KR102060677B1 - Hydraulic apparatus - Google Patents

Abstract

The present invention relates to a hydraulic device. Specifically, according to an embodiment of the present invention, a movement space formed therein so as to extend in one direction, including an inlet provided on one side of the exercise space for the inflow of fluid, and an outlet provided on the other side of the exercise space cylinder; A first piston including a first hydraulic space formed therein so as to extend in the one direction, the first piston being reciprocally provided along the one direction in the movement space; A second piston disposed in the first hydraulic space and reciprocally provided along the one direction in the first hydraulic space, and connected to the cylinder and provided to open and close the movement space; A hydraulic device may be provided that includes an overpressure preventing unit configured to open when the pressure inside the exercise space is greater than or equal to a predetermined value.

Description

Hydraulic device {HYDRAULIC APPARATUS}

The present invention relates to a hydraulic device.

The hydraulic device is sometimes composed of multiple stages of cylinders to be configured to lift up while taking up less volume. In particular, by simplifying the structure of the multi-stage cylinder to stop the equipment in the middle, it is possible to easily install the multi-stage cylinder in a narrow space, while reducing the cost can help to improve productivity.

In general, cylinders are mostly used for the operation of this equipment in various equipment or equipment used to produce a vessel in the ship manufacturing process, and these cylinders can operate or stop the equipment by operating a cylinder rod with hydraulic driving force. Used to ensure that In addition, since the intermediate stop action that allows the equipment to be temporarily stopped using the cylinder is also performed, a brake or a multistage cylinder is used for the intermediate stop.

This multi-stage cylinder is provided with an inlet through which a pressure-generating fluid, such as oil, flows in, and an outlet through which such a fluid is returned. There was a problem that the cylinder is damaged due to excessive pressure.

Embodiments of the present invention have been invented to solve the above-described problem, and to provide a hydraulic apparatus that can be prevented from being damaged due to excessive pressure of the fluid inside the cylinder.

According to an aspect of the present invention, a cylinder including a movement space formed therein so as to extend in one direction, an inlet provided on one side of the exercise space for the inflow of fluid, and an outlet provided on the other side of the exercise space; A first piston including a first hydraulic space formed therein so as to extend in the one direction, the first piston being reciprocally provided along the one direction in the movement space; A second piston disposed in the first hydraulic space and reciprocally provided along the one direction in the first hydraulic space, and connected to the cylinder and provided to open and close the movement space; A hydraulic device may be provided that includes an overpressure preventing unit configured to open when the pressure inside the exercise space is greater than or equal to a predetermined value.

In addition, the overpressure preventing unit may be provided with a hydraulic device provided between the inlet and the outlet.

In addition, the first piston may include a first head portion receiving pressure from the fluid flowing into the movement space; And a cylinder communication hole for communicating the first inflow space with the movement space through the first head portion.

In addition, the first head portion includes a first head side wall in close contact with the inner wall of the cylinder forming the movement space, the second piston, the pressure under pressure from the fluid flowing into the first hydraulic space A second head portion including a surface, and a second hydraulic space formed therein, wherein the first piston is configured such that one side is formed on the first head side wall and the other side communicates with the second hydraulic space. A hydraulic device may be provided that includes a guide passage portion.

In addition, the second piston may be provided with a hydraulic device inserted into the guide passage portion to be movable along the one direction.

Further, the guide passage portion may be provided with a hydraulic device configured to communicate with the outlet through the first head side wall when the first piston is placed at the top dead center.

The second piston may include a second head portion including a pressure surface receiving a pressure from the fluid flowing into the first hydraulic space, and a second hydraulic space formed therein; And a communication passage, wherein one side communicates with the first hydraulic space opposite the pressure surface of the second head portion, and the other side communicates with the second hydraulic space.

The overpressure preventing unit may include an overpressure preventing passage communicating the movement space with the outside of the cylinder; A stopper configured to selectively close the prevention passage; And an elastic member for applying an elastic force to the stopper in a direction in which the stopper closes the prevention passage.

According to the embodiment of the present invention, the hydraulic device is prevented from being damaged by excessively applying the pressure of the fluid inside the cylinder.

1 is a perspective view of a hydraulic apparatus according to an embodiment of the present invention.
2 is an exploded perspective view of the hydraulic apparatus of FIG. 1.
3 is a longitudinal cross-sectional view showing a hydraulic apparatus in which the first piston and the second piston of FIG. 1 are located at the bottom dead center.
4 is a longitudinal cross-sectional view showing a hydraulic device in which the first piston is raised and lowered in a state where the second piston of FIG. 1 is located at the bottom dead center.
FIG. 5 is a longitudinal cross-sectional view showing a hydraulic apparatus in which a second piston is lifted and lowered in a state where the first piston of FIG.
FIG. 6 is a longitudinal cross-sectional view showing a hydraulic apparatus in which the first piston and the second piston of FIG. 1 are located at a top dead center; FIG.
7 is an enlarged view showing an overpressure preventing unit of the hydraulic device.

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

In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, the expression of the upper side, the lower side, the side, etc. in the present specification have been described with reference to the drawings in the drawings and it will be apparent that it may be expressed differently when the direction of the corresponding object is changed.

1 to 6, the hydraulic device 1 may generate a lifting force under pressure by a fluid such as oil. The hydraulic device 1 may include a cylinder 100, a first piston 200, a second piston 300, and an overpressure preventing unit 400.

The cylinder 100 may include an exercise space 110 formed therein so as to extend in the vertical direction, an inlet 120, an outlet 130, and an outlet 140 communicating with the exercise space 110. The inlet 120 may be formed at one side of the lower portion of the exercise space 110 for the inflow of the fluid. The outlet 130 may be formed at an upper portion of the exercise space for discharging the fluid contained in the exercise space 110. Outlet 140 may include an outlet 140 formed on the other side of the lower portion of the exercise space for the discharge of the fluid contained in the exercise space (110). The outlet 140 provides a passage through which fluid in the movement space 110 on the side of the first head pressure surface 222 can escape. In case of an emergency situation such as the operation of the hydraulic device 1 should be stopped while the fluid is being supplied to the hydraulic device 1, the first head pressure surface 222 is provided through the outlet 140 while the supply of the fluid is interrupted. The fluid in the movement space 110 on the side is discharged.

The first piston 200 may have a shape extending in the vertical direction and may be configured to vertically reciprocate in the movement space 110. In addition, the first piston 200 may be configured to be moved upward by being pushed by the pressure of the fluid introduced into the movement space (110). The first piston 200 has a first hydraulic space 210, the first head portion 220, the first body portion 230, the guide passage portion 250, and the cylinder communication formed therein so as to extend in the vertical direction Ball 240.

The first hydraulic space 210 may be formed to extend in the vertical direction as a space inside the first piston 200 and may be formed in the first body portion 230.

The first head portion 220 may serve as a piston head, and the first head side wall 221 and the first hydraulic space 210 closely contact the inner wall of the cylinder 100 forming the motion space 110. The first head pressure surface 222 and the first head counter surface 223 on the opposite side may be included. The first head side wall 221 may be provided with a sealing member along its circumference. In other words, the first head side wall 221 may be configured to move up and down while fluid sealing between the movement space 110 under the first head portion 220 and the movement space under the first head portion 220. The first head pressure surface 222 may be a bottom surface of the first head portion 220. The first head counter surface 223 may be an upper surface of the first head portion 220 and may have an area smaller than the first head pressure surface 222 and the second head pressure surface 322.

The first body portion 230 may extend upward from the first head portion 220 and may be provided on an opposite side of the first head pressure surface 222. The side wall of the first body part 230 may be spaced apart from the inner wall of the cylinder 100 forming the movement space 110. Therefore, the fluid may be accommodated in the movement space 110 on the side of the first body part 230. When the fluid flows into the hydraulic device 1 and the hydraulic device 1 generates the lifting force, the fluid in the movement space 110 on the side of the first trunk portion 230 passes through the outlet 130 of the cylinder 100. Out through the exercise space 110 through.

The cylinder communication hole 240 may be formed in the first head portion 220 and communicates the movement space 110 and the first hydraulic space 210 on the side of the first head pressure surface 222 with each other. Therefore, when the fluid is introduced through the inlet 120 and the hydraulic device 1 generates the lifting force, the fluid contained in the movement space 110 on the side of the first head pressure surface 222 is the cylinder communication hole 240. It moves to the first hydraulic space 210 through.

The guide passage part 250 may communicate the first hydraulic space 210 and the outside of the first piston 200. The guide passage part 250 is a guide part 251 formed of an elongated passage extending from the lower portion of the first hydraulic space 210 in the vertical direction, and a first head as a passage communicating with the passage in the guide portion 251. The head penetrating part 252 may be formed in the part 220. The head through part 252 communicates the guide part 251 and the first head side wall 221 with each other.

The second piston 300 may have a shape extending in the vertical direction and may be configured to vertically reciprocate in the second hydraulic space 310. In addition, the second piston 300 may be configured to be moved upward by being pushed by the pressure of the fluid introduced into the second hydraulic space (310). The second piston 300 may include a second hydraulic space 310, a second head portion 320, a second body portion 330, and a communication passage 340 formed therein so as to extend in the vertical direction. have.

The second hydraulic space 310 may be formed to extend in the vertical direction as a space formed in the second piston 300, and may be formed in the second body 330.

The second head part 320 may serve as a piston head, the second head side wall 321 in close contact with an inner wall of the first piston 200 forming the first hydraulic space 210, and the second head part 320. The second head pressure surface 322 that is pressurized by the fluid introduced into the hydraulic space 310 may be included. The second head side wall 321 may be provided with a sealing member along its circumference. In other words, the second head side wall 321 is formed by fluid sealing between the second hydraulic space 310 under the second head 320 and the second hydraulic space 310 under the second head 320. It may be configured to move. The second head pressure surface 322 may be a bottom surface of the second head portion 320. In addition, the width of the second head pressure surface 322 may be wider than the first head pressure surface 222.

The second body portion 330 may extend upward from the second head portion 320 and may be provided on an opposite side of the second head pressure surface 322. The side wall of the second body 330 may be spaced apart from the inner wall of the first piston 200 forming the first hydraulic space 210. Therefore, the fluid may be accommodated in the second hydraulic space 310 on the side of the second body portion 330.

The communication passage 340 may be configured to communicate the first hydraulic space 210 and the second hydraulic space 310. The communication passage 340 may be formed through at least one of the second head portion 320 and the second body portion 330, and the guide portion 251 and the second piston 300 of the guide passage portion 250. It may include a gap formed between. When the fluid flows into the hydraulic device 1 and the first piston 200 is fully elevated to the top dead center, and the outlet 130 and the guide passage part 250 communicate with each other, the first head on the first head part 220 side Fluid flows into the hydraulic space 210 to elevate the second piston 300. At this time, the fluid in the first hydraulic space 210 on the side of the second body portion 330 passes through the communication passage 340 in the second hydraulic space 310 and the guide passage portion 250 in the first hydraulic space 210. Exit through the outlet 130 through). When the second piston 300 is at the bottom dead center, the guide part 251 of the guide passage part 250 maintains the state inserted in the second hydraulic space 310. Thereafter, after the first piston 200 is fully elevated to the top dead center, fluid is introduced into the first hydraulic space 210 through the cylinder communication hole 240 so that the second piston 300 moves from the bottom dead center to the top dead center. The guide part 251 exits in the 2nd hydraulic space 310 while raising and lowering.

Referring to FIG. 7, the overpressure preventing unit 400 may be in a state in which the outlet 130 is closed due to an operator's mistake or failure of the outlet 130, or a fluid in the hydraulic apparatus 1 due to a malfunction of the hydraulic apparatus 1. When the fluid continues to be supplied into the hydraulic device 1 in a state in which the flow path of the closed flow path is closed, by discharging the fluid in the hydraulic device 1, it is possible to prevent the hydraulic device 1 from being damaged due to excessive hydraulic pressure.

The overpressure preventing unit 400 may be provided adjacent to the outlet 130 side at a position between the inlet 120 and the outlet 130. The overpressure preventing unit 400 may be configured to selectively communicate the movement space 110 with the outside of the cylinder 100 when the pressure of the movement space 110 on the side of the first head counter surface 223 is greater than or equal to a predetermined value. have. The first head counter surface 223 has an area smaller than the cross section of the first head pressure surface 222, the second head pressure surface 322, and the second hydraulic space 310, and thus, the first head counter surface 223. The pressure of the movement space 110 of) is higher than the pressure of the movement space 110 of the second head pressure surface 222, the pressure of the first hydraulic space 210 and the second hydraulic space 310. Can have. Therefore, when the fluid is continuously supplied into the hydraulic device 1 while the flow path of the fluid in the hydraulic device 1 is closed due to a malfunction of the hydraulic device 1, the movement space on the side of the first head counter surface 223 The pressure of 110 is raised to the highest. However, since the overpressure prevention unit 400 prevents the pressure of the movement space 110 on the first head counter surface 223 from rising above a predetermined value, breakage of the hydraulic apparatus 1 can be prevented.

The overpressure preventing unit 400 may include an overpressure preventing passage 410, a stopper 420, and an elastic member 440. The overpressure prevention passage 410 may include a prevention passage inlet 411 connected to the movement space 110 of the cylinder 100 and a prevention passage outlet 412 in communication with the movement passage 110. The stopper 420 may be configured to be pressed by the elastic force of the elastic member 420 to block the overpressure preventing passage 410. The elastic member 420 may be provided between the stopper 420 and the overpressure preventing passage 410 to apply an elastic force to the stopper 420 so that the stopper 420 closes the overpressure preventing passage 410. The elastic force of the elastic member 420 may be set to the extent that the stopper 420 opens the overpressure preventing passage 410 when the pressure in the exercise space 110 is greater than or equal to a predetermined value.

In addition, the hydraulic apparatus 1 further includes an hydraulic supply control unit (not shown) for controlling the supply of fluid into the hydraulic apparatus 1 and an opening detection sensor (not shown) for detecting whether the overpressure preventing unit 400 is opened. It may include. The hydraulic pressure supply control unit may be linked with the opening detection sensor. In other words, when the overpressure prevention unit 400 is opened and the fluid flows to the downstream side of the overpressure prevention unit 400, the sensor detects that the overpressure prevention unit 400 is open. In this way, the supply control unit recognizes that the hydraulic device 1 has malfunctioned and that overpressure is formed in the inside (the movement space 110 on the side of the first head counter surface 223) and stops the supply of the fluid to the hydraulic device 1. You can. Therefore, the pressure of the fluid inside the cylinder is excessively applied to prevent damage.

On the other hand, while the embodiments of the present invention have been described as specific embodiments, this is only an example, the present invention is not limited to this, it should be construed as having the broadest range in accordance with the basic idea disclosed herein. Those skilled in the art may combine / substitute the disclosed embodiments to implement a pattern of a timeless shape, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, it is apparent that such changes or modifications belong to the scope of the present invention.

1: hydraulic system 100: cylinder
110: movement space 120: inlet
130: outlet 140: outlet
200: first piston 210: first hydraulic space
220: first head portion 221: first head sidewall
222: first head pressure surface 223: first head counter surface
230: first body part
240: cylinder communication hole 250: guide passage portion
251: guide portion 252: head through portion
300: second piston 310: second hydraulic space
320: second head portion 321: second head sidewall
322: second head pressure surface 330: second body portion
340: communication passage 400: overpressure protection
410: overpressure prevention passage 411: prevention passage entrance
412: prevention passage exit 420: plug
430: elastic member

Claims (8)

A cylinder including an exercise space formed therein so as to extend in one direction, an inlet provided at one side of the exercise space for the inflow of fluid, and an outlet provided at the other side of the exercise space;
A first piston including a first hydraulic space formed therein so as to extend in the one direction, the first piston being reciprocally provided along the one direction in the movement space;
A second piston disposed in the first hydraulic space and provided reciprocally along the one direction in the first hydraulic space; and
It is connected to the cylinder, provided to open and close the exercise space, and comprises an overpressure prevention unit configured to open when the pressure in the exercise space is a predetermined value or more,
The second piston includes a second hydraulic space formed therein,
The first piston
A first head portion receiving pressure from the fluid flowing into the movement space;
A cylinder communication hole for communicating the first hydraulic space with the movement space through the first head portion; And
And a guide passage portion communicating the second hydraulic space with the outlet of the cylinder so that the fluid in the second hydraulic space is discharged to the outlet when the first piston is at the top dead center.
The second piston has a pressure surface receiving pressure from a fluid flowing from the movement space into the first hydraulic space,
And the pressure surface is pressurized by a fluid flowing through the cylinder communication hole when the first piston is at the top dead center. The method of claim 1,
The overpressure preventing unit is provided between the inlet and the outlet. delete The method of claim 1,
The first head portion includes a first head side wall in close contact with the inner wall of the cylinder forming the movement space,
One side of the guide passage is formed on the first head side wall, the other side is configured to be in communication with the second hydraulic space. The method of claim 4, wherein
And the guide passage portion is configured to insert through the second piston so that the second piston is movable along the one direction. The method of claim 5, wherein
And the guide passage portion is configured to communicate with the outlet through the first head side wall when the first piston is placed at the top dead center. The method of claim 1,
The second piston,
A second hydraulic space formed therein; And
And a communication passage, wherein one side communicates with the first hydraulic space on the opposite side of the pressure surface of the second head portion, and the other side communicates with the second hydraulic space. The method of claim 1,
The overpressure prevention unit
An overpressure preventing passage communicating the movement space with the outside of the cylinder;
A stopper configured to selectively close the overpressure preventing passage; And
And a resilient member for applying the resilient force to the stopper in a direction in which the stopper closes the overpressure preventing passage.

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