KR101002174B1 - Active flow varying multi-arrayed horizontal axis turbine tidal current power device - Google Patents

Abstract

The disclosed active direct current control multi-row horizontal axis tidal current generator, the support is fixed to the sea bottom; A power generation unit provided with at least one support unit, the tubular underwater enclosure, a rotor rotated by a bird in a state rotatably installed in the underwater enclosure, and a power generation assembly configured to receive and generate rotational force of the rotor; Including a rotary connection rotatably installed in the support portion, the power generation portion is rotated in accordance with the direction of the tidal flow so that the inflow angle of the fluid to the rotor is maintained at a right angle.

Such an active direct current control multi-array horizontal axis tidal power generation device, the power generating unit rotates by the tidal power in the water is rotatably installed on the support portion as a rotatable connection portion, the buoyancy body is installed to maintain the level in the water in the power generation unit Can be. Therefore, the power generation unit is rotated by the rotary connection portion in the water according to the direction, so that the inflow angle of the fluid to the rotor is always maintained at a right angle, the generation efficiency is maintained high regardless of the direction.

Description

Active flow varying multi-arrayed horizontal axis turbine tidal current power device}

The present invention relates to an active direct current control multi-array horizontal axis algae generator, and more particularly, to an active direct current control multi-array horizontal axis algae generator that generates power using a high current or current of the ocean.

In general, a tidal current generator is installed in a place where the tidal velocity is high, and a tidal current generator is generated using tidal current, which is the kinetic energy of seawater. It is being developed by the flow. That is, the rotor provided on one side of the generator is generated while rotating by the tidal current, the flow of sea water.

The efficiency and amount of power generated by the tidal current generator have a great relationship with the frankincense, that is, the direction of incidence of the tidal current generator. In other words, the rotor that changes the fluid flow to the rotational motion is designed based on the incidence angle of the fluid at 90 degrees and has the cross-sectional shape of the blade and the inclination angle of the cross-section so that the highest rotational motion can be achieved. Therefore, in recent years, the practical horizontal axis tidal current generator has a device to increase the power generation efficiency by changing the blade pitch angle of the rotor according to the flow rate, and it is also applied to the change of direction.

However, in the conventional tidal current generator, since the generator assembly and the rotor are fixed integrally to the upper part of the pillar embedded in the sea bottom, the rotation of the rotor is not constant when the flow direction of the seawater changes, so that the output of electricity generated is stable. There is a problem. That is, the conventional tidal current generator, when the flow direction of the sea water is incident from the rear of the pillar, there is a problem that the rotational movement of the generator is sharply lowered due to the interference of the pillar.

It is an object of the present invention to provide an active direc- tive multi-array horizontal axis tidal current generator that enables stable power generation irrespective of frankincense.

The present invention, the support is fixed to the sea bottom; At least one installed on the support portion, the generator portion is provided with a tubular underwater enclosure, a rotor rotated by a bird in a state rotatably installed in the underwater enclosure, and a power generation assembly for receiving and generating the rotational force of the rotor Wow; Including a rotary connector for rotatably installing the power generation unit, Active direction control multi-array horizontal axis tidal power generation to maintain the inflow angle of the fluid to the rotor while rotating the power generation unit in accordance with the direction of the tidal current Provide the device.

At this time, the support is a column-shaped length member, the lower end may be fixed to the sea bottom surface.

The support portion includes an anchor fixed to the sea bottom; The other end may include a mooring rope in which the power generation unit is coupled and installed by the rotation connection part while one end is coupled to the anchor. Here, the buoy cable extending to the mooring rope; A buoy for displaying the position of the power generation unit may be further included while drifting on the sea while being connected to the buoy cable.

In addition, the rotation connecting portion, the rotating cylinder is rotatably installed on the support; A head rotatably installed on the rotor; It may include a ring-shaped connecting body connecting the rotating cylinder and the head.

In addition, the power generation unit may further include a buoyancy body disposed in the underwater enclosure to keep the power generation unit in a horizontal state in the water.

In the active direct current control multi-array horizontal axis tidal current generation device according to the present invention, the power generation unit rotating by the tidal current in the water is rotatably installed on the support as a rotary connection, the buoyancy body to maintain the horizontal in the power generation unit Can be installed. Therefore, the power generation unit is rotated by the rotary connection portion in the water according to the direction, so that the inflow angle of the fluid to the rotor is always maintained at a right angle, the generation efficiency is maintained high regardless of the direction.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is an installation state diagram of an active direct current control multi-array horizontal axis tidal current generator according to an embodiment of the present invention, Figure 2 is a partially enlarged cross-sectional view of FIG. 1 and 2, the active direct current control multi-array horizontal axis tidal current generation device includes a support part 100, a power generation part 200, and a rotation connection part 300.

The support part 100 is placed in the water in the power generation unit 200 to be described later in a fixed state installed on the sea bottom. The support portion 100 is a columnar length member, the lower end of which is fixed to the bottom surface. In the pillar-shaped support part 100, a plurality of auxiliary frames (not shown in the drawing) are provided such that the support part 100 is stably fixed to the sea bottom in a state in which the support part 100 is fixed to the sea bottom. You can also connect them.

3 is an installation state diagram of an active direct current control multi-array horizontal axis tidal current generator by the support 110 of another embodiment. Referring to FIG. 3, the support 110 may include an anchor 111 and a mooring rope 112.

The anchor 111 is a structure that is fixed to the sea bottom surface. This, the anchor 111 is connected to one end of the mooring rope 112 to be described later in the state fixed to the sea bottom. Accordingly, the anchor 111 allows the power generation unit 200 to maintain a predetermined position in the water.

The mooring rope 112 connects the power generation unit 200 and the anchor 111 so that the power generation unit 200 to be described later is installed on the water in a state of being locked to the anchor 111. One end of the mooring rope 112 is coupled to the anchor 111, and the other end of the mooring rope 112 is installed in a rotatable state by the rotary connection unit 300 to be described later.

Here, the buoy cable 113 may be extended to the end of the mooring rope 112. When one end of the buoy cable 113 is connected to the mooring rope 112, the buoy 114 is connected to the other end of the buoy cable 113. Accordingly, the buoy 114 is able to grasp the position of the power generation unit 200 located in the water while drifting at sea in the connected state with the mooring rope 112 by the buoy cable 113.

The power generation unit 200 is located in the water in the state installed in the support unit 100, 110, and is generated while rotating by the tidal current. Here, the power generation unit 200 shown in the embodiment is shown that one is installed in the support portion 100, 110, but not limited to this, as shown in Figure 6 a plurality of the support portion 100 to increase the power generation capacity Of course, the dog can be installed, as well as the support 110 according to another embodiment in FIG. 3 described above can be installed a plurality of the power generation unit 200 in a state spaced apart from each other.

The power generation unit 200 includes an underwater enclosure 210, a rotor 220, and a power generation assembly 230.

The submersible body 210 fluidizes the power generation assembly 230 so that power generation can be made in the power generation assembly 230 which receives the rotational force from the rotor 220 when the rotor 220 to be described later rotates. It has a cylindrical shape that is sealed to protect it from. Referring to FIG. 4, a ring-shaped support plate 211 having a bearing 212 disposed therein is installed to support an end of the rotating shaft 221 of the rotor 220 in a rotatable state within the underwater enclosure 210. do. Here, reference numeral 213 is a cable transfer hole for passing the cable 10 for transmitting power, monitoring signals, etc. produced in the power generation assembly 230 to be described later.

The rotor 220 changes the horizontal movement of the flow rate to the rotational movement. This, the rotor 220 is rotatably installed in the underwater enclosure (210). That is, the rotation shaft 221 of the rotor 220 is rotatably coupled to the bearing 212 disposed on the support plate 211 inside the underwater enclosure 210. Here, the rotating shaft 221 of the rotor 220 has a tubular shape having a space therein so as to connect the cable 10 described above to the outside.

The power generation assembly 230 receives the rotational force from the rotor 220 to produce power. The power generation assembly 230 includes a plurality of gears 231 for converting rotational speed in a state connected to the rotation shaft 221, and a generator 7 for generating power using the rotational force transmitted from the gears 231. do.

Here, the power generation unit 200 may include a buoyancy body 240 coupled to the underwater enclosure 210. The buoyancy body 240 allows the underwater enclosure 210 to maintain a horizontal state without being inclined to one side in the water. Here, the buoyancy body 240 is installed by adjusting the buoyancy according to the weight of the power generation unit 200.

The rotation connection part 300 allows the power generation part 200 to be rotatably installed on the support part 100. The rotation connector 300 allows the power generation unit 200 disposed in the water according to the direction of the rotation to rotate. That is, the rotary connection unit 300 allows the power generation unit 200 to rotate in accordance with the direction, so that the inflow angle of the fluid to the rotor 220 can maintain a right angle.

Referring to FIG. 2, the rotation connector 300 includes a rotation cylinder 310, a head 320, and a connection body 330.

The rotary cylinder 310 is rotatably installed in the support portion (100, 110). In the rotation cylinder 310, a bearing (not shown) may be disposed in the support part 100 and 110 so that the rotation can be easily installed. Here, one side of the rotating cylinder 310 is provided with a pad-eye (311) for connecting the connecting member 330 and the rotating cylinder 310 to be described later. The pad eye 320 allows the power generation unit 200 to be connected to the rotation cylinder 310 in a state where free movement is possible.

The head 320 is rotatably installed in the front portion of the rotor 220 of the power generation unit 200. That is, one end of the connector 330 to be described later is connected to the head 320. Such, the front portion of the head 320 is provided with a pad eye 321 so that one end of the connector 330 is connected. As described above, the pad eye 321 of the head 320 allows the power generation unit 200 to be connected to one end of the connector 330 in a state where free movement is possible.

The connector 330 connects the rotary cylinder 310 and the head 320. That is, one end of the connector 330 is connected to the pad eye 320 of the rotary cylinder 310, the other end is coupled to the head 320. The connection body 330 has a ring shape to be connected to the pad eye 311 of the rotary cylinder 310 and the pad eye 321 of the head 320.

As such, the rotation connection part 300 is rotatably connected to the power generation part 200 on the support part 100. Therefore, as shown in FIG. 5, the power generation unit 200 is rotated according to the direction of the water, and the inflow angle of the fluid to the rotor 220 is always maintained at a right angle, so that the rotation efficiency of the rotor 220 is high. As a result, the power generation efficiency is increased accordingly.

Referring to the operation of the active direct current control multi-array horizontal axis tidal current generator according to an embodiment made in such a configuration, first, the power generation unit (3) to the support portion 100 fixed to the bottom surface; 200) is rotatably installed. At this time, the power generation unit 200 is located in the water submerged in the fluid.

Then, the rotor 220 of the power generation unit 200 is rotated by the flow of the fluid, that is, the flow rate of the tidal current, and transmits the generated rotational force to the power generation assembly 230 to generate power.

Subsequently, in the case where the direction of the tidal flow is changed, the power generation unit 200 is rotated by the rotation connection part 300 such that the direction of the incense incident on the rotor 220 is perpendicular.

As such, the active direct current control multi-array horizontal axis tidal current generator according to an embodiment, the power generation unit 200 that is rotationally generated by the tidal current in the water is rotatably installed on the support portion 100 as a rotary connection portion 300 do. Accordingly, the power generation unit 200 is rotated by the rotary connection unit 300 according to the direction of the water, so that the inflow angle of the fluid to the rotor 220 is always maintained at a right angle, the generation efficiency is high regardless of the direction maintain.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is an installation state diagram of an active direct current control multi-array horizontal axis tidal current generator according to an embodiment of the present invention.

FIG. 2 is a partially enlarged cross-sectional view of FIG. 1.

3 is an installation state diagram of an active direct current control multi-array horizontal axis tidal current generator according to another embodiment of the present invention.

4 is a front view of the support plate shown in FIG. 2.

5 is an operational state diagram of an active direct current control multi-array horizontal axis tidal current generator according to an embodiment of the present invention.

6 is an installation state diagram of an active direct current control multi-array horizontal axis tidal current generator according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

100, 110: support portion 200: power generation portion

210: underwater enclosure 220: rotor

230: power generation assembly 240: buoyancy body

300: rotary connection 310: rotary cylinder

320: head 330: connecting body

Claims (6)

A support part fixed to the sea bottom; At least one installed on the support portion, the generator portion is provided with a tubular underwater enclosure, a rotor rotated by a bird in a state rotatably installed in the underwater enclosure, and a power generation assembly for receiving and generating the rotational force of the rotor Wow; Including a rotary connector for rotatably installing the power generation unit, Active direction control multi-array horizontal axis tidal power generation to maintain the inflow angle of the fluid to the rotor while rotating the power generation unit in accordance with the direction of the tidal current Device. The method according to claim 1, The support portion is a column-shaped length member, the active direction control multi-array horizontal axis tidal current generator is fixed to the bottom of the bottom end. The method according to claim 1, The support portion An anchor fixed to the sea bottom; Active direction control multi-row horizontal axis tidal current generator comprising a mooring rope coupled to the power generation portion by the rotary connection portion at the other end is coupled to the anchor. The method according to claim 3, A buoy cable extending and connected to the mooring rope; And a buoy which displays the position of the power generation unit while drifting on the sea while being connected to the buoy cable. The method according to claim 1 or 3, The rotation connection portion, A rotating cylinder rotatably installed on the support portion; A head rotatably installed on the rotor; An active direct current control multi-row horizontal axis tidal current generator comprising a ring-shaped connecting body connecting the rotating cylinder and the head. The method according to claim 1, The generating unit further includes a buoyancy body disposed in the underwater enclosure to keep the generating unit horizontal in the water.

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