TWI412146B - Wind power and solar panels integrated power supply device - Google Patents

Abstract

An electric power supply device with integrated wind-powered electric generation and solar panel, including a turbine fan, a plurality of extending wings, a solar panel set, a transmission mechanism, at least one electric generator, and a motor. The solar panel set is mounted on the top of the turbine frame of the turbine fan. The transmission mechanism is installed on the top surface of the turbine frame. Each of the electric generators includes a rotor shaft which is connected with the transmission mechanism. The transmission mechanism rotates with the turbine frame and drives the rotor shaft to rotate so as to drive the electric generators to generate electricity. The motor is connected to the solar panel through conductive wires and has a rotation shaft which is connected with the transmission mechanism. Each extending wing has a connection shaft by which the extending wing is installed on the circumference of the turbine frame of the turbine fan.

Description

Wind power generation and solar panel integrated power supply device

The present invention relates to the design of a power generating device, and more particularly to a power supply device integrated with wind power and solar panels.

In recent years, with the rapid increase of the world population and the rapid development of global technology, the demand for various forms of energy, such as various fuels and electric energy for providing heat sources, light sources, traffic power and production power, has also increased dramatically. The prices of other traditional fossil fuels also fluctuate rapidly. What is becoming more and more obvious is that even the development of hydropower facilities and traditional fossil fuel sources is not enough to provide the world's rapid population growth. In addition, petrochemical fuels such as oil and gas are becoming more expensive and their global stocks are limited. Moreover, it is hoped that nuclear energy will solve the current energy dilemma faced by mankind, and will face more serious environmental problems and nuclear safety in the future.

In the face of increased energy demand and the development of alternative energy sources, wind energy is once again regarded as the focus of research. The reason is nothing more than the supply of wind energy sources, which are picked up in all countries of the world and their sources. Nor is it scarce, and wind energy can be used as long as it is powered by wind turbines or any other device that converts the kinetic energy of the wind into a form of energy available in modern technology. Moreover, with the rising mining costs and trading prices of traditional petrochemical fuels, the benefits of wind energy development and control to use wind energy in the form of electricity for households and factories have also increased. In addition, what is more desirable is that when wind energy is converted into usable energy, it does not cause any environmental pollution or air pollution at all.

In the case of a general wind turbine, it is mainly composed of a fan and a generator, and the fan is connected to the rotating shaft of the generator, whereby when the fan is operated by the wind, the connected generator is driven. Generate electricity.

However, in actual use, in the case of a typhoon or other wind speed too fast, the turbo fan is heated and violently rotated, causing the generator connected to the turbo fan to generate excessively high rotational speed, making its internal components unsatisfactory to rotate at high speed. The load, but there are those who burned.

Moreover, when there is no wind, the power generated and stored by a typical wind turbine is limited, and it cannot be used as a constant power supply station. It is necessary to combine the power generated by another natural energy source (such as solar energy) to meet the demand.

Accordingly, the main object of the present invention is to provide a power supply device integrated with wind power generation and solar panels to generate sufficient power in combination with wind power and solar energy.

Another object of the present invention is to provide a power supply device for integrating wind power generation and solar panels with an adjustable angle extending wing to avoid overheating when the wind is too large to cause the generator to burn, and to increase the wind by the extension wing. The area and direction to facilitate greater power in the wind hours.

The technical means for solving the problems of the prior art is to provide a power supply device integrated with wind power generation and solar panels, comprising a turbo fan, a solar panel, a transmission mechanism, at least one generator, and a motor. . The solar panel is placed above the turbine frame of the turbofan. The transmission mechanism is disposed on the top surface of the turbine frame of the turbofan. Each of the generator systems includes a rotor shaft, and the rotor shaft is coupled to the transmission mechanism. The transmission mechanism rotates with the rotation of the turbine frame and drives the rotor shaft to rotate to generate electric power. The motor is connected to the solar panel by wires and has a rotating shaft. The shaft of the motor is coupled to the transmission mechanism, and the solar panel is covered by the transmission mechanism, the generator and the motor.

In a preferred embodiment of the present invention, a plurality of extension wings are further included, each of the extension wings has a coupling shaft and is respectively disposed on the circumference of the turbine frame of the turbofan via its coupling shaft, and the position of each extension wing Corresponding to the blades of a single turbo fan, the extension wings are oscillated and rotated about their combined axes when subjected to wind.

Through the technical means adopted by the present invention, solar energy and wind power generation are integrated, and the two natural energy sources can be fully utilized and converted into electric energy to sufficiently cope with various power demands. Moreover, the provision of the extension wings prevents the overspeed of the invention from rotating and causing the generator to burn out.

The specific embodiments of the present invention will be further described by the following examples and the accompanying drawings.

Referring to Fig. 1, there is shown a first embodiment of a power supply apparatus for integrating wind power generation and solar panels of the present invention. The power supply device 100 integrated with the solar power panel and the solar panel of the present invention includes a turbofan 1 including a turbine frame 11, a plurality of blades 12 and a center shaft column 13. The turbine frame 11 includes an upper cover 111 and a lower frame 112. The blades 12 are upright blades, and the tops of the blades 12 are coupled to the upper cover 111 of the turbine frame 11, and the bottoms of the blades 12 are coupled to the lower frame of the turbine frame 11. 112. A plurality of air guiding fins 113 are formed on the bottom of the turbine frame 11, and the air guiding fins 113 are used to guide the wind introduced by the blades 12 of the turbo fan 1 to the lower side of the turbo fan 1. The center shaft column 13 is disposed at a central position of the turbine frame 11.

A solar panel 2 is disposed above the turbine frame 11, and a lightning rod 3 can be disposed at the top of the solar panel 2. The solar panel 2 includes four solar panels 21, and each of the solar panels 21 is disposed adjacent to each other, and is disposed adjacent to each other with a central axis I at an oblique angle to form a cone-shaped solar panel 2 . A predetermined length of the fins 211 are respectively protruded outwardly between the adjacent side edges of the solar panels 21 to increase the wind receiving area of the power supply device 100 integrated with the wind power generation and the solar panels.

The top surface of the turbine frame 11 is provided with a ventilation frame 22, and the solar panel 2 is disposed on the ventilation frame 22. The four corners of the ventilation frame 22 are respectively provided with a baffle 23, which can increase the integration of wind power generation and solar panels. The wind receiving area of the power supply device 100 is guided by the deflector 23 on the windward side to the inner space of the ventilation frame 22, and the wind is discharged from the baffle 23 on the leeward side as a ventilation frame. The heat dissipation of the device in the 11th.

Please also refer to FIG. 2, the central shaft column 13 includes an outer shaft 131 and an inner shaft 132. The outer shaft 131 is hollow tubular, and the top of the outer shaft 131 is coupled to the upper cover 111 of the turbine frame 11 and protrudes upwardly from the top surface of the upper cover 111 of the turbine frame 11 by a predetermined distance. The outer shaft 131 follows the turbine frame 11 . Rotate and rotate. The inner shaft 132 is also hollow tubular and disposed in the inner space of the outer shaft 131. The outer ring surface of the inner shaft 132 and the inner annular surface of the outer shaft 131 have a reserved space (refer to FIG. 7). The top of the shaft 132 projects upwardly from the top of the outer shaft 131 by a predetermined distance, and the inner shaft 132 is fixed and does not rotate.

The present invention includes a fixed plate 24, a transmission mechanism 4, a generator 5 and a motor 6. The fixed plate 24, the transmission mechanism 4, the generator 5 and the motor 6 are located in the internal space of the ventilation frame 22, and the solar panel The set 2 is covered by the fixed plate 24, the transmission mechanism 4, the generator 5, and the motor 6.

The fixing plate 24 is disposed on the top surface of the inner shaft 132. The transmission mechanism 4 is disposed on the top surface of the turbine frame 11, and the transmission mechanism 4 includes a belt pulley 41 and a belt 42 which is disposed at a central position of the top surface of the turbine frame 11.

The generator 5 includes a housing 51 and a rotor shaft 52. The housing 51 is disposed at one end of the fixed plate 24, and the rotor shaft 52 has a pulley 521. The motor 6 is disposed at the other end of the fixed plate 24 and is connected to the solar panel 2 via a wire. The motor 6 is coupled to a gear set 60. The motor 6 has a rotating shaft 61. The rotating shaft 61 is coupled to the gear set 60. The gear, and the shaft 61 includes a small pulley 611. The small pulley 611 of the rotating shaft 61 of the motor 6 and the pulley 521 of the rotor shaft 52 of the generator 5 are coupled to the belt 42 of the transmission mechanism 4, that is, the belt 42 is sleeved on the belt 42 The belt pulley 41, the pulley 521 of the rotor shaft 52 of the generator 5, and the small pulley 611 of the rotating shaft 61 of the motor 6 are attached. Therefore, the transmission mechanism 4 rotates with the rotation of the turbine frame 11 and drives the rotor shaft 52 to rotate to generate electric power, that is, when the turbo fan 1 rotates, the outer shaft 131 and the belt pulley 41 rotate together, and the belt pulley 41 drives the belt 42 to rotate, and the belt 42 drives the rotor shaft 52 to rotate to cause the generator 5 to generate electric power.

A selected position on the fixed plate 24 is provided with a pair of belt elastic adjusters 244 (only one can be seen in a side view), and the belt elastic adjuster 244 is coupled to the gear set 60 under the motor 6, and the belt is increased as the usage time increases. 42 will produce elastic fatigue, loose wear phenomenon, at this time the belt elastic adjuster 244 can automatically move the motor 6 toward the outer side of the fixed plate 24, so that the small pulley 611 of the shaft 61 of the motor 6 will also be fixed to the fixed plate When the outer side edge of the 24 is moved to tighten the belt 42, the belt 42 can be made to function as it is.

Anyone familiar with the art can easily know that the fixing plate 24 can be a long plate or a circular plate, and the fixing plate 24 can be provided with more than two generators.

The top surface of the fixing plate 24 is provided with a hollow tubular extending shaft 14. Please refer to FIG. 3 at the same time, the fixing plate 24 defines an opening 242, and the opening 242 is located at the top end of the inner shaft 132. The opening and the opening of the bottom end of the extension shaft 14. The fixing plate 24 is locked to the top end of the inner shaft 132 via a locking member 243. The periphery of the bottom end of the extension shaft 14 is formed with a locking portion 141 (see FIG. 7). The fixing plate 24 is provided with a threaded hole 244 for the screw to pass through the locking portion 141 of the extension shaft 14 to extend the shaft. 14 is disposed on the top surface of the fixed plate 24.

Referring to FIG. 2 and FIG. 4, the inner side of the solar panel 2 is provided with four brackets 201 near the top end of the solar panel 2 (only one can be seen in this side view), and the bottom of the bracket 201 The edge is provided with a rotating circuit board 25 (ie, the rotating circuit board 25 is located in the inner space of the solar panel group 2 and adjacent to the top end of the solar panel group 2), and the top end of the extending shaft 14 is provided with a fixed circuit board 26, a fixed circuit A predetermined distance is formed between the board 26 and the rotating circuit board 25. A lightning conductor 31 is connected between the lightning rod 3 and the rotating circuit board 25. A first wiring group 27a is connected between the rotating circuit board 25 and the solar panel 2. 27b, a lightning conductor contact piece 251 and a pair of conductive contact pieces 252a, 252b are connected between the rotating circuit board 25 and the fixed circuit board 26, and the lightning protection line 31 is connected to the lightning conductor contact piece 251, the first wire group 27a, 27b is connected to the conductive contact pieces 252a, 252b, and the bottom surface of the fixed circuit board 26 is connected with a second wire group 261a, 261b and a lightning protection wire 264 (the lightning protection wire 264 is connected to a grounding metal post), and the second wire group 261a 261b is connected to the conductive Contacts 252a, 252b, and a solar panel controller 245, in this embodiment, a second set of wires 261a, 261b defines the top of the line extending through the shaft hole 14 of the solar panel is connected to the controller 245. The lightning conductor contact piece 251 and the conductive contact pieces 252a, 252b may be carbon brushes, and the rotating circuit board 25, the fixed circuit board 26, the lightning conductor contact piece 251 and the conductive contact pieces 252a, 252b constitute a connecting unit 28.

That is, as shown in FIG. 5 and FIG. 6, the rotating circuit board 25 is provided with three sets of screws 253, 254, 255, and the fixed circuit board 26 has a first circuit 261, a second circuit 262, and A third circuit 263. The first wire sets 27a and 27b are connected to the screw sets 253 and 254, respectively, and the lightning conductors 31 are connected to the screw set 255. One ends of the conductive contact pieces 252a, 252b are respectively connected to the screw sets 253, 254, and the other ends of the conductive contact pieces 252a, 252b are respectively in contact with the first circuit 261 and the second circuit 262, when the rotating circuit board 25 is followed When the shaft 131 rotates, the conductive contact pieces 252a, 252b are in contact with the circuit patterns of the first circuit 261 and the second circuit 262, respectively, in contact with the circuit pattern of the first circuit 261 and the second circuit 262, and remain with the first circuit 261 and Contact of the second circuit 262. Since the screw set 255 and the third circuit 263 are respectively located at the center point of the rotating circuit board 25 and the fixed circuit board 26, one end of the lightning line contact piece 251 is connected to the screw set 255, and the lightning conductor contact piece 251 is The other end is in contact with the third circuit 263, so that when the rotating circuit board 25 rotates with the solar panel 2, the lightning conductor contact piece 251 remains in contact with the third circuit 263. The lightning rod 3, the lightning conductor 31, the lightning conductor contact piece 251 and the lightning protection line 264 are optional.

Please also refer to FIG. 2, FIG. 4, FIG. 7 and FIG. 8. The fixed board 24 is provided with a solar panel controller 245, a voltage comparison circuit 246 and a current voltage regulator 247, and a solar panel. 2 is connected to the solar energy via the first wire sets 27a, 27b, the connecting unit 28 (the rotating circuit board 25 in the connecting unit 28, the conductive contact pieces 252a, 252b, the fixed circuit board 26) and the second wire group 261a, 261b. The board controller 245, the solar panel controller 245 is connected to the voltage comparison circuit 246, the voltage comparison circuit 246 is connected to the motor 6, and the current voltage regulator 247 is connected to a power storage wire group 291a, 291b and via a control wire group 53c. 53d is connected to the generator 5, and the generator 5 is connected to a bridge rectifier 248 via a power supply wiring group 53a, 53b. The bridge rectifier 248 is connected to a power storage device 29 via the power storage wire group 291a, 291b (the storage wire group 291a). 291b is connected to the power storage device 29) through the hole formed in the top of the extension shaft 14 and passing through the inner space of the extension shaft 14, the opening 242 of the fixing plate 24, and the inner space of the inner shaft 132, and the solar panel controller 245 Connected to the storage wire sets 291a, 291b, the voltage comparison circuit 246 is connected to a bridge rectifier 249, the bridge rectifier 249 is connected to the power wire sets 53a, 53b via a sense wire set 62a, 62b, and the power wire set 53a, 53b can prevent the power generated by the solar panel group 2 or the power of the power storage device 29 from flowing to the voltage comparison circuit 246 via the power storage wire groups 291a, 291b and the sense wire groups 62a, 62b due to the current direction limitation of the bridge rectifier 248. .

When no wind is present, the power generated by the solar panel 2 is supplied to the motor via the first conductor sets 27a, 27b, the conductive contact pads 252a, 252b, the second conductor sets 261a, 261b, the solar panel controller 245, and the voltage comparison circuit 246. 6. Rotating the shaft 61 of the motor 6 to drive the transmission mechanism 4 to rotate, thereby driving the turbine frame 1 and the solar panel 2 disposed thereon to slowly rotate, so that the solar panels 21 of the solar panel 2 take turns to absorb sunlight. Produce the best power efficiency. When the wind causes the turbo fan 1 to rotate, the generator 5 generates electric power by the transmission mechanism 4, and the electric power flows to the sensing wire groups 62a, 62b via the power supply wire groups 53a, 53b and the partial power connection connection sensing voltage is compared. At circuit 246, voltage comparison circuit 246 shuts off the power supplied by solar panel 2 to motor 6.

The power stored in the power storage device 29 can be applied to various devices, devices or places requiring power, such as radio stations, wireless base stations, street lamps, etc., so that the present invention becomes a power supply station for a universal use, as long as there is wind. And where the sun shines, electricity can be supplied endlessly.

Referring to FIG. 7, the outer shaft 131 protrudes downwardly from the wind deflector 113 at the bottom of the turbine frame 11 to form a protruding structure 131'. The inner shaft 132 protrudes downwardly from the protruding structure 131'. The plurality of wind deflectors 113 formed by forming a projection 132', that is, the bottom of the turbine frame 11, are coupled to the protruding structure 131' of the outer shaft 131 of the center post. The bottom end of the protruding portion 132' of the inner shaft 132 is coupled with a fixed base 17 outside the annular surface, and the protruding base 131, the protruding structure 131' of the outer shaft 131 and the protruding portion 132' of the inner shaft 132 are outside the annular surface. A first axial bearing mechanism 15 is disposed, and a second axial bearing mechanism 16a is disposed between the outer annular surface of the inner shaft 132 and the inner annular surface of the protruding structure 131' of the outer shaft 131. The second axial bearing mechanism 16a is located adjacent to the first axial bearing mechanism 15, and the outer end of the inner shaft 132 and the inner annular surface of the top of the outer shaft 131 are provided with another second shaft. To the bearing mechanism 16b. The first axial bearing mechanism 15 is used to buffer the gravity generated by the power supply device 100 integrated with the wind power generation and the solar panel of the present invention in a first axial direction A, and the second axial bearing mechanism 16a, 16b is used to buffer the present The centrifugal force generated by the power supply device 100 integrated with the solar power panel and the solar panel is generated in a second axial direction B.

Referring to Figures 9 and 10, there is shown a second embodiment of the power supply apparatus incorporating the wind power generation and solar panel of the present invention. The structural design of the power supply device 200 integrated with the wind power generation and the solar panel of the present invention is substantially the same as that of the first embodiment described above, and the same components are denoted by the same component numbers. The difference between the wind power generation and the solar panel integration power supply device 200 includes a plurality of extension wings 19. Each of the extending wings 19 has a coupling shaft 191, and each of the extending wings 19 is disposed on the periphery of the turbine frame 11 of the turbofan 1 via its coupling shaft 191 and a coupling mechanism 7, respectively, and the position of each of the extending wings 19 Corresponding to the blades 12 of one turbofan 1 respectively.

Each of the coupling mechanisms 7 includes an upper coupling member 71 and a lower coupling member 72. The upper coupling member 71 is coupled to the top surface of the upper cover 111 via the locking member 711, and the lower coupling member 72 is coupled to the lower portion via the locking member 721. The bottom surface of the frame 112.

The bottom surface of each of the upper joint members 71 may be respectively provided with a stopper portion 713, and the top surfaces of the respective lower joint members 72 may be respectively provided with a stopper portion 722, and each of the stopper portions 713 and each of the stopper portions 722 are respectively The upper coupling member 71 and each of the lower coupling members 72 project outwardly. Each of the upper connecting members 71 is respectively provided with a continuous through hole 714, and each of the lower connecting members 72 is respectively provided with a continuous through hole 723, and two ends of the connecting shaft 191 of each piece of the extending piece 19 are respectively disposed through the respective through holes 714 and each The through holes 723 are respectively protruded from the respective through holes 714 and the respective through holes 723 by a predetermined distance. Preferably, between one of the outer end surfaces of the coupling shaft 191 of the extending wing 19 and the inner annular surface of the through hole 714, a binding (not shown) and a coupling shaft of the extending wing 19 may be disposed. A Palin (not shown) may be disposed between the outer end of the outer end of the 191 and the inner annular surface of the through hole 723.

Please also refer to FIG. 11 , each of the extending wings 19 includes a concave portion 192 , and each of the concave portions 192 is formed with a reinforcing portion 193 , and the reinforcing portion 193 can increase the three-dimensional strength structure of the extending wing 19 . The position height of each of the stopper portions 713 and the positional height of each of the stopper portions 722 correspond to the positional heights of the upper and lower peripheral edges of the respective recessed portions 192, respectively, so that the respective stopper portions 713 and the respective stopper portions 722 are The individual extension wings 19 can be blocked. Each of the extension wings 19 is used to increase the area and direction of the wind, respectively, and guide the received wind to the blades 12 of the turbofan 1, respectively, and the wind power generation and the solar panel of the present invention are provided by the extension wings 19 The wind power area of the integrated power supply device 200 is larger than that of the conventional wind power turbine device, and since the extension wing 19 is not shielded by the upper cover 111 and the lower frame 112, the wind can be absorbed not only by the horizontal wind direction but also by the upper and lower sides. The wind direction or the tornado winds the wind in the wind, so the invention can maintain a certain speed when the wind is small.

Referring to Fig. 12, a second embodiment of the present invention may include a plurality of elastic coupling members 8 and a plurality of adjustable mechanisms 9 (this figure is combined with an elastic coupling member 8 and an adjustable mechanism 9). The coupling member 71 is taken as an example). Each of the elastic joint members 8 has a first joint end 81 and a second joint end 82, and the first joint ends 81 of the elastic joint members 8 are respectively coupled to the joint shafts 191 of the respective sheet extending wings 19 (this embodiment) In the example, the first joint end 81 of the elastic joint member 8 is inserted into the joint shaft 191 of the extension wing 19, and the second joint ends 82 of the elastic joint members 8 are respectively coupled to the respective adjustable mechanisms 9, respectively, and each elastic joint The pieces 8 are respectively used to provide an elastic restoring force to the respective extending wings 19, and the respective adjustable mechanisms 9 are respectively for the user to adjust the elastic restoring force provided by each of the elastic engaging members 8.

Please also refer to FIG. 13 , the adjustable mechanism 9 can be disposed on the upper coupling member 71 and the lower coupling member 72 (this illustration is only illustrated by the adjustable mechanism 9 being disposed on the upper coupling member 71). The adjustable mechanism 9 includes a screw 91, a pair of positioning plates 92a and 92b, a sliding piece 93, and a positioning nut 94.

The screw 91 includes a screw body 911, interposed portions 912 and 913 projecting from both ends of the screw body 911, and an operating member 914 coupled to the interposing portion 912. The insertion portion 912 of the screw 91 is inserted into the positioning plate 92a, and the insertion portion 913 of the screw 91 is inserted into the positioning plate 92b. The user can rotate the screw body 911 by rotating the operating member 914. . The sliding piece 93 is disposed on the outer surface of the screw body 911, and the bottom edge of the sliding piece 93 is flatly attached to the top surface of the upper coupling member 71, and the second coupling end 82 of the elastic coupling member 8 is coupled to the sliding piece 93. . The positioning nut 94 is disposed at a selected position of the annulus outside the screw body 911.

When the user rotates the operating member 914 to rotate the screw body 911, the sliding piece 93 slides in the direction of the screw body 911, and the user can control the sliding piece 93 toward the positioning plate by controlling the rotating direction of the operating member 914. 92a is either slid toward the positioning plate 92b. When the sliding piece 93 slides toward the positioning plate 92a, the elastic coupling member 8 provides a small elastic restoring force. When the sliding piece 93 slides in the direction of the positioning plate 92b, the elastic coupling member 8 provides an elastic restoring force. Big. When the slider 93 is moved to the selected position, it can be positioned and secured by the positioning nut 94.

Referring to Fig. 14, the power supply device 200 integrated with the wind power generation and the solar panel of the present invention rotates in a rotation direction R when the wind is blown, and the extension wing 19 rotates around the coupling shaft 191 when subjected to the wind. The swinging, for example, the extending wing 19 located at about three o'clock in the figure, can reduce the wind receiving surface of the blade 12 of the turbofan 1 when the air volume is large, so that the air inlet space of the blade 12 of the turbo fan 1 can be covered. The rotational speed of the power supply device 200 in which the wind power generation of the present invention is integrated with the solar panel is limited. Moreover, when the extension wing 19 is rotated along the rotation direction R to the position of the wind and the weaker position, the extension wing 19 is returned to the stopped portion 713 by the elastic restoring force provided by the elastic coupling member 8. The position of the stop (since each stop portion 713 and each stop portion 722 can be used to limit the angle of rotation of each piece of extension wing 19, respectively), for example, from about 9 o'clock to eleven o'clock in the figure The extension wing 19, at this time, has the effect of the wind deflector, which can slow down the rotation speed of the power supply device 200 integrated with the wind power generation and the solar panel of the present invention, so as to avoid the rotation speed being too fast and damaging the present invention. Thus, when the air volume is large, the extension wing 19 of the present invention has a double limiting effect on the rotational speed of the power supply device 200 integrated with the wind power generation and the solar panel of the present invention, and can prevent the overspeed and cause the burning of the generator 5.

Referring to Fig. 15, there is shown a third embodiment of the power supply apparatus integrated with the wind power generation and solar panel of the present invention. The structural design of the power supply device 300 integrated with the wind power generation and the solar panel of the present invention is substantially the same as that of the second embodiment described above, and the same components are denoted by the same component numbers. The difference is that the bottom edge of each of the solar panels 21a of the solar panel 2a extends downward to an adjacent position above the extension wing 19, and in addition to increasing the power by increasing the area of the solar panel, each solar panel can also be used. The coupling shaft 191 of the 21a mask extension wing 19 and the coupling mechanism 7 prevent the coupling shaft 191 of the extension wing 19 and the coupling mechanism 7 from being rusted by the rain.

It will be readily appreciated by those skilled in the art that the above described blade 12 and extension wings 19 are shaped such that the present invention rotates in a clockwise direction (i.e., direction of rotation R) when subjected to wind, and is suitable for use in the southern hemisphere. It is of course also possible to design the concave arc direction of the blade and the extension wing to be opposite to the blade 12 and the extension wing 19 in the above embodiment, so that the present invention can be applied to the northern hemisphere in a counterclockwise direction when subjected to wind. As for the gear set 60, it is used to solve the contradiction between the dynamic interlocking, and the functional design may include a clutch transmission, a one-way transmission, a shifting, etc., and may also have the functions of acceleration, deceleration, protection, or braking, which can be seen by the present invention. The application needs to be changed.

It can be seen from the above embodiments that the power supply device integrated with the wind power generation and the solar panel provided by the present invention has industrial utilization value, and thus the present invention has met the requirements of the patent. The above description is only for the preferred embodiment of the present invention, and those skilled in the art can make other various improvements according to the above description, but these changes still belong to the inventive spirit of the present invention and the following definitions. In the scope of patents.

100, 200, 300. . . Wind power generation and solar panel integrated power supply device

1. . . Turbo fan

11. . . Turbine frame

111. . . Upper cover

112. . . Lower frame

113. . . Wind guide

12. . . blade

13. . . Central shaft column

131. . . Outer shaft

131’. . . Protruding structure

132. . . Inner shaft

132’. . . Protrusion

14. . . Extension axis

141. . . Locking part

15. . . First axial bearing mechanism

16a, 16b. . . Second axial bearing mechanism

17. . . Fixed base

19. . . Extension wing

191. . . Combined shaft

192. . . Concave

193. . . Reinforcement department

2, 2a. . . Solar panel

201. . . support

21, 21a. . . Solar panels

211, 211a. . . Wing

twenty two. . . Ventilation frame

twenty three. . . Baffle

twenty four. . . Fixed plate

241. . . Belt elastic regulator

242. . . Opening

243. . . Locking element

244. . . Threaded hole

245. . . Solar panel controller

246. . . Voltage comparison circuit

247. . . Current and voltage regulator

248. . . Bridge rectifier

249. . . Bridge rectifier

25. . . Rotating circuit board

251. . . Lightning line contact piece

252a, 252b. . . Conductive contact piece

253, 254, 255. . . Screw set

26. . . Fixed circuit board

261. . . First circuit

261a, 261b. . . Second wire set

262. . . Second circuit

263. . . Third circuit

264. . . Lightning line

27a, 27b. . . First wire set

28. . . Connection unit

29. . . Power storage device

291a, 291b. . . Power storage wire set

3. . . lightning rod

31. . . Lightning line

4. . . Transmission mechanism

41. . . Belt pulley

42. . . Belt

5. . . generator

51. . . case

52. . . Rotor shaft

521. . . Pulley

53a, 53b. . . Power lead set

53c, 53d. . . Control wire set

6. . . motor

60. . . Gear set

61. . . Rotating shaft

611. . . Small pulley

62a, 62b. . . Sensing wire set

7. . . Combined mechanism

71. . . Upper joint

711. . . Locking element

713. . . Stop section

714. . . Through hole

72. . . Lower joint

721. . . Locking element

722. . . Stop section

723. . . Through hole

8. . . Elastic joint

81. . . First junction

82. . . Second binding end

9. . . Adjustable mechanism

91. . . Screw

911. . . Screw body

912, 913. . . Interposer

914. . . Operating part

92a, 92b. . . Positioning plate

93. . . Slide

94. . . Positioning nut

A. . . First axial direction

B. . . Second axial direction

I. . . Central axis

R. . . turn around

1 is a perspective view of a first embodiment of a power supply device integrated with a wind power generation and a solar panel according to the present invention; and FIG. 2 is a schematic structural view of a portion of the solar panel set in the first embodiment of the present invention; The fixing plate of the present invention, the inner shaft disposed under the fixing plate, and the extending shaft locking hole of the fixing plate; FIG. 4 is a sectional view of the fixed circuit board and the rotating circuit board of the present invention; FIG. 5 is a top view of the rotating circuit board in the present invention; FIG. 6 is a top view of the fixed circuit board in the present invention; and FIG. 7 is a central shaft column and a bearing mechanism in the present invention; , FIG. 8 is a perspective view of a control circuit of the present invention; FIG. 9 is a perspective view of a second embodiment of the present invention; and FIG. 10 is an extension wing and a turbine of the present invention; FIG. 11 is a cross-sectional view of the section 11-11 in FIG. 10; FIG. 12 is a combination mechanism of the second embodiment of the present invention, which is coupled to the extension wing via an adjustable mechanism and an elastic coupling member. Combined shaft top view Figure 13 a cross-sectional view of line 12 in the section 13-13; Figure 14 a top view of a second embodiment of the system according to the present invention; Fig. 15 a perspective view of a third embodiment of system of the embodiment of the present invention.

200. . . Wind power generation and solar panel integrated power supply device

112. . . Lower frame

113. . . Wind guide

12. . . blade

19. . . Extension wing

192. . . Concave

193. . . Reinforcement department

2. . . Solar panel

twenty one. . . Solar panels

211. . . Wing

twenty two. . . Ventilation frame

3. . . lightning rod

7. . . Combined mechanism

71. . . Upper joint

711. . . Locking element

713. . . Stop section

72. . . Lower joint

722. . . Stop section

Claims (18)

An electric power supply device integrated with a solar power panel and a solar panel, characterized in that the electric power supply device integrated with the solar power panel comprises: a turbo fan comprising: a turbine frame; a plurality of blades, the top of the blade And a bottom portion is coupled to the turbine frame; a central shaft column is disposed at a central position of the turbine frame, the central shaft column includes: an outer shaft, which is hollow tubular, and the top of the outer shaft is coupled to the turbine frame And protruding upwardly from the top surface of the turbine frame by a predetermined distance, the outer shaft rotates with the rotation of the turbine frame; an inner shaft is hollow and is disposed in the inner space of the outer shaft, The outer ring surface of the inner shaft and the inner ring surface of the outer shaft have a reserved space, and the top of the inner shaft protrudes upward from the top of the outer shaft by a predetermined distance, and the inner shaft is fixed and does not rotate. a solar panel set above the turbine frame. The power supply device integrated with the wind power generation and the solar panel according to claim 1, further comprising a transmission mechanism, at least one generator, and a motor disposed on a top surface of the turbine frame. Each of the generator systems includes a rotor shaft coupled to the transmission mechanism, the transmission mechanism rotates with the rotation of the turbine frame and drives the rotor shaft to rotate to generate electric power, and the motor is connected. In the solar panel, the motor has a rotating shaft coupled to the transmission mechanism, and the solar panel is covered by the transmission mechanism, the generator and the motor. The power supply device integrated with the wind power generation and the solar panel according to claim 2, further comprising a rotating circuit board disposed in the inner space of the solar panel and adjacent to the top of the solar panel, The top surface of the inner shaft is provided with a fixing plate, and the top surface of the fixing plate is provided with a hollow tubular extending shaft, and the fixing plate is provided with an opening, and the opening is located corresponding to the top end of the inner shaft. The opening and the opening of the bottom end of the extending shaft, the top end of the extending shaft is provided with a fixed circuit board, the fixed circuit board and the rotating circuit board have a predetermined distance between the rotating circuit board and the solar panel A first wire set is connected between the rotating circuit board and the fixed circuit board, and a pair of conductive contact pieces are connected between the rotating circuit board and the fixed circuit board. The first wire group is connected to the pair of conductive contact pieces, and the bottom surface of the fixed circuit board is A second wire set is coupled to the pair of conductive contacts and a solar panel controller. The power supply device integrated with the wind power generation and the solar panel according to claim 3, wherein the solar panel controller is connected to a power storage device and a voltage comparison circuit, and the voltage comparison circuit is connected to the motor, The generator is connected to a current voltage regulator, the current voltage regulator is connected to the power storage device and the generator, and when the wind is no wind, the power generated by the solar panel is via the first wire set, the pair of conductive contacts a chip, the second wire set, the solar panel controller and the voltage comparison circuit are supplied to the motor, and the rotating shaft of the motor is rotated to drive the transmission mechanism to drive the turbine frame and the solar panel disposed thereon The group rotates, when the wind causes the turbo fan to rotate and the generator generates electricity by the transmission mechanism, and part of the power generated by the generator flows to the voltage comparison circuit, the voltage comparison circuit cuts off the The solar panel is supplied with power to the motor. The power supply device integrated with the wind power generation and the solar panel according to claim 2, wherein the transmission mechanism comprises a belt pulley and a belt, and the belt pulley is disposed at a central position of a top surface of the turbine frame. The belt is sleeved on the belt pulley, a pulley of one of the rotor shafts of the generator, and a small pulley of one of the rotating shafts of the motor. The power supply device integrated with the wind power generation and the solar panel according to claim 5, wherein the top surface of the inner shaft is provided with a fixing plate, and the selected position of the fixing plate is provided with a pair of belt elastic adjusters, A belt tension adjuster is coupled to the motor. The power supply device integrated with the wind power generation and the solar panel according to claim 6, wherein the motor is coupled to a gear set, and the belt elastic adjuster is coupled to the gear set. The power supply device integrated with the wind power generation and the solar panel according to the first aspect of the invention, wherein the solar panel comprises at least three solar panels, each of which is disposed adjacent to each other and is a center The axes are arranged adjacent to each other at an oblique angle to form a cone-shaped solar panel. The power supply device integrated with the wind power generation and the solar panel according to claim 8 , wherein the adjacent side edges of the solar panels respectively protrude outwardly with a predetermined length of the fins to increase the The wind receiving area of the power supply unit integrated with wind power and solar panels. The power supply device integrated with the wind power generation and the solar panel according to claim 1, further comprising a ventilation frame disposed on a top surface of the turbine frame, the solar panel being disposed on the ventilation frame. The power supply device integrated with the wind power generation and the solar panel according to claim 10, further comprising a plurality of baffles disposed at selected positions of the ventilation frame. The power supply device integrated with the wind power generation and the solar panel according to claim 1, further comprising a first axial bearing mechanism and two second axial bearing mechanisms, wherein the outer shaft protrudes downward Forming a protruding structure for the bottom of the turbine frame, the inner shaft protruding downwardly from the protruding structure to form a protruding portion, and the bottom end of the protruding portion of the inner shaft is coupled with a fixed surface a base, the first axial bearing mechanism is disposed between the fixed base, the protruding structure of the outer shaft and the outer annular surface of the protruding portion of the inner shaft, wherein a second axial bearing mechanism is disposed therein Between the outer annular surface of the protruding portion of the shaft and the inner annular surface of the protruding structure of the outer shaft and adjacent to the first axial bearing mechanism, another second axial bearing mechanism is disposed on the outer shaft Between the inner annulus of the top and the outer annulus of the inner shaft. The power supply device integrated with the wind power generation and the solar panel according to claim 1, further comprising a plurality of extension wings, each of the extension wings having a coupling shaft and respectively coupled via the coupling shaft and a coupling mechanism Provided on a circumference of the turbine frame of the turbofan, each of the extending wings is corresponding to a blade of the turbofan, and each of the extended wings is respectively configured to receive wind and respectively guide the received wind to the turbine. Each blade of the fan. The power supply device integrated with the wind power generation and the solar panel according to claim 13 , wherein the solar panel is covered by the coupling shaft of the extension wing. The power supply device integrated with the wind power generation and the solar panel according to claim 13, wherein the extension wing is rotatably oscillated about the combined shaft when subjected to wind. The power supply device integrated with the wind power generation and the solar panel as described in claim 15 further includes a plurality of elastic joint members, each of the elastic joint members having a first joint end and a second joint end, respectively The first joint ends of the elastic joints are respectively coupled to the joint shafts of the respective extension wings, and the second joint ends of the elastic joint members are respectively coupled to selected positions of the respective joint mechanisms, and the elastic joint members are respectively used to provide one The elastic restoring force is applied to each piece of the extended wing. The power supply device integrated with the wind power generation and the solar panel according to claim 16 , wherein the second combined end of each elastic coupling member is respectively coupled to one adjustable mechanism disposed on each of the coupling mechanisms, each adjustable The mechanism is used for the user to adjust the magnitude of the elastic restoring force provided by each elastic joint. The power supply device integrated with the wind power generation and the solar panel as described in claim 15 further includes a plurality of stop portions respectively protruding outward from the turbine frame of the turbo fan or respectively by respective bonding mechanisms The outer protrusions are respectively extended to limit the angles of the rotation of the respective extension wings.