TW201527645A - A wind turbine with blew sheet guided arm - Google Patents

Abstract

A wind turbine by which the arm is guided by blew sheet, wherein the wind turbine is a vertical shaft wind turbine includes a shaft, arms, and sheets. The shaft is vertically disposed and connects with the arms, and the sheets are mounted on the arms. The sheets can be suppressed and bent by the wind, in order to generate thrust to push the arms and rotate the shaft. Thus, the wind turbine neither require a tall tower nor a wind-sensing equipment to be disposed, so the gravity center can be lower to improve safety, and the structure can be simplify to lower the cost.

Description

Wind turbine with long arm propelled by wind plate

The invention provides a wind turbine, in particular to a wind turbine which uses wind power as a power to push a long arm by a wind plate.

According to human beings, using natural energy and using wind power as power has been for thousands of years. At present, various vertical axis wind turbines are not efficient or large, so the world's large wind turbines are horizontal axis three-blade wind turbines. Mainly, but it must have the equipment to track the wind direction, so the structure is complicated, and high towers must be built, which is expensive, especially the main institutional cabin (Nacelle) is located at the top of the tall tower, which is difficult to maintain. It is not easy to save. In addition, the generator of the wind turbine, the gear box, and the control device for tracking the wind direction are all located at the top of the high tower column, which is very heavy, and because the center of gravity is on the top, and the head is heavy, the situation is caused by strong wind blowing.

In summary, the inventors have felt that the above-mentioned deficiency can be improved, and the research is devoted to the application of the theory, and finally a design that is reasonable in design and effective in improving the above-mentioned deficiency is proposed.

The technical problem to be solved by the present invention is to provide a wind turbine that pushes a long arm by a wind plate, without designing a high tower, low center of gravity and safety, and without having to set up a complicated windward direction device, which can simplify the structure and reduce the cost. .

In order to solve the above technical problem, the present invention provides a wind turbine that pushes a long arm with a wind receiving plate, which is a vertical axis wind turbine, comprising: an axial center, the shaft center is upright; a plurality of long arms, The long arms are connected to the shaft; and the plurality of wind receiving sheets are mounted on the long arms; the wind receiving sheets are bent by the wind pressure, and the long arms are pushed to rotate the shaft .

The present invention has at least the following advantages: the present invention utilizes the concept that the boom of the crane has a large load, and constructs the large vertical axis wind turbine of the present invention, and the long arm that lifts the heavy load of the wind turbine shaft is driven; Each long arm is equipped with one or several wind receiving plates to absorb wind energy. The wind deflector is bent by the wind pressure, and the generated curved thrust pushes the long arm to push the wind turbine shaft to rotate.

The invention also utilizes the crane boom to be easy to lift and lower, can set the height arbitrarily, or set the concept of the length of the telescopic arm. In particular, the long arm of the truss structure can have a long span, a large load, and the longer the long arm of the wind turbine, The stronger the torque torque is; the longer the long arm is, the longer the elevation angle is set, the higher the suction wind is, and the higher the demand of the tower is saved.

The invention adopts a wind turbine that pushes a long arm by a wind plate piece, because it is not necessary to design a high tower column; and a heavy and expensive engine room can be arranged under the center of the wind turbine, so that the low center of gravity is the safest, for the future The offshore wind turbine project will be simplified, and the low center of gravity can be used for wind power generation as well as various power applications. It is even suitable for the power of the ship. It is not necessary to set up these complicated wind-fighting devices, and the wind-pressure winds without any wind direction can be used.

For a better understanding of the features and technical aspects of the present invention, reference should be made to the accompanying drawings.

1‧‧‧After cabin

2‧‧‧ long arm

2A‧‧‧Long arm

2B‧‧‧Long arm

2C‧‧‧ long arm

2D‧‧‧ long arm

3‧‧‧Wind plate

3A‧‧‧Wind plate

3B‧‧‧Wind plate

3C‧‧‧Wind plate

3D‧‧‧Wind plate

4‧‧‧House

5‧‧‧Axis

6‧‧‧Rotating disk holder

7‧‧‧Active joints

8‧‧‧H-beam

9‧‧‧Axis support

10‧‧‧Central Support Tower

11‧‧‧Steel cable

12‧‧‧ Telescopic rod

12A‧‧‧Active joints

12B‧‧‧Active joints

12C‧‧‧Active joints

13‧‧‧Support backbone

14‧‧‧ front end

15‧‧‧ Backend

A‧‧‧Wind machine

B‧‧‧Rotation direction

C‧‧‧Wind direction

Fig. 1 is a perspective view of a wind turbine according to the present invention (a form in which a long arm is operated at an elevation angle).

Figure 2 is a partial detail view of Figure 1.

Fig. 3 is a schematic view showing the longitudinal operation of the long arm of Fig. 1.

4 is a schematic view showing the reduced configuration of the long arm of FIG. 1.

Figure 5 is a perspective view of the miniaturized wind turbine of the present invention.

Fig. 6 is a plan view schematically showing Fig. 5 in a plan view.

Figure 7 is a perspective view of another embodiment of the wind turbine of the present invention.

Figure 8 is a partially enlarged schematic view of Figure 7.

Figure 9 is another enlarged view of a portion of Figure 7.

[First Embodiment]

Referring to FIG. 1 , the present invention provides a wind turbine that pushes a long arm with a wind deflector. In this embodiment, the wind turbine A includes a cabin 1 , a plurality of long arms 2 , and a plurality of wind deflectors 3 . The long arms 2 may be disposed on the cabin 1 , and the wind receiving sheets 3 are mounted on the long arms 2 .

Fig. 1 is a schematic view showing the configuration in which the long arm 2 is operated at an elevation angle. The length of the long arm 2 and the angle of the arrangement are not limited. For example, the long arm 2 may be 50 meters long and extend upward at an angle of about 30 degrees, and the tip of the long arm 2 is more than 35 meters from the ground. A large vertical axis wind turbine with a diameter of 100 meters can be operated without the need to build a tall tower.

As shown in Fig. 1, the wind turbine A that pushes the long arm 2 by the wind plate 3 has a configuration in which the long arm 2 is operated at an elevation angle (about 30 degrees). The embodiment is a vertical axis wind turbine A. The four shafts 2 are driven to rotate the shaft, and four wind receiving sheets 3 are mounted on each long arm 2, and the wind receiving sheets 3 are used for Draw in wind energy. When the wind is blown to the wind turbine A in the wind direction C; all the wind receiving sheets 3 are subjected to the wind pressure, and the long arm 2 is pushed to push the wind turbine A to rotate and rotate in the rotation direction B.

In order to absorb more wind energy, between the long arms 2, the appropriate spacing, as much as possible to set the windshield plate 3 (such as Figure 1 and Figure 3), the more the wind receiving area, the more the wind The more thrust there is. As shown in FIG. 1 and FIG. 2, although four wind deflector sheets 3 are mounted on each long arm 2, in practice, more wind deflecting sheets 3 can be loaded, and as shown in the example. It is shown that each of the long arms 2 is a triangular truss structure, and the inner space of the triangular truss can also be provided with a plurality of wind receiving sheets 3, which are methods for increasing the wind receiving area.

The long arm 2 is capable of lifting heavy loads by using the crane's boom. The long-arm shape of the crane we see everyday can be square, triangular, curved or telescopic, and does not limit the appearance. This embodiment is a triangular truss long arm type, because its structure is strong and light and has a long span, the longer the arm, the stronger the torque and torque of the wind turbine.

The wind turbine A can be built on a building that can accommodate people, such as the roof of the house 4. The dwelling house 4 is only a relatively good land use space, and is a large wind turbine that can be built on the roof of a residential house on the coast or with a wind farm. However, the house 4 does not have the necessary relationship with the wind turbine A, that is, the wind turbine A of the present invention is not limited to being built on the house 4. However, the house 4 as shown in the figure must be constructed of steel, and has a strong structure to bear the weight of the wind turbine A and the strict lightning protection measures.

The cabin 1 of the wind turbine can be built in the center of the roof of the house 4. The greatest advantage of the present invention is that the wind turbine A that pushes the long arm 2 by the wind plate 3 as the vertical axis wind power generation is that the cabin 1 is located at the center of the wind turbine A. If it is used for wind power generation, the internal equipment of the cabin 1 can be equipped with gearboxes, generators, brakes, speed controllers, hydraulic systems, AVRs and inverters. These are all wind turbines. Knowing and customary facilities, it is not disclosed in the drawings so as not to be repeated.

Further, a central support tower 10 and a plurality of steel cable 11 can be included, and the long arm 2 and the central support tower 10 can be pulled by the steel cable 11, that is, one end of the steel cable 11 is connected to the long arm 2, and the other end of the steel cable 11 It is installed in the center support tower 10, and is connected to the hoist (not shown). The steel wire rope 11 connected to the long arm 2, a hoisting machine, etc. can comprise a control long arm lifting mechanism. Since the long arm 2 is pulled by the steel wire rope 11 and the hoisting machine is a lifting mechanism conventionally used for a crane or a hanging tower, and therefore will not be described again. Most importantly, the tension control wire ropes 11 of the long arms 2 must be synchronized so that the long arms 2 are simultaneously raised and lowered. In another embodiment of the present invention, it can also be a hydraulically stretched long arm type or a hydraulic lifter The arm type, that is, the hydraulic device can be used to telescope or lift the long arm 2, and the hydraulic device constitutes the control long arm lifting mechanism, so that the central support tower 10 and the steel cable 11 are not required, so the steel cable 11 and the central support tower 10 does not have to be available and can be omitted.

Please refer to FIG. 2, which is a partial detail view of FIG. 1. The wind turbine A can have a shaft center 5 and a rotating disc holder 6, the shaft core 5 is arranged upright, and one end of the shaft core 5 is connected to the rotating disc holder 6, so that the two are integrated into one body, the shaft core 5 and the rotating disc holder 6 It can be made by welding and turning. A central support tower 10 is disposed on the rotating disk holder 6, and the inner space of the central support tower 10 is a space in which the hoist can be disposed.

The long arms 2 are respectively disposed on the four opposite sides of the rotating disk holder 6, so that the long arms 2 are connected to the shaft center 5 through the rotating disk holder 6, so that the long arms 2 can be used to push the shaft center 5 to rotate. The long arms 2 can be connected to the rotating disc holder 6 by the movable joints 7, respectively, that is, one ends (lower ends) of the long arms 2 are connected to the rotating disc holder 6 by the movable joints 7. The movable joint 7 enables the long arm 2 to move and has a lifting function, and can also transmit the large thrust energy that is subjected to the thrust of the wind plate 3 to push the long arms 2 together to be transmitted to the rotating disk holder 6.

Further, the top of the cabin 1 may be provided with a steel beam 8, which may comprise four H-shaped steel beams 8, which are combined with the central axial support 9 with very strong welding to support the entire wind turbine A. The full weight. The shaft center 5 is disposed in the axial center support body 9, and the shaft support body 9 is internally provided with a plurality of bearings and lubricating oil capable of withstanding gravity (not shown), so that the shaft center 5 can smoothly rotate without hindrance.

When the long arms 2 push the rotating disk holder 6 to rotate, the huge energy of the torque rotation is introduced into the cabin 1 through the shaft center 5 through the shaft support body 9, and then the gearbox is driven to make the generator run or play the energy. .

Please refer to FIG. 3 , which is a schematic diagram of the horizontal operation mode of the long arm of the present invention. Referring to FIG. 1 and FIG. 4 simultaneously, the long arm 2 of the wind turbine A can be lifted or lowered to correspond to the natural wind and weak wind. Unstable wind speed changes such as strong winds and squalls. When the wind speed is too strong (for example, the wind speed exceeds 15 meters per second), the height of the long arm 2 can be appropriately lowered. The stronger the wind speed, the longer the arm 2 is controlled to lower the lower limit, and the long arm lifting mechanism is controlled by the control. The height of the variable length arm 2 corresponds to the strength of the wind to achieve a stable rotation speed of the wind turbine shaft 5 .

Please refer to FIG. 4 , which is a schematic diagram of the reduced configuration of the long arm of the present invention, which is lowered to the bottom to stop operation. In the event of a typhoon warning, a tornado warning, the long arm 2 of a safe wind turbine can even be locked to the ground, or in the completely windless season, the long arm 2 of the wind turbine is lowered to the ground to avoid obstructing the landscape.

The wind turbine A that pushes the long arm 2 by the wind plate 3; the embodiment shown in Figs. 1 and 3 is four long arm type, and of course, it can be a long arm type or three lengths. Arm type or two long arm type, the more the number of long arm 2, the slower the rotation speed of the shaft 5 but the greater the torque torque. The smaller the number of long arms 2, the faster the shaft 5 speed will be, but the smaller the torque torque.

In order to facilitate the explanation of the operating principle of the wind deflector 3, FIG. 3 is simplified and reduced to a relatively small wind turbine as shown in FIG. 5, which comprises four long arms 2, and each long arm 2 is only schematically provided with one. The wind deflector 3 is used to explain the principle of the wind turbine operating the windward blade 3 to push the long arm 2. One end (front end 14) of the wind receiving sheet 3 is provided with a supporting backbone 13 which is connected to the corresponding long arm 2, thereby supporting the backbone 13 as a supporting force and weight for supporting the entire wind receiving sheet 3, and Thereby, the support backbone 13 is coupled to the strong long arm 2, and after the support of the wind plate 3 to the other end (the rear end 15), most of the entire area of the plate is free to move freely. It can be bent by wind pressure to absorb wind energy. The wind-receiving sheet 3 is subjected to the wind pressure of the wind direction C, and is curved corresponding to the strength of the wind pressure, and generates a curved surface thrust to push the long arm 2 to push the wind turbine shaft 5 to rotate.

Please refer to FIG. 5 , which is a perspective view of the miniaturized normal operation mode of the long arm of the wind turbine with the long arm supported by the wind plate; FIG. 6 is a schematic plan view of the present invention in a top view. An explanatory view of a corresponding relationship in which the wind plate is bent by the wind pressure of the wind direction C by a circular orbital ring.

In order to explain the relationship between FIG. 5 and FIG. 6 in a more convenient manner, the four long arms 2 are respectively distinguished from the growth arm 2A, the long arm 2B, the long arm 2C, and the long arm 2D. The four wind receiving sheets 3 are respectively divided into a wind receiving sheet 3A, a wind receiving sheet 3B, and a wind receiving sheet. 3C and windshield 3D. Fig. 6 shows the four wind receiving sheets 3A, 3B, 3C, and 3D of Fig. 5 in a plan view, and the wind receiving sheets are bent and changed by the wind pressure of the wind direction C at each angle to which the wind receiving sheets are rotated. The four wind deflecting plates 3A, 3B, 3C, and 3D are subjected to a wind-curved curved surface, that is, a force that pushes forward, and pushes the long arms 2A, 2B, 2C, and 2D to rotate forward, that is, the wind in the rotation The plate is continuously subjected to the wind pressure of the wind direction C, corresponding to the degree of wind pressure and the angle is bent to the left and right, thereby generating forward thrust, constantly pushing the long arm and pushing the axis of the wind turbine to rotate.

In the rotating track shown in FIG. 6, the solid line represents the wind pressure bending state of the wind receiving plates 3A, 3B, 3C, and 3D on the four long arms 2A, 2B, 2C, and 2D corresponding to the wind direction C in the indicated orientation. . For the sake of clearer description, the wind pressure bending state corresponding to the wind direction C of the wind receiving plates 3A, 3B, 3C, and 3D on the four long arms 2A, 2B, 2C, and 2D in the azimuth is indicated by a broken line.

Further explaining the embodiment shown in FIG. 5, the wind turbine in the normal horizontal operation mode is four long arms that drive the wind turbine on the wind turbine A; only one wind receiving plate is installed on each long arm, for a total of four The wind receiving sheets 3A, 3B, 3C, and 3D, each of the wind receiving sheets and the supporting backbone 13 disposed therein are all vertically vertical.

The windshield sheet can be subjected to the principle of wind. The most basic feature is that one end is rigid and one end is relatively weak and elastic, so each of them is supported by the end of the wind panel (front end 14) to support the backbone 13 to make it rigid. The support backbone 13 also supports the opening force and weight of the entire wind deflector sheet and is coupled to the strong long arm by the support backbone 13.

The front end 14 of the wind receiving sheet 3A is provided with a support backbone 13 and is coupled to the long arm 2A. The front end 14 of the wind receiving sheet 3B is provided with a support backbone 13 and is coupled to the long arm 2B. The front end 14 of the wind receiving sheet 3C is supported. The backbone 13 is coupled to the long arm 2C; the front end 14 of the wind receiving plate 3D is provided with a support backbone 13 and is coupled to the long arm 2D.

When the wind is blown to the wind turbine A by the wind direction C, after the support backbone 13 of each of the wind receiving panels 3A, 3B, 3C and 3D to the rear end 15, the entire area of the entire panel is allowed to play. Elastic free movement, that is, after each wind plate is supported from the backbone 13 to the rear end 15, most of the entire plate is relatively weak due to the elastic Sex is free to move, let it bend freely by the wind pressure of wind C (the bending condition is compared with Figure 6) and produce curved curved thrust, which pushes the long arm and pushes the axis of the wind turbine; the figure is the direction of rotation Rotation of direction B (if you want to rotate in the opposite direction of B, just place each windshield on the opposite side of the long arm).

A wide variety of panels can be made into windshield sheets, but in order to absorb the highest efficiency of wind energy, the better the elasticity of the material of the fabric to be produced, the better the efficiency of drawing wind energy.

[Second embodiment]

If the wind turbine is driven by the wind plate, if the long arm is set to a fixed angle or height due to ground factors or environmental factors, the long arm must be in the wind turbine because it has no lifting function or telescopic function. The wind plate can be equipped with a mechanism that can adjust the inclination to face the infinite destruction of nature. Unstable changes in response to nature's weak winds, strong winds and squalls. As shown in Figs. 7, 8, and 9, the wind receiving plate 3 can be connected with a tilting mechanism such as a telescopic rod 12, as shown in Figs. 7, 8, and 9. When the wind is weaker, the wind receiving plate 3 is more vertical and vertical, and the wind receiving area is larger. When the wind speed is too strong, the wind plate 3 is more inclined, and the wind receiving area is smaller. When the natural wind is stronger, it will be tilted by the wind plate 3. The mechanism for adjusting the inclination of the wind receiving plate 3 corresponds to the change of the wind strength, and the steady thrust of the long arm 2 can be maintained regardless of the wind force, so that the wind turbine shaft 5 maintains a stable rotational speed.

Fig. 7 is a perspective view showing the state in which the wind receiving plate of the wind turbine propelling the long arm by the wind plate is inclined. If we compare Figure 7 with Figure 5, we can see the difference between the four wind deflectors 3A, 3B, 3C and 3D. In order to explain the adjustment of the tilting mechanism of the wind deflector, for the sake of clarity, the part of Figure 7 is shown. Zoom in and become Figure 8 and Figure 9 for comparison.

Please refer to FIG. 8 , which is a partially enlarged schematic view of the wind deflecting plate 3 , which is vertical and vertical. The vertical wind receiving plate can absorb the maximum wind energy, and the wind receiving plate 3 can be generated by the wind pressure. Bending, the situation of the surface thrust, can promote the long arm 2, and promote the wind turbine operation, that is, as shown in Figure 5, under the normal operation mode of the wind turbine, The wind deflecting plate 3 and its supporting support trunk 13 are all vertically perpendicular, and the telescopic rod 12 is contracted to the uppermost vertex.

Please refer to FIG. 9 , which is a partially enlarged schematic view of the wind deflecting plate 3 . The more inclined the wind receiving plate 3 is, the less wind energy can be absorbed, as shown in FIG. 7 . Due to the inclined form of the wind deflector 3, the telescopic rod 12 extends to the lowermost bottom point, and the wind receiving plate 3 and its supporting backbone 13 are extremely inclined, and the wind turbine has been stopped.

From the schematic diagram of FIG. 8 and the schematic diagram of FIG. 9, the windshield plate and the support backbone 13 disposed therewith are connected between the long arm 2 through the movable joint 12A, the movable joint 12B, the movable joint 12C and the telescopic rod 12, That is, one end of the telescopic rod 12 is connected to the long arm 2 through the movable joint 12A, the other end is connected to the wind receiving sheet 3 through the movable joint 12B, and the wind receiving sheet 3 is connected to the long arm 2 through a movable joint 12C. The inclination angle of the wind receiving sheet 3 is controlled by controlling the extent of the extension and contraction of the telescopic rod 12.

The schematic diagram of Fig. 7 is a schematic view of Fig. 5, and it is most important that all of the wind deflector sheets 3 are controlled in accordance with the tilting mechanism, and the tilt angles synchronized with all of the wind deflector sheets 3 must be adjusted in synchronization.

The schematic diagram of the mechanism for adjusting the inclination of the wind plate is shown in Fig. 7 with reference to Fig. 8 and Fig. 9. For the convenience of explanation, the hydraulic cylinder telescopic rod 12 is used to push the indication. In practice, the electric motor and the hydraulic cylinder can also be used to control the inclination. Or use centrifugal force. When the running speed of the long arm 2 exceeds a set value, the wind receiving plate 3 is tilted due to the centrifugal force being opened, and the wind receiving area is reduced to automatically control the rotational speed to maintain the constant rotational speed of the wind turbine. All of the above methods are well-known mechanical designs and will not be described again.

The example of all the drawings in the wind turbine that pushes the long arm by the wind plate is that the wind plate is rectangular, but in reality, the wind plate is triangular or curved, and the appearance is beautiful. Applicable, the most important shape of the wind plate is to achieve the highest efficiency and aesthetics of the wind energy to match the overall shape of the long arm.

In summary, the wind turbine of the long arm with the wind plate is indeed practical, and has the unstable wind and wind, strong wind and squally wind. The ability to use the long arm lifting mechanism to change the height of the long arm, or to control the inclination mechanism of the wind receiving plate, to control the steady rotation speed of the wind turbine shaft or to achieve a stable energy output of the wind turbine. These two control mechanisms can also be used together for greater safety considerations. The long arm technology is very mature, and the application of various crane booms is strong, light and safe. The control lifting mechanism is already a mature and reliable technology, whether it is using the hydraulic press method or the winch method.

As long as the wind plate manufacturing is focused on durability and elastic properties, the manufacturing materials are aluminum plate, stainless steel plate or various metal plates or synthetic resin fiber boards, nylon plates, PC boards, PE boards, FRP boards, plastic sheets, rubber sheets or various Plates, even hard canvases and even wood panels, can be adapted to local conditions and will be very cheap, thus facilitating the use of wind energy opportunities in poor and backward areas or countries.

The wind turbine of the long arm is driven by the wind plate piece, and the windmill of the large wind power generator is originally an arduous project. The original technical field and the high cost engineering are ordinaryized, and it becomes simple and easy to do, and the wind power generation will be As a result, power generation costs are cheaper and more universal, and humans will be more widely used to use the inexhaustible clean energy that winds have given them.

The wind turbine that pushes the long arm with the wind plate will continue to evolve in the future. In addition to the maximum efficiency of the wind energy, the shape of the wind plate is more beautiful and the long arm has more curved lines and beautiful lines. With the mechanical engineering and aesthetic engineering, the wind turbine is designed to rise when there is wind, and it will be lifted when there is no wind. It will lift the conventional three-blade horizontal axis vertical large wind turbine windmill, which will hinder the beautiful scenery and obstruct the skyline. It will also benefit the poor people in the coastal areas, suffering from the strong sea breeze every year. The wind will become their god-given wealth in the future. The future fishermen will not only make up the fish to make money, but also make up the wind to make money. Because wind energy can make hydrogen gas. The power of the ship is also reduced by the engine and fuel consumption, and the ship can also be powered by the wind turbine that pushes the long arm by the wind plate.

The above is only the preferred embodiment of the present invention, and is not intended to limit the scope of the invention, and the equivalents of the present invention and the equivalents of the drawings are all included in the present invention. Within the scope of protection, it is given to Chen Ming.

1‧‧‧After cabin

2‧‧‧ long arm

3‧‧‧Wind plate

4‧‧‧House

6‧‧‧Rotating disk holder

8‧‧‧H-beam

9‧‧‧Axis support

10‧‧‧Central Support Tower

11‧‧‧Steel cable

A‧‧‧Wind machine

B‧‧‧Rotation direction

C‧‧‧Wind direction

Claims (16)

A wind turbine that pushes a long arm by a wind plate, which is a vertical axis wind turbine, comprising: an axial center, the shaft is upright; a plurality of long arms connected to the shaft; and A plurality of wind receiving sheets are mounted on the long arms; the wind receiving sheets are bent by the wind pressure, and the long arms are pushed to rotate the shaft. A wind turbine according to claim 1, wherein the wind turbine is driven by the wind plate, further comprising a rotating disc holder, one end of the shaft is connected to the rotating disc base, and the long arms are respectively disposed on the rotating disc base Upper, the long arms are connected to the axis through the rotating disk holder. A wind turbine according to claim 2, wherein the long arms are driven by the wind plate, wherein the long arms are respectively connected to the rotating disk block by movable joints. The wind turbine according to claim 3, wherein the wind turbine is driven by the wind plate, further comprising a central support tower and a plurality of steel cables, wherein the central support tower is disposed on the rotating disc base, and the steel cables are connected at one end. In the long arms, the other ends of the steel cables are disposed on the central support tower and connected to the hoist. The wind turbine according to claim 1 is characterized in that the long arm is driven by the wind plate, wherein the long arms are respectively connected with the control long arm lifting mechanism. The wind turbine according to claim 1, wherein the long arm is driven by the wind plate, wherein the long arm is disposed on a cabin, and the top of the cabin is provided with an axial support body, and the shaft is disposed on the shaft In the heart support. The wind turbine according to claim 1 is characterized in that the long arm is driven by the wind plate, wherein the long arms are provided with two, three or four. The wind turbine according to claim 1, wherein the long arms are in a square shape, a triangle shape or an arc shape. a wind turbine driven by a wind plate to support a long arm, as described in claim 1 The long arm is a telescopic long arm type, a hydraulic telescopic long arm type, a hydraulic lifting long arm type or a truss structure. The wind turbine according to claim 1, wherein the long arms are driven by the wind plate, wherein the long arms are in an elevation mode, a horizontal operation mode or a reduced shape. The wind turbine according to claim 1, wherein the wind deflector pushes the long arm, wherein one end of each wind deflecting plate is provided with a supporting backbone, and the supporting backbone is connected to the corresponding long arm. The wind turbine according to claim 1, wherein the wind deflector is vertically or obliquely disposed on the corresponding long arm. A wind turbine according to claim 1 which is driven by a wind plate to a long arm, wherein the wind plate is a resilient plate. The wind turbine according to claim 1 is characterized in that the wind turbine is driven by a wind plate, wherein the wind plate is respectively connected with a regulating inclination mechanism. A wind turbine that pushes a long arm with a wind plate as described in claim 14, wherein the regulating tilt mechanism comprises a telescopic rod, a hydraulic cylinder or an electric motor. A wind turbine according to claim 1, wherein the wind deflector is a rectangular shape, a triangular shape or an arc shape.