KR102140666B1 - Power generator and operation method thereof including multistage accumulators - Google Patents

Abstract

The present invention relates to a power generating device including a multi-stage accumulator, and a method of operating the same, and more specifically, to a power generating device including two or more multi-stage accumulators which are connected in series with each other, and a method of operating the same. The present invention includes a hydraulic system, and an air compressor for storing compressed air.

Description

Power generator and operation method including a multi-stage accumulator and a multistage accumulators thereof

The proposed technology relates to a power generating device including a multi-stage accumulator and a driving method thereof, and more particularly, to an invention relating to a power generating device including two or more multi-stage accumulators connected in series with each other and a driving method thereof.

In general, in the case of a hydraulic system that requires an instantaneous high power, it is driven by being supplied with power from a power generating device including an accumulator and a hydraulic power unit (HPU) for charging the accumulator.

When power is supplied to the hydraulic system using only the hydraulic power unit, it is not efficient in terms of size or cost compared to an accumulator when an instantaneous large force is required because the size must be quite large in order to instantaneously generate high power.

When power is supplied to the hydraulic system using only the accumulator, a large volume can be generated even with a small volume because hydraulic pressure can be released at a high pressure for a very fast time due to an inert gas compressed at a high pressure. However, since the accumulator can no longer supply power when all the hydraulic oil stored therein is released, it is very disadvantageous in terms of sustainability compared to the hydraulic power device.

Therefore, when power is supplied to the hydraulic system using the accumulator, the accumulator must be periodically recharged, and for this reason, as shown in FIG. 1, the hydraulic system using the accumulator 50 as a power source. In the case of (42), a high power accumulator and a small hydraulic power unit 48 are provided together, and the accumulator 50 is frequently charged and used.

In the case of the power generator configured as described above, it brings a lot of spatial/economical benefits, but it takes a long time to recharge the accumulator after exhausting the accumulator, and in the case of a small hydraulic power unit, noise and vibration Because of this very large size, there is a problem in that a separate device must be configured to shield noise and vibration.

Korean Patent Publication No. 10-2014-0090625

The present invention was invented to solve the above problems, and compared to a conventional power generator including a single accumulator and a hydraulic power unit by constructing a power generator including two or more multi-stage accumulators connected in series with each other. The purpose is to shorten the charging time of the accumulator and to solve noise and vibration problems.

In the power generating apparatus including the multi-stage accumulator of the present invention for achieving the above object,

Includes two or more multi-stage accumulators connected in series with each other,

A pressure transmission fluid that delivers pressure to a hydraulic oil filled in one of the multi-stage accumulators is characterized by receiving pressure from the air charged in the other accumulator.

Of the multi-stage accumulators, the highest stage accumulator,

A first filling part in which air is filled; And a second filling part filled with the pressure transmission fluid and receiving pressure from the first filling part.

Of the multi-stage accumulators, the last one is

A third filling part in which the pressure transmission fluid is filled; And it is characterized in that it comprises; and a hydraulic oil is filled, the fourth filling portion receiving the pressure from the third filling portion.

The pressure transmission fluid is characterized by being an inert gas.

The pressure transmission fluid is characterized by being a non-flammable liquid.

It is characterized in that the second filling part of the highest-stage accumulator among the multi-stage accumulators and the third filling part of the last-stage accumulator among the multi-stage accumulators are connected by a pressure transmission fluid supply pipe.

It characterized in that the pressure transmission fluid supply pipe is provided with a shut-off valve for opening and closing the pressure transmission fluid supply pipe.

The first filling part is characterized in that the air supplied from the air compressor is filled.

The air supply pipe connecting the first filling unit and the air compressor is provided with a shut-off valve for opening and closing the air supply pipe.

The hydraulic pressure of the hydraulic oil is characterized in that it is the power transmitted to the hydraulic system.

A hydraulic system connecting port connecting the fourth filling part and the hydraulic system is characterized in that a shut-off valve for opening and closing the hydraulic system connecting port is provided.

The first filling part is characterized in that a safety valve is provided for discharging the air filled therein to the outside when the internal pressure increases due to an increase in the external temperature.

The third filling part is characterized in that a safety valve is provided for discharging the pressure transmission fluid filled therein to the outside when the internal pressure increases due to an increase in the external temperature.

The first filling portion is characterized in that an air outlet for discharging the air inside the first filling portion to the atmosphere is formed.

It characterized in that the air outlet is provided with a shut-off valve for opening and closing the air outlet.

Each of the second filling part of the highest accumulator among the multi-stage accumulators and the third filling part of the last accumulator among the multi-stage accumulators is characterized in that a pressure transmission fluid filling port for discharging or filling the pressure transmission fluid is formed. .

The fourth filling portion is characterized in that a hydraulic oil filling port for discharging or filling the hydraulic oil is formed.

It is characterized in that each of the uppermost accumulator and the last accumulator constituting the multi-stage accumulator is provided with a sensor unit that detects an internal state and whether it is damaged.

In the driving method of the power generating apparatus including the multi-stage accumulator of the present invention for achieving the above object,

A step in which the hydraulic oil inside the multi-stage accumulator is formed as the operating pressure of the hydraulic system;

A step in which hydraulic oil is supplied to the hydraulic system;

Step of reducing the pressure of the hydraulic oil filled in the multi-stage accumulator;

The operation of the hydraulic system is completed;

A step in which residual hydraulic oil in the hydraulic system flows into the multi-stage accumulator;

The step of re-forming the pressure of the hydraulic oil filled in the multi-stage accumulator.

The stage in which the hydraulic oil is supplied to the hydraulic system,

A step in which a shut-off valve provided in a hydraulic system connecting port connecting the hydraulic system and the fourth filling part of the last stage accumulator in which the hydraulic oil is filled among the multi-stage accumulator is opened;

It characterized in that it comprises; a step of supplying the hydraulic oil inside the fourth filling portion to the hydraulic system along the hydraulic system connector.

The step of reducing the pressure of the hydraulic oil filled in the multi-stage accumulator,

A step in which the internal pressure of the fourth filling part of the last stage accumulator of the multi-stage accumulator decreases;

Reducing the internal pressure of the third filling part of the last accumulator transferring the pressure to the fourth filling part;

A step in which the pressure transmission fluid filled in the second filling part of the uppermost accumulator connected to the third filling part of the multi-stage accumulator is supplied to the third filling part;

Reducing the internal pressure of the second filling part;

It characterized in that it comprises a; reducing the internal pressure of the first filling portion of the uppermost accumulator to transfer the pressure to the second filling portion while the internal pressure of the second filling portion decreases.

In the step of supplying the pressure transfer fluid filled in the second filling portion to the third filling portion,

The shut-off valve provided in the pressure transmission fluid supply pipe connecting the second filling part and the third filling part is characterized in that it is opened.

After the step of reducing the internal pressure of the first filling part of the foremost accumulator,

The internal pressure of the first filling portion, the second filling portion, the third filling portion, and the fourth filling portion is higher than atmospheric pressure.

The step of introducing residual hydraulic oil inside the hydraulic system into the multi-stage accumulator,

A step in which the air discharge port formed in the first filling part of the uppermost accumulator among the multi-stage accumulators is opened to discharge the air inside the first filling part into the atmosphere;

A step in which the internal pressures of the first and second filling sections of the uppermost accumulator and the third and fourth filling parts of the last accumulator among the multi-stage accumulators are equal to atmospheric pressure;

A step in which hydraulic oil remaining inside the hydraulic system flows into the fourth filling portion along the hydraulic system connector by the internal pressure of the hydraulic system higher than atmospheric pressure;

The air outlet is closed;

A step in which the internal pressures of the first filling part, the second filling part, the third filling part and the fourth filling part become equal to the internal pressure of the hydraulic system;

It characterized in that it comprises a; step of closing the shut-off valve provided on the hydraulic system connector.

The step in which the internal pressure of the first filling part, the second filling part, the third filling part and the fourth filling part becomes equal to the atmospheric pressure,

A step in which the internal pressure of the first filling portion decreases and becomes equal to atmospheric pressure;

A step in which the internal pressure of the second filling portion decreases and becomes equal to the atmospheric pressure by the pressure balance of the first filling portion and the second filling portion;

The pressure transfer fluid of the third filling portion is transferred to the second filling portion along the pressure transmission fluid supply pipe;

A step in which the internal pressure of the third filling portion decreases and becomes equal to atmospheric pressure;

And a step in which the internal pressure of the fourth filling part decreases and becomes equal to the atmospheric pressure by the pressure balance of the third filling part and the fourth filling part.

The step in which the internal pressure of the first filling part, the second filling part, the third filling part and the fourth filling part becomes equal to the internal pressure of the hydraulic system,

A step in which the internal pressure of the fourth filling portion rises and becomes equal to the internal pressure of the hydraulic system;

The pressure transfer fluid of the third filling portion is transferred to the second filling portion along the pressure transmission fluid supply pipe by the pressure balance of the fourth filling portion and the third filling portion;

A step in which the internal pressures of the second filling part and the third filling part rise and become equal to the internal pressure of the hydraulic system;

It characterized in that it comprises; a step of equalizing the internal pressure of the hydraulic system by increasing the internal pressure of the first filling part by the pressure balance of the second filling part and the first filling part.

The step of reforming the pressure of the hydraulic oil filled in the multi-stage accumulator,

A step in which a shut-off valve that opens and closes an air supply pipe connecting the first filling part of the uppermost accumulator among the multi-stage accumulators and the air compressor is opened;

Step of introducing air from the air compressor to the first filling unit;

A step in which the internal pressures of the first filling part and the second filling part of the uppermost accumulator among the multi-stage accumulators and the third filling part and the fourth filling part of the last accumulator among the multi-stage accumulators are equal to the internal pressure of the air compressor;

It characterized in that it comprises a; step of closing the shut-off valve to open and close the air supply pipe.

The step in which the internal pressure of the first filling part, the second filling part, the third filling part, and the fourth filling part becomes equal to the internal pressure of the air compressor,

A step in which the internal pressure of the first filling part rises and becomes equal to the internal pressure of the air compressor;

A step in which the internal pressure of the second filling part rises by the pressure balance of the first filling part and the second filling part to become equal to the internal pressure of the air compressor;

The pressure transmission fluid of the second filling unit is transferred to the third filling unit along the pressure transmission fluid supply pipe;

A step in which the internal pressure of the third filling part rises and becomes equal to the internal pressure of the air compressor;

It characterized in that it comprises; a step of equalizing the internal pressure of the air compressor by increasing the internal pressure of the fourth filling part by the pressure balance of the third filling part and the fourth filling part.

According to the present invention, by constructing a power generator including two or more multi-stage accumulators connected in series with each other, the charging time of the accumulator is shortened and noise and noise are reduced compared to a conventional power generator including a single accumulator and a hydraulic power unit. It has the effect of solving the vibration problem.

1 is a schematic diagram of a conventional power generator.
2 is a schematic diagram of a power generating device according to the present invention.
3 is a schematic diagram of a multi-stage accumulator according to the present invention.
Figure 4 is a schematic diagram of the state of the multi-stage accumulator after power transmission from the power generator according to the present invention to the hydraulic system.
5 is a first state schematic diagram of a multi-stage accumulator after the operation of the hydraulic system according to the present invention is completed.
6 is a schematic view of a second state of a multi-stage accumulator after the operation of the hydraulic system according to the present invention is completed.
7 is a schematic diagram of a state of a multi-stage accumulator when supplying air from an air compressor according to the present invention.

The above-described features and effects of the present invention will become more apparent through the following detailed description in connection with the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention. Will be able to. The present invention can be applied to various changes and may have various forms, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, it is not intended to limit the present invention to a specific disclosure form, and it should be understood that all modifications, equivalents, and substitutes included in the spirit and scope of the present invention are included. The terminology used in the present application is only for describing specific embodiments and is not intended to limit the present invention.

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

The present invention relates to a power generating device including a multi-stage accumulator and a driving method thereof, and more particularly, to a power generating device including two or more multi-stage accumulators connected in series with each other and a driving method thereof.

2 is a schematic diagram of a power generating device according to the present invention.

The power generating device of the present invention for supplying power to a hydraulic system that operates using hydraulic power, includes two or more multi-stage accumulators connected in series with each other, and hydraulic oil filled in any one of the multi-stage accumulators The pressure transmission fluid that transmits pressure to the air receives pressure from the air charged in the other accumulator.

3 is a schematic diagram of a multi-stage accumulator according to the present invention.

The multi-stage accumulator comprises a top-end accumulator 2 and a bottom-end accumulator 18.

The uppermost accumulator 2 comprises a first filling part 4 filled with the air and a second filling part 12 filled with the pressure transmission fluid and receiving pressure from the first filling part 4. Including.

The last stage accumulator 18 includes a third filling part 20 in which the pressure transmission fluid is filled, and a fourth filling part 26 in which the hydraulic oil is filled and receiving pressure from the third filling part 20. Including.

Air supplied from the air compressor 36 is filled in the first filling part 4. In order to make the filling of the second filling part 12 faster, the air compressor 36 may be replaced with an air tank that stores compressed air in advance.

The air supply pipe 38 connecting the first filling part 4 and the air compressor 36 is provided with a shutoff valve 40 for opening and closing the air supply pipe 38.

When the shut-off valve 40 provided in the air supply pipe 38 is opened, the air of the air compressor 36 moves to the first filling part 4.

The air filled in the first filling part 4 applies pressure to the pressure transmission fluid filled in the second filling part 12.

The second filling portion 12 and the third filling portion 20 are connected by a pressure transmission fluid supply pipe 32, and the pressure transmission fluid supply pipe 32 opens and closes the pressure transmission fluid supply pipe 32 A shut-off valve 34 is provided.

The pressure transmission fluid is movable in both directions inside the pressure transmission fluid supply pipe 32, and the second filling part 12 according to the opening direction of the shutoff valve 34 provided in the pressure transmission fluid supply pipe 32 The internal pressure transmission fluid is moved to the third filling portion 20 through the pressure transmission fluid supply pipe 32 or the pressure transmission fluid inside the third filling portion 20 is the pressure transmission fluid supply pipe 32 Through this, it is moved to the second filling part 12.

In addition, when the shut-off valve 34 provided in the pressure transmission fluid supply pipe 32 is closed, the movement of the pressure transmission fluid between the second filling part 12 and the third filling part 20 is made. Do not lose.

The pressure transmission fluid filled inside the third filling portion 20 applies pressure to the hydraulic oil filled in the fourth filling portion 26.

The hydraulic pressure of the hydraulic oil filled in the fourth filling portion 26 becomes power transmitted to the hydraulic system 42.

The hydraulic system connection port 44 connecting the fourth filling part 26 and the hydraulic system 42 is provided with a shut-off valve 46 for opening and closing the hydraulic system connection port 44.

The hydraulic oil is movable in both directions inside the hydraulic system connector 44, and the hydraulic oil inside the fourth filling part 26 according to the opening direction of the shut-off valve 46 provided in the hydraulic system connector 44. A is moved to the hydraulic system 42 through the hydraulic system connector 44, or the hydraulic oil inside the hydraulic system 42 is moved to the fourth filling part 26 through the hydraulic system connector 44 Is done.

In addition, when the shut-off valve 46 provided in the hydraulic system connection port 44 is closed, the movement of the hydraulic oil between the hydraulic system 42 and the fourth filling portion 26 is not made.

The first filling part 4 is provided with a safety valve 6. The safety valve 6 provided in the first filling part 4 is opened when the internal pressure of the first filling part 4 increases to a predetermined pressure or more due to an increase in external temperature. The air filled in the interior of the part 4 is discharged to the outside.

In addition, an air outlet 8 for discharging the air inside the first fill portion 4 to the atmosphere is formed in the first filling portion 4, and the air outlet 8 is provided in the air outlet 8. ) Is provided with a shut-off valve (10) for opening and closing.

When it is necessary to discharge the air filled in the first filling part 4 during the operation of the power generator, the shutoff valve 10 provided in the air outlet 8 is opened to discharge the air.

Each of the second filling part 12 and the third filling part 20 has the pressure transmission fluid inside the second filling part 12 and the third filling part 20 during operation of the power generating device. Or a pressure transmission fluid filling port 14 or 24 for discharging the pressure transmission fluid from the second filling part 12 and the third filling part 20 to the outside.

The third filling part 20 is provided with a safety valve 22, the safety valve 22 provided in the third filling part 20, and a safety valve 22 provided in the first filling part 4 As in the case of ), when the internal pressure of the third filling part 20 increases above a certain pressure due to an increase in the external temperature, it becomes an open state and the pressure transmission fluid filled inside the third filling part 20 is external. Is discharged.

A hydraulic oil filling port 28 for discharging or filling the hydraulic oil is formed in the fourth filling part 26.

Each of the foremost accumulator (2) and the foremost accumulator (18) has a sensor unit (16) for detecting the internal state and damage of the foremost accumulator (2) and the last accumulator (18). 3) is provided.

The pressure transmission fluid may be an inert gas or a non-flammable liquid.

Various types, such as a piston, a bladder, and a corrugation membrane, may be used as the uppermost accumulator 2 and the lastmost accumulator 18.

Hereinafter, an operation method of the power generator of the present invention described above will be described.

The driving method of the power generator of the present invention,

A step in which the hydraulic oil inside the accumulator is formed with the operating pressure of the hydraulic system (42);

Supplying the hydraulic oil to the hydraulic system 42;

The pressure of the hydraulic oil filled in the accumulator is lowered;

The operation of the hydraulic system 42 is completed;

A step in which residual hydraulic oil inside the hydraulic system 42 is introduced into the accumulator;

And the step of re-forming the pressure of the hydraulic oil filled in the accumulator.

First, the hydraulic oil inside the fourth filling portion 26 maintains a state formed by the operating pressure of the hydraulic system 42, and when a power supply signal to the hydraulic system 42 occurs, the hydraulic oil is transferred to the hydraulic system 42. Is supplied.

The step in which the hydraulic oil is supplied to the hydraulic system 42 is shown in FIG. 2, first, the shut-off valve 46 provided in the hydraulic system connection port 44 is opened, and the shut-off valve 46 According to the opening of the hydraulic oil inside the fourth filling portion 26 is supplied to the hydraulic system 42 along the hydraulic system connector (44).

4 shows a state schematic diagram of a multi-stage accumulator after power transmission from the power generator according to the present invention to a hydraulic system.

When the hydraulic oil filled in the fourth filling part 26 is supplied to the hydraulic system 42, the pressure inside the fourth filling part 26 is reduced.

The fourth filling part 26 and the third filling part 20 form a pressure balance, and the pressure is transmitted to the fourth filling part 26 according to a decrease in the internal pressure of the fourth filling part 26. The internal pressure of the third filling portion 20 is reduced.

At this time, the shutoff valve 34 provided in the pressure transmission fluid supply pipe 32 is opened, and the pressure transmission fluid filled in the second filling part 12 is supplied to the third filling part 20.

As the pressure transmission fluid filled in the second filling part 12 is supplied to the third filling part 20, the internal pressure of the second filling part 12 decreases, and the second filling part ( As the internal pressure of 12) decreases, the internal pressure of the first filling portion 4 forming a pressure balance with the second filling portion 12 also decreases.

After the step of reducing the internal pressure of the first filling part 4, the first filling part 4, the second filling part 12, the third filling part 20 and the fourth filling part ( The internal pressure of 26) is maintained above atmospheric pressure.

5 is a schematic diagram of a first state of a multi-stage accumulator after the operation of the hydraulic system according to the present invention is completed.

When the operation of the hydraulic system 42 is completed according to the above steps, a step in which residual hydraulic oil inside the hydraulic system 42 is introduced into the accumulator.

First, the shut-off valve 10 of the air outlet 8 is in an open state, and the air inside the first filling part 4 is discharged into the atmosphere along the air outlet 8.

The first filling part 4, which was maintained at a state higher than atmospheric pressure, has an internal pressure equal to atmospheric pressure because the internal pressure decreases as the air outlet 8 communicates with the atmosphere.

The pressure of the first filling part 4 and the second filling part 12 decreases the internal pressure of the second filling part 12, and accordingly, provided in the pressure transmission fluid supply pipe 32 As the shut-off valve 34 is opened, the pressure transmission fluid that has been filled in the third filling portion 20 is supplied to the second filling portion 12 so that the internal pressure of the second filling portion 12 is equal to atmospheric pressure. Becomes

As the pressure transmission fluid stored in the third filling part 20 is supplied to the second filling part 12, the internal pressure of the third filling part 20 decreases and the third filling part 20 ), the internal pressure becomes equal to the atmospheric pressure.

The pressure of the third filling part 20 and the fourth filling part 26 decreases the internal pressure of the fourth filling part 26 so that the internal pressure of the fourth filling part 26 also increases with atmospheric pressure. It becomes the same.

As described above, when the internal pressures of the uppermost accumulator 2 and the lowermost accumulator 18 become equal to atmospheric pressure, the hydraulic system by the internal pressure of the hydraulic system 42 having a pressure higher than atmospheric pressure ( 42) The hydraulic oil remaining inside flows into the fourth filling part 26 along the hydraulic system connector 44.

6 is a schematic diagram of a second state of a multi-stage accumulator after the operation of the hydraulic system according to the present invention is completed.

When the hydraulic oil remaining inside the hydraulic system 42 completely flows into the fourth filling part 26, the shut-off valve 10 provided in the air outlet 8 is changed to a closed state to fill the first filling. The connection between the part 4 and the atmosphere is blocked.

As the shut-off valve 10 provided in the air outlet 8 is closed, the internal pressure of the fourth filling part 26 rises to become equal to the internal pressure of the hydraulic system 42.

When the pressure of the fourth filling part 26 rises, the internal pressure of the third filling part 20 also increases due to the pressure balance between the fourth filling part 26 and the third filling part 20, The internal pressure of the hydraulic system 42 becomes the same, and as the internal pressure of the third filling part 20 rises, the pressure transmission fluid filled inside the third filling part 20 becomes the second. It is transferred to the filling part 12.

As the pressure transmission fluid of the third filling part 20 is transmitted to the second filling part 12, the internal pressure of the second filling part 12 also rises and the internal pressure of the hydraulic system 42 increases. It becomes the same, and the internal pressure of the first filling part 4 also rises by the pressure balance between the second filling part 12 and the first filling part 4, thereby increasing the internal pressure of the hydraulic system 42. And become the same.

When the internal pressure of the first filling part 4 becomes equal to the internal pressure of the hydraulic system 42, the shut-off valve 46 provided in the hydraulic system connection port 44 is changed to the closed state, and the hydraulic system 42 ) To prevent the movement of hydraulic oil delivered to the fourth filling part 26.

When the shut-off valve 46 provided in the hydraulic system connection port 44 is changed to the closed state, the pressure of the hydraulic oil filled in the accumulator is reformed.

7 shows a state schematic diagram of a multi-stage accumulator when supplying air from the air compressor according to the present invention.

In order to re-form the pressure of the hydraulic oil filled in the accumulator, first change the shut-off valve 40 provided in the air supply pipe 38 to the open state so that the air inside the air compressor 36 is the first Let it flow into the filling portion (4).

When the air inside the air compressor 36 flows into the first filling part 4, the internal pressure of the first filling part 4 rises and becomes the same as the internal pressure of the air compressor 36.

The pressure of the first filling part 4 and the second filling part 12 also increases the internal pressure of the second filling part 12 and becomes equal to the internal pressure of the air compressor 36.

As the internal pressure of the second filling part 12 rises, the pressure transmission fluid filled in the second filling part 12 is transferred to the third filling part 20.

The third filling part 20 receiving the pressure transmission fluid from the second filling part 12 has an internal pressure rising and becomes equal to the internal pressure of the air compressor 36.

The pressure of the third filling part 20 and the fourth filling part 26 also increases the internal pressure of the fourth filling part 26 and becomes equal to the internal pressure of the air compressor 36.

When the internal pressure of the fourth filling part 26 becomes equal to the internal pressure of the air compressor 36, the shut-off valve 40 that opens and closes the air supply pipe 38 is changed to a closed state. 4 The pressure of the hydraulic oil filled in the filling part 26 becomes the operating pressure of the hydraulic system 42.

In the detailed description of the present invention described above, it has been described with reference to preferred embodiments of the present invention, but those skilled in the art or those skilled in the art will appreciate the spirit of the present invention as set forth in the claims below. And it will be understood that various modifications and changes of the present invention can be made without departing from the technical field.

2: best stage accumulator
4: 1st filling part
6: Safety valve of the first filling part
8: Air outlet
10: Shut-off valve at the air outlet
12: 2nd filling part
14: pressure transmission fluid filling port of the second filling part
16: sensor part of the highest-stage accumulator
18: last stage accumulator
20: third filling unit
22: safety valve of the third filling part
24: pressure transfer fluid filling port of the third filling section
26: 4th filling part
28: hydraulic oil filling
30: sensor part of the last accumulator
32: pressure transmission fluid supply pipe
34: Shut-off valve of the pressure transmission fluid supply pipe
36: air compressor
38: air supply pipe
40: shutoff valve of the air supply pipe
42: hydraulic system
44: Hydraulic system connector
46: Shut-off valve of hydraulic system connection
48: hydraulic power unit
50: conventional accumulator

Claims (28)

Hydraulic system; and
An air compressor that stores compressed air; And
In the power generating device for supplying power to the hydraulic system,
Between the hydraulic system and the air compressor includes two or more multi-stage accumulator,
The multi-stage accumulator includes a top-end accumulator and a bottom-end accumulator connected in series with the top-end accumulator,
The uppermost accumulator includes a first filling part filled with the compressed air and a second filling part filled with a pressure transmission fluid and receiving pressure from the first filling part,
The last stage accumulator includes a third filling part filled with the pressure transfer fluid, and a fourth filling part filled with hydraulic oil and receiving pressure from the third filling part,
When the hydraulic fluid of the fourth filling part is supplied to the hydraulic system and the operation of the hydraulic system is completed, the compressed air of the first filling part is discharged into the atmosphere, and the internal pressure of the first to fourth filling parts becomes equal to atmospheric pressure. Power generating device comprising a multi-stage accumulator, characterized in that. delete delete According to claim 1,
The pressure transmission fluid is a power generating device comprising a multi-stage accumulator, characterized in that the inert gas. According to claim 1,
The pressure transmission fluid is a non-flammable liquid power generating device comprising a multi-stage accumulator. According to claim 1,
A power generating device including a multi-stage accumulator, characterized in that the second filling portion of the multi-stage accumulator and the third filling portion of the last-stage accumulator among the multi-stage accumulators are connected by a pressure transmission fluid supply pipe. . The method of claim 6,
Power supply device including a multi-stage accumulator, characterized in that the pressure transmission fluid supply pipe is provided with a shut-off valve for opening and closing the pressure transmission fluid supply pipe. delete According to claim 1,
A power generating device including a multi-stage accumulator, characterized in that an air supply pipe connecting the first filling part and the air compressor is provided with a shut-off valve for opening and closing the air supply pipe. According to claim 1,
The hydraulic pressure of the hydraulic oil is a power generating device including a multi-stage accumulator, characterized in that the power transmitted to the hydraulic system. According to claim 1,
A power generating device including a multi-stage accumulator, characterized in that a shut-off valve for opening and closing the hydraulic system connection port is provided at a hydraulic system connection port connecting the fourth filling part and the hydraulic system. According to claim 1,
A power generating device including a multi-stage accumulator, wherein the first filling part is provided with a safety valve for discharging the air filled therein to the outside when the internal pressure increases due to an increase in the external temperature. According to claim 1,
A power generating device including a multi-stage accumulator, wherein the third filling part is provided with a safety valve for discharging the pressure transmission fluid filled therein to the outside when the internal pressure increases due to an increase in external temperature. According to claim 1,
A power generating device including a multi-stage accumulator, wherein the first filling part is provided with an air outlet for discharging the air inside the first filling part to the atmosphere. The method of claim 14,
Power generation device including a multi-stage accumulator, characterized in that the air outlet is provided with a shut-off valve for opening and closing the air outlet. According to claim 1,
A pressure transmission fluid filling port for discharging or filling the pressure transmission fluid is formed in each of the second filling part of the most advanced accumulator of the multi-stage accumulator and the third filling part of the last stage accumulator of the multi-stage accumulator. Power generating device comprising a multi-stage accumulator characterized by. According to claim 1,
A power generating device including a multi-stage accumulator, wherein the fourth filling part is provided with a hydraulic oil filling port for discharging or filling the hydraulic oil. According to claim 1,
Power generating device including a multi-stage accumulator, characterized in that the sensor unit for detecting the internal state and whether the damage is provided in each of the last stage and the last stage accumulator constituting the multi-stage accumulator. Hydraulic system; and
An air compressor that stores compressed air; And
Power comprising two or more multi-stage accumulators filled with hydraulic oil between the hydraulic system and the air compressor, the multi-stage accumulator comprising a top-end accumulator and a bottom-end accumulator connected in series with the top-end accumulator. In the operation method of the generator,
Forming the hydraulic oil inside the multi-stage accumulator as the operating pressure of the hydraulic system;
Supplying the hydraulic oil to the hydraulic system;
The pressure of the hydraulic oil filled in the multi-stage accumulator is lowered;
The operation of the hydraulic system is completed;
A step in which residual hydraulic oil inside the hydraulic system flows into the multi-stage accumulator;
Re-forming the pressure of the hydraulic oil filled in the multi-stage accumulator; Including,
The step of introducing residual hydraulic oil inside the hydraulic system into the multi-stage accumulator,
A step in which the air outlet formed in the first filling part of the uppermost accumulator among the multi-stage accumulators is opened to discharge the air inside the first filling part into the atmosphere;
A step in which the internal pressures of the first filling part and the second filling part of the uppermost accumulator and the third filling part and the fourth filling part of the last accumulator of the multi-stage accumulator are equal to atmospheric pressure;
A step in which hydraulic oil remaining inside the hydraulic system flows into the fourth filling portion along the hydraulic system connector by the internal pressure of the hydraulic system higher than atmospheric pressure;
Closing the air outlet;
A step in which the internal pressure of the first filling part, the second filling part, the third filling part and the fourth filling part becomes equal to the internal pressure of the hydraulic system;
A method of operating a power generating device including a multi-stage accumulator, comprising: a step in which a shutoff valve provided in the hydraulic system connector is closed. The method of claim 19,
The step of supplying the hydraulic oil to the hydraulic system,
A step in which a shut-off valve provided in a hydraulic system connection port connecting the fourth filling part of the last stage accumulator filled with the hydraulic oil and the hydraulic system among the multi-stage accumulators is opened;
Including the step of supplying the hydraulic oil inside the fourth filling portion to the hydraulic system along the hydraulic system connector.
Driving method of a power generating device comprising a multi-stage accumulator, characterized in that. The method of claim 19,
The step of reducing the pressure of the hydraulic oil filled in the multi-stage accumulator,
Reducing the internal pressure of the fourth filling part of the last stage accumulator among the multistage accumulators;
Reducing the internal pressure of the third filling part of the last stage accumulator transferring the pressure to the fourth filling part;
Supplying a pressure transfer fluid filled in the second filling part of the uppermost accumulator connected to the third filling part of the multi-stage accumulator to the third filling part;
Reducing the internal pressure of the second filling part;
Reducing the internal pressure of the first filling part of the uppermost accumulator transferring the pressure to the second filling part while the internal pressure of the second filling part decreases;
Driving method of a power generating device comprising a multi-stage accumulator, characterized in that it comprises a. The method of claim 21,
In the step of supplying the pressure transfer fluid filled in the second filling portion to the third filling portion,
The method of operating a power generating apparatus including a multi-stage accumulator, characterized in that the shut-off valve provided in the pressure transmission fluid supply pipe connecting the second filling part and the third filling part is in an open state. The method of claim 21,
After the step of reducing the internal pressure of the first filling portion of the uppermost accumulator,
The first filling part, the second filling part, the third filling part and the inner pressure of the fourth filling part is a method of operating a power generating apparatus including a multi-stage accumulator, characterized in that higher than atmospheric pressure. delete The method of claim 19,
The step in which the internal pressure of the first filling part, the second filling part, the third filling part, and the fourth filling part becomes equal to atmospheric pressure,
A step in which the internal pressure of the first filling portion decreases and becomes equal to atmospheric pressure;
A step in which the internal pressure of the second filling portion is lowered by the pressure balance of the first and second filling portions to equal the atmospheric pressure;
A step in which the pressure transmission fluid of the third filling part is delivered to the second filling part along the pressure transmission fluid supply pipe;
A step in which the internal pressure of the third filling portion decreases and becomes equal to atmospheric pressure;
Including the step of lowering the internal pressure of the fourth filling portion to equal to atmospheric pressure by the pressure balance of the third filling portion and the fourth filling portion.
Driving method of a power generating device comprising a multi-stage accumulator, characterized in that. The method of claim 25,
The step in which the internal pressure of the first filling part, the second filling part, the third filling part and the fourth filling part becomes equal to the internal pressure of the hydraulic system,
A step in which the internal pressure of the fourth filling portion rises and becomes equal to the internal pressure of the hydraulic system;
The pressure transfer fluid of the third filling portion is transferred to the second filling portion along the pressure transmission fluid supply pipe by the pressure balance of the fourth filling portion and the third filling portion;
A step in which the internal pressures of the second filling part and the third filling part rise and become equal to the internal pressure of the hydraulic system;
Including the step of equalizing the internal pressure of the hydraulic system by increasing the internal pressure of the first filling part by the pressure balance of the second filling part and the first filling part.
Driving method of a power generating device comprising a multi-stage accumulator, characterized in that. The method of claim 19,
The step of reforming the pressure of the hydraulic oil filled in the multi-stage accumulator,
A step in which a shut-off valve that opens and closes an air supply pipe connecting the first filling part of the multi-stage accumulator to the first compressor and the air compressor is opened;
Air is introduced from the air compressor to the first filling part;
The internal pressure of the air compressor is the internal pressure of the first filling part and the second filling part of the uppermost accumulator among the multi-stage accumulators, and the third filling part and the fourth filling part of the last accumulator among the multi-stage accumulators. Becoming equal;
Including the step of closing the shut-off valve to open and close the air supply pipe;
Driving method of a power generating device comprising a multi-stage accumulator, characterized in that. The method of claim 27,
The step in which the internal pressure of the first filling part, the second filling part, the third filling part and the fourth filling part becomes equal to the internal pressure of the air compressor,
A step in which the internal pressure of the first filling part rises and becomes equal to the internal pressure of the air compressor;
A step in which the internal pressure of the second filling part is increased by the pressure balance of the first filling part and the second filling part, and equal to the internal pressure of the air compressor;
A step in which the pressure transmission fluid of the second filling part is transferred to the third filling part along the pressure transmission fluid supply pipe;
A step in which the internal pressure of the third filling part rises and becomes equal to the internal pressure of the air compressor;
Including the step of equalizing the internal pressure of the air compressor by increasing the internal pressure of the fourth filling part by the pressure balance of the third filling part and the fourth filling part.
Driving method of a power generating device comprising a multi-stage accumulator, characterized in that.

Images