KR102207695B1 - A wind power generating device - Google Patents

Abstract

The present invention relates to a wind power generator instrument (100) which comprises: a rotor (110) installed by being connected to a power generator of a wind power generation apparatus; one or more shafts (120) rotatably placed on the rotor (110); blades (130) placed on both sides of the shaft (120) with the rotor (110) disposed therebetween; and a stopper (115) placed on the rotor (110). The shaft (120) rotates in a direction of hanging on the stopper (115) while the blades (130) rotate towards a load side, and the rotor (110) rotates on its axis by wind power applied to the blades (130) as the shaft (120) is hung. Then, the blades (130) rotate towards a non-load side, and the shaft (120) rotates in a direction of being farther away from the stopper (115), thereby reducing resistance by wind power. The blades (130) placed on both sides of the shaft (120) with the rotor (110) disposed therebetween have a phase difference. The blades (130) rotate as one body with the shaft (120). The present invention aims to provide a wind power generator instrument which is able to suppress noise and vibration.

Description

Wind power generation mechanism {A WIND POWER GENERATING DEVICE}

The present invention relates to a wind power generation mechanism, wherein the wind power is increased by maximizing the rotational resistance at the load side, while the rotational resistance at the no-load side is reduced to increase power generation efficiency, About.

There is no fear of depletion due to the continuous increase in energy use and the increase in the need for clean energy, research on renewable energy that is renewable and free of environmental pollution is actively being conducted. A wind power generator is a device that generates electric energy by turning a generator using the power of the wind, and it is a device that produces energy without concern for environmental pollution. In general, a wind power generator includes a rotor having blades that rotate by wind, and a generator that generates electricity by rotation of the rotor. In addition, a power transmission unit for transmitting the rotation of the rotor to the generator may be further provided, and the power transmission unit may be implemented by a gear assembly and a chain or rope. In addition, a generator is installed inside the rotor so that power is generated from the generator inside by the rotation of the rotor without a power transmission unit.

The conventional wind power generator 100 includes a support shaft 110, a power generation unit 130 and a plurality of blades 180. The support shaft 110 is provided with a flange 112 at the upper and lower ends, respectively. The power generation unit 130 includes a housing 140, a field 150, and an armature 160. The housing 140 is formed in a cylindrical shape and is rotatably supported and installed on the support shaft 110. The housing 140 includes an outer cylinder 141 and an upper cover 145 and a lower cover 147. The outer cylinder 141 is formed in a hollow cylindrical body and is installed in a form surrounding the outer peripheral surface of the support shaft 110. The upper cover 145 and the lower cover 147 are respectively coupled to the upper and lower surfaces of the outer cylinder 141 to be rotatably installed on the support shaft 110. Through holes 145a and 147a through which the support shaft 110 passes are formed on the central side of the upper cover 145 and the lower cover 147, respectively. When the upper cover 145 and the lower cover 147 are respectively coupled to the outer cylinder 141 and the housing 140 is installed on the support shaft 110, the housing 140 flows up and down the support shaft 110 To avoid this, the upper cover 145 is supported on the outer circumferential surface of the support shaft 110 by contacting the portion in contact with the through hole 145a of the upper cover 145 and the portion in contact with the through hole 147a of the lower cover 147. A protruding frame 114 is formed that prevents flow to the lower side of the shaft 110 and prevents the lower cover 147 from flowing to the upper side of the support shaft 110.

The field 150 is installed on the inner circumferential surface of the outer cylinder 141 of the housing 140, and at regular intervals on the inner circumferential surface of the ring-shaped field core 151 and the field core 151 installed on the inner circumferential surface of the outer cylinder 141. It includes a plurality of magnets 153 attached. Since the field 150 is installed in the outer cylinder 141, the field 150 is supported by the support shaft 110 via the outer cylinder 141 and rotated. Ring-shaped support frames 141a and 151a are formed on the lower end side inner circumferential surface of the outer cylinder 141 of the housing 140 and the lower end side inner circumferential surface of the field core 151, respectively, and the support frame 141a of the outer cylinder 141 ) And the support frame 151a of the field core 151, the lower surface of the field core 151 and the lower surface of the magnet 153 are contact-supported, so that the field core 151 and the magnet 153 are each external cylinder 141 And falling to the lower side of the field iron core 151 is prevented. An armature 160 is fixedly installed on the outer peripheral surface of the support shaft 110 located on the central side of the outer cylinder 141. The armature 160 includes a ring-shaped armature core 161 having an inner peripheral surface fixed to the outer peripheral surface side of the support shaft 110 and a coil wound on the outer peripheral surface of the armature core 161.

When the housing 140 rotates by the blade 180, the field 150 rotates, and electricity is generated by the action of the rotating field 150 and the fixed armature 160, and the generated electricity generates the coil. Through the capacitor. The lead wire 163 of the coil flows into the support shaft 110 through the first through hole 116a formed in the support shaft 110, and then goes to the outside of the support shaft 110 through the second through hole 116b. The end side of the lead wire 163 drawn out and drawn out of the support shaft 110 is connected to the capacitor. The armature 160, the field 150, and the outer cylinder 141 may be arranged concentrically, and the outer circumferential surface of the armature core 161 and the inner circumferential surface of the field core 151 face each other.

A support member 118 is formed on an outer peripheral surface portion of the support shaft 110 between the upper cover 145 and the lower cover 147, and the inner peripheral surface and the lower surface of the armature 160 are supported on the support member 118. The support member 118 includes a support plate 118a protruding radially outward of the support shaft 110 from the outer peripheral surface of the support shaft 10 and a support pipe 118b protruding upward from the upper surface of the support plate 118a. , The inner peripheral surface of the electric magnetic core 161 is supported on the outer peripheral surface of the support pipe 118b, and the lower surface of the electric magnetic core 161 is supported on the upper surface portion of the support plate 118a located outside the support pipe 118b.

A plurality of blades 180 are radially installed on the outer circumferential surface of the outer cylinder 141 of the housing 140, centering on the support shaft 110. The blade 180 is installed in the outer cylinder 141 via the connection bar 143. The blade 180 rotates the housing 140 while orbiting around the support shaft 110 by the drag caused by the wind acting on its front or rear, and is supported by the lift caused by the wind acting on its side. The housing 140 is rotated while revolving around the axis 110. In order for the housing 140 rotated by the blade 180 to rotate more smoothly due to inertia, a weight (in the through hole 145a, 147a) side of the upper cover 145 and the lower cover 147 145, 147b) may be provided.

Wind power generator 100 of the prior art as described above acts to resist rotation when the load-side blade 180-1 rotates to the no-load side. For example, when the wind blows in the direction (B) shown by the arrow in FIG. 1 and rotates in the direction of the arrow "A", the blade on the load side indicated by the reference numeral 180-1 generates rotational force by the action of the wind. , There is a problem in that the power generation efficiency is lowered because the blade on the no-load side indicated by 180-2 acts to resist rotation.

Korean Registered Patent No. 10-1807718 Republic of Korea Registration No. 20-0481468 Registration Utility Model Gazette

The present invention has been proposed to solve the problems of the prior art as described above, and it is an object of the present invention to provide a wind power generation mechanism capable of minimizing the generation of rotational resistance due to the blade and suppressing the generation of noise and vibration.

For the above purposes, the present invention provides a rotating body connected to and installed on a generator of a wind power generator, at least one shaft rotatably provided on the rotating body, and blades provided on both sides of the shaft with the rotating body interposed therebetween. , Including a stopper provided in the rotation body, the shaft rotates in a direction applied to the stopper while the blade rotates toward the load side, and the rotation body rotates by the wind force acting on the blade, and the blade rotates toward the no-load side, and the stopper The axis rotates in a direction away from the wind power to reduce the resistance; The blades provided on both sides of the shaft with the rotation body interposed therebetween have a phase difference, and the blades provide a wind power generation mechanism that rotates integrally with the shaft.

In the above, the shaft extends past the center of the rotating body and is spaced apart in the vertical direction and provided in plurality; Each of the shafts is characterized in that blades are provided on both sides with a rotating body therebetween.

In the above, the axis extends in a horizontal direction, and the phase difference of the blade is 90°.

In the above, the shaft is spaced apart from both ends of the blade in the width direction, and is coupled to the blade at a position spaced apart from the center in the width direction.

On the other hand, the present invention is a rotating body that is installed connected to the generator of the wind power generator, a plurality of shafts rotatably provided on the rotating body and protruding from one side of the rotating body, and the shaft coupled to the shaft integrally with the shaft. And a rotating blade and a locking protrusion, and a stopper provided on the rotating body; The rotation of the blade is prevented by being caught by the stopper on the load side, so that the rotating body rotates by the wind acting on the blade, and the blade rotates toward the no-load side and away from the stopper; As the blade rotates toward the load side, the rotor rotates by the wind force acting on the blade by rotating in the direction applied to the stopper, and the blade rotates toward the no-load side and rotates away from the stopper, thereby reducing the resistance of the blade against the wind power. Decreases; The shaft is spaced apart along the circumferential direction of the rotating body to provide a plurality of wind power generators.

In the above, the axis is characterized in that it extends in the horizontal direction.

In the wind power generation mechanism according to the present invention, the blade has a structure that rotates around the axis while revolving around the rotation center of the rotating body, minimizing rotational resistance generated by the blade, and thus has great power generation efficiency, and noise due to contact with the stopper Vibration is suppressed and the blade rotation on the load side and the rotation of the blade on the non-load side are reinforced with each other, thereby minimizing the loss of wind power.

1 is a perspective view of a conventional wind power generator,
Figure 2 is a cut-away perspective view of the support member and the power generation unit of the wind power generator shown in Figure 1,
Figure 3 is an enlarged view of the "A" part of Figure 2,
Figure 4 is a perspective view showing a wind power generating device having a wind power generating mechanism according to the present invention,
5 is an enlarged view of "A" of FIG. 4,
Figure 6 is a perspective structure diagram schematically showing to explain the operation of the wind turbine generator according to the present invention,
7 is a plan view and a partial enlarged view showing a wind turbine generator according to another example of the present invention,
FIG. 8 is a schematic side view showing part “A” of FIG. 7,
9 is a perspective view showing a wind power generator having a multi-layer blade wind power generator according to a variant of the present invention,
10 is a perspective view showing a wind power generating device having a plurality of wind power generating mechanism according to the present invention,
11 is a perspective view showing a modified example of a wind power generating device having a plurality of wind power generating mechanism according to the present invention,
12 is a perspective view and a partial enlarged view showing a wind turbine generator of another modified example of the present invention,
13 is a partially enlarged side view of the wind power generator shown in FIG. 12.

Hereinafter, a wind turbine generator according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a perspective view showing a wind power generating device having a wind power generating mechanism according to the present invention, Figure 5 is an enlarged view of "A" of Figure 4, Figure 6 is a description of the operation of the wind power generator according to the present invention It is a perspective structure diagram schematically shown in order to, Figure 7 is a plan view and a partial enlarged view showing another example of the wind turbine generator of the present invention, Figure 8 is a schematic side view showing the "A" part of Figure 7, Figure 9 Is a multilayer blade according to a variant of the present invention It is a perspective view showing a wind power generator having a wind power generating mechanism, Figure 10 is a perspective view showing a wind power generator having a plurality of wind power generators according to the present invention, Figure 11 is a wind power having a plurality of wind power generators according to the present invention A perspective view showing a modified example of the power generation device, FIG. 12 is a perspective view and a partial enlarged view showing a wind power generation mechanism according to another modified example of the present invention, and FIG. 13 is a partial enlarged side view of the wind power generation apparatus shown in FIG. 12 .

The wind turbine generator according to the present invention is rotatably installed in the wind turbine generator.

Figure 4 is a perspective view showing an example of a wind power generating device is installed in the wind turbine according to the present invention. The wind power generator shown in FIG. 4 is installed on a ground or offshore structure to generate power while the wind power generator rotates by the wind, and the generated electricity is stored in a power storage facility (not shown). A description of the process of power storage is omitted. 4 is an example for explaining the principle, the generator may be installed between the upper portion of the rotation support (C1) and the connection (C) including the rotating body (110).

The wind power generator includes a hollow body base portion (B) and a hollow body connection portion (C) extending upward from the base portion (B), and the wind power generator 100 according to the present invention comprises an upper portion of the connection portion (C). It is installed to be rotatable. As shown in Fig. 4, a generator (not shown) is installed in the base portion B. The generator includes an armature made of a coil (not shown) and a field made of a plurality of permanent magnets (not shown), and when the field is rotatably installed inside the armature, electricity is generated in the armature. The field may be rotatably installed outside the armature to surround the outside. Since the description of the generator is a conventionally known technology, a detailed description thereof will be omitted.

A generator shaft (not shown) is connected to the field so as to extend upwardly into the connection part C, and the generator shaft is connected to the rotating body 110 to rotate with the rotation of the rotating body 110. It may be connected to the rotating body 110 by a power transmission means such as a gear or a belt pulley, or a rotating body shaft (not shown) is provided at the center of the lower portion of the rotating body 110 and connected to the rotating body shaft by a coupling. have. A brake device for holding the generator shaft and preventing rotation is provided, and when it is necessary to stop rotation such as maintenance, the brake device catches the generator shaft and stops rotation.

A circular rotation support part C1 extending radially outwardly in a flange shape is provided at an upper end of the connection part C. The rotating body 110 included in the wind turbine generator 100 according to the present invention is coupled to the rotation support unit C1 to be integrally rotatably installed. An axial rolling bearing (not shown) is installed between the rotation support part C1 and the connection part C, and the rotation support part C1 and the rotation body 110 are rotatably installed with respect to the connection part C.

The wind turbine generator 100 according to the present invention includes a rotating body 110 connected to and installed on a generator of a wind power generator, one or more shafts 120 rotatably provided on the rotating body 110, and a rotating body It includes a blade 130 provided on both sides of the shaft 120 with 120 interposed therebetween, and a stopper 115 provided on the rotating body 120.

The rotating body 110 may be provided in a hollow shape having a circular cross section as shown in FIG. 4. The rotating body 110 may be made of a metal such as steel. A shaft hole 121 penetrated in the radial direction is formed in the rotating body 110. The shaft holes 121 are formed in pairs at positions opposite to each other. Shaft holes 121 formed in pairs and formed at opposite positions may be formed in a plurality of pairs in the vertical direction. The shaft holes 121 forming a pair are spaced downwardly and are formed to have a phase difference with the shaft holes 121 forming a pair. As shown in FIG. 4, when two pairs of shaft holes 121 are formed, they are formed with a phase difference of 90°. When three pairs of shaft holes 121 are formed, they are formed with a phase difference of 60°. And when four pairs of shaft holes 121 are formed, they are formed with a phase difference of 45°.

When the rotating body 110 is provided as a solid body having a circular cross section, the shaft hole 121 is formed through the center of the rotating body 110.

A bearing 150 for rotatably supporting the shaft 120 inserted into the shaft hole 121 is installed outside the rotating body 110 in which the shaft hole 121 is formed. The rotating body 110 is provided with an installation part 160 protruding outwardly at the lower part of the outer side of the shaft hole 121, and the bearing 150 is installed on the upper part of the installation part 160 by a fixing bolt 118 It is equipped. The bearing 150 may be in the form of a unit and a plummer bearing housing, and in some cases, a bearing may be installed by directly processing the bearing support part on the rotating body 110. The flange portions of both sides of the bearing 150 are fastened to the upper portion of the installation unit 160 by fixing bolts 118 and installed. 4 is an exemplary view explaining the basic principle, and the present invention may be modified to the basic principle.

The shaft 120 is rotatably inserted into the shaft hole 121 and is inserted into the inner ring inner diameter of the bearing 150 installed outside the shaft hole 121 and extends past the bearing 150. The shaft 120 extends horizontally. The shaft 120 may be made of a metal such as steel. A blade 130 is coupled to the extended portion of the shaft 120 and provided. One shaft 120 may be provided, but a plurality of pairs of shaft holes 121 may be formed, and a plurality of shafts may be inserted into each pair of shaft holes 121 to be provided. The plurality of shafts 120 are provided to be spaced apart from each other in the vertical direction. The shaft 120 is provided with a phase difference. When two shafts 120 are provided, as shown in FIG. 4, the two shafts 120 have a phase difference of 90°. When three shafts 120 are provided, the shaft 120 has a phase difference of 60°. When four shafts 120 are provided, the shaft 120 has a phase difference of 45°.

The shaft 120 is provided with a locking protrusion 141 protruding toward the side of the shaft 120. The rotation body 110 is provided with a stopper 115 to which the locking protrusion 141 is engaged. The mounting portion 160 is provided with a surface facing the locking protrusion 141 that rotates with the rotation of the shaft 120, and may act as a stopper 115. A locking member 140 positioned between the bearing 150 and the blade 130 and into which the shaft 120 is inserted may be provided, and the locking protrusion 141 protruding to the side thereof may be formed on the locking member 140. . The locking member 140 is a hollow body and a shaft is inserted into the locking member 140, and a key (not shown) is a pin (not shown) to prevent relative rotation of the locking member 140 and the shaft 120 It is inserted and provided. The locking member 140 and the shaft 120 may be splined and rotated integrally.

The blade 130 is provided on both sides of the shaft 120 with the rotating body 110 interposed therebetween. The blade 130 may be made of a metal such as steel, or a synthetic resin having high rigidity such as nylon 6 or nylon 66.

The blade 130 of the wind power generator 100 provided in the wind power generator according to the present invention is provided to rotate integrally with the shaft 120. The end of the shaft 120 may be provided by being forcibly fitted into the blade 130. A spline is provided at the end of the shaft 120 and the spline is inserted into the blade 130 so that the shaft 120 and the blade 130 are integrally rotated. It is also possible to have a polygonal end of the shaft 120 inserted and coupled to the blade 130. The blade 130 may have a shape of a quadrangular plate as shown in FIG. 4 in a form capable of generating wind power by wind. The shape of the blade 130 may be any shape capable of generating wind power by wind, and is not limited to a quadrangular plate shape.

Blades 130 provided on both sides of the shaft 120 are provided to have a phase difference from each other. Preferably, it has a phase difference of 90°. As shown in FIGS. 4 and 6, when the blade 130 provided on one side of the shaft 120 rotates and becomes horizontal, the blade 130 provided on the other side of the shaft 120 also rotates and becomes vertical. . In FIG. 6, when the rotating body 110 rotates in the direction "B" by the wind (indicated by the arrow "A"), the stopping protrusion 141 is caught on the stopper 115 and the blade 130 is vertically Thus, a rotational force for rotating the rotating body is generated in the blade 130 by the wind. As the rotating body 110 rotates with the shaft 120 by the rotational force acting on the blade 130, the blade 130 located on the load side rotates toward the no-load side, and the blade 130 located on the no-load side is the load side. Comes by rotating. The blade 130 rotating from the load side to the no-load side rotates in a horizontal state by external force F2 by the wind, and since the blade 130 and the shaft 120 rotate integrally, it rotates from the no-load side to the no-load side. The on-blade 130 rotates in the direction to be in a vertical state, and the locking protrusion 141 is caught by the stopper 115 so that it cannot be rotated anymore, so that the rotating body rotates by an external force F1 by the wind. Occurs.

Since the blades 130 provided on both sides of the shaft 120 rotate integrally with the shaft 120, and the blades 130 on both sides are installed with a phase difference, the blade 130 rotates to the no-load side by the wind. Since the rotation is a rotational force to rotate the on-blade 130 in the vertical direction through the rotation of the shaft 120, the rotation of the no-load side blade 130 is transmitted by the rotation of the shaft 120 The rotation of the blade 130 on the load side acts as an external force that assists rotation of each other, so that the rotation of the shaft 120 may proceed much smoothly and quickly. And accordingly, the rotation in the horizontal direction and the rotation in the vertical direction of both blades 130 are smoothly and rapidly progressed, and the maximum rotational (orbital) force in the load-side blade creates the minimum rotational resistance in the half-load side, so the maximum rotational force Is exerted.

7 and 8 are a plan view and a partially enlarged side view showing a wind power generation mechanism showing another example of the present invention provided in the wind power generation device. 7 and 8 is a one-side blade structure provided with a blade 130 only on one side of the shaft 120.

In the description of the wind turbine 100 according to another example of the present invention, redundant descriptions of the above-described contents are omitted, and only differences are described.

A wind turbine generator 100 according to another example of the present invention is rotatably provided with a rotating body 110 connected to and installed to a generator of a wind power generating device, and a bearing 150 on the rotating body 110 and rotatably provided. The entire 110 includes a plurality of shafts 120 protruding outward, blades 130 provided on the shaft 120, and a stopper 115 provided on the rotating body 110. The stopper 115 is disposed under the shaft 120 to the outside of the rotating body 110 and provided. The shaft 120 extends in a horizontal direction, and a plurality of shafts 120 are provided at equal intervals along the circumferential direction. The rotation body 110 has a circular upper surface, and the shaft 120 extends radially above the rotation body 110 so that the outer side protrudes from the rotation body 110. And the blade 130 is provided to rotate integrally on the protruding portion of the shaft 120. In FIG. 7, reference numeral 182 denotes an auxiliary locking protrusion described below.

The shaft 120 may be fixedly installed on the rotating body 110, and the blade 130 may be rotatably coupled to the shaft 120 via a bearing. When the blade 130 is rotatably coupled to the shaft 120, the locking protrusion 141 is provided with a structure that rotates integrally with the blade 130. A hollow insertion portion extending radially inward and into which the shaft 120 is inserted may be provided at an inner end of the blade 130 in the radial direction, and the locking protrusion 141 may be provided to protrude radially outward from the insertion portion.

In the above, the shaft 120 is spaced apart from both ends of the blade 130 in the width direction as shown in FIG. 4 and is coupled to the blade 130 at a position spaced apart from the center in the width direction. A first blade portion 130-1 and a second blade portion 130-2 are provided on both sides in the width direction of the portion where the shaft is coupled. The area of the first blad part 130-1 is larger than the area of the second blad part 130-2. As shown in FIG. 4, the shaft 120 may be coupled to a portion spaced approximately 1/6 from the center in the width direction of the blade 130. In the above, 1/6 may vary depending on changes in the shape, material, and thickness of the blade 130 and is described as an example.

As described above, the shaft 120 is spaced from both ends in the width direction of the blade 130, and is coupled to the blade 130 at a position spaced from the center in the width direction, so that the blade 130 is improved around the shaft 120. ,Right symmetrical and neutral state (both blades are in the form of ∧ by gravity), so that the blade 130 is reliably distinguished from the role of no-load, and at the same time, the reversal movement is made quickly, The rotation of the shaft 120 by the external force acting on the blade 130 by the wind becomes smooth and continuous, and noise or vibration caused by the contact between the stopping protrusion 141 and the stopper 115 is reduced.

As shown in FIGS. 7 and 8, in a one-side blade structure in which a blade is provided only on one side of the shaft 120, the shaft 120 is coupled to an end portion in the width direction of the blade 130. Since the blade is provided only on one side of the shaft 120, the canceling action cannot occur on the unloaded side and the load side. As shown in FIG. 4, the shaft 120 is spaced apart from the center of the width direction of the blade 130. It doesn't have to be combined.

As shown in Fig. 9, the length of the rotor 110 of the multilayered blade wind power generator 100 is lengthened, and the number of blades 130 is increased by installing a plurality of shafts 120 separated in the vertical direction. You can increase the efficiency. When two shafts 120 separated in the vertical direction are installed in a phase difference of 90° to each other as one set, the length of the rotating body 110 is lengthened, and as shown in FIG. 9, a plurality of sets of shafts 120 It is possible to install wind power.

As shown in Fig. 10, a plurality of wind power generators 100 are provided, and it is also possible to use an upper and lower layer reverse rotation blade wind power generator. A circular rotating body flange 120 extending radially outward is provided at the upper end of the rotating body 110 constituting the wind power generation device 100, and another wind power generation device 100 is provided on the upper part of the rotating body flange 120. ) Are stacked rotatably. By stacking and installing as described above, the generator 112 is stopped, and the upper rotor 110 (generator rotor) has a structure that rotates reversely to the upper rotor 110 (generator stator). ) Can be used when required to double the rotational speed of the generator 112 by connecting.

As shown in Fig. 11, it is also possible to have the two wind turbines 100 are horizontally aligned. An installation extension part (C2), a hollow body extending horizontally, is provided at the end of the connection part (C), and a generator is installed inside the installation extension part (C2), so that the rotor shaft of the generator extending on both sides of the generator It is installed to be rotatable by transmitting power. Rotators 110 constituting the wind power generation mechanism 100 are coupled to rotate integrally at both ends of the transmission shaft. It is a device that is connected integrally with the generator and is supported by the connection part C, and rotates the soft parts except for the connection part (C) and the fixed part (B) according to the wind direction in the required wind direction by the wind direction drive motor to generate electricity (wind direction control device and Drive not shown).

12 and 13, the wind turbine generator 100 according to the present invention further includes an auxiliary engaging portion 180. The rotation of the blade 130 is prevented by the auxiliary locking part 180, and the generator shaft can be repaired in a state in which rotation is stopped (neutral state) by a brake device. Alternatively, when excessive wind such as a typhoon blows, in order to prevent damage, the auxiliary locking unit 180 may be operated to prevent the blade 130 from rotating. The blade 130 rotated by the auxiliary locking part 180 is caught while being rotated at the same angle and rotation is stopped. Therefore, the wind that acts on the blade 130 at the load side to rotate the rotor 110 may be offset to some extent by the wind force that acts on the blade 130 at the no-load side to rotate the rotor 110 in the opposite direction. .

The auxiliary locking unit 180 is provided in the auxiliary locking member 189 rotatably installed on the installation unit 160 and the auxiliary locking member 189 provided on the shaft 120 to rotate the shaft 120 It includes an auxiliary locking protrusion 182 to prevent this, and a locking driving part 181 for rotating the auxiliary locking member 189 so that the auxiliary locking protrusion 182 is caught by the auxiliary locking member 189. The auxiliary locking protrusion 182 has a lower protruding height than the locking protrusion 141 so that it does not get caught by the stopper 115.

In the one-sided blade structure as shown in FIGS. 7 and 8, the auxiliary locking projection 182 acts to prevent further rotation by being caught by the stopper 115 when the blade 130 rotates to a horizontal position where wind resistance is minimized. Do it.

The locking driver 181 may be a hydraulic or pneumatic cylinder, or an electric cylinder having a solenoid structure made of a coil and a permanent magnet. A plate-shaped locking installation part 185 protruding outwardly is provided on the connection part C, and the locking driving part 181 may have a lower end fixedly installed on the locking installation part 185. The locking installation part 185 may have an annular plate shape and a connection part C is inserted therein, and an inner edge thereof may be welded to the outer surface of the connection part C to be fixed.

An auxiliary locking operation unit 183 is coupled to an upper end of the locking driving unit 181 and an upper end of a sliding rod. The auxiliary engaging operation part 183 is inserted into an annular plate shape so that the connection part C is reciprocated. The auxiliary locking member 189 is bent and has one end rotatably coupled to the installation unit 160 by a hinge. The bent end is upward. By the operation of the locking driving unit 181, the auxiliary locking operation unit 183 is raised to rotate the auxiliary locking member 189 upward, and the auxiliary locking protrusion 182 is caught at the bent end to prevent rotation of the shaft 120. . A buffer member 187 may be coupled to the lower portion of the auxiliary locking member 189, that is, opposite to the bent end 1891 of the auxiliary locking member 189 . As shown in the drawing, the buffer member 187 may be formed of a plate spring that is obliquely extended, or may be formed of a coil spring.

When the auxiliary locking operation unit 183 is raised by the operation of the locking driving unit 181 and the auxiliary locking member 189 is pushed up together with the buffer member 187, the auxiliary locking member 189 rotates around the hinge , The bent end is rotated toward the auxiliary locking projection 182, the auxiliary locking projection 182 is caught, so that the shaft 120 is not rotated. Therefore, the blade 130 is in a state in which it does not rotate. In the above, the auxiliary locking projection 182 is provided so that the inclination at the load side of the blade 130 and the inclination at the no-load side are the same. When the auxiliary locking operation unit 183 descends by the operation of the locking driving unit 181, the auxiliary locking member 189 comes down together with the buffer member 187, and the auxiliary locking member 189 rotates around the hinge, The bent end is rotated away from the auxiliary locking protrusion 182, and the locking with the auxiliary locking stone 182 is released.

100: wind turbine 110: rotating body
120: axis 130: blade

Claims (8)

A rotating body 110 connected to and installed in the generator of a wind power generator, at least one shaft 120 rotatably provided in the rotating body 110, and a shaft 120 with the rotating body 120 interposed therebetween The shaft 120 includes a blade 130 provided on both sides of the shaft 120 and rotates integrally with the shaft 120, and a stopper 115 provided on the rotating body 120, wherein the blade 130 moves toward the load side. While rotating, the shaft 120 is rotated in the direction applied to the stopper 115, and the rotor 110 is rotated by the wind acting on the blade 130, and the blade 130 rotates to the no-load side while the stopper 115 The shaft 120 rotates in a direction away from the axis 120 to reduce resistance due to wind power, and the blades 130 on both sides have a phase difference;
It further includes an auxiliary locking part 180, wherein the auxiliary locking part 180 is provided with an auxiliary locking member 189 rotatably installed on the installation unit 160, and an auxiliary locking member ( An auxiliary locking protrusion 182 that prevents rotation of the shaft 120 by being caught 189, and a locking that rotates the auxiliary locking member 189 so that the auxiliary locking protrusion 182 is caught in the auxiliary locking member 189 It includes a driving unit 181;
The locking driving part 181 is a cylinder that expands and contracts, and a plate-shaped locking installation part 185 protruding outwardly is provided on the connection part C, and the locking driving part 181 has a lower end on the locking installation part 185. Fixed installation; An auxiliary locking operation part 183 is coupled to the upper end of the locking driving part 181, and the connection part C is inserted into the auxiliary locking operation part 183 to enable reciprocating motion; The auxiliary locking member 189 is bent and has one end rotatably coupled to the installation unit 160 by a hinge, and the auxiliary locking operation unit 183 is raised by the operation of the locking driving unit 181 to increase the auxiliary locking member. Wind power generation mechanism (100), characterized in that the rotation of the shaft (120) is prevented by rotating the (189) upward and the auxiliary locking projection (182) is caught on the bent end. According to claim 1, The shaft (120) extends past the center of the rotating body (110), is provided in a plurality of spaced apart in the vertical direction; Each of the shafts 120 is a wind power generating mechanism 100, characterized in that the blades 130 are provided on both sides with the rotation body 110 interposed therebetween. The wind turbine generator (100) according to claim 1, wherein the shaft (120) extends in a horizontal direction, and a phase difference of the blade (130) is 90°. The wind turbine generator (100) according to claim 1, wherein the shaft (120) is spaced apart from both ends in the width direction of the blade (130), and is coupled to the blade (130) at a position spaced apart from the center in the width direction. delete delete A rotating body 110 connected to and installed in the generator of a wind power generator, and a plurality of shafts 120 rotatably provided on the rotating body 110 and protruding outwardly of the rotating body 110, and the shaft It is coupled to 120 and includes a blade 130 and a locking protrusion 141 that rotates integrally with the shaft, and a stopper 115 provided on the rotating body 110;
As the blade 130 rotates toward the load side by the rotation of the rotor 110, the blade 130 rotates in a direction applied to the stopper 115, and is caught by the stopper 115, and is caused by wind power acting on the blade 130. 110) rotates and the blade 130 rotates in a direction away from the stopper 115 while rotating toward the no-load side, thereby reducing the resistance of the blade 130 to wind power; The shaft 120 is spaced apart along the circumferential direction of the rotating body 110 is provided in plurality;
It further includes an auxiliary locking part 180, wherein the auxiliary locking part 180 is provided with an auxiliary locking member 189 rotatably installed on the installation unit 160, and an auxiliary locking member ( An auxiliary locking protrusion 182 that prevents rotation of the shaft 120 by being caught 189, and a locking that rotates the auxiliary locking member 189 so that the auxiliary locking protrusion 182 is caught in the auxiliary locking member 189 It includes a driving unit 181;
The locking driving part 181 is a cylinder that expands and contracts, and a plate-shaped locking installation part 185 protruding outwardly is provided on the connection part C, and the locking driving part 181 has a lower end on the locking installation part 185. Fixed installation; An auxiliary locking operation part 183 is coupled to the upper end of the locking driving part 181, and the connection part C is inserted into the auxiliary locking operation part 183 to enable reciprocating motion; The auxiliary locking member 189 has one end rotatably coupled to the installation unit 160 in a bent form by a hinge, and the auxiliary locking operation unit 183 is raised by the operation of the locking driving unit 181 to increase the auxiliary locking member. Wind power generation mechanism (100), characterized in that the rotation of the shaft (120) is prevented by rotating the (189) upward and the auxiliary locking projection (182) is caught on the bent end. 8. The wind turbine generator (100) according to claim 7, wherein the shaft (120) extends in a horizontal direction.

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