KR20090081791A - Horizontal Axis Wind Power Generator Using Double Wings - Google Patents

Abstract

A horizontal axis wind turbine generator using a dual blade is provided to generate with the small blade when the wind velocity is out of the set range of the large blade. A horizontal axis wind turbine generator using a dual blade comprises a first rotation shaft(110) installed on the front part of the generator body, a large blade(112) installed at a first hub(111) of the first rotation shaft, a first speed increasing gear device(120) connected to the backend of the first rotation shaft, a generator(300) connected to the output terminal of the first speed increasing gear device, a first brake device(130) decelerating or stopping the first rotation shaft, a second rotation shaft installed on the rear part of the body late in parallel to the wind direction, a small blade(212) installed on a second hub of the second rotation shaft, a second speed increasing gear device(220) connected to the second rotation shaft, a second brake device(230) decelerating or stopping the second rotation shaft, and a controller(400) selecting and operating the first and second brake devices according to the wind velocity.

Description

Horizontal Axis Wind Turbine Generator Using Dual Blade and Operating Method

The present invention relates to a horizontal axis wind power generation device, and in particular, by using a double wing wind power generation to increase the power generation efficiency by increasing the wind power range of the horizontal axis wind power generator of the upwind type to facilitate the initial driving of the wing Relates to a device.

As is well known, the upwind-type horizontal axis wind turbine is one of the most common types of horizontal-axis wind turbines (HAWTs) in which the axis of rotation of the blades is parallel to the wind flow. Compared to the downwind type, which receives the wind passing through it, it is an upwind type power generation device that receives the wind from being placed on the tip of the fuselage.

The horizontal wind turbine of this upwind type has a nacelle rotatably installed horizontally about a vertical axis at the top of a tower, and at least one blade is installed at a hub of the front end of the tower. A rotor is installed at the rear of the hub, i.e., inside the fuselage, and an increase gear device and a generator are sequentially connected to the end of the rotor shaft, and a brake device is provided to reduce the rotation shaft or stop the rotation. do.

However, such a wind power generator can use the wind power only when the wind blows into the design wind speed range, and the power generation efficiency is low because it is not used when the wind winds away from the design wind speed. That is, if the wind speed at the hub height is outside the start wind speed (Vin: cut-in wind speed) and the end wind speed (Vout: cut-out wind speed), The wind speed range that can be developed is limited.

In addition, in order for the vane to stop and rotate again, the weight of the vane, the rotational axis and the moment of inertia of the gear unit (ie the resistive force), and the resistance due to the gear engagement or the viscosity of the lubricant in the gearbox must be overcome. Therefore, it requires a lot of energy, so that even if the wind blows at the start wind speed, there is a problem that the start is not started or the start is delayed.

The present invention was developed to solve the problems of the conventional horizontal axis wind power generator as described above, an object of the present invention is to expand the wind power generation range of the wind power generator to improve the power generation efficiency.

In addition, the present invention is to facilitate the initial drive of the wing in addition to the above object.

The object of the present invention described above is to provide a horizontal wind turbine generator using a double wing to install a small wing of the rear wind type in the rear of the fuselage in addition to the large wind blades installed on the front end of the fuselage and to use them for power generation. Is achieved.

Specifically, the horizontal axis wind turbine generator using the double blade of the present invention, the body is rotatably installed around the vertical axis on the top of the tower; A first rotating shaft installed in the first half of the fuselage in parallel with a wind flow direction; A first hub installed on a first rotation shaft of the fuselage tip and a large-blade wing having a radial wind installed thereon; A first speed increasing gear device connected to a rear end of the first rotation shaft; A generator connected to an output end of the first speed increasing gear device; A first braking device for slowing down or stopping rotation of the first rotating shaft; A second rotating shaft installed in the rear half of the fuselage in parallel with a wind flow direction; A second hub installed at a second rotation shaft of the fuselage rear and a rear wind small blade installed radially thereto; A second speed increasing gear device connected to the second rotation shaft; A second braking device for slowing down or stopping the rotation of the second rotating shaft; And a controller for selecting and manipulating the first braking device and the second braking device according to the wind speed. When the wind is within the range of the start wind speed and the end wind speed, power is generated by the large blades, and the wind It is characterized in that the power generation is made by the small blade when out of the range of the end wind speed.

In the wind power generator according to the present invention, a converter for converting alternating current of the generator into direct current, a power storage device for storing current through the converter, and electrical energy of the power storage device under control of the controller. It may further include an electric motor for driving the large blade by rotating the input shaft or the first rotary shaft of the first speed increasing gear device.

According to the present invention, a large wing and a small wing are provided in front and rear of the fuselage, and the wind power can be generated by the small wing when the wind speed is outside the range of the start wind speed and the end wind speed set on the large wing, thereby generating a wind speed range. Can be extended, thereby improving the efficiency of the wind turbine.

In addition, according to the present invention, the energy generated by the wind power through the small blades can be stored in the power storage device and used as energy for the initial startup of the large blades, thereby easily driving the driving force required for the initial startup of the large blades in a stationary state. Wind turbines with improved utilization rates can be implemented.

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

1 is a perspective view schematically showing the appearance of a horizontal axis wind turbine generator using a double wing according to the present invention. As shown in FIG. 1, the wind power generator is installed on the top of the tower 50 in a rotatable manner with a body 100 rotatably installed on a vertical axis, and installed in parallel with a direction of wind flow in the first half of the body 100. It includes a first rotating shaft 110, the first hub 111 is installed at the front end of the first rotating shaft 110, the large blade 112 of the upwind type (Upwind type) Is installed radially. In parallel with this, a second hub 211 is installed at the rear end of the second rotating shaft 210 at the second half of the fuselage 100, and a small wing 212 having a downwind type is provided at the second hub 211. It is installed radially. The large blade 112 and the small blade 212 is set to match the direction of rotation. For example, when the large blade 112 is rotated clockwise due to the wind, the small blade 212 is set to rotate clockwise with the wind back through the large blade 112 as the back wind. In this way, the front of the fuselage 100 is provided with a large blade 112 known in the prior art, a small blade 212 is installed behind the fuselage 100, the wind is set on the large blade 112 When within the range of the start wind speed (Vin) and the end wind speed (Vout), the power is generated by the large blade 112, and when out of the range of the start wind speed and the end wind speed (Vin), the power can be generated by the small blade (212) It extends the range of wind speeds that can be generated.

2 is a schematic diagram showing the configuration of a horizontal axis wind turbine generator according to a first embodiment of the present invention. As shown in FIG. 2, a first speed increasing gear device 120 is connected to a rear end of the first rotating shaft 110 in which the large blade 112 described above is installed, and at an output end of the first speed increasing gear device 120. Generator 300 is installed. The first speed increasing gear device 120 serves to increase the rotation speed input from the first rotation shaft 110 rotated by the large blade 112 to a rotation speed suitable for electric power generation of the generator 300. In addition, a first braking device 130 is installed on the first rotation shaft 110 to decelerate or stop the rotation of the first rotation shaft 110.

On the other hand, the second speed increasing gear device 220 is connected to the rear end of the second rotating shaft 210, the small blade 212 is installed above, the output terminal of the second speed increasing gear device 220 is the generator 300 Is connected to. In addition, a second braking device 230 is installed on the second rotation shaft 210 to slow down or stop the rotation of the second rotation shaft 210.

Power generation by the large blade 112 and the small blade 212 is controlled by the controller 400. The controller 400 performs a control operation of selecting one of the first braking device 130 and the second braking device 230 according to the wind speed.

The wind turbine generator of the present invention may include a main controller 500, a trip controller 600, and an associated facility 700. The main controller 500 controls the linkage between the wind turbine and the external grid, and the trip controller 600 is urgently disconnected between the grids in order to prevent the occurrence of a failure occurring in the internal or external grid of the wind turbine. To perform, the linkage facility 700 is electrically connected to the wind power generator and the external system, the signal.

Figure 3 schematically shows the operation of the horizontal axis wind turbine generator using the double blade of the present invention made as described above. It demonstrates with reference to FIG. First, when the wind speed is more than the start wind speed (Vin) and less than the end wind speed (Vout), a force acts on the large blade (112) and the large blade (112) rotates. The rotational motion of the large blade 112 by the wind energy is transmitted to the first rotation shaft 110 through the first hub 111 is changed to the rotation force, that is, the rotation moment. Subsequently, the number of revolutions is increased through the first speed increase gear device 120 (usually about 54 times speed increase) and then transferred to the generator 300 to be converted into electrical energy.

On the contrary, when the wind speed is greater than or equal to the end wind speed Vout or less than the start wind speed Vin, a driving command is given to the first braking device 130 of the wind turbine according to the present invention, and the first braking device 130 causes the first rotation shaft ( Grab 110 to stop the rotation of the large blade (112). Then the energy of the wind acts on the small wing 212 to move the small wing (212). The rotation of the small blade 212 is transmitted to the second rotation shaft 210 through the second hub 211. Subsequently, the rotational force of the second rotating shaft 210 is increased while the second speed increasing gear device 220 is increased (usually about 54 times increased), and then transferred to the generator 300 and converted into electrical energy.

4 and 5 are schematic diagrams showing the configuration of a horizontal axis wind turbine generator according to a second embodiment of the present invention. As shown in FIG. 4 and FIG. 5, the wind power generator according to the present embodiment includes the converter 800, the power storage device 810, and the electric motor 900 as compared to the wind power generator according to the first embodiment. Consists of more configuration. The converter 800 converts the alternating current of the generator 300 into direct current, the power storage device 810 stores the current through the converter 800, and the electric motor 900 is the controller described above. The large blade 112 is driven by the electric energy of the power storage device 810 under the control of 400 and rotates the input shaft (not shown) or the first rotation shaft 110 of the first speed increase gear device 120. Start up. That is, in a state where the wind strength is too weak or the large blade 112 is stopped by exceeding the terminal wind speed Vout as described above, the wind speed just exceeds the starting wind speed Vin set in the large blade 112. Initial maneuvering of the large blade 112 is difficult. In order to prepare for this time, an extra current is stored in the power storage device 810 at the time of power generation, or preferably, the current produced by the rotation of the small blade 212 is stored in the power storage device 810, and the large blade 112 At the initial startup of the large blades 112 to be used as energy to rotate. When a current is applied to the motor 900, the motor 900 rotates an input shaft (not shown) or the first rotation shaft 110 of the first speed increasing gear device 120 so that the large blade 112 can be easily started. do.

As described above, the electric motor 900 may be connected to the input shaft of the first speed increasing gear device 120 to thereby rotate the first rotating shaft 110, and may be directly connected to the first rotating shaft 110 to rotate the same. have.

5 shows an example of a structure for connecting the electric motor 900 to the large blade 112. As shown in FIG. 5, the driven gear 910 is installed on the first rotational shaft 110 (which may be an input shaft of the first speed increasing gear unit 120), and the electric motor 900 may be installed therein. Engage drive gear 920. If necessary, the idle gear 921 may be restarted between the drive gear 920 and the driven gear 910, and a reduction gear 930 is further provided on the output side of the motor 900, thereby providing an electric motor 900. It is possible to reduce the rotational speed of the to increase the rotational force to be transmitted to the drive gear 920.

As described above, the present invention is to install a large wing in the front of the fuselage and a small wing in the rear of the fuselage, when the wind speed is within the range of the start wind speed and the end wind speed set in the large blade, the power generation by the large blade However, it may be generated by small vanes when it is outside the range of starting wind speed and terminal wind speed. Therefore, in the conventional wind turbine generator, when wind speed is out of a set range using only one blade (that is, a large blade), wind power generation is impossible, but according to the present invention, the wind power can be generated by providing small blades in parallel. The range has been extended to enable more efficient wind turbines.

In addition, the present invention can store the energy generated by the wind through the small blades in the power storage device can be used as the energy required for the initial start-up of the large blades. Therefore, in the conventional wind power generator, it takes a long time to restart the large blade stationary, but according to the present invention can provide a driving force necessary for the initial start of the large blade can implement a wind power generator with improved operation rate .

1 is a perspective view schematically showing the appearance of a horizontal axis wind turbine generator using a double wing according to the present invention.

2 is a schematic diagram showing the configuration of a horizontal axis wind turbine generator according to a first embodiment of the present invention.

3 is a flowchart schematically illustrating an operation process of a horizontal axis wind turbine generator according to a first embodiment of the present invention.

4 is a schematic view showing the configuration of a horizontal axis wind turbine generator according to a second embodiment of the present invention.

FIG. 5 is a view showing an example of a connection relationship between the electric motor of FIG. 4 and the input shaft of the first rotational shaft or the first speed increasing gear device.

<Explanation of symbols for the main parts of the drawings>

50: tower 100: fuselage

110: first axis of rotation 111: first hub

112: large wing 120: first speed gear device

130: first braking device 210: second rotating shaft

211: second hub 212: small wing

220: second speed increasing gear device 230: second braking device

300: generator 400: controller

500: main control unit 600: trip control unit

700: linkage 800: converter

810: power storage device 900: electric motor

910: driven gear 920: drive gear

921: idle gear 930: reducer

Claims (2)

A fuselage installed rotatably around a vertical axis at the top of the tower; A first rotating shaft installed in the first half of the fuselage in parallel with a wind flow direction; A first hub installed on a first rotation shaft of the fuselage tip and a large-blade wing having a radial wind installed thereon; A first speed increasing gear device connected to a rear end of the first rotation shaft; A generator connected to an output end of the first speed increasing gear device; A first braking device for slowing down or stopping rotation of the first rotating shaft; A second rotating shaft installed in the rear half of the fuselage in parallel with a wind flow direction; A second hub installed on the second rotating shaft of the fuselage rear and a small wind blade having a rear wind type radially installed on the second hub; A second speed increasing gear device connected to the second rotation shaft; A second braking device for slowing down or stopping the rotation of the second rotating shaft; And And a controller configured to select and manipulate the first and second braking devices according to wind speed. When the wind is within the range of the start wind speed and the end wind speed, the power generation is generated by the large blade, and when the wind is out of the range of the start wind speed and the end wind speed, the power generation can be generated by the small blade. Horizontal axis wind turbine generator using wings. The method of claim 1, A converter for converting alternating current of the generator into direct current; A power storage device for storing current through the converter; A horizontal axis using a double blade, characterized in that it further comprises an electric motor driven by the electrical energy of the power storage device under the control of the controller to rotate the input shaft or the first rotary shaft of the first speed increasing gear device to start the large blades Wind power generation device.

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