KR101218136B1 - Wind power generator - Google Patents

Abstract

The present invention relates to a two-way wind power generator, when the front wing and the rear wing rotates in different directions at different speeds for the same wind, the generator in a different direction at different speeds through a rotating member provided inside the body In addition to receiving the rotational force of the front wing and the rear wing to rotate more easily to generate electrical energy, in particular, there is an effect that can be provided with a variety of generators inside the body.

Description

Two-Way Wind Power Generators {WIND POWER GENERATOR}

The present invention is the front wing and the rear wing in which the generator rotates in different directions at different speeds through a rotating member provided inside the body when the front wing and the rear wing rotates in different directions at different speeds for the same wind. In addition to being able to easily receive the rotational force of the generated electric energy, in particular, it relates to a two-way wind power generator that can be provided with a variety of generators inside the body.

In general, electric energy is covered by almost all electric power by thermal power generation using oil or coal, hydropower using water level difference, nuclear power generation using uranium or plutonium, and the like.

On the other hand, thermal power plants burn oil or coal to generate high-pressure steam supplied to a steam turbine. At this time, a large amount of soot is generated, which pollutes the air.

Hydroelectric power generation does not pollute the air compared to other power generation methods, but it causes side effects such as flooding of upstream areas and destruction of ecosystems.

Nuclear power generation has been concerned about radioactive pollution caused by radioactive waste and large casualties caused by radioactive leakage accidents.

Accordingly, many researches are being conducted to develop environment-friendly alternative energy. For example, tidal power generation using tidal wave difference, wave power generation using wave height, wind power generation using wind, solar power generation using solar power, solar power. Solar cell power generation using light, fuel cell power generation that directly obtains electrical energy from fuel, etc.

Among them, a wind power generator proposed as wind power generation using wind usually includes a body part including a front wing, a rear wing, a hub, and a power generation unit for converting the front and rear wing rotational motions into electrical energy; A support stand to which the body portion is rotatably coupled; It is configured to include; a power storage unit for storing the electrical energy generated by the power generation unit.

However, the front wing and the rear wing is formed so as to rotate in the opposite direction to the same wind, and the rotation speed of the rear wing is slower than the front wing, so that the generator rotates the front wing and the rear wing electrical energy Not only is it difficult to easily convert to, there is a problem in particular in accordance with the type of generator provided in the body portion.

The present invention was created in order to solve the above-described problems, the generator is different from each other through a rotating member provided inside the body when the front wing and the rear wing rotates in different directions at different speeds for the same wind By receiving the rotational force of the front and rear blades to rotate in different directions more easily to generate electrical energy, in particular, to provide a two-way wind power generator that can be equipped with a variety of generators inside the body It is for that purpose.

The present invention for achieving the above object and holding; A body having a lower portion coupled to the upper portion of the support and having front and rear wings respectively rotating in different directions with respect to the same wind in front and rear; A generator configured to generate electric energy by receiving rotational force from the front wing and the rear wing which rotate in different directions in a state provided between the front wing and the rear wing respectively provided in front and rear of the body; It is vertically provided at a predetermined interval inside the body and rotates in different directions along the front and rear blades, respectively, having different front and rear rotary members having different diameters, and are fixed in the vertical direction at an upper side of the front and rear rotary members. In the horizontally spaced state at intervals, respectively, the upper rotary member having different diameters for rotating the front and rear rotary members in different directions by rotating the rotary force from the front rotary member and the lower side of the front and rear rotary members. Rotating member consisting of lower rotating members having different diameters to rotate the front and rear rotating members in different directions by rotating the rotational force received from the front rotating member in a horizontally spaced state at a predetermined interval in the vertical direction; Two-way wind turbine, characterized in that made It provides a group.

Here, the front shaft is horizontally provided on the inner front side of the body axially coupled to the front end, the inner rear side of the body of the rotating shaft of the front end of the shaft of the generator exposed to the outside is axially coupled to the rear end This horizontally equipped, the generator is a low-speed generator, the rear wing is axially coupled to the rear end of the shaft of the generator, the front rotating member of the rotating member is the front bevel is vertically coupled to the rear end of the front shaft And a rear bevel gear that is axially coupled to the front end of the rotating shaft in a state in which the rear rotating member is larger in diameter than the front bevel gear, and the upper rotating member is located above the front bevel gear. The lower front side is engaged with the horizontal beveled on the upper side of the front bevel gear in a state that is engaged with the rotational force from the front bevel gear A first upper bevel gear that is transmitted and rotated, and axially coupled with the first upper bevel gear so as to be horizontally arranged in the upper direction of the first upper bevel gear, the diameter is larger than the first upper bevel gear, the lower rear side is the rear bevel A second upper bevel gear configured to rotate by receiving rotational force from the first upper bevel gear while being engaged with the upper side of the gear to allow the rear bevel gear to rotate in a direction different from the front bevel gear; The rotating member has a first lower bevel gear and a first lower bevel gear, which is horizontally provided to the lower side of the front bevel gear in a state where the upper front side is engaged with the lower side of the front bevel gear, and is rotated by receiving rotational force from the front bevel gear. It is axially coupled with the first lower bevel gear so as to be horizontally arranged in the lower direction of the gear and has a larger diameter than the first lower bevel gear. A second lower bevel gear that rotates by receiving rotational force from the first lower bevel gear while the upper rear side is engaged with the lower side of the rear bevel gear so that the rear bevel gear can rotate in a different direction from the front bevel gear. It is preferable that it consists of.

In addition, a front shaft is horizontally provided on the inner front side of the body axially coupled to the front blade, the front shaft is provided with a universal joint at the rear end, and a hollow shaft rotating along the front blade; It is inserted into the inside of the hollow shaft to be movable back and forth, the front blade is coupled to the front end shaft, the front and rear movable shaft for rotating along the front wing to rotate the hollow shaft in the rotation direction of the front blade; It is preferable that the universal joint shaft is made of a universal joint shaft, and the front rotary member of the rotary member is vertically provided at the rear end of the rotary shaft which is universally coupled to the universal joint provided at the rear end of the hollow shaft.

Furthermore, a rear shaft having the rear blades coupled to the rear end is horizontally provided at the inner rear side of the body, and a rear shaft of the generator shaft exposed to the outside at the inner front side of the body is coupled to the front end of the rotating shaft. It is horizontally equipped, the generator is a high speed generator, the front blade is axially coupled to the front end of the shaft of the generator, the front rotating member of the rotating member is axially coupled to the rear end of the rotating shaft vertically And a rear bevel gear that is axially coupled to the front end of the rear shaft in a state in which the rear rotating member is larger in diameter than the front bevel gear, and the upper rotating member is located above the front bevel gear. The lower front side is engaged with the horizontal beveled on the upper side of the front bevel gear in a state in which the front bevel gears transmit a rotational force A first upper bevel gear that is rotated by rotation and coupled with the first upper bevel gear so as to be horizontally arranged in an upper direction of the first upper bevel gear, having a diameter larger than that of the first upper bevel gear, and a lower rear side of the rear bevel gear. A second upper bevel gear configured to rotate by receiving a rotational force from the first upper bevel gear while being engaged to an upper side of the second bevel gear so that the rear bevel gear can rotate in a different direction from the front bevel gear; The member has a first lower bevel gear and a first lower bevel gear, which are horizontally provided to the lower side of the front bevel gear while the upper front side is engaged with the lower side of the front bevel gear and rotates by receiving rotational force from the front bevel gear. It is axially coupled with the first lower bevel gear to be horizontally arranged in the lower direction of the larger diameter than the first lower bevel gear and the upper A second lower bevel gear that rotates by receiving rotational force from the first lower bevel gear while the rear side is engaged with the lower side of the rear bevel gear so that the rear bevel gear can rotate in a different direction from the front bevel gear. It is preferable to make.

In addition, the inner rear side of the body has a rear shaft horizontally coupled to the rear end is coupled to the rear end, the rear shaft is provided with a universal joint at the front end, and a hollow shaft for rotating along the rear wing; It is inserted into the inside of the hollow shaft so as to move back and forth, the rear blade is axially coupled to the rear end, the front and rear movement shaft for rotating along the rear wing to rotate the hollow shaft in the rotational direction of the rear blade; It is preferable that the universal joint shaft is made of a universal joint shaft, and the rear rotating member of the rotating member is vertically provided at the front end portion of the rotary shaft having the universal joint axially coupled to the universal joint provided at the front end portion of the hollow shaft.

In addition, the outer periphery of the generator is preferably formed extending in the longitudinal direction of the generator, the heat dissipation fins protruding in the upper direction at equal intervals.

The present invention is the front wing and the rear wing in which the generator rotates in different directions at different speeds through a rotating member provided inside the body when the front wing and the rear wing rotates in different directions at different speeds for the same wind. In addition to being easily transmitted to the rotational force of the electric energy can be generated, in particular, there is an effect that can be provided inside the body of various types of generators.

And, the front and rear bevel gears constituting the front and rear rotating members of the rotating member; First and second upper bevel gears forming an upper rotating member of the rotating member; Through the first and second lower bevel gears constituting the lower rotating member of the rotating member, the rear side of the body, in particular, there is an effect that can be more easily installed in the state exposed to the low speed generator of the generator.

The universal joint shaft may be rotated from side to side along the body when the front shaft, which is horizontally provided on the inner front side of the body, is formed of a universal joint shaft including a hollow shaft and a front and rear movement shaft. Even if there is a slight change in the front and rear length of the joint shaft, the front and rear movement shafts move back and forth in response to the small change in the front and rear lengths. There is an effect that disappears.

Furthermore, the front and rear bevel gears forming the front and rear rotating members of the rotating member; First and second upper bevel gears forming an upper rotating member of the rotating member; The first and second lower bevel gears forming the lower rotating member of the rotating member have an effect of being able to more easily install the high speed generator among the generators, especially on the front side of the body.

In addition, when the rear shaft horizontally provided on the inner rear side of the body is made of a universal joint shaft including a hollow shaft and the front and rear movement shaft, the universal joint shaft shaft during the process of rotating the left and right along the body Even if there is a slight change in the longitudinal length of the joint shaft, the front and rear movement shafts move back and forth in response to the slight change in the longitudinal length, so that the rear shaft made of the universal joint shaft shaft may be damaged during the rotational movement along the body. There is an effect that disappears.

In addition, as the heat generating fins are formed at the outer periphery of the generator in the longitudinal direction of the generator and protrude in the upper direction at equal intervals, the high heat generated by the generator during the process of generating the electric energy to the outside is provided. There is an effect that can be radiated more smoothly.

1 is a perspective view schematically showing a two-way wind power generator which is a first embodiment of the present invention,
FIG. 2 is a longitudinal cross-sectional view taken along line AA of FIG. 1,
FIG. 3 is a partially enlarged perspective view schematically illustrating a universal joint shaft shaft constituting the front shaft of FIG. 2;
Figure 4 is a perspective view schematically showing a two-way wind power generator of a second embodiment of the present invention,
5 is a longitudinal cross-sectional view taken along line B-B of FIG.
FIG. 6 is a partially enlarged perspective view schematically illustrating a universal joint shaft shaft constituting the rear shaft of FIG. 5.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a perspective view schematically showing a bidirectional wind power generator according to a first embodiment of the present invention, and FIG. 2 is a longitudinal cross-sectional view taken along line AA of FIG. 1.

The bidirectional wind power generator according to the first embodiment of the present invention includes a strut 10, a body 30, a generator 50, and a rotating member 70, as shown in FIGS. 1 and 2.

First, the support 10 may be fixedly installed perpendicular to the ground.

Next, the body 30 is axially coupled to the upper portion of the support (10).

The body 30 may be rotated in place in the left and right directions by the wind to indicate the wind direction.

A well-known slip ring (not shown) is provided between the lower portion of the body 30 and the upper portion of the support 10 so that the body 30 can be easily rotated from side to side in the wind by the wind. It may be provided.

Front and rear of the body 30 is provided with a front wing 310 and a rear wing 330 are rotated in different directions for the same wind as shown in Figures 1 and 2, respectively.

The length L ₁ of the front wing 310 is formed shorter than the length L ₂ of the rear wing 330 (L ₁ <L ₂ ),

The rotational speed of the front blade 310 to each other rotate in different directions for the same wind (S ₁₎ is relatively faster than the rotational speed (S ₂₎ of said rear wings (330). ₍₁ S 〉 S ₂

Next, the generator 50 is horizontally provided between the front wing 310 and the rear wing 330 provided in front and rear of the body 30, respectively.

The generator 50 generates electric energy by receiving rotational force from the front wing 310 and the rear wing 330 which rotate in different directions.

Next, the rotating member 70 of the first embodiment is largely composed of the front and rear rotary members 710 and 730, the upper rotary member 750 and the lower rotary member 770 as shown in FIG.

The front rotating member 710 is vertically provided on the inner center of the body (30).

The rear rotating member 730 is vertically provided on the inner rear side of the body 30 in a state spaced apart from the front rotating member 710 at a predetermined interval.

The front rotating member 710 and the rear rotating member 730 rotate in different directions along the front wing 310 and the rear wing 330, respectively, and the front rotating member 710 and the rear rotating member 730. ) Diameters are different from each other.

The upper rotating member 750 is vertically mounted on the upper side of the body 30 so as to be horizontally provided at a predetermined interval in the vertical direction on the upper side of the front and rear rotating members 710 and 730, respectively. The outer periphery of the can be horizontally coupled to each other at regular intervals in the vertical direction.

An upper end portion of the rotating shaft 301 vertically provided on the upper side of the body 30 may be fixed to the upper surface of the body 30.

Diameters of the upper rotating members 750 horizontally arranged at regular intervals in the vertical direction on the outer circumference of the rotating shaft 301 are different from each other.

The upper rotating member 750 is rotated by receiving a rotational force from the front rotating member 710 to rotate the front and rear rotating members 710 and 730 in different directions.

The lower rotating member 770 is vertically mounted to the inner lower side of the body 30 so as to be horizontally provided at a predetermined interval in the vertical direction to the lower side of the front and rear rotating members 710 and 730, respectively. The outer periphery of the can be horizontally coupled to each other at regular intervals in the vertical direction.

The lower end of the rotating shaft 303 which is provided vertically to the inner lower side of the body 30 may be bearing fixed to the lower surface of the body (30).

The diameters of the lower rotating members 770 horizontally arranged at regular intervals in the vertical direction on the outer circumference of the rotating shaft 303 are different from each other.

The lower rotating member 770 is rotated by receiving a rotational force from the front rotating member 710 to rotate the front and rear rotating members 710 and 730 in different directions.

Next, as shown in FIG. 2, the front shaft 320 may be horizontally provided at the inner front side of the body 30.

The front wing 310 is axially coupled to the front end of the front shaft 320.

A rotating shaft 313 may be horizontally provided on the inner rear side of the body 30.

The rear end of the rotating shaft 313 may be coupled to the front end of the shaft 510 provided in the center of the generator 50 provided in the state exposed to the outside on the rear side of the body (30).

The generator 50 provided in the state exposed to the outside on the rear side of the body 30 may be made of a low speed generator.

The rear wing 330 may be axially coupled to a rear end of the shaft 510 of the generator 50 including a low speed generator.

When the generator 50 provided in the state exposed to the outside on the rear side of the body 30 is made of a low speed generator,

The front rotating member 710 of the rotating member 70 may be made of a front bevel gear 711 that is axially coupled vertically to the rear end of the front shaft (320).

The rear rotating member 730 of the rotating member 70 may be formed of a rear bevel gear 731 which is axially coupled vertically to the front end of the rotating shaft 313 in a larger diameter than the front bevel gear 711. have.

The upper rotating member 750 of the rotating member 70 may be formed of first and second upper bevel gears 751 and 753.

The first upper bevel gear 751 is horizontally provided on the upper side of the front bevel gear 711 in a state in which the lower front side is engaged with the upper side of the front bevel gear 711, thereby applying rotational force from the front bevel gear 711. It can receive and rotate.

The second upper bevel gear 753 may be axially coupled with the first upper bevel gear 751 so as to be horizontally arranged in an upper direction of the first upper bevel gear 751.

The diameter of the second upper bevel gear 753 may be larger than the diameter of the first upper bevel gear 751.

The lower rear side of the second upper bevel gear 753 is rotated by receiving rotational force from the first upper bevel gear 751 in a state of being engaged with the upper side of the rear bevel gear 731. Is able to rotate in a different direction than the front bevel gear 711.

The lower rotating member 770 of the rotating member 70 may be composed of first and second lower bevel gears 771 and 773.

The first lower bevel gear 771 is horizontally provided to the lower side of the front bevel gear 711 in a state in which the upper front side is engaged with the lower side of the front bevel gear 711 to apply a rotational force from the front bevel gear 711. It can receive and rotate.

The second lower bevel gear 773 may be axially coupled to the first lower bevel gear 771 so as to be horizontally provided in a lower direction of the first lower bevel gear 771.

The diameter of the second lower bevel gear 773 may be larger than the diameter of the first lower bevel gear 771.

The upper rear side of the second lower bevel gear 773 is rotated by receiving a rotational force from the first lower bevel gear 771 in a state of being engaged with the lower side of the rear bevel gear 731. Is able to rotate in a different direction than the front bevel gear 711.

Meanwhile, when the rear side of the first upper bevel gear 751 and the rear side of the first lower bevel gear 771 come into contact with the front surface of the rear bevel gear 731, the first upper bevel gear 751 and the first 1below bevel gear 771 is difficult to rotate smoothly,

The front surface of the rear bevel gear 731 is the rear bevel so that the rear side of the first upper bevel gear 751 and the rear side of the first lower bevel gear 771 do not contact the front surface of the rear bevel gear 731. It is preferable to be recessed to a certain depth inside the gear 731.

When the front blade 310 rotates in a high speed in the forward direction by the wind,

The front shaft 320 and the front bevel gear 711 is rotated at high speed along the front blade 310 in the forward direction.

The first upper bevel gear 751 in a state where the lower front side is engaged with the upper side of the front bevel gear 711 is rotated in the reverse direction.

The first lower bevel gear 771 in a state where the upper front side is engaged with the lower side of the front bevel gear 711 is rotated in the forward direction.

The second upper bevel gear 753 rotates in a reverse direction along the first upper bevel gear 751.

The second lower bevel gear 773 rotates in the forward direction along the first lower bevel gear 771.

The rear bevel gear 731 in a state where the lower rear side of the second upper bevel gear 753 and the upper rear side of the second lower bevel gear 773 are engaged with each other on the upper side and the lower side bevel gear 731 is decelerated in the reverse direction.

The rotating shaft 313, the shaft 510 of the generator 50 made of a low speed generator is decelerated in the reverse direction along the rear bevel gear 731.

The rear wing 330 axially coupled to the rear end of the shaft 510 of the generator 50 is rotated in a reverse direction along the rear bevel gear 731 by wind.

Front and rear bevel gears (711, 731) forming the front and rear rotating members (710, 730) of the rotating member (70) of the first embodiment; First and second upper bevel gears 751 and 753 constituting the upper rotating member 750 of the rotating member 70 of the first embodiment; In particular, in the generator 50, on the rear side of the body 30 via the first and second lower bevel gears 771 and 773 forming the lower rotating member 770 of the rotating member 70 of the first embodiment. There is an advantage that the low-speed generator can be installed more easily in the state exposed to the outside.

3 is a partially enlarged perspective view schematically illustrating a universal joint shaft 325 constituting the front shaft 320 of FIG. 2.

Next, the front shaft 320 of the first embodiment horizontally provided on the inner front side of the body 30 is large, as shown in Figure 3, comprising a hollow shaft 321 and the front and rear movement shaft 323 It may be made of a universal joint shaft shaft 325.

The hollow shaft 321 may be provided with a universal joint 322 at the rear end.

The hollow shaft 321 may rotate in the forward direction along the front blade 310.

The front and rear movement shaft 323 may be inserted into the hollow shaft 321 so as to be movable back and forth.

The front wing 310 may be axially coupled to the front end of the front and rear movement shaft 323.

The front and rear moving shaft 323 may rotate in the forward direction along the front blade 310 to rotate the hollow shaft 321 in the rotation direction of the front blade 310.

Protruding portions 324 such as a quadrangle are formed on the outer circumference of the front and rear movement shaft 323 so that the front and rear movement shaft 323 rotates the hollow shaft 321 more smoothly in the rotation direction of the front blade 310. It is provided at equal intervals, it is preferable that the receiving groove 326, such as a rectangular shape for receiving the protrusion 324 in the inner circumference of the hollow shaft 321 is formed at a constant depth at equal intervals.

The protruding portion 324 may be provided at equal intervals while being extended in the longitudinal direction of the longitudinal movement shaft 323 and protruded upward in the outer circumference of the longitudinal movement shaft 323.

The front bevel gear 711 forming the front side rotating member 710 of the rotating member 70 of the first embodiment is axially coupled in a state perpendicular to the universal joint 322 provided at the rear end of the hollow shaft 321. The universal joint 722 may be vertically provided at the rear end of the rotating shaft 720 provided at the front end portion.

The universal joint shaft 325 is the front shaft 320 of the first embodiment horizontally provided on the inner front side of the body 30 includes the hollow shaft 321 and the front and rear movement shaft 323. The universal joint shaft 323 is moved back and forth in response to the minute longitudinal length change even when the longitudinal joint change in the longitudinal direction of the universal joint shaft shaft 325 occurs during the rotational movement from side to side along the body 30. The front shaft 320 made of the shaft shaft 325 has the advantage that there is no risk of being damaged during the process of rotating left and right along the body 30.

4 is a perspective view schematically illustrating a bidirectional wind power generator according to a second embodiment of the present invention, and FIG. 5 is a longitudinal cross-sectional view taken along line BB of FIG. 4.

As shown in FIGS. 4 and 5, the bidirectional wind power generator according to the second embodiment of the present invention includes a support 10, a body 30, a generator 50, and a rotating member 70, as in the first embodiment. It is done by

However, an inner rear side of the body 30 may have a rear shaft 340 horizontally coupled to the rear end of the rear wing 330.

The rotating shaft 314 may be horizontally provided on the inner front side of the body 30.

The front end of the rotating shaft 314 may be coupled to the rear end of the shaft 510 provided in the center of the generator 50 which is provided to the front side of the body 30 to the outside.

The generator 50 provided in the state exposed to the outside on the front side of the body 30 may be made of a high speed generator.

The front wing 310 may be axially coupled to a front end of the shaft 510 of the generator 50 including a high speed generator.

When the generator 50 provided in a state exposed to the outside on the front side of the body 30 is made of a high speed generator,

The front rotating member 710 of the rotating member 70 may be formed of a front bevel gear 711 that is axially coupled vertically to the rear end of the rotating shaft 314.

The rear rotating member 730 of the rotating member 70 is formed of a rear bevel gear 731 which is axially coupled vertically to the front end of the rear shaft 340 in a larger diameter than the front bevel gear 710. Can be.

The upper rotating member 750 of the rotating member 70 may be formed of first and second upper bevel gears 751 and 753.

The first upper bevel gear 751 is horizontally provided on the upper side of the front bevel gear 711 in a state in which the lower front side is engaged with the upper side of the front bevel gear 711, thereby applying rotational force from the front bevel gear 711. It can receive and rotate.

The second upper bevel gear 753 may be axially coupled with the first upper bevel gear 751 so as to be horizontally arranged in an upper direction of the first upper bevel gear 751.

The diameter of the second upper bevel gear 753 may be larger than the diameter of the first upper bevel gear 751.

The lower rear side of the second upper bevel gear 753 is rotated by receiving rotational force from the first upper bevel gear 751 in a state of being engaged with the upper side of the rear bevel gear 731. Is able to rotate in a different direction than the front bevel gear 711.

The lower rotating member 770 of the rotating member 70 may be composed of first and second lower bevel gears 771 and 773.

The first lower bevel gear 771 is horizontally provided to the lower side of the front bevel gear 711 in a state in which the upper front side is engaged with the lower side of the front bevel gear 711 to apply a rotational force from the front bevel gear 711. It can receive and rotate.

The second lower bevel gear 773 may be axially coupled with the first lower bevel gear 771 so as to be horizontally provided in a lower direction of the first lower bevel gear 771.

The diameter of the second lower bevel gear 773 may be larger than the diameter of the first lower bevel gear 771.

The upper rear side of the second lower bevel gear 773 is rotated by receiving a rotational force from the first lower bevel gear 771 in a state of being engaged with the lower side of the rear bevel gear 731. Is able to rotate in a different direction than the front bevel gear 711.

When the front blade 310 rotates in a high speed in the forward direction by the wind,

The shaft 510, the rotation shaft 314, and the front bevel gear 711 of the generator 50 are rotated at high speed along the front blade 310 in the forward direction.

The first upper bevel gear 751 in a state where the lower front side is engaged with the upper side of the front bevel gear 711 is rotated in the reverse direction.

The first lower bevel gear 771 in a state where the upper front side is engaged with the lower side of the front bevel gear 711 is rotated in the forward direction.

The second upper bevel gear 753 rotates in a reverse direction along the first upper bevel gear 751.

The second lower bevel gear 773 rotates in the forward direction along the first lower bevel gear 771.

The rear bevel gear 731 in a state where the lower rear side of the second upper bevel gear 753 and the upper rear side of the second lower bevel gear 773 are engaged with each other on the upper side and the lower side bevel gear 731 is decelerated in the reverse direction.

The rear shaft 340 is rotated in a reverse direction along the rear bevel gear 731.

The rear wing 330 coupled to the rear end of the rear shaft 340 is rotated in a reverse direction along the rear bevel gear 731 by wind.

Front and rear bevel gears 711 and 731 forming the front and rear rotating members 710 and 730 of the rotating member 70 of the second embodiment; First and second upper bevel gears 751 and 753 constituting the upper rotating member 750 of the rotating member 70 of the second embodiment; The first and second lower bevel gears 771 and 773 constituting the lower rotating member 770 of the rotating member 70 of the second embodiment, in particular, the high speed of the generator 50 The advantage is that the generator can be installed more easily.

FIG. 6 is an exploded perspective view schematically illustrating the universal joint shaft 345 constituting the rear axis 340 of FIG. 5.

Next, the rear shaft 340 of the second embodiment horizontally provided on the inner rear side of the body 30 is large, as shown in Figure 6, comprises a hollow shaft 341 and the front and rear movement shaft 343 It may be made of a universal joint shaft shaft 345.

The hollow shaft 341 may be provided with a universal joint 342 at the front end portion.

The hollow shaft 341 may rotate in a reverse direction along the rear wing 330.

The front and rear movement shaft 343 may be inserted into the hollow shaft 341 so as to be movable back and forth.

The rear wing 330 may be axially coupled to the rear end of the front and rear moving shaft 343.

The front and rear movement shaft 343 may rotate in the reverse direction along the rear wing 330 to rotate the hollow shaft 341 in the rotational direction of the rear wing 330.

Protruding portions 344, such as a quadrangle, are formed on the outer circumference of the front and rear movement shaft 343 so that the front and rear movement shaft 343 can rotate the hollow shaft 341 in the rotational direction of the rear wing 330 more smoothly. It is provided at equal intervals, it is preferable that the receiving grooves (not shown), such as a rectangular shape for accommodating the protrusion 344 at the inner circumference of the hollow shaft 341 is formed at regular intervals at a constant depth.

The protruding portion 344 may be provided at equal intervals while extending in the longitudinal direction of the front and rear movement shaft 343 and protruding upward in the outer circumference of the front and rear movement shaft 343.

The rear bevel gear 731 forming the rear rotating member 730 of the rotating member 70 of the second embodiment is axially coupled to the universal joint 342 provided at the front end of the hollow shaft 341 orthogonally. The universal joint 742 may be vertically provided at the front end of the rotation shaft 740 provided at the rear end.

The rear shaft 340 of the second embodiment horizontally provided on the inner rear side of the body 30 includes the universal joint shaft shaft 345 including the hollow shaft 341 and the front and rear movement shaft 343. When the universal joint shaft shaft 345 rotates from side to side along the body 30, even if there is a slight change in front and rear length of the universal joint shaft shaft 345, the front and rear movement shaft 343 is fine. Since the rear shaft 340 made of the universal joint shaft shaft 345 is rotated along the body 30 from side to side in response to the change in length, there is an advantage that there is no risk of being damaged. .

Next, as shown in FIGS. 1, 2, 4 and 5, the outer periphery of the generator 50 of the first and second embodiments extends in the longitudinal direction of the generator 50 and protrudes upwards. The heat dissipation fins 530 may be provided at equal intervals.

As the generator 50 extends in the longitudinal direction of the generator 50 in the outer periphery of the generator 50 and the heat dissipation fins 530 protruding upward are provided at equal intervals, the generator 50 generates electric energy. There is an advantage that the high heat generated in the generator 50 during the process can be radiated to the outside more smoothly.

The present invention configured as described above is the first and second implementations provided in the interior of the body 30 when the front wing 310 and the rear wing 330 rotate in different directions at different speeds with respect to the same wind. For example, through the rotating member 70, the generator 50 may receive electric power of the front wing 310 and the rear wing 330 which rotates in different directions at different speeds to generate electric energy more easily. In addition, in particular, there is an advantage that can be provided inside the body 30 of the generator 50 of various kinds.

10; Prop, 30; Body Part,
301, 303, 313, 314, 720, 740; Axis of rotation 310; Front Wing,
320; Front axle, 321, 341; Hollow Shaft,
322, 342, 722, 742; Universal joints, 323, 343; Forward and backward axis,
324, 344; Protrusions, 325, 345; Universal joint shaft,
326; Receiving groove, 340; Rear Axle,
50; Generator, 510; shaft,
530; Heat sink, 70; Rotating member,
710; Front rotating member, 711; Front bevel gear,
730; Rear bevel gear, 731; Rear bevel gear,
750; Upper rotating member, 751; First upper bevel gear,
753; Second upper bevel gear, 770; Lower rotating member,
771; First lower bevel gear, 773; Second lower bevel gear.

Claims (6)

A support 10;
A body 30 having a lower portion axially coupled to the upper portion of the support 10 and having front and rear blades 310 and rear wings 330 respectively rotating in different directions with respect to the same wind in front and rear;
Rotation force from the front wing 310 and the rear wing 330 which rotates in different directions in a state provided between the front wing 310 and the rear wing 330 respectively provided in front and rear of the body 30 A generator 50 which receives and generates electric energy;
The front and rear rotary members 710 and 730 having vertical diameters provided at predetermined intervals inside the body 30 and rotating in different directions along the front wing 310 and the rear wing 330, respectively; The front and rear rotating members 710 are rotated by receiving rotational force from the front rotating member 710 in a state where the upper and rear rotating members 710 and 730 are horizontally provided at a predetermined interval in the vertical direction, respectively. The front side rotating member 750 having different diameters for rotating the 730 in different directions, and the front side rotating members at horizontal intervals at regular intervals in the vertical direction below the front and rear rotating members 710 and 730, respectively. Rotating portion composed of lower rotating members 770 having different diameters for rotating the front and rear rotating members 710 and 730 in different directions by receiving rotational force from the member 710. It comprises including,; 70
The front shaft 320, the front blade 310 is axially coupled to the front end portion is horizontally provided on the inner front side of the body 30,
On the inner rear side of the body 30 is provided with a rotating shaft 313 horizontally coupled to the rear end of the front end of the shaft 510 of the generator 50 exposed to the outside,
The generator 50 is composed of a low speed generator, the rear wing 330 is coupled to the rear end of the shaft 510 of the generator 50,
The front rotating member 710 of the rotating member 70 is made of a front bevel gear 711 that is axially coupled vertically to the rear end of the front shaft 320,
The rear rotating member 730 is made of a rear bevel gear 731 which is axially coupled vertically to the front end of the rotating shaft 313 in a larger diameter than the front bevel gear 711,
The upper rotating member 750 is horizontally provided on the upper side of the front bevel gear 711 in a state where the lower front side is engaged with the upper side of the front bevel gear 711 to receive the rotational force from the front bevel gear 711. The first upper bevel gear 751 is axially coupled with the first upper bevel gear 751 to be horizontally provided in the upper direction of the first upper bevel gear 751 and the first upper bevel gear 751. The rear bevel gear 731 is rotated by receiving a rotational force from the first upper bevel gear 751 in a state where the diameter is larger and the lower rear side is engaged with the upper side of the rear bevel gear 731. And a second upper bevel gear 753 to rotate in a direction different from that of 711,
The lower rotating member 770 is horizontally provided on the lower side of the front bevel gear 711 while the upper front side is engaged with the lower side of the front bevel gear 711 to receive the rotational force from the front bevel gear 711. The first lower bevel gear 771 and the first lower bevel gear 771 are axially coupled to the first lower bevel gear 771 so as to be horizontally arranged in a lower direction of the first lower bevel gear 771. The rear bevel gear 731 is rotated by receiving a rotational force from the first lower bevel gear 771 in a state where the diameter is larger and the upper rear side is engaged with the lower side of the rear bevel gear 731. 711) and a second lower bevel gear 773 to rotate in a different direction.
A support 10;
A body 30 having a lower portion axially coupled to the upper portion of the support 10 and having front and rear blades 310 and rear wings 330 respectively rotating in different directions with respect to the same wind in front and rear;
Rotation force from the front wing 310 and the rear wing 330 which rotates in different directions in a state provided between the front wing 310 and the rear wing 330 respectively provided in front and rear of the body 30 A generator 50 which receives and generates electric energy;
The front and rear rotary members 710 and 730 having vertical diameters provided at predetermined intervals inside the body 30 and rotating in different directions along the front wing 310 and the rear wing 330, respectively; The front and rear rotating members 710 are rotated by receiving rotational force from the front rotating member 710 in a state where the upper and rear rotating members 710 and 730 are horizontally provided at a predetermined interval in the vertical direction, respectively. The front side rotating member 750 having different diameters for rotating the 730 in different directions, and the front side rotating members at horizontal intervals at regular intervals in the vertical direction below the front and rear rotating members 710 and 730, respectively. Rotating portion composed of lower rotating members 770 having different diameters for rotating the front and rear rotating members 710 and 730 in different directions by receiving rotational force from the member 710. It comprises including,; 70
The front shaft 320, the front blade 310 is axially coupled to the front end portion is horizontally provided on the inner front side of the body 30,
The front shaft 320 is provided with a universal joint 322 at the rear end, the hollow shaft 321 to rotate along the front blade 310;
The front shaft 310 is inserted into the hollow shaft 321 so as to be movable back and forth, and the front blade 310 is axially coupled to a front end portion, and rotates along the front blade 310 to rotate the hollow shaft 321 to the front blade. It consists of a universal joint shaft 325, including; the front and rear movement shaft 323 to rotate in the rotation direction of (310),
The front rotating member 710 of the rotating member 70 has a universal joint 722 which is axially coupled to the universal joint 322 provided at the rear end of the hollow shaft 321 is provided with a rotary shaft 720 Two-way wind power generator, characterized in that it is vertically provided at the rear end.
A support 10;
A body 30 having a lower portion axially coupled to the upper portion of the support 10 and having front and rear blades 310 and rear wings 330 respectively rotating in different directions with respect to the same wind in front and rear;
Rotation force from the front wing 310 and the rear wing 330 which rotates in different directions in a state provided between the front wing 310 and the rear wing 330 respectively provided in front and rear of the body 30 A generator 50 which receives and generates electric energy;
The front and rear rotary members 710 and 730 having vertical diameters provided at predetermined intervals inside the body 30 and rotating in different directions along the front wing 310 and the rear wing 330, respectively; The front and rear rotating members 710 are rotated by receiving rotational force from the front rotating member 710 in a state where the upper and rear rotating members 710 and 730 are horizontally provided at a predetermined interval in the vertical direction, respectively. The front side rotating member 750 having different diameters for rotating the 730 in different directions, and the front side rotating members at horizontal intervals at regular intervals in the vertical direction below the front and rear rotating members 710 and 730, respectively. Rotating portion composed of lower rotating members 770 having different diameters for rotating the front and rear rotating members 710 and 730 in different directions by rotating the rotary force from the member 710. It comprises including,; 70
On the inner rear side of the body 30 is a rear shaft 340, the rear wing 330 is axially coupled to the rear end is horizontally equipped,
A rotating shaft 314 having a rear end coupled to a front end of the shaft 510 of the generator 50 in a state exposed to the outside is horizontally provided on the inner front side of the body 30,
The generator 50 is made of a high speed generator, the front blade 310 is axially coupled to the front end of the shaft 510 of the generator 50,
The front rotating member 710 of the rotating member 70 is made of a front bevel gear 711 that is axially coupled to the rear end of the rotary shaft 314,
The rear rotating member 730 is made of a rear bevel gear 731 is axially coupled to the front end of the rear shaft 340 in a larger diameter than the front bevel gear 711,
The upper rotating member 750 is horizontally provided on the upper side of the front bevel gear 711 in a state where the lower front side is engaged with the upper side of the front bevel gear 711 to receive the rotational force from the front bevel gear 711. The first upper bevel gear 751 is axially coupled with the first upper bevel gear 751 to be horizontally provided in the upper direction of the first upper bevel gear 751 and the first upper bevel gear 751. The rear bevel gear 731 is rotated by receiving a rotational force from the first upper bevel gear 751 in a state where the diameter is larger and the lower rear side is engaged with the upper side of the rear bevel gear 731. And a second upper bevel gear 753 to rotate in a direction different from that of 711,
The lower rotating member 770 is horizontally provided on the lower side of the front bevel gear 711 while the upper front side is engaged with the lower side of the front bevel gear 711 to receive the rotational force from the front bevel gear 711. The first lower bevel gear 771 and the first lower bevel gear 771 are axially coupled to the first lower bevel gear 771 so as to be horizontally arranged in a lower direction of the first lower bevel gear 771. The rear bevel gear 731 is rotated by receiving a rotational force from the first lower bevel gear 771 in a state where the diameter is larger and the upper rear side is engaged with the lower side of the rear bevel gear 731. 711) and a second lower bevel gear 773 to rotate in a different direction.
A support 10;
A body 30 having a lower portion axially coupled to the upper portion of the support 10 and having front and rear blades 310 and rear wings 330 respectively rotating in different directions with respect to the same wind in front and rear;
Rotation force from the front wing 310 and the rear wing 330 which rotates in different directions in a state provided between the front wing 310 and the rear wing 330 respectively provided in front and rear of the body 30 A generator 50 which receives and generates electric energy;
The front and rear rotary members 710 and 730 having vertical diameters provided at predetermined intervals inside the body 30 and rotating in different directions along the front wing 310 and the rear wing 330, respectively; The front and rear rotating members 710 are rotated by receiving rotational force from the front rotating member 710 in a state where the upper and rear rotating members 710 and 730 are horizontally provided at a predetermined interval in the vertical direction, respectively. The front side rotating member 750 having different diameters for rotating the 730 in different directions, and the front side rotating members at horizontal intervals at regular intervals in the vertical direction below the front and rear rotating members 710 and 730, respectively. Rotating portion composed of lower rotating members 770 having different diameters for rotating the front and rear rotating members 710 and 730 in different directions by receiving rotational force from the member 710. It comprises including,; 70
On the inner rear side of the body 30 is a rear shaft 340, the rear wing 330 is axially coupled to the rear end is horizontally equipped,
The rear shaft 340 is provided with a universal joint 342 at the front end portion, and the hollow shaft 341 rotates along the rear wing 330;
The rear blade 330 is axially coupled to the inside of the hollow shaft 321, and the rear wing 330 is axially coupled to the rear end thereof, and rotates along the rear wing 330 to rotate the hollow shaft 341 to the rear wing. Consists of a universal joint shaft 345 comprising a; front and rear movement shaft 343 for rotating in the rotation direction of 330,
The rear rotating member 730 of the rotating member 70 is a rotary shaft 740 having a universal joint 742 which is axially coupled to the universal joint 342 provided at the front end of the hollow shaft 341. Two-way wind power generator, characterized in that it is vertically provided at the front end.
The method according to any one of claims 1 to 4,
The outer periphery of the generator 50 is formed in the longitudinal direction of the generator 50, the heat radiation fins 530 protruding in the upper direction is characterized in that provided with equal intervals. delete

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