KR20100009433A - Water and wind generator - Google Patents

Abstract

PURPOSE: A water and wind generating apparatus is provided to improve the torque of a rotation shaft by supplying the hydraulic power or the wind force in only one way based on the center of a rotation shaft through a hydraulic unit and by positioning the inner front end of a lower guide part and a rotation shaft of a body unit in the same line. CONSTITUTION: A water and wind generating apparatus is composed of a body unit(1), an inlet unit(2), an outlet part(3), and a support unit(4). The body unit comprises a rotary shaft(11), plural blades(12), and a driving gear(13). The blades are formed outside the rotation shaft. The driving gear is connected on the rotation shaft. The inlet unit has a guide unit(21). The guide unit has a tapered slope unit so that the water and wind is flowed in to one side of the body unit. A lower guide unit near the body unit is positioned in the line same as the center shaft of the rotation shaft. The outlet part has an opening. The water and wind flowed though the inlet unit is flowed out through the opening toward the other side of the body unit. A bearing(41) is formed in the center of the support unit and is rotatably connected to a post(17). The body unit is rotated according to the water and wind.

Description

Water and wind generator

1 is a perspective view of the present invention

2 is an exploded perspective view of the present invention

3 is a cross-sectional view of the present invention

Figure 4 is a front view of the reverse rotation prevention unit is coupled to the present invention

Figure 5 is a side view of the rotary shaft and the generator and the auxiliary generator coupled state

Figure 6 is a side view of the on-off valve having a peristaltic opening and closing method

7 is a side view of the on-off valve having the individual opening and closing method

8 is a front view of a brake device using a disc brake

9 is a front view of the brake device using a dual server brake

10 is a perspective view of a state in which a plurality of rotary shafts are coupled

11 is an exploded perspective view of a state in which a plurality of rotary shafts are coupled;

12 is a cross-sectional view of a state in which a plurality of rotary shafts are coupled

13 is a perspective view of a state installed in the upright structure

14 is a perspective view of a state installed in the apartment factory structure

<Brief description of the main parts of the drawing>

A: Water generator 1: Body part

2: inlet 3: outlet

4: supporting part 11: rotating shaft

12: Wing part 13: Drive gear

14: main generator gear 15: auxiliary generator gear

16: Belt 17: post

18: Reverse rotation prevention unit 21: Guide part

22: support 23: open / close valve

100: main generator 101: auxiliary generator

102: wind direction sensor 103: rotational speed sensor

104: valve detection sensor 105: wind speed detection sensor

111: brake panel 112: wind panel

113: piston 114: lining

115: brake cylinder 116: drum

161: idle roller 171: support frame

172: rolling part F: structure

The present invention relates to a wind turbine generator.

More specifically, the present invention relates to a wind turbine generator which generates electricity by using external wind power so that predetermined energy can be supplied.

In general, since a wind power generator is to obtain rotational power using natural wind, its performance depends on the structure of the windmill, and various types of windmills have been disclosed.

The typical windmill is characterized in that it is proposed to obtain a rotational power by having a blower having a plurality of propeller-shaped rotary wings on the top of the rotary shaft.

Such a wind turbine generator consists of a stationary rotary shaft through which the blades are three to four flat blades from the rotary shaft.

Accordingly, there is a problem in that the power source obtained as compared to the device and the temporary equipment is extremely weak and the blade is easily broken or cut.

Hydroelectric generators, on the other hand, use a method of generating electricity by using 'potential energy' of high water. In other words, when the water wheel is rotated by the force of falling water, the generator attached to the shaft of the water wheel rotates, and electricity is generated.

The advantages of such hydroelectric power generation are to generate power using natural water potential energy, so as not to generate soot as in thermal power generation, to solve the problems caused by environmental pollution.

In addition, it can continuously generate energy, the operating cost of the power generation device is low and the time required for power generation is short.

However, in the case of the hydroelectric generator, it takes a lot of money to construct a dam that holds water, and there is a problem such as destroying the ecosystem because it has to be freshwater over a large area.

In addition, there is a disadvantage in that the amount of energy varies depending on the amount of water together with the restriction on the proper place to build the dam.

On the other hand, the conventional wind generator and the hydroelectric generator as described above, in addition to the various problems, the wind or hydraulic power applied to the rotary blade is not transmitted only in the direction in which the rotary blade is rotated, but the same in both directions around the rotary shaft There is this.

As the wind or hydraulic power is transmitted in the same direction in both directions as described above, the wind or hydraulic power is transmitted to the rotary wing on one side about the rotary shaft, or the rotary blade formed on the other side around the rotary shaft. Or there is a problem that the hydraulic power is transmitted to reduce the rotational speed of the rotary shaft according to the wind power and hydraulic transmission.

Therefore, in the case of the wind turbine and the hydroelectric generator proposed as described above, the wind or hydraulic power should be applied only in the direction in which the rotary shaft is rotated, so that a more desirable energy source can be supplied, but the wind or hydraulic power is substantially up to the opposite direction of the rotary shaft. There is a need to study the technology to block the wind and hydraulic power is transmitted to the opposite direction of the rotation shaft.

In addition, the wind power generator and the hydroelectric generator are transmitted through a direction in which the wind turbine or the hydraulic inflow portion and the upper and lower surfaces of the body portion for supporting the rotary shaft are hermetically sealed and rotated about the rotary shaft. Since the pressure of the wind or hydraulic pressure collides with the lower or upper surface of the body part, the circulation of the wind or hydraulic pressure is not desired, thereby reducing the rotational force of the rotating shaft.

In addition, using the same rotation principle can provide a lot of effects at a low cost when using a wind power generator or a hydro-power generator in combination, but in reality, the generator that can combine the wind power and hydraulic power is still under study.

An object of the present invention is formed by a support frame having a post to the lower side of the body portion and the body portion is coupled to the inlet and the rotation shaft is introduced into the receiving portion, the post is coupled to the support portion, the rotating shaft of the body portion According to the present invention provides a wind generator configured to be able to supply the energy source of the generator according to the rotational force through.

Another object of the present invention is formed by the guide portion formed in the upper and lower portions of the inlet tapered inward direction and the guide portion is formed with a plurality of on-off valves, the on-off valve is any angle depending on the hydraulic or wind power It is another object of the present invention to be formed so as to be openable.

Another object of the present invention is formed so that the rotary shaft of the inner end of the guide portion and the body portion formed in the lower portion of the inlet is located on the same line so that the hydraulic power or wind power through the inlet is supplied only in one direction with respect to the center of the rotation shaft. To provide.

Another object of the present invention is a bearing formed in the center of the support portion and the post formed to the lower side of the support frame is rotatably coupled, the wind direction sensor is coupled to the upper side of the body portion to detect the direction of the wind direction the body It is to provide a wind generator that is rotated along the direction in which the additional wind is blowing.

Hereinafter, the components of the present invention will be described.

The wind turbine generator of the present invention can be easily supplied with an energy source through a generator by receiving an external hydro or wind power such as a typhoon or a strong wind flowing from the outside.

Most of the generators used in the prior art mainly include wind generators using wind and hydroelectric generators using water.

The wind power generator of the present invention is characterized in that to generate power by using wind power to rotate the windmill using natural wind and to generate power by using the rotating power of the windmill rotated.

The basic structure of the wind turbine is provided with a rotary shaft in the vertical direction on the support provided in the tower shape and at the top of the rotary shaft having a windmill having a plurality of rotor blades rotated by the wind pressure of the natural wind and at the same time The lower part is to have a power generation means for generating power by the rotational force of the rotary shaft.

The present invention is a wind generator (A) for generating power by using hydraulic power and wind power, the wind generator (A) is a rotary shaft 11 is formed inward and a plurality of the outer shaft 11 The wing 12 is formed and the drive gear 13 is coupled to the shaft of the rotary shaft 11, the main generator 100 and the main generator gear 14, belt 16 and gear belt A body portion (1) coupled to a power connection device such as a hydraulic power; Guide portion 21 having a tapered inclined portion is formed so that the wind is introduced into one side of the body portion 1, the lower guide portion 21 of the adjacent region of the body portion 1 is a rotary shaft 11 An inlet portion (2) formed to be colinear with the central axis of the inlet; An outlet portion 3 having an opening portion so that the water flowing through the inlet portion 2 can flow out to the other side of the body portion 1; The support frame 171 is formed below the body portion 1, the post 17 is formed below the support frame 171, and the supporting portion 4 is formed below the post 17. In the center of the support portion 4, a bearing 41 and a rotatable fixing device are formed so as to be rotatably coupled to the post 17 so that the body portion 1 is rotatably formed according to the wind. do.

In addition, in the wind generator A to generate power by using hydraulic power and wind as described above, a guide portion 21 having inclined portions tapered inward in each of the upper and lower portions so that the wind is introduced therein is formed. The support part 22 is connected to both sides of the guide part 21, but the guide part 21 has an inlet part 2 formed with a plurality of open / close valves 23 that can be opened and closed according to the wind. .

In addition, a plurality of auxiliary parts in the inner region of the belt 16 for receiving the drive gear 13 and the main generator gear 14 of the main generator 100 coupled to the axis of the rotary shaft 11 of the body portion (1). The generator 101 and the auxiliary generator gear 15 and the power transmission device that is built up is formed.

In addition, a plurality of rolling parts 172 are formed at the edges of the post 17 and the support frame 171 which are formed under the supporting frame 171 to be implemented in one direction from the inside of the supporting part 4. Is rotatably formed, characterized in that the rolling portion 172 and the support portion 4 is engaged.

In addition, the opening and closing valve 23 formed in the guide portion 21 is adjusted at an arbitrary angle and is opened and closed in accordance with the wind power flowing through the inlet portion 2 of the wind generator A.

In addition, the brake control device is formed on one side of the rotary shaft 11 to control the rotational speed of the rotary shaft 11 of the body portion 1, the braking control device is one side of the rotary shaft (11). The brake panel 111 is formed therein, and the wind wave plate 112 is formed on the front side of the inflow portion 2, and the piston 113 on one side of the wind wave plate 112 is pressed by wind or hydraulic power so that the lining 114 is formed. The brake cylinder 115 connected through) pressurizes the brake panel 111 to control the rotation speed of the rotary shaft 11, and the circular drum 116 is connected to one side of the rotary shaft 11. Lining 114 is coupled to the inner circumference of the drum 116 so that the lining 114 presses the drum 116 according to the centrifugal force of the rotary shaft 11 to increase the rotational speed of the rotary shaft 11. It is characterized by the enforcement.

In addition, a plurality of idle rollers 161 are formed on the outer periphery of the belt 16 to which the drive gear 13, the main generator gear 14, and the auxiliary generator gear 15 are connected. By increasing the tension of the belt 16 is characterized in that.

In addition, the reverse rotation prevention unit 18 is formed on one side of the rotation shaft 11 to prevent the rotation shaft 11 from being reversely rotated.

Wind direction detection sensor 102 is coupled to the upper portion of the body portion 1 of the wind turbine generator A is carried out as described above to adjust the direction of the body portion (1).

In addition, the rotational speed sensor 103 is coupled to the outer periphery of the belt 16 detects the rotational speed of the rotary shaft 11 and the rotational speed of the belt 16 according to the inflow of water. In addition, the valve detection sensor 104 is coupled to the outside of the open / close valve 23 to control the open / close of the open / close valve 23.

In addition, the wind speed and the pressure sensor 105 is coupled to the front surface of the piston 113 to press the brake panel 111 through the brake cylinder 115.

In addition, another post 17 is connected between the inlet part 2 and the support part 4 so that the body part 1 and the inlet part 2 can be safely rotated using the support part 4. .

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

1 shows a perspective view of the present invention.

2 is an exploded perspective view of the present invention.

Figure 3 is a cross-sectional view of the present invention, respectively, as shown in the wind generator (A) is the inlet (2) through which the wind or hydraulic power, and the wind flowing through the inlet (2) A body portion (1) having a rotary shaft (11) formed at an outer circumference and a drive gear (13) coupled to the shaft of the rotary shaft (11) rotatably by hydraulic power; An outlet portion 3 formed with an opening portion so that the wind direction flowing through the inlet portion 2 and the body portion 1 flows out to the other side of the body portion 1 and formed below the body portion 1; It is formed of a support portion 4 having a bearing 41 rotatably coupled with the post 17 at the lower side of the support frame 171.

Another post 17 is connected between the inlet part 2 and the support part 4 formed as described above, so that the wind generator A more reliably centers the cylinder through the bearing 41 and the driving means. Rotatably formed.

In addition, the wing portion 12 is formed in an arc shape and a shape that can receive as much of the wind force as possible to form a maximum to absorb the wind or hydraulic power flowing through the inlet (2).

Accordingly, the rotation speed of the rotary shaft 11 can be increased.

The inlet portion 2 of the wind turbine generator A, which is implemented as described above, has an upper guide portion 21 and a lower guide portion 21 having inclined portions tapered inwardly in upper and lower portions, respectively, and the guide portion ( The support part 22 is connected to both sides of the 21, and the support part 22 may be provided with an opening / closing valve 23 formed in the upper guide 21 and the lower guide 21 as necessary.

In addition, the upper guide portion 21 formed in the inlet portion 2 is formed in a tapered shape inclined downward from the front region to the rear region, and the lower guide portion 21 is tapered in an upward slope from the front region to the rear region. The front end portion of the lower guide portion 21 to be coupled to the body portion 1 is formed to be on the same line as the central axis of the rotary shaft 11.

Accordingly, the amount of wind blown in through the inlet 2 can be introduced by the width of the front region and flows into the front region along the tapered slopes of the upper and lower guide portions 21 of the inlet 2. The amount can be delivered to the inside of the body portion 1 can introduce a large amount of wind.

In addition, by placing the center axis of the lower guide portion 21 and the rotary shaft 11 on the same line, the water wind is transmitted only to the wing portion 12 located above the central shaft of the rotary shaft 11.

Accordingly, the water wind is transmitted to only one side of the rotary shaft 11 to maximize the rotational force of the rotary shaft 11.

As described above, the wind is transmitted only to one side wing portion 12 of the rotary shaft 11, thereby solving the problem of transmitting the whole wing portion 12 of the rotary shaft 11 as in the related art.

That is, the wind is evenly transmitted in the reverse direction opposite to the forward direction in which the rotary shaft 11 rotates, thereby reducing the rotational force when friction with the wing portion 12 located in the reverse direction, and thus the rotational speed of the rotary shaft 11 is increased. In the present invention, it is possible to increase the rotational speed of the rotary shaft 11 by transmitting wind to one side of the wing portion 12 to be reduced.

In addition, the body 1 of the wind turbine generator A formed as described above has a support frame 171 formed below the rotary shaft 11 so that wind power or hydraulic power introduced through the inlet portion 2 is rotated. It is configured to prevent the pressure contained in the inner surface of the wing portion 12 formed in the arcuate shape to collide with the lower surface of the body portion 1 while rotating through the wing portion 12 of the (11).

On the other hand, the support frame 171 is provided below the body portion 1, the post 17 is installed below the support frame 171, the end of the post 17 is the supporting portion 4 It is coupled to the linkage means such as a bearing 41 formed in the center of the).

In addition, a plurality of rolling parts 172 are formed at the edge of the support frame 171 so as to be rotatable in one direction from the inside of the support part 4.

The supporting portion 4 coupled to the rolling portion 172 formed as described above is configured to be more hermetically engaged to prevent the body portion 1 and the post 17 from being separated from the outside even when rotating.

As described above, the wind direction detection sensor 102 is coupled to the upper side of the body part 1 so that the body part 1 may be rotatable in an arbitrary direction according to the wind direction, and thus the wind may be winded through the wind direction detection sensor 102. After the blowing direction is detected, the body 1, the post 17, and the support frame 171 are rotated about the bearing 41 along the wind blowing direction. The rolling part 172 is coupled to the edge of the support frame 171.

In addition, the support frame 171 is formed of a plurality of horizontal bars and the post 17 is coupled to the lower portion of the horizontal bar and the vertical bar 173 is formed on both sides of the upper portion of the horizontal bar.

The end of the vertical bar 173 formed as described above is formed to support both sides of the rotary shaft 11 to support the load of the rotary shaft 11.

As shown in FIG. 5, a side view of a state in which the rotary shaft 11, the main generator 100, the auxiliary generator 101, and the power transmission device are coupled to each other is illustrated. On the shaft of the rotary shaft 11, the drive gear 13 is coupled, and in the inner region of the belt 16 accommodating the drive gear 13 and the main generator 100, a plurality of auxiliary generators 101 and auxiliary power generation that are built up. A plurality of gears 15 and a power transmission device are formed.

A plurality of idle rollers 161 are formed on the outer periphery of the belt 16 formed as described above to enhance the tension of the belt 16 by the idle rollers 161.

In addition, the idle roller 161 is formed as described above is between the drive gear 13 and the main generator gear 14, between the drive gear 13 and the auxiliary generator gear 15, the main generator gear 14 and auxiliary power generation. Between the gear 15, and between the auxiliary generator gear 15 and the auxiliary generator gear 15, respectively.

Accordingly, the main generator 100 and the sub-generator 101 may operate smoothly according to the amount of hydraulic power or wind power delivered to the wind generator A. FIG.

The outer periphery of the belt 16 is coupled as described above is coupled to the speed sensor to detect the rotational speed of the belt 16 is rotated in conjunction with the rotational speed of the rotary shaft 11 according to the inflow of wind or hydraulic power. .

Figure 6 shows a side view of the on-off valve having a peristaltic opening and closing method.

FIG. 7 is a side view of the on / off valve having an individual opening / closing method, and as shown in the drawing, the upper guide part 21 and the lower part formed on the inlet part 2 of the wind turbine generator A and the lower part are tapered. The guide part 21 is formed with a plurality of on-off valve 23.

Opening and closing valve 23 formed as described above can be implemented in a manner that is opened and closed individually and interlocked as a whole.

In the interlocking opening and closing method of the singer electronics, the feldspar lamp is coupled to one side, and the link is coupled to the other side, so that the opening / closing valve 23 is rotated and opened around the feldspar lamp according to the wind direction flowing through the inlet 2. When the on-off valve 23 is opened along the link, an elastic spring formed below the connection member connected to the plurality of on-off valves 23 is expanded, and another on-off valve 23 is simultaneously opened and the elastic spring is opened. In this contraction, the on-off valve 23 is formed to be restored to its original state.

In addition, the valve detecting sensor 104 is coupled between the elastic spring and the connecting member to open and close the on / off valve 23.

In addition, the latter individual opening and closing method is that each of the opening and closing valve 23, the hinge portion is formed on one side and the elastic spring is formed on the other side, the opening and closing valve 23 to the upper guide portion 21 and the lower guide portion 21 Each is formed, the opening and closing valve 23 is opened and closed in accordance with the wind direction flowing through the inlet (2).

Opening and closing method of the valve as described above is not limited to the elastic spring can be carried out through a variety of coupling means.

In addition, the opening and closing angle of the valve is adjusted to any angle according to the wind or hydraulic power.

8 is a front view of a brake device using a disc brake.

9 is a front view of the brake device using the dual server brake.

As shown in FIG. 8 and FIG. 9, a brake device is coupled to the rotary shaft 11 to control the rotational speed of the rotary shaft 11 according to the rotational speed of the rotary shaft 11.

The brake device of the rotary shaft 11 may be implemented as a disc brake and a dual server brake (internal extension type).

The electronic disk brake is formed in the front of the inlet portion 2, the wind wave plate 112, the wind wave plate 112 is provided rotatably at any angle by the wind or hydraulic power and the wind wave plate ( On the lower side of 112, a master cylinder having oil and a piston 113 which is pressurized inwards is formed, and a lining 114 is connected to one side of the master cylinder, and the end of the lining 114 has a brake cylinder ( 115 is formed to be adjacently coupled to the brake panel formed on the shaft of the rotary shaft 11 to press the piston 113 in accordance with the rotation of the wind panel 112, the brake cylinder 115 is the brake panel By pressing 111, the rotation speed of the rotary shaft 11 is interrupted.

In addition, the wind direction sensor 102 is coupled to the front surface of the piston 113 is pressed by the brake panel 111 through the brake cylinder 115 can be controlled to the rotational speed of the rotary shaft (11).

The latter dual server brake has a circular drum 116 is connected to one side of the rotary shaft 11 and the lining 114 is coupled to the inner circumference of the drum 116 to the centrifugal force of the rotary shaft 11. Accordingly, the lining 114 is rotated to expand outward to pressurize the drum 116 to control the rotation speed of the rotary shaft 11.

In addition, when the drum 116 is rotated, the lining 114 located in the inner region of the drum 116 is also rotated and extended outward by centrifugal force to press the drum 116 to rotate the shaft 11. Can control the speed of rotation.

10 is a perspective view of a state in which a plurality of rotary shafts 11 are coupled.

11 is an exploded perspective view of a state in which a plurality of rotary shafts 11 are coupled.

12 is a cross-sectional view of a state in which a plurality of rotary shafts 11 are coupled, respectively.

As shown in Figure 10 to 12, by installing a plurality of the number of the rotary shaft 11 as needed so that the wind or hydraulic power flowing through the inlet 2 from the outside can be more smoothly supplied. Can be installed.

When the plurality of rotary shafts 11 are installed at the upper and lower portions, respectively, the wing portion 12 formed at the lower side of the rotary shaft 11 located at the upper portion and the wing formed at the upper side of the rotary shaft 11 located at the lower portion. Water flows introduced through the upper guide part 21 and the lower guide part 21 to the part 12 may be respectively supplied to increase rotation of the rotary shaft 11 in one direction.

In addition, the rotation shaft 11 has a drive gear 13 is formed on the shaft and the main gear (14) coupled to the drive gear 13 and the other drive gear 13 is rotated by the It is configured to receive electricity from the main generator gear 14 through the rotation of the shaft (11).

4 is a front view of the reverse rotation prevention unit 18 is coupled to the present invention.

As shown in FIG. 4, the rotation shaft 11 rotated as described above is rotated in one direction while the rotation shaft 11 is rotated in the reverse direction to control the rotation shaft 11 in the reverse direction. Rotation prevention unit 18 is formed. The reverse rotation prevention unit 18 formed as described above is formed at the end of the drive gear 13 coupled to the shaft of the rotary shaft 11, one side of the reverse rotation prevention unit 18 is coupled to the fixed rod The other end is coupled with the elastic spring to guide the rotational direction of the drive gear 13 in one direction by the elastic spring.

That is, the reverse rotation prevention unit 18 is provided in a state in which the reverse rotation preventing unit 18 is separated from the drive gear 13 through the elastic spring. When the rotation shaft 11 rotates in the reverse direction, the reverse rotation prevention coupled with the elastic spring is prevented. Unit 18 is coupled to the end of the drive gear 13 to control the reverse rotation of the drive gear 13 is configured to prevent the rotation shaft 11 interlocked with the drive gear 13 to reverse rotation do.

In another embodiment of the present invention, a plurality of wind turbine generators (A) may be installed in a tower structure, and FIG. 13 illustrates a perspective view of a state installed in an upright structure.

Figure 14 shows a perspective view of the state installed in the apartment plant-like structure, respectively.

As shown in FIG. 13 and FIG. 14, the tower structure may be divided into an upright type and an apartment factory type. Accordingly, by installing each wind generator A in the tower type structure, a large amount of energy source may be provided. It will be available.

Meanwhile, the present invention enumerates the best configuration thereof, but is not limited thereto, and if it can be practiced without departing from the scope of the appended claims, it is a matter of course that modifications of the above-described configuration can be considered.

By generating the supply of energy sources using wind and water, which are infinite energy that can be obtained from nature, there is an effect that can satisfy alternative energy sources even when depletion of underground resources.

In particular, the present invention solves the problem of environmental pollution, it is possible to supply a sufficient amount of energy source even in the wind or small water pressure can be used with high efficiency.

In addition, it is a very useful invention that can be installed regardless of the place by receiving the energy source by simply installing the present invention on a windy beach or island or waterfall or stream water.

Claims (15)

In the wind turbine generator to generate power by using hydraulic power and wind power, The wind generator A has a rotary shaft 11 formed therein, a plurality of wings 12 are formed outside the rotary shaft 11, and driven on the shaft of the rotary shaft 11. A body 13 coupled to the gear 13 and coupled to the main generator 100 and the main generator gear 14 and the belt 16 that are arranged; Guide portion 21 having a tapered inclined portion is formed so that the wind is introduced into one side of the body portion 1, the lower guide portion 21 of the adjacent region of the body portion 1 is a rotary shaft 11 An inlet portion (2) formed to be colinear with the central axis of the inlet; An outlet portion 3 having an opening portion so that the water flowing through the inlet portion 2 can flow out to the other side of the body portion 1; A support frame 171 is formed below the body portion 1, a post 17 is formed below the support frame 171, and a support portion 4 is formed below the post 17. And a bearing (41) formed at the center of the support part (4) to be rotatably coupled to the post (17), so that the body part (1) is formed to be rotatable according to the wind. In the wind turbine generator to generate power by using hydraulic power and wind power, Guide portions 21 having inclined portions tapered inwardly are respectively formed on the upper and lower portions so that the wind is introduced therein, and the support portions 22 are connected to both sides of the guide portion 21, and the guide portions 21 are formed. ) Is a wind generator, characterized in that it has an inlet (2) is formed with a plurality of opening and closing valves 23 that can be opened and closed in accordance with the wind. The method of claim 1, Auxiliary power generation that is built up with a plurality of auxiliary generator 101 in the inner region of the belt 16 for receiving the drive gear 13 and the main generator 100 coupled to the shaft shaft 11 of the body portion 1 The wind turbine generator further comprises a gear 15 and a power transmission device. The method according to claim 1 or 3, A lower portion of the post 17 is penetrated with the support frame 171 and a plurality of rolling parts 172 are formed at the edge of the support frame 171 so as to be rotatable in one direction from the inside of the support part 4. It is formed, the rolling unit, characterized in that the rolling portion 172 and the support portion (4) is coupled to each other. The method according to claim 1 or 2, Water-wind generator, characterized in that the opening and closing valve 23 formed in the guide portion 21 is adjusted at any angle in accordance with the water-flow force introduced through the inlet portion 2 of the wind generator (A) is opened or closed. . The method of claim 1 or 3, The braking control device is formed on one side of the rotary shaft 11, characterized in that the wind turbine generator characterized in that to control the speed of rotation of the rotary shaft (11) and fixed. The method of claim 1 or 3, The circular drum 116 is connected to one side of the rotary shaft 11 and the lining 114 is coupled to the inner circumference of the drum 116 so that the lining 114 is in accordance with the centrifugal force of the rotary shaft 11. Water pressure generator, characterized in that for pressing the drum 116 to control the rotational speed of the rotary shaft (11). The method of claim 3, wherein A plurality of idle rollers (161) is formed on the outer periphery of the belt (16) is a wind generator characterized in that to increase the tension of the belt (16) by the idle roller (161). The method of claim 1 or 3, A wind generator, characterized in that the reverse rotation prevention unit 18 is formed on one side of the rotary shaft (11). The method of claim 4, wherein A wind generator, characterized in that the wind direction sensor 102 is coupled to the upper side of the body portion 1 to adjust the direction of the body portion 1. The method of claim 1 or 3, Wind speed generator characterized in that the rotational speed sensor 103 is coupled to the outer periphery of the belt 16 to detect the rotational speed of the rotary shaft 11 and the rotational speed of the belt 16 according to the inflow of water . The method according to claim 1 or 2, Water-wind generator, characterized in that the wind speed detection sensor 105 and the valve detection sensor 104 is coupled to the outside of the on-off valve 23 to open and close the on-off valve 23 at any angle. The method of claim 6, The wind speed generator is coupled to the front of the piston 113, the wind speed generator, characterized in that the brake panel 111 is pressed through the brake cylinder (115). The method of claim 4, wherein A wind generator, characterized in that another post (17) is connected between the inlet (2) and the support (4). In the interior of the structure (F) formed of a vertical panel having a horizontal bar and a vertical bar coupled in a rectangular shape and a plurality of auxiliary bars are connected to the central area and a plurality of vertical bars coupled in a vertical direction at the corners of the supporting panel. A wind generator (A) is installed, the structure (F) and the wind generator (A) is a wind generator, characterized in that a plurality is installed on the upper side.

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