KR101584184B1 - Wave power generating apparatus using breakwater - Google Patents

Abstract

The present invention provides a wave power generation device using a breakwater. The present invention comprises: a first fixer (10) and a second fixer (10a) having a first installation hole (11) and a second installation hole (12) respectively; a moving body support shaft (20) horizontally positioned with respect to a front surface (1a) of a breakwater (1); a gear support shaft (30); a power generation gear (40) having a means to rotate the gear support shaft (30) in one direction; a moving body (50) having a resistant plate (52); a power transmission shaft (60) where a first power transmission gear (61) is provided to an end of an upper portion; a rotational force transmission unit (70) transmitting a rotational force of the gear support shaft (30) to the power transmission shaft (60); and a power generation unit (80) having a second power transmission gear (81).

Description

[0001] WAVE POWER GENERATING APPARATUS USING BREAKWATER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wave power generator using a breakwater, and more particularly, to a wave power generator using a breakwater capable of generating electricity using up-and-down kinetic energy of a wave collected in a breakwater.

Generally, electricity is an essential element in our daily life. Most of it has been produced using fossil energy as a raw material. However, many problems such as depletion of fossil fuels, difficulty in purchasing raw materials, destruction of global environment, There is a need to develop power generation facilities using new alternative energy instead of generating power using fossil energy.

As a result, countries around the world are investing heavily in the development of power generation facilities using alternative energy sources. Indeed, countries and regions that produce electricity using a variety of energy sources such as solar heat, wind power, and tidal power In recent years, domestic power generation facilities using wind and tidal power have been installed in various places to produce a certain amount of electricity.

Particularly, tidal power generation that uses electricity of tidal river only, tidal power generation that uses electricity at high velocity of seawater, and wave power that uses electricity of waves to attract electricity are attracting attention. It is a technology to produce electric energy by using the waves of the waves which are generated continuously, so it is advantageous in that the most stable energy can be obtained.

In addition, since the ocean is composed of three sides and the ocean is abundant and the waves are generated continuously, it is easy to obtain the wave by the waves, so that the development of the power generation device using the wave which is easy to install and less in installation cost is urgently required It is a fact that it is demanded.

On the other hand, a breakwater is an external facility to protect a port facility or a ship from the waves of an outer sea. It is a structure that is installed on a coastal area in order to block the flow of sea water, It is installed for the safety of the ship or the coast from the wave energy of the ocean and is designed and constructed so as to artificially block the energy going to the coast of the wave and to be exhausted from the breakwater.

When the wave crashes against the breakwater, the direction of the kinetic energy is changed to the up and down direction, and the flow of the seawater moves in the up and down direction.

Accordingly, there is an urgent need for an electric power generating apparatus using a wave generated when a force that is collected when a wave hits against a breakwater, that is, a wave is shifted up and down, and a flow of seawater moves in a vertical direction, A wave breaker for generating power by using a breakwater as a facility has been disclosed.

As a conventional art, a wave breaker for wave power generation is disclosed in Japanese Patent No. 10-1260037, which comprises a breakwater body, a horizontal flow channel having a rectangular cross section formed inside the breakwater body at an inlet formed at one side of the breakwater body, A transverse flow turbine section connected to the horizontal flow passage and connected to an upper surface of the breakwater body, a transverse flow turbine section installed in the horizontal flow passage and rotated in one direction by seawater introduced into the horizontal flow passage, And a wells turbine section rotated by seawater vibrated up and down in the order receiving section.

Such a conventional technique allows the wave energy to be efficiently converted into electrical energy by using the crossflow turbine and the wells turbine portion using vibration order.

However, in the conventional art, since the transverse flow turbine is provided inside the breakwater body and the flow path and vibration order connected to the transverse turbine portion and the wells turbine portion are provided, it is difficult to proceed with the wave generation using the existing breakwater .

That is, in order to apply the prior art, a breakwater having a transverse flow turbine section, a flow path, a vibration order and a well turbine section should be newly manufactured, and a breakwater newly installed should be installed after removing the existing breakwater installed in the port There is an economically inefficient problem.

Furthermore, there is a problem that the installation cost is increased due to the installation cost and the manufacturing cost.

Korean Registered Patent No. 10-1260037 (Registered on April 25, 2013) Korean Registered Patent No. 10-1296859 (Registered on Aug. 20, 2013)

The present invention minimizes the burden on the installation cost and greatly improves the workability and installability by using power of the up-down kinetic energy generated when the wave crashes against the breakwater while using the existing breakwater as it is. There is provided a wave power generator using a breakwater.

In order to achieve the above object, the wave power generator using the breakwater of the present invention is provided with a first constriction hole and a second constriction hole which are fixed on the front surface of a breakwater to which seawater is touched, A first fixture and a second fixture; A moving support shaft which is fitted in a first axis hole corresponding to the first fixing member and the second fixing member which are positioned so as to face each other in a horizontal direction on the front surface of the breakwater and are positioned horizontally with respect to the front surface of the breakwater; A gear support shaft fitted in a second axis hole corresponding to the first fixture and the second fixture, which are positioned so as to face each other in the horizontal direction of the front surface of the breakwater, and are positioned horizontally with respect to the front surface of the breakwater; A power generating gear provided on the gear support shaft and having a bi-directional gear portion on an outer surface thereof and means for rotating the gear support shaft in one direction; And a means for rotating the power generation gear in one direction by flowing upward and downward due to up-and-down kinetic energy of a wave impinging on the breakwater; A power transmission shaft having a first power transmission gear located at a side end of one of side portions of the gear support shaft and positioned in a direction orthogonal to the gear support shaft and having a first power transmission gear at an upper end thereof; A rotational force transmitting portion for transmitting a rotational force of the gear support shaft to the power transmission shaft; And a second power transmission gear meshed with the first power transmission gear of the power transmission shaft so that the rotational force of the power transmission shaft is transmitted by the first power transmission gear and the second power transmission gear meshed with the first power transmission gear And a power generating unit for generating and generating electric power.

Further, the moving body includes: a resistance cardboard earth which is installed on the moving body supporting shaft; A resistive plate extending from one side of the resistance cardboard strip and flowing upward and downward by a vertical kinetic energy of a wave impinging on a front surface of the breakwater; A rotary shaft extending from the other side of the resistance cardboard strip and being rotatable in a downward direction when the resistance plate is rotated upward and the upward direction when the resistance plate is rotated downward; Wherein the power generating gear is rotatable in the up and down direction by rotating the power generating gear in the first and second direction A gear portion and a second unidirectional gear portion.

Further, the rotational force transmitting portion may include: a first bevel gear provided at one of the side ends of the opposite side portions of the gear support shaft; And a second bevel gear which is fitted to the power transmission shaft and meshed with the first bevel gear in a direction perpendicular to the first bevel gear.

Furthermore, a cover for covering the first fixing member, the second fixing member, the moving body supporting shaft, the gear supporting shaft, and the power generating gear is installed on the front surface of the breakwater, and the resistance plate of the moving body is exposed to the cover, And a stopper groove portion interfering with the upper and lower flow ranges.

The present invention can provide a power generating device at the front of a breakwater installed in the harbor, so that the existing breakwater can be utilized as it is and economical effect can be obtained, and electricity can be obtained by using the wave generated when a wave hits a breakwater. It is possible to produce electricity and it can transfer power to the power generation part by using up and down kinetic energy of the wave that moves depending on the waves hitting against the breakwaters so that the power generation efficiency can be improved. It is possible to minimize the cost burden.

1 is a perspective view showing a wave power generator using a breakwater according to the present invention.
2 is an exploded perspective view showing a configuration of a wave power generator using a breakwater according to the present invention.
3 is a perspective view showing an example in which a wave power generator using a breakwater according to the present invention is installed in a breakwater.
4 is a perspective view showing another embodiment of the wave power generator using the breakwater of the present invention.
5 is a configuration diagram showing the configuration of a wave power generator using a breakwater according to the present invention.
6 is a block diagram showing the operation state of the wave power generator using the breakwater of the present invention.
7 is a block diagram showing another embodiment of the wave power generator using the breakwater of the present invention.
8 is a perspective view showing still another embodiment of the wave power generator using the breakwater of the present invention.

Hereinafter, other objects and features of the present invention will be apparent from the following description of embodiments with reference to the accompanying drawings.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

Hereinafter, a wave generator using a breakwater according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

As shown in the figure, the wave power generator using the breakwater according to the present invention includes a first fixture 10 and a second fixture 10a, a movement support shaft 20, a gear support shaft 30, a power generation gear 40, (50), a power transmitting shaft (60), a torque transmitting portion (70), and a power generating portion (80).

In the present invention as described above, the moving body 50, which is supported on the moving body supporting shaft 20 horizontally supported on the first and second anchors 10 and 10a, The power generating gear 40 is rotated in one direction and the rotating force of the power generating gear 40 in one direction is transmitted to the power transmitting shaft 60. [ And the rotational force transmission unit 70 to the power generation unit 80 to generate electric power.

Accordingly, it is possible to produce environmentally friendly electricity by installing the wave power generator of the present invention without replacing the breakwater installed in the existing port, thereby minimizing cost and installation cost.

The first fixture 10 and the second fixture 10a of the present invention are fixed to the front surface 1a of the breakwater 1 to which the seawater is contacted and are positioned and fixed so as to face each other horizontally, 11 and a second axis lug 12 are respectively provided.

The method of fixing the first fixture 10 and the second fixture 10a to the front surface 1a of the breakwater 1 can be firmly fixed using anchor bolts and anchor nuts, It goes without saying that the first fixing member 10 and the second fixing member 10a may be fixed to the front surface 1a of the breakwater 1.

Of course, when a breakwater is newly manufactured, it is of course possible to fix the first fixture 10 and the second fixture 10a to the front surface of a newly manufactured breakwater.

The moving body supporting shaft 20 of the present invention includes a first axis hole 11 and a second axis hole 11 which correspond to the first and second anchors 10 and 10a positioned to face each other on the horizontal surface of the breakwater front surface 1a, And are positioned in the horizontal direction with respect to the front surface 1a of the breakwater 1.

The first fixing holes 10 and the first fixing holes 10a of the first fixing hole 10 and the second fixing holes 10a are aligned on the same horizontal line so as to correspond to the first fixing hole 10 and the second fixing hole 10a, The first support shaft 20 is inserted into the first shaft hole 11 so as to allow the support shaft 20 to rotate about the first shaft hole 11 easily.

The gear support shaft 30 of the present invention is provided with a first shaft 10 and a second shaft 10a which are positioned so as to face each other on the horizontal plane of the front surface 1a of the breakwater 1, (12) and positioned horizontally with respect to the front surface (1a) of the breakwater (1).

At this time, the second axle holes 12 provided in the first fixing hole 10 and the second fixing hole 10a are positioned on the same horizontal line with respect to each other, The gear support shaft 30 is inserted into the second shaft lug 12 which is communicated with the second fixture 10a so as to facilitate rotation of the gear support shaft 30 relative to the second shaft lug 12 .

Of course, in some cases, there may be a first shaft lug 11 in which the moving body supporting shaft 20 and the driving body supporting shaft 20 are fitted, and a second shaft driving hole 11 in which the gear supporting shaft 30 and the gear supporting shaft 30 are fitted The second shaft lug 12 may be provided with a separate means for smoothly performing the rotational motion such as a bearing or a bushing.

The power generation gear 40 of the present invention is configured to rotate on the gear support shaft 30 and the gear support shaft 30 in one direction with a bi-directional gear portion 41 on the outer surface.

In addition, the moving body 50 of the present invention rotates the power generation gear 40 in one direction by flowing in the vertical direction by the up-down kinetic energy of a wave which is spread on the moving body support shaft 20 and impinges on the breakwater. And a resistance plate 52 provided with a means for applying a magnetic field.

In this case, the moving body 50 of the present invention includes a resistance cardboard earth 51 that is installed on the moving body support shaft 20, and a front surface of the resistance waveguide strip 51 extending from one side of the resistance cardboard earth 51 A resistance plate (52) which flows upward and downward due to the upward and downward kinetic energy of a wave impinging on the resistance plate (1a), and a resistance plate (52) extending from the other side of the resistance cardboard (51) (53) which is rotated downward when the rotor (52) is rotated upward and upwardly when the rotor (52) is rotated downward, a rotor Symmetrical to each other on the other side so as to be engaged with the bi-directional gear portion 41 of the power generation gear 40 and the rotation tool 53 is rotated in the up and down direction movement direction, The first unidirectional gear portion 54 and the second unidirectional gear portion 55, which rotate the first unidirectional gear portion 54 and the second unidirectional gear portion 55, It can be done.

The resistance plate 52 is installed below the water surface in order to minimize the wave power of the crane, ensuring safety, and has a limit point of a vertical swing angle of the resistance plate 52 to prevent superheat generation, thereby inducing efficient energy production desirable.

The reason why the resistance plate 52 can flow (swing) in the up-and-down direction when the wave hits the breakwaters is that the wave becomes larger as the energy in the left and right traveling direction approaches the breakwater This is because the breakwater blocks the flow energy of the waves, and the energy of the left and right waves in the wave direction is converted into the energy of the upper and lower sides in the breakwater. Therefore, when the wave hits the breakwater, And flows vertically.

As shown in the figure, the rotation hole 53 is formed in a hollow shape so as to block the periphery of the rotation hole 53, thereby interfering with the rotation radius of the rotation hole 53, May be appropriately and selectively applied according to the wave environment.

The moving body 50 of the present invention is constructed so that the resistance plate 52 of the moving body 50 is moved upward and downward by the up and down kinetic energy of the wave acting on the front surface 1a of the breakwater 1, When the resistance plate 52 is moved upward and downward as described above, the resistance cardboard strip 51 connected to the resistance plate 52 is connected to the resistance plate 52 in the same direction as the resistance plate 52 (Rotates).

When the resistance cardboard strip 51 is rotated in the same direction as the flow direction of the resistance plate 52, the rotary ball 53 connected to the resistance cardboard strip 51 is rotated. At this time, 53 are rotated downward when the resistance plate 52 is rotated upward and upwardly when the resistance plate 52 is rotated downward.

The first unidirectional gear portion 54 and the second unidirectional gear portion 54, which are provided symmetrically on one side and the other side of the inner surface of the rotary tool 53 when the rotary tool 53 is rotated in the upward and downward directions, The first unidirectional gear portion 54 and the second unidirectional gear portion 55 are rotated by rotating the first unidirectional gear portion 54 and the second unidirectional gear portion 55. [ 55 are engaged with the bi-directional gear portion 41, the power generation gear 40 is rotated in one direction.

When the power generation gear 40 is rotated in one direction, the power generation gear 40 is rotated and the fixed gear support shaft 30 is rotated in one direction in accordance with the rotation direction of the power generation gear 40.

The power transmission shaft 60 of the present invention is disposed at a side end of one of the opposite side portions of the gear support shaft 30 and is positioned in a direction orthogonal to the gear support shaft 30, And a power transmission gear 61.

The rotational force transmitting portion 70 of the present invention transmits the rotational force of the gear support shaft 30 to the power transmission shaft 60. At this time, A first bevel gear 71 provided at one side end of one side of the first bevel gear 30 and a second bevel gear 71 fixed to the power transmission shaft 60 and meshed with the first bevel gear 71 in a direction perpendicular to the first bevel gear 71; And a second bevel gear 72 may be provided.

Accordingly, when the gear support shaft 30 is rotated by the rotation of the power generation gear 40, the rotational force of the gear support shaft 30 is transmitted to the power transmission shaft 60 by the torque transmission portion 70 And the power transmission shaft 60 is rotated.

That is, when the gear support shaft 30 is rotated, the first bevel gear 71 is rotated and the second bevel gear 72 is rotated by the rotation of the first bevel gear 71, The power transmitting shaft 60 into which the armature 72 is fitted is rotated.

Since the first bevel gear 71 is positioned at a horizontal position and the second bevel gear 72 is positioned at a vertical position perpendicular to the first bevel gear 71, The rotational force of the support shaft 30 is transmitted to the power transmission shaft 60 positioned vertically with respect to the gear support shaft 30 so that the power transmission shaft 60 is rotated vertically.

The power generating unit 80 of the present invention is provided with the second power transmission gear 81 that is engaged with the first power transmission gear 61 of the power transmission shaft 60, And is transmitted by the first power transmission gear 61 and the second power transmission gear 81 engaged with the first power transmission gear 61 to generate electric power.

In this case, the power generator 80 may further include a transmission (not shown) for reducing or increasing the rotational speed.

The rotational force of the gear support shaft (30) is transmitted by the rotational force transmitting portion (70) to the power transmitting portion (80) When the shaft 60 rotates, the first power transmission gear 61 provided at the upper end of the power transmission shaft 60 rotates and is engaged with the first power transmission gear 61 in a direction perpendicular to the first power transmission gear 61 The electric power of the power generation unit 80 is generated by the rotational force transmitted to the second power transmission gear 81.

The generation of electric power by the power generation unit 80 in the present invention is not so different from a known generator that generates electric power using rotational power, and a detailed description thereof will be omitted.

The resistance plate 52 of the moving body 50 of the present invention and the resistance cardboard strip 51 extending one side are extended from the resistance plate 52 and the power generation gear 40 is disposed inside The rotating member 53 of the moving body 50 may be provided on the other side of the plurality of resistance cardboard strips 51 extending from the plurality of the resistance cardboard strips 51.

That is, as shown in the figure, one or more resistance cardboard strips 51 and rotating balls 53 extending from the resistance plate 52 are provided in one or more of the moving support shaft 20 and the gear support shaft 30 The rotational force for the same area can be increased.

A plurality of motive bodies 50 of the present invention may be provided on the plurality of the motive body support shafts 20 and the gear support shafts 30 in a horizontal plane. A plurality of first fixtures 10 and second fixtures 10a which are fitted and fixed to the support shaft 30 at equal intervals and a plurality of first fixtures 10 and second fixtures 10a And a plurality of the moving bodies 50 may be provided.

The first fixture 10, the second fixture 10a, the moving body support shaft 20, the gear support shaft 30, and the power generation gear 40 are covered on the front surface 1a of the breakwater 1 of the present invention The cover 90 is further provided with a stopper groove portion 91 for exposing the resistance plate 52 of the moving body 50 and interfering with the upper and lower flow ranges of the resistance plate 52, As shown in FIG.

The cover 90 is further provided to cover the first fixing member 10, the second fixing member 10a, the moving body supporting shaft 20, the gear supporting shaft 30 and the power generating gear 40, The operation of the first fixing member 10, the second fixing member 10a, the moving body supporting shaft 20, the gear supporting shaft 30 and the power generating gear 40 due to the foreign matter can be prevented from being interfered with At this time, the shape of the cover 90 may be variously changed in addition to the semicircular shape as shown in the figure.

7, the same operation and effect can be obtained even when the moving body 50 is positioned vertically with respect to the moving body supporting shaft 20 and the gear supporting shaft 30, Such as the shape of the harbor or coastal environment and the type of waves to be installed, depending on the installation site.

As shown in the drawings, the present invention may include a plurality of the moving bodies 50 with respect to the moving body supporting shaft 20 and the gear supporting shaft 30, Since the plurality of moving bodies 50 are provided on the gear support shaft 30 of the first and second gears, the rotational force for the same area or the same space can be increased.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention

1: Breakwater 1a: Breakwater front
10: first fixture 10a: second fixture
11: 1st axis lug 12: 2nd axis lug
20: a moving body supporting shaft 30: a gear supporting shaft
40: power generation gear 41: bi-
50: Movement 51: Resistance Carton Zone
52: Resistance plate 53: Rotor
54: first directional gear portion 55: second unidirectional gear portion
60: Power transmission shaft 61: First power transmission gear
70: rotational force transmitting portion 71: first bevel gear
72: second bevel gear 80:
81: second power transmission gear 90: cover
91: Stopper groove

Claims (6)

A first fixture (1) fixed to the front surface (1a) of the breakwater (1) to which the seawater is touched and fixed and positioned so as to be opposed to each other in a horizontal plane and having a first axis hole (11) and a second axis hole 10 and a second fixture 10a;
The first fixing hole 10a and the second fixing hole 10a are located on the horizontal surface of the breakwater front surface 1a and are respectively fitted to the first axis holes 11 corresponding to the first fixing hole 10 and the second fixing hole 10a, A moving body support shaft 20 positioned in a horizontal direction with respect to the vehicle body 1 a;
The first fixing hole 10 and the second fixing hole 10a are positioned on the horizontal surface of the front surface 1a of the breakwater 1 so as to face each other, A gear support shaft 30 positioned in a horizontal direction with respect to a front surface 1a of the motorcycle 1;
A power generating gear (40) provided on the gear support shaft (30) and having a bi-directional gear portion (41) on the outer surface thereof and means for rotating the gear support shaft (30) in one direction;
A resistance plate 52 having means for rotating the power generation gear 40 in one direction by flowing vertically in the up and down direction due to the up-down kinetic energy of a wave which is formed on the motive body support shaft 20 and impinges on the breakwater, A moving body (50) provided;
And a power transmission shaft having a first power transmission gear (61) located at an upper end of the gear support shaft (30) and positioned at a side end of one of the opposite side portions of the gear support shaft (60);
A torque transmitting portion 70 for transmitting the rotational force of the gear support shaft 30 to the power transmission shaft 60;
And a second power transmission gear 81 meshing with the first power transmission gear 61 of the power transmission shaft 60 so that the rotational force of the power transmission shaft 60 is transmitted to the first power transmission gear 61 And a power generation unit (80) which is transmitted by a second power transmission gear (81) meshed with the first power transmission gear (61) and generates electric power by generating electricity.
The method according to claim 1,
The moving body (50)
A resistance cardboard strip (51) shrouded in the movement support shaft (20);
A resistance plate (52) extending from one side of the resistance cardboard (51) and flowing in the vertical direction by the up and down kinetic energy of a wave impinging on the front surface (1a) of the breakwater (1);
The power generation gear 40 is extended from the other side of the resistance cardboard region 51 and is rotated in the downward direction when the resistance plate 52 is rotated upward and the resistance plate 52 is moved downward A rotating shaft 53 which is rotated upwardly when the rotating shaft 53 is rotated;
And are symmetrically provided on one side and the other side of the inner surface of the rotary shaft 53 so as to be engaged with the bidirectional gear portion 41 of the electric power generator gear 40 and the rotary shaft 53 is rotated in the vertical direction And a first unidirectional gear portion (54) and a second unidirectional gear portion (55) for rotating the power generation gear (40) in one direction.
3. The method of claim 2,
The resistance plate 52 of the moving body 50 and the resistance cardboard strip 51,
A plurality of protrusions extending from the resistance plate 52,
The rotating gear 53 of the moving body 50 in which the power generation gear 40 is located is provided on the other side of the plurality of resistance cardboard strips 51, Wave power generator using a breakwater.
The method according to claim 1,
The rotational force transmitting portion (70)
A first bevel gear 71 provided at one of side ends of the gear support shaft 30;
And a second bevel gear (72) fitted in the power transmission shaft (60) and meshing with the first bevel gear (71) in a direction orthogonal to the first bevel gear (71).
The method according to claim 1,
The front surface 1a of the breakwater 1 is provided with a cover for covering the first fixing member 10, the second fixing member 10a, the moving body supporting shaft 20, the gear supporting shaft 30, (90) is further provided,
Wherein the cover (90) further comprises a stopper groove portion (91) that exposes the resistance plate (52) of the moving body (50) and interferes with the upper and lower flow ranges of the resistance plate (52) Wave power generator using.
The method according to claim 1,
The moving body (50)
And a plurality of gears are provided along the longitudinal direction of the moving body supporting shaft (20) and the gear supporting shaft (30) with respect to the moving body supporting shaft (20) and the gear supporting shaft (30) .

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