KR20100085229A - Horizontal-vertical axis variabe type wind power generation - Google Patents

Abstract

PURPOSE: A horizontal-vertical shaft variable type wind power generator is provided to minimize load applied on a tower, wherein an upper generator is only installed on a nacelle and a lower generator is installed on the ground through a vertical shaft. CONSTITUTION: A horizontal-vertical shaft variable type wind power generator comprises an upper generator(10), a vertical shaft(30), a power transmission unit(40), a lower generator(20), and a power control unit. A horizontal-vertical shaft variable type wind power generator comprises an upper generator is installed inside a nacelle(2) and generates power by the torque of a horizontal shaft(7). The vertical shaft is installed inside a tower(1). The power transmission unit selectively transfers the torque of the horizontal shaft to the vertical shaft. The lower generator is installed on the lower part of the tower and generates power by the torque of the vertical shaft.

Description

Horizontal-Vertical Axis variabe type Wind Power Generation}

The present invention relates to a horizontal-vertical shaft variable wind turbine, and more particularly, to minimize the load applied to a tower in a horizontal wind turbine to reduce installation costs and difficulty in installation and to maximize power generation. It relates to a vertical axis variable wind turbine.

Wind power generation refers to a power generation method that uses windmills to convert wind energy into mechanical energy (rotational power) through the main shaft, and this mechanical energy is converted into electrical energy by driving a generator to obtain power. It is not only the most economical among the new renewable energy sources, but also because of the advantage of being able to generate power using the wind, the clean energy source for unlimited use, active investors in Europe and the Americas and Asia in recent years It is happening.

Particularly, wind power generation is accompanied by cost aspects such as improving the price competitiveness of power generation costs and minimizing the required area of power generation system, and social and environmental aspects such as alternative energy sources for fossil energy depletion and global environmental protection such as prevention of warming. The government is actively supporting the dissemination of wind power generation due to economic advantages such as the stability of supply and the reduction of dependence on energy imports.

Wind turbines for wind power generation are divided into vertical shaft wind turbines and horizontal shaft wind turbines according to the direction of the rotation axis. Until now, horizontal wind turbines are more efficient and stable than vertical shafts. The generator is being applied.

In general, the horizontal axis wind turbine is composed of a rotor and a plurality of blades, the rotor blade rotated by the wind, the horizontal shaft coupled to the rotary blade portion driven by the rotation of the rotary blade portion, and the rotational force of the horizontal shaft It includes a generator that generates power by.

However, in such a conventional horizontal wind turbine, in order to obtain a lot of power, it is necessary to raise a blade or to install a generator corresponding to the size of the blade. As the blade and the generator become larger, the weight increases so that the heavy blade and the generator The size of the tower and the structure to support the system should be increased together. Also, if the power plant becomes heavy, the parts such as bearings to support its weight should be increased, and the direction of the rotor blade according to the direction of the wind will be changed. yaw) A special device must be installed for operation.

Therefore, due to such technical difficulties, the installation and maintenance costs are increased exponentially, and there is a problem that causes a huge obstacle to the wide spread of the wind power generator due to the increase in technical difficulty and cost.

The present invention has been made to solve the above-mentioned conventional problems, an object of the present invention is to equalize and minimize the load on the tower to significantly reduce the installation cost and the upper and lower generators according to the size of the wind power It is to provide a horizontal-vertical axis variable wind power generator that can maximize the amount of power by allowing the variable power generation.

The present invention as a problem solving means for achieving the above object,

The horizontal axis wind power generator is provided on one side of the nacelle, which is supported by the tower and is installed at a constant height from the ground, and has a rotary blade rotated by wind power, and a horizontal axis driven by the rotation of the rotary blade portion extends into the nacelle. An upper generator, which is installed inside the nacelle and generates power by the rotational force of the horizontal axis, a vertical axis installed inside the tower, and a power transmission unit for selectively transmitting the rotational force of the horizontal axis to the vertical axis, A lower generator installed under the tower to generate power by the rotational force of the vertical axis, and when the rotational force of the horizontal axis exceeds the power generation capacity of the upper generator, operate the power transmission unit to control the rotational force of the horizontal axis to be transmitted to the vertical axis. It characterized in that it comprises a power control unit.

Here, the upper generator is located on the opposite side of the rotary blade portion with respect to the tower, it is preferable to have a weight corresponding to the rotary blade portion so that the load applied to the tower can be balanced.

The power transmission unit is installed on the horizontal shaft, and the clutch operates to selectively apply or cut off the horizontal power in response to a control signal of the power control unit, and a first coupled to the clutch coupled to the clutch to which the rotational force is applied. It is preferable to include a bevel gear, and a second bevel gear is assembled at a right angle to the first bevel gear and coupled to the upper end of the vertical axis.

Horizontal-vertical axis variable wind turbine according to the present invention,

In the nacelle supported by the tower, only the upper generator having the minimum weight to balance the rotor blades and weight is installed, and the remaining excess power is diverted to the vertical axis to generate power from the lower generator installed on the ground. Therefore, the overall load applied to the tower is minimized to reduce the size of the overall support structure including the tower, thereby eliminating technical difficulties in installation and significantly reducing the installation and maintenance costs.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. In the following description of the present invention, if it is determined that the technical features of the present invention may be unnecessarily obscured as a matter already known to those skilled in the art, such as a known function or a known configuration, in detail The description will be omitted.

1 is a cross-sectional view showing the overall configuration of a horizontal-vertical axis variable wind turbine according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing the configuration of the power transmission unit 40 according to an embodiment of the present invention. 3A / B is an exemplary view illustrating an operating state of the power transmission unit 40, and FIG. 4 is a block diagram illustrating a schematic configuration of the power control unit 50 according to an embodiment of the present invention.

As shown in the drawings, the horizontal-vertical axis variable wind turbine according to an embodiment of the present invention is a tower (1) of a constant height standing on the ground, and the ground is rotatably installed on the top of the tower It includes a streamlined nacelle (2, Nacelle) located at a constant height from.

One side of the nacelle is composed of a rotor (4) having a plurality of blades (3) is provided with a rotary wing portion 5 which is rotated by the wind, the other side yak (2) is rotated in accordance with the wind direction (yaw) ) Tail wing (6, Wind Vane) is provided to help the operation.

A horizontal shaft 7 which is driven to rotate by the rotation of the rotary blade 5 is installed to extend into the nacelle 2, and generates electricity by converting the rotational force of the horizontal shaft 7 into electrical energy. Is provided.

The configuration as described above is the same as a conventional horizontal wind turbine, the horizontal-vertical axis variable wind turbine according to an embodiment of the present invention, the power generating unit for generating electricity in the upper portion is installed inside the nacelle (2) It is characterized by being divided into a generator 10 and a lower generator 20 installed on the lower part of the tower 1, that is, the ground, and thus installed on the upper generator 10 installed on the nacelle 2 and the ground. Composed of the lower generator 20 is to minimize the load on the tower (1) and to balance the load applied.

The upper generator 10 is installed in the nacelle 2 connected to the horizontal shaft 7 like a conventional horizontal wind power generator, and generates power by converting the rotational force of the horizontal shaft 7 into electrical energy. Will be

Here, the upper generator 10 is located on the opposite side of the position where the rotary blade 5 is installed around the tower 1, to have a weight corresponding to the weight of the rotary blade 5 It is preferable.

That is, in the present invention, the upper generator 10 does not consider the power generation capacity corresponding to the size of the rotary blade portion 5, but the balance between the rotary blade portion 5 and the weight around the tower (1) Considering the weight to achieve, the upper generator 10 is to be adopted to have a minimum weight that can balance the weight with the rotary blade (5).

Thus, the upper generator 10 installed inside the nacelle 2 has a minimum weight corresponding to the rotor blade 5 so that a minimum uniform load is applied to the tower 1 so that the Yaw operation can be made by the action of the tail wing 6 without a separate device, it is not necessary to install a separate structure to distribute the load applied to the tower (1).

When wind power exceeding the generating capacity of the upper generator 10 having the minimum weight is applied, the rotational power of the horizontal shaft 7 is transferred to the lower generator 20 installed on the ground to further generate power. It is.

Thus, in order to transmit the rotational force of the horizontal shaft (7) to the lower generator 20, the horizontal-vertical axis variable wind turbine according to an embodiment of the present invention is a vertical shaft 30, the power transmission unit 40, The power control unit 50 is further included.

The vertical shaft 30 is rotatably installed in the inside of the tower (1), is driven to receive the rotational force of the horizontal shaft (7) by the power transmission unit 40 to be described later, the lower generator 20 Is generated by the rotational force of the vertical axis (30).

Reference numeral 35 is a bearing connecting portion for rotatably connecting each vertical shaft 30 when the vertical shaft 30 is installed in multiple stages in order to prevent vibration, etc. according to the height of the tower 1.

The power transmission unit 40 is for selectively transmitting the rotational force of the horizontal shaft (7) to the vertical shaft (30), as shown in Figure 2, the clutch 41 is installed on the horizontal shaft (7), and The first bevel gear 42 is coupled to the clutch 41 and interlocked with each other, and the second bevel gear 43 is coupled to the upper end of the vertical shaft 30 while being perpendicular to the first bevel gear 42. .

The clutch 41 is coupled to the outer periphery of the horizontal shaft (7) to operate to selectively apply or block the rotational force of the horizontal shaft (7), such a clutch (41) by Hyundai Clutch (www.hyundaiclutch. com) is a well-known technology that is already produced in various clutch companies.

Therefore, a detailed configuration of the clutch 41 will be omitted, and will be briefly described. As shown in FIG. 2, the clutch 41 is rotated together with the horizontal axis 7 so that the horizontal axis ( 7) the first clutch member 41a fixedly coupled to the second clutch, and the second clutch member 41b coupled to the horizontal shaft 7 via a bearing to maintain an idling state regardless of the rotation of the horizontal shaft 7; And a clutch ring 41c between the first clutch member 41a and the second clutch member 41b.

In addition, a magnetic force is generated in the internal coil 41d in response to the application or interruption of power by a control signal of the power control unit 50, which will be described later. The clutch ring 41c is moved by the magnetic force, and the first clutch member 41a is moved. It is to operate to selectively transmit the rotational force of the second clutch member (41b). 3A shows a state in which the rotational force of the horizontal shaft 7 is blocked, and FIG. 3B shows a state in which the rotational force is transmitted.

The first bevel gear 42 is coupled to the second clutch member 41b of the clutch 41 to rotate interlocked with the second clutch member 41b, and the second bevel gear 43 assembled at right angles. By rotating, the rotational force is transmitted to the vertical axis 30.

The power control unit 50 controls the operation of the clutch 41 of the power transmission unit 40 so that the rotational force of the horizontal shaft (7) can be selectively transmitted to the vertical axis (30), for which As described above, the controller 50 may include a storage unit 51, a speed sensing unit 52, and a power transmission control unit 53.

The storage unit 51 stores the data on the power generation capacity of the upper generator 10, the speed detection unit 52 detects the rotational speed (RPM) of the horizontal axis (7) in real time.

The power transmission control unit 53 is a microprocessor (CPU), and determines the amount of power generated according to the rotational speed of the horizontal axis 7 sensed by the speed sensing unit 52 to exceed the generated capacity of the upper generator 10 stored therein. If the wind power applied exceeds the power generation capacity of the upper generator 10, by operating the power transmission unit 40 so that the rotational force of the horizontal axis 7 is transmitted to the vertical axis 30 by lower power generator ( 20) the development will be made.

If briefly described the installation and operation of the horizontal-vertical axis variable wind turbine according to an embodiment of the present invention made of the configuration as described above.

First, the size of the blade 3 can be set in consideration of the general wind speed and the amount of power generated in the region where the wind power generator according to the present invention is installed, and accordingly, the overall weight of the rotary blade 5 is determined, and the upper generator ( 10) is installed to have a minimum weight for balancing the load applied to the tower 1 in consideration of the weight of the rotary blade (5).

That is, if the rotary blade 5 can produce about 10 kW at a typical wind speed, the upper generator 10 can be balanced around the tower 1, such as 500W, 1 ,, 2㎾, etc. It is to be installed so as to have a minimum weight corresponding to the weight of the rotary blade 5, the lower generator 20 is installed on the ground for the amount of excess power generated.

When the wind is blown and the rotary blade unit 5 is rotated in the installed state, the rotational force is transmitted to the upper generator 10 through the horizontal shaft 7 to generate power. If the power generation capacity of the generator 10 is not exceeded, rotational force is not transmitted to the vertical shaft 30, and power generation is performed only in the upper generator 10.

In this state, if the wind speed increases and the rotational force of the horizontal shaft 7 is increased, the speed sensing unit 52 of the power control unit 50 detects this, and the current rotational force is transmitted from the power transmission control unit 53 to the upper generator 10. When it is determined that the power generation capacity of the power generator 40, the clutch 41 of the power transmission unit 40 to operate the excess rotational force of the horizontal shaft 7 to be transmitted to the vertical shaft 30 in the lower generator 20 installed on the ground It is to allow further development.

As such, the upper generator 10 supported by the tower 1 and installed at a predetermined height is installed only to have a minimum weight to balance the rotary blade 5, and the excess energy is lowered to the ground. Because it can be used in the generator 20, while maximizing the amount of power generation, it is possible to significantly reduce the installation and maintenance costs by reducing the size of the overall support structure, including the tower.

Although the preferred embodiments of the present invention have been described above, the technical scope of the present invention is not limited to the above-described embodiments and the contents described in the drawings, and equivalents modified or changed by those skilled in the art. The configuration will be said to be within the scope of the technical idea of the present invention.

1 is a cross-sectional view showing a horizontal-vertical axis variable wind turbine according to an embodiment of the present invention;

2 is a cross-sectional view of the power transmission unit according to an embodiment of the present invention;

Figure 3a / b is an illustration of the state of use of the power transmission unit according to an embodiment of the present invention,

4 is a schematic view of a power control unit according to an embodiment of the present invention.

＊ Explanation of symbols on major part of drawing ＊

1: tower 2: nacelle

3: blade 4: rotor

5: rotary wing part 6: tail wing

7: horizontal axis

10: upper generator 20: lower generator

30: vertical axis 40: power transmission unit

41: Clutch 42: First Bevel Gear

43: second bevel gear 50: power control unit

51: storage unit 52: speed detection unit

53: power transmission control unit

Claims (3)

The horizontal axis wind power generator is provided on one side of the nacelle, which is supported by the tower and is installed at a constant height from the ground, and has a rotary blade rotated by wind power, and a horizontal axis driven by the rotation of the rotary blade portion extends into the nacelle. To An upper generator installed inside the nacelle to generate power by the rotational force of the horizontal shaft; A vertical shaft installed inside the tower; A power transmission unit for selectively transmitting the rotational force of the horizontal axis to the vertical axis; A lower generator installed at a lower portion of the tower to generate power by the rotational force of the vertical axis; And A power control unit which controls the rotational force of the horizontal axis to be transmitted to the vertical axis by operating the power transmission unit when the rotational force of the horizontal axis exceeds the power generation capacity of the upper generator; Horizontal-vertical axis variable wind turbine comprising a. The method of claim 1, The upper generator is located on the opposite side of the rotary blades with respect to the tower, horizontal-vertical shaft variable wind power generation, characterized in that having a weight corresponding to the rotary blades to balance the load applied to the tower Device The method of claim 1, The power transmission unit, A clutch installed on the horizontal shaft and operative to selectively apply or cut off the horizontal power of the horizontal shaft according to a control signal of the power control unit; A first bevel gear coupled to the clutch and interlocked with a clutch to which rotational force is applied; And A second bevel gear assembled at a right angle with the first bevel gear and coupled to an upper end of the vertical axis; Horizontal-vertical shaft variable wind power generator comprising a

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