KR101476233B1 - The structure of the blade to get energy from the flowing fluid - Google Patents

Abstract

The present invention relates to a structure of a wing that obtains power from a fluid, a pillar (10) supporting a rotating body (20), and a first wing coupled to one end of a shaft (30) inserted in the rotating body (20) In the structure of the wing to obtain power from the fluid consisting of (40) and the second wing (50) coupled to the other end, the first wing (40) has an overall shape of a trapezoidal shape and the first upper surface (41a) and A first main surface 41 with a first lower surface 41b extending to one side, and a first inclined toward the first lower surface 41b from both left and right sides based on the longitudinal direction of the first upper surface 41a An inclined surface 42 and a third inclined surface 44 inclined toward the first lower surface 41b from one end of the first upper surface 41a adjacent to the shaft 30, the first main surface 41 Is extended from the lower end of the third inclined surface 44 toward the first upper surface 41a and the other end of the first main surface 41 that is not adjacent to the shaft 30 is sharply connected to the first upper surface 41a. , The second wing 50 has a second main surface 51 in which the entire shape is formed in a trapezoidal shape and the second upper surface 51a and the second lower surface 51b extend to one side, and the second upper surface 51a A second inclined surface 52 inclined toward the second lower surface 51b from both left and right sides based on the longitudinal direction of the second surface, and a second bottom surface at one end of the second upper surface 51a adjacent to the shaft 30 It includes a fourth inclined surface (54) inclined toward (51b), the second main surface 51 extends toward the second upper surface (51a) from the bottom of the fourth inclined surface 54 and adjacent to the shaft (30) It characterized in that the other end of the second main surface 51 is not sharply connected to the second upper surface (51a).

Description

The structure of the blade to get energy from the flowing fluid}

The present invention relates to a device for converting kinetic energy generated when a fluid such as wind or water flows into mechanical energy, that is, a structure and shape of a windmill or aberration.

The present invention relates to a wing in a power generation device using a fluid (flowing water or wind) on the earth, and more specifically, a structure of a wing that can obtain power from a low speed wind or flow rate by using hydraulic pressure as well as a fluid flow rate. It is about.

In general, a windmill or a water turbine is a device that generates necessary power by using wind or flow power that is generated and destroyed indefinitely on the earth, and has two or more wings.

In the case of a general windmill, the force that the blade rotates is obtained by the lifting force acting on the blade at the wind speed. Wings need to generate lift even at low wind speeds, and should not be damaged by strong wind speeds. At the same time, a braking system is needed to prevent the generator from rotating at too high a speed.

In the case of general hydro power generation, to use the potential energy of water, a river is blocked to build a dam or a water tank is made to confine the water, then the water gate is opened and the water is dropped downstream to create a stronger water pressure to turn the turbine.

In the case of the prior art windmill, most of them are a method of rotating the windmill using the speed of the wind, that is, lift. However, when the wind is weak, the lift does not generate enough to turn the windmill due to the load of the generator. In the case of windmills for power generation, most of the prior art wind power generators can generate power only by blowing winds of about 5m/s or more, but in Korea, some areas and islands with an average annual wind speed of 5m/s or more in the past 5 years at 50m altitude Almost none except. In addition, in the case of the conventional windmill, there is a problem that the direction of the windmill must be aligned toward the direction in which the wind blows. However, in the case of Gosan, Jeju Island, which has the highest annual average wind speed over the past 5 years at an altitude of 50 meters, the average wind speed is 7.9m/s, but the probability that the wind speed is equal to or higher than 5m/s is 29.5% and the power generation efficiency is about 30%. It does not have a problem.

In addition, in the case of a windmill using a conventional lift, it generates a lot of noise during rotation, and in developed countries such as Europe, it is regulated to maintain a certain distance from the residential area when installing a wind power generator.

In the case of hydroelectric power generation, power generation using a drop of water, which is the most of the prior art, requires construction of a dam that can trap water. In addition to the cost of astronomical construction, dam construction has many problems such as environmental destruction, conflicts with local residents, and even international disputes.

In order to solve the above problem, the structure of the wing that obtains power from the fluid according to the present invention is coupled to one end of the pillar 30 supporting the rotating body 20 and the shaft 30 inserted into the rotating body 20. In the structure of the wing to obtain power from the fluid composed of the first wing 40 and the second wing 50 coupled to the other end, the first wing 40 has a whole trapezoidal shape and a first upper surface The first main surface 41 with the 41a and the first lower surface 41b extended to one side, and toward the first lower surface 41b from both left and right sides based on the longitudinal direction of the first upper surface 41a. It includes a first inclined surface 42 inclined and a third inclined surface 44 inclined toward the first lower surface 41b from one end of the first upper surface 41a adjacent to the shaft 30, the first The main surface 41 extends from the lower end of the third inclined surface 44 toward the first upper surface 41a, and the other end of the first main surface 41 that is not adjacent to the shaft 30 has the first upper surface 41a. Connected sharply, the second wing 50 has a second main surface 51 in which the entire shape is formed in a trapezoidal shape and the second upper surface 51a and the second lower surface 51b extend to one side, and the second A second inclined surface 52 inclined toward the second lower surface 51b from both left and right sides based on the longitudinal direction of the upper surface 51a, and one end of the second upper surface 51a adjacent to the shaft 30 In the second lower surface (51b) comprises a fourth inclined surface (54) inclined toward, the second main surface (51) extends toward the second upper surface (51a) from the bottom of the fourth inclined surface (54) shaft ( 30) is characterized in that the other end of the second main surface 51 that is not adjacent to the second upper surface 51a is sharply connected to the second upper surface 51a.
The first and second wings 40 and 50 are characterized by being installed in even numbers.
The first wing 40 and the second wing 50 are characterized by being spaced at an angle within 70 to 110 degrees.
The thickness of the first and second wings 40 and 50 is increased from one end of the first and second main surfaces 41 and 51 to the third and fourth inclined surfaces 44 and 54 that are the other ends. do.

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The structure of the blade that obtains power from the fluid according to the present invention uses wind power as well as wind pressure, so that the blade can rotate at low wind speeds, regardless of the direction in which the wind flows, that is, up, down, left, and right. Since the blade rotates, there is no need to orient the blade according to the direction in which the wind flows, and even when the blade rotates, no noise is generated. Since the acceleration is controlled, there is no need to control the rotational speed of the rotating body.

In addition, in the case of hydroelectric power generation, it is possible to install power in a variety of sizes as needed, since it can be generated only with a simple device in a river or an algae flowing without a dam or a separate structure. Since there is no need to construct structures such as dams, it can be installed at a very low cost, and there is no dispute about environmental destruction, and there is no dispute between countries in rivers flowing through both countries or multi-countries.

1 is a perspective view showing the present invention.
FIG. 2 is a plan view showing angles at which the first wing and the second wing are fixed when the first wing and the second wing are viewed from one end of the shaft.
Figure 3 is an embodiment showing the direction of the force by the fluid pressure received by the first wing and the second wing when the fluid flows in front of the first and second main surfaces.

1 to 4 attached to the wing to obtain power from the fluid according to the present invention, the pillar 10 and the rotating body 20 and the shaft 30 and the first wing 40 and the second wing 50 ). The first wing 40 includes a first main surface 41, a first inclined surface 42 and a third inclined surface 44, and the second wing 50 has a second main surface 51 and a second inclined surface 52 and a fourth inclined surface 54.

In the present invention, the pillar 10 serves to support and secure the shaft 30, the first wing 40, and the second wing 50, but the specific implementation method is the same as the well-known technology. I won't.

In the present invention, the rotating body 20 is connected to the pillar 10 in a bearing manner and functions to transmit kinetic energy of the shaft 30 to a mechanical device as power to operate a device such as a generator. The method of transmitting power is also the same as the well-known technology, so I will not describe it separately.

In the present invention, the shaft 30 is connected to the rotating body 20 in a bearing manner to function to support the first wing 40 and the second wing 50.

In the present invention, the first wing 40 has a first main surface 41 in which the entire shape is formed in a trapezoidal shape, and the first upper surface 41a and the first lower surface 41b extend to one side, and the first upper surface 41a. ), a first inclined surface 42 inclined toward the first lower surface 41b from both left and right sides based on the longitudinal direction, and a first at one end of the first upper surface 41a adjacent to the shaft 30 A third inclined surface 44 inclined toward the lower surface 41b, the first main surface 41 extending from the lower end of the third inclined surface 44 toward the first upper surface 41a, and the shaft 30 The other end of the non-adjacent first main surface 41 is sharply connected to the first upper surface 41a.

The second wing 50 is formed in a trapezoidal shape, and the second upper surface 51a and the second main surface 51b extending from the second lower surface 51b to one side, and the length of the second upper surface 51a A second inclined surface 52b inclined toward the second lower surface 51b from both left and right sides based on the direction, and a second lower surface 51b at one end of the second upper surface 51a adjacent to the shaft 30 ), a fourth inclined surface 54 inclined toward the second main surface 51 extending toward the second upper surface 51a from the bottom of the fourth inclined surface 54 and not adjacent to the shaft 30 It is characterized in that the other end of the second main surface 51 is sharply connected to the second upper surface 51a.
The first and second wings 40 and 50 are installed in even numbers, and the first and second wings 40 and 50 are spaced at an angle within 70 to 110 degrees.
The first and second wings (40, 50) is characterized in that the thickness and weight increase from one end of the first and second main surfaces (41, 51) to the other end of the third and fourth inclined surfaces (44, 54). do.

The first wing 40 and the second wing 50 are fixed to the shaft 30 so that the shape is symmetrical on both the left and right sides of the rotating body 20, respectively, and the rotating body ( It functions to rotate the shaft 30 around 20). The first wing 40 and the second wing 40 and the shaft 30 are interlocked and fixed to move, and when viewed from one end of the shaft 30, the first wing 40 and the second wing ( 40) forms an angle within 70 to 110 degrees as illustrated in FIG.

The first wing 40 and the second wing 40 are coupled to the shaft 30 at a position adjacent to the third and fourth inclined surfaces 44 and 54, and the engaging position is the first and second wings 40 and 50 The center of gravity is formed around the third and fourth inclined surfaces 44 and 54 to which the shaft 30 is coupled, and when the shaft 30 is coupled to the position, rotation by the wind can be made more easily. .
When installing a weight such as a weight (not shown) in order to maintain the center of gravity at the coupling position of the shaft 30, the first wing 40 standing first in the direction in which the wind blows, that is, receiving wind pressure first, or The second wing (any one of the 500 blades makes an angle of 35 degrees to 55 degrees with the ground, so it can maintain an angle that can receive more wind pressure where there is a lot of mountainous terrain and a lot of upward airflow, so rotation can be made more easily. have.

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10: pillar
20: rotating body
30: shaft
40: first wing
41: first main surface
41a: first top surface
41b: first lower surface
42: first slope
44: third slope
50: second wing
51: second main surface
51a: Second top surface
51b: Second bottom
52: second slope
54: fourth slope

Claims (6)

With a pillar 10 supporting the rotating body 20, a first wing 40 coupled to one end of the shaft 30 inserted into the rotating body 20 and a second wing 50 coupled to the other end In the structure of the wing that is powered from the composed fluid,
The first wing 40,
The first main surface 41 in which the entire shape is formed in a trapezoidal shape and the first upper surface 41a and the first lower surface 41b extend to one side, and left and right based on the longitudinal direction of the first upper surface 41a. A first inclined surface 42 inclined toward the first lower surface 41b from both sides, and a third inclined toward the first lower surface 41b at one end of the first upper surface 41a adjacent to the shaft 30 It includes an inclined surface 44,
The first main surface 41 extends from the lower end of the third inclined surface 44 toward the first upper surface 41a and the other end of the first main surface 41 that is not adjacent to the shaft 30 is the first upper surface ( 41a),
The second wing 50,
The entire shape is formed in a trapezoidal shape, and the second upper surface 51a and the second lower surface 51b extend from one side to the second main surface 51, and the left and right sides of the second upper surface 51a in the longitudinal direction. The second inclined surface 52 inclined toward the second lower surface 51b from both sides, and the fourth inclined toward the second lower surface 51b from one end of the second upper surface 51a adjacent to the shaft 30 Including an inclined surface 54,
The second main surface 51 extends from the lower end of the fourth inclined surface 54 toward the second upper surface 51a and the other end of the second main surface 51 that is not adjacent to the shaft 30 has a second upper surface 51a. ) And the structure of the wing to get power from the fluid, characterized in that the pointed connection. According to claim 1,
The first and second wings (40, 50),
The structure of the wing which gets power from the fluid characterized by being installed in even numbers. According to claim 1,
The first wing 40 and the second wing 50,
A structure of a wing that is powered from a fluid, characterized by being spaced at an angle within 70 to 110 degrees. According to claim 1,
The first and second wings (40, 50),
The structure of the wing to obtain power from the fluid, characterized in that the thickness and weight increase as it goes from one end of the first and second main surfaces (41, 51) to the third and fourth inclined surfaces (44, 54). delete delete

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