KR20050043115A - Force-generating apparatus using the wind - Google Patents

Abstract

The present invention can receive wind in any direction irrespective of the wind direction to generate wind power, and the axis of the rotor is also perpendicular to the wind direction to simplify the structure of the speed increasing gear system, thereby increasing the efficiency of the wind as a whole Wind turbines are simple and structured.

An example of such a wind turbine is the installation of a specially designed guide means outside the circumferential direction of a rotor, similar to the impeller of a centrifugal blower, to allow the wind to act efficiently on the rotor. By increasing the wind collecting area by increasing the wind speed, the wind speed acting on the rotor can be increased to generate wind power even when the wind speed is low. The bevel gear that changes the angle by 90 degrees becomes unnecessary, and the structure is simplified.

Description

Wind power unit {force-generating apparatus using the wind}

The present invention relates to a wind turbine, and more particularly, to receive wind in any direction irrespective of the wind direction, to generate wind power, and to simplify the structure of the speed increasing gear system by making the axis of the rotor perpendicular to the wind direction. Accordingly, the present invention relates to a wind power device that can improve the efficiency of wind power as a whole and has a simple structure.

Global environmental issues and the depletion of fossil energy have led to the development of new clean energy, wind and sunlight being the most widely used alternatives.

Among them, wind energy has been developed and used mainly for large propeller type wind turbines. However, the cost of generating energy is high because the wind conditions are limited and the products are expensive. In particular, it is less useful than the sunlight energy for small application.

Therefore, in order to increase the utilization, it is necessary to develop a cheaper and simpler structure of the wind turbine.

Wind energy, along with solar energy, is the most convenient energy source available anywhere. However, depending on the strength and quality of the wind, the use is currently very limited, there is a problem that the economic efficiency is low.

Therefore, it is necessary to construct a highly efficient system that is limited to the wind quality and the price of the product so that it can be used in a wide range, so that it can be used in a wider range.

In addition, since a general wind turbine uses a propeller-shaped blade, the wind turbine is first obtained by rotating the blade in a windy direction and maintaining it. Therefore, if the wind direction changes frequently or the speed of change is high, the efficiency of the wind will inevitably decrease, and there is also a problem that the probability of equipment failure increases. That is, in general, the wind turbine is turned in the direction of the wind and the rotor is turned to generate the wind. Therefore, if the wind direction changes frequently or if the wind speed changes very rapidly, such as a gust, the gear system may be damaged or the wind turbine may not follow. The efficiency of is bound to be greatly reduced.

 Accordingly, the present invention is to solve this problem and to meet the above-mentioned demands, and the device receives wind in all directions so that the wind can be generated by the wind in any direction, and the axis of the rotor is also perpendicular to the wind direction. The purpose of the present invention is to simplify the structure of the speed increasing gear system, thereby increasing the efficiency of the wind as a whole, and to provide a wind power device with a simple structure.

In order to achieve the above object, a wind device according to an embodiment of the present invention is a wind device for generating a force by wind regardless of a change in wind direction: a plurality of wind turbines that generate rotational force by the force of wind. A rotor assembly including at least a rotor and a shaft for transmitting rotational force of the rotor by rotating with the plurality of rotors; And wind direction toward the rotor side at the upstream of the rotor regardless of the wind direction, and redirects the wind in a direction for efficiently rotating the rotor, and downstream of the rotor to guide the outflow of wind from the rotor. It characterized in that it comprises a guide means that is fixedly installed.

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

1 shows a schematic cross-sectional view of an embodiment of the present invention together with a cross-sectional shape of a guide vane and a rotor blade, and FIG. 2 shows an operating state of FIG. 1.

In FIG. 1, the wind power device of the present invention basically includes a rotor assembly 12 and guide means 11 which generate rotational force by wind to generate force by wind regardless of the change in wind direction. .

The rotor assembly 12 includes a plurality of rotor blades 12c that generate a rotational force by the force of the wind, and the plurality of rotor blades 12c have a direct shaft (as shown in FIGS. 1 to 4B). 13, or as shown in FIGS. 5A and 5B, the plurality of rotor blades 32c are indirectly spaced apart from the shaft 13 and indirectly via the main plate 32a or 22a or the side plate 32b. It can be configured to be rotated together while being supported by the bearing means 17 by being fixed to the 13 to transmit the rotational force of the rotor blade 12c to the outside.

The rotor blade 12c configured as described above has a radial flow secondary shape of a radial flow or a mixed flow in the impeller of the centrifugal blower. It may be curved. That is, the airfoil (FIG. 3) or the plate may be molded into a primary or secondary curve, and the length of the rotor blade may be increased or the diameter of the rotor blade may be increased while performing the same performance depending on the wind conditions or the installation conditions. In addition, an aluminum alloy that is light and maintains some strength may be used.

The shaft 13 is light and yet capable of sufficiently transmitting torque, and a durable material is preferable. The shaft 13 transmits power through a gear group 18 capable of increasing or decreasing speed by applying an appropriate gear of high efficiency according to the use. Since the direction of the shaft 13 is vertical, it is also easy to connect with the apparatus used.

The guide means 11 is configured to wind the wind upstream of the rotor blade 12c, regardless of the wind direction, and to change the direction of the wind in a direction for effectively rotating the rotor blade 12c. . Although the guide means 11 winds in the vertical direction and the circumferential direction in the example of the figure, it is shown in any of the vertical direction (the collection wind due to the difference in height in the vertical direction) and the circumferential direction (the collection wind due to the difference in radial circumference). It may be collected only in one direction, the guide means 11 may be configured to be separated for each direction, or may be configured to be separated for the wind and the direction change. The guide means 11 can also be formed as a guide vane form that can be blown, formed into an airfoil shape or a primary curved shape of a plate, and is designed so that the wind direction can effectively act on the rotor blade 2. In addition, the guide means 11 is fixedly installed around the rotor blade 12c, so that the downstream of the rotor blade 12c guides the outflow of wind from the rotor blade 12c to face the original wind direction. . Insect repellent means such as a net is preferably installed on the outer circumference to prevent the introduction of insects.

In addition, the main plate 12a and the side plate 12b are fixed to both ends of the plurality of rotor blades 12c. Such a main plate 12a may be in the shape of a blocked original plate 22a as shown in FIGS. 4B, 5B, 6B and 7, and after the wind acts on the rotor blade 12c at least, It may also be open centrally as shown in FIGS. 4A and 5A to allow a portion of the to flow out.

The side plate 12b may also be a disc with an open center in FIGS. 4A to 5B, or a center part may be opened to the greatest extent in FIGS. 6A and 6B, and may be configured in a structure in which the side plate 12b is not installed at all. have. Although not shown, the side plate 12b may also be a closed disc similar to the main plate 12a.

As shown in FIG. 7 as an example, when the rotor blade 22c is a secondary curved shape of a mixed flow, the radially introduced wind may be configured to pass mostly through the upper casing 14 of the upper portion. have.

Meanwhile, in FIGS. 1 to 7, the upper casing 14 and the lower casing 15 are installed to be fixed to the upper and lower ends of the guide means 11. The upper casing 14 and the lower casing 15 are formed of a steel plate structure so as to easily maintain the strength of the entire structure and to protect the apparatus used, and at least the central portions of the main plate 12a and the side plate 12b are If opened, a vent 16 is provided. Further, the wind flows in and out through the vent 16 to generate negative pressure in the open portions of the main plate 12a and the side plate 12b, thereby facilitating the flow of wind through the open portion of the side plate 12b, thereby improving wind efficiency. It is preferable that the upper guide 9 be installed below the upper casing 14 so as to increase the height. The upper guide 19 is composed of a curved surface with a smooth lower surface, so that the pressure of the passing air is increased, and a negative pressure is formed so that air exits from the rotor blade 12c through the central opening of the side plate 12b. It is possible to smoothly discharge through) can increase the efficiency of the wind power.

In FIG. 2, when the wind direction is in the directions of arrows A and A ', the outlet of the guide means 11 flows out in the direction of arrow B, and the rotor blade 12c rotates in the direction of arrow C by the wind in the direction of arrow B, and again. It flows out in the direction of arrow D through the opposite guide means 11. On the other hand, when the central portions of the main plate 12a and the side plate 12b are opened, part of the wind flows out toward the upper casing 14 and the lower casing 15 in the directions of the arrows E and E ', and the upper casing 14 and The lower casing 15 flows out in the direction of arrows F and F 'with the wind in the direction of arrow A. FIG.

Moreover, the outgoing wind power and the amount of air flow in the directions of the arrows D, E, E ', F, and F' are varied depending on the size of the center opening of the main plate 12a and the side plate 12b and the structure of the rotor blade 12c. Can be. That is, as shown in FIGS. 4A and 4B, the wind in the direction of arrow D may be configured to be stronger than the wind in the directions of arrows E, E ', F, and F', and as shown in FIGS. 5A and 5B, arrows D and E. , Winds in the directions of E ', F and F' may be configured to be equal to each other, and winds in the directions of arrows E, E ', F, and F' are three times higher than those in the direction of the arrow D, as shown in FIGS. 6A to 7. It can be configured to.

As described above, the present invention, by installing a specially designed guide means outside the circumferential direction of the rotor of the shape similar to the impeller of the centrifugal blower, the wind effectively acts on the rotor, guide vanes to increase the effect more Increasing the wind collecting area by increasing the inlet side of the wind, increases the wind speed acting on the rotor blades so that the wind can be generated even when the wind speed is low. Since the bevel gear for changing the transmission direction by 90 degrees is unnecessary, the structure is simplified.

According to the configuration and operation of the wind power device according to the embodiment of the present invention described above, first, the performance can be maintained regardless of the change speed and the change frequency of the wind direction. Therefore, it can be used particularly effectively even in areas where wind direction changes are large.

In addition, by adjusting the entry angle of the wind turning the rotor through the guide vane can maximize the efficiency of the wind turbine can be used at low wind speeds.

In addition, due to the lack of direction, the structure is simple, so the probability of failure is low, the price is low, and the overall height is low, so that the installation conditions are advantageous compared to the conventional large propeller type wind turbine, and the diameter of the rotor may be increased depending on the installation conditions. In addition, it is possible to increase the height of the rotor, so that the field adaptability is excellent.

1 is a schematic cross-sectional view showing the configuration of an embodiment of the present invention with the shape of the guide vane and the rotor blade;

FIG. 2 is a view similar to FIG. 1 for illustrating an operating state of FIG. 1;

3 is a cross-sectional view showing the shape of an airfoil employed in the present invention;

4A through 7 are views similar to those of Fig. 1 showing various configurations according to embodiments of the present invention.

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

11: guide means 12: rotor assembly

12a: abacus 12b: side plate

12c: rotor 13: shaft

14: upper casing 15: lower casing

16: vent 17: bearing means

18: Gear group 19: Upper guide

Claims (3)

In wind turbines that generate power by wind regardless of the change in wind direction: A rotor assembly comprising at least a plurality of rotor blades 12c generating a rotational force by the force of the wind, and a shaft 13 for transmitting the rotational force of the rotor blades 12c by rotating together with the plurality of rotor blades 12c. (12); And Irrespective of the wind direction, the upstream of the rotor blade 12c winds the wind toward the rotor blade 12c side and changes the direction of the wind in a direction for efficiently rotating the rotor blade 12c, and downstream of the rotor blade 12c the rotor blade ( Wind power device, characterized in that it comprises a guide means (11) which is fixedly installed around the rotor blade (12c) to guide the outflow of wind from 12c. 2. The rotor according to claim 1, further comprising a main plate (12a) and a side plate (12b) fixed to both ends of the plurality of rotor blades (12c), and after the wind acts on at least the rotor blades (12c), a portion of the wind is moved up and down in the center. At least one of the main plate (12a) and the side plate (12b) is open in the center so as to flow in both directions or one direction. The upper casing 14 and the lower casing 15 are installed to be fixed to the upper and lower ends of the guide means 11, and the ventilation holes 16 of the upper casing 14 and the lower casing 15 are disposed. Through the flow of the wind through the negative pressure generated in the open portion of the main plate 12a and the side plate 12b to promote the flow of wind through the open portion of the main plate 12a and the side plate 12b to increase the efficiency of the wind power Wind power device, characterized in that.