spring 50 is in a natural state.

When the solar panel 28 absorbs solar radiation to generate electric energy, the air at the upper end in the solar panel cavity 27 is heated to high-temperature gas through the solar radiation, the temperature sensing plate 55 conducts heat through the high-temperature gas to heat the gas in the helium gas cavity 56, the light sliding plate 54 is driven to slide leftwards through the thermal expansion and cold contraction reaction, the light sliding rod 53 is driven to slide leftwards to drive the light sliding rod pull rope 49 to move leftwards, the light sliding rod pull rope 49 drives the sliding plate pull rope 25 to move downwards, the sliding plate 12 is driven to slide downwards through the sliding plate spring 17, the sliding plate 12 drives the upper side contact switch 13 to move downwards, when the temperature in the solar panel cavity 27 is raised to a certain temperature, the upper side contact switch 13 is driven to move downwards through the light sliding plate 54 to be in contact with the lower side contact switch 13, the circulating motor 15 is started, and the left side power shaft, thereby driving the left power bevel gear 19 to rotate, the left power bevel gear 19 driving the fan bevel gear 21 to rotate through gear engagement, the fan bevel gear 21 driving the right power bevel gear 19 to rotate through gear engagement, the right power bevel gear 19 driving the right power shaft 18 to rotate, the fan bevel gear 21 driving the fan 22 to rotate, thereby driving the lower end gas in the solar panel cavity 27 to filter into the fan cavity 24 through the fan cavity filter plate 23, the lower end gas in the solar panel cavity 27 driving the upper end high temperature gas in the solar panel cavity 27 to enter into the gas circulation cavity 71 through the upper side through hole 70 and then to enter into the lower end in the solar panel cavity 27 through the lower side through hole 70, heating the low temperature clear water in the clear water cavity 61 through heat conduction, at the same time, the right power shaft 18 driving the driven bevel gear 67 to rotate and then driving the rotating rod bevel, the rotating rod bevel gear 64 rotates the rotating rod 63 to drive the connecting rod 66 to rotate through the hinge connection, the connecting rod 66 rotates to drive the piston plate 58 to slide left and right in the piston plate cavity 59, the piston plate 58 drives the sliding shaft 62 to slide left and right in the sliding sleeve rod 65 to drive the piston plate 58 to slide left and right, the piston plate 58 slides left and right to drive the low-temperature gas in the piston plate cavity 59 to enter the piston cavity one-way valve 57 through the piston plate cavity filter plate 60, enter the air inlet one-way valve 31 through the piston cavity one-way valve 57, and then enter the upper end in the solar panel cavity 27 through the air inlet one-way valve 31, at the moment, the high-temperature gas enters the lower end in the solar panel cavity 27 through the gas circulation cavity 71, the external low-temperature gas enters the upper end in the solar panel cavity 27 through the air inlet one-way valve 31 to form gas circulation, the high-temperature gas at the lower end in the solar, the indoor heat system is connected through a connecting pipe 72 to provide heat;

when high-temperature gas passes through the connecting pipe 72, the sliding motor 42 is started to drive the sliding motor shaft 36 to rotate, the sliding motor shaft 36 drives the left and right drive bevel gears 38 and the left and right drive bevel gears 34 to rotate simultaneously, the drive bevel gear 38 drives the driven bevel gear 37 to rotate through gear engagement, the driven bevel gear 37 drives the inner friction wheel 40 to rotate through the inner friction wheel shaft 75, the inner friction wheel 40 rubs with the meshing rack 74 through the outer circular surface to drive the meshing rack 74 to move downwards, the meshing rack 74 drives the inner heat-insulating material 73 to move downwards to perform heat-insulating work on the connecting pipe 72, meanwhile, the drive bevel gear 34 drives the meshing bevel gear 33 to rotate through gear engagement, the meshing bevel gear 33 drives the lower side belt wheel 48 and the lower friction wheel 77 to rotate simultaneously through the lower friction wheel shaft 78, and the lower friction wheel 77 drives the outer heat-insulating material 32 to move upwards, downside band pulley 48 passes through hold-in range 46 and drives upside band pulley 48 and rotates, and then drives friction wheel axle 44 and rotate, goes up friction wheel axle 44 and drives friction wheel 43 and rotate and then drive outer insulation material 32 upward movement to solar panel chamber 27 carries out heat preservation work in 11 upper ends of solar panel case, prevents that the heat loss of upper end high temperature gas is too fast in the solar panel chamber 27, has guaranteed thermal utilization ratio.

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 reuse auxiliary device based on solar radiation, includes the solar panel case, its characterized in that: the solar panel incasement is equipped with the ascending solar panel chamber of opening, solar panel case up end fixedly connected with clear glass, clear glass can with the solar panel intracavity is sealed, the fixed solar panel that is equipped with of solar panel intracavity lower extreme inner wall, the array is equipped with the clean water pipe in the solar panel, the array is equipped with annular gas circulation chamber in the clean water pipe, two wall symmetries and intercommunication have the through-hole about the gas circulation intracavity, the solar panel upside just is located solar panel intracavity upper end air can pass through the upside the through-hole gets into the gas circulation intracavity, and then through the downside the through-hole gets into solar panel intracavity lower extreme, two wall symmetries and fixed the check valve that admits air are equipped with about solar panel intracavity upper end, the check valve that admits air can bring clean air into solar panel intracavity upper end, solar panel incasement lower extreme be equipped with the opening upwards and a cavity, a rotatable fan is arranged in the fan cavity, a temperature measuring box is fixedly arranged at the left side of the lower side of the air inlet one-way valve and is positioned at the left end in the solar panel box, the right end of the temperature measuring box extends rightwards to the transparent glass, a temperature sensing plate is fixedly arranged in the transparent glass, a helium cavity with a right opening is arranged in the temperature measuring box, helium is arranged in the helium cavity, when the temperature of the upper end in the transparent glass rises through solar radiation, the temperature sensing plate enters the helium cavity through transmitting the temperature of the temperature sensing plate, the helium cavity reacts with expansion and contraction of the helium through the heat of the helium, so that the fan is started, when the fan rotates, high-temperature gas at the upper end in the transparent glass can be driven to enter the lower end in the transparent glass and further enter the fan cavity, a connecting pipe communicated with the back wall in the fan cavity is fixedly, the connecting pipe is connected with an indoor heat circulation system, an inner heat insulation material is arranged on the outer circular surface of the connecting pipe in a sliding mode, and when high-temperature gas flows in the connecting pipe, the inner heat insulation material slides downwards to be in contact with the outer circular surface of the lower end of the connecting pipe, so that the heat insulation effect is achieved.

2. A solar radiation-based recycling aid as set forth in claim 1, wherein: the portable gas-liquid separation helium device is characterized in that a light sliding plate capable of sliding left and right is arranged in the helium cavity, the left wall in the helium cavity is communicated with a light sliding rod cavity, a light sliding rod is fixedly arranged at the center of the left end face of the light sliding plate, the left end of the light sliding rod extends leftwards to the light sliding rod cavity, a light sliding rod pull rope is fixedly connected in the light sliding rod cavity, and a light sliding rod spring is fixedly arranged between the left wall in the light sliding rod cavity and the left end face of the light sliding rod.

3. A solar radiation-based recycling aid as claimed in claim 2, wherein: the solar panel incasement lower extreme just is located fan chamber downside is equipped with the power chamber, power chamber left side just is located the solar panel incasement is fixed and is equipped with the circulation motor case, the circulation motor incasement is fixed and is equipped with the circulation motor, circulation motor case up end is equipped with the circulation motor chamber, it is equipped with the sliding plate to slide in the circulation motor chamber, terminal surface under the sliding plate with symmetry just fixes being equipped with contact switch between the circulation motor case up end, the sliding plate up end with it is fixed with the sliding plate spring to be equipped with between the circulation motor intracavity upper wall, the sliding plate up end center fix be equipped with the sliding plate stay cord that the light slide bar stay cord is connected.

4. A solar radiation-based recycling aid as set forth in claim 1, wherein: the power cavity is internally provided with a power shaft, the left wall and the right wall of the power cavity are symmetrical and can rotate, the power shaft is arranged on the left side and the right side of the power cavity, the power bevel gear is fixedly arranged in the power cavity respectively, the left end of the power shaft extends leftwards into the circulating motor box and is in power connection with the right end face of the circulating motor, the lower end of the fan extends downwards to the power cavity, a fan bevel gear meshed with the power bevel gear is fixedly arranged in the power cavity, and a fan cavity filter plate is fixedly arranged on the inner wall of the upper end.

5. A solar radiation-based recycling aid as recited in claim 4, wherein: a piston plate cavity is arranged at the lower end in the solar panel box and is positioned on the right side of the fan cavity, a driven cavity is arranged at the lower end in the solar panel box and is positioned on the lower side of the piston plate cavity, a piston plate cavity filter plate is fixedly arranged on the inner wall of the left end in the piston plate cavity, a piston plate capable of sliding left and right is arranged in the piston plate cavity, a sliding sleeve rod is fixedly arranged at the upper end of the right wall in the piston plate cavity, a sliding shaft fixedly connected with the upper side of the right end face of the piston plate is arranged in the sliding sleeve rod in a sliding manner, a driven bevel gear is fixedly arranged in the driven cavity by rightwards extending the right end of the power shaft on the right side, a rotating rod bevel gear meshed with the driven bevel gear is rotatably arranged at the upper end in the driven cavity, a rotating rod is fixedly arranged at the lower end in the piston plate cavity by, the left end of the connecting rod is hinged with the right end face of the piston plate, and a piston cavity one-way valve connected with the air inlet one-way valve is fixedly arranged in the center of the left wall in the cavity of the piston plate.

6. A solar radiation-based recycling aid as set forth in claim 1, wherein: the solar panel box is characterized in that a meshing rack is fixedly connected to the outer circular surface of the inner heat-insulating material, inner friction wheel cavities with openings facing one side of the connecting pipe are symmetrically arranged at the lower end of the outer circular surface of the meshing rack, inner friction wheel shafts are arranged on the inner rear wall of each inner friction wheel cavity in a rotating mode, inner friction wheels are fixedly arranged on the outer circular surface of each inner friction wheel shaft and located in the corresponding inner friction wheel cavity, the outer circular surface of each inner friction wheel is connected with the outer circular surface of the meshing rack in a friction mode, lower friction wheel cavities with openings facing one side away from the corresponding fan cavity are symmetrically arranged on the left end and the right end of the inner friction wheel cavity and located in the solar panel box, lower friction wheel shafts are arranged on the centers of the inner rear wall of the lower friction wheel cavities in a rotating.

7. A solar radiation-based recycling aid as recited in claim 6, wherein: the solar panel box comprises a solar panel box body, a sliding motor, a driving shaft, a driving bevel gear, a driving shaft.

8. A solar radiation-based recycling aid as recited in claim 7, wherein: the rear side of the lower friction wheel cavity is provided with an engaging cavity, one end of the sliding motor shaft at the left side and the right side, which is far away from the sliding motor, extends to the left side and the right side respectively, the engaging cavity is fixedly provided with a transmission bevel gear, the rear end of the lower friction wheel shaft at the left side and the right side extends backwards to the left side and the right side, the engaging bevel gear engaged with the transmission bevel gear is fixedly arranged in the engaging cavity at the left side and the right side, belt wheel cavities are respectively arranged in the inner walls of the lower friction wheel cavity at the left side and the right side, the upper end and the lower end of the belt wheel cavity are symmetrically provided with belt wheels capable of rotating, a synchronous belt is wound between the belt wheels at the upper side and the lower side, the axle center of the belt wheel at the lower side is fixedly connected with an upper friction wheel shaft, the upper friction wheel cavity with, the front end of the upper friction wheel shaft extends forwards to the upper friction wheel cavity, and an upper friction wheel is fixedly arranged in the upper friction wheel cavity.

9. A solar radiation-based recycling aid as recited in claim 8, wherein: the solar panel box is characterized in that outer heat insulation materials are symmetrically arranged at the left end and the right end of the solar panel box in a sliding mode, and the outer heat insulation materials are in friction connection with the outer circular surface of the lower friction wheel and the outer circular surface of the upper friction wheel.