KR101696584B1 - Wind power generator and hybrid power generator that include it - Google Patents

Abstract

The present invention relates to a wind power generator and a hybrid power generator having the same, wherein a rotation radius of a blade is minimized, and energy conversion efficiency can be maximized in spite of a moderate wind. Moreover, without space restriction, the generators can be installed in various places, and even if the wind does not rise, electric energy can be produced. According to the present invention, the wind power generator comprises: a casing unit; a first rotation unit; and a power generation unit.

Description

Technical Field [0001] The present invention relates to a wind power generator and a hybrid power generator including the same,

The present invention relates to a wind turbine generator and a hybrid generator including the same. More particularly, the present invention relates to a wind turbine generator that minimizes a turning radius of a blade, maximizes energy conversion efficiency even in a weak wind, The present invention relates to a wind power generator capable of producing electric energy without blowing, and a hybrid generator including the same.

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.

As shown in FIG. 1, such a wind turbine generator is divided into various types according to the shape of a blade, and is largely divided into three parts: a blade, a transmission, and a generator.

The wing is rotated by the wind to convert the wind energy into mechanical energy. The transmission changes the rotational speed of the generator by the rotational speed of the generator when the rotational force transmitted from the wing is transmitted to the transmission through the central rotary shaft. And converts the mechanical energy generated from the power supply to electrical energy.

However, the conventional wind turbine has a problem that the turning radius of the wing is so large that there are many restrictions on the installation site, the installation process is very complicated, and the noise generation is not suitable for installation in the city center. In addition to this, there is a disadvantage that the generation efficiency is very low if the wind strength is weak.

The embodiments of the present invention are capable of minimizing the turning radius of a blade and maximizing the energy conversion efficiency even in a weak wind, capable of being installed in various places without restriction of space, and also capable of producing electric energy even when wind is blown, The present invention is directed to a hybrid generator including the hybrid generator.

In order to achieve the above object, a wind turbine according to the present invention includes a casing unit having an air inlet formed at one side thereof and an air outlet formed at the other side thereof, and a plurality of blades disposed circumferentially around the rotating shaft, A first rotating part of a Sirocco fan type rotating in one direction by the incoming air and a power generating part connected to the first rotating part to convert mechanical energy into electric energy, Wherein a driving region in which the first rotating portion is located is formed on the inner side of the air inlet, and a streamlined acceleration member having a shape symmetrical with respect to an imaginary center line is positioned at a center portion of the air inlet, And the rear portion is located in the direction of the driving region, and one side of the driving region Wherein the first speed increasing hole communicates with the upper portion of the speed increasing member and is smaller than the air inlet, and the air remaining in the driving region during rotation of the first rotating portion passes through the first speed increasing hole, And the air inlet, the air outlet and the vanes are formed in the same direction as the longitudinal direction of the rotary shaft.

In addition, the hybrid generator according to the present invention includes a sloped solar panel, a support for supporting the solar panel, and a wind turbine provided horizontally at an upper end of the solar panel, To guide the air toward the air inlet side.

The present invention has the following various effects.

First, according to the present invention, a blade formed in the same direction as the longitudinal direction of the rotary shaft is applied to minimize the turning radius, so that it can be installed in various spaces and the noise is very small.

Second, according to the present invention, an air inlet and an air outlet are formed in the casing to increase the flow rate even if the wind strength is weak, thereby inducing the first rotating part to rotate strongly, thereby maximizing the energy conversion efficiency.

Third, the present invention forms a separate first speed-increasing hole in the driving region to induce the flow rate of air remaining in the driving region to increase.

Fourth, the present invention provides a separate speed increasing member and a second speed increasing hole around the air inlet to further maximize the effect of increasing the flow rate of air.

Fifth, it is possible to produce electricity by applying the present invention to a lower portion of a bridge, an outer wall of a building, a bridge, a tunnel entrance / exit, a center separator of a road,

Sixth, the present invention can produce electricity using a solar panel even when the wind is not blowing, and it further improves the energy conversion efficiency by guiding the wind direction toward the air inlet side of the wind power generator by using the solar panel.

1 is a view showing a conventional type of wind turbine generator.
2 is a front perspective view showing an embodiment of a wind power generator according to the present invention.
3 is a rear perspective view showing an embodiment of a wind power generator according to the present invention.
4 is a AA 'cross-sectional perspective view of FIG. 2;
5 is a cross-sectional perspective view of BB 'of FIG.
6 is a cross-sectional view taken along line AA 'of FIG.
7 is a perspective view showing another embodiment of the wind power generator according to the present invention.
8 is a cross-sectional perspective view of CC 'of FIG.
9 is a front perspective view of a hybrid generator according to the present invention.
10 is a rear perspective view of a hybrid generator according to the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings, and the same reference numerals are given to the background art and the constituent elements of the constitution which have already been described.

Further, the description of the wind turbine generator and the hybrid generator including the same according to the present invention is not intended to limit the present invention to the preferred embodiments, but may be embodied in various forms, and the shape, It is not a fixed one but a variety of changes if the same / similar effect can be realized.

2 to 6, the wind turbine generator 100 according to the present invention includes a casing unit 110, a first rotation unit 120, and a power generation unit 130.

The casing unit 110 is configured to form an outer shape of the wind power generator 100. The casing unit 110 has an air inlet 111 formed at one side thereof and an air outlet 113 formed at the other side thereof. The casing unit 110 is formed to be long in the horizontal direction and a driving region 114 for positioning the first rotation unit 120, which will be described later, is formed inside the casing unit 110.

The air inlet 111 formed at one side of the casing unit 110 serves as a passage through which the wind blowing from the outside flows inwardly and the air outlet 113 located at the opposite side serves as a passage through which the air passing through the driving region 114 And serves as a passage for discharging it to the outside again.

In a conventional general wind turbine, wings themselves are exposed to the outside, and wings are formed in a direction orthogonal to the rotation axis. Due to such a structure, when the rotation radius of the wing is very large and the wind strength is not high, it is impossible to produce electricity because the rotation is not performed, and noise is generated during rotation and the generated noise spreads to the outside.

However, in order to solve such a problem, the present invention minimizes the spread of noise to the outside by positioning the first rotation part 120 inside the casing part 110, and at the same time, the size of the air inlet 111 is reduced to the air outlet 113 So that the blade 122 can be rotated even in a small wind.

That is, the wind blowing from the outside of the wind turbine generator 100 passes through the narrow air inlet 111 of the horizontally installed casing portion 110, and the flow velocity is further increased (the pressure drops) The first rotating part 120 is rotated strongly to produce electricity.

A part of the air moved by the rotation of the first rotation part 120 is discharged to the outside through an air outlet 113 formed to be wider than the air inlet 111, 114).

If the size of the air outlet 113 is smaller than the size of the air inlet 111, the amount of air flowing into the driving area 114 is drastically reduced. Therefore, the size of the air outlet 113 is smaller than the size of the air inlet 111, Is formed larger than the size of the opening.

The first rotary part 120 is located in the driving area 114 formed inside the casing part 110 and is configured to rotate in one direction by the air flowing through the air inlet 111. The first rotary part 120 rotates about the center of the rotary shaft 121 And a plurality of blades 122 are provided along the circumferential direction at the periphery thereof.

The first rotating part 120 has a shape of a Sirocco fan type and has a plurality of blades 122 formed in the same direction as the longitudinal direction of the rotating shaft 121. When the first rotating part 120 rotates, The radius of rotation of the rotor 122 is minimized.

In addition, each blade 122 takes a shape that is curved in a direction opposite to the rotation direction so as to be stronger and faster rotated by the air that is introduced.

The power generation unit 130 is connected to the first rotation unit 120 in a configuration that converts mechanical energy into electrical energy when the first rotation unit 120 rotates. 2 to 6, the power generation unit 130 is positioned at the center of the casing unit 110 and the driving region 114 is formed on both sides of the power generation unit 130 to form a pair of first rotation units 120, The first rotary part 120 may be formed to be long and the power generation part 130 may be provided separately on the outer side of the casing part 110 as shown in FIG. 7 and FIG. 8, 120, respectively.

In the embodiment of the present invention, a transmission for increasing the number of revolutions may be provided between the power generator 130 and the first rotary part 120 by using the gear ratio of the transmission.

The air inlet 111 may be provided with a streamlined accelerating member 112 having a shape symmetrical with respect to an imaginary center line on the center portion of the air inlet 111. An upper portion of the speed increasing member 112 The first speed increasing hole 115 can be formed.

The curved front portion of the speed increasing member 112 is located in the forward direction in which air is introduced and the rear portion is located in the driving region 114 direction. The air entering through the air inlet 111 meets the front portion of the speed increasing member 112, and the flow speed is further increased due to the curved front portion. That is, the speed increasing member 112 functions to further improve the effect of speeding up the flow rate by the air inlet 111.

The first speed increasing hole 115 is formed to be smaller than the air inlet 111 so as to accelerate the flow rate of air remaining inside the driving region 114 to be combined with the air entering through the air inlet 111.

That is, the inside driving region 114 of the casing unit 110 in which the first rotation unit 120 is located is partially surrounded by the partition wall 123 formed in a semicircular shape. When the first rotation unit 120 rotates, A part of the air introduced through the air outlet 111 is discharged through the air outlet 113 but the remaining part of the air can not escape and is located in the driving area 114.

At this time, the air remaining inside is moved along the rotating direction by the wing 122 and the partition wall 123 and flows through the first speed increasing hole 115 located at the end of the partition wall 123, It will accelerate.

The air that has passed through the first speed increasing hole 115 joins with the wind flowing through the air inlet 111 and is brought into contact with the curved portion of the speed increasing member 112, And the wing 122 of the first rotary part 120 is positioned. That is, the blade 122 is rotated more quickly and strongly, thereby maximizing the energy conversion efficiency.

In addition, in order to further maximize the energy conversion efficiency, the second speed increasing hole 116, which is provided below the casing unit 110 and communicates with the lower side of the speed increasing member 112 after having a separate fixing unit 118 .

The fixing part 118 provided at the lower part of the casing part 110 is formed in a three-dimensional shape having a protruded height so as to be spaced apart by a predetermined distance when the wind power generator 100 of the present invention is installed at another place, And the auxiliary inlet hole 117 is formed in the side surface.

The front surface of the fixing portion 118 is formed so as to be inclined upwards to extend to the air inlet 111 so that the blowing air can be guided to the air inlet 111 side.

The air blown from the outside of the casing part 110 flows into the driving area 114 through the auxiliary inlet hole 117 and the second speed increasing hole 116 as well as the air inlet 111. [

That is, the air introduced through the auxiliary inflow hole 117 flows into the lower side of the speed increasing member 112 through the second speed increasing hole 116 to increase the flow velocity, and the air introduced through the air inlet 111 And comes into contact with the blade 122 in a state where the flow velocity is further increased while being in contact with the curved bottom surface of the acceleration member 112 at the same time.

As described above, according to the present invention, even when a weak wind is blown from the outside, the flow rate is maximized by using the air inlet 111, the auxiliary inlet hole 117 and the second speed increasing hole 116 to rotate the first rotation part 120 fast And the flow rate of the air remaining inside the driving region 114 is further increased and recirculated, so that the maximum energy conversion efficiency can be obtained even in a small wind.

Hereinafter, a hybrid generator 500 according to another embodiment of the present invention will be described with reference to FIGS. 9 and 10, and the description of the wind turbine generator 100 will be omitted.

The hybrid generator 500 according to the present invention is for generating electric energy using both sunlight and wind power, and includes a solar panel 510, a support portion 511, and a wind power generator 100.

The solar panel 510 is configured to convert solar energy into electric energy. The solar panel 510 is formed into a plate shape having a plurality of solar cells connected thereto. The solar panel 510 is inclined at a predetermined angle and supported by the support portion 511. The wind power generator 100 is horizontally disposed at an upper end of the solar panel 510 and the second rotary part 530 is connected to the wind power generator 100 and the solar panel 510.

The solar panel 510 of the present invention not only functions to convert sunlight into electrical energy, but also guides natural wind to the air inlet 111 side of the wind power generator 100.

That is, the naturally blowing wind comes into contact with the upper surface of the inclined solar panel 510 and flows on the upper surface thereof. The wind which is moved on the inclined surface is transmitted to the wind turbine And flows into the driving region 114 through the air inlet 111 of the housing 100.

The side guider 512 is provided on both sides of the solar panel 510 along the inclined direction and the side guider 512 protrudes in the direction of the upper surface of the solar panel 510 to cover the upper surface of the solar panel 510 Limit the wind traveling on the way to escape laterally and not to be lost.

As described above, the wind power generator 100 of the present invention can produce electric energy by using weak wind by itself. However, the wind power generator 100 collects the wind that is discarded by using the solar panel 510 and guides it to the inside of the wind power generator 100 It is possible to further maximize the energy conversion efficiency.

On the other hand, a plate-shaped rotation induction unit 140 is provided on both sides of the wind power generator 100 to generate a resistance according to the direction of wind blowing. The resistance generated by the wind induction unit 140 causes the second- Turns freely and looks at the wind direction.

However, since components such as electric wires are disposed inside the second rotary part 530, the rotation angle of the second rotary part 530 is limited to about 350 ° or less so that the electric wire is not damaged during rotation of the wind power generator 100 desirable.

100: Wind turbine generator 110:
111: Air inlet 112: Acceleration member
113: air outlet 114: driving area
115: first speed increasing hole 116: second increasing speed hole
117: auxiliary inlet hole 120: first rotating part
130: power generation section 500: hybrid
510: solar panel 512: side guider
530:

Claims (9)

A casing portion having an air inlet formed at one side and an air outlet formed at the other side;
A first rotating part of a Sirocco fan type having a plurality of blades around the rotating shaft in a circumferential direction around the rotating shaft and located inside the casing part and rotating in one direction by the introduced air; And
And a generator connected to the first rotation unit to convert mechanical energy into electric energy,
Wherein a driving region in which the first rotating portion is located is formed inside the casing portion and a streamlined accelerating member having a shape symmetrical with respect to an imaginary center line is positioned at a center portion of the air inlet, And a first speed increasing hole communicating with the upper side of the speed increasing member and being smaller than the air inlet is located at one side of the driving region, Wherein air remaining in the driving region passes through the first speed increasing hole and is re-introduced into the driving region, and the air inlet, the air outlet and the vanes are formed in the same direction as the longitudinal direction of the rotating shaft. generator.
The method according to claim 1,
Wherein the plurality of blades are curved in a direction opposite to the rotating direction.
The method according to claim 1,
And the air inlet is formed to be smaller than the air outlet.
delete delete The method according to claim 1,
Wherein a lower portion of the casing portion is provided with a second speed increasing hole communicating with a lower side of the speed increasing member and smaller than the air inlet and an auxiliary inlet hole guiding external air to the second speed increasing hole.
A sloped solar panel;
A support for supporting the solar panel; And
And a wind turbine provided in an upper end portion of the solar panel in a horizontal direction,
The wind power generator is the wind power generator according to any one of claims 1, 2, 3, and 6,
Wherein the inclined solar panel guides wind to the air inlet side.
8. The method of claim 7,
Wherein a side guider for restricting the release of wind guided to the air inlet side protrudes toward the upper surface of the solar panel at both sides of the solar panel.
8. The method of claim 7,
A second rotating part connecting the wind power generator and the solar panel,
And a rotation inducing part for guiding the wind power generator to rotate in the wind direction,
And the wind turbine rotates around the second rotary part according to the direction of the wind.

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