KR101238304B1 - A system for generating electric power using hydraulilc power - Google Patents

Abstract

The present invention relates to a power generation system using hydraulic pressure, which can perform power generation without restriction of power generation location, and relates to a power generation system capable of minimizing generation of pollutants.
The present invention comprises a plurality of hydraulic jacks having a head for performing a reciprocating motion by the hydraulic pressure; A power transmission unit connected to the hydraulic jack and operating according to the movement of the hydraulic jack, converting and transferring the reciprocating motion of the hydraulic jack head to a rotational movement; a main drive unit connected to the power transmission unit to perform a rotational movement; A driven part connected to the main drive part to perform a rotational motion by the power received from the main moving part; and a power generation device connected to the driven part to generate power by the rotational motion of the driven part. Provide power generation system.

Description

A system for generating electric power using hydraulilc power}

The present invention relates to a power generation system using hydraulic pressure, which can perform power generation without restriction of power generation location, and relates to a power generation system capable of minimizing generation of pollutants.

In general, the electricity industry that generates electricity uses fossil fuel-fired power generation systems, nuclear power systems using nuclear power, and hydroelectric power generation using hydropower.

In the case of thermal power generation, the use of fossil fuels generates greenhouse gases such as carbon, causing global warming and destroying ecosystems.

In the case of nuclear power generation, it has been recognized as a relatively stable and inexpensive energy. However, as seen in recent Japanese nuclear power accidents, the question has been raised about its safety.

On the other hand, in the case of hydro power generation, there is a limitation of a place where power generation facilities can be installed only in a large river or lake as a system for generating power using a drop of water.

Recently, interest and research on renewable energy generating electricity using wind and solar light have been increasing. In the case of solar energy use, solar panels should be installed in a large area in order to produce satisfactory electricity, and there was a problem in that power generation was possible only during the day when the sun was rising and on a clear day.

In addition, even in the case of wind power generation, there is a place restriction that the power generation efficiency is increased when the wind strength is installed on a strong coast, etc., and there is a problem that stable power generation is difficult because the power generation fluctuates greatly according to the wind strength and direction.

The present invention is to solve this problem, it is an object of the present invention to provide a power generation system that can be stably obtained without being restricted by the place, and can minimize the generation of pollution.

The present invention for achieving this object is a plurality of hydraulic jack having a head portion for performing a reciprocating motion by hydraulic pressure; A power transmission unit connected to the hydraulic jack to operate according to the movement of the hydraulic jack, and converting and transferring the reciprocating motion of the hydraulic jack head to a rotational motion; A main drive unit connected to the power transmission unit to perform a rotational movement; A driven part connected to the main moving part and performing a rotational motion by the power received from the main moving part; It is connected to the follower provides a power generation system comprising a power generation device for generating power by the rotational movement of the follower.

The power transmission unit and the cylinder is connected to the hydraulic jack;

A piston provided in the cylinder to reciprocate and performing reciprocating motion according to the reciprocating motion of the hydraulic jack;

It characterized in that it comprises a connecting rod connected to the piston.

The main body and the main shaft;

A main rotating member connected to the main shaft;

It includes a rotational inertia connected to the main shaft and provided to increase the rotational inertia of the main shaft,

The main shaft is a crank shaft connected to the connecting rod;

It is provided on both ends of the crank shaft, characterized in that it comprises a rotating shaft is installed the main rotating member and the rotary inertia.

The rotational inertia is characterized in that the inertial member for increasing the rotational inertia is provided.

The main shaft is provided in plurality,

Each of the main shaft is provided with the rotary inertia and the main rotating member,

Each main shaft is characterized in that connected to the shaft connecting member.

The driven part and the driven shaft;

It includes a driven rotary member connected to the driven shaft,

The generator is characterized in that it is provided at one end of the driven shaft.

It is characterized in that it further comprises a clutch member provided between the power generator and the driven shaft to selectively perform the connection between the driven shaft and the power generator.

The main rotating member and the driven rotating member is composed of a chain gear formed with a predetermined tooth,

The chain may further include a chain connecting the main rotating member and the driven rotating member and transmitting power of the main rotating member to the driven rotating member.

The main gear rotating member and the chain gear constituting the driven rotating member is provided so as to be separated from each other and the tooth portion is formed on the outer peripheral surface;

Characterized in that it comprises a fastening member for fastening a plurality of components constituting the body portion.

The follower includes a first follower and a second follower,

The power generation device includes a first power generation device connected to the first follower and a second power generation device connected to the second follower,

The first driven part includes a first driven shaft, a first driven rotating member provided on the first driven shaft, and an intermediate rotating member provided separately from the first driven rotating member,

The second driven part includes a second driven shaft and a second driven rotating member connected by the intermediate rotating member and a predetermined power transmission member.

The clutch unit may include a first clutch unit selectively connecting the first power generator and the first driven shaft, and a second clutch unit selectively connecting the second power generator and the second driven shaft. do.

In the power generation system according to the present invention, since power generation can be performed with only minimal energy for driving a hydraulic jack, there is an advantage that the pollution problem due to power generation itself can be minimized.

On the other hand, as long as there is a stable ground on which the components of the power generation system of the present invention can be placed, the power generation system can be assembled and thus can be generated anywhere without restriction.

On the other hand, when the size of the main rotating member, the driven rotating member and the like is large, since it can be disassembled and assembled, it is easy to install and transport.

In addition, since the driven shaft or the main shaft can be continuously connected by the shaft connecting member, it is possible to easily scale up.

In addition, by mounting the clutch unit between the power generator and the driven shaft, it is possible to reduce the load by the power generator at the beginning of the movement of the main drive, so that after the rotation speed of the driven shaft reaches a certain level more quickly Since the driven shaft can be connected, there is an advantage that the stability of the system can be realized by reducing the load in the initial startup state.

1 is a schematic diagram of a first embodiment of a power generation system according to the present invention.
Figure 2 is an exploded perspective view of the power transmission unit of the power generation system according to the present invention.
3 is a combined perspective view of the power transmission unit of the power generation system according to the present invention.
4 (a) and 4 (b) are views of the shaft connecting member of the power generation system according to the present invention.
5 is a side view of the main rotating member and the driven rotating member and the power transmission member connecting them in the power generation system according to the present invention.
Figure 6 (a) is a side view showing that the main rotating member and the driven rotating member is provided in a disassembled state in the power generation system according to the present invention.
Figure 6 (b) is a side view of the rotary inertia in the power generation system according to the present invention.
7 is a schematic diagram of a second embodiment of a power generation system according to the present invention;

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

As shown in FIG. 1, the power generation system 1 according to the present invention includes a hydraulic jack 10 having a head 11 for performing reciprocating motion by hydraulic pressure, and a hydraulic jack 10 connected to the hydraulic jack 10. It operates in accordance with the movement of the head portion 11 of 10) and includes a power transmission unit 100 for converting and transmitting the reciprocating motion of the head portion 11 to the rotational movement.

In addition, the power generation system 1 is connected to the main drive unit 200 and the main drive unit 200 to perform a rotary motion by the rotational force switched by the power transmission unit 100, the main drive unit 200 Further comprising a driven unit 300 for performing a rotational movement by the power received from, and a power generation device 400 is connected to the follower 300 to perform a power generation action by the rotational movement of the follower 300 do.

The hydraulic jack 10 includes the head portion 11 and a casing 12 in which the head portion 11 is reciprocally received.

In addition, the hydraulic fence 10 is preferably placed on the support (15) for a stable arrangement.

A working fluid tank 20 is provided outside the hydraulic jack 10, the working fluid tank 20 and the hydraulic jack 10 are connected by a fluid flow tube 21, and the fluid flow tube 21 is operated. A valve 22 is provided that can interrupt the flow of fluid.

The hydraulic jack 10 is provided to be spaced apart from each other in plurality, the working fluid tank 20 is connected to the plurality of hydraulic jack 10, for this purpose the fluid flow pipe 21 is also connected to each of the hydraulic jack 10. do.

The hydraulic jack 10 is driven by the principle of Pascal. Therefore, there is an advantage that can output a large output by inputting a small force.

The configuration of the power transmission unit 100 connected to the hydraulic jack 10 may be provided to reciprocate the cylinder 110 and the cylinder 110, and may contact the head 11 of each hydraulic jack 10. And a connecting rod 130 connected to the piston 120.

When the head 11 of the hydraulic jack 10 pushes the piston 120 provided in the cylinder 110, the piston 120 moves in the pushing direction.

On the other hand, the driving unit 200 is connected to the piston 120 by the connecting rod 130, the reciprocating motion of the piston 120 by the connecting rod 130 in the moving unit 200 Is converted into the rotational motion of.

The main drive unit 200 has a main drive shaft 201 having a crank shaft 210 connected to the connecting rod 130 and a rotation shaft 220 connected to both ends of the crank shaft 210.

The rotation shaft 220 has a main rotation member 230 provided in the form of a chain gear or a sprocket, and the rotation inertial body 240 is disposed separately from the main rotation member 230 to increase the rotational force of the rotation shaft 220 Is provided, the main rotating member 230 and the rotary inertia 240 also becomes a component of the main driving unit 200.

 To this end, it is preferable that a heavy inertial member 241 is provided on the outer circumference of the rotary inertial body 240.

The rotating shaft 220 is provided on both sides of the crank shaft 210, the main shaft is supported by the support bearing 250.

The crank shaft 210 and the main shaft 201 composed of the rotating shaft may be provided in one, or provided in plurality, each of the main shaft 201 is connected by the shaft connecting member 260 at the same time It may be able to rotate together.

The reason why the plurality of main shafts 201 are provided in this way is to make it easy to adjust the scale of the power generation system 1.

The quantity of the hydraulic jack 10 and the power transmission unit 100, that is, the quantity of the cylinder 110, the piston 120, the connecting rod 130 is preferably provided to be the same, and each of the crank shaft ( It is preferable that the coarse rotation member 230 and the rotary inertia 240 are respectively provided on the left and right sides of the 210.

The driven part 300 is disposed in parallel with the rotation shaft 220 of the main shaft 201, spaced apart from the predetermined interval 301 and the driven shaft 301 is disposed on the main rotating member 230 ) And a driven rotating member 330 connected by a predetermined power transmission member 290.

Here, when the main rotating member 230 is in the form of a sprocket or chain gear, the driven rotating member 330 is also preferably provided in the form of a sprocket or chain gear, the power transmission member 290 is provided in a chain It is preferable to be.

The main rotating member 230 and the driven rotating member 330 is provided with a sprocket or a chain gear, and the power transmission member 290 is provided as a chain because the power transmission is the main and driven rotating members 230 and 330. This is to ensure that based on the exact gear ratio between the ().

The driven shaft 301 is rotatably supported by support bearings 350 disposed on both sides of the driven rotating member 330, and the driven rotating member 330 is preferably provided in plurality and spaced apart from each other.

Here, the quantity of the driven rotating member 330 is preferably the same as the quantity of the main rotating member 230.

In addition, the driven shaft 301 may also be one, or may be provided in plural, when the driven shaft 301 is provided in plural, it is connected by the shaft connecting member 360 can be rotated together. It is desirable to have.

As described above, the reason why the plurality of driven shafts 301 are provided in the same manner as the reason for providing the plurality of main shafts 301 can be easily expanded and the scale of the power generation system 1 of the present invention can be easily expanded. Because.

The end of the driven shaft 301 is provided with a generator 400, the generator 400 is composed of a coil and a permanent magnet to perform power generation, the driven shaft in a magnetic field made of a permanent magnet Power generation can be performed by rotating the coil connected to the.

On the other hand, between the driven shaft 301 and the power generator 400 is preferably provided with a clutch unit 500 consisting of a clutch plate 501. The clutch unit 500 serves to selectively connect or disconnect between the driven shaft 301 and the power generator 400.

As such, the reason why the clutch part 500 is provided is that the power generation device 400 itself may act as a load of the moving part at the initial start-up of the main driving part 100. Until the rotational motion of the coaxial 301 is smooth, the clutch unit 500 is controlled to separate the driven shaft 301 and the generator 400 so that the generator 400 does not operate.

When the speed of the driven shaft 301 is greater than or equal to a predetermined level, the clutch unit 500 is controlled to connect the driven shaft 301 and the power generator 400 to achieve a power generation function.

2 illustrates a coupling relationship between the crank shaft 210 and the power transmission unit 100 in the present invention.

A coupling groove 131 is provided at an upper portion of the connecting rod 130 to be in contact with the crank pin 211 of the crank shaft 210, and a coupling cover 140 is provided at the coupling groove 131. Together with the coupling groove 131 serves to wrap the crank pin 211.

Around the coupling cover 140 and the coupling groove 131 is coupled by a fastening member 141 such as a bolt so that the crank shaft 210 is not separated.

On the other hand, the lower portion of the coupling groove 131 is provided with a straight rod portion 132, the lower end of the rod portion 132 connecting pin 160 for connecting the piston 120 and the connecting rod 130 ) Is inserted into the insertion hole 133 is provided.

The connecting pin 160 connects the connecting rod 130 and the piston 120 through the outer circumferential surface of the piston 120 and the insertion hole 133.

3 illustrates that the piston 120 connected to the connecting rod 130 is accommodated in the cylinder 110, and the head portion 11 is provided below the cylinder 110.

The edge of the casing 12 in which the head portion 11 is provided is provided to be coupled or contactable with the lower edge of the cylinder 110, and the head portion 11 is insertable into the cylinder 110. It is preferably provided to be in contact with the piston 120.

Therefore, when the head portion 11 rises, the piston 120 also rises, and thus the connecting rod 130 also rises.

As the connecting rod 130 ascends, when the upper end of the connecting rod 130 pushes up the crank shaft 210, the crank shaft 210 makes a rotational movement.

That is, the reciprocating motion of the head 11 and the piston 120 is converted to the rotational motion of the crank shaft 210.

Since the crank shaft 210 is connected to the rotating shaft 220, the rotational movement of the crank shaft 220 is the main rotating member (see Fig. 1, 230) and the rotating inertia (see Fig. 1, 240) Rotational power of.

4 (a) and (b) are connected to each other while being composed of a plurality of rotary shafts (see Fig. 1, 220) and the driven shaft (see Fig. 1, 301) of the main shaft (see Fig. 1, 201) In this case, the shaft connecting member 260 used is shown.

As shown in Figure 4 (a), when looking at the side of the shaft connecting member 260, a body portion having an insertion hole 261, the end of the rotary shaft 220 or the driven shaft 301 is inserted 262 and an adjustment screw 263 inserted into the body 262 to adjust the size of the insertion hole 261.

The adjusting screw 263 is fitted to the nut portion 264 and is fixed to the body portion 262.

The adjustment screw 263 is inserted into the extension portion 265 is extended to one side of the body portion 262 and spaced apart from each other, when the adjustment screw 263 is rotated, the interval between the extension portion 265 This adjustment can be adjusted accordingly the size of the insertion hole (261).

Therefore, when the driven shaft 301 and the rotating shaft 220 is inserted into the insertion hole 261, the adjustment screw 263 is operated to narrow the interval between the extension parts 265. As the inner diameter of the 261 is narrowed, the end of the driven shaft 301 or the end of the rotating shaft 220 can be fixed.

As shown in Figure 4 (b), both ends of the rotating shaft 220 or the driven shaft 301 is inserted into both ends of the body portion 262, the insertion hole using the adjustment screw 263. The inner diameter of the 261 is reduced to connect the rotating shafts 220 or the driven shafts 301 spaced apart from each other.

FIG. 5 shows a sprocket or chain gear constituting the main rotation member 230, a sprocket chain gear constituting the driven rotation member 330, and a chain as a power transmission member 290 connecting them. will be.

Since the rotational speed of the driven shaft 301 should be faster than the rotational speed of the main shaft 201, the diameter of the driven rotating member 330 is smaller than the diameter of the main rotating member 230, the tooth surface Also in the number of teeth of the driven rotating member 330 is preferably less than the number of teeth of the main rotating member 230.

On the other hand, the main rotary member 230 and the driven rotary member 330 is composed of a friction difference, the power transmission member may be composed of a belt such as a V belt.

FIG. 6 (a) shows that the main rotating member 230 or the driven rotating member 330 is composed of a plurality of components, not an integral type, when the sprocket or the chain gear is configured.

Here, the main rotating member 230 or the driven rotating member 330 is the body portion (231,331), the teeth (232,332) formed on the outer peripheral surface of the body portion (231,331) and the central portion of the body portion (231,331) It is formed to include a shaft hole (233,333) is fixed to the rotary shaft or the driven shaft is inserted.

In the figure, the body portions 231 and 331 are provided in a quadrant shape, but are not limited thereto.

Each component constituting the body parts 231 and 331 is coupled by fixing members 235 and 335 inserted into and fixed to the coupling parts 234 and 334 provided in the respective components.

The reason that the main rotating member 230 or the driven rotating member 330 is provided in a splitable form is for ease of storage and transportation of the component.

When the gear ratio between the main rotating member 230 and the driven rotating member 330 is increased, the diameter of the main rotating member 230 should be significantly larger than that of the driven rotating member 330.

In this case, however, when the main rotating member 230 having a large diameter is composed of an integrated chain gear or sprocket, the movement and installation difficulties may increase.

Therefore, it may be more effective in terms of installation or transportation to provide the main rotating member 230 as a plurality of components that can be assembled in consideration of this point.

6 (b) is a side perspective view of the rotational inertia.

The rotary inertia 240 has a rotary wheel 243 is formed in the center of the shaft hole 242 is inserted into the rotation shaft, and the inertia member 241 disposed on the edge and the adjacent portion of the rotary wheel 243 It includes.

The inertial member 241 is preferably made of a heavy metal such as lead or steel, or concrete.

When the rotational inertia 240 is fitted to the rotation shaft 220 to rotate by the rotational movement of the rotational shaft 220, the rotational movement of the rotational shaft 220 may occur more continuously by the inertia force.

The continuity of the rotational movement as such can eventually be shown as the continuity of the rotational movement of the driven shaft 301, which can greatly contribute to increasing the amount of power generated by the power generator.

Figure 7 shows another embodiment of the present invention.

Here, the difference between the first embodiment shown in Figure 7 and Figure 1 is that the follower 300 is composed of a plurality.

The generator 400 is also connected to the driven shafts 1301 and 2301 of each follower 300.

Since the structure of the main body 200 and the hydraulic jack 10 in Figure 7 is the same as the first embodiment shown in Figure 1 will be omitted a detailed description.

Meanwhile, the follower 300 includes a first follower 1300 connected to the main drive 200, and a second follower 2300 connected to the first follower 1300.

Here, the first follower 1300 is provided on the first follower 1301 and the first follower 1301 and is connected to the main rotating member 230 by the power transmission member 290. A first driven rotating member 1330, an intermediate rotating member 1500 connected to the second driven part 2300, and a first support bearing 1350 supporting the first driven shaft 1301. do.

The first driven rotating member 1330 is preferably provided separately from the intermediate rotating member 1500.

The first power generator 1400 is connected to the first driven shaft 1301 to perform a power generation function according to the rotation of the first driven shaft 1301.

On the other hand, the second follower 2300 is provided on the second follower 2301 and the second follower 2301 and is connected by the intermediate rotating member 1500 and the power transmission member 1290. A second driven rotating member 2330 and a second support bearing 2350 for supporting the second driven shaft 2301 are included.

The second power generator 2400 is connected to an end of the second driven shaft 2301 to perform a power generation function by the rotation of the second driven shaft 2301.

Here, when the first and second driven rotating members (1330, 2330) and the intermediate rotating member (1500) is composed of a chain gear or a sprocket, the power transmission members (290, 1290) is preferably composed of a chain. .

On the other hand, when the first and second driven rotating members (1330, 2330) and the intermediate rotating member 1500 is composed of a friction difference, the power transmission members (290, 1290) is preferably composed of a belt.

As such, the reason why the plurality of driven parts 300 and the power generating device 400 are provided is to obtain more power generation using one main moving part.

To this end, the main rotating member 230, the first and second driven rotating members (1330, 2330), the diameter of the main rotating member 230 is the largest, and the first driven rotating member (1330) in the center And, it is preferable that the diameter of the second driven rotary member 2330 is the smallest.

Accordingly, the main rotating member 230 has a larger gear ratio than the first driven rotating member 1330, and the first driven rotating member 1330 has a larger gear ratio than the second driven rotating member 2330. It is preferable.

Meanwhile, the first and second driven shafts 1301 and 2301 are also provided in plural, and each of the separated first and second driven shafts 1301 and 2301 is connected by the shaft connecting member 260, thereby Scale can be easily scaled up.

Hereinafter, an operation of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, when the head portion 11 of the hydraulic jack 10 moves, the piston 120 also moves in accordance with the movement, thereby rotating the crank shaft 210.

At this time, a plurality of the hydraulic jack 10 is provided, and in a state in which they are spaced apart from each other, before performing the power generation function, the head portion of all the hydraulic jack is accommodated in the hydraulic jack housing, all the piston is located at the bottom dead center in the cylinder. do.

In this figure, four hydraulic jacks, a power transmission unit, and a crankshaft are provided, respectively.

That is, the leftmost of the hydraulic jack 10, the power transmission unit 100, the crankshaft 210 are called hydraulic jack 1, power transmission unit 1, crankshaft 1, the hydraulic jack on the rightmost, Let the power train and crankshafts be the 4 hydraulic jacks, the 4 power trains and the 4 crankshafts, respectively.

Then, when the power generation operation is started, first, the head 11 of the 1st and 4th hydraulic jacks rises, and the 1st and 4th power transmission units 100 contacting the heads 11 of the 1st and 4th hydraulic jacks. Push up the piston (120) provided in the).

Then, the piston 120 of the first and fourth power transmission unit 100 moves from the bottom dead center to the top dead center, so that the first and fourth crankshaft 120 rotates upwards, and the rotary shaft 220 ) Rotate.

At this time, just before the piston 120 of the first and fourth power transmission unit 100 reaches the top dead center, the head portion 11 of the first and fourth hydraulic jacks 10 moves downward, and at the same time the The second and third heads 10 move upward to push the pistons 120 of the second and third power transmission units 100.

And, the piston 120 of the power transmission unit 100, the second and third move to the top dead center at the bottom dead center, the second and third crankshaft 210 also moves to the upper, the rotary shaft 220 continuously Rotate).

Then, just before the piston 120 of the 2nd and 3rd power transmission units 100 reaches the top dead center, the head 11 of the 2nd and 3rd hydraulic jacks 10 moves downward, and at the same time the 1 The fourth head 11 moves upward, pushing up the piston 120 of the first and fourth power transmission units 100.

like this. Reciprocating motion of the head portion 11 and the piston 120 of the hydraulic jack 10 and reciprocating motion of the head portion 11 and the piston 120 of the other hydraulic jack 10 occur alternately to form the rotary shaft 220 and The main rotating member 230 and the rotary inertia 240 provided on the rotary shaft 220 are rotated.

Since the main rotating member 230 is connected by the driven rotating member 330 and the power transmission member 290 such as a chain or belt, the rotational movement of the main rotating member 240 is driven by the driven rotating member ( Induces a rotational movement of 330, and accordingly also rotates the driven shaft 301.

On the other hand, the diameter of the main rotating member 230 is formed to be significantly larger than the diameter between the driven rotating member 330, or a large gear ratio between the main rotating member 230 and the driven rotating member 330 is formed. desirable.

When the diameter ratio or gear ratio is formed in this way, the rotation speed of the driven rotation member 330 becomes significantly larger than the rotation speed of the main rotation member 230.

On the other hand, in order to reduce the load on the main drive unit 200 to control the clutch unit 500 between the driven shaft 301 and the power generator 400 connected to the driven shaft 301 in the initial state of the rotary motion The connection between the power generator 400 and the driven shaft 301 is released.

As such, when the rotational speed of the driven shaft 301 reaches a predetermined level in a state in which the connection relationship between the driven shaft 301 and the power generator 400 is released, the clutch 500 is controlled to control the driven shaft. 301 and the power generator 400 is connected.

By such a connection, the coil or the lead portion inside the power generator 400 is connected to the driven shaft 301, and the rotation of the driven shaft 301 causes the coil or the conductive wire to rotate, thereby producing electricity. Can be.

Meanwhile, the operation of the second embodiment will be described.

Since the configuration and operation of the main body 200 in the second embodiment is the same as the configuration of the first embodiment, description thereof will be omitted.

On the other hand, the follower 300 is composed of a first follower 1300 and a second follower 2300, the first follower 1301 and the second follower 2301 are first and second clutches, respectively. The first and second power generation apparatuses 1400 and 2400 are connected by the units 1500 and 2500.

In the initial rotational motion state, the first and second clutch units 1500 and 2500 separate the first and second driven shafts 1301 and 2301 from the first and second power generators 1400 and 2400, respectively.

In this state, when the main driving unit 200 operates, the first driven rotating member 1330 is rotated by the main rotating member 230, and the first driven shaft 1301 and the intermediate rotating member 1600 are rotated. Rotate).

In addition, the rotational movement of the intermediate rotating member 1600 rotates the second driven rotating member 2330 connected by the intermediate rotating member 1600 and the power transmission member 290 such as a chain or a belt. Induces rotational movement of the driven shaft 2301.

When the rotational speeds of the first and second driven shafts 1301 and 2301 reach a predetermined level, the first and second clutch units 1500 and 2500 are controlled to control the first and second power generators 1400 and 2400. Are connected to the first and second driven shafts 1301 and 2301, respectively, to perform a power generation function.

10: hydraulic jack 11: head part
100: power transmission unit 110: cylinder
120: piston 130: connecting rod
200: main shaft 201: main shaft
210: crack axis 220: rotation axis
230: main rotating member 240: rotary inertia
300: driven part 301: driven shaft
330: driven rotary member 400: generator

Claims (10)

A fluid flow tube 21 having a movable fluid received therein and having a valve 22 connected to one side thereof, and having a device composed of a prime mover provided to selectively discharge or move the movable fluid to the outside. With the tank 20,
A plurality of hydraulic jacks having a head 11 for performing a reciprocating motion by the hydraulic pressure of the fluid discharged from the fluid tank 20 and a casing 12 in which the head 11 is reciprocally received. 10;
The piston is connected to the hydraulic jack 10 and operates in accordance with the movement of the hydraulic jack 10, the piston in contact with the head portion 11 to convert the reciprocating motion of the hydraulic jack head 11 into a rotational movement ( A power transmission unit (100) including a cylinder (110) for receiving the piston (120) and connected to the hydraulic jack (10), and a connecting rod (130) connected to the piston (120);
A main shaft including a crank shaft 210 connected to the power transmission unit 100 and a rotating shaft 220 connected to the crank shaft 210 to perform a rotational movement ( 201) and a main drive part 200 including a main rotational member 230 provided on the main drive shaft 201 and implemented with gears or sprockets having teeth.
Gear that is connected to the driven shaft 301 consisting of a rotating shaft, the power transmission member 290 is installed on the driven shaft 301 and the main rotating member 230 and the chain of the main drive part 200 Or a driven part 300 including a driven rotating member 330 implemented as a sprocket and performing a rotating motion;
The power generation system characterized in that it comprises a power generation device 400 is connected by the driven part 300 and the clutch unit 500 to generate power by the rotational movement of the driven part 300. delete The method of claim 1,
The main moving part 200 is
The power generation system, characterized in that it further comprises a rotary inertia (240) installed on the rotary shaft 220 to increase the rotational inertia of the rotary shaft (220). The method of claim 3,
The rotational inertia (240) is provided with an inertial member (241) for increasing the rotational inertia, the inertial member (241) characterized in that consisting of concrete or metal. The method of claim 3,
The rotating shaft 220 is provided in plurality,
Each rotary shaft 220 is provided with the rotary inertia 240 and the main rotary member 230,
Each rotary shaft 220 is connected to the shaft connecting member 260 which is mounted at both ends thereof to connect the respective rotary shaft 220,
The shaft connecting member 260 is
Body portion 262 having an insertion hole (261) is inserted into the end of the rotating shaft 220, and adjustment screw 263 that is inserted into the body portion 262 to adjust the size of the insertion hole (261). ),
The adjustment screw 263 is fitted to the nut portion 264 is fixed to the body portion 262,
The adjustment screw 263 is inserted into the extension portion 265 is extended to one side of the body portion 262 and spaced apart from each other, when the adjustment screw 263 is rotated, the interval between the extension portion 265 This adjustment is characterized in that the size of the insertion hole (261) can also be adjusted accordingly. delete delete delete The method of claim 1,
Chain gears constituting the main rotation member 230 and the driven rotation member 330 are provided to be divided into a plurality of body parts (231, 331) and the teeth (232, 332) are formed on the outer peripheral surface and ;
Shaft holes (233,333) formed in the center of the body portion (231,331) is fixed to the rotary shaft 220 or the driven shaft 301 is inserted,
And fastening members 235 and 245 for fastening the plurality of body parts 331 which are divided from each other.
The fastening member (235, 245) is a power generation system, characterized in that the coupling is inserted into the fastening portion (234,334) provided in the body portion (231, 331). The method of claim 1,
The follower 300 includes a first follower 1300 and a second follower 2300,
The power generator 400 includes a first power generator 1400 connected to the first follower 1300 and a second power generator 2400 connected to the second follower 2300,
The first driven part 1300 is provided on a first driven shaft 1301, the first driven shaft 1301, and a first driven rotating member 1330 in the form of a chain gear or sprocket, and the first driven rotation. It is provided separately from the member 1330 and includes an intermediate rotating member 1600 in the form of a chain gear or sprocket,
The second driven part 2300 includes a second driven shaft 2301 and a second driven rotating member 2330 connected by the intermediate rotating member 1600 and a chain-type power transmission member 1290. ,
The clutch unit 500 includes a first clutch unit 1500 for selectively connecting the first power generator 1400 and the first driven shaft 1301, the second power generator 2400, and the second power generator 1400. And a second clutch part (2500) for selectively connecting the driven shaft (2301).

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