KR20080070179A - Simultaneous Power Generation of Small Hydropower and Wind Power - Google Patents

Abstract

An apparatus for generating small hydro power and wind power is provided to employ six blades with a predetermined angle of 60 degrees so that torque is increased. A watermill blade, a watermill fixing cylinder, a windmill blade, a wind rotation cylinder, and a horizontal rotational plate(5) are connected to each other. A groove is formed in upper and lower diameters of a central rotation shaft(2), and a bearing is inserted into the groove. The central rotation shaft and a central rotation shaft support(1) are connected to each other such that the central rotation shaft freely moves in relation to the central rotation shaft support. A column of the central rotation shaft is fixed to a floating boat(8). A hydraulic device is mounted on the floating boat, so that the central shaft support moves up and down.

Description

Simultaneous Generation of Small Hydro and Wind Powers

1 is an overall structure diagram.

Fig. 2 Center of rotation shaft

3 is a rotational shaft support structure diagram.

4 aberration detail.

5 windmill detailed view.

6 is a structural diagram of a circular horizontal rotating plate.

7 power train system diagram.

8 is an example of assembly of assembly parts.

* Description of Symbols for Important Parts of Drawings *

1.Center pivot support.

2. Center of rotation axis.

3. Windmill Rudder.

4. Windmills.

5. Circular horizontal turntable.

6. Generator.

7. Aberration.

8. Buoyancy lines.

9. Fixed beam.

10. Fixed anchor.

11. Aberration fixing support.

The present invention relates to an apparatus for generating power by using hydropower and wind power on a buoyancy line at the same time.

Existing buoyant power generators use only water flow on the water surface, so there are many shortcomings in the installation of facilities. Other small hydropower generators are submerged in water depending on the precipitation level or are severely affected by continuous power generation. There is a weak point.

The present invention is a device for generating power and wind power using the buoyancy line at the same time as the power, the water power uses the water flow of the water surface and the depth, the wind power up to the height of the equipment from the equipment surface and wind flow in any direction by using the rotational force Use it as a power source.

In addition, depending on the amount of water flow and speed using the water flow of the river, the ebb and flow of the sea, the flow of the sea, the drainage of the reclaimed land (Asan Bay, Cheonsu Bay, etc.) As it has the advantage of increasing power generation.

The present invention has been made to solve the above problems, the object of the invention is to arrange the aberration buoys and windmills on the same axis to generate rotation by hydraulic power and wind power to complete the power generation to the generator.

In order to achieve this object, the power generation according to the present invention is characterized by transmitting power to a generator by generating a rotating force on the central axis and the horizontal rotating plate on the same axis by using a small force and wind power at the same time, in detail by the accompanying drawings The explanation is as follows.

In the present invention for achieving the above object (1-a) is a power generation device using a small hydrophobic force and wind power on one buoyancy line at the same time, Figure (1-a, b, ...) is one buoyancy As a structure in which a large number of facilities are installed on a ship, as shown in the center rotation shaft diagram (2A, B), both sides of the outer diameter of the center rotation shaft are regularly cut to make aberration blades, aberration fixing cylinders, windmill wings, windmill rotation cylinders, and horizontal The assembly of the rotating plate to facilitate the fixing, and to prevent the fixture parts to overlook the rotation of the central axis of rotation as shown in Figures 4, 5 and 6.

The center shaft material is selected by high-strength pipe, and the shaft support is installed as shown in (3).

The upper and lower parts of the center rotating shaft are inserted with a grooved bearing in the inner diameter of the upper and lower portions of the center rotating shaft as shown in Fig. 2 (d), and the center rotating shaft is connected by assembling the center rotating shaft and the center rotating shaft support. Drive freely from the central shaft fixing support.

Secure the central axis support column to the buoyancy line as shown in Figure (3), and move the central axis support up and down (when the central axis support is moved below the surface of the ice during the freezing of winter steel). -A, C) is used as a hydraulic device to move the central shaft support up and down, and to fix it with a fixed lock as shown in Fig. 3 (b).

As shown in Fig. 4, the construction and description of the aberration is made by rotating the aberration vane (4-c) in the center axis of rotation (2) as shown in Fig. 4, and the aberration blade material is rigid elastic material (FRP, carbon ceramic, Rigid plastics, etc.) are used, and the arrangement of the wings improves the rotational force by arranging six in a circle at 60 ° intervals as shown in Fig. 4 (d), and the aberration is as shown in Fig. 4. It is aimed at using the water flow and the whole of the installation depth of the equipment, and the fixed aberration cylinder type rotates the water flow to reduce the disturbance of the water flow on the aberration rotor rotation as shown in Fig. 4 (4). When the water flows in one direction (river, sea flow, reclamation only), one side of the water pipe is cut and opened as shown in Fig. 4A. It acts on the aberration blades to rotate the central axis of rotation. In addition, when the water flow alternately flows in both directions (when the tide of the sea, when the ebb tide) (4-B), both sides of the circular cylinder is cut open to open and close by the water flow force on both sides.

The switchgear is automatically opened and closed by the force of water when the water flow flows in either direction as shown in Fig. 4 (bar).

At this time, the working wing of the open surface is acting, and rotates.

In addition, the opposite side is automatically closed by the force of the water and protects the rotational force by preventing the water access to the wing.

In addition, the flow of the flow in either direction of the two sides in the same manner as the rotary blades use the rotational force in one direction.

Aberration fixed cylindrical material is preferably used to process a stainless steel plate resistant to corrosion,

In addition, the aberration fixing cylindrical type, as shown in Fig. 4 (e), fixes the upper and lower parts of the cylindrical center to the central axis by inserting bearings in the outer diameter of the central axis as shown in Fig. 4-4. It can be driven freely from the cylinder.

The configuration and description of the windmill is to rotate by fixing the windmill blade diagram (5-bar) in the central axis of rotation (2) as shown in Figure (5), the material of the windmill blade is a rigid elastic material (carbon ceramic, FRP , .... etc.), and the arrangement of the wings improves the rotational force by arranging 6 pieces at 60 ° intervals as shown in Fig. 5 (G), and the windmill is installed at the height of the installation height as shown in Fig. (5). Use the wind flow until.

The rotating cylinder of the windmill is installed as shown in Fig. 5 (a), and the wind flow reduces the interference of the windmill rotor blade rotation (referring to the rotation of the vanes in the rotor cylinder) to make the rotation smooth. As shown in Fig. 5 (b), the rudder guides the direction of the wind to the inlet of the rotating cylindrical opening so that the wind flow acts on the windmill action vanes to rotate the central axis of rotation.

The windmill rotating cylindrical material is made of light, strong and elastic material (carbon ceramic, FRP ... etc.), And the rotating cylinder of the windmill is bearing on the upper and lower part of the cylindrical center as shown in Fig. 5 (d). Put the center rotation shaft and the windmill rotation cylinder to rotate freely without interfering with each other rotation and driving.

As shown in Fig. 5 (e), the fixing ring is installed one at the top of the diagram (5-c) and one at the bottom of the diagram (5-d). As the windmill rotating cylinder continues to drive, play occurs between Fig. 5 (d) and Fig. 2 to prevent the windmill rotating cylinder from slipping on the central axis and changing the position of the windmill rotating cylinder.

The rudder material of the windmill is light and durable and is made of rigid elastic materials (carbon ceramic, FRP ... etc.), and a pair is installed on the windmill rotating circle diagram (5-a) as shown in FIG.

In addition, the rudder induces wind in all directions of the wind flow in all directions and allows the wind to rotate by acting on the action wing (the force of the wind pushes).

Circular horizontal rotary plate is fixed to the horizontal rotary plate connected to the central axis of rotation as shown in Figure (6) and makes a groove in the side of the horizontal rotary plate to transfer power through the belt.

The horizontal rotating plate is preferably made of aluminum, which is a light metallic material.

Power transmission from the horizontal rotary plate to the generator is generated by connecting the power to the horizontal and vertical gears through the horizontal rotary plate rotation as a belt as shown in Figure 7 and connecting the power to the generator.

Assembling and fixing of aberration wing, water cylinder, horizontal rotating plate, windmill wing, and windmill rotating cylinder on the central axis of rotation is carried out in the same way as the assembly 'example' of Fig. 8 Fix it with bolt nut.

The fixed beam anchors the beam when anchored to a buoyant river or sea.

An anchor is also used to anchor buoyancy lines in deep seas.

As described in detail above, the present invention can generate power regardless of the season as a device for generating power by using the hydrophobic force and the wind power on the same rotary shaft simultaneously. (When the winter steel freezes, the aberration moves below the surface freezing point. At this time, only the rotating shaft rotates at the freezing point, so the central shaft rotation is not affected by the friction of the central shaft rotation between the ice and the central rotating shaft.)

It also uses buoyancy to develop when there is a significant increase in flooding and precipitation, and develops wherever there is a large amount of water (e.g. ocean tide, ebb, sea flow, rivers, drainage of reclaimed land, etc.). can do.

In addition to the above, according to the strength of the wind is a certain amount of continuous power generation and the generation of wind power is added to the advantage.

Claims (4)

Drive means for generating rotational power by using water and wind of river or sea and wind power on the buoyancy line using the same central axis of rotation with aberrations and windmills, and driving the horizontal rotating plate fixedly connected to the drive means. And a power generating device characterized by generating power by connecting power to a generator via a horizontal and vertical gear. It is a method to apply the power of hydraulic power and wind power completely to the working wing of aberration and windmill. Power generating device. The method according to claim 2, wherein the actuating wing force of the aberration and the actuating wing force of the windmill are connected to the central axis of rotation and driven to drive the circular male rotary plate fixedly connected to the central axis of rotation. Characterized in that the generator. The power generation apparatus according to claim 3, wherein when the power is generated by separating the working wing force of the aberration and the working wing force of the windmill (separate the hydraulic power and the wind power), the hydropower is a small hydro power generation, and the wind power is the wind power generation.

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