KR20100120068A - The wind power generato system with multiple rotor wing blades - Google Patents

Abstract

PURPOSE: A wind energy system with a multi-stage blade is provided to efficiently convert continuous wind energy to power energy since a turbine slopes at a certain angle due to the physical characteristic of the air flow. CONSTITUTION: A wind energy system with a multi-stage blade comprises a turbine(40), a structure(30), a housing(10), wheels(80) and a rail(90). The turbine comprises a plurality of turbine mounts(40a), turbine supports(40b), a plurality of blades(40c) and a rotary ring. A hub(30a) is fixed to the structure and supports the turbine. The hub is fixed on the housing. A frame comprises frame mounts(60a), frame supports and auxiliary frame supports(62). The wheels are installed under each frame mount. The rail is fixed to the structure(30).

Description

The wind power generato system with multiple rotor wing blades}

1 is a side internal structure diagram according to the present invention,

2 is a front view of FIG. 1,

3 is a rear view of FIG. 2;

Figure 4 is a view showing the mold, the wheel, the rail of the lower plane of Figure 3,

5 is an enlarged view of a portion of the wing of FIG. 2,

Symbols for Important Parts of Drawings

10: housing,

20: generator,

21: generator central axis,

22 generator shaft bearings,

30: construct,

30a, 30b hub,

40: turn wheel,

40a: swivel pedestal,

40b: rotor wheel support,

40c: rotor blades,

40d: rotary ring,

50: wind direction check,

51: engine control medium,

52: first turning bearing,

53: second turning bearing,

60: Template,

60a, 60b: mold support,

61: mold support,

62: reinforcement frame support,

70: circumferential bearing,

80: wheels,

90: rails,

The present invention relates to a multi-stage multi-wing wind power system, and more particularly, to convert the continuous wind energy into power energy through a rotating wheel having a multi-stage multi-wing in a predetermined angle for the use of the mechanical specificity of air flow. The present invention relates to a multi-stage multi-wing wind power system for maintaining total power at high efficiency.

Representative propeller windmills on modern horizontal shafts generally have two or three wings. Most winds do not act on the wings and pass through them. They generate small energy, unlike large equipment costs. There is a problem.

The present invention is to solve the above problems, in order to use the mechanical specificity of the air flow, the total power to convert the continuous wind energy into power energy through a rotary wheel formed with a predetermined angle of the entire cross-sectional area is maintained at high efficiency Its purpose is to provide a multi-stage, multi-wing wind power system.

The present invention relates to a multi-stage multi-wing wind power system, comprising: a housing accommodating a generator, and a generator central shaft supported and supported by a generator shaft bearing inside the housing, wherein the entire cross-sectional area is provided in front of the generator central shaft for operation of the generator. A rotor wheel formed of a rotary ring around a circumferential circumference of a plurality of wheel supports, a plurality of wheel supports, and a plurality of rotor blades each connected and coupled to each other at a predetermined interval angle: A fixed hub and: a first rotation diverting bearing above the hub; A housing connected to an upper portion of the first rotating diverting bearing; a hub fixed above the housing; and a second rotating diverting bearing below the hub; a mold support fixed to a circumferential circumference of the second rotating diverting bearing; Each frame support on each of the upper and lower sides of the mold support, each of the reinforcement frame support, and the frame connected integrally: Each wheel in the lower portion of each frame support: Rails fixed to the building: Connected integrally, each supporting large windmill Afford operation. Sensing the natural wind direction in the hub top wind direction check sense transmitted to the engine control modulus to improve the natural wind to the front of the rotor, improve the rotor to improve the natural wind 100 (%) accommodating the generator central axis, the rotary ring, the top, bottom, left and right of the mold Circumferential bearing device: Integral connection Supports the operation of a large windmill with the entire cross-sectional area of the flow path as a function of energy efficiency.

When described in detail with reference to the accompanying drawings, the configuration is as follows.

(1), (2) and (3) is a side internal structure diagram according to the present invention, Figure 2 is a front view of Figure 1 and Figure 3 is a rear view of Figure 2, the housing 10 and The generator 20, the hub 30a, the generator central shaft 21, the generator shaft bearing 22, and the first direction change bearing 52 are similar to the typical propeller windmills of the conventional horizontal shaft type. .

The present invention is a wind system configuration for utilizing the mechanical properties of the air flow, the housing 10 accommodates the generator 20, which is supported by the generator shaft bearing 22 inside the housing 10 In the generator central axis 21,

In order to operate the generator 20, a plurality of rotor blades 40a and a plurality of rotor wheels 40a are respectively connected to the whole of the cross-sectional area in front of the generator central axis 21 and several rotor wheel supports 40b. 40c) is a windmill structure having a rotary wheel 40 structure having a rotary ring 40d around a circumference of the flow path cross section at angles of predetermined intervals.

The first rotation switching bearing 52, and the first rotation conversion bearing 52, the upper portion of the upper portion of the hub (30a) fixed to the building 30 for the support of the rotating wheel 40: the housing It is connected to the (10), each of the central pillar with the hub (10b) fixed above the housing (10).

The second rotation conversion bearing 53 and the first rotation conversion bearing (52,) and the circumferential rotation of the hub (30a) in the circumferential peripheral position of the hub 30a.

The mold support 60a fixed to the circumferential circumference of the second rotation conversion bearing 53, the mold support 60a fixedly connected to the left and right sides of the housing 10, and the mold support on the outer sides of the mold support 60a and 60b. 61) and the mold 60 is integrally connected to each of the reinforcing mold support 61. Each of the wheels 80 in the lower portion of the mold support 60a and the rails 90 fixed to the building 30 are integrally connected to each other to accommodate 100% of natural wind by using the entire cross-sectional area as a flow path section. It is a constituent device of the structure that can support the operation of the large windmill.

At this time, the natural wind direction is sensed by the first and the rotation switching bearings 52 and the lower engine control medium 51 is sensed by the upper wind direction check sense 50 of the hub 30b. The adjustable rotor 40 accommodates 100 (%) of the natural wind to enhance the action, with the centrifugal force of the generator central axis 21 at the inner center of the housing 10. Rotating wheel 40 The rotary ring 40d attached to the circumference of the body and the mold 60 are integrally connected to the centripetal force of each circumferential bearing 70 on the upper, lower, left, and right sides. According to the needs of the function, it is a constituent device that performs energy-efficiency with high efficiency.

FIG. 4 is a view showing the mold, the wheel, and the rail of the lower plane of FIG. 3, with the respective wheels 80 and the bottom of each mold pedestal 60a of the plane: Rail 90: Integrated connection Supports 100% natural wind energy generation. Safe operation of large windmills.

FIG. 5 is an enlarged view of a part of the wing of FIG. 2, wherein several rotor wheels 40a and a plurality of rotor wheels 40b are respectively connected and coupled to the entire cross-sectional area in front of the generator central axis 21. It is a windmill structure device of a part of the first rotor wheel 40 of the rotor wheel 40 configuration of the rotary ring 40d formed on the circumferential circumferential circumference of the plurality of rotor blades 40c at a predetermined interval angle.

Therefore, the present invention is limited to the ground installation area as a configuration that makes the total power value accommodating the maximum number of natural winds in the maximum maximal position to maximize the maximum wing size and the structure function that the rotor blades exist as a living being in mechanical energy conversion. The large-capacity windmills are integrally connected to the generator central shaft 21, the rotary ring 40d attached to the circumference of the wheel 40, and the respective circumferential bearings 70, respectively, and below the mold 60, respectively. The wheels 80 and the rails 90 are integrally connected and supported, and all the rotors are made of high-efficiency energy chunks to smoothly operate integrally according to the needs of each device structure function.

At this time, the present invention is a structure that converts the entire cross-sectional area of the rotor wheel 40 into the operating power energy by receiving the entire natural wind at the maximum position angle as shown using the mechanical specificity of the air flow to generate a high-efficiency power energy do.

According to the present invention, the total power value in which the entire cross-sectional area accommodates 100 (%) of natural wind at the maximum maximal position on the windmill blade is mechanical energy conversion and a large capacity windmill supports various devices. Energy generation We make effect to solve human energy and pollution.

Claims (4)

A multi-stage multi-wing wind power system, comprising: a housing (10) housing a generator and a generator central shaft (21) supported and operated by a generator shaft bearing (22) inside the housing (10), In order to operate the generator 20, a plurality of rotor blades 40a, several rotor wheel supports 40b, and a plurality of rotor blades are respectively connected and coupled to the entire cross-sectional area in front of the generator central axis 21. With the rotation difference 40 of the rotation ring 40d formation in the circumference | circumference of the flow path cross section which 40c makes a predetermined spacing angle: A hub (30a) fixed to the structure (30) for supporting the rotating wheel (40): a first rotation switching bearing (52,) above the hub (30a); The housing 10 connected above the first rotation conversion bearing 52, and the hub 30b fixed above the housing 10, and the second rotation conversion bearing 53 below the hub 30a. The mold holder 60a fixed to the circumferential circumference of the second rotation conversion bearing 53, the housing 10, the mold holder 60b on the left and right, and the mold holders 61 on the outer sides of the mold holders 60a and 60b. And each reinforcing mold support 62, and a mold 60 connected integrally with each wheel 80 under each mold support 60a, and a rail 90 fixed to the construction 30. And: integrally connected and supported. The hub 30b senses the direction of the natural wind in the upper wind direction check sense 50, and transmits it to the engine control medium 51. The control wheel 40 adjusts the natural wind 100 to improve the front of the rotor 40. %) Receiving generator central axis 21, rotary ring 40d, and each cylindrical bearing 70 device on the upper and lower left and right sides of the mold 60: integrally connected, each supporting all the rotating body of each device structure function Multi-stage multi-wing wind power system featuring high-efficiency energy Ching Chul, which handles smooth operation as needed. The method of claim 1, In order to operate the generator 20, a plurality of rotor blades 40a, several rotor wheel supports 40b, and a plurality of rotor blades are respectively connected and coupled to the entire cross-sectional area in front of the generator central axis 21. Multi-stage multi-wing wind power system characterized by the rotation difference 40 of the rotary ring 40d formed around the circumferential circumference of the passage 40c at a predetermined interval angle, The method of claim 1, A hub (30a) fixed to the structure (30) for supporting the rotating wheel (40): a first rotation switching bearing (52,) above the hub (30a); The housing 10 connected above the first rotation conversion bearing 52, and the hub 30b fixed above the housing 10, and the second rotation conversion bearing 53 below the hub 30a. The mold holder 60a fixed to the circumferential circumference of the second rotation conversion bearing 53, the housing 10, the mold holder 60b on the left and right, and the mold holders 61 on the outer sides of the mold holders 60a and 60b. And each reinforcing mold support 62, and a mold 60 connected integrally with each wheel 80 under each mold support 60a, and a rail 90 fixed to the construction 30. Wings: Multi-stage multi-wing wind power system, each of which is integrally connected, supporting large windmills The method of claim 1, The hub 30b senses the natural wind direction at the uppermost wind direction check sense 50, and transmits it to the engine control medium 51, and adjusts the rotating wind 40 so that the natural wind improves the front of the rotor 40. %) Receiving generator central axis 21, rotary ring 40d, and each cylindrical bearing 70 device on the upper and lower left and right sides of the mold 60: integrally connected and supporting all the rotating bodies need the respective device structure function Multi-stage multi-wing wind power system characterized by high-efficiency energy Ching Chul,

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