KR101089421B1 - Wave power generation system - Google Patents

Abstract

The present invention is to provide a wave power generator having a structure that is easy to operate even at low crest with low energy loss due to friction. The present invention is a floating body that accommodates seawater therein, a support shaft fixed to the inside of the fuselage, a weight link provided on the support shaft to pivot freely about the support shaft, and the weight In the weight generating device, a buoyant body floating the weight link provided in the weight link in the sea water, a rotation generating device for generating a rotational force according to the turning of the weight link, and in the rotation generating device It provides a wave power generator comprising a generator that receives the rotational force to the power generation shaft.

Description

Wave power generation system

The present invention relates to a wave power generation apparatus, and more particularly, to a wave power generation apparatus of a method of generating by changing the movement of the buoyancy body and weight to the rotational force by using the sea water inside the flow by the wave or the shoulder.

Wave power generation is a method of obtaining electrical energy by converting the kinetic energy of water particles caused by waves into mechanical rotational or axial motion using an energy converter, and has been the subject of much interest and research as a future energy source.

1 illustrates an example of a conventional wave power generator, which is a wave power generator that operates by a wave while floating on the sea. The wave power generator is a power generator called Pelamis, and a plurality of tubes 10 are connected to each other, and a hydraulic pump is attached to the nodes 20 between the tubes.

The wave power generator is a bending occurs in the neighboring tubes (10) by the movement of the wave, the neighboring tube (10) is folded and unfolded repeatedly. Accordingly, the generator is operated by pushing and pulling the piston of the hydraulic pump installed in the node 20.

However, the conventional wave power generator as described above needs to operate the piston, so a large force is required for starting. Therefore, there is a problem that maneuvering is difficult unless waves of a predetermined size or more do not work. In addition, the wave power generator has a problem that the power generation efficiency is low because the internal structure is not only complicated, but also the energy loss for driving the piston is large.

The present invention has been made to solve the above problems, an object of the present invention is to provide a wave power generation apparatus of a structure that is easy to operate even at low crest with low energy loss due to friction.

The present invention for achieving the above object is a floating body that is accommodated in the sea water (내부 體), the support shaft is installed in the interior of the body, and is installed on the support shaft to pivot freely around the support shaft A weight generating link, a weight installed on the weight link, a buoyancy body floating the weight link provided in the weight link in the seawater, and a rotation generator for generating a rotational force according to the turning of the weight link. And, it provides a wave power generator comprising a generator for receiving the rotational force generated in the rotation generating device to the power generation shaft.

The rotation generating device is coupled to the weight link is connected to the weight link is moved when the pivot around the support shaft, the rack belt installed on the connecting line, and the rack belt is rotated when the connection line moves in contact with And a gear, wherein the rotational force is a rotational force generated by the gear.

More specifically, the weight link is respectively installed on both sides of the support shaft, the weight and the buoyancy body is installed on each of the weight link, the connecting line is provided in each of the weight link is coupled separately, Each of the connecting wires is connected to both sides of the rack belt, the rack belt is formed by splitting into two strands, the gears are installed on the power generation shaft two are installed so as to bite each of the two belt rack belt, And the power generating shaft are each coupled through a one-way bearing for rotating the power generating shaft in the same one direction.

On the other hand, in another aspect of the present invention, the rotation generating device, the rack gear is pivoted about the support shaft in conjunction with the weight link and a fan shape around the support shaft and the rack gear bite the rack gear It includes a gear that is rotated when the turning of, the rotational force may be configured to be a rotational force generated in the gear.

More specifically, the weight link is respectively installed on both sides of the support shaft, the weight and the buoyancy body is installed on each of the weight link, the rack gear is each of the weight link is installed on the support shaft Separately provided and coupled to the portion, the gear and the power generating shaft is characterized in that each is coupled via a one-way bearing for rotating the power generating shaft in the same one direction only.

On the other hand, it is preferable that a seawater inlet is further provided at a predetermined height on the side of the fuselage to allow access of seawater.

In addition, the lower portion of the fuselage is preferably further provided with a horizontal maintenance so that the horizontal can be maintained only in the direction of the support shaft.

The present invention having the configuration as described above has the following effects.

First, the present invention has a simple overall structure and low energy loss such as friction in the process of converting wave energy into electrical energy. In addition, since it is easy to start even if manufactured in a small size, it can be implemented in a small power generation device.

Secondly, the wave power generator of the present invention can be used even in an environment where the wave height is not high because the power generation is possible only by the inclination caused by the waves. In addition, even if a wave with a very short wavelength can be generated because it can generate a slope to the body due to the irregular waves.

Third, since the present invention is a structure in which the generator, the rotation generator, and the like are protected by the fuselage, damage to the generator is prevented from the influence of floating objects floating in the sea or the external environment.

Fourth, since the wave power generation device of the present invention is configured in a small capacity type and is suitable for connecting a plurality of power generation units, it is easy to construct a power generation complex and to easily add or subtract the overall power generation capacity of the power generation complex.

1 is an operation explanatory diagram of a conventional wave power generator
Figure 2 is a perspective view of the inside of the wave power generating apparatus according to an embodiment of the present invention
3 is a cross-sectional view taken along the line XX 'of FIG.
4 is a cross-sectional view taken along the line YY ′ of FIG. 2.
5 is an enlarged view of the rotation generator 400 of the wave power generator according to an embodiment of the present invention.
Figure 6 (a) (b) is an explanatory diagram illustrating the operation of the wave power generator according to the present invention
7 is an explanatory diagram illustrating the operation of the wave power generator according to an embodiment of the present invention in the state of FIG.
8 is an explanatory diagram for explaining the operation of the wave power generator according to an embodiment of the present invention in the state of FIG.
Figure 9 is a perspective view of the inside of the wave power generating apparatus according to another embodiment of the present invention
10 is an enlarged view of a rotation generator 400 ′ of a wave power generator according to another embodiment of the present invention.
FIG. 11 is an explanatory view for explaining the operation of the wave power generator according to another embodiment of the present invention in the state of FIG.
12 is an explanatory diagram for explaining the operation of the wave power generator according to another embodiment of the present invention in the state of FIG.
13 is a state diagram of a wave power generation complex by arranging a plurality of wave power generation devices of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings.

2 is a perspective view showing the inside of the wave power generator according to an embodiment of the present invention, Figure 3 is a sectional view in the XX 'direction of Figure 2, Figure 4 is a sectional view in the YY' direction of FIG. .

2 to 4, the wave power generator of the present invention includes a box-shaped floating body 100 in which seawater is accommodated therein, and a support shaft fixed to the body 100. 200, weight weight links 301 and 302 provided on the support shaft 200 so as to pivot freely about the support shaft 200, weight weight 320 installed on the weight links 301 and 302, The buoyancy body 340 for floating the weight link (301,302) is installed in the weight of the weight 320 is installed, and the rotation generator 400 for generating a rotational force in accordance with the turning of the weight link (301,302) And, the generator 500, which receives the rotational force from the rotation generating device 400 to the power generation shaft 520.

The floating body 100 is manufactured in a box shape and an empty space is formed therein so that seawater can be accommodated therein, and the generator 500, the weight link 301, 302, the rotation generator 400, etc. Is installed. In addition, the fuselage 100 is provided with floating means so that it can be floated at sea. The floating means may include a light material such as styrofoam, but in this embodiment, the air tanks 151 and 152 are formed on both sides of the body 100.

Seawater inlet 120 is installed on both sides of the body (100). The seawater inlet 120 is installed at a predetermined height from the bottom of the fuselage 100 near the center of the fuselage 100 so that a small amount of seawater can enter and exit from time to time to maintain the seawater inside the fuselage 100 at a predetermined height. Can be. That is, up to the height at which the seawater inlet 120 is installed, seawater may be accommodated in the fuselage 100. Due to the movement of the fuselage 100, the internal seawater may leak, but the fuselage 100 of the present invention receives irregular waves continuously from the sea, and the seawater is replenished from time to time through the seawater inlet 120. Therefore, the interior of the body 100 can maintain a state in which a predetermined amount or more of seawater.

The support shaft 200 is supported and fixed by the left and right walls at the central portion of the body 100. The support shaft 200 forms a central axis to which the weight link (301,302) to be described later turns.

The weight link (301,302) is installed on the support shaft 200 is configured to be free to pivot around the support shaft (200). Weight linker (301, 302) may be configured to be installed only on one side around the support shaft 200, it is installed on both sides of the support shaft 200 as in the operation of the present invention to be described later any Even if tilted toward the side, it is more desirable because it is possible to generate electricity.

In addition, it is preferable that both weight links 301 and 302 are not linked to each other and move at the same angle, and are independently configured to pivot freely about the support shaft 200.

The weight 320 is installed at the free ends of the weight link (301,302), it is formed of a metal or ceramic. The weight 320 serves to pivot the weight links 301 and 302 around the support shaft 200 by descending by gravity.

The buoyancy body 340 is installed at the free end of the weight link (301,302) together with the weight (320). The buoyancy body 340 receives the buoyancy from the sea water 600 accommodated inside the fuselage 100 despite the weight of the weight 320 to maintain a floating state on the sea surface. That is, when the sea water is increased by the buoyancy body 340, the free ends of the weight links 301 and 302 are high, and when the sea water is low, the free ends of the weight links 301 and 302 may be lowered by the weight 320.

The rotation generating device 400 is connected to the free ends of the weight link (301,302) of both sides, the connection line 441,442, rack belts (415,425) connecting both connecting lines (441,442), and the rack belt (415,425) Rotating gears 410 and 420 and one-way bearings 414 connecting the gears 410 and 420 to the power generation shaft 520.

One end of each of the connecting lines 441 and 442 is provided at the free ends of the weight links 301 and 302, and the other end is provided at both ends of the rack belts 415 and 425, respectively. The connecting lines 441 and 442 are flexible joint means such as a rope, a cable or a belt, and are supported by the pulleys 443 and 444 to change directions.

The rack belts 415 and 425 have teeth formed so as to be rotated by the gears 410 and 420, and both ends thereof are coupled to both connecting lines 441 and 442, respectively, and are moved to the left and right by pulling the connecting lines 441 and 442. The rack belts 415 and 425 are composed of two strands in this embodiment, and the two strands are gathered at both ends thereof and are coupled to both connecting lines 441 and 442, respectively.

5 shows an enlarged view of the rotation generator 400 of this embodiment.

Referring to FIG. 5, two gears 410 and 420 are installed and both are coupled to the power generation shaft 520 of the generator 500. The gears 410 and 420 are coupled to the two rackbelts 415 and 425, respectively, to generate rotational force as the rack belts 415 and 425 move left and right. As shown in FIG. 5, one strand of the rack belt 425 is coupled to an upper portion of one gear 420, and the other strand of the rack belt 415 is coupled to a lower portion of the other gear 410. Both gears 410 and 420 and the power generating shaft 520 are coupled to each other via a one-way bearing 414. The one-way bearing 414 rotates the power generating shaft 520 only in one and the same direction, and does not transmit the rotational force in the opposite direction.

The generator 500 receives power of the power generating shaft 520 connected to the gears 410 and 420 to generate power through a speed increaser (not shown) installed therein. Since the rotation force generated by the rotation generating device 400 of the present invention is a deviation occurs, it is also possible to install a flywheel (not shown) on the power generation shaft 520 in order to make the rotation even.

Reference numerals 412 and 422 denote guide rollers for stably contacting the rack belts 415 and 425 to the gears 410 and 420, and reference numeral 430 denotes shaft support pieces that support shafts of the power generating shaft 520 and the guide rollers 412 and 422.

On the other hand, in the wave power generator of the present embodiment, it is preferable that the horizontal holding weight 140 is further installed to prevent the body 100 from being inclined laterally, that is, in the direction of the support shaft 200. The horizontal maintenance weight 140 allows tilting in the longitudinal direction of the fuselage 100, but not tilting in the lateral direction so that the fuselage 100 is always horizontal only in the lateral direction. Accordingly, the seawater inside the fuselage 100 may be excessively prevented from leaking or the fuselage 100 may be overturned, and the rotation generator 400 and the weight weight links 301 and 302 may operate in a highly efficient horizontal state. .

In addition, by adjusting the weight of the horizontal maintenance weight 140, it is preferable to configure the body 100 to be submerged in water about half.

The following describes the operation of the wave power generator according to an embodiment of the present invention.

 As shown in Figure 6, the wave power generator according to an embodiment of the present invention is inclined as shown in Fig. 6 (a) or (b) in the inclined surface, such as wind wave or shoulder. As shown in Fig. 6 (a) or (b), the inclined state of the fuselage 100 is alternately generated each time a wind wave or a swell passes.

FIG. 7 illustrates the operation of the wave power generator according to the present embodiment in a state where the inclination of the body 100 to the left occurs as shown in FIG. 6 (a).

In such a case, when the seawater 600 inside the fuselage 100 is horizontal, the left side becomes higher and the right side becomes lower when viewed based on the fuselage 100. Accordingly, the weight link 301 of the left side is raised by the buoyancy body 340, the weight link 302 of the right side is lowered by the weight 320 occurs. As a result, since the right side connecting line 442 pulls the rack belts 415 and 425, the two strands of rack belts 415 and 425 move to the right and rotate the gears 410 and 420 coupled thereto. At this time, one side of the rack belt 425 is coupled to the upper gear 420 and the other side of the rack belt 415 is coupled to the lower gear 410 is rotated in the opposite direction from each other, The power generation shaft 520 coupled thereto receives only the rotational force of the one-side gear 420 by the one-way bearing 414 such that the power generation shaft 520 rotates in one direction.

FIG. 8 shows the operation of the wave power generator of this embodiment in the state where the inclination as shown in FIG. 6 (b) occurs.

In this case, the fuselage 100 is inclined to the right side, so that the seawater 600 accommodated inside the fuselage 100 is horizontal, based on the fuselage 100, the right side is higher and the left side is lower. Accordingly, the weight link 302 on the right side is raised by the buoyancy body 340, and the weight link 301 on the left side is lowered by the weight 320. As a result, since the left connection line 441 pulls the rack belts 415 and 425, the two strands of rack belts 415 and 425 move to the left to rotate the gears 410 and 420 coupled thereto. At this time, as in the operation of the enlarged view of FIG. 8, one gear 420 having one strand of the rack belt 425 coupled to the upper portion and the other gear having the other portion of the rack belt 415 coupled to the lower portion thereof. 410 rotates in opposite directions, but the power generation shaft 520 coupled thereto receives only the rotational force of the other gear 410 by the one-way bearing 414 such that the power generation shaft 520 is described above with reference to FIG. 7. Rotate in the same direction as

As a result, the power generation shaft 520 may rotate in the same direction no matter which way the body 100 is inclined.

The following describes the configuration of a wave power generator according to another embodiment of the present invention.

9 is a perspective view showing the inside of a wave power generator according to another embodiment of the present invention, Figure 10 is an enlarged view of the rotation generating device 400 'of the wave power generator according to another embodiment of the present invention.

9 and 10, the rotation generating device 400 ′ according to another embodiment of the present invention includes gears in which rack gears 455 and 465 interlocked with the weight weight links 301 and 302 interlock with the power generation shaft 520. 410 and 420 are being driven.

The rack gears 455 and 465 of the present embodiment are fixed to the shaft coupling parts 303 and 304 installed on the support shaft 200 so that the weight links 301 and 302 pivot about the support shaft 200. The rack gears 455 and 465 are also configured to pivot about the support shaft 200 at the same angle. In addition, the rack gear 455 fixed to one weight link 301 is in contact with the upper portion of the gear 420 on one side to rotate the gear 420 on one side, to the weight link 302 on the other The fixed rack gear 465 rotates the gear 410 in contact with the lower portion of the gear 410 on the other side.

The gears 410 and 420 of the one side and the other side are coupled via the gear shaft 470 and the one-way bearing 414, respectively, to rotate the gear shaft 470 in one direction as in the above-described embodiment. The gear shaft 470 and the power generating shaft 520 are connected so that rotational force is transmitted by the power transmission means 475 such as a chain.

Reference numerals 412 and 422 denote guide rollers for stably contacting the rack gears 455 and 465 to the gears 410 and 420, and reference numeral 430 'denotes a shaft supporting the shafts of the gear shaft 470, the power generating shaft 520, and the guide roller. It is a support piece.

The rest of the configuration is the same as in the above-described embodiment.

The following describes the operation of the wave power generator according to another embodiment of the present invention.

11 illustrates a state in which the fuselage 100 is inclined to the left side due to wind or wind. When the fuselage 100 is inclined to the left as shown in FIG. 11, since the seawater 600 accommodated inside the fuselage 100 is horizontal, the weight link 301 on the left side is raised by the buoyancy body 340, The weight link 302 on the right side is lowered by the weight 320. As a result, both the rack gear 455 coupled to the weight link 301 on the left side and the rack gear 465 coupled to the weight link 302 on the right side pivot in a clockwise direction. Accordingly, the rack gear 455 coupled to the weight link 301 on the left rotates one gear 420 while proceeding from the upper side of the one gear 420, and is coupled to the weight link 302 on the right side. The rack gear 465 rotates the gear 410 while traveling under the other gear 410 such that both gears 410 and 420 rotate in opposite directions. However, the gear shaft 470 coupled to each of the gears 410 and 420 rotates by receiving only the rotational force of one gear 420 by the one-way bearing 414.

12 illustrates a state in which the fuselage 100 is inclined to the right. When the fuselage 100 is inclined to the right, the seawater 600 accommodated in the fuselage 100 is horizontal, the weight link 302 on the right side is lifted by the buoyancy body 340, and the weight link on the left side. 301 is lowered by the weight 320. As a result, the rack gear 465 coupled to the weight link 302 on the right side and the rack gear 455 coupled to the weight link 301 on the left side turn counterclockwise, while the weight link on the right side is turned. The rack gear 465 coupled to the 302 rotates the other gear 410 while proceeding from the bottom of the other gear 410, and the rack gear 455 coupled to the weight link 301 on the left side is the one gear. As the gear 420 is rotated while the upper gear 420 is rotated, both gears 410 and 420 rotate in opposite directions. However, the gear shaft 470 coupled to both gears 410 and 420 receives only the rotational force of the other gear 410 by the one-way bearing 414. Accordingly, even in this case, the gear shaft 470 rotates in the same direction as the case in which the body 100 is tilted to the left to transmit rotational force to the power generating shaft 520.

On the other hand, Figure 13 shows a state in which a plurality of wave power generation apparatus according to an embodiment of the present invention is connected to constitute a power generation complex at sea.

The power generation complexes are arranged in a plurality of columns and rows by connecting to each other with a rope 734 so that each body 100 can freely float and swing. Each wave power generator transmits the generated power to the current collector 710 through a power cable connected with the rope. Unexplained reference numeral 730 is a support for supporting the current collector 710 and the rope 734, reference numeral 732 is a floating body, reference numeral 712 is a power line and a fixed cable.

When a plurality of wave power generators according to the present invention are connected in a row, each of the wave power generators generates power independently while repeating fluctuations sequentially in accordance with the propagation of blue waves or shoulders. Therefore, even if there is a deviation in the amount of power produced by each of the power generators, since the inclined state along the heat occurs in various ways, if the current is collected by the current collector 710, the power with a small deviation over time Can produce. If the wave power generator is arranged more along the heat, a more uniform amount of power can be supplied.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. It goes without saying that other modified embodiments are possible.

100; Fuselage 120; Seawater Inlet
140; Leveling weights 151,152; Air tank
200; Support shafts 301,302; Weight link
303,304; Axial coupling portion 320; Weight
340; Buoyant body 400,400 '; Rotation generator
410,420; Gears 412,422; Guide Roller
415,425; Rack belt 414; One Way Bearing
430,430 '; Axial support pieces 441,442; slur
443,444; Pulleys 455,465; Rack gear
475; Power transmission means 500; generator
520; Development shaft 600; Seawater inside the fuselage
710; Current collector 712; Power lines and fixed cables
730; Support 732; Float
734; rope

Claims (7)

A floating body 100 in which the sea water 600 is accommodated therein;
A support shaft 200 installed inside the fuselage 100;
A weight link (301, 302) installed on the support shaft (200) so as to pivot freely about the support shaft (200);
A weight 320 installed in the weight link 301 and 302;
A buoyancy body (340) for floating the weight link (301,302) in which the weight (320) is installed in the sea water (600);
A rotation generator (400) for generating a rotational force in accordance with the turning of the weight link (301,302);
Wave power generator characterized in that it comprises a generator 500 for receiving the rotational force generated in the rotation generating device 400 to the power generation shaft 520 The method of claim 1,
The rotation generator 400
A connection line 441 and 442 coupled to the weight link 301 and 302 and moved when the weight link 301 and 302 is pivoted about the support shaft 200;
Rack belts (415, 425) installed on the connection lines (441, 442);
And gears 410 and 420 which rotate in contact with the rack belts 415 and 425 when the connection lines 441 and 442 are moved.
The rotational force is a wave power generator, characterized in that the rotational force generated in the gears (410,420) The method of claim 2,
The weight link (301, 302) is respectively installed on both sides of the support shaft 200,
The weight 320 and the buoyancy body 340 are installed in each of the weight link (301,302),
The connection lines 441 and 442 are separately provided and coupled to each of the weight links 301 and 302,
Each of the connecting lines 441 and 442 is connected to both sides of the rack belt, respectively, and the rack belt is divided into two strands.
Two gears 410 and 420 are installed on the two-strand rackbelt, respectively, and are installed on the power generation shaft 520.
The gear 410, 420 and the power generating shaft 520 is a wave power generator characterized in that each coupled via a one-way bearing 414 for rotating the power generating shaft 520 in the same one direction only The method of claim 1,
The rotation generator 400
A rack gear (455, 465) pivoting around the support shaft (200) in association with the weight link (301, 302) and forming a fan shape around the support shaft (200);
And gears 410 and 420 that are rotated when the rack gears 455 and 465 are rotated by the rack gears 455 and 465.
The rotational force is a wave power generator, characterized in that the rotational force generated in the gears (410,420) The method of claim 4, wherein
The weight link (301, 302) is respectively installed on both sides of the support shaft 200,
The weight 320 and the buoyancy body 340 are installed in each of the weight link (301,302),
The rack gears 455 and 465 are separately provided and coupled to the shaft coupling parts 303 and 304 installed on the support shafts 200, respectively.
The gear 410, 420 and the power generating shaft 520 is a wave power generator characterized in that each coupled via a one-way bearing 414 for rotating the power generating shaft 520 in the same one direction only The method according to any one of claims 1 to 5,
Wave power generation apparatus characterized in that the seawater inlet is further installed at a predetermined height to allow the entrance and exit of the seawater 600 on the side of the fuselage The method according to any one of claims 1 to 5,
The lower portion of the body of the wave power generator, characterized in that the horizontal holding weight 140 is further installed so as to maintain the horizontal only in the direction of the support shaft

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