CN117605393A

CN117605393A - Sunshade system for energy-saving doors and windows

Info

Publication number: CN117605393A
Application number: CN202311553977.1A
Authority: CN
Inventors: 张文忠; 刘大伟; 孙瑞
Original assignee: Jinpeng Energy Saving Technology Co ltd
Current assignee: Jinpeng Energy Saving Technology Co ltd
Priority date: 2023-11-21
Filing date: 2023-11-21
Publication date: 2024-02-27
Anticipated expiration: 2043-11-21
Also published as: CN117605393B

Abstract

The utility model discloses a sunshade system for an energy-saving door and window, which relates to the technical field of green energy-saving doors and windows and comprises a hollow glass window body, wherein a shutter sunshade curtain and a solar panel are arranged in an inner cavity of the hollow glass window body, and the solar panel supplies energy for opening and closing the shutter sunshade curtain.

Description

Sunshade system for energy-saving doors and windows

Technical Field

The utility model relates to the technical field of green energy-saving doors and windows, in particular to a sunshade system for an energy-saving door and window.

Background

In order to solve the problem that the energy-saving and heat-insulating effects of the single-layer door and window glass of the building are too poor, a hollow door and window is more and more popular, which is formed by separating two or more glass plates by using frames and filling dry air or inert gas in the middle to obtain excellent heat insulation and sound insulation, and the arrangement scheme of arranging a shutter in the space between the two glass plates is common practice of the existing hollow door and window;

the prior Chinese patent publication number is as follows: CN215565430U, the name of this patent is "an environmental protection and energy saving type hollow glass embeds sunshade curtain", this patent includes "toughened glass", toughened glass is provided with two altogether, and is provided with the structure adhesive tape between two toughened glass, the structure adhesive tape is provided with two altogether, and two structure adhesive tapes along toughened glass's axis upper and lower symmetric distribution, the block is installed to the top of structure adhesive tape, and the movable carrier plate is installed to the lateral wall of block, the fixed slot has been seted up to the inner wall of movable carrier plate, the movable carrier plate is installed to the lateral wall of block of this utility model, and the stopper has all been installed to the both sides of movable carrier plate, during the use, the draw-in groove and the fixture block looks block of movable block inner wall block, and fixed slot and fixed arch block mutually block, prevent that the movable block from dropping, the stopper of movable carrier plate link prevents that the movable block from taking out from the flank, has avoided the movable block can be taken out easily and the condition that the movable block that leads to easily loses.

In the prior art, the common electric driving mode of the blind curtain arranged in the cavity of the hollow window body is that the corresponding driving motor is in transmission connection with the driving shaft of the blind curtain, and the solar energy system is utilized to supply power for the driving motor, but the solar energy lighting panel is not enough to be subjected to environmental interference, such as dust coverage, rain and snow weathering erosion and the like, in the long-term use process, so that the power supply effect is influenced and the normal use of the sunshade system is not facilitated.

Disclosure of Invention

The utility model aims to provide an energy-saving sunshade system for doors and windows, which aims to solve the defects in the prior art.

In order to achieve the above object, the present utility model provides the following technical solutions:

the sunshade system for the energy-saving door and window comprises a hollow glass window body, wherein a shutter sunshade curtain and a solar panel are arranged in an inner cavity of the hollow glass window body, and the solar panel supplies energy for opening and closing the shutter sunshade curtain.

Preferably, a magnetic transmission mechanism is arranged on the hollow glass window body, and the magnetic transmission mechanism can receive electric energy of the solar panel to drive the shutter sunshade to open and close.

Preferably, the magnetic transmission mechanism comprises an internal magnetic column in transmission connection with the shutter sunshade, an external magnetic column capable of magnetically driving the internal magnetic column to move is arranged outside the hollow glass window body, and the external magnetic column is rotatably installed on the hollow glass window body through a connecting unit.

Preferably, the axial lead of the built-in magnetic column is perpendicular to the different surfaces of the axial lead of the external magnetic column.

Preferably, the axis of the internal magnetic column is parallel to the axis of the external magnetic column.

Preferably, the end face of the shaft end of the internal magnetic column is perpendicular to the facing angle of the shaft end of the external magnetic column.

Preferably, the axial lead of the built-in magnetic column and the axial lead of the external magnetic column are on the same straight line.

Preferably, the connecting unit comprises a box body fixed with the hollow glass window body, a supporting plate is inserted in the box body in an adapting way, and supporting plates fixed with the supporting plate are rotatably arranged at two ends of a post rod of the external magnetic post.

Preferably, a driving motor is fixed on the supporting plate, a power output end of the driving motor is fixed with a pole of the external magnetic column, and an electric power input end of the driving motor is electrically connected with the solar panel through a power supply unit.

Preferably, the power supply unit is a wireless power transmission assembly, the power supply unit comprises a power transmission module and a power receiving module, the power transmission module is electrically connected with the solar panel through a conductive wire, the power receiving module is electrically connected with the driving motor, and the power of the solar panel can be wirelessly transmitted to the driving motor.

In the technical scheme, the solar panel is arranged in the inner cavity of the hollow glass window body, so that the solar panel is prevented from being exposed to the air, the interference of the solar panel caused by the external influence is reduced, the normal power supply effect is guaranteed, and the normal use of the sunshade system is facilitated.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic view of the indoor side of a hollow glass window body of a sunshade system for energy-saving doors and windows according to the present utility model;

FIG. 2 is a schematic view of the exterior of a hollow glass window of the sunshade system for energy-saving doors and windows according to the present utility model;

FIG. 3 is a schematic cross-sectional view of a hollow glass window of a sunshade system for energy-saving doors and windows according to the present utility model;

FIG. 4 is a schematic cross-sectional view of a top box of a sunshade system for energy-saving doors and windows according to the present utility model;

FIG. 5 is a schematic cross-sectional view of a case of a sunshade system for energy-saving doors and windows according to the present utility model;

FIG. 6 is a schematic top cross-sectional top view of a top box of a sunshade system for energy saving doors and windows according to the present utility model;

FIG. 7 is a schematic view of a driving assembly of a sunshade system for energy-saving doors and windows according to the present utility model;

fig. 8 is a schematic diagram of a bridge engagement assembly of a sunshade system for energy-saving doors and windows according to the present utility model.

Reference numerals illustrate:

1. a hollow glass window; 2. shutter sunshade curtain; 3. a solar panel; 4. a magnetic transmission mechanism; 4.1, a built-in magnetic column; 4.2, externally arranging a magnetic column; 4.3, a connection unit; 4.31, a box body; 4.32, supporting plate; 4.33, a supporting plate; 5. a driving motor; 6. a power supply unit; 6.1, a power transmission module; 6.2, a power receiving module; 6.3, conducting wires; 7. a gearbox; 8. a baffle; 9. notch; 10. a top tank shell; 11. a drive assembly; 11.1, a drive shaft; 11.2, a wire clamping device; 11.3, a reel; 11.4, winding roller; 11.5, a worm; 11.6, worm gear; 12. a bridge engagement assembly; 12.1, connecting the strip plates; 12.2, a first gear; 12.3, a second gear; 12.4, a rod; 12.5, a third gear; 13. track through hole.

Detailed Description

In order to make the technical scheme of the present utility model better understood by those skilled in the art, the present utility model will be further described in detail with reference to the accompanying drawings.

Referring to fig. 1-8, the sunshade system for energy-saving doors and windows provided by the embodiment of the utility model comprises a hollow glass window body 1, wherein a shutter sunshade curtain 2 and a solar panel 3 are arranged in the inner cavity of the hollow glass window body 1, and the solar panel 3 supplies energy for opening and closing the shutter sunshade curtain 2;

specifically, the hollow glass window 1 is a glass deep-processing product in which two or more glass sheets are separated by an aluminum spacer frame and are filled with molecular sieves, the glass deep-processing product is sealed by sealing rubber strips, a dry gas space is formed between the glass sheets, the shutter sunshade curtain 2 is a sunshade curtain which controls the light inlet amount by utilizing a multi-layer blade design, the sunshade curtain can be fully folded upwards like a roller shutter, and the solar panel 3 is a photoelectric semiconductor sheet which directly generates electricity by sunlight, and is also called a solar chip or a photocell. The device can output voltage and generate current under the condition of a loop instantly as long as the device is subjected to illuminance meeting a certain illuminance condition;

through setting up solar panel in the inner chamber of cavity glass window form to avoided solar panel to expose in the air, reduced solar panel and receive external influence interference, solar panel can be normal the accepted illumination, is favorable to guaranteeing that the power supply effect is normal, is favorable to sun-shading system's normal use.

In another embodiment provided by the utility model, a magnetic transmission mechanism 4 is arranged on the hollow glass window body 1, the magnetic transmission mechanism 4 can receive electric energy of the solar panel 3 to drive the shutter sunshade curtain 2 to open and close, the magnetic transmission mechanism 4 comprises an internal magnetic column 4.1 in transmission connection with the shutter sunshade curtain 2, an external magnetic column 4.2 capable of magnetically driving the internal magnetic column 4.1 to move is arranged outside the hollow glass window body 1, and the external magnetic column 4.2 is rotatably arranged on the hollow glass window body 1 through a connecting unit 4.3;

it should be specifically noted that, the axis of the internal magnetic column 4.1 is parallel to the axis of the external magnetic column 4.2, where the ends of the internal magnetic column 4.1 and the external magnetic column 4.2 are fixedly penetrated by a post rod, the post rod forms an axial rotating shaft rod, in actual use, when the external magnetic column 4.2 axially rotates, the internal magnetic column 4.1 rotates correspondingly, so that kinetic energy outside the hollow glass window body 1 is transferred into the hollow glass window body 1, at this time, the shutter sunshade curtain 2 in transmission connection with the internal magnetic column 4.1 is subjected to a driving force to perform a corresponding opening and closing action, so as to achieve the effect of glass isolation transmission, in other words, the transmission power of the two magnetic columns in parallel is similar to that of a mechanical common gear, but the magnetic columns have no engagement of a mechanical gear, and are non-contact magnetic transmission.

In still another embodiment provided by the utility model, the axial end face of the built-in magnetic column 4.1 is perpendicular to the axial end face facing angle of the external magnetic column 4.2, which is a right-angle transmission mode, in other words, the axial lines between the two magnetic columns are in a perpendicular shape, the two axes are in the same plane, the structure of the built-in magnetic column is similar to two bevel gears meshed with each other mechanically, and when the external magnetic column 4.2 axially rotates, the built-in magnetic column 4.1 correspondingly axially rotates.

In still another embodiment provided by the utility model, the axial lead of the built-in magnetic column 4.1 and the axial lead of the external magnetic column 4.2 are on the same straight line, the built-in magnetic column 4.1 and the external magnetic column 4.2 are in the same plane and are in butt joint shape, the transmission structure is similar to a conventional coupling, but the built-in magnetic column 4.1 and the external magnetic column 4.2 are not contacted, and when the external magnetic column 4.2 axially rotates, the built-in magnetic column 4.1 correspondingly axially rotates.

In still another embodiment provided by the utility model, the axis of the built-in magnetic column 4.1 is perpendicular to the axis of the external magnetic column 4.2, which means that the axes of the two magnetic wheels are perpendicular, but the two axes are not on the same plane.

In still another embodiment provided by the utility model, the connecting unit 4.3 comprises a box body 4.31 fixed with the hollow glass window body 1, the box body 4.31 is made of non-magnetic materials, such as aluminum alloy materials, the whole box body 4.31 is of a long column structure, a length direction line of the box body 4.31 is parallel to the axis line of the external magnetic column 4.2, one end of the box body 4.31 is an open end, a supporting plate 4.32 is adaptively inserted in the box body 4.31, the supporting plate 4.32 is positioned at the bottom of the box body 4.31, supporting plates 4.33 fixed with the supporting plate 4.32 are rotatably arranged at two ends of a post rod of the external magnetic column 4.2, so that the external magnetic column 4.2 can axially rotate in the box body 4.31, a driving motor 5 is further fixed on the supporting plate 4.32, a power output end of the driving motor 5 is fixed with the axis line of the external magnetic column 4.2, a power input end of the driving motor 5 is electrically connected with the solar panel 3 through the power supply unit 6, and the opening of the supporting plate 4.32 can be blocked by the supporting plate 8, which can block the opening of the box body 4.32;

in the actual installation process, the supporting plate 4.32 carrying the external magnetic column 4.2 and the driving motor 5 is inserted into the box body 4.31 from the opening end of the box body 4.31, when the baffle plate 8 is used for plugging the opening end of the box body 4.31, the external magnetic column 4.2 reaches the position corresponding to the internal magnetic column 4.1, the internal magnetic column 4.1 can receive the power driving of the external magnetic column 4.2, and when the driving motor 5 is connected with a power supply to operate, the driving force is provided for the rotation of the external magnetic column 4.2, and when the maintenance is needed, the supporting plate 4.32 is pulled out from the box body 4.31, so that the maintenance and disassembly work is convenient to develop.

In still another embodiment provided by the utility model, the bottom of the box body 4.31 is provided with a notch 9 communicated with the opening end of the box body 4.31, and when the supporting plate 4.32 is positioned in the box body 4.31, the bottom surface of the supporting plate 4.32 forms the bottom surface of the box body 4.31; the power supply unit 6 is a wireless power transmission component, the power supply unit 6 includes a power transmission module 6.1 and a power receiving module 6.2, the specific power transmission module 6.1 includes a power transmission coil for transmitting ac power, the power receiving module 6.2 includes a power receiving coil and a compensation circuit, the power receiving module 6.2 is fixed with the supporting plate 4.32, the power receiving module 6.2 is electrically connected with the driving motor 5, preferably, the power transmission module 6.1 is electrically connected with a power output end of the solar panel 3, the power transmission module 6.1 is located inside the hollow glass window 1, the power receiving module 6.2 is located outside the hollow glass window 1, specifically, the power of the solar panel 3 can be wirelessly transmitted to the driving motor 5 through the power transmission wire 6.3, the power supply unit 6 is the same as the existing wireless charging technology principle, that is, by using a wireless charging device to convert electric energy into magnetic energy, and then using a corresponding device to convert the magnetic energy into electric energy at a receiving end, thereby completing wireless transmission of electric energy, and charging for mobile devices, which will not be described.

In still another embodiment of the present utility model, the power transmission module 6.1 and the power receiving module 6.2 are both outside the hollow glass window body 1, the power transmission module 6.1 and the solar panel 3 are electrically connected through the conductive wire 6.3, and the conductive wire 6.3 is fixed through the window frame of the hollow glass window body 1.

In still another embodiment of the present utility model, the transmission shaft of the blind 2 is in transmission connection with the post of the built-in magnetic column 4.1 through the gearbox 7, and it should be specifically noted that the gearbox 7 is a specific existing mechanism in the field of blinds, and is an important component for controlling the lifting speed and stability of the blinds, and is usually composed of a plurality of gears, and the lifting speed and stability of the blinds are controlled by adjusting the transmission ratio of the gears, and the gearbox 7 of the common blinds generally includes an input shaft, an output shaft, a transmission ratio adjusting mechanism, a limiting mechanism, and other parts, where the input shaft is connected with the driver, and if the input shaft is fixed with the output shaft of the driving motor 5 to receive power, the specific principle is not repeated in the prior art.

In still another embodiment provided by the utility model, the shutter blind 2 comprises a top groove shell 10, the top groove shell 10 is positioned at the inner top of the cavity of the hollow glass window body 1, the shutter blades of the shutter blind 2 are positioned below the top groove shell 10, a driving component 11 for controlling the shutter blades of the shutter blind 2 to open and close in a lifting manner is positioned in the top groove shell 10, the solar panel 3 is arranged outside the top groove shell 10, the solar panel 3 can normally receive sunlight, the power transmission module 6.1 is arranged at one side, close to the box body 4.31, of the top groove shell 10, and therefore, electric energy generated by the solar panel 3 positioned in the cavity of the hollow glass window body 1 can be transmitted to the external power receiving module 6.2 through glass.

In still another embodiment provided by the utility model, the driving assembly 11 comprises a driving shaft 11.1 rotatably installed in the top groove shell 10, a wire clamping device 11.2 for controlling the turning of blades is installed on the driving shaft 11.1, the driving assembly 11 further comprises a wire winder 11.3 installed at the inner bottom of the top groove shell 10, a wire winding rope for controlling the lifting of the shutter curtain is wound on the wire winder 11.3, a wire winding roller 11.4 of the wire winder 11.3 is rotatably installed with the top groove shell 10, the wire winder 11.3 is in transmission connection with the built-in magnetic column 4.1 through a gearbox 7, the axial lead of the wire winding roller 11.4 is parallel to the horizontal plane, one end of the wire winding rope for controlling the lifting of the shutter curtain is fixed on the roller body of the wire winding roller 11.4, the roller body of the wire winding roller 11.4 is in a tooth column structure, a worm 11.5 which is rotatably arranged with the top groove shell 10 is arranged between the driving shaft 11.1 and the winding roller 11.4, the axial lead of the worm 11.5 is perpendicular to the axial lead different surface of the driving shaft 11.1, the axial lead of the worm 11.5 is parallel to the axial lead of the winding roller 11.4, the worm 11.5 is positioned above the winding roller 11.4, a worm wheel 11.6 which is in fit engagement with the worm 11.5 is fixed on the driving shaft 11.1, a bridge engagement assembly 12 is arranged between the worm 11.5 and the winding roller 11.4, the bridge engagement assembly 12 has an engagement position and a separation position, when the bridge engagement assembly 12 is positioned at the engagement position, the driving shaft 11.1 can be driven by the power of the winding roller 11.4 at the moment, so that the blades of the blind curtain can be overturned, and when the bridge engagement assembly 12 is positioned at the separation position, the driving shaft 11.1 is not influenced by the power of the winding roller 11.4;

the bridge engagement assembly 12 comprises a connecting slat 12.1, a first gear 12.2 is rotatably arranged on the surface of the slat 12.1 near the end, a second gear 12.3 meshed with the first gear 12.2 is rotatably arranged on the surface of the same side of the slat 12.1 near the end of the other end, the plane of the surface of the slat 12.1 is perpendicular to the axis of the winding roller 11.4, the slat 12.1 is rotatably arranged in the top trough shell 10 through a bar 12.4, and the bridge engagement assembly 12 further comprises a third gear 12.5 fixed with a worm 11.5;

specifically, the mass of the second gear 12.3 is greater than that of the first gear 12.2, on the same straight line, the distance value between the rod 12.4 and the first gear 12.2 is smaller than that between the rod 12.4 and the second gear 12.3, in a natural state, the connecting slat 12.1 always has a motion trend of keeping a vertical state, the state is that the first gear 12.2 is located above the second gear 12.3, in other words, the first gear 12.2 always has a motion trend towards the position where the third gear 12.5 is located, the second gear 12.3 always has a motion trend towards the position where the winding roller 11.4 is located, preferably, the rod 12.4 and the connecting slat 12.1 are connected through a torsion spring, so that the connecting slat 12.1 always has a motion trend of keeping a vertical state, the second gear 12.3 and a columnar structure on a winding roller 11.4 are meshed, so that the bridge engagement assembly 12 has a stable transmission effect when the second gear 12.2 is located at the meshing position, in addition, the second gear 12.3 can be meshed with the columnar structure 12.4 on the winding roller 11.4, and the first gear 12.4 can be meshed with the columnar structure 12.2 when the second gear 12.4 is meshed with the columnar structure;

in the actual use process, the winding roller 11.4 rotates positively, when the shutter curtain is fully unfolded, the winding rope on the winding roller 11.4 is fully released, the winding rope does not isolate the second gear 12.3 from the toothed columnar structure on the roller body of the winding roller 11.4, the tooth groove structure of the winding roller 11.4 is exposed, the roller body of the winding roller 11.4 is toothed columnar, the second gear 12.3 can be meshed with the winding roller 11.4, the first gear 12.2 is also meshed with the third gear 12.5 in a contact manner, so that the bridge meshing assembly 12 is in a meshing position, and the driving shaft 11.1 can be driven by the power of the winding roller 11.4, so that the blades of the shutter curtain are overturned; when the winding roller 11.4 reversely rotates, the winding rope is wound, the tooth groove structure on the winding roller 11.4 also enables the winding rope to have good anti-slip effect when in winding, the winding rope wound on the winding roller 11.4 enables the tooth column structure of the winding roller 11.4 to be isolated from the second gear 12.3, the bridge engagement assembly 12 is in a separation position, on the other hand, the winding rope enables the diameter of the winding roller 11.4 to be increased, and accordingly the connecting slat 12.1 also deflects around the stick 12.4;

in the whole process, on the premise of not adding an additional power unit, the lifting of the shutter curtain and the control of blade overturning are realized through the driving assembly 11, the space is reasonably utilized, the space occupation surface of the window is reduced, and the light transmission area of the window in unit area is increased.

In still another embodiment provided by the utility model, the length of the wheel body of the first gear 12.2 is provided with the track through hole 13, the track through hole 13 is in an arc-shaped structure, the circle center of the track through hole 13 coincides with the circle center of the wheel body of the first gear 12.2, the rod 12.4 movably penetrates through the track through hole 13, the radian of the track through hole 13 is 220-310 degrees, and the preferred radian of the track through hole 13 is 260 degrees; in the actual use process, when the first gear 12.2 rotates, the driving shaft 11.1 rotates at the moment to enable the louver blades of the louver to overturn, and when the louver blades of the louver reach the maximum overturning position, the rod 12.4 contacts with the end part of the track through hole 13, so that further rotation of the driving shaft 11.1 is limited, and the effect of timely locking is achieved.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims

1. The utility model provides an energy-conserving sunshade system for door and window, includes cavity glass window (1), its characterized in that is equipped with tripe sunshade screen (2) and solar panel (3) in cavity glass window (1), solar panel (3) are the opening and close energy supply of tripe sunshade screen (2).

2. The sunshade system for the energy-saving doors and windows according to claim 1, wherein a magnetic transmission mechanism (4) is arranged on the hollow glass window body (1), and the magnetic transmission mechanism (4) can receive electric energy of the solar panel (3) to drive the opening and closing of the shutter sunshade curtain (2).

3. The sunshade system for the energy-saving doors and windows according to claim 2, wherein the magnetic transmission mechanism (4) comprises an internal magnetic column (4.1) in transmission connection with the shutter sunshade curtain (2), an external magnetic column (4.2) capable of magnetically driving the internal magnetic column (4.1) to move is arranged outside the hollow glass window body (1), and the external magnetic column (4.2) is rotatably installed on the hollow glass window body (1) through a connecting unit (4.3).

4. A sunshade system for energy saving doors and windows according to claim 3, characterized in that the axis of the inner magnetic column (4.1) is perpendicular to the different plane of the axis of the outer magnetic column (4.2).

5. A sunshade system for energy saving doors and windows according to claim 3, characterized in that the axis of the inner magnetic column (4.1) is parallel to the axis of the outer magnetic column (4.2).

6. A sunshade system for energy saving doors and windows according to claim 3, characterized in that the end face of the shaft end of the inner magnetic column (4.1) is perpendicular to the facing angle of the shaft end of the outer magnetic column (4.2).

7. A sunshade system for energy saving doors and windows according to claim 3, characterized in that the axis of the inner magnetic column (4.1) is on the same straight line with the axis of the outer magnetic column (4.2).

8. A sunshade system for energy-saving doors and windows according to claim 3, characterized in that the connecting unit (4.3) comprises a box body (4.31) fixed with the hollow glass window body (1), a supporting plate (4.32) is inserted in the box body (4.31) in an adapting way, and supporting plates (4.33) fixed with the supporting plate (4.32) are rotatably arranged at two ends of a pole of the external magnetic column (4.2).

9. The sunshade system for the energy-saving door and window according to claim 8, wherein a driving motor (5) is fixed on the supporting plate (4.32), a power output end of the driving motor (5) is fixed with a pole of the external magnetic column (4.2), and an electric power input end of the driving motor (5) is electrically connected with the solar panel (3) through the power supply unit (6).

10. The sunshade system for the energy-saving door and window according to claim 9, wherein the power supply unit (6) is a wireless power transmission assembly, the power supply unit (6) comprises a power transmission module (6.1) and a power receiving module (6.2), the power transmission module (6.1) is electrically connected with the solar panel (3) through a conductive wire (6.3), the power receiving module (6.2) is electrically connected with the driving motor (5), and the power of the solar panel (3) can be transmitted to the driving motor (5) in a wireless mode.