KR20130067479A - Power generating equipment using wave and wind forces - Google Patents

Abstract

PURPOSE: A power generation apparatus using wind and wave power is provided to generate power by using wind together with wave on the sea. CONSTITUTION: A power generation apparatus using wind and wave power includes a marine supporting unit(110), a wind power wing assembly(120), a floating unit(125), a power generation unit(130), and a rope unit. The marine supporting unit is fixed on the seabed, and protruded over the sea. The wind power wing assembly is installed on the marine supporting unit. The floating unit moves vertically by wave power when waves rise. A roller is installed on the marine supporting unit. The power generation unit generates power by using the rotatory power of at least one between the roller and the wind power wing assembly. The rope unit has one end which is fixed on the floating unit, and comprises a rope which rotates the roller according to the vertical movement of the floating unit, where the rope is wound around the roller.

Description

Power generating equipment using wave and wind forces

The present invention relates to a power generator using wind force, and more particularly, it is possible to generate power by rotating the wing assembly with wind power, as well as winding or unwinding the rope with wave force to generate wind power using the same. It is about the power generator used.

A wave generator is a device that generates waves to convert into a useful energy such as electricity using a sea wave or an ocean wave. It is well known that sea waves constitute an almost infinite source of energy that can solve a significant portion of the world's energy problems if they are developed efficiently. Therefore, many applications have been filed at home and abroad for devices that generate electricity using sea waves. Korean Patent No. 10-0926463 is directed to a wave generator capable of generating power by using kinetic energy of a tide and a wave which are flow of seawater. Fig. 5 is a conceptual diagram of the wave generating device disclosed in Japanese Patent No. 10-0926463. 5 includes a screw bar 1, a first auxiliary fluid 3, a power converting means 5, a second auxiliary fluid 15, and a compressor 20 .

One end of the screw bar 1 is fixed to the seabed. The first part fluid (3) moves upward and downward along the screw bar (1) when the wave is hit and the wave is slack.

The power converting means (5) has a rotating portion and a linear motion portion (8). The rotating portion is constituted by a circular cam (7). The circular cam (7) is fixed to the upper part of the first float (3). Thus, when the first subfluid (3) moves up and down, the circular cam (7) also moves up and down. The circular cam (7) is engaged with the screw bar (1) so as to be able to rotate around the screw bar (1) during vertical movement. That is, the screw bar 1 is inserted through the circular cam 7. At this time, the screw bar (1) is inserted through the one side so as to be able to rotate about one side off the center of the circular cam (7).

The rectilinear motion part 8 serves to guide the rectilinear motion of the circular cam 7 during the rotational motion. To this end, an annular ring (9) and a power transmission shaft (11) are provided. The annular ring 9 surrounds the circular cam 7 as an elliptical shape. And the power transmitting shaft 11 engages with the annular ring 9. [ Therefore, when the circular cam 7 rotates, the power transmitting shaft 11 performs linear motion.

The compressor (20) is installed on the upper portion of the second float (15) and connected to the power transmission shaft (11). Thus, when the power transmission shaft 11 linearly moves, the fluid such as air or water is compressed.

When the wave (30) is hit, the wave is a sliver. Then, the first-order fluid (3) moves up and down in the direction of the arrow (31). When the first part fluid 3 moves up and down, the circular cam 7 rotates about the screw bar 1 in the direction of the arrow 33. When the screw bar 1 is rotated, the power transmission shaft 11 linearly moves in the direction of the arrow 35 to drive the compressor 20. At this time, the efficiency of driving the compressor (20) depends on the linear reciprocating distance of the power transmission shaft (11).

The conventional wave force generating device disclosed in FIG. 5 requires a first subfluid and a second subfluid to generate power by using a wave force, and the power conversion means is divided into a rotary motion part and a linear motion part, and thus the configuration is complicated.

In addition, the conventional wave generating device disclosed in FIG. 5 has a problem in that power generated by using only wave power is weak.

The present invention is intended to solve the above problems. An object of the present invention is to provide a power generator with a simple configuration by generating power by wave force using a rope.

In addition, an object of the present invention is to provide a power generator that can generate power using wind wave force by generating power using offshore wind power as well as wave power.

The power generating apparatus using the wind force according to the present invention includes an offshore support means, a wing assembly for wind power, floating means, power generating means, rope means. The sea support means is fixed to the bottom of the sea and protrudes into the sea. The wing assembly is installed on the marine support means to be rotated by the wind. The floating means moves up and down by the force of the wave when the wave hits. The power generating means includes a roller installed in the marine support means, and a power generating unit for generating power by at least one of the rotational force of the roller or the wing assembly. The rope means has one end fixed to the floating means and has a rope for winding the roller to rotate the roller as the floating means moves up and down.

In addition, in the power generating apparatus using the wind force, the rope means is a tension member for pulling the other end of the rope with a constant tension so that the rope can rotate the roller when the floating means moves up and down. It is preferable to further provide.

In addition, in the power generating device using the wind force, the tension member is preferably a rope winding member provided on the marine support means to pull the other end of the rope with a constant force.

In addition, in the power generator using the wind force, the tension member may be a weight weight coupled to the other end of the rope so as to pull the other end of the rope with its own weight.

In this case, in the power generating apparatus using the wind wave force, the marine support means includes a first guide for guiding the movement of the floating means in the vertical direction, and a second for guiding the movement of the weight in the vertical direction. It is preferable to have a guide.

In this case, it is preferable that in the power generating device using the wind wave force, the contact portion of the first guide and the floating means in contact with the first guide is formed of a conductor. In addition, the second guide and the contact portion of the weight in contact with the second guide is preferably formed of a conductor. Thus, the first guide, the second guide, the contact portion of the floating means, and the electricity generated in the power generating unit to prevent the seafood from sticking to the contact portion of the weight, the first guide and the first It is delivered in two guides.

In this case, in the power generator using the wind wave force, the power generator is preferably a generator or a fluid compressor.

According to the present invention, power is generated using both the wind power and the wave power, so that a large power can be obtained.

In addition, according to the present invention, since the rope is used when generating power by using the wave force, not only the configuration can be simplified, but also the installation can be facilitated.

1 is a conceptual diagram of an embodiment of a power generator using the wind force according to the present invention,
Fig. 2 is a conceptual diagram of the power generating means of the embodiment shown in Fig. 1,
3 is a front view of the embodiment shown in FIG.
4 is a conceptual diagram of another embodiment of the power generator using the wind force according to the present invention,
5 is an embodiment of a conventional wave power generator.

An embodiment of a power generator using wind wave according to the present invention will be described with reference to FIGS. 1 to 3.

Power generating device using the wind force according to the present invention includes a marine support means 110, wing assembly 120, floating means 125, power generating means 130, rope means 140 .

The sea support means 110 is fixed to the bottom of the sea and protrudes into the sea. And the marine support means 110 has a first guide 111 and a second guide 113 formed in the vertical direction on both sides thereof.

The wing assembly 120 has a plurality of wings 121 and is installed on the upper portion of the marine support means 110 to be rotated by the wind.

Floating means 125 is formed of a floating body so as to move up and down by the force of the wave when the wave hits, the floating means 125 is the first guide 111 to move up and down along the sea support means 110 ) Is combined. That is, the floating means 125 is coupled to slide along the first guide 111. And since the marine support means 110 and the floating means 125 is installed on the sea, seafood such as seaweed may adhere to the contact surfaces of the first guide 111 and the floating means 125 in contact with the first guide 111. have. In this case, it is difficult for the floating means 125 to slide along the first guide 111. Therefore, in order to prevent the seafood from adhering to the contact surface of the first guide 111 and the floating means 125, it is preferable that the contact surface of the first guide 111 and the floating means 125 can pass current. In this case, when the current is supplied from the power generating means 130 to allow a fine current to flow through the contact surface of the first guide 111 and the floating means 125 it can prevent the seafood is attached.

The power generating means 130 includes a roller 131 and a power generating portion. The roller 131 is installed in the sea support means 110. The power generating part serves to generate power by the rotational force of the roller 131 or the wing assembly 120. In the present embodiment, the power generating unit is a generator 133 capable of producing electricity by the rotational force of the roller 131 or the wing assembly 120 is configured. That is, when the roller 131 or the wing assembly 120 rotates, the generator 133 generates electricity by the rotational force. Although the generator 133 is used in this embodiment, a fluid compressor or the like may be used according to the embodiment. Even in the case of using a fluid compressor, it is also possible to generate electricity by operating a generator using the fluid compressor.

The rope means 140 serves to drive the roller 131 by using the shandong of the floating means 125. To this end, the rope means 140 is provided with a rope 141, the tension member.

The rope 141 is fixed at one end to the floating means 125, and winds the roller 131 to rotate the Shanghai simultaneous roller 131 of the floating means 125. At this time, when the rope 141 winds the roller 131, bearings 132 and the like may be installed at both sides of the roller 131 to guide the rope 141.

The tension member serves to pull the other end of the rope 141 with a constant tension. In the present embodiment, the tension member is formed of a weight 143. That is, the weight 143 is coupled to the other end of the rope 141 to pull the other end of the rope 141 as much as the weight of the weight 143. The weight 143 moves up and down in the opposite direction to the Shanghai simultaneous floating means 125 of the floating means 125. That is, when the floating means 125 is raised, the weight 143 is lowered, and when the floating means 125 is lowered, the weight 143 is raised. Therefore, the weight 143 also moves up and down. At this time, the weight 143 is coupled to the second guide 113 so as to slide along the second guide 113. Since the seafood such as seaweed may also adhere to the contact surface of the weight guide 143 in contact with the second guide 113 and the second guide 113, the same as the contact surface of the first guide 111 and the floating means 125. It is desirable that the current can be passed. In addition, the contact surfaces of the first guide 111 and the floating means 125 and the contact surfaces of the second guide 113 and the weight 143 are all formed to receive a current from the power generating means 130.

The operation of this embodiment will be described below.

Since the wing assembly 120 is installed on the upper portion of the sea support means 110, the wing assembly 120 rotates when the wind blows. When the wing assembly 120 rotates to drive the generator 133 to generate electricity. Since the wing assembly 120 of the present embodiment is installed at sea, the ground frictional force of the wind is smaller than that of the land, and thus, the wing assembly 120 may receive a larger wind than the land. So it is easier to generate power than onshore wind turbines.

In addition, the sea support means 110, the floating means 125 and the rope means 140 is provided. When the wave hits the floating means 125 is Shanghai-dong according to the wave. First, when the floating means 125 descends in the direction of arrow 101 by the wave, the weight 143 rises in the opposite direction. In this case, since the rope 141 is wound around the roller 131, the roller 131 rotates by the movement of the rope 141. The rotational force of the roller 131 drives the generator 133 to produce electricity. In addition, when the floating means 125 is raised in the direction of the arrow 103 by the wave, the weight 143 is reversed. As the weight 143 is lowered, the rope 141 moves in the direction of the weight 143 to rotate the roller 131. Then, the roller 131 rotates to drive the generator 133 to produce electricity.

Meanwhile, in the present embodiment, since the floating means 125 and the weight 143 move along the first guide 111 and the second guide 113, the rope 141 may be prevented from being entangled or twisted. Part of the electricity produced by the generator 133 is supplied to the contact surface of the first guide 111, the second guide 113, the floating means 125 and the contact surface of the weight 143, so that the seafood is attached to these Can be prevented.

In addition, the present embodiment can use both wind power and wave power to increase the efficiency of power generation.

Figure 4 is another embodiment of a power generator using a wind wave according to the present invention. As the tension member for applying the tension to the other end of the rope 141, the weight 143 may be used as in the embodiment shown in FIG. 1, but the rope winding member 145 may be used in the embodiment shown in FIG. 4. . Rope winding member 145 may be composed of a spring or the like, the rope 141 by pulling a rope 141 with a constant force when a greater force than the rope winding member 145 acts on the rope 141 in the opposite direction It is released from the rope winding member 145. In this case, since the rope winding member 145 does not move, the second guide 113 of the embodiment shown in FIG. 1 is not necessary.

110: maritime support means 111: first guide
113: second guide 120: wing assembly
125: floating means 130: power generating means
131: roller 133: generator
140: rope means 141: rope
143: weight 145: rope winding member

Claims (7)

A sea support means fixed to the bottom of the sea and projecting to the sea;
A wing assembly for wind power installed in the marine support means to rotate by wind;
Floating means for moving up and down by the force of the wave when the wave hits,
A power generating means having a roller installed at the sea support means, and a power generating unit generating power by at least one of the roller and the wing assembly;
One end is fixed to the floating means and the wind power generator using a wind wave force comprising a rope means having a rope for rotating the rollers as the floating means moves up and down by winding the roller. The method of claim 1,
The rope means further comprises a tension member for pulling the other end of the rope with a constant tension so that the rope rotates the roller when the floating means is vertical movement. . The method of claim 2,
The tension member is a power generator using a wind wave force, characterized in that the rope winding member installed on the marine support means to pull the other end of the rope with a constant force. The method of claim 2,
The tension member is a power generator using a wind wave, characterized in that the weight is coupled to the other end of the rope so as to pull the other end of the rope with its own weight. 5. The method of claim 4,
The above-
A first guide for guiding the movement of the floating means in a vertical direction,
And a second guide for guiding the movement of the weight in a vertical direction. The method of claim 5,
The first guide and the contact portion of the floating means in contact with the first guide is formed of a conductor,
The contact portion of the second guide and the weight in contact with the second guide is formed of a conductor,
In order to prevent seafood from sticking to the first guide, the second guide, the contact portion of the floating means, and the contact portion of the weight, the electricity generated by the power generating unit is the first guide and the second Power generator using wind wave, characterized in that the transmission to the guide. 7. The method according to any one of claims 1 to 6,
The power generator is a power generator using a wind wave, characterized in that the generator or a fluid compressor.

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