KR101623684B1 - Hydroelectric power plant - Google Patents

Abstract

The present invention relates to a hydroelectric power generation apparatus. More specifically, the hydroelectric power generation apparatus connects chains to rotary shafts arranged on front and rear portions of a pair of buoyant bodies, installs multiple water collecting sheets on the chains to generate a large amount of power, has rotary bars to be rotated to apply a high water pressure to rear surfaces of the water collecting sheets and apply a load in a direction opposite to a rotational of the chains to maximally prevent the water collecting sheets or the chains from breaking down and improve power generation efficiency, and alternately forms a number or positions of holes on the water collecting sheets to prevent a decrease in a flow rate or a water pressure applied to the water collecting sheets arranged in the rear to apply a uniform water pressure to the multiple water collecting sheets to stably generate power.

Description

[0001] Hydroelectric power plant [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hydraulic power generating apparatus, and more particularly, to a hydraulic power generating apparatus capable of generating a large amount of electric power by connecting a chain to rotary shafts disposed forward and rearward of a pair of buoyant bodies, When water is submerged in the water, a large hydraulic pressure is applied to the rear surface of the water receiving sheet, and a load opposite to the rotational direction of the chain is applied, thereby preventing the water receiving sheet, It is possible to improve the power generation efficiency and to prevent the flow velocity or the water pressure on the water receiving sheet disposed on the rear side from being reduced by forming the number or positions of the holes alternately in the water receiving sheet to provide uniform water pressure on the plurality of water receiving sheets, To a hydropower generator.

Generally, the power generating apparatus generates steam by heat generated during combustion of atomic energy or fossil fuel, generates power by its vapor pressure, and the power generating apparatus such as an internal combustion engine or an external combustion engine generates explosive force .

However, such a power generation system using fossil fuels is subject to a lot of restrictions in developed countries due to environmental problems.

On the other hand, a hydro turbine or a water turbine is considered to be an environmentally friendly device as a power generating device using fall of water, but it is limited to installing the device like a river dam, and thus is a technology that is not widely used.

In addition, a power generating device that uses solar, solar, wind or tidal power as an energy source has the advantage of using environmentally friendly energy. However, since it does not have economical efficiency and practical technology, I can not.

To solve this problem, Korean Patent Laid-Open No. 10-2001-0096812 discloses a water bottle; An upper road rail and a first lower road rail installed at upper and lower portions of the water tank, respectively; A second lower roadway connected to an axis of the lower roadway and installed outside the waterway; A belt connected to the upper road and the first lower road; A reservoir in which one side is open and the other side is closed; A piston provided below a bottom of a water reservoir existing beneath a downward direction of the air cylinders at a position where the closed surfaces of the air cylinders face downward; A drive roller provided directly below the piston; A belt connecting the second lower road and the driving road; A piston rod connected to a bottom surface of the piston and a point of one end of the circumference of the driving road rail; A first check valve installed to communicate with an upper surface of the piston and a bottom surface of a water reservoir; And a second check valve provided on a lower surface of the piston, wherein the upper check valve and the first lower check valve are spaced apart from the water can, .

However, since the air cylinders are formed in a fixed shape, there is a problem in that the power generation efficiency is low due to the large resistance during the descent.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a buoyant body having a pair of buoyant bodies and a plurality of buoyant seats in the chain, And to provide a hydraulic power generator capable of generating positive power.

The object of the present invention is to provide a water retention device that is capable of rotating a rotating bar so that when water is submerged in water, a large water pressure is applied to the back surface of the water receiving sheet, And to provide a hydroelectric generating apparatus capable of preventing a trouble as much as possible and improving power generation efficiency.

It is another object of the present invention to provide a water receiving sheet in which the number and position of holes are alternately formed in the water receiving sheet to prevent the flow velocity or the water pressure applied to the water receiving sheet disposed at the rear side from being reduced, And to provide a hydropower generator capable of generating electricity.

It is another object of the present invention to provide a method and system for controlling a power generation system in which a plurality of first and second buoyant bodies can be easily attached and detached so that the scale of power generation can be easily adjusted, And to provide a hydroelectric generating apparatus capable of easily installing a plurality of hydroelectric generators in a desired area.

It is also an object of the present invention to provide a hydraulic power generating apparatus capable of preventing the water flow from pulsing or rapidly changing at the boundary of the water receiving sheet or at the boundary of a plurality of buoyant bodies.

To this end, the hydroelectric power generating apparatus according to the present invention comprises at least a pair of first and second buoyant bodies which are fixed in floating state and are arranged side by side in a horizontal direction; A front and rear rotating shafts disposed laterally in front and rear regions of the first and second buoyant bodies, respectively; Front and rear chain gears installed at both ends of the front and rear rotating shafts; First and second chains connected to the front and rear chain gears in the front-rear direction; A plurality of first and second rotating bars installed along the peripheries of the first and second chains, and a plurality of water receiving sheets provided between the first and second rotating bars; And a generator connected to the front rotary drum or the rear rotary drum, wherein the plurality of water receiving sheets disposed in parallel to each other in the longitudinal direction are submerged in water below the rotary shaft and pushed rearward by the flow of water, So that power generation is performed.

The rotary bar of the hydraulic power generating apparatus according to the present invention is rotatably hinged to the chain, and a guide groove is formed at one side thereof, one end is fixed to one side of the rotary bar, A wire fixed to a chain in a front region of the rotating bar to limit a range of rotation of the rotating bar; And a support bar having one end coupled to the guide groove and the other end fixed to a chain in a rear region of the rotation bar to support the rotation bar, wherein when the rotation bar is submerged in water, And is folded in a state in which it passes through the rear chain gear and goes out of the water.

The water-receiving sheet of the hydro-electric power generating apparatus according to the present invention has at least one hole formed therein to transmit the water flow to the water-receiving sheet disposed behind the water-receiving sheet and to prevent it from being damaged by water pressure, .

Further, adjacent water receptacle sheets of the hydro-power generator according to the present invention are characterized in that the holes are formed at different positions.

At least one of the first and second buoyant members is connected to a rear end of each of the first and second buoyant members of the hydraulic power generating apparatus according to the present invention to generate additional power, And the other end is fixed to the front lower end of the first and second buoyant bodies disposed rearward.

In addition, the first and second buoyant bodies of the hydro-electric power generating apparatus according to the present invention are characterized by being in the form of a vessel having a streamlined shape.

Further, when the water receiving sheet of the hydroelectric power generating apparatus according to the present invention is flooded, the proximal portion is located at a depth of at least 0.3 to 1.0 m from the surface of the water based on the rotation axis, and is completely flooded.

According to the hydraulic power generating apparatus according to the present invention, a chain is connected to rotary shafts disposed forward and rearward of a pair of buoyant bodies, and a large number of water receiving sheets are provided in the chain, thereby generating a large amount of electric power.

Further, according to the hydraulic power generating apparatus according to the present invention, when the water is submerged in the water, a large hydraulic pressure is applied to the rear surface of the water receiving sheet and a load opposite to the rotating direction of the chain is applied, It is possible to prevent the breakdown of the sheet, the chain, and the like as much as possible and to improve the power generation efficiency.

Further, according to the hydraulic power generating apparatus according to the present invention, the number and position of the holes are alternately formed in the water receiving sheet, thereby preventing the flow velocity and the water pressure on the water receiving sheet disposed at the rear side from being reduced, Thereby making it possible to stably generate electricity.

In addition, according to the hydroelectric power generating apparatus according to the present invention, since the first and second buoyant bodies can be easily attached and detached, the power generation scale can be easily adjusted, and it can be configured in the form of a ship, There is an effect that a plurality of hydroelectric generators can be easily installed in the apparatus.

Further, according to the hydraulic power generating apparatus according to the present invention, the water flow can prevent the water receiving sheet from pulsing or rapidly changing at the boundary or at the boundaries of the plurality of buoyant bodies.

1 is a plan view showing an embodiment of a hydroelectric power generating apparatus according to the present invention.
2 is a side view showing an embodiment of a hydroelectric power generating apparatus according to the present invention.
3 is a front view showing an embodiment of the hydroelectric power generating apparatus according to the present invention.
4 is a view showing a state where the rotating part of the present invention is coupled to the chain and rotating.
Fig. 5 is a view showing a state in which a water receiving sheet of the present invention is disposed.
6 and 7 are views showing a state where a plurality of first and second buoyant bodies of the present invention are connected.

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

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the terms described below are defined in consideration of the functions of the present invention, and these may vary depending on the intention of the user, the operator, or the precedent. Therefore, the definition should be based on the contents throughout this specification.

2 is a side view showing an embodiment of a hydroelectric power generating apparatus according to the present invention. FIG. 3 is a schematic view of a hydroelectric power generating apparatus according to an embodiment of the present invention. And Fig. FIG. 4 is a view showing a state where the rotating part of the present invention is coupled to the chain, and FIG. 5 is a view showing a state in which the water receiving sheet of the present invention is disposed.

1 to 5, the hydroelectric power generating apparatus 100 according to the present invention generates power by floating a buoyant body in a flow of water such as a river or the sea. The hydraulic power generating apparatus 100 includes a first and a second buoyant bodies 110 and 110a The front and rear rotating shafts 120 and 120a, the front and rear chain gears 125 and 125a, the first and second chains 130 and 130a, the rotation unit 140, and the generator 160 .

Specifically, at least a pair of first and second buoyant bodies 110 and 110a, which are fixed in a floating state and are arranged side by side in a horizontal direction, and a pair of first and second buoyant bodies 110 and 110a are disposed in front and rear regions of the first and second buoyant bodies 110 and 110a, Front and rear chain gears 125 and 125a provided at both ends of the front and rear rotation shafts 120 and 120a and front and rear chain gears 125 and 125a disposed at both ends of the front and rear rotation shafts 120 and 120a, A plurality of first and second rotating bars 141 and 141a installed along the peripheries of the first and second chains 130 and 130a, And a generator 160 connected to the front rotary shaft 120 or the rear rotary shaft 120a, the rotary shaft 140 including a plurality of water receiving sheets 150 installed between the first and second rotary bars 141 and 141a, .

Hereinafter, each configuration and operation of the hydraulic power generating apparatus according to the present invention will be described in detail.

The first and second buoyant bodies 110 and 110a are arranged on the left and right sides and are formed as a pair. The first and second buoyant bodies 110 and 110a are fixed by the fixed anchor 111 in a floated state and are made of a streamlined vessel But the present invention is not limited thereto. However, when the ship is used as the first and second buoyant bodies 110 and 110a, the hydroelectric power generator 100 can be installed or moved without a separate tow line.

The rotating shafts 120 and 120a to the generator 160 are installed on the first and second buoyant bodies 110 and 110a.

The front rotary shaft 120 is installed transversely to the front area of the first and second buoyant bodies 110 and 110a and the rear rotary shaft 120a is disposed laterally in the rear area of the first and second buoyant bodies 110 and 110a. And the rotary shafts 120 and 120a are installed on the first buoyant body 110 at one end and installed on the second buoyant body 110a at the other end.

A generator 160 is connected to one end of the front and rear rotary shafts 120 and 120a.

The generator 160 converts rotational force transmitted through the rotating shafts 120 and 120a into electrical energy. The generator 160 includes a permanent magnet (not shown) and a coil wound around the permanent magnet ), And vice versa. However, since such a generator corresponds to a known configuration, detailed description thereof will be omitted.

A pair of front chain gears 125 are provided on the front rotation shaft 120 and a pair of rear chain gears 125a are provided on the rear rotation shaft 120a.

The first chain 130 is connected to the front chain gear 125 and the rear chain gear 125a disposed at one side of the first buoyant body 110 and the front chain gears 125a, The second chain 130a is connected to the rear chain gear 125a and the rear chain gear 125a. That is, the first and second chains 130 and 130a are installed parallel to each other between the first and second buoyant bodies 110 and 110a, and are rotated by the hydraulic force transmitted through the rotation unit 140 in a state where they are arranged long before and after.

As described above, the forward and rear chain gears 125 and 125a are advantageous in that they can generate a large amount of power as compared with those having a single axis like a spinning wheel.

The first and second chains 130 and 130a are rotated by water pressure applied to the rotation unit 140, and the rotation unit 140 is configured to receive the flowing water.

Specifically, the rotation unit 140 includes first and second rotation bars 141 and 141a hinged to the chains 130 and 130a, a water receiving sheet 150 coupled between the first and second rotation bars 141 and 141a, ≪ / RTI >

The first rotating bar 141 is hinged to the first chain 130 and the second rotating bar 141a is hinged to the second chain 130a.

The rotary bars 141 and 141a disposed below the rotary shafts 120 and 120a are submerged in water so that the flow of the water in the horizontal direction And the rotating bar disposed above the rotating shafts 120 and 120a is folded.

A guide groove 143 is formed on one side of each of the rotation bars 141 and 141a and a wire 145 is provided in front of the rotation bars 141 and 141a. Respectively.

One end of the wire 145 is fixed to one side of the rotation bars 141 and 141a and the other end is fixed to chains 130 and 130a in a front region of the rotation bars 141 and 141a, , 141a) is limited to, for example, 90 degrees.

In the case where the wire 145 or the wire 145 is fast enough, the rotating bar may not be sufficiently supported by the wire 145. For this purpose, a supporting bar 147 for supporting the rotating bars 141 and 141a from the rear is installed .

An arc-shaped guide groove 143 is formed on one side of the rotation bars 141 and 141a.

One end of the support bar 147 is coupled to the arc-shaped guide groove 143 and the other end of the support bar 147 is hinged to the chain 130 or 130a in the rear region of the rotation bar 141 or 141a, (141, 141a) from behind.

One end of the support bar 147 moves along the guide groove 143 and the other end rotates in the process of folding and unfolding the rotation bars 141 and 141a.

The reason why the rotation bars 141 and 141a are rotatable is that when the water is immersed in the water outside the water and the rotation bars 141 and 141a are fixed vertically, Water pressure is applied to the rear surface, which is likely to break, and a load opposite to the rotational direction of the chains 130 and 130a is applied, which may cause a failure, and the power generation efficiency also deteriorates.

When the rotation bars 141 and 141a pass the rear chain gear 125a, the rotation bars 141 and 141a and the water receiving sheet 150 are inflated into the water as they are developed. At this time, It is preferable that the weight 142 is provided so that the immersion process is performed promptly and that the immersion process is not sensitive to changes in the flow velocity even after immersion.

At least one hole 151 is formed in the water receiving sheet 150 to transmit the water flow to the water receiving sheet 150 disposed behind the water receiving sheet 150 and to prevent the water receiving sheet 150 from being damaged by water pressure, desirable.

Further, since the water receiving sheet 150 is made of a fabric, it is light and flexible compared to a metal or plastic material, so that it has excellent impact resistance, is easy to manufacture, has a low manufacturing cost, and is easy to replace.

The holes 151 prevent the flow velocity on the water receiving sheet 150 disposed at the rear by the water receiving sheet 150 at the front side from being reduced so that uniform water pressure is applied to the plurality of water receiving sheets 150 arranged in a row And prevents the flow of water from pulsating to the boundary of the water receiving sheet.

It is preferable that the holes 151 are formed at positions or numbers different from the adjacent water receiving sheet 150.

For example, when one water receptacle sheet 150 has one hole 151 at its center, two adjacent water receptacle sheets 150 have two holes 151 formed at both sides thereof.

By alternately forming the holes 151 in the adjacent water receiving sheet 150 in this manner, it is possible to more effectively prevent the flow velocity or the water pressure applied to the water receiving sheet 150 disposed on the rear side from being reduced.

Although not shown, as another embodiment, adjacent water receiving sheets may have different areas. For example, the water receiving sheet disposed in front is narrow, the water receiving sheet disposed adjacent to the rear side is wide, and the water receiving sheet is then narrowed.

When the water receiving sheet 150 is submerged, the proximal portion 153 is located at a depth of at least 0.3 to 1.0 m from the surface of the water based on the rotation axis 120, 120a to be completely submerged so that the flow of water is not blocked at the surface .

6 and 7 are views showing a state where a plurality of first and second buoyant bodies of the present invention are connected.

Referring to FIGS. 1 to 5 and FIGS. 6 and 7, at least one other first and second buoyant bodies 110 and 110a are connected to a rear end of each of the first and second buoyant bodies 110 and 110a by a connection wire 113, Can be connected and configured for further development.

One end of the connecting wire 113 is fixed to the rear upper end of the first and second buoyant bodies 110 and 110a and the other end is connected to the front and rear ends of the first and second buoyant bodies 110 and 110a, It is desirable to fix it, since the front end of the buoyant body is lowered during power generation to compensate it.

Since a plurality of first and second buoyant bodies can be easily attached and detached, the power generation scale can be easily adjusted, and a plurality of hydroelectric generators can be easily installed in a desired area in accordance with the environment of the river or the sea, There are advantages to be able to.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities. Accordingly, the scope of the present invention should be construed as being limited to the embodiments described, and it is to be interpreted that the scope of the present invention includes not only the following claims, but also equivalents thereof.

100: hydroelectric power generation apparatus 110, 110a: first and second buoyancy elements
111: fixed anchor 113: connecting wire
120, 120a: front and rear rotating shafts
125, 125a: front and rear chain gears
130, 130a: first and second chains 140:
141, 141a: first and second rotating bars 143: guide grooves
145: wire 147: support bar
150: water receiving sheet 151: hole
153: proximal portion 160: generator

Claims (7)

delete At least one pair of first and second buoyant bodies fixed in a floating state and arranged side by side in the water;
A front and rear rotating shafts disposed laterally in front and rear regions of the first and second buoyant bodies, respectively;
Front and rear chain gears installed at both ends of the front and rear rotating shafts;
First and second chains connected to the front and rear chain gears in the front-rear direction;
A plurality of first and second rotating bars installed along the peripheries of the first and second chains, and a plurality of water receiving sheets provided between the first and second rotating bars;
And a generator connected to the front rotation shaft or the rear rotation shaft,
The plurality of water receiving sheets disposed in parallel to each other in the longitudinal direction are submerged in water below the front and rear rotating shafts and are rotated backward by the flow of water to rotate the front and rear rotating shafts to generate electricity,
The first and second rotating bars are rotatably hinged to the first and second chains, and arc-shaped guide grooves are formed on one side,
One end of which is fixed to one side of the first and second rotating bars and the other end is fixed to the first and second chains in the front region of the first and second rotating bars to limit the range of rotation of the first and second rotating bars A wire;
And a support bar fixed to the first and second chains at one end and coupled to the guide groove and at the other end in a rear region of the first and second rotation bars to support the first and second rotation bars,
Wherein the first and second rotary bars are configured to expand in a direction perpendicular to the flow of water when the first and second rotary bars are submerged in water and to fold when the first and second rotary bars are out of the water through the rear chain gear. 3. The method of claim 2,
Wherein the water receiving sheet is formed of at least one hole so as to prevent the water receiving sheet from being damaged by water pressure. The method of claim 3,
Wherein the adjacent water receiving sheets have the holes formed at different positions. 3. The method of claim 2,
At least one of the first and second buoyant members is connected to the rear end of each of the first and second buoyant members by a connecting wire to perform additional power generation,
Wherein the connecting wire is fixed to a rear upper end of one of the first and second buoyant bodies disposed at the front and the other end is fixed to a front lower end of the first and second buoyant bodies disposed at the rear. 3. The method of claim 2,
Wherein the first and second buoyant members are in the form of a ship having a streamlined shape. delete

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