KR100773115B1 - Wind power generator - Google Patents

Abstract

Wind generators according to the present invention, a plurality of supports that are each erected at a position spaced a considerable distance; At least one overhead support line connected between the support and the support; A plurality of windmills which are continuously arranged in a state in which a plurality of them are supported by the processing support line and rotated by wind; It is configured to include a generator for generating electricity by receiving the rotational force of the plurality of windmills, it is possible to increase the economic feasibility while reducing the initial investment costs and large-scale power generation.

Windmill, generator, overhead support, support, lightning rod, hydraulic pump, hydraulic motor

Description

Wind power generator

1 is a configuration diagram showing a wind generator according to a first embodiment of the present invention,

2 is a detailed view of the main part of FIG.

3 is a configuration diagram showing a wind generator according to a second embodiment of the present invention,

4 is a detailed view of the main part of FIG.

5 is a configuration diagram showing a wind generator according to a third embodiment of the present invention,

FIG. 6 is a detailed view 'A' of FIG. 5;

7 is a hydraulic circuit diagram of a third embodiment of the present invention;

8 is a configuration diagram showing a wind generator according to a fourth embodiment of the present invention,

FIG. 9 is a detailed view 'B' of FIG. 8;

10 is a configuration diagram illustrating a wind generator according to a fifth embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: support 13: machining support line

15: joint 17: windmill

18 generator 19 power line

20: lightning rod 115: axis of rotation

116: universal joint 118: generator

122: shaft support line 123: bearing

125: shaft bearing 222: windmill support

224: bevel gear set 230: hydraulic pump

233: hydraulic hose 240: hydraulic motor

250: transmission 260: generator

270 control unit 360 generator

425: Coupler

The present invention relates to a wind generator, in particular, by connecting the processing support line to both supports, and by installing a number of windmills continuously supported by the processing support line to reduce the installation cost, a large-capacity power generation can be improved economic efficiency It is about.

Normally, a wind power generator is a power generator that turns a windmill by natural wind and turns the generator by speeding it up using a gear mechanism or the like.

Such a wind power generator is environmentally friendly, or because the initial investment cost of the power generation facility is large, the recovery period is long, so the economic feasibility is not widespread than other power generation facilities.

The reason why the conventional wind power generator is low in economic efficiency is that the structure for supporting each windmill and the installation cost of the generator are large, and each windmill is equipped with a separate generator, which is also expensive and maintenance costs are also high.

However, as fossil fuels are depleted recently and global environmental pollution is also an important issue, research on wind power generation facilities using natural wind is being actively conducted, and demand for wind generators capable of generating large capacity while reducing investment cost is required. It is becoming.

The present invention has been made in order to solve the above problems, by providing a number of windmills arranged in the processing support connecting the two supports to provide a wind power generator that can increase the economic feasibility while reducing the initial investment cost and large capacity There is a purpose.

Wind generators according to the present invention for realizing the above object, a plurality of supports that are each erected at a position separated by a considerable distance; At least one overhead support line connected between the support and the support; A plurality of windmills which are continuously arranged in a state in which a plurality of them are supported by the processing support line and rotated by wind; It is configured to include a generator for generating electricity by receiving the rotational force of the plurality of windmills.

According to a first aspect of the present invention, the overhead support line is made of a linear member and fixed to both supports, and the windmill and generator are configured in one set to be installed on the overhead support line to generate electricity.

Between the support and the support is connected to each generator is connected to the power line for drawing power to the outside.

The windmill is installed to offset the rotation torque by reversing the wing angle between the windmills.

The processing support line is composed of a plurality of linear members, connected in a mutual joint structure.

A lightning rod is connected between the support and the support so that the wind generator can be protected from lightning.

According to a second aspect of the present invention, the wind generator is located in the direction parallel to the processing support line is connected to the rotating shaft to rotate together with the windmill is installed, the rotating shaft is supported by the processing support line through the shaft support line.

At least one side of the rotary shaft is provided with the generator for generating electricity in accordance with the rotation of the rotary shaft.

The rotating shaft is divided into a plurality, the connecting portion of each shaft is connected by a universal joint.

A lightning rod is connected between the support and the support so that the wind generator can be protected from lightning.

According to a third aspect of the present invention, a plurality of the processing support lines are installed side by side up and down, and a windmill supporter for supporting each of the windmills in a vertical direction is provided between the processing support lines.

The windmill support is provided with a bevel gear set for transmitting the rotational power generated in the windmill in a direction orthogonal to each other.

One side of the windmill support is provided with a power transmission means for transmitting the power generated by the rotation of the windmill to the generator.

The power transmission means comprises a hydraulic pump driven by the windmill, and a hydraulic motor for driving the generator while being rotated by the hydraulic pressure generated by the hydraulic pump.

A transmission for adjusting the rotational speed is provided between the hydraulic motor and the generator.

A plurality of shutoff valves are provided on the pipeline between the hydraulic pump and the hydraulic motor to open and close the flow path.

On the conduit between the hydraulic pump and the hydraulic motor is provided with a bypass line and a bypass valve for bypassing the flow path.

An automatic pressure valve is provided on the conduit between the hydraulic pump and the hydraulic motor.

A lightning rod is connected between the support and the support so that the wind generator can be protected from lightning.

According to a fourth aspect of the present invention, the windmill support is provided with a bevel gear set for transmitting the rotational power generated in the windmill in a direction orthogonal to each other, the generator is installed on each of the windmill support is rotated from the bevel gear set Configured to receive power.

According to a fifth aspect of the present invention, a plurality of the processing support lines are installed side by side up and down, and a windmill supporter is installed in the vertical direction to the upper side and the lower side of the processing support line, respectively, and the windmill is at the end of the windmill supporter. Each is installed.

Wherein the windmill support is fixed to the processing support line through the cross-type coupler.

In addition, the wind power generator according to the present invention for realizing the above object, a plurality of supports that are respectively erected at a position spaced a considerable distance; At least one overhead support line connected between the support and the support; A plurality of windmills which are continuously arranged in a state in which a plurality of them are supported by the processing support line and rotated by wind; A hydraulic system receiving a rotational force of the plurality of windmills through a hydraulic pump to drive a hydraulic motor; It is also possible to include a generator for generating electricity by the rotational force of the hydraulic motor.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram showing a wind generator according to a first embodiment of the present invention, Figure 2 is a detailed view of the main part of FIG.

As shown therein, the wind power generator according to the first embodiment of the present invention is connected to a plurality of supports 10 which are respectively erected at positions spaced apart from each other in a horizontal direction between the supports 10 and the supports 10. The processing support line 13, the plurality of windmills 17 which are continuously arranged in a state supported by the processing support line 13 and rotated by wind, and receive rotational force of the plurality of windmills 17 to receive electricity It is composed of a generator 18 to generate.

The support 10 is composed of a conventional metal rod, a steel tower structure or a concrete structure such as a power pole, etc., it is preferable to be installed on the peaks 1 such as on the valley between the windy mountains and mountains or between islands and islands. Do.

The processing support line 13 is made of a linear member such as a reinforcing rope having sufficient tensile strength and rigidity, and is fixedly installed at both support bases 10. The processing support line 13 may be composed of one long wire, but it is preferable that the processing support line 13 is connected to each other by a joint 15 or the like in a state consisting of a plurality of linear members to facilitate the installation and expansion of the wire.

The windmill 17 and the generator 18 of this embodiment consist of one integrated set, which is directly installed on the processing support line 13. Of course, since the processing support line 13 does not rotate, the windmill 17 is rotatably installed in the processing support line 13 by a bearing or the like.

A power line 19 is connected between the support 10 and the support 10 to draw power to the outside of the generator 18.

Unlike this, the power line 19 may be installed to be connected to the support 10 through the inside of the processing support line 13 without additional installation, and also to store power such as a power load or a battery in each generator 18. It can be installed in series or parallel connection to the system.

On the other hand, the windmill 17 is preferably installed so as to offset the rotation torque by reversing the wing angle between the windmills. That is, when the windmills 17 rotate only in one direction, a considerable torque is generated in the processing support line 13, so that the front windmills 17 and the rear windmills 17 are installed in opposite directions. The torsional torque generated in the support 10 during rotation can be reduced.

A lightning rod 20 is connected between the support 10 and the support 10 to protect the wind generator 18 from lightning strikes, and the lightning rod 20 is a lightning rod installed in the support 10. It is connected to the external ground 22 through 21.

The wind generator according to the first embodiment of the present invention configured as described above is provided with a plurality of windmills 17 and generators 18 in succession between both supports 10 and as each windmill 17 is rotated The power generated by each generator 18 can be recovered through the power line and supplied to the power source.

Such a wind power generator of the present invention can be installed at the same time a plurality of windmills 17 on one support line 13 can produce a greater amount of power, thereby reducing the initial installation cost of the power plant at the same time to produce power Even if it is economical.

3 is a block diagram showing a wind generator according to a second embodiment of the present invention, Figure 4 is a detailed view of the main part of FIG.

As shown in the wind generator according to the second embodiment of the present invention, as shown in the first embodiment, the processing support line 113 is connected to both support bases 110, and the lightning rod 120 is connected to the upper side thereof. do.

In particular, in the second embodiment of the present invention, the rotary shaft 115 is installed to rotate the windmills 117 directly in the direction parallel to the processing support line 113, the rotation shaft 115 is located on the processing support line 113 It is supported through the axial support line 122. A bearing 123 is installed between the shaft support line 122 and the rotation shaft 115.

Here, the rotation shaft 115 is divided into a plurality of steel bars, etc., the connection portion of each shaft is connected to the universal joint 116 to be able to be assembled while being able to some extent bending. Of course, instead of the universal joint 166 it is also possible to be connected in a clutch type joint structure capable of power interruption.

One end of the rotary shaft 115 is provided with a generator 118 that generates electricity as the rotary shaft 115 rotates by the windmills 117. And the other end of the rotating shaft 115 is provided with a shaft bearing 125.

In the wind power generator according to the third embodiment of the present invention as described above, a plurality of windmills 117 are continuously installed on one rotary shaft 115 to generate power in one generator 118, thereby reducing the installation cost of the power plant. Can be reduced, and large-capacity power production becomes possible.

5 is a configuration diagram showing a wind generator according to a third embodiment of the present invention, Figure 6 is a partial view 'A' of Figure 5, Figure 7 is a hydraulic circuit configuration of a third embodiment of the present invention. .

As shown therein, in the wind power generator according to the third embodiment of the present invention, processing support lines 213 and 215 are installed side by side up and down between both supports 210.

And the windmill supporter 222 which supports each said windmill 217 in a vertical direction between the process support line 213 is installed. The windmill support 222 is configured to allow the windmill 217 to rotate freely in the direction of the wind direction.

The windmill support 222 is provided with a bevel gear set 224 to transmit the rotational power generated in the windmill 217 in the direction orthogonal as shown in Figure 6, the bevel gear set 224 is a windmill Power is transmitted between the shaft 218 and the transmission shaft 225. Of course, the gear housing 223 is provided on the windmill supporter 222 to protect the bevel gear set 224. In addition, the gear housing 223 may be installed to be freely rotated with respect to the windmill supporter 222.

Between the lower end of the windmill support 222 and the lower processing support line 215 is provided with a power transmission means for transmitting the power transmitted by the transmission shaft 225 to the generator 260, shown in FIG. As described above, the power transmission means includes a plurality of hydraulic pumps 230 driven by the windmills 217 and hydraulic pressures that drive the generator 260 while being rotated by the hydraulic pressure generated by the hydraulic pumps 230. The motor 240 and the hydraulic motor 240 and the generator 260 is composed of a transmission 250 for adjusting the rotational speed.

The hydraulic pump 230 is preferably provided in each of the windmills 217, the pump is operated as the transmission shaft 225 of Figure 6 rotates to generate the hydraulic pressure to flow toward the hydraulic motor 240 Is configured to.

Wherein the hydraulic pump 230 and the hydraulic motor 240 is connected to the hydraulic hose 233, the hydraulic hose 233 may be connected in series or parallel to the hydraulic pump 230, the present embodiment In the example, a configuration connected in series is illustrated.

On the conduit between the hydraulic pump 230 and the hydraulic motor 240, a plurality of shutoff valves for opening and closing the flow passage to facilitate maintenance and control of the hydraulic system, a bypass valve for bypassing the flow passage, and a pressure in the conduit automatically. An automatic pressure valve and the like are provided to adjust the pressure.

That is, referring to FIG. 7, each of the hydraulic pumps 230 is provided with a supply shutoff valve V2 and a discharge shutoff valve V1 for blocking the flow path and bypass the hydraulic lines 230. BL and a bypass valve (BV) are provided, and on the safety line (PL) connecting the inlet and outlet side of the hydraulic pump 230 is provided with an automatic pressure valve (PV) for releasing the excessive pressure.

In addition, a shutoff valve V3 is also provided at the hydraulic motor 240 side, and a bypass valve BV is disposed on a line BL 'PL' connecting the outlet side and the discharge side of the hydraulic motor 240, respectively. ') And automatic pressure valve PL' are respectively provided.

Here, the various valves are configured to be operated manually or automatically, and in the case of automatic operation, it is preferable to be configured to be automatically operated by the control signal of the controller 270 to be described later.

In addition, an accumulator or hydraulic tank 235 is provided on the hydraulic hose 233 to store or replenish hydraulic oil or gas.

On the other hand, a pressure or flow sensor 236 is provided on the hydraulic hose 233, receives the signal sensed by the flow sensor 236, the control unit 270 to adjust the rotational force of the hydraulic motor 240 Done.

The hydraulic motor 240 is preferably composed of a multi-stage hydraulic motor 240 capable of speed control. Of course, even if not the multi-stage hydraulic motor 240, the shut-off valve V1 (V2) and the bypass valve BV of the hydraulic pump 230 side or the bypass valve BV 'of the hydraulic motor 240 side automatically. By adjusting the flow rate flowing into the hydraulic motor 240 may be configured to enable the output rotation speed adjustment.

On the other hand, the support rods 220 are installed on both support bases 210 so as to reduce the loss of the windmill 217 due to lightning or the like.

In the wind generator according to the third embodiment of the present invention, a plurality of windmills 217 are installed between both supports 210, and the power obtained from each of the windmills 217 is transferred to the hydraulic pump 230 and the hydraulic hose 233. In addition to driving the hydraulic motor 240 through), by operating a single generator 260 by the driving force of the hydraulic motor 240 to produce power.

In particular, since the power generated from each windmill 217 is transmitted to the generator 260 using hydraulic pressure, the entire system including the windmill 217 and the like installed between the both support 210 can be reduced in weight. .

Therefore, in the present embodiment, since the power generated by the multiple windmills 217 is configured to be transmitted to the generator 260 by using a hydraulic system, power loss is reduced while initial power and maintenance cost are reduced. It is possible to increase the overall economic feasibility.

In addition, by controlling the hydraulic system through the control unit 270 and various valves, etc., the windmill 217 and the generator 260 can be operated more efficiently, and the output of the generator 260 can be easily adjusted.

FIG. 8 is a block diagram illustrating a wind power generator according to a fourth embodiment of the present invention, and FIG. 9 is a detailed view 'B' of FIG. 8.

As shown in the wind generator according to the fourth embodiment of the present invention, the processing support lines 313 and 315 are vertically connected to both supports 310 as in the above-described third embodiment, and the lightning rod is located at the top. 320 is connected.

In addition, a windmill supporter 322 for supporting each windmill 317 in a vertical direction is installed between the processing support lines 313 and 315, and the windmill supporter 322 has the windmill 317 as shown in FIG. 9. Bevel gear set 324 for transmitting the rotational power generated in the orthogonal direction is provided.

Here, the bevel gear set 324 transmits power between the windmill shaft 318 and the transmission shaft 325, and protects the bevel gear set 324 and free rotation of the windmill 317. Gear housing 323 is provided to enable this.

In particular, in this embodiment, the generator 360 is provided on the upper side of the windmill support 322, the generator 360 receives the rotational force from the transmission shaft 325 to generate power, the electricity generated here Is drawn to a power storage system such as an external power load or a battery through a power line connected to the windmill supporter 322 and the processing support line 313.

In the wind power generator according to the fourth embodiment of the present invention, a plurality of windmills 317 are continuously installed between both supports 310 to produce power in each generator 360, thereby reducing the installation cost of power generation facilities. And large-capacity power production becomes possible.

10 is a configuration diagram illustrating a wind generator according to a fifth embodiment of the present invention.

As shown in the wind generator according to the fifth embodiment of the present invention, the processing support lines 413 and 415 are vertically connected to both support units 410 and the lightning rods (upper and lower) are connected to both support units 410. 420 is connected.

In particular, in the present embodiment, the processing support lines 413 and 415 are installed at upper and lower proximity distances, and the windmill supports 422 and 422 are vertically connected to upper and lower portions of the processing support lines 413 and 415, respectively. Windmills 417, 417 'and generators 418, 418' are installed at the ends of the windmill supports 422, 422, respectively.

Here, the windmill supports 422 and 422 are fixed to the processing support lines 413 and 415 through a cross coupler 425, and the vertical support lines 413 and 415 are also connected through the coupler 425. It is preferred to be configured to be interconnected.

The power generated by the generators 418 and 418 'of each of the windmills 417 and 417' is transferred to the outside through a power line connected between the windmill supports 422 and 422 'and the processing support lines 413 and 415. It is withdrawn.

In the above, the structure of the windmill supporters 422 and 422 'is installed in the plurality of the processing support lines 413 and 415, but only one processing support line is used and the windmill supports are formed above and below the processing support line according to the implementation conditions. Of course it is possible. In addition, it is also possible to install and configure different types of windmills in each of the windmill supports 422 and 422 'according to the implementation conditions.

In the wind power generator according to the fifth embodiment of the present invention, a plurality of windmill supports 422 and 422 'are installed vertically between both supports 410, and the windmill supports 422 and 422' are respectively installed. Since the windmills 417 and 417 'are installed at the end to generate power, the installation cost of the power generation equipment can be reduced, and large-capacity power can be produced.

The wind generator according to the present invention configured and operated as described above is configured to produce power by continuously arranging a plurality of windmills between both supports, so that large-scale power generation can be achieved while reducing initial investment costs, thereby increasing economic efficiency. There is an advantage to that.

In addition, since the wind generator according to the present invention is configured to produce power by transmitting the rotational force generated from the various windmills to the generator through the hydraulic pump and the hydraulic motor, the structure of transferring the power from one windmill to one generator is simple. In addition, it is easy to control the output of the generator, there is an advantage that can reduce the maintenance cost of the power plant.

Claims (23)

delete A plurality of supports, each of which is erected at a considerable distance from each other; At least one overhead support line connected between the support and the support; A plurality of windmills which are continuously arranged in a state in which a plurality of them are supported by the processing support line and rotated by wind; It includes a generator for generating electricity by receiving the rotational force of the plurality of windmills, The processing support line is made of a linear member is fixed to both supports, The windmill and the generator are configured in one set is installed on the processing support line to generate electricity, Between the support and the support is connected to each generator is connected to the power line for drawing power to the outside, The windmill is installed to offset the rotational torque by reversing the wing angle between the windmills, The processing support line is composed of a plurality of linear members, are connected to each other in a joint structure, A wind generator, characterized in that the lightning rod is connected between the support and the support so that the wind generator is protected from lightning. delete delete delete delete delete delete delete delete A plurality of supports, each of which is erected at a considerable distance from each other; At least one overhead support line connected between the support and the support; A plurality of windmills which are continuously arranged in a state in which a plurality of them are supported by the processing support line and rotated by wind; It includes a generator for generating electricity by receiving the rotational force of the plurality of windmills, The processing support line is provided with a plurality of side by side up and down, Between the processing support line is provided a windmill supporter for supporting the respective windmills in the vertical direction, The windmill support is provided with a bevel gear set for transmitting the rotational power generated in the windmill in a direction perpendicular to, One side of the windmill support is provided with a power transmission means for transmitting the power generated by the rotation of the windmill to the generator, The power transmission means includes a hydraulic pump driven by the windmill, and a hydraulic motor for driving the generator while being rotated by the hydraulic pressure generated by the hydraulic pump, Between the hydraulic motor and the generator is provided with a transmission for adjusting the rotational speed, On the pipeline between the hydraulic pump and the hydraulic motor, a plurality of shutoff valves for opening and closing the flow path, a bypass line and a bypass valve for bypassing the flow path, and an automatic pressure valve are provided. A wind generator, characterized in that the lightning rod is connected between the support and the support so that the wind generator is protected from lightning. delete delete delete delete delete delete delete delete delete delete delete delete

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