TWM571908U - Auxiliary power wind turbine - Google Patents

Abstract

The present invention is an auxiliary power wind power generator comprising: a wind power generator set having a plurality of blades and a bracket, each of the blades being mounted on the bracket, and each of the blades has a blow hole respectively The bracket is provided with a gas passage connecting each of the air blowing holes; a sea wave inflatable group is inflated toward the air passage by the sea wave inflation group, so that air is discharged from the air blowing hole, thereby making the wind power generator not only It is possible to use wind power to generate electricity by using sea wave rotation.

Description

Auxiliary power wind turbine

The present invention relates to a wind power generator, and more particularly to an auxiliary power wind power generator.

Due to the advancement of science and technology and the evolution of society, limited energy sources such as oil, natural gas and media have been extensively and rapidly excavated, driving the rapid exhaustion of limited energy. Therefore, energy development has become one of the global concerns.

Currently, renewable energy sources are obtained in environments such as water, wind, geothermal heat, firepower, and the sun. Therefore, hydropower generation, wind power generation, thermal power generation, and solar power generation have been developed.

Since the wind power generation device not only has the advantages of simple structure, convenient maintenance and maintenance, and low environmental damage, the installation location is flexible in both land and sea, and thus the wind power generation device is highly valued.

A wind turbine is a kind of power generation method that uses a wind to push a fan blade and converts kinetic energy into electric power through the rotation of the fan blade. According to the power generation principle, the wind power generator is a geographically limited power generation device, and wind power is not set in any country or region. The generator can obtain satisfactory power generation benefits, and the reason is mainly because the fan blade has a large volume and weight, and the wind that can drive the fan blades to generate electricity must not only overcome the weight of the blade itself, but also the fan. The friction between the blade and the relatively rotatable component must also be overcome before it can begin to rotate. It can be seen that the wind that starts the wind power must be extremely powerful, but in terms of mechanics, it overcomes the maximum static of the wind power generation. After the friction force, although the frictional force after the blade starts to rotate may be reduced, it is still necessary to overcome the weight of the blade to continuously generate electricity; thus, when the wind turbine is located in an area where the wind volume is insufficient or cannot last for a long time, Therefore, the satisfactory power generation efficiency cannot be obtained; in view of this, the creator has conceived and studied more deeply. And finally the creation of a wind turbine having an auxiliary power.

The purpose of the novel is to prevent the wind turbine from being unable to sustain power generation due to insufficient wind power, thereby enabling the wind power generator to continue generating electricity.

To achieve the foregoing objectives, the present invention is an auxiliary power wind turbine comprising:

a wind turbine having a plurality of blades and a bracket, each of the blades being mounted on the bracket, and each of the blades has a blowing hole, and the bracket is provided with a transmission connecting each of the blowing holes Gas passage

a sea wave inflating group having a body and a gas valve member, the body having an inflatable space, and the body is provided with a first inflation channel and a second inflation channel communicating with the gas passage, and the body a first air inlet and a second air inlet are respectively connected to the outside, and the first air passage, the second air passage, the first air inlet and the second air inlet are respectively respectively a one-way air valve is provided, the air valve member has a pusher block, a connecting rod and a floating block, the pusher block is installed in the inflatable space, and the inflatable space is divided into a first space and a second space, the first inflation passage and the first air inlet communicate with the first space, the second inflation passage and the second inflation passage communicate with the second space, and one end of the connecting rod is connected to the push air a block, and the other end of the connecting rod is connected to the floating block, the floating block is placed on the sea surface;

Thereby, the floating block undulates with the sea surface, and the connecting rod and the pushing block are driven by the floating block, so that the air pushing block pushes the air in the inflating space into the air conveying channel and is discharged from the air blowing hole. .

In a preferred embodiment, the body has a top surface and a bottom surface, the top surface and the bottom surface face the inflated space, and the top surface extends to the bottom surface in a vertical direction, and the top surface is located at the first The space is located in the second space, and the push block is displaced along the vertical direction.

In a preferred embodiment, an air outlet valve is disposed on the first inflation passage and the second inflation passage, and an intake valve is disposed on the first air inlet and the second air inlet, respectively.

An auxiliary power wind turbine comprising:

a wind turbine having a plurality of blades and a bracket, each of the blades being mounted on the bracket, each of the blades having a sump, and the wind generator has an energy conversion unit and a storage battery a unit, the energy of the rotation of the blade is converted into electric power by the energy conversion unit, and the energy conversion unit is connected to the power storage unit, thereby storing energy converted by the energy conversion unit in the power storage unit;

a pumping device is connected to the power storage unit, the pumping device has a pumping motor and a water pipe, the pumping motor is pumped, and one end of the water pipe is connected to the pumping motor, and the other end of the water pipe has a The water outlet corresponds to the position of the sump of each of the blades.

In a preferred embodiment, each of the receiving leaves has a connecting portion and a receiving portion, and one end of the connecting portion is connected to the receiving portion, and the receiving portion can receive the water discharged from the water outlet, thereby driving the wind power generation The unit rotates.

Thereby, the wind power generator is capable of discharging water by receiving the water outlet, causing the wind power generator to generate power and converting the power into electric power by the energy conversion unit, and storing the power to the electricity storage unit.

Referring to FIG. 1 to FIG. 3, an auxiliary power wind generator of the present invention, in the first embodiment, includes:

A wind turbine 10 has a plurality of blades 11 and a bracket 12, each of the blades 11 is mounted on the bracket 12, and each of the blades 11 has a blowing hole 111, and the bracket 12 is disposed a gas passage 121 connecting each of the blowing holes 111;

A sea wave inflating group 20 has a body 21 and a valve member 22, the body 21 has an inflatable space 211, a top surface 212 and a bottom surface 213, the top surface 212 and the bottom surface 213 face the inflatable space 211, and The top surface 212 extends to the bottom surface 213 in a vertical direction Y. The body 21 is provided with a first inflation passage 214 and a second inflation passage 215 communicating with the air passage 121, and the body 21 is further A first air inlet 216 and a second air inlet 217 are connected to the outside. The air valve member 22 has a pushing block 221, a connecting rod 222 and a floating block 223. The air pushing block 221 The first inflatable space 214 and the first air inlet 216 are connected to the first space 211A, and the first air inlet 214 and the first air inlet 216 are connected to the first space 211A. The top surface 212 is located in the first space 211A, the second inflation channel 215 and the second inflation channel 215 are connected to the second space 211B, and the bottom surface 213 is located in the second space 211B, one end of the connecting rod 222 The push block 221 is connected, and the other end of the connecting rod 222 is connected to the floating block 223, and the floating block 223 is provided. Placed on the sea;

Thereby, the floating block 223 undulates with the sea surface, and the connecting rod 222 and the urging block 221 are driven by the floating block 223, so that the air pushing block 221 pushes the air in the plenum 211 into the gas conveying channel. 121 is discharged from the blow hole 111.

In a preferred embodiment, an air outlet valve 218 is disposed on the first air inlet passage 214 and the second air inlet passage 215, and the first air inlet hole 216 and the second air inlet hole 217 are respectively disposed. There is an intake valve 219.

The above is the structural configuration and the connection relationship of the novel embodiment in the first embodiment. The usage of the first embodiment of the present invention is as follows:

Referring to FIG. 1 and FIG. 3, the floating block 223 is driven by the sea surface to move the floating block 223 along the vertical direction Y toward the top surface 212, so that the air pushing block 221 is pushed toward the top surface 212 by using the lifting block 223. The air pushing block 221 pushes the air of the first space 211A from the first air passage 214 into the air passage 121, and when the sea surface descends, the floating block 223 is displaced along the vertical direction Y by the sea surface, thereby further The urging block 221 is moved along the vertical direction Y toward the bottom surface 213. While the urging block 221 is moving, the urging block 221 squeezes the air of the second space 211B into the second inflation passage 215, and the air Each of the air blowing holes 111 is ejected from the air blowing holes 111, and air is ejected from each of the air blowing holes 111 to rotate the respective blades 11.

In particular, the air outlet valve 218 is disposed on the first air inlet passage 214 and the second air inlet passage 215, and the first air inlet hole 216 and the second air inlet hole 217 are provided with the air inlet. When the urging block 221 is displaced along the vertical direction Y in the plenum 211, the air in the first space 211A and the second space 211B will only be from the first inflation passage 214 and the first The second inflation passage 215 is exhausted and only intakes from the first intake aperture 216 and the second intake aperture 217.

Referring to FIG. 4 and FIG. 5, the present invention does not have the sea wave inflating group 20 in the second embodiment, and the wind power generating set 10 does not have the air blowing hole 111 and the air conveying passage 121;

Each of the blades 11 of the wind turbine 10 has a sump 112, and the wind turbine 10 has an energy conversion unit 30 and a storage unit 40, and the energy of the rotation of the blade 11 is converted by the energy. The unit 30 is converted into electric power, and the energy conversion unit 30 is connected to the electric storage unit 40, thereby storing the energy converted by the energy conversion unit 30 in the electric storage unit 40;

A pumping device 50 is connected to the power storage unit 40. The pumping device 50 has a pumping motor 51 and a water pipe 52. The pumping motor 51 is pumped, and one end of the water pipe 52 is connected to the pumping motor 51. The other end of the water conduit 52 has a water outlet 521 corresponding to the position of the sump 112 of each of the blades 11, so that when the water outlet 521 is out of water, water can be received in one of the sumpes 112. .

The energy conversion unit 30 generates electric power by the wind power generating unit 10, and stores the electric power in the electric storage unit 40, and the water pumping device 50 is connected to the electric storage unit 40, and the electric storage unit 40 provides the electric power unit 40. The pumping device 50 is powered to enable the pumping device 50 to draw water to the water outlet 521.

The above is the structural configuration and the connection relationship of the novel embodiment in the second embodiment. The usage of the second embodiment of the present invention is as follows:

Referring to FIG. 4, each of the blades 11 of the wind turbine 10 is rotated by wind blowing, and the kinetic energy of the rotation of each of the blades 11 is transmitted to the energy conversion unit 30, and the energy conversion unit 30 converts the power into electricity. The electric power is stored in the electric storage unit 40, and the electric storage unit 40 supplies the electric power of the water pumping device 50, so that the motor of the water pumping device 50 can pump water, and then pump water to the water outlet 521, through the water outlet. The 521 discharge water is received into the sump 112 of each of the blades 11, and each of the blades 11 is rotated by the water received in the sump 112. The rotation of the blades 11 can generate kinetic energy, and the energy is converted. The unit 30 converts kinetic energy into electrical energy, and supplies the electric energy to the pumping device 50 to pump water to the water outlet 521 to continue power generation.

Referring to FIG. 6 , in the third embodiment of the present invention, the wind turbine 10 further has a plurality of receiving blades 13 , and each of the receiving blades 13 has a connecting portion 131 and a receiving portion 132 respectively. One end is connected to the receiving portion 132, and the receiving portion 132 can receive the water discharged from the water outlet 521, thereby driving the wind turbine 10 to rotate.

Referring to FIG. 7, in the fourth embodiment, each of the blades 11 has a solution tank 113, and each of the solution tanks 113 has a first end 113A and a second end 113B, respectively. The end 113A is closer to the sump 112 than the second end 113B, and the second end 113B is away from the sump 112 than the first end 113A. Each of the blades 11 has a communication tube 114, and the communication tube 114 is connected. The sump 112 and the outside, through the communication pipe 114, can fill the solution tank 113 with liquid without filling the liquid, whereby the liquid can flow in the solution tank 113, and when the blade 11 is turned from a high point When the position is low, the liquid in the solution tank 113 flows from the second end 113B to the first end 113A, thereby increasing the kinetic energy of the rotation, and the solution tank 113 is turned when the blade 11 is turned from a low position to a high position. The liquid in the flow flows from the first end 113A to the second end 113B, thereby reducing the kinetic energy of the rotation, thereby increasing the rotational torque to enable each of the blades 11 to continuously rotate to generate electricity.

Referring to FIG. 8, in the fifth embodiment of the present invention, each of the air blowing holes 111 is respectively connected to an extension pipe 115, and one end of each of the extension pipes 115 is connected to each of the air blowing holes 111, and each of the extension pipes 115 is further One end is bent and faces the blade 11 , so that the wind blown by each of the blow holes 111 can be guided to each of the blades 11 by the extension pipes 115 , so that the blades can be blown out by the extension pipes 115 . The wind turns.

More preferably, when the typhoon comes, the water can be filled in each of the solution tanks 113 from the respective communication tubes 114, so that the weight of each of the blades can be increased, and the problem that the typhoon blows rapidly and is easily damaged can be prevented.

Thereby, the wind power generator set 10 can transmit the water discharged from the water outlet 521, cause the wind power generating set 10 to generate power, convert the power into electric power by the energy conversion unit 30, and store the electric power to the electric storage unit. 40.

10‧‧‧ wind turbines

11‧‧‧ fan leaves

111‧‧‧Blow holes

112‧‧‧ sink

113‧‧‧solution tank

113A‧‧‧ first end

113B‧‧‧ second end

114‧‧‧Connected pipe

115‧‧‧ Extension tube

12‧‧‧ bracket

121‧‧‧Gas channel

13‧‧‧Accepting leaves

131‧‧‧Connecting Department

132‧‧‧Acceptance Department

20‧‧‧Haibo Inflatable Group

21‧‧‧ body

211‧‧‧Inflatable space

211A‧‧‧First Space

211B‧‧‧Second space

212‧‧‧ top surface

213‧‧‧ bottom

214‧‧‧First inflation channel

215‧‧‧Second inflation channel

216‧‧‧First air intake

217‧‧‧Second air intake

218‧‧‧Exhaust valve

219‧‧‧Intake valve

22‧‧‧ gas valve parts

221‧‧‧Pushing block

222‧‧‧Connecting rod

223‧‧‧ floating block

30‧‧‧ energy conversion unit

40‧‧‧Power storage unit

50‧‧‧ pumping device

51‧‧‧ pumping motor

52‧‧‧Water pipes

521‧‧‧Water outlet

Y‧‧‧Vertical direction

Figure 1 is a schematic view showing the structure of the present invention in the first embodiment. Fig. 2 is a partial enlarged view of the blow hole of the fan in the first embodiment of the present invention. Fig. 3 is a schematic view showing another state in which the Haibo inflatable group is inflated in the first embodiment. Figure 4 is a schematic view showing the structure of the present invention in the second embodiment. Figure 5 is a structural configuration diagram of the present invention in the second embodiment. Fig. 6 is a structural view of the present invention in a third embodiment. Fig. 7 is a structural view of the present invention in the fourth embodiment. Figure 8 is a cross-sectional view of the fan in the fifth embodiment of the present invention.

Claims (9)

An auxiliary power wind power generator comprising: a wind power generator set having a plurality of blades and a bracket, each of the blades being mounted on the bracket, and each of the blades has a blowing hole, and the bracket is respectively a gas passage connecting the air blowing holes; a sea wave inflatable group having a body and a gas valve member, the body having an inflatable space, and the body is provided with a first communicating with the gas passage An air inlet channel and a second air inlet channel, and the body further has a first air inlet hole and a second air inlet hole communicating with the outside, the air valve member has a pushing block and a connecting rod and a sump that is disposed in the plenum and divides the plenum into a first space and a second space, the first inflation channel and the first air inlet are connected to the first space The second inflation passage and the second inflation passage communicate with the second space, one end of the connecting rod is connected to the push block, and the other end of the connecting rod is connected to the floating block, and the floating block is placed on the sea surface By the way, the float rises and falls with the sea surface. This drives the floating block and said push rod connecting the gas block, the block that the forward gas plenum within the air pushed into the gas delivery passage and is discharged from the blowing hole. The auxiliary power wind turbine of claim 1, wherein the body has a top surface and a bottom surface, the top surface and the bottom surface face the inflatable space, and the top surface extends to the bottom surface in a vertical direction. The top surface is located in the first space, and the bottom surface is located in the second space, and the air pushing block is displaced along the vertical direction. The auxiliary power wind turbine of claim 1, wherein the first inflation passage and the second inflation passage are respectively provided with an air outlet valve, and the first air inlet hole and the second air inlet hole are respectively An intake valve is separately provided. The auxiliary power wind turbine of claim 1, wherein each of the air blowing holes is respectively connected with an extension pipe, one end of each of the extension pipes is connected to each of the air blowing holes, and the other end of each of the extension pipes is bent. And facing each of the blades. An auxiliary power wind power generator comprising: a wind power generator set having a plurality of blades and a bracket, each of the blades being mounted on the bracket, each of the blades having a sump and the wind power generation The unit has an energy conversion unit and an electric storage unit, and the energy of the rotation of the fan is converted into electric power by the energy conversion unit, and the energy conversion unit is connected to the electric storage unit, thereby converting the energy converted by the energy conversion unit Stored in the power storage unit; a pumping device is connected to the power storage unit, the pumping device has a pumping motor and a water pipe, the pumping motor is pumped, and one end of the water pipe is connected to the pumping motor, The other end of the water pipe has a water outlet corresponding to the position of the sump of each of the blades. The auxiliary power wind turbine of claim 5, wherein the wind power generator further has a plurality of receiving leaves, each of the receiving leaves having a connecting portion and a receiving portion, wherein one end of the connecting portion is connected to the wind turbine The receiving portion is capable of receiving water discharged from the water outlet, thereby driving the wind turbine to rotate. An auxiliary power wind power generator comprising: a wind power generator set having a plurality of blades and a bracket, each of the blades being mounted on the bracket, and each of the blades has a blowing hole, and the bracket is respectively a gas passage connecting each of the blowing holes, each of the blades having a solution tank, each of the solution tanks having a first end and a second end; thereby, the liquid can be in the solution tank Flowing, when the blade turns from a high position to a low position, the liquid in the solution tank flows from the second end to the first end, thereby increasing the kinetic energy of the rotation, and the blade is turned from a low position to a high position The liquid in the solution tank flows from the first end to the second end. The auxiliary power wind turbine of claim 7, wherein each of the blades has a communication tube that communicates with the solution tank and the outside, and the communication tube can fill the solution tank with liquid Do not fill the liquid. The auxiliary power wind turbine of claim 7, wherein each of the blades has a sump, and the wind power generator has an energy conversion unit and a power storage unit, and the energy of the blade rotation Converting into power by the energy conversion unit, and the energy conversion unit is connected to the power storage unit, thereby storing energy converted by the energy conversion unit in the power storage unit; and a pumping device connected to the power storage unit, The pumping device has a pumping motor and a water pipe, the pumping motor is pumped, and one end of the water pipe is connected to the pumping motor, and the other end of the water pipe has a water outlet corresponding to each fan blade The location of the sink.