KR101453849B1 - Apparatus for gas wind generatoin and system thereof - Google Patents

Abstract

The present invention relates to a gas wind power generating apparatus and a gas wind power generating system. According to an embodiment of the present invention, the gas wind power generating apparatus comprises: a rotation unit of which surfaces of a plurality of wind blades connected to a central body are formed vertically against the surface of a gas outlet pipe, and rotates by the deflecting force of gas rising from the lower part of the gas outlet pipe; a power generation unit which generates induced electromotive force by the rotating rotation unit; and a supporting unit which supports the rotation unit by one end thereof being fixated on the inner surface of the gas outlet pipe. Therefore, power generation using the pressure and speed of the gas being discharged is carried out.

Description

[0001] APPARATUS FOR GAS WIND GENERATOIN AND SYSTEM THEREOF [0002]

The present invention relates to a gas wind power generation apparatus and a gas wind power generation system, and more particularly, to a wind power generation technology using rotational energy of a discharged gas.

A wind turbine generator is a device that converts wind energy into electrical energy. It generates electricity by rotating the wing of the wind turbine and generating the rotational force of the wing. Wind power is attracting much attention as a clean energy that does not generate environmental pollution because it uses natural wind using topographical characteristics. Wind power generates electricity from wind-driven wind turbines, and the generated electricity is carried through the connected transmission and distribution.

However, the conventional wind power generation is influenced by the geographical position, and it is difficult to predict the speed and direction of a certain wind, which is a disadvantage that the power generation efficiency is poor. In addition, since the wind direction is not constant, there is a problem that the energy of the wind for rotating the rotary wing is used much less than the actual wind energy. In addition to natural winds, the technology to produce electricity from the wind energy emitted from an artificial industrial environment has been developed.

Among them, the Korean Patent Registration No. 0500709 (published on July 11, 2005) is a technology related to a "power generation system using exhaust wind power", and discharges the air from the air conditioning system purifying or harmonizing the air inside a building or factory A technique using exhaust wind power capable of generating and utilizing electric power using wind power is disclosed.

However, in the above conventional technology, there is still a limit to efficiently generate air energy discharged to the outside by artificially discharging air to the outside by using a suction device in a passage and using a conventional wind power generator outside. Therefore, there is a need for a technology for producing electric energy more efficiently in the exhaust system.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a gas wind power generation device and a gas wind power generation system which can generate electricity by using a rotational force by a turning force of a gas discharged through a gas discharge pipe.

A gas wind power generation apparatus according to an embodiment of the present invention is a gas wind power generation apparatus in which a wing surface of a plurality of vanes connected to a central body is formed perpendicular to a surface of a gas discharge pipe, And a support portion having one end fixed to the inner surface of the gas discharge tube and supporting the rotation portion.

A plurality of vanes having one end fixed to an inner surface of the gas discharge tube and the other end positioned at an upper portion or a lower portion of one side of the plurality of vanes and a first magnetic body formed on a surface facing the vanes, The rotation unit may further include a rotation inducing unit, and a second magnetic body having the same polarity as that of the first magnetic body may be formed on one side of the plurality of blades.

In addition, the rotating unit may rotate the blades of a plurality of auxiliary wind power generators installed on the inner surface of the gas discharge pipe in parallel with the ends of the plurality of blades by the side wind generated by the rotation of the plurality of blades.

The power generating unit may include a third magnetic body formed on an inner surface of the gas discharge tube so as to be parallel to an end of the plurality of vanes and on a surface opposite to an end of the plurality of vanes, And a fourth magnetic body having the same polarity as that of the third magnetic body may be formed at the end.

A gas wind power generation system according to another embodiment of the present invention is a gas wind power generation system including a cylindrical gas discharge pipe and a wing surface of a plurality of wings connected to the center body, the wing surface of the wing rising perpendicularly to the surface of the gas discharge pipe, And a support portion for supporting the rotating body by being fixed to an inner surface of the gas discharge pipe at one end thereof, and a supporting portion for supporting the rotating body, And a plurality of auxiliary wind power generators installed on the inner surface of the gas discharge pipe in parallel with the ends of the plurality of vanes to generate induced electromotive force by side winds generated by the plurality of vanes while rotating do.

Accordingly, power generation can be performed using the pressure and the velocity of the discharged gas. In addition, it is possible to generate electricity by using the wind generated by the gas using the auxiliary wind power generator installed in the gas discharge pipe. Further, the magnetic body included in the rotating body rotating by the gas makes it easier to rotate and the amount of generated power can be increased.

1 is a perspective view of a gas wind power generation system according to an embodiment of the present invention,
2 is a cross-sectional view of a gas wind power generator included in the gas wind power generation system according to Fig. 1,
3 is a plan view of the gas wind power generator according to Fig. 2,
4 is a cross-sectional view of a gas wind power generator according to another embodiment of the present invention,
5 is a plan view of the gas wind power generator according to Fig. 4,
Fig. 6 is an exemplary view for explaining a rotating part of the gas wind power generator according to Fig. 4,
7 is a cross-sectional view of a gas wind power generator according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or the precedent of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

1 is a perspective view of a gas wind power generation system according to an embodiment of the present invention.

Referring to FIG. 1, a gas wind power generation system according to an embodiment of the present invention includes a gas discharge pipe 100, a gas wind power generator 200, and an auxiliary wind power generator 300.

The gas discharge pipe 100 has a cylindrical shape and is installed in a direction perpendicular to the surface of the earth. In this case, the cross-sectional area of the gas exhaust pipe 100 may be designed to become narrower from the bottom to the top. The gas discharge pipe 100 is connected to an external gas discharge system (not shown), and guides the gas discharged through the gas discharge system to the outside.

The gas wind power generator 200 is fixedly installed inside the gas discharge pipe 100, and may be installed in one or a plurality of the gas wind power generators 200. The gas turbine generator 200 generates electric power by generating induced electromotive force while rotating by the gas moving upward from the lower portion of the gas exhaust pipe 100. Further, the gas wind power generator 200 can generate electricity by rotating using the magnetic force in addition to the rotational force of the gas.

In addition, the gas wind power generator 200 may be detachable in a lower region of the gas discharge pipe 100. This structure can be formed in such a structure that the gas wind power generator 200 can be detached from the gas discharge pipe 100 and replaced when the gas wind power generator 200 needs to be repaired unexpectedly. Specific details related to the gas wind power generator 200 will be described later.

The auxiliary wind power generator (not shown) is a plurality of wind power generators installed on the inner or outer surface of the gas discharge pipe 100 separately from the gas wind power generator 200. The auxiliary wind power generator formed inside the gas discharge pipe 100 can generate electricity using the wind power generated as the gas wind power generator 200 rotates. Also, the auxiliary wind power generator, which is formed outside the gas discharge pipe 100, can generate electricity using natural wind power according to the surrounding terrain.

As described above, the gas wind power generation system of the present invention can maximize the energy production by converting the wind power derived from the discharged gas and the wind power according to the natural topography into electricity.

Fig. 2 is a sectional view of a gas wind power generator included in the gas wind power generation system according to Fig. 1, and Fig. 3 is a plan view of the gas wind power generator according to Fig.

2 and 3, a gas turbine generator 200 according to an embodiment of the present invention includes a rotation unit 210, a power generation unit 220, and a support unit 230.

The rotation unit 210 includes a center body 211 and a plurality of vanes 212 connected to the center body 211. The plurality of vanes 212 connected to the central body 211 may be formed perpendicular to the ground surface. This is because the gas rising from the lower portion of the gas discharge pipe 100 is rotated by the turning force to rotate the plurality of vanes 212. In other words, the discharged gas theoretically linearly moves from the lower part to the upper part of the gas discharge pipe 100, but a turning force is generated according to the rotation of the earth, and the movement of the gas in the gas discharge pipe 100 generates a rotational force . Accordingly, the rotation unit 210 rotates using the kinetic energy of the natural gas. In addition, the plurality of vanes 212 of the rotation unit 210 may have different rotational directions because the direction of the gas is opposite to that of the northern or southern hemisphere.

In addition, the rotation unit 210 serves to supply wind to the auxiliary wind power generator 300. That is, an internal auxiliary wind power generator 310 is formed on the inner side of the gas discharge pipe 100, and an external auxiliary wind power generator 320 is formed on the outer side. In this case, the external auxiliary wind power generator 320 rotates due to the influence of natural wind, but the internal auxiliary wind power generator 310 generates side wind generated by rotating the plurality of blades 212, that is, As shown in Fig. The internal auxiliary wind power generator 310 is installed in parallel with the ends of the plurality of vanes 212 of the rotation unit 210. For example, the internal auxiliary wind power generator 310 can use a general impeller as a rotating body. That is, it is preferable that the wings are bent at a predetermined angle.

The power generation unit 220 generates an induced electromotive force as the rotation unit 210 rotates. The power generation unit 220 is connected to the central body 211 of the rotation unit 210 in a coaxial manner and connected to the upper or lower part of the rotation unit 210. The power generation unit 220 may transmit electricity generated by the rotation of the rotation unit 210 to an external battery to store the generated electricity or may be connected to a system (not shown) or a gas wind power generation system.

One end of the support portion 230 is fixed to the inner surface of the gas discharge tube 100 to support the rotation portion 210. The supporting part 230 supports a bearing 231 at the center and a center shaft 232 connected to the center body 211 of the rotating part 210 to rotate. The supporting part 230 is connected to the power generating part 220 connected to the central body 211 of the rotary part 210 and has one end fixed to the inner surface of the gas discharge pipe 100 and supporting the supporting part 230. The support part 230 is formed on the upper part of the rotation part 210 to support the rotation part 210 and is formed in a direction parallel to the power generation part 220 at the lower part of the rotation part 210 to support the power generation part 220 do.

FIG. 4 is a cross-sectional view of a gas wind power generator according to another embodiment of the present invention, and FIG. 5 is a plan view of a gas wind power generator according to FIG.

4 and 5, a gas turbine generator 200 according to another embodiment of the present invention includes a rotation unit 210, a power generation unit 220, a support unit 230, and a rotation induction unit 240 .

The rotation unit 210 includes a plurality of blades 212 connected to the central body 211 and the central body 211 as described above with reference to FIGS. 2 and 3. Hereinafter, a description overlapping with FIG. 2 and FIG. 3 will be omitted. The rotation part 210 may be formed with a ring-shaped rim 213 surrounded by the ends of the plurality of vanes 212. The rim 213 improves the rotational force of the rotation unit 210. This is to increase the rotational inertia of the gas turbine generator 200 to improve the rotational force.

In addition, the rotation unit 210 serves to supply wind to the auxiliary wind power generator 300. In this case, the internal auxiliary wind power generator 310 is installed in parallel with the ends of the plurality of vanes 212 of the rotation unit 210.

The rotation unit 210 may include a second magnetic body b having the same polarity as that of the first magnetic body a of the rotation induction unit 240 described later at the end of the plurality of vanes 212. Specific details related to this will be described later.

The power generation unit 220 generates an induced electromotive force as the rotation unit 210 rotates. The power generation unit 220 is connected to the central body 211 of the rotation unit 210 and connected to the lower part of the rotation unit 210. The power generation unit 220 may transmit electricity generated by the rotation of the rotation unit 210 to an external battery to store the generated electricity or may be connected to a system (not shown) or a gas wind power generation system.

One end of the support portion 230 is fixed to the inner surface of the gas discharge tube 100 to support the rotation portion 210. The supporting portion 230 supports the center shaft 232 to rotate in connection with the central body of the rotating portion 210. [ The supporting portion 230 is connected to the power generating portion 220 having one end fixed to the inner surface of the gas exhausting pipe 100 and the other end coaxially connected to the central body 211 of the rotating portion 210, ). The support part 230 is formed on the upper part of the rotation part 210 to support the rotation part 210 and is formed in a direction parallel to the power generation part 220 at the lower part of the rotation part 210 to support the power generation part 220 do.

One end of the rotation inducing portion 240 is fixed to the inner surface of the gas exhausting tube 100 and the other end is located at the upper portion or the lower portion of one side of the plurality of vanes 212. The rotation inducing unit 240 has a first magnetic body a formed on a surface facing the plurality of vanes 212 to induce rotation of the rotation unit 210. That is, as described above, the rotation inducing unit 240 is formed with the first magnetic body a, and the second magnetic body b is formed at the ends of the plurality of vanes 212 of the rotation unit 210, do. This is to lift the plurality of blades 212 of the rotating part 210 with repulsive force to facilitate rotation. In this case, the repulsive force between the first magnetic body (a) and the second magnetic body (b) is preferably such that the plurality of blades 212 of the rotating portion 210 can be lifted to a predetermined height.

For example, it is possible that the first magnetic body (a) is an electromagnet and the second magnetic body (b) is a permanent magnet. When power is not supplied to the first magnetic body (a), the plurality of vanes 212 of the rotation unit 220 do not move in contact with the rotation induction unit 240. When electricity is supplied to the first magnetic body (a), a magnetic force is generated to lift the plurality of vanes 212 by a predetermined height. In this case, the rotation part 220 can reduce friction and facilitate rotation.

6 is an exemplary view for explaining a rotating part of the gas wind power generator according to FIG.

Referring to FIG. 6, the rotating unit 210 has a plurality of blades 212 formed on the central body 211 in a direction perpendicular to the ground surface, as described above. In this case, a ring-shaped rim 213 is formed at the ends of the plurality of blades 212, so that the rotational force of the rotating portion 210 can be increased. In addition, a groove 213-1 may be formed in the rim 213 of the rotation part 210. [ The groove portion 213-1 is a region having a plurality of grooves formed at a predetermined depth. And serves to supply wind to the outer surfaces of the plurality of vanes 212 through the groove portion 213-1 of the rotation portion 210 when the rotation portion 210 rotates due to the directing force of the gas. For example, when the internal auxiliary wind power generator 310 is formed on the inner surface of the gas discharge tube 100, more wind is generated from the groove 213-1 to improve the rotation of the internal auxiliary wind power generator 310 .

In addition, the rotation unit 210 can fill the groove 213-1 with a predetermined magnet or material. When the rotation unit 210 is operated, the center of gravity of the rotation unit 210 does not move toward the center body 211. In this case, the center of gravity is shifted toward the outer rim 213, thereby further increasing the rotational inertia.

7 is a cross-sectional view of a gas wind power generator according to another embodiment of the present invention.

Referring to FIG. 7, the gas turbine generator according to another embodiment of the present invention includes a rotation unit 210, a power generation unit 220, a support unit 230, and a rotation induction unit 240.

The rotation unit 210 includes a plurality of blades 212 connected to the central body 211 and the central body 211 as described above with reference to FIGS. Hereinafter, a detailed description of the contents overlapping with those of FIG. 2 to FIG. 6 will be omitted. A ring-shaped rim 213 may be formed at the end of the plurality of vanes 212. In this case, a second magnetic body (b) having the same polarity as that of the first magnetic body (a) of the rotation inducing unit 240 described later is formed on the upper or lower end of the end of the wing (212). The outer side of the plurality of vanes 212 is a fourth magnetic body b 'having the same polarity as the third magnetic body a' of the power generation section 220 described later.

For example, the first magnetic material (a) may use an electromagnet, and the second magnetic material (b) may use a permanent magnet. Also, the third magnetic body (a ') and the fourth magnetic body (a') have the same polarity and can be set to the same polarity as the first magnetic body (a) and the second magnetic body (b) or different polarities. The third magnetic body (a ') and the fourth magnetic body (b') are spaced apart by a predetermined distance to increase the rotational force of the plurality of blades (212).

2 to 5, the power generation unit 220 is formed at a position corresponding to the rotation unit 210 inside the gas discharge pipe 100, not at the bottom of the rotation unit 210. [ 2 to 5, the position of the power generation unit 220 is positioned above or below the rotation unit 210. In this embodiment, the power generation unit 220 has a ring shape in which the rotation unit 210 is positioned . In this case, the power generating unit 220 may be divided into a plurality of modules at predetermined positions, or may be formed in a circular ring shape.

For example, the interior of the gas discharge pipe 100 may be formed alternately with the internal auxiliary wind power generator 310 of the auxiliary wind power generator 300, The power generation section 220 may be formed solely.

The power generation unit 220 is formed so that the second magnetic body b 'formed on the outer side of the end of the plurality of vanes 212 of the rotation unit 210 and the first magnetic body a' . This is to facilitate the rotation of the rotation part 210 by using the repulsive action between the first magnetic body (a ') and the second magnetic body (b'). In this case, the sizes of the first magnetic body (a ') and the second magnetic body (b') may vary depending on the setting of the user.

One end of the support portion 230 is fixed to the inner surface of the gas discharge tube 100 to support the rotation portion 210. The support portion 230 supports a bearing 231 at the center thereof and rotates by connecting the center shaft 232 to the central body of the rotation portion 210. The support frame 230 is divided into an upper frame and a lower frame and the upper frame is positioned on the upper part of the rotation part 210 to support the central body 211. The lower frame is located below the rotation part 210, .

For example, when the first magnetic body (a) is an electromagnet and the second magnetic body (b) is a permanent magnet, the rotation section 210 moves up and down the center axis 232. That is, when electricity is supplied to the first magnetic body (a), the rotation part 210 is lifted up by a predetermined height along the center axis 232 by the second magnetic body (b) do. On the other hand, the supply of electric power to the first magnetic body (a) is interrupted, and the rotation part 210 is seated on the rotation induction part 240 to be described later. Therefore, the rotation unit 210 can rotate only when electricity is supplied.

One end of the rotation inducing portion 240 is fixed to the inner surface of the gas exhausting tube 100 and the other end is located at a lower portion of one side of the plurality of vanes 212. The rotation inducing unit 240 has a first magnetic body a formed on a surface facing the plurality of vanes 212 to induce rotation of the rotation unit 210. That is, as described above, the rotation inducing unit 240 is formed with the first magnetic body a, and the second magnetic body b is formed at the ends of the plurality of vanes 212 of the rotation unit 210, do. This is to float in the air using repulsive force with the plurality of vanes 212 of the rotation unit 210 to facilitate rotation. In this case, the intensity of the repulsive force between the first magnetic body (a) and the second magnetic body (b) may be changed by user setting.

As described above, the gas wind power generation apparatus and the gas wind power generation system according to the embodiments of the present invention can generate power using the pressure and speed of the discharged gas. In addition, it is possible to generate electricity by using the wind generated by the gas using the auxiliary wind power generator installed in the gas discharge pipe. Further, the magnetic body included in the rotating body rotating by the gas makes it easier to rotate and the amount of generated power can be increased.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, Therefore, the present invention should be construed as a description of the claims which are intended to cover obvious variations that can be derived from the described embodiments.

100: gas discharge pipe
200: Gas wind power generator
210:
211:
212: wing
213: Border
213-1:
220:
230: Support
231: Bearings
232: center axis
240:
300: auxiliary wind power generator
310: Internal auxiliary wind power generator
320: External auxiliary wind power generator

Claims (5)

A rotating portion that is formed by a wing surface of a plurality of vanes connected to the central body and formed by a vertical surface of a surface of a gas discharge pipe and rotated by a turning force of a gas rising from a lower portion of the gas discharge pipe;
A generator for generating an induced electromotive force when the rotating unit rotates;
A support having one end fixed to an inner surface of the gas discharge pipe to support the rotation part;
And a plurality of rotation induction parts in which one end is fixed to the inner surface of the gas discharge pipe and the other end is located at an upper portion or a lower part of one side of the plurality of blades and a first magnetic body is formed on a surface facing the plurality of blades, Lt; / RTI >
The power generation unit includes:
A third magnetic body is formed on an inner surface of the gas discharge tube so as to be parallel to an end of the plurality of vanes and on a surface opposite to an end of the vanes,
The rotation unit includes:
Wherein a plurality of grooves are formed in the rim and a second magnetic body having the same polarity as that of the first magnetic body is formed on one side of the plurality of wings, And a fourth magnetic body having the same polarity as that of the third magnetic body is formed at an end of the plurality of blades, and a side wind generated by the plurality of blades rotates, Wherein the plurality of auxiliary wind power generators are installed in parallel with each other. delete delete delete A cylindrical gas discharge pipe;
A rotating portion formed by a plurality of vanes of a plurality of blades connected to the central body and formed by a vertically extending surface of the gas discharge pipe and rotated by a turning force of a gas rising from a lower portion of the gas discharge pipe; A support portion that is fixed to an inner surface of the gas discharge tube and supports the rotation portion; and a support portion that has one end fixed to the inner surface of the gas discharge tube, and the other end fixed to the upper portion of one side of the plurality of vanes And a plurality of rotation inducing units positioned at a lower portion of the rotor and having a first magnetic body formed on a surface facing the plurality of blades; And
And a plurality of auxiliary wind power generators installed on an inner surface of the gas discharge pipe in parallel with the ends of the plurality of vanes to generate induced electromotive force by side winds generated by the plurality of vanes while rotating,
Wherein the power generating portion is disposed on an inner surface of the gas discharge pipe in parallel with an end of the plurality of vanes and a third magnetic body is formed on a surface of the vane facing the end of the plurality of vanes,
Wherein the rotary portion has a ring-shaped rim at an end of the plurality of blades, a plurality of grooves are formed in the rim, and a second magnetic body having the same polarity as the first magnetic body is formed on one side of the plurality of blades And a fourth magnetic body having the same polarity as that of the third magnetic body is formed at an end of the plurality of vanes, and a plurality of vanes are formed on the inner surface of the gas discharge tube by side winds generated while the vanes rotate, A gas turbine system for rotating a plurality of auxiliary wind turbine blades mounted parallel to an end of a wing.

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