KR102442561B1 - Liquid pressurized gas compression device - Google Patents

Abstract

The present invention relates to a liquid pressurized gas compression device. The liquid pressurized gas compression device comprises: an oil tank in which hydraulic oil is stored; a hydraulic pump sucking and discharging the hydraulic oil in the oil tank; an amplification device provided with a rod operating in both directions by the flow of the hydraulic oil discharged from the hydraulic pump and formed with first and second compression units connected to first and second discharge pipes, respectively, on both sides; first and second shock absorbing units disposed in the first and second compression units of the amplification device, respectively, and absorbing impact generated when the rod compresses; a first upright compressor having the first discharge pipe connected to the lower part thereof, provided with a floating body operating up and down by compression and expansion pressure generated by the amplification device in internal space to generate suction and compression force, and connected to a first suction pipe to which a gas supply pipe is connected and a first injection pipe discharging sucked gas on the upper part thereof; a second upright compressor having the second discharge pipe connected to the lower part thereof, provided with a floating body operating up and down by compression and expansion pressure generated by the amplification device in the internal space to generate suction and compression force, and connected to a second suction pipe to which the gas supply pipe is connected and a second injection pipe discharging the sucked gas on the upper part thereof; a gas and water separator connected to the first injection pipe and the second injection pipe to store the sucked gas; a gas discharge pipe discharging the gas of the gas and water separator; and a cooling unit formed outside each of the first upright compressor and the second upright compressor. Accordingly, internal temperature rise can be prevented.

Description

Liquid pressurized gas compression device

The present invention relates to a liquid pressurized gas compression device, and more particularly, to a liquid pressurized gas compression device that is linked to a compression or expansion operation of a cylinder so that the inflow of gas from the outside and the compression operation are repeated.

A pistonless compressor for gaseous media is known from US 6,652,243 B2.

In a conventional pistonless compressor, the working fluid in the compressor cylinder is connected with a displacement machine composed of a hydraulic pump, and a control valve is provided to control the inflow and outflow of the working fluid, the control valve being detected by an electromagnetic movement measurement system. It is controlled according to the fluid level of the working fluid in the compressor cylinder. The compressor cylinder is preferably arranged vertically, thereby assisting the outflow of the working fluid out of the displacement cylinder via gravity.

Since there is no piston between the working fluid and the gas medium in this conventional pistonless compressor, the working fluid and gas are in direct contact, and the working fluid descends only by gravity to suck the gas. There is a problem that the efficiency is low, and it is not suitable as a compression device.

The compression device according to the prior art includes a plurality of compression transducers operated in parallel, and a cylinder connected to each of these compression transducers for suction and discharge operation, and by suction and discharge operation of the cylinder, the gas is sucked from the outside and then compressed. The discharging operation is performed.

At this time, as the piston of the cylinder performs a reciprocating operation at high speed, heat is generated, which may cause equipment failure.

In addition, since it is necessary to provide a plurality of compression converters, the installation cost is increased, and the failure rate is high when operating them, so there are problems in that a large amount of money is spent on the operation of the system and damages due to the interruption of the operation during maintenance work.

Korean Patent Application No. 10-2016-0098032

The present invention has been devised to solve the problems of the prior art, and it is possible to prevent the internal temperature rise by cooling an upright compressor that exhibits gas suction power, and an amplifying device that sucks and compresses hydraulic oil to generate a compressive force in the upright compressor. An object of the present invention is to provide a liquid pressurized gas compression device capable of improving quietness by mitigating operating shock.

The above object of the present invention, the oil tank in which the hydraulic oil is stored; a hydraulic pump for sucking and discharging hydraulic oil from the oil tank; an amplifying device provided with a rod operated in both directions through which the hydraulic oil discharged from the hydraulic pump is introduced and first and second compression units connected to both sides of the first and second discharge pipes, respectively; first and second shock absorbers respectively disposed in the first and second compression units of the amplifying device and for absorbing shocks generated when the rod compresses; The first discharge pipe is connected to the lower part and a floating body is provided in the inner space that is operated up and down by the compression and expansion pressure generated by the amplifying device to generate suction and compression force, and a first suction pipe connected to the gas supply pipe at the upper part; a first upright compressor to which a first injection pipe for discharging the sucked gas is connected; The second discharge pipe is connected to the lower part, and a floating body that is operated up and down by the compression and expansion pressure generated by the amplifying device to generate suction and compression force is provided in the inner space, and a second suction pipe connected to the gas supply pipe at the upper part; a second upright compressor to which a second injection pipe for discharging the sucked gas is connected; a water separator in which the first injection pipe and the second injection pipe are connected to store the sucked gas; A gas discharge pipe through which the gas of the water separator is discharged; each of the first upright compressor or the second upright compressor includes a cooling unit formed outside, and the cooling unit includes: a cooling jacket in which cooling water is stored; It can be achieved by a liquid pressurization type gas compression device including a water supply pipe connected to the cooling jacket to supply cold water and a recovery pipe through which the cooling jacket water is discharged.

Each of the first and second shock absorbers includes a roller, a cylinder to which the roller is mounted, a valve to which the cylinder is coupled to operate and contract, and an elastic body coupled to the cylinder.

The amplifying device has a main body having a space therein, protruding on both sides of the main body, and first and second compression parts having a hollow so that the rod is drawn in/out, is formed to pass through, and is in close contact with the inner circumferential surface of the main body and moves in both directions. It partitions the inner space and includes a piston to which a rod is coupled, and characterized in that it includes first and second compartments respectively formed in the interior of the body by the piston.

and a hydraulic pressure supply pipe connected to the discharge side of the hydraulic pump, and first and second hydraulic branch pipes branching from the hydraulic supply pipe and respectively connected to the first and second compartments of the amplifying device to supply hydraulic pressure, It is characterized in that it includes a; hydraulic direction control unit mounted on the branch to selectively branch the hydraulic pressure to the first and second hydraulic branch pipes.

The hydraulic direction control unit has an inlet hole passing through the hydraulic supply pipe formed on one side thereof, first and second branch flow passages branching to both sides are formed inside, and a plunger selectively opening and closing the first and second branch flow passages, and moving the plunger It is characterized in that it comprises a valve having an actuator to actuate.

According to the present invention, it is possible to prevent the internal temperature rise by cooling the upright compressor that exerts the gas suction power, and it is possible to improve the quietness by alleviating the operating shock of the amplifying device that generates the compressive force in the upright compressor by compressing the hydraulic oil after suction. there is an effect

1 is a block diagram of a liquid pressurized gas compression device according to the present invention;
2 is a view showing a 'cooling unit' of the liquid pressurized gas compression device according to the present invention;
Figure 3 is a view showing a 'buffer' of the liquid pressurized gas compression device according to the present invention.

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

The embodiments to be described below are intended to explain in detail enough to be easily implemented by those of ordinary skill in the art to which the present invention pertains, thereby limiting the technical spirit and scope of the present invention. doesn't mean

In addition, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. It should be noted that definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram of a liquid pressurized gas compression device according to the present invention, FIG. 2 is a view showing a 'cooling unit' of the liquid pressurized gas compression device according to the present invention, and FIG. 3 is a liquid according to the present invention It is a view showing the 'buffer part' of the pressurized gas compression device.

1 to 3 , the liquid pressurized gas compression device according to the present invention includes an oil tank 2 , a hydraulic pump 3 , an amplifying device 4 , and first and second shock absorbers 5 and 5' ), a first upright compressor (6), a second upright compressor (6'), a water separator (7), a gas supply pipe (8A), a gas discharge pipe (8B), and a cooling unit (9).

The oil tank 2 is stored so that an appropriate amount of hydraulic oil is constant. The hydraulic pump 3 sucks and discharges hydraulic oil from the oil tank 2 , and a suction pipe inserted into the oil tank 2 and a hydraulic pressure supply pipe 32 on the discharge side are formed, and include a motor connected to one side.

The amplifying device 4 is a hollow body with an empty inside, and the hydraulic oil discharged from the hydraulic pump 3 is introduced and a rod 42 operated in both directions is coupled therein, and first and second discharge pipes ( The first and second compression units 44 and 46 to which L1 and L2 are connected are formed.

The first and second shock absorbers 5 and 5 ′ are respectively disposed in the first and second compression units 44 and 46 of the amplifying device 4 , and absorb shock generated when the rod 42 compresses them. do it

The first upright compressor 6 has a body made of a cylindrical body and the first discharge pipe L1 is connected to the lower part, and the first upright compressor 6 is operated up and down by the compression and expansion pressure generated by the amplifying device 4 in the inner space to suction , A floating body generating a compressive force is provided, and the first suction pipe 61 to which the gas supply pipe 8 is connected, and the first injection pipe 62 for discharging the sucked gas are connected.

The second upright compressor (6') is connected to the lower part of the second discharge pipe (L2) in a body made of a cylindrical body, and is operated up and down by the compression and expansion pressure generated by the amplifying device (4) in the inner space. A floating body generating suction and compression force is provided, and a second suction pipe 61 ′ to which a gas supply pipe 8 is connected and a second injection pipe 62 ′ for discharging the sucked gas are connected to the upper portion.

The water separator 7 is connected to the first injection pipe 62 and the second injection pipe 62' to store the sucked gas, separate the gas and moisture, so that the moisture sinks to the bottom, and Make sure that only the gas flows out. The gas discharge pipe (8B) is connected to the upper end of the water separator (7) so that only compressed gas is discharged.

The cooling unit 9 is formed outside each of the first upright compressor 6 or the second upright compressor 6'. The cooling unit 9 includes a cooling jacket 92 in which cooling water is stored; It is composed of a water supply pipe 93 connected to the cooling jacket 92 to supply cold water, and a recovery pipe 94 through which the water of the cooling jacket 92 is discharged.

Cold water is always supplied through the water supply pipe 93 and stored in the cooling jacket 92 , and the first upright compressor 6 or the second upright compressor 6 ′ is in a high temperature state by the cold water stored in the cooling jacket 92 . can be prevented.

On the other hand, each of the first and second shock absorbers 5 and 5 ′ includes a roller 50 , a cylinder 52 on which the roller 50 is mounted, and a valve 54 in which the cylinder 52 is coupled to the expansion and contraction operation; , consisting of an elastic body 56 coupled to the cylinder (52).

Therefore, the hydraulic fluid in the roller 50, the cylinder 52 with the rollers, and the valve 54 in which the cylinder is coupled and contracted and operated simultaneously absorbs the compression shock generated while the rod 42 is moved, resulting in noise and vibration. can offset the

The amplifying device 4 includes a main body 41 having a space therein, and first and second compression parts 44 protruding from both sides of the main body 41 and having a hollow so that the rod 42 is drawn in/out. 46) is formed to pass through, it is moved in both directions in close contact with the inner circumferential surface of the main body 41, divides the inner space, and includes a piston 43 to which a rod is coupled, and each inside of the main body by the piston 43 It is configured to include the first and second compartments 45 and 47 formed.

The first and second hydraulic branch pipes (L3, L4) are connected to communicate with the first and second compartments (45 and 47), respectively.

The first and second hydraulic branch pipes L3 and L4 are branched from the hydraulic supply pipe 32 connected to the discharge side of the hydraulic pump 3 , and branched from the hydraulic supply pipe 32 to the first and second parts of the amplifying device 4 . They are respectively connected to the compartments 45 and 47 so that hydraulic pressure is supplied.

On the other hand, it is mounted on the branch of the hydraulic pressure supply pipe 32, the hydraulic pressure direction control unit 100 to selectively branch the hydraulic pressure to the first and second hydraulic branch pipes (L3, L4); may include.

The hydraulic direction control unit 100 has an inlet hole through the hydraulic supply pipe 32 formed on one side, and first and second branch flow paths 110 and 120 branching to both sides are formed inside, and the first and second branch flow paths 110 and 120 are formed. It is composed of a plunger for selectively opening and closing the valve, and a valve having an actuator for moving the plunger.

Accordingly, as the operator and the plunger move according to the signal of the control unit, the first and second branch flow paths 110 and 120 are selectively opened, and the hydraulic oil moves through the opened flow path to selectively enter the first and second compartments 45 and 47. to supply working oil.

As a result, the rod 42 alternately compresses the first and second compression units 44 and 46 while moving to the left or right, and alternately generates suction force through the first and second discharge pipes L1 and L2 connected thereto. do.

In conjunction with this, the first and second upright compressors 6 and 6' each alternately perform suction operations to suck gas from the external gas supply pipe 8A, discharge it and store it in the water separator 7 .

The gas stored in the water separator 7 is discharged through the gas discharge pipe 8B.

Although described with reference to the preferred embodiment, it will be readily recognized by those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, and all such changes and modifications fall within the scope of the appended claims. is self-evident

2: oil tank, 3: hydraulic pump,
4: amplification device, 5,5': first and second buffer parts,
6: first upright compressor, 6': second upright compressor,
7: Water separator, 8A, 8B: gas supply pipe, gas discharge pipe,
9: cooling unit

Claims (5)

oil tank in which hydraulic oil is stored;
a hydraulic pump for sucking and discharging hydraulic oil from the oil tank;
an amplifying device having a rod operated in both directions through which the hydraulic oil discharged from the hydraulic pump is introduced, and first and second compression units having first and second discharge pipes connected to both sides thereof;
first and second shock absorbers respectively disposed in the first and second compression units of the amplifying device and for absorbing shocks generated when the rod compresses;
The first discharge pipe is connected to the lower part, and a floating body that is operated vertically to generate suction and compression force by the compression and expansion pressure generated by the amplifying device is provided in the inner space, and a first suction pipe connected to the gas supply pipe at the upper part; a first upright compressor to which a first injection pipe for discharging the sucked gas is connected;
The second discharge pipe is connected to the lower part, and a floating body that is operated up and down by the compression and expansion pressure generated by the amplifying device to generate suction and compression force is provided in the inner space, and a second suction pipe connected to the gas supply pipe at the upper part; a second upright compressor to which a second injection pipe for discharging the sucked gas is connected;
a water separator in which the first injection pipe and the second injection pipe are connected to store the sucked gas;
To include; a gas discharge pipe through which the gas of the water separator is discharged,
Each of the first upright compressor or the second upright compressor includes a cooling unit formed outside;
The cooling unit,
a cooling jacket in which coolant is stored;
and a water supply pipe connected to the cooling jacket to supply cold water, and a recovery pipe through which water from the cooling jacket is discharged. The method of claim 1,
Each of the first and second buffer parts
A liquid pressurizing gas compression device comprising: a roller; a cylinder to which the roller is mounted; The method of claim 1,
The amplifier is
a body having a space therein;
It is formed to protrude on both sides of the main body so that the first and second compression parts having a hollow so that the rod is drawn in/out is formed to pass therethrough,
It is in close contact with the inner circumferential surface of the body, moves in both directions, divides the inner space, and includes a piston to which a rod is coupled,
Liquid pressurization type gas compression device, characterized in that it includes first and second compartments respectively formed in the interior of the body by the piston. The method of claim 1,
A hydraulic pressure supply pipe connected to the discharge side of the hydraulic pump, and first and second hydraulic branch pipes branched from the hydraulic supply pipe and connected to the first and second compartments of the amplifying device to supply hydraulic pressure,
and a hydraulic pressure control unit mounted on the branch of the hydraulic supply pipe to selectively branch the hydraulic pressure to the first and second hydraulic branch pipes. 5. The method of claim 4,
The hydraulic direction control unit has an inlet hole passing through the hydraulic supply pipe formed on one side thereof, first and second branch flow passages branching to both sides are formed inside, and a plunger selectively opening and closing the first and second branch flow passages, and moving the plunger A liquid pressurization type gas compression device comprising a valve having an actuator to actuate.

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