KR102445501B1 - Tidal power generator - Google Patents

Abstract

Disclosed is an invention relating to a tidal energy conversion device for tidal power generation, which converts the up-and-down motion of a buoyant body into a unidirectional rotating motion and generates electricity by a conversion and power generation unit when the buoyant body is lifted by a sea level change, so that repetitive energy such as tidal difference or wave height can be continuously utilized. The disclosed tidal energy conversion device for tidal power generation includes a support frame which is fixedly installed in the sea water, a buoyant body which floats by the sea water, and a conversion and power generation unit which produces electricity by converting the up-and-down motion of the buoyant body into a unidirectional rotating motion when the buoyant body is lifted by a sea level change.

Description

Tide energy converter for tidal power generation {TIDAL POWER GENERATOR}

The present invention relates to a tidal energy conversion device for tidal power generation, and more particularly, when the buoyancy body is floating in seawater, the conversion power generation unit converts the lifting motion of the buoyancy body into a one-way rotational motion to produce electricity, thereby generating electricity. It relates to a tidal energy conversion device for tidal power generation that can continuously utilize repetitive energy, such as a wave height caused by a difference or an ocean current.

Recently, as eco-friendly green energy, power generation using natural power such as wind power, solar power, and algae is attracting attention. Hydroelectric power generation has site conditions and huge construction cost, thermal power generation has atmospheric warming and pollution, nuclear power has problems with residents’ rejection and radiation, green energy such as wind and solar power has a problem of stable power supply due to weather changes, and tidal power generation using dams is located There are problems such as conditions and construction cost.

On the other hand, in Korea, there are scattered straits or waterways where rapid currents and waves are formed between islands and land in the west and south coasts of the archipelago, or between islands, so there is a lot of potential for low-cost and eco-friendly tidal power generation using them.

In particular, the tide has the advantage of being able to produce electricity in a planned manner because the amount of power generation can be sufficiently predicted because the ebb and flow are repeated by a constant tidal cycle. is in progress

Since most of these conventional tidal current generators generate power independently using one blade, the size of the blades is limited in areas with low water depth in the ocean or rivers, so a plurality of small generators are installed to operate a plurality of generators. Therefore, there is a problem that not only the economic feasibility is reduced, but also the maintenance work is quite difficult because the foundation construction cost according to the facilities of the tidal current generator is excessively required.

Therefore, there is a need to improve it.

As a related background technology, there is Republic of Korea Patent Publication No. 10-1226719 (Registered on Jan. 21, 2013, title: Floating tidal current generator and its construction method).

The present invention was created by the necessity as described above, and when the buoyancy body floats in seawater, the conversion power generation unit converts the lifting motion of the buoyancy body into a one-way rotational motion to produce electricity, thereby generating electricity An object of the present invention is to provide a tidal energy converter for tidal power generation that can continuously utilize repetitive energy such as wave height.

In order to achieve the above object, a tidal energy conversion device for tidal power generation according to an embodiment of the present invention includes a support frame, a buoyancy body floating by buoyancy in seawater, and the buoyancy body when the buoyancy body is lifted due to a change in the water level of the seawater. It includes a conversion power generation unit for generating electricity by converting the lifting motion into a one-way rotational motion.

The conversion power generation unit includes a support that is fixedly installed on the upper side of the support frame, a rotation shaft that is rotatably provided on the support, and a rotation shaft that is provided in the rotation shaft, and is connected to the buoyancy body so as to be rotated by the lifting and lowering of the buoyancy body. A link member, an interlocking rotation generating unit that is linked to the rotating link member to generate a one-way rotational force when the rotating link member reciprocates, and an electricity production unit provided on the support to receive the rotational force of the interlocking rotation generating unit to produce electricity. include

The interlocking rotation generating unit includes a support shaft rotatably supported by the support, a first interlocking rotation guide for guiding the support shaft to rotate in one direction in association with the rising of the rotation link member, and the support shaft portion is the rotation link It includes a second interlocking rotation guide for guiding to rotate in one direction in conjunction with the lowering of the member.

The first interlocking rotation guide portion includes a first interlocking sprocket provided on the rotation shaft portion, a first latch sprocket provided to be rotatably interlocked or idling on the support shaft portion, and a pair of rotatably provided on the support rotatably spaced apart When the first guide sprocket and the first interlocking sprocket are rotated as the rotation link member is raised, the first guide sprocket is rotated in a direction opposite to the rotation direction of the first interlocking sprocket, and the first latch sprocket is the support shaft portion and a first connecting chain connecting the first interlocking sprocket, the first latch sprocket, and the first guide sprocket to rotate in the same direction as the rotational direction of the first interlocking sprocket.

The second interlocking rotation guide portion includes a second interlocking sprocket provided on the rotating shaft portion, a second latch sprocket provided to be rotatably interlocked or idling on the support shaft portion, and a pair of rotatably provided spaced apart on the support. When the second guide sprocket and the second interlocking sprocket are rotated in the downward direction of the rotation link member, the second guide sprocket is rotated in the same direction as the rotation direction of the second interlocking sprocket, and the second latch sprocket is connected to the support shaft portion. and a second connecting chain connecting the second interlocking sprocket and the second latch sprocket and the second guide sprocket to rotate together in a direction opposite to the rotational direction of the second interlocking sprocket.

The electricity production unit includes a plurality of speed-increasing rotation units installed on a support so as to be able to rotate at increased speed with the rotational force of the support shaft, a flywheel that receives the rotational force of the increase-speed rotation unit in a storable manner, and a generator that produces electricity with the rotational force stored in the flywheel. include

The tidal energy conversion device for tidal power generation according to the present invention has a structure to produce electricity by converting the lifting motion of the buoyancy body into a one-way rotational motion when the buoyancy body elevates due to a change in the water level of the seawater. Alternatively, there is an effect of continuously utilizing repetitive energy such as wave height.

1 is a perspective view showing a tidal energy conversion device for tidal power generation according to an embodiment of the present invention.
2 is a side view illustrating a tidal energy conversion device for tidal power generation according to an embodiment of the present invention.
3 is a plan view illustrating a tidal energy conversion device for tidal power generation according to an embodiment of the present invention.
4 is a perspective view illustrating an interlocking rotation generating unit and an electricity generating unit in the tidal energy conversion device for tidal power generation according to an embodiment of the present invention.
5 is another perspective view illustrating an interlocking rotation generating unit and an electricity generating unit in the tidal energy conversion device for tidal power generation according to an embodiment of the present invention.
6 is an operation diagram illustrating the operation state of the conversion power generation unit when the buoyancy body rises in the tidal energy conversion device for tidal power generation according to an embodiment of the present invention.
7 is an operation diagram illustrating an operating state of the conversion power generation unit when the buoyancy body descends in the tidal energy conversion device for tidal power generation according to an embodiment of the present invention.

Hereinafter, an embodiment of a tidal energy conversion device for tidal power generation according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a perspective view showing a tidal energy converter for tidal power generation according to an embodiment of the present invention, FIG. 2 is a side view showing a tidal energy converter for tidal power generation according to an embodiment of the present invention, FIG. 3 is a plan view showing a tidal energy conversion device for tidal power generation according to an embodiment of the present invention, and FIG. 4 shows an interlocking rotation generating unit and an electricity generating unit in the tidal energy converting device for tidal power generation according to an embodiment of the present invention. One perspective view, FIG. 5 is another perspective view showing an interlocking rotation generating unit and an electricity generating unit in the tidal energy conversion device for tidal power generation according to an embodiment of the present invention, and FIG. 6 is tidal power generation according to an embodiment of the present invention. It is an operation diagram showing the operation state of the conversion power generation unit when the buoyancy body rises in the tidal energy conversion device for tidal energy, and FIG. 7 is the operation of the conversion power generation unit when the buoyancy body descends in the tide energy conversion device for tidal power generation according to an embodiment of the present invention. It is an operation diagram showing the state.

1 to 7 , the tidal energy conversion device for tidal power generation according to an embodiment of the present invention includes a support frame 100 , a buoyancy body 200 , and a conversion power generation unit 300 .

The support frame 100 is fixedly installed on the sea or land to provide a space in which the conversion power generation unit 300 is operably installed. At this time, the support frame 100 is disposed so that the upper portion is exposed from the seawater when the seawater is high tide. Of course, the support frame 100 is shown in the figure in a rectangular parallelepiped shape, but is not limited thereto, and may be made of various shapes and materials.

And, the buoyancy body 200 floats in seawater by buoyancy. The buoyancy body 200 serves to be alternately raised and lowered by a change in the water level of the seawater or the wave force of the seawater while being connected to the end of the rotating link member 330 provided in the conversion power generation unit 300 . At this time, the shape and material of the buoyancy body 200 is not limited, and may be variously changed within the technical idea that can float by buoyancy in seawater.

On the other hand, the conversion power generation unit 300 generates electricity by converting the lifting motion of the buoyancy body 200 into a one-way rotational motion when the buoyancy body 200 elevates due to a change in the water level of the seawater.

To this end, the conversion power generation unit 300 includes a support 310 fixedly installed on the upper side of the support frame 100 , a rotary shaft portion 320 rotatably provided on the supporter 310 , and a rotary shaft portion 320 . It is provided, and the rotation link member 330 connected to the buoyancy body 200 so as to be rotated by the lifting and lowering of the buoyancy body 200, and the rotation link member 330 when the rotation link member 330 is reciprocally rotated is linked to a one-way rotational force It includes an electricity production unit 350 provided in the support 310 to generate electricity by receiving the rotational force of the interlocking rotation generating unit 340 and the interlocking rotation generating unit 340 for generating the .

That is, when the buoyancy body 200 is raised and lowered by the tidal difference or wave force of seawater and the rotary link member 330 is reciprocally rotated, the interlocking rotation generating unit 340 is linked to the reciprocating rotation of the rotary link member 330, It is rotated in one direction to transmit the rotational force to the electricity production unit 350 .

To this end, the interlocking rotation generating unit 340 guides the support shaft portion 341 rotatably supported by the support 310 and the support shaft portion 341 to rotate in one direction in association with the rise of the rotation link member 330 . and a second interlocking rotation guide part 343 for guiding the first interlocking rotation guide part 342 and the support shaft part 341 to rotate in one direction in conjunction with the lowering of the rotation link member 330 .

Specifically, the first interlocking rotation guide part 342 includes a first interlocking sprocket 342a provided on the rotation shaft part 320 and a first latch sprocket 342b provided on the support shaft part 341 to allow interlocking rotation or idling. ) and the first guide sprocket (342c) and the first interlocking sprocket (342a) rotatably provided as a pair on the support 310 while being spaced apart from each other when the rotation link member 330 is rotated by the rise of the first guide sprocket ( 342c) is rotated in a direction opposite to the rotational direction of the first interlocking sprocket 342a, and the first latch sprocket 342b is rotated together with the support shaft portion 341 in the same direction as the rotational direction of the first interlocking sprocket 342a. and a first connecting chain 342d connecting the first interlocking sprocket 342a, the first latch sprocket 342b, and the first guide sprocket 342c to be rotated.

At this time, the first latch sprocket 342b is constrained to the support shaft portion 341 to rotate together with the support shaft portion 341 when the first interlocking sprocket 342a is rotated due to the rise of the buoyancy body 200, and the buoyancy body 200 ), when the first interlocking sprocket 342a is rotated by descending, the restraint is released from the support shaft portion 341 and idles in the support shaft portion 341 .

To this end, the first latch sprocket 342b includes a first rotation disk 342e fixedly coupled to the support shaft portion 341 and a plurality of second rotation disks 342e fitted to the first rotation disk 342e on the inner surface along the circumferential direction. The first rotation disk 342e so that the first locking jaw 342g is caught or released from the first body portion 342f and the first body portion 342f in which the first locking jaw 342g is engaged or released according to the rotation direction of the first body portion 342f. and a first rotation latch member 342h rotatably provided to the .

In addition, the second interlocking rotation guide part 343 includes a second interlocking sprocket 343a provided in the rotary shaft part 320 and a second latch sprocket 343b provided in an interlocking rotation or idle rotation to the support shaft part 341 and , when the second guide sprocket 343c and the second interlocking sprocket 343a rotatably provided as a pair on the support 310 are rotatably spaced apart from each other by the lowering of the rotation link member 330, the second guide sprocket 343c The second interlocking sprocket 343a is rotated in the same direction as the rotational direction, and the second latch sprocket 343b is rotated in the opposite direction to the rotational direction of the second interlocking sprocket 343a together with the support shaft portion 341. and a second connecting chain 343d connecting the second interlocking sprocket 343a, the second latch sprocket 343b, and the second guide sprocket 343c.

At this time, the second latch sprocket 343b is constrained to the support shaft portion 341 to rotate together with the support shaft portion 341 when the second interlocking sprocket 343a is rotated due to the descent of the buoyancy body 200, and the buoyancy body 200 ), when the first interlocking sprocket 343a is rotated by descending, the restraint is released from the support shaft portion 341 and idles in the support shaft portion 341 .

To this end, the second latch sprocket 343b includes a second rotation disk 343e fixedly coupled to the support shaft 341 and a plurality of second rotation disks 343e fitted to the second rotation disk 343e on the inner surface along the circumferential direction. The second rotating disk 343e so that the second locking jaw 343g is caught or released by the second locking jaw 343g according to the rotation direction of the second body part 343f and the second body part 343f, which are formed to be inclined. and a second rotational latch member 343h rotatably provided to the .

That is, when the rotation link member 330 is rotated by the rise of the buoyancy body 200 and the first interlocking sprocket 342a and the second interlocking sprocket 343a are rotated in the same direction at the same time, the first latch sprocket 342b is the first The first connecting chain 342d rotates in the same direction as the rotational direction of the first interlocking sprocket 342a together with the support shaft portion 341, and the second latch sprocket 343b is disengaged from the support shaft portion 341. It is rotated in a direction opposite to the rotation direction of the second interlocking sprocket 343a by the second connecting chain 343d. Conversely, when the rotation link member 330 is rotated by the descent of the buoyancy body 200 and the first interlocking sprocket 342a and the second interlocking sprocket 343a are rotated in the same direction at the same time, the second latch sprocket 343b is the first The second interlocking sprocket 343a is rotated in a direction opposite to the rotational direction of the second interlocking sprocket 343a together with the supporting shaft portion 341 by the two connecting chains 343d, and the first latch sprocket 342b is released from interlocking with the supporting shaft portion 341. It is rotated in the same direction as the rotational direction of the first interlocking sprocket 342a by the first connecting chain 342d.

Accordingly, the support shaft portion 341 can always be rotated in one direction regardless of the rotation direction of the rotation link member 330 by the first interlocking rotation guide 342 and the second interlocking rotation guide 343 . .

In addition, the electricity production unit 350 receives the rotational force of the increasing-speed rotating unit 351 and the increasing-speed rotating unit 351 installed on the support 310 so as to be rotated at increased speed by the rotational force of the supporting shaft unit 341 so that the rotational force of the increasing-speed rotating unit 351 can be stored. It includes a flywheel 352 and a generator 353 that generates electricity with the rotational force stored in the flywheel 352 .

At this time, the speed increase rotation unit 351 is a driven sprocket 351a rotated by the rotational force of the supporting shaft portion 341 and a driven sprocket 351b and a driven sprocket 351b provided in the support 310 so as to have a smaller diameter than the driven sprocket 351a. The sprocket 351b includes a transmission chain 351c connecting the driven sprocket 351a and the driven sprocket 351b to receive the rotational force of the driven sprocket 351a.

That is, when the support shaft portion 341 is rotated in one direction, the speed increase rotation unit 351 increases and transmits the rotational force to the flywheel 352, and the flywheel 352 receives and stores the rotational force increased from the increase speed rotation unit 351, The generator 353 can stably produce electricity.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and those of ordinary skill in the art to which various modifications and equivalent other embodiments are possible. will understand

Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

100: support frame 200: buoyancy body
300: conversion power generation unit 310: support
320: rotation shaft portion 330: rotation link member
340: interlocking rotation generating unit 341: support shaft unit
342: first interlocking rotation guide 343: second interlocking rotation guide
350: electricity production unit 351: increased rotation unit
352: flywheel 353: generator

Claims (6)

support frame;
a buoyant body that floats buoyantly in seawater; and
Containing; and a conversion power generation unit for generating electricity by converting the lifting motion of the buoyancy body into a one-way rotational motion when the buoyancy body moves up and down due to a change in the water level of the seawater.
The conversion power generation unit includes a support that is fixedly installed on the upper side of the support frame, a rotation shaft that is rotatably provided on the support, and a rotation shaft that is provided in the rotation shaft, and is connected to the buoyancy body so as to be rotated by the lifting and lowering of the buoyancy body. A link member, an interlocking rotation generating unit that is linked to the rotating link member to generate a one-way rotational force when the rotating link member reciprocates, and an electricity production unit provided on the support to receive the rotational force of the interlocking rotation generating unit to produce electricity. includes,
The interlocking rotation generating unit includes a support shaft rotatably supported by the support, a first interlocking rotation guide for guiding the support shaft to rotate in one direction in association with the rising of the rotation link member, and the support shaft portion is the rotation link Includes a second interlocking rotation guide for guiding to rotate in one direction in conjunction with the lowering of the member,
The first interlocking rotation guide portion includes a first interlocking sprocket provided on the rotation shaft portion, a first latch sprocket provided to be rotatably interlocked or idling on the support shaft portion, and a pair of rotatably provided on the support rotatably spaced apart When the first guide sprocket and the first interlocking sprocket are rotated as the rotation link member is raised, the first guide sprocket is rotated in a direction opposite to the rotation direction of the first interlocking sprocket, and the first latch sprocket is the support shaft portion and a first connecting chain connecting the first interlocking sprocket, the first latch sprocket, and the first guide sprocket to rotate in the same direction as the rotational direction of the first interlocking sprocket. Tide energy converter.
delete delete delete The method of claim 1,
The second interlocking rotation guide unit,
a second interlocking sprocket provided on the rotating shaft;
a second latch sprocket provided to be rotatably interlocked with the support shaft portion or idling;
a second guide sprocket rotatably provided with a pair of spaced apart from the support; and
When the second interlocking sprocket rotates in the downward direction of the rotation link member, the second guide sprocket rotates in the same direction as the rotation direction of the second interlocking sprocket, and the second latch sprocket rotates in the second interlocking direction together with the support shaft portion. a second connecting chain connecting the second interlocking sprocket, the second latch sprocket, and the second guide sprocket to rotate in a direction opposite to the rotation direction of the sprocket;
Tide energy conversion device for tidal power generation, characterized in that it comprises a.
The method of claim 1,
The electricity production unit,
a plurality of speed-increasing rotation units installed on the support so as to be rotated at increased speed by the rotational force of the support shaft;
a flywheel receiving the rotational force of the speed-increasing rotation unit to be stored; and
a generator for generating electricity from the rotational force stored in the flywheel;
Tide energy conversion device for tidal power generation, characterized in that it comprises a.

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