CN116181578A - Coaxial reverse wind cup structure wide-area composite energy collector based on wind energy - Google Patents

Abstract

The invention discloses a coaxial reverse-rotation wind cup structure wide-area composite energy collector based on wind energy, which comprises a forward-rotation assembly, a first driving piece, a moving coil cantilever piece and an electric slip ring piece, wherein the moving coil cantilever piece is connected with the first driving piece; and the magnet fixing assembly comprises a first magnet fixing piece positioned at one side of the moving coil cantilever piece. According to the solar panel, the positive rotation wind cup is driven to rotate by wind power, so that the first coil generates current to play a role in generating electricity, the reverse rotation wind cup rotates to enable the first coil to generate current to be stronger and generate electricity at a higher speed when wind power is high, meanwhile, the second coil generates current to play a role in generating electricity, the solar panel plays a role in generating electricity, and when the wind power is high, the solar panel can be driven to change an inclined state by the reverse rotation wind cup to be horizontally placed on the outer support frame, so that the solar panel is prevented from being blown away by the high wind.

Description

Coaxial reverse wind cup structure wide-area composite energy collector based on wind energy

Technical Field

The invention relates to the technical field of energy collection, in particular to a coaxial reverse wind cup structure wide-area composite energy collector based on wind energy.

Background

With the development of economy, the demand of people for traditional energy is increasing, and the problems of global climate warming, environmental pollution and the like are also aggravated by the excessive use of traditional energy. Meanwhile, with the progress of semiconductor technology and the development of micro-electromechanical systems, the power consumption of various electronic devices and intelligent equipment is gradually reduced to mW or even mu W level, so that the electronic devices can be powered by acquiring weak energy sources in the environment. In nature, a large amount of clean energy sources with large capacity, ubiquitous and environment-friendly performance, such as solar energy, wind energy, water energy, heat energy, vibration energy, sound energy and the like, exist. The wind energy is used as the most widely distributed collectable energy, and the most main collection modes at present comprise various forms such as friction voltage, piezoelectric effect, electromagnetic induction and the like.

When adopting single form energy collection and conversion scheme, energy collection inefficiency, and there is the narrow problem of wind speed collection scope when utilizing friction voltage and piezoelectricity to carry out wind energy collection, can't realize long-time continuous power supply. And when the electromagnetic is singly used, the response is poor at low wind speed, and the starting is difficult.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the invention, which should not be used to limit the scope of the invention.

The invention is provided in view of the problems of narrow wind speed collection range, poor response at low wind speed and lower output of the existing wind energy-based collector.

Therefore, the invention aims to provide a coaxial reverse wind cup structure wide-area composite energy collector based on wind energy.

In order to solve the technical problems, the invention provides the following technical scheme: the coaxial reverse-rotation wind cup structure wide-domain composite energy collector based on wind energy comprises a forward rotation assembly, a first driving piece, a moving coil cantilever piece connected with the first driving piece, and an electric slip ring piece positioned in the middle of the first driving piece; the magnet fixing assembly comprises a first magnet fixing piece positioned at one side of the moving coil cantilever piece, a fixed connecting piece connected with the first magnet fixing piece and a second magnet fixing piece connected with the fixed connecting piece; and the reversing assembly comprises a second driving piece and a support plate piece which is positioned on one side of the second magnet fixing piece and connected with the second driving piece.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the first driving piece comprises a forward rotating wind cup, a forward rotating transmission shaft connected with the forward rotating wind cup, and a connecting clamping head is arranged on one side of the forward rotating transmission shaft; the moving coil cantilever part comprises a moving coil cantilever, a group of first coils are arranged on the moving coil cantilever, one side of the moving coil cantilever is provided with a connecting clamping groove, the other side of the moving coil cantilever is provided with a group of limiting clamping rings, and the first coils are clamped and embedded on the limiting clamping rings; the connecting clamping head is connected with the connecting clamping groove in a clamping manner.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the electric slip ring piece comprises an electric slip ring, and a line pin is arranged on the electric slip ring; the movable coil cantilever is provided with a circuit for communicating the first coil and the electric slip ring.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the first magnet mounting includes first magnet rand, be equipped with a plurality of first magnet on the first magnet rand, first magnet inlay card is on the first magnet rand, the air gap distance between first magnet and the first coil of a set of is 2mm.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the second driving piece comprises a reversing wind cup and a reversing transmission shaft positioned at one side of the reversing wind cup, and a connecting sleeve is arranged at one side of the reversing transmission shaft; the connecting sleeve is clamped and embedded on the inner side of the fixed connecting piece.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the support plate comprises a support side plate and a plurality of second coils positioned on one side of the support side plate, a first bearing is arranged in the middle of the support side plate, a plurality of second coil clamping grooves are formed in one side of the support side plate, and the second coils are clamped and embedded in the second coil clamping grooves; the inner ring of the first bearing is embedded on the outer side of the reversing transmission shaft, and the outer ring of the first bearing is embedded on the inner side of the supporting side plate; the second magnet fixing piece comprises a second magnet clamping ring, and a plurality of second magnets are arranged on the second magnet clamping ring; the air gap distance between the second magnet and the second coil is 2mm.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the solar power generation device comprises a magnet fixing assembly, a solar panel, a solar power generation assembly, a transmission piece and a power supply assembly.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: the outer support frame piece comprises an outer support frame, a group of rotary dampers is arranged on the outer side of the outer support frame, and a second bearing is arranged at the joint of the outer support frame and the forward rotation transmission shaft; the solar panel comprises a solar panel, a group of rotating brackets are arranged on the outer side of the solar panel, and the rotating brackets are clamped and embedded on the rotary damper; the transmission piece comprises a first transmission rod, a second transmission rod positioned at one side of the first transmission rod and a fixed stop lever positioned at one side of the second transmission rod.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: a first bevel gear is arranged on one side of the first transmission rod, a second bevel gear is arranged on the other side of the first transmission rod, a fixed bracket is arranged on the outer side of the first transmission rod, and the fixed bracket is fixed on the supporting side plate; and a third bevel gear meshed with the first bevel gear is further arranged on the reversing transmission shaft.

As a preferable scheme of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy, the invention comprises the following steps: a fourth bevel gear is arranged on the outer side of the second transmission rod, and the fourth bevel gear is meshed with the second bevel gear; the outer side of the transmission piece is also provided with a protruding block, one end of the transmission piece is provided with a hexagonal clamping block, and one side of the hexagonal clamping block is provided with a spring; the solar panel is also provided with a clamping groove capable of accommodating the hexagonal clamping block and the spring to move transversely, and the second transmission rod, the hexagonal clamping block and the spring are clamped and embedded on one side of the solar panel; the fixed stop lever is fixed on the outer support frame.

The invention has the beneficial effects that: according to the solar panel, the positive rotation wind cup is driven to rotate by wind power, so that the first coil generates current to play a role in generating electricity, the reverse rotation wind cup rotates to enable the first coil to generate current to be stronger and generate electricity at a higher speed when wind power is high, meanwhile, the second coil generates current to play a role in generating electricity, the solar panel plays a role in generating electricity, and when the wind power is high, the solar panel can be driven to change an inclined state by the reverse rotation wind cup to be horizontally placed on the outer support frame, so that the solar panel is prevented from being blown away by the high wind.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

FIG. 1 is a schematic diagram of the overall structure of a wide-area composite energy harvester of a coaxial inversion wind cup structure based on wind energy.

FIG. 2 is a schematic diagram of an exploded structure of a wind energy based coaxial inversion cup structure wide area composite energy harvester of the present invention.

FIG. 3 is a schematic diagram of a partial structure of a wide-area composite energy harvester of a coaxial inversion wind cup structure based on wind energy according to the invention.

FIG. 4 is a schematic diagram of a forward rotating assembly of the wind energy-based coaxial reverse-rotation cup structure wide-area composite energy harvester of the invention.

FIG. 5 is a schematic view of a magnet fixing assembly of the wind energy-based coaxial inversion cup structure wide-area composite energy harvester according to the present invention.

FIG. 6 is a schematic diagram of a reversing assembly of the wind energy-based coaxial reversing cup structure wide-area composite energy harvester of the invention.

Fig. 7 is a schematic structural diagram of a solar power generation assembly of the coaxial reverse wind cup structure wide-area composite energy collector based on wind energy.

FIG. 8 is a schematic diagram of a driving member structure of the wind energy-based coaxial inversion cup structure wide-area composite energy harvester according to the present invention.

FIG. 9 is a circuit diagram of the connection of the second coil of the wind energy based coaxial inversion cup structure wide area composite energy harvester of the present invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Further, in describing the embodiments of the present invention in detail, the cross-sectional view of the device structure is not partially enlarged to a general scale for convenience of description, and the schematic is only an example, which should not limit the scope of protection of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

Example 1

Referring to fig. 1, there is provided an overall structure schematic diagram of a wind-based coaxial reverse-rotation wind cup structure wide-area composite energy harvester, as shown in fig. 1 to 5, which includes a forward rotation assembly 100 including a first driving member 101, a moving-coil cantilever member 102 connected to the first driving member 101, and an electric slip ring member 103 located in the middle of the first driving member 101; and, the magnet fixing assembly 200 includes a first magnet fixing member 201 located at one side of the moving coil cantilever member 102, a fixing connection member 202 connected to the first magnet fixing member 201, and a second magnet fixing member 203 connected to the fixing connection member 202; and a reversing assembly 300 including a second driving member 301, and a support plate member 302 connected to the second driving member 301 at one side of the second magnet fixing member 203.

Specifically, the first driving piece 101 includes a forward rotating cup 101a, a forward rotating transmission shaft 101b connected with the forward rotating cup 101a, and a connecting chuck 101b-1 is arranged at one side of the forward rotating transmission shaft 101 b; the moving coil cantilever member 102 comprises a moving coil cantilever 102a, a group of first coils 102b positioned on the moving coil cantilever 102a, a connecting clamping groove 102a-1 arranged on one side of the moving coil cantilever 102a, a group of limiting clamping rings 102a-2 arranged on the other side of the moving coil cantilever 102a, and the first coils 102b clamped on the limiting clamping rings 102 a-2; the connecting clamping head 101b-1 is in embedded connection with the connecting clamping groove 102a-1, and the positive rotation wind cup 101a is fixedly connected with the positive rotation transmission shaft 101b through rivets.

Specifically, the electric slip ring 103 includes an electric slip ring 103a, and a line pin 103a-1 is disposed on the electric slip ring 103 a; the moving coil cantilever 102a is pre-provided with a circuit for mutually communicating the first coil 102b and the electric slip ring 103a, a rotor in the electric slip ring 103a is fixed on the forward rotation transmission shaft 101b, one end of a circuit pin 103a-1 is fixed on the rotor in the electric slip ring 103a, the circuit pin 103a-1 can rotate along with the rotor on the electric slip ring 103a, and the other end of the circuit pin 103a-1 is connected with a pre-set circuit on the moving coil cantilever 102 a.

Further, the first magnet fixing member 201 includes a first magnet collar 201a, a plurality of first magnets 201a-1 are disposed on the first magnet collar 201a, the first magnets 201a-1 are embedded on the first magnet collar 201a, an air gap distance between the first magnets 201a-1 and the first coils 102b is 2mm, and an air gap distance between the first magnets 201a-1 and the first coils 102b is 2mm, so that the first coils 102b can better cut a magnetic field generated by the first magnets 201 a-1.

The operation process comprises the following steps: when wind exists, the forward rotating wind cup 101a rotates to enable the forward rotating transmission shaft 101b to rotate, the forward rotating transmission shaft 101b rotates to enable the moving coil cantilever 102a to rotate, the moving coil cantilever 102a rotates to enable a group of first coils 102b to cut a magnetic field generated by the first magnet 201a-1, current generated by the first coils 102b is guided to the electric slip ring 103a through a line pin 103a-1 on the moving coil cantilever 102a, and then the current can be guided and collected through a pin on the electric slip ring 103 a.

Example 2

Referring to fig. 1-6 and 9, this embodiment differs from the first embodiment in that: the second driving member 301 includes a reversing wind cup 301a, and a reversing transmission shaft 301b located at one side of the reversing wind cup 301a, wherein a connecting sleeve 301b-1 is provided at one side of the reversing transmission shaft 301 b; the connecting sleeve 301b-1 is clamped inside the fixed connector 202, the reversing wind cup 301a and the reversing transmission shaft 301b are fixedly connected through rivets, and the connecting sleeve 301b-1 and the fixed connector 202 are fixedly connected through rivets.

Specifically, the support plate 302 includes a support side plate 302a, and a plurality of second coils 302b located at one side of the support side plate 302a, where a first bearing 302a-1 is disposed in the middle of the support side plate 302a, and a plurality of second coil clamping grooves 302a-2 are disposed at one side of the support side plate 302a, and the second coils 302b are embedded in the second coil clamping grooves 302 a-2; the inner ring of the first bearing 302a-1 is embedded on the outer side of the reverse transmission shaft 301b, and the outer ring of the first bearing 302a-1 is embedded on the inner side of the supporting side plate 302 a; the second magnet fixing member 203 comprises a second magnet clamping ring 203a, and a plurality of second magnets 203a-1 are arranged on the second magnet clamping ring 203 a; the air gap distance between the second magnet 203a-1 and the second coil 302b is 2mm, and the second coils 302b are connected in series in the specific manner of fig. 9, and the air gap distance between the second magnet 203a-1 and the second coil 302b is 2mm, so that the second coil 302b can better cut the magnetic field generated by the second magnet 203 a-1.

The rest of the structure is the same as in embodiment 1.

The operation process comprises the following steps: when wind force is large and can drive the reversing wind cup 301a to rotate, the reversing wind cup 301a rotates to enable the reversing transmission shaft 301b to rotate, the reversing transmission shaft 301b rotates to enable the connecting sleeve 301b-1 to drive the fixed connecting piece 202 to rotate, the fixed connecting piece 202 rotates to enable the magnetic field generated by the first magnet 201a-1 to rotate, and the rotating direction of the magnetic field generated by the first magnet 201a-1 is opposite to the rotating direction of the first coil 102b, so that the current intensity generated by the first coil 102b is stronger; simultaneously, the fixed connecting piece 202 rotates to enable the magnetic field generated by the second magnet 203a-1 to rotate, the magnetic field generated by the second magnet 203a-1 rotates to enable the second coil 302b to generate current, and then the current generated in the second coil 302b can be guided and collected through the lead wire.

Example 3

Referring to fig. 1-9, this embodiment differs from the above embodiments in that: also included is a solar power assembly 400 comprising an outer support frame member 401 positioned outside of the magnet securing assembly 200, a solar panel member 402 positioned on the outer support frame member 401, and a transmission member 403 positioned on one side of the support panel member 302.

Specifically, the outer support frame member 401 includes an outer support frame 401a, a group of rotation dampers 401a-1 are arranged on the outer side of the outer support frame 401a, and a second bearing is arranged at the joint of the outer support frame 401a and the forward rotation transmission shaft 101 b; the solar panel 402 comprises a solar panel 402a, a group of rotating brackets 402a-1 are arranged on the outer side of the solar panel 402a, and the rotating brackets 402a-1 are clamped and embedded on the rotating damper 401 a-1; the transmission member 403 includes a first transmission rod 403a, a second transmission rod 403b located at one side of the first transmission rod 403a, and a fixed stop rod 403c located at one side of the second transmission rod 403b, where the rotation bracket 402a-1 is embedded in the rotation damper 401a-1, so as to prevent the solar panel 402a from overturning due to gravity.

Specifically, a first bevel gear 403a-1 is arranged on one side of the first transmission rod 403a, a second bevel gear 403a-2 is arranged on the other side of the first transmission rod 403a, a fixed bracket 403a-3 is arranged on the outer side of the first transmission rod 403a, and the fixed bracket 403a-3 is fixed on the supporting side plate 302 a; the reverse transmission shaft 301b is further provided with a third bevel gear 301b-2 which is meshed with the first bevel gear 403a-1, and the fixing bracket 403a-3 is fixed on the supporting side plate 302a to support the first transmission rod 403 a.

Further, a fourth bevel gear 403b-1 is arranged on the outer side of the second transmission rod 403b, and the fourth bevel gear 403b-1 and the second bevel gear 403a-2 are meshed with each other; the outer side of the transmission member 403 is also provided with a protruding block 403b-2, one end of the transmission member 403 is provided with a hexagonal clamping block 403b-3, and one side of the hexagonal clamping block 403b-3 is provided with a spring 403b-4; the solar panel 402a is also provided with a clamping groove capable of accommodating the hexagonal clamping block 403b-3 and the spring 403b-4 to move transversely, and the second transmission rod 403b, the hexagonal clamping block 403b-3 and the spring 403b-4 are clamped and embedded on one side of the solar panel 402 a; the fixed stop lever 403c is fixed on the outer support frame 401a, and a clamping groove capable of accommodating the hexagonal clamping block 403b-3 and the spring 403b-4 to move transversely is further formed in the solar panel 402a, so that the spring 403b-4 can be compressed in the clamping groove when the hexagonal clamping block 403b-3 moves.

The rest of the structure is the same as in embodiment 2.

The operation process comprises the following steps: when the wind force is large, the solar panel 402a is in an inclined state initially, when the wind force can drive the reversing wind cup 301a to rotate, the reversing wind cup 301a rotates to enable the reversing transmission shaft 301b to rotate, the reversing transmission shaft 301b rotates to enable the third bevel gear 301b-2 to rotate, the third bevel gear 301b-2 rotates to enable the first bevel gear 403a-1 to rotate, the first bevel gear 403a-1 rotates to enable the first transmission rod 403a to rotate, the first transmission rod 403a-2 rotates to enable the second bevel gear 403a-2 to rotate, the fourth bevel gear 403b-1 rotates to enable the second transmission rod 403b to rotate, the second transmission rod 403b rotates to enable the hexagonal clamping block 403b-3 to drive the solar panel 402a to rotate, the solar panel 402a changes the inclined state to be horizontally placed on the upper side of the outer support frame 401a, the second transmission rod 403b rotates to enable the protruding block 403b-2 to rotate, the protruding block 403b-2 rotates to enable the protruding block 403b-2 to rotate to enable the fourth bevel gear 403b-1 to rotate, the fourth bevel gear 403b-2 rotates to enable the fourth bevel gear 403b-1 to enable the fourth bevel gear 403b-2 to rotate, the fourth bevel gear 403b-3 b-rotates to enable the second transmission rod 403b to rotate, the hexagonal clamping block 403b to enable the second bevel gear to be enabled to change the hexagonal clamping block 403b-3 to rotate, and the second bevel gear 403b to enable the second bevel gear to change, and the second bevel gear 3b to be kept to be pressed against the second bevel gear groove 4 b, and the second bevel gear 3b, and the second bevel gear to be kept opposite.

It is important to note that the construction and arrangement of the present application as shown in a variety of different exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the invention is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (10)

1. A coaxial reverse wind cup structure wide-area composite energy collector based on wind energy is characterized in that: the device comprises a forward rotation assembly (100), a first driving piece (101), a moving coil cantilever piece (102) connected with the first driving piece (101) and an electric slip ring piece (103) positioned in the middle of the first driving piece (101); the method comprises the steps of,

the magnet fixing assembly (200) comprises a first magnet fixing piece (201) positioned at one side of the moving coil cantilever piece (102), a fixed connecting piece (202) connected with the first magnet fixing piece (201), and a second magnet fixing piece (203) connected with the fixed connecting piece (202); the method comprises the steps of,

the reversing assembly (300) comprises a second driving piece (301), and a supporting plate (302) which is positioned on one side of the second magnet fixing piece (203) and connected with the second driving piece (301).

2. The wind-based coaxial inversion cup structure wide-area composite energy harvester of claim 1, wherein: the first driving piece (101) comprises a forward rotating wind cup (101 a), a forward rotating transmission shaft (101 b) connected with the forward rotating wind cup (101 a), and a connecting clamping head (101 b-1) is arranged on one side of the forward rotating transmission shaft (101 b);

the moving coil cantilever part (102) comprises a moving coil cantilever (102 a), a group of first coils (102 b) positioned on the moving coil cantilever (102 a), a connecting clamping groove (102 a-1) is formed in one side of the moving coil cantilever (102 a), a group of limiting clamping rings (102 a-2) are arranged on the other side of the moving coil cantilever (102 a), and the first coils (102 b) are clamped and embedded on the limiting clamping rings (102 a-2);

the connecting clamping head (101 b-1) is in embedded connection with the connecting clamping groove (102 a-1).

3. The wind-based coaxial inversion cup structure wide-area composite energy harvester of claim 2, wherein: the electric slip ring (103) comprises an electric slip ring (103 a), and a line pin (103 a-1) is arranged on the electric slip ring (103 a);

the moving coil cantilever (102 a) is provided with a circuit for communicating the first coil (102 b) and the electric slip ring (103 a) with each other.

4. A wind energy based coaxial inversion cup structure wide area composite energy harvester according to claim 3 wherein: the first magnet fixing piece (201) comprises a first magnet clamping ring (201 a), a plurality of first magnets (201 a-1) are arranged on the first magnet clamping ring (201 a), the first magnets (201 a-1) are clamped on the first magnet clamping ring (201 a), and the air gap distance between the first magnets (201 a-1) and a group of first coils (102 b) is 2mm.

5. The wind-energy-based coaxial inverted wind cup structure wide-area composite energy harvester of claim 1 or 4, wherein: the second driving piece (301) comprises a reversing wind cup (301 a) and a reversing transmission shaft (301 b) positioned at one side of the reversing wind cup (301 a), and a connecting sleeve (301 b-1) is arranged at one side of the reversing transmission shaft (301 b);

the connecting sleeve (301 b-1) is clamped and embedded on the inner side of the fixed connecting piece (202).

6. The wind-based coaxial inversion cup structure wide-area composite energy harvester according to claim 5, wherein: the support plate (302) comprises a support side plate (302 a) and a plurality of second coils (302 b) positioned on one side of the support side plate (302 a), a first bearing (302 a-1) is arranged in the middle of the support side plate (302 a), a plurality of second coil clamping grooves (302 a-2) are formed in one side of the support side plate (302 a), and the second coils (302 b) are clamped and embedded in the second coil clamping grooves (302 a-2);

the inner ring of the first bearing (302 a-1) is embedded on the outer side of the reverse transmission shaft (301 b), and the outer ring of the first bearing (302 a-1) is embedded on the inner side of the supporting side plate (302 a);

the second magnet fixing piece (203) comprises a second magnet clamping ring (203 a), and a plurality of second magnets (203 a-1) are arranged on the second magnet clamping ring (203 a);

the air gap distance between the second magnet (203 a-1) and the second coil (302 b) is 2mm.

7. The wind-based coaxial inversion cup structure wide-area composite energy harvester of claim 6, wherein: the solar power generation assembly (400) further comprises an outer support frame (401) positioned outside the magnet fixing assembly (200), a solar panel (402) positioned on the outer support frame (401), and a transmission piece (403) positioned on one side of the support panel (302).

8. The wind-based coaxial inversion cup structure wide-area composite energy harvester of claim 7, wherein: the outer support frame piece (401) comprises an outer support frame (401 a), a group of rotary dampers (401 a-1) are arranged on the outer side of the outer support frame (401 a), and a second bearing is arranged at the joint of the outer support frame (401 a) and the forward rotation transmission shaft (101 b);

the solar panel (402) comprises a solar panel (402 a), a group of rotating brackets (402 a-1) are arranged on the outer side of the solar panel (402 a), and the rotating brackets (402 a-1) are clamped and embedded on the rotary damper (401 a-1);

the transmission member (403) comprises a first transmission rod (403 a), a second transmission rod (403 b) positioned on one side of the first transmission rod (403 a), and a fixed stop lever (403 c) positioned on one side of the second transmission rod (403 b).

9. The wind-based coaxial inversion cup structure wide-area composite energy harvester of claim 8, wherein: a first bevel gear (403 a-1) is arranged on one side of the first transmission rod (403 a), a second bevel gear (403 a-2) is arranged on the other side of the first transmission rod (403 a), a fixed bracket (403 a-3) is arranged on the outer side of the first transmission rod (403 a), and the fixed bracket (403 a-3) is fixed on the supporting side plate (302 a);

the reversing transmission shaft (301 b) is also provided with a third bevel gear (301 b-2) which is meshed with the first bevel gear (403 a-1).

10. The wind-based coaxial inversion cup structure wide-area composite energy harvester of claim 9, wherein: a fourth bevel gear (403 b-1) is arranged on the outer side of the second transmission rod (403 b), and the fourth bevel gear (403 b-1) is meshed with the second bevel gear (403 a-2);

the outer side of the transmission piece (403) is also provided with a protruding block (403 b-2), one end of the transmission piece (403) is provided with a hexagonal clamping block (403 b-3), and one side of the hexagonal clamping block (403 b-3) is provided with a spring (403 b-4);

the solar panel (402 a) is also provided with a clamping groove capable of accommodating the hexagonal clamping block (403 b-3) and the spring (403 b-4) to move transversely, and the second transmission rod (403 b), the hexagonal clamping block (403 b-3) and the spring (403 b-4) are clamped and embedded on one side of the solar panel (402 a);

the fixed stop lever (403 c) is fixed on the outer support frame (401 a).

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