KR200152631Y1 - Pressure intensifying system - Google Patents

Abstract

The present invention relates to a pressure intensifier, and more particularly, to a pressure intensifier for continuously generating and discharging ultra-high pressure water pressure, including a water jet cutting device.

The structure of the plunger 3 is such that the high-pressure cylinders 1 and 11 and the single-pressure intensifiers A and B, which form the low pressure cylinders 2 and 21, are connected in parallel to each other so that discharge may be sequentially performed. 31, the piston (4, 41) is integral with the cylinder (1, 11, 2, 21) reciprocating inside the configuration, so that pressurization, forward, retraction can occur in association with each other It is a device.

As the above structure maintains the discharge state by continuously operating two single-actuator type boosters continuously, the pulsation of discharge water pressure is extremely small and the load pressure of the hydraulic pump is kept almost constant so that the life of the machine can be maintained for a long time. It can be useful and economical.

Description

Booster

The present invention relates to a pressure intensifier, and more particularly, to a pressure intensifier for continuously generating and discharging ultra-high pressure water pressure, including a water jet cutting device.

Conventional intensifiers generally use double-acting intensifiers as shown in FIG. As shown in FIG. 5, the double-acting type pressure intensifier 110 has a hydraulic oil supplied from the hydraulic pump 111 in order to discharge water, and the spool valve is operated by the electronic solenoid valve 112. Opening the entrance between the hydraulic fluid is passed through the solenoid valve 112 by the hydraulic pump 111 to enter the left side 114 of the high-pressure cylinder 113 to push the piston 116 to the right 115. At this time, since the high pressure plungers 117 and 118 connected to the piston 116 also move together, the liquid in the high pressure cylinder 113 is discharged through the accumulator 200 through the check valve 119 and the supply water pump 210. The liquid supplied from) is sucked into the high pressure cylinder 113 on the left side 114 through the check valve 212. When the piston 116 completes the forward movement and the sensor 213 (the sensor 214 is operated at the retreat) is operated, the solenoid valve 112 is switched to the discharged state, and the piston 116 is pushed to the left 114 to discharge. The suction direction is changed. As described above, the high pressure plungers 117 and 118 continue to discharge while repeating the reciprocating motion. At this time, the double-acting type pressure intensifier is simple in structure and easy to obtain high pressure, but the sum of the time (valve switching time) and time required for the liquid to be compressed in the high pressure cylinder 113 each time the operation stroke is changed. There is a time interval in which high pressure water cannot be discharged as much as (sum of the fluid compression time). At this time, a pulsation phenomenon occurs in which the discharge water pressure decreases and the drive hydraulic pressure decreases. In order to alleviate this, the accumulator 200 is installed in the high-pressure discharge pipe, and the valve switching time adjustment and the notching of the valve spool are used to prevent the sudden drop in the hydraulic pressure. There is a closed end that affects the cutting quality due to the impact or the noise of the hydraulic drive unit.

Therefore, as a countermeasure, there is a method of adjusting the operating time of the two intensifiers by connecting two double-acting intensifiers in parallel, but this has been avoided because the structure is large and the operation is very complicated.

The present invention is designed to solve the above-mentioned deficiency. By connecting two single-actuator type intensifiers, each one solenoid valve operates the piston so that the pulsation does not occur and the discharge stroke is not broken. Since the pressurization is completed before the discharge stroke by operating continuously, the suction stroke can prevent the deterioration of cutting quality by providing that the retraction speed is adjusted by the flow control valve so that the pressurization can be completed before the opposite piston is completed. It is for the purpose.

In addition, since the suction drive is made by air spring, there is no flow rate consumption of the hydraulic source, so the pressure change and the flow rate change of the hydraulic valve are small, and the hydraulic capacity of the minimum capacity can be driven and the compressed air is consumed little. It is.

1 is a structural diagram showing a state in which the A intensifier of the present invention is discharging and the B intensifier is being pressurized.

2 is a structural diagram illustrating the state in which the A pressure intensifier of the present invention is inhaled and the B pressure intensifier is being discharged.

3 is a structure showing a state in which the pressure intensifier A of the present invention is being pressurized and the pressure B is being discharged.

4 is a structure of an intensifier showing another embodiment of the present invention.

5 is a structure of a conventional double-acting booster.

* Description of the main parts of the drawings

1: high pressure cylinder 2: low pressure cylinder

3: plunger 4: piston

5: Forward diagnosis sensor 6: Retraction sensor

7: solenoid valve 8: air tank

9: air adjusting device 10: flow control valve

Referring to the structure of the present invention for achieving the above object by the accompanying drawings as follows.

The plunger (3, 31) and the single actuating pressure intensifier (A, B) forming the high pressure cylinder (1, 11) and the low pressure cylinder (2, 21) are connected in parallel to each other so that discharge can be sequentially performed. An integral piston 4, 41 can reciprocate inside the cylinders 1, 11, 2, 21 to keep the air pressure inside the cylinder constant so that pressurization, forward and retraction can occur in correlation. The pressure booster is characterized in that it is configured to.

In addition, the high-pressure cylinder (1, 11) of the single-actuator type pressure intensifier (A, B) is a pressure increaser, characterized in that configured to be made of a plunger type or a piston type.

The pressure increasing device is characterized in that the driving force of the rod side (retraction side) of the low pressure cylinders 2 and 22 of the single acting pressure intensifiers A and B is made of an air spring.

In addition, the pressure increaser is characterized in that the electromagnetic solenoid valves 7 and 71 for varying the hydraulic pressure of the single acting pressure intensifiers A and B are configured such that their neutral position type is a one-way throttle.

The present invention shown in Fig. 1 is a configuration in which the single-actuator type intensifiers A and B are connected in parallel with each other. That is, the single acting pressure intensifiers A and B are pistons integrally coupled with the plungers 3 and 31 which can reciprocate inside the high pressure cylinders 1 and 11 and the low pressure cylinders 2 and 21 ( 4, 41 and both ends of the low-pressure cylinder (2, 21) and the forward and retracting sensors (5, 51) (6, 61) connected to a power source to operate the piston (4, 41), and the low pressure On one side of the cylinders 2 and 21, the electromagnetic solenoid valves 7 and 71 and the flow regulating valves 10 and 101 are respectively connected. In addition, discharge pipes 12 are connected to one side of the high pressure cylinders 1 and 11, respectively, so that water supplied by the supply water pump 13 can discharge through the discharge pipe 12. In addition, the electromagnetic solenoid valves 7 and 71 adjust the direction of the fluid flowing into the flow path by the hydraulic pump 14, and the flow rate adjusting valves 10 and 101 use the flow rate at which the pistons 4 and 41 are retracted. To adjust. In addition, the air tank 8 connected to the air regulator 9 is connected to the upper ends of the low pressure cylinders 2 and 21, respectively. It is a booster that can act as an air spring to keep the constant.

When described in more detail based on the accompanying effects of the present invention configured as described above as follows.

As shown in Fig. 1, the single-acting intensifier of (A) is a discharge stroke in which the piston 4 is advanced, and the single-acting intensifier of (B) is a pressure stroke in which the piston 41 is pushed at a low speed.

In other words, when discharging ultra high pressure water, first, the fluid introduced by the hydraulic pump 14 passes through the solenoid valve 7 which is switched to the discharge state, and the low pressure cylinder (2) formed in the single acting intensifier. ), And when the introduced fluid advances the piston (4) integral with the plunger (3), the single-acting intensifier of (A) becomes a discharge stroke.

In FIG. 1, the solenoid valve 71 of the single-actuator type intensifier of (B) is pressurized, and the fluid supplied from the hydraulic pump 14 flows at a low speed through the throttled flow path of the solenoid valve 71. 41), the single acting pressure intensifier becomes a pressure stroke.

In FIG. 2, the solenoid valve 7 is sucked in when the forward solenoid valve 5 is formed when the piston 4 is fully advanced and completed. The piston 4 is retracted together with the flanger 3 by the air spring supplied from the air tank 8 to the upper portion of the low pressure cylinder 2 so that the single-acting intensifier of (A) is suctioned. The stroke is made and the retraction speed is adjusted by the flow control valve 10. At the same time, the solenoid valve 71 connected to the low pressure cylinder 21 forming the single-acting intensifier of (B) is switched to the discharged state, and the fluid introduced by the hydraulic pump 14 is the solenoid valve 71. The cylinder 41, which is integral with the plunger 31, is introduced into the low-pressure cylinder 21 constituting the single-acting pressure intensifier of (B) through the discharged state of (B). At this time, the single-acting intensifier of (B) is a discharge stroke.

When the piston 4 of the single-actuator type intensifier of (A) is fully retracted and the retracting end sensor 6 is operated as shown in FIG. 3, the solenoid valve 7 is switched to pressurized to push the piston 4 at low speed ( It becomes a pressurizing stroke which pressurizes the single acting pressure intensifier of A).

At this time, the flow regulating valve 10 of the single-acting intensifier of (A) is kept in the discharge stroke until the single-pressure intensifier of (A) reaches the required pressure value. Adjusted to set suction speed. Therefore, the water discharged through the discharge tube 12 by the high pressure of the high-pressure cylinder 11 is to be discharged continuously without rest while maintaining the ultra-high pressure.

As described above, the above embodiment reciprocates into the high pressure cylinders 1 and 11 by the pistons 4 and 41 in the high pressure cylinders 1 and 11 and the low pressure cylinders 2 and 21 formed in the pressure-increasing device of the present invention. Although a plunger type pressure intensifier in which the rod generating the high pressure by moving is formed of the plungers 3 and 31 has been described, another embodiment of the present invention is shown in FIG. It relates to a piston type single-pressure intensifier which is formed by forming a piston (30) at the top instead of the plunger (3, 30) the rod reciprocating inside. When the piston type single acting pressure intensifier (C) is used in parallel with each other as in the above embodiment, the working effect is the same as that of the plunger type intensifiers (A, B) of the above embodiment.

The present invention, which operates in this way, continuously operates the two single actuating pressure intensifiers continuously to maintain the discharged state. Therefore, the pulsation of the discharge water pressure is extremely low and the load pressure of the hydraulic pump is kept constant so that the life of the machine is extended. It is useful and economical to maintain.

Claims (1)

In the booster device in which the high pressure cylinders (1, 11) and the low pressure cylinders (2, 21), the single actuating pressure intensifiers (A, B) are connected in parallel to each other, so that the discharge can be carried out sequentially. Flow rate control valves (10, 101) for adjusting the flow rate to the flow rate, the air tank (8) and the air regulator (9) for controlling the suction driving force of the piston, and the direction of the fluid flowing into the flow path by the hydraulic pump, A booster device comprising an electronic three-position directional valve (7,71) configured such that its neutral position type is a one-way throttle.