KR101074646B1 - Wind-collecting type wind power generator - Google Patents

Abstract

The present invention relates to a wind turbine generating electricity using the force of the wind. Wind turbine wind turbine according to an embodiment of the present invention is a plurality of blades are disposed radially around a central rotation axis and the wind hit the blades to rotate the rotation shaft, the support for separating the rotor from the ground to the top And a generator installed on the support to generate electricity by rotating by the rotational force of the rotor, and one surface of the blade is concave toward the wind collecting point so that the wind hitting the blade is concentrated to the wind collecting point provided on the blade. Can be formed.

Description

Wind-collecting type wind power generator

The present invention relates to a wind turbine generating electricity using the force of the wind.

In general, a wind power generator is a device for converting a rotational motion into electrical energy, the wind hits the rotor to generate a rotational force, using the rotational force to drive the generator to produce electricity.

Such a wind turbine generator is divided into a vertical shaft wind turbine in which the rotating shaft is located in a vertical state and a horizontal shaft wind turbine in which the rotating shaft is in a horizontal state according to the position of the rotating shaft of the rotor.

The horizontal axis wind turbine is limited in the installation location because the rotor can only rotate the wind from the front of the rotor, while the vertical axis wind turbine can rotate the rotor by the wind from all directions. Do not receive.

For the same reason as above, the installation of vertical axis wind power generators is increasing more recently than horizontal axis wind power generators.

On the other hand, the conventional vertical axis wind turbine generator is composed of a rotor that rotates about a vertical axis, a pedestal that separates the rotor from the floor, and a generator that rotates by the rotor.

And, the rotor is provided with a rotating shaft in the center, the radial axis of the rotating shaft is configured in a form that the blade is formed integrally coupled with the rotating shaft by a cross-section having a streamlined vertically long.

The vertical axis wind turbine is constructed in such a way that when the wind blows from the front facing each of the plurality of blades constituting the rotor, the rotor rotates due to the lift force generated by the blades, so that the generator can be driven, so it is easy to wind from all directions. Power can be generated by rotating the rotor.

However, in the conventional vertical axis wind turbine, the lift is generated only when the blade of the rotor blows perpendicular to the wind, so that the rotor does not rotate in the wind blowing from the top or the bottom, such as a building wind blowing in the city, so the power generation efficiency is low. In addition, in order to generate the lift of the blade for rotating the rotor there was a problem that can produce electricity only when the wind blows over a certain wind speed.

In addition, there is a problem that the power generation efficiency is low because the power generation only in the generator connected to the rotor.

In addition, the blade and the crosspiece and the rotating shaft is formed integrally there is a problem in that the entire rotor needs to be replaced when the number of blades in accordance with the amount of wind blown or when the blade is damaged.

The present invention is to solve the problems as described above, the problem to be solved by the present invention is easy to rotate the rotor even with a small wind irrespective of the direction of the wind is not restricted by the installation site, improving the power generation efficiency In addition to providing a wind turbine generator that can improve the power generation efficiency by further comprising a power generation unit capable of producing electricity in addition to the generator.

In addition, it is easy to replace the blade when the blade is broken, to provide a wind-type wind power generator that can adjust the number of blades according to the amount of wind blowing.

Wind turbine wind turbine according to an embodiment of the present invention for achieving the above object is a plurality of blades are disposed radially about a central rotation axis and the rotor to rotate the rotation shaft by hitting the blades, the rotor A support spaced apart from the ground to an upper portion, the generator being installed on the support to rotate by the rotational force of the rotor to generate electricity, and one side of the blade concentrates the wind hitting the blade to the wind collecting point provided on the blade It may be formed concave toward the wind collecting point.

The wind collecting point may be positioned to be biased in a direction in which the rotation shaft is positioned about a center of the left and right longitudinal directions of the blade, and may be located at a central portion of an upper and lower width of the blade.

The blade may be provided with 2 ⁿ pieces (where n is a natural number except 0).

The blade is an upper end of the upper end of the upper end of the rotating shaft to the outside, a curved portion formed to be curved downward in the direction in which the rotation axis is located at the outer end of the upper end, and extending from the end of the curved portion is connected to the rotating shaft It may include a lower end.

The lower end of the rotor may be provided with a bearing insert that is inserted into the bearing to facilitate the rotation of the rotor in the support.

The rotor power generation unit may further include a magnetic force unit provided in the plurality of blades to generate magnetic force, and a coil unit provided in the support to generate an induced current by generating interaction with the magnetic force unit.

The magnetic force unit may include a permanent magnet of the N pole and a permanent magnet of the S pole, and the permanent magnet of the N pole and the permanent magnet of the S pole may be alternately installed in the plurality of blades.

The coil unit may be provided with a plurality of coils wound around the rotational axis of the coil coil wound around the electric coil.

A coupling groove is formed in the rotating shaft, and a coupling protrusion is formed in the blade, and the blade may be detachably coupled to the rotating shaft in a form in which the coupling protrusion is fitted into the coupling groove.

The coupling groove may be formed in a greater number than the number of the blade to be installed on the rotation shaft.

The rotating shaft may be provided with a fixed cover for preventing the separation of the blade coupled to the rotating shaft.

According to the present invention, since the wind hitting the blades gathers at the wind collecting point and rotates the rotor, there is an effect that the rotor can be easily rotated even with relatively little wind.

In addition, since the wind blowing from the upper and lower portions of the blades as well as the blades are guided to the concavely formed portions of the blades so that the rotor can be rotated in the form of collecting wind points.

In addition, the rotor generating unit is provided in addition to the generator to generate power, it is possible to double the power generation efficiency.

In addition, the blade is detachably coupled to the rotating shaft to facilitate replacement when the blade is broken, and a larger number of coupling grooves are formed than the number of blades to be installed, thereby controlling the number of blades according to the amount of wind blowing.

1 is a perspective view showing a wind turbine generator according to an embodiment of the present invention.
Figure 2 is a side cross-sectional view schematically showing a wind turbine type wind turbine generator according to an embodiment of the present invention.
Figure 3 is a side view schematically showing a blade constituting the rotor of the wind turbine generator according to an embodiment of the present invention.
4 is an enlarged view of part “A” of FIG. 1 and schematically illustrates a state in which a blade is coupled to a rotating shaft.
5 is a cross-sectional view taken along line AA of FIG. 2.
Figure 6 is a plan view schematically showing a rotor generator of the wind turbine generator according to an embodiment of the present invention.

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

As illustrated in FIGS. 1 and 2, the wind turbine generator 100 according to the embodiment of the present invention may include a rotor 110.

The rotor 110 may be hit by wind to generate a rotational force. Meanwhile, the rotor 110 may include a blade 111 and a rotation shaft 115.

The rotating shaft 115 may be formed in a rod shape and disposed in a state perpendicular to the floor.

As shown in FIGS. 3 to 5, the blades 111 provide a rotational force of the rotor 110 due to wind collision, and a plurality of blades 111 may be provided radially around the rotation shaft 115.

On the other hand, the blade 111 may be formed in a plate shape to receive a lot of wind resistance, the blade 111 may be provided with a wind collecting point (113). The wind point 113 is the wind hit the blade 111 is collected to the wind point 113 can maximize the rotational force of the blade 111.

In addition, one surface of the blade 111 may be formed concave toward the wind collecting point 113 to collect the wind hit the blade 111 to the wind collecting point 113.

That is, the blade 111 in the present invention is guided to the concave portion of the blade 111 by the wind hitting the circumference of the blade 111 is gathered to the wind collecting point 113, so that the rotor 110 easily in spite of the small wind In addition to the rotation, the rotor 110 can be easily rotated even in the wind blowing in various directions.

On the other hand, the wind collecting point 113 is preferably positioned so as to be biased in the direction in which the rotation axis 115 is located about the center of the left and right longitudinal direction of the blade 111 (see Fig. 3).

That is, when the wind collecting point 113 is viewed from the plane of the blade 111 in a plane, it is positioned so as to be biased in the direction in which the rotation axis 115 is located around the middle of the blade 111 and gathers to the wind collecting point 113. This can prevent the blade 111 from being easily deformed.

For example, when the wind collecting point 113 is viewed from the plane of the blade 111, the wind is concentrated at a long distance from the rotation axis 115 to which the blade 111 is coupled when located outside the center of the blade 111 The blade 111 can be easily deformed by the wind is concentrated.

In addition, the wind collecting point 113 is preferably located at the center in the upper and lower portions of the blade 111. That is, when the wind collecting point 113 is viewed from the side of the blade 111, the wind collecting point 113 may be prevented from being deformed by the wind that is located in the middle of the blade 111 and gathers to the wind collecting point 113. (See Figure 3).

For example, when the wind collecting point 113 is viewed from the side of the blade 111, when the biased toward the upper or lower direction from the center of the blade 111, by the wind gathered to the wind collecting point 113, the blade ( Deformation may occur where 111 is twisted upwards or downwards.

In addition, the blades 111 provided in the rotor 110 may be provided with 2 ⁿ pieces (where n is a natural number except 0).

That is, the blade 111 is provided with 2 ⁿ pieces, for example, 2, 4, 8, 16, ....., so that the balance of the rotor 110 without shaking the rotor 110 during the rotation of the rotor 110 It can be easily maintained and at the same time can improve the rotational force of the rotor (110).

In addition, the blade 111 may include an upper end 111a, a curved portion 111b, and a lower end 111c.

The upper end 111a is formed with the end upwardly outward from the upper end 111a of the rotation shaft 115, and the curved portion 111b is downward in the direction in which the rotation shaft 115 is positioned at the outer end of the upper end 111a. It is formed to be curved, the lower end 111c is configured to extend from the lower end of the curved portion 111b to connect the rotating shaft 115.

When the blade 111 is formed in the shape as described above, the outer lower end of the blade 111 is formed to be curved to minimize the resistance of the wind during the rotation of the rotor 110 and at the same time the outer upper end of the blade 111 is upward Since more wind can be collected by the wind collecting point 113, the rotational force of the rotor 110 can be improved.

In addition, the blade 111 may be detachably coupled to the rotation shaft 115. For example, as shown in FIG. 4, the coupling protrusion 111d protruding to both sides of the blade 111 may be formed at the end of the blade 111.

In addition, a coupling groove 115a is formed in the rotary shaft 115 and is opened upwardly and is formed vertically long along the longitudinal direction of the rotary shaft 115 so that the engaging protrusion 111d of the blade 111 is coupled to the rotary shaft 115. The blade 111 may be detachably coupled to the rotation shaft 115 in a form of being fitted into the groove 115a.

At this time, the coupling groove 115a of the rotation shaft 115 is open at the upper end to match the position of the coupling protrusion 111d of the blade 111 at the upper portion of the coupling groove 115a, and the blade 111 is coupled to the coupling groove ( The blade 111 may be coupled to the rotation shaft 115 in the form of sliding down the 115a.

In addition, a fixing cover 119 may be coupled to an upper end portion of the rotating shaft 115 to seal the open upper end of the coupling groove 115a to prevent the blade 111 from being separated from the rotating shaft 115.

The fixing cover 119 has a disk shape having a circumference equal to or greater than the circumference of the rotation shaft 115 so as to seal the plurality of coupling grooves 115a formed in the rotation shaft 115 with one fixing cover 119. The fixing cover 119 may be coupled to the rotation shaft 115 by a fastening member such as a bolt, for example.

Meanwhile, a larger number of coupling grooves 115a are formed radially of the rotation shaft 115 than the number of blades 111 to be installed on the rotation shaft 115, so that the blades 111 are installed on the rotation shaft 115 according to the amount of wind. You can adjust the number of).

For example, when a small amount of wind blows, the blade 111 is installed in addition to the rotating shaft 115 to improve the rotational force of the rotor 110, and when a large amount of wind blows, the fastness of the rotor 110 In order to prevent damage to the rotor 110 due to rotation, the number of installation of the blades 111 may be adjusted by separating some of the blades 111 from the rotating shaft 115.

At this time, the number of blades 111 added or removed from the rotating shaft 115 is preferably added or separated to 2 ⁿ pieces.

Thus, the blade 111 is detachably coupled to the rotating shaft 115, so that the blade 111 is easy to replace when the blade 111 is broken, and the number of blades 111 is adjusted according to the amount of wind to make the rotor ( There is an advantage to obtain an optimized rotational force of 110).

 In addition, a bearing insertion portion 117 is provided at the lower end of the rotor 110 so that the bearing 110 may smoothly rotate the rotor 110 at the support 130 when the rotor 110 and the support 130 are coupled to each other. ) Can be inserted into the installation.

In this case, a well-known flat sliding bearing may be installed at a portion at which the lower end of the bearing insert 117 contacts the upper end of the support 130, and the rotation shaft 115 and the support 130 and the rotor of the rotor 110 may be installed. A generally known roller bearing may be installed between the bearing insert 117 and the support 130 of the 110.

Wind collecting type wind power generator 100 according to an embodiment of the present invention may include a support (130). The support 130 may space the rotor 110 upward from the ground.

On the other hand, the support 130 may be formed in a cylindrical shape formed long up and down, the lower end of the support 130 may be provided with a pedestal 133 having a circumference larger than the circumference of the support 130 is fixed to the floor The rotor 110 may be rotatably coupled to the upper end of the support 130.

In this case, the rotating shaft 115 of the rotor 110 may be partially inserted into the support 130, and the protrusion 131 is provided at the upper end of the support 130 so that the protrusion 131 is inserted into the bearing of the rotor 110. It can be combined in a form that is inserted into the portion 117.

Wind collecting type wind power generator 100 according to an embodiment of the present invention may include a generator (150). The generator 150 may produce electricity by the rotational force of the rotor 110.

On the other hand, the generator 150 is directly connected to the rotating shaft 115 of the rotor 110 or connected to each other by a power transmission means 155, for example, a chain, a belt, a gear to drive the generator 150 when the rotor 110 rotates. The rotational force of the rotor 110 may be converted to drive the generator 150 by a reducer that converts the rotational force of the rotor 110 into a suitable rotational force for driving the generator 150.

At this time, the generator 150 is preferably installed inside the support 130, the configuration of the generator 150 is a known configuration, so a detailed description thereof will be omitted.

As shown in FIG. 6, the wind collecting wind power generator 100 according to the embodiment of the present invention may further include a rotor generator 170.

The rotor generator 170 may produce electricity together with the generator 150 to double the amount of electricity produced by the wind turbine generator 100.

 On the other hand, the rotor generator 170 may be composed of a magnetic force unit 171 and the coil unit 173.

The magnetic force unit 171 may be provided on the blade 111 of the rotor 110, and the magnetic force unit 171 may include a plurality of permanent magnets 171N and 171S of the N pole and the S pole of the rotor 110. For example, if the blade 111 is alternately provided with a permanent magnet 171N of N poles in one of the blades 111, the adjacent blade 111 may be provided in the form of a permanent magnet 171S of the S pole. Can be.

In this case, the magnetic force unit 171 may be provided at the lower end of the blade 111.

In addition, the coil unit 173 is inserted into the winding coil 175 in which the electric coil is wound so that electricity is generated by the induced current by the permanent magnets 171N and 171S of the magnetic pole 171 and the S pole. Can be.

In this case, the coil unit 173 may be configured to generate electricity by interacting with a portion adjacent to the magnetic force unit 171 provided in the blade 111.

For example, as in the embodiment, the coil unit 173 is a magnetic force unit 171 provided on the blade 111 at the upper end portion 111a of the support 130, that is, the permanent magnets of the N pole and the S pole ( 171N and 171S may be formed in a disc shape so as to extend outward to a portion where the 171N and 171S are installed, and the winding coil 175 may be inserted therein.

Here, it is preferable that the plurality of winding coils 175 are provided radially inside the coil unit 173. In this case, the production amount of electricity may be improved in proportion to the number of the winding coils 175 inserted into the coil unit 173.

When the rotor 110 rotates due to wind hitting the blade 111, the rotor power generation unit 170 configured as described above has the permanent magnet 171N of the north pole provided in the blade 111 and S of the coil unit 173. The permanent magnets 171S of the poles alternately pass, thereby causing the induction current by interacting with the permanent magnets 171N and 171S of the N pole and the S pole in the winding coil 175 embedded in the coil unit 173. It generates electricity in the form of generating.

The operation and effect between the above-described respective constitutions will be described.

In the wind turbine-type wind power generator 100 according to the embodiment of the present invention, the blade 111 formed concave toward the wind collecting point 113 on one surface of the blade 111 is rotated about the axis of rotation 115. A plurality of spaced apart along a circumference of the is provided.

At this time, the blades 111 are coupled to each other in such a way that the engaging protrusion 111d of the blade 111 is fitted into the engaging groove 115a of the rotating shaft 115 so as to be detachable from the rotating shaft 115. A fixing cover 119 is installed at an upper end to prevent the blade 111 from being separated from the rotating shaft 115.

And, the rotor 110 is installed on the upper portion of the support 130, the bearing BR between the support 130 and the rotor 110 is installed in the bearing insert 117, the rotor (130) in the support 130 Smooth rotation of 110).

In addition, the lower end of the rotor 110 more specifically, the magnetic force unit 171 and the upper end of the support 130 are provided with alternating permanent magnets (171N, 171S) of the N pole and the S pole at the lower end of the blade 111. That is, the rotor generator 170 including the coil unit 173 in which the winding coil 175 is embedded is extended to the portion provided with the magnetic force portion 171 of the blade 111.

When the wind-type wind power generator 150 according to the embodiment of the present invention configured as described above winds hit the blades 111, the wind is guided to the concave portion of the blades 111 and gathers to the wind-up points 113. The rotor 110 is rotated by the force of the wind concentrated at the point 113.

Then, when the rotor 110 rotates, it generates electricity in the form of driving the generator 150 connected to the rotating shaft 115 and the power transmission means 155 of the rotor 110.

Meanwhile, when the rotor 110 rotates, the upper part of the coil unit 173 provided on the support 130 passes through the S pole and the N pole permanent magnets 171S and 171N provided in the blade 111. Induced current is generated by interaction with the winding coil 175 embedded in the portion 173 to produce electricity in the coil unit 173 in addition to the generator 150.

Therefore, the wind-wind-type wind power generator 100 according to the embodiment of the present invention by concentrating the wind to the wind collecting point 113 by rotating the rotor 110, irrespective of the strength of the wind, for example, the urban area does not blow much wind It can be installed in a place such as the production of electricity, as well as a small wind can easily rotate the rotor 110 in the wind blowing in various directions.

In addition, since the power generator 170 can generate power in addition to the generator 150, there is an effect of further increasing the amount of electricity produced.

In addition, the blade 111 is detachably coupled to the rotating shaft 115 to facilitate replacement when the blade is broken, and the number of installation of the blade 111 may be adjusted according to the amount of wind.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and it is recognized that the present invention is easily changed and equivalent by those skilled in the art to which the present invention pertains. Includes all changes and modifications to the scope of the matter.

100: wind turbine 110: rotor
111: blade 111a: upper portion
111b: curved portion 111c: lower portion
111d: Combined protrusion 113: Wind-up point
115: rotating shaft 115a: coupling groove
117: bearing insert 119: fixed cover
130: support 131: protrusion
133: pedestal 150: generator
155: power transmission means 170: rotor generator
171: magnetic portion 171N: permanent magnet of N pole
171S: permanent magnet of S pole 173: coil part
175: winding coil BR: bearing

Claims (11)

A rotor for radially arranged around the central axis of rotation and the wind to hit the blade to rotate the rotation axis,
A support for separating the rotor from the ground upwards,
It is installed on the support and includes a generator for generating electricity by rotating by the rotational force of the rotor,
One surface of the blade is formed concave toward the wind collecting point so that the wind hit the blade is concentrated to the wind collecting point provided on the blade,
And a rotor power generation unit including a magnetic force unit provided in the plurality of blades to generate magnetic force, and a coil unit provided in the support to generate an induced current in interaction with the magnetic force unit to generate power. Wind power generator. The method of claim 1,
The wind blowing point
The wind turbine type wind turbine generator, characterized in that it is positioned to be inclined in the direction in which the rotating shaft is positioned about the center of the left and right longitudinal direction, and is located in the central portion of the upper and lower widths of the blade. The method of claim 1,
The wind turbine wind turbine generator, characterized in that the blade is provided with 2 ⁿ pieces (where n is a natural number except 0). The method of claim 1,
The blade is
An upper end of which the end is upwardly outward from the upper end of the rotating shaft,
Curved portion formed to be curved downward in the direction in which the rotation axis is located at the outer end of the upper end,
Wind collecting device, characterized in that it comprises a lower end extending from the end of the curved portion connected to the rotating shaft. The method of claim 1,
At the bottom of the rotor
Wind collecting type wind turbine generator, characterized in that the bearing insertion portion is inserted into the bearing is inserted into the support to facilitate the rotation of the rotor. delete The method of claim 1,
The magnetic portion
And a permanent magnet of the N pole and a permanent magnet of the S pole, wherein the permanent magnet of the N pole and the permanent magnet of the S pole are alternately installed on the plurality of blades. The method of claim 1,
The coil unit
Wind-up wind power generator, characterized in that a plurality of winding coils of the type wound around the coil is installed radially around the rotation axis. The method of claim 1,
A coupling groove is formed in the rotation shaft, and the blade is formed with a coupling protrusion, the wind turbine type wind turbine generator, characterized in that the blade is detachably coupled to the rotating shaft in the form of fitting the coupling protrusion to the coupling groove. 10. The method of claim 9,
The coupling groove
Wind collecting type wind turbine generator, characterized in that formed in the rotation shaft more than the number of the blades to be installed. 10. The method of claim 9,
The rotation axis
Wind-up wind power generator, characterized in that the fixing cover is installed to prevent the separation of the blade coupled to the rotating shaft.

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