KR101405114B1 - Tidal Power Generation - Google Patents

Abstract

The present invention relates to a tidal power generation system capable of conveniently producing and using more environmentally friendly, economical and stable electricity in a book area that is not supplied with electric power from the land and a caged farm which is separated from the land.

The natural phenomena where tide and ebb tide occur repeatedly 24 hours a day is a phenomenon that can be seen all around the island area and the cage farm, and the whole area is the best place for the tidal power generation facilities.

As a specific means for realizing the above object, the present invention is characterized in that a drum type rotary drum is rotated by the force of tide and ebb and a plurality of rotary blades are disposed on the rotary drum, The present invention relates to a tidal power generation system which is coupled to a drum and is configured to be folded or unfolded according to a flow of tide or ebb to reduce the resistance generated during rotation, thereby increasing the production efficiency of electricity.

  Tidal power generation. Wave power generation. Hydropower. Hydraulic generator. Gear Pump.

Description

[0001] Tidal Power Generation [0002]

FIG. 1 is a perspective view showing a rotary drum according to the present invention. FIG.

FIG. 2 is a perspective view showing a state in which a rotary drum according to the present invention is coupled to a shaft. FIG.

FIG. 3 is a perspective view of a rotary drum according to an embodiment of the present invention. FIG.

FIG. 4 is a perspective view showing another embodiment of the rotary drum according to the present invention. FIG.

FIG. 5 is a schematic perspective view showing a tidal power generation system according to the present invention. FIG.

FIG. 6 is a perspective view showing an inspection port according to the present invention; FIG.

FIG. 7 is a schematic perspective view showing a coupled state of hydraulic pipes according to the present invention; FIG.

Description of the Related Art

1: rotating drum 2: rotating blade

3: Hydraulic gear pump 4: Incremental gear

5: Generator 6: Hydraulic check valve

7: Shaft 8: Bearing
9: Structure top plate. 10: superstructure

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11: Substructure 12: Buoyant material

13: Checkpoint

15: Hydraulic tandem piping. 16: Hydraulic parallel piping.

[0001] The present invention relates to a tidal power generation system using tidal and ebb-flow energy obtained from the ocean, and more particularly, to a tidal power generation system for producing electric power for use in a cage,

It is a method to obtain necessary electric power from a place away from the land such as a lot of a book area and a cage, and it installs a power line through the land and the seabed near a land to obtain electricity through it, Solar panels using solar panels, and wind turbines using wind.

In addition, fish cages are used to connect power lines from the land to the seawater.

In the vulnerable areas such as the island and cage, it is most convenient and stable to supply electricity by connecting the land and the power line. However, there is a problem of the installation process requiring installation of the power line at the seabed, There is a problem that the cost of electricity supplied due to maintenance and repair is high and it is vulnerable to natural disasters such as typhoons. In order to provide users with relatively stable electricity for the problems of cost and natural disasters, Generator, and wind turbine generator.

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However, these facilities can not be used 24 hours a day.

In addition, solar and wind power generation must meet the climate and conditions, so a separate storage facility is a prerequisite. For oil generators, expensive fossil fuels are used.

As a proposal for solving the above problems, tidal generation using natural phenomena such as tide and ebb that occur repeatedly 24 hours a day is an optimal place for generating the tidal power around the island like a book area, In addition, there is no problem with the surrounding marine ecosystem, and the resident in the book area can use convenient and economical electricity without inconvenience.
[Literature information of the prior art]
(Patent Document 0001) Korean Patent No. 10-1026196

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a tidal power generation system using a tide and an ebb flow, in which a rotary drum having a plurality of rotary blades folded or unfolded according to a position contacting with water is disposed, The rotating drum is rotated to increase the rotating force of the rotating drum by reducing the resistance of the rotating drum in accordance with the flow of the water, and the generator is coupled to the upper portion of the shaft to which the plurality of rotating drums are coupled, And to provide a tidal power generation system.

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Hereinafter, the structure of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a rotary drum 1 as a main component of the present invention. As shown in FIG. 1, four rotary blades 2 are rotatably engaged with each other at regular intervals in a radial manner, So that it is completely immersed in the seawater in a state where it is coupled to the shaft 7 to be described later.

The rotary blades 2 are expanded and closed by the hinges 2a according to the flow direction and the rotated position of the water at the time of tide and ebbing, This is for minimizing the decrease in the rotational force due to the unnecessary resistance in the water due to the rotational resistance in the water.

Therefore, the portion of the rotary vane 2 directly receiving the water flow is opened, and the portion of the rotary vane 2 which is not subjected to the flow resistance is closed by the rotation force and the pressure.
That is, the rotary vane 2 is unfolded or folded in one direction by the hinge 2a. When the rotating vane 2 is unfolded, when the advancing water comes into contact with the inner peripheral surface of the rotary vane 2, The wings 2 are spread by the hinge 2a and the rotary wings 2 are supported by the hinge 2a to rotate the rotary drum 1 while being pushed by the advancing force of the water, The rotating blades 2 are folded toward the rotating drum 1 when water advancing on the outer peripheral surface of the rotating blades 2 comes into contact with each other.

Further, the drum type of the rotary drum 1 is further away from the center of the shaft 7, which is the center axis of rotation during the rotary motion, and the rotary vane 2 receiving the flow of water generates an effect of increasing the rotational force, Thereby rotating the connected speed increasing gear 4.

The inside of the rotary drum 1 is filled with buoyant material to prevent submergence in the seawater from being completely submerged in the seawater. At the same time, the overall weight is reduced, the maintenance is easy, and the unit cost is reduced.

2 shows a state in which a plurality of the rotating drums 1 are coupled to one shaft 7 to which the generator 5 is coupled at an upper portion thereof and the shaft 7 is rotated through a plurality of rotating drums 1, So as to obtain a stronger rotational force for rotating the motor.
That is, depending on the number of the rotating drums 1 coupled to the shaft 7, the rotational forces obtained through the respective rotating drums 1 are combined, so that the shaft 7 can be rotated strongly.
6, a bearing 8 is coupled to the shaft 7 so that the shaft 7 can be smoothly rotated when the shaft 7 is rotated by a rotational force transmitted through the rotary drum 1 .

This is because the number of revolutions of the drum-type rotary drum 1 is the same regardless of the number of revolutions of the drum 1, but the rotational force of the drum-type revolving drum 1 is as high as the number of connections.

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3 shows another embodiment of the present invention in which a plurality of rotary drums 1 are coupled to a shaft 7 and a hydraulic gear pump 3 to which an upper end of the shaft 7 is coupled is connected to a shaft 7 So that the hydraulic gear pump 3 is operated by the rotation of the shaft 7. 7, a check valve 6 for hydraulic pressure is provided on the supply side of the hydraulic gear pump 3 so that the hydraulic pressure flows only to one side, and each of the hydraulic gear pumps 3 One end of the series pipe 15 is coupled to the parallel pipe 16 and is connected to a plurality of series pipes 15 (Not shown) after being introduced into the parallel piping 16 via the hydraulic pump (not shown).

A plurality of rotary drums 1 and a hydraulic gear pump 3 are provided on one shaft 7 as described above, and a plurality of the hydraulic gear pumps 3 are arranged as necessary, The shaft 7 is connected to the disposed hydraulic gear pump 3, respectively, to obtain a required amount of power that can be obtained through a stronger pump action.

4 shows that the electric motor 5 is connected to the upper end of the shaft 7 to which the rotary drum 1 is coupled so that electricity can be obtained through the rotational force of the shaft 7 , And the generator (5) is operated by rotating the speed increasing gear (4) during the rotation of the shaft (7) to produce electricity. The bearing 8 is coupled to the shaft 7 and the bearing 8 is disposed on the upper surface of the upper structure 10 to be described later so that when the shaft 7 is inserted into the upper structure 10, 8 so as to facilitate rotation.
4 is a view showing a state where a plurality of rotary drums 1 are disposed below one shaft 7 and a speed increasing gear 4 is coupled to an upper end of a shaft 7, (5) is provided, and a plurality of sets are arranged.
5 is a general schematic view showing a power generation system according to the present invention in which a plurality of shafts 7 to which a rotary drum 1 is coupled is arranged such that the shaft 7 is coupled to an upper structure 10, A buoyant material 12 is provided below the upper structure 10 to prevent the upper structure 10 from being submerged in the sea while being placed in the sea, The buoyant member 12 supports the upper structure 10 to minimize damage and breakage of components such as the upper structure 10 and the shaft 7. [
The shaft 7 is coupled to the upper structure 10 and the bearing 8 is fixed to the upper surface of the upper structure 10 so that the shaft 7 is inserted into the bearing 8 .

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The lower structure 11 disposed at a lower portion of the upper structure 10 has a rectangular pipe shape filled with a buoyancy material therein and a lower end of the shaft 7 is fixed. And the upper structure 10 is prevented from sinking in the sea.

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6 shows a state in which when a failure occurs in a part of the rotary drum 1 disposed on the entire upper structure 10, the other rotary drum 1 is maintained in a normal operation while the failed rotary drum 1 is maintained And each of the shafts 7 is provided with a rotary plate check hole 13. The inspection port 13 is disposed on the upper surface of the upper structure 10 so as to be recessed from the upper surface of the upper structure 10 to the inside so as not to be exposed to the upper portion.
The shaft 7 coupled to the rotary drum 1 having the failure is connected to the bearing 8 fixed to the upper surface of the upper structure 10 through the hole 7, And then lifts the inspection port 13 from the upper structure 10 and then replaces the rotating drum 1 in which the failure has occurred by removing the inspection port 13 from the upper structure 10 do.

In addition, since the drum-type rotary drum 1 is always kept in the seawater, there is a possibility that the seaweed or other foreign matter may cause a problem, so that the inspection hole 13 is required to be easily repaired and replaced at any time.

FIG. 7 shows that a plurality of hydraulic gear pumps 3 are arranged in another embodiment of the present invention according to FIG. 3, and a plurality of hydraulic gear pumps (not shown) 3 are connected to each other through a series piping 15 and a parallel piping 16 so as to supply hydraulic pressure to a hydraulic piston pump (not shown in the figure) to obtain necessary electricity.

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At this time, the hydraulic oil supplied to the hydraulic piston pump is circulated to the hydraulic gear pump 3 continuously through an oil tank (not shown in the figure).

In places that receive electricity benefits, they do not feel the importance of it, and they can be solved by simply pushing the switch. However, there are still a few inconveniences in using electricity for oil generators, solar panels, and wind power in many islands, and there are a lot of areas that need to be managed.

The present invention is a tidal and ebb tidal generation method using a natural phenomenon that occurs repeatedly without interruption 24 hours a day, so that it is more stable than any other method and can obtain the maximum effect. Further, If small and medium-sized tidal power is produced to the extent that it is necessary to use electricity at the optimum place where facilities can be used, the people living in the island area can conveniently and economically use electricity without any problem in the surrounding marine ecology environment .

The small and medium sized tidal power generation system of the present invention will be provided with a condition to be solved by simply setting up a switch for them, and it will be able to take a more cultural advantage and power the productive business more than before.

Claims (4)

1. A tidal power generation system for generating electricity using a flow of tide and ebb, A rotary drum 1 provided with a buoyancy material therein and a plurality of rotary blades 2 radially coupled to a hinge 2a so that the rotary blades 2 are folded or unfolded according to the flow of tide or ebb; A shaft 7 coupled to the rotary drum 1 and rotated together with the rotary drum 1 and having a generator 5 coupled to the upper end thereof; An upper structure 10 having the shaft 7 penetratingly connected thereto and having a buoyant material 12 at a lower portion thereof; And a lower structure (11) disposed below the upper structure (10), the lower end of the shaft (7) being fixed and the buoyancy material being filled therein, The shaft 7 is coupled to a bearing 8 fixed to an upper surface of the upper structure 10 and having an upper end exposed above the upper structure 10, A hydraulic gear pump 3 coupled to the upper end of the shaft 7; a hydraulic check valve 6 provided on the supply side of the hydraulic gear pump 3 to control the hydraulic pressure to flow only to one side; A hydraulic pump for supplying hydraulic pressure to the hydraulic pump; a hydraulic pump connected to the hydraulic pump; a hydraulic pump for generating hydraulic pressure; And a parallel piping (16) for transferring the mixed gas to the piston pump. delete delete delete

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