KR20150124688A - a hydraulic cylinder - Google Patents

Abstract

The present invention adjusts a performance of a cushion device to mitigate a shock generated during stroke end by an extending operation of a hydraulic cylinder. According to an embodiment of the present invention, a hydraulic cylinder comprises: a cylindrical tube; a cylinder rod extending and contacting by being moved by working oil introduced into and discharged from the tube; a piston coupled to an end of the cylinder rod to reciprocate in the tube, and dividing the inside of the tube into a large chamber and a small chamber; a flange extending from one end of the tube having a screw hole which communicates with the small chamber, and a first flow path communicating with the screw hole; a head cover coupled to an outer end of the flange having a port to introduce and discharge the working oil by communicating with the first flow path; and a block for an orifice coupled to the screw hole to be able to be replaced, allowing the first flow path to communicate with the small chamber through an orifice hole inside, wherein the block for an orifice adjusts an amount of working oil discharged from the small chamber to the first flow path by the orifice hole during stroke end.

Description

A hydraulic cylinder}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hydraulic cylinder, and more particularly to a hydraulic cylinder provided with a cushion device for relieving an impact generated at the stroke end.

Generally, the hydraulic cylinder is provided with a cushioning device for protecting the component from the peak pressure generated at the stroke end due to the maximum extension drive or the shrinkage drive. That is, the cushion device absorbs a shock by reducing the extension drive or shrinkage driving speed as the amount of the hydraulic oil discharged through the orifice from the hydraulic cylinder is shortened during the stroke end.

On the other hand, when the working oil is discharged to the port through the throttle passage (serving as an orifice) formed inside the hydraulic cylinder at the stroke end, the peak pressure generated in the chamber instantaneously rises. If the peak pressure momentarily generated in the chamber exceeds the set value, the tube may be expanded or leaking due to the tube expansion may occur. Therefore, in order to optimally set the performance of the hydraulic cylinder, it is tuned to maintain a proper peak pressure in the chamber at the stroke end.

In the hydraulic cylinder according to the prior art shown in Fig. 1,

A cylinder rod (2) which is stretch-driven or shrink-driven is accommodated movably by a working oil introduced into and discharged from a cylindrical tube (1) through a port.

A piston 3 partitioning the inside of the tube 1 into a large chamber 1a and a small chamber 1b is screwed to one end of the cylinder rod 2 so as to reciprocate in the tube 1 .

And a head cover 6 having an orifice 5 therein is detachably fastened to the outer end of the flange 4 formed at one end of the tube 1 by bolts.

In the conventional hydraulic cylinder, the cylinder rod 2 is moved in the tube 1 by the hydraulic oil flowing into the large chamber 1a, and part of the working oil in the small chamber 1b at the stroke end is moved to the orifice (5) to the port (7) communicating with the orifice (5). A part of the operating oil in the small chamber 1b is discharged to the port 7 through the gap 9 between the cylinder rod 2 and the head cover 6 which is opened and closed by the cushion ring 8 at the stroke end, do. As a result, the hydraulic cylinder is driven for extension.

The peak pressure generated in the small chamber 1b at the stroke end of the hydraulic cylinder can be controlled by adjusting the size of the orifice 5.

In order to adjust the size of the orifice 5, it is troublesome to separate the head cover 6 fastened to the flange 4. Further, since the size of the orifice 5 formed on the head cover 6 is fixed, the entire head cover 6 needs to be replaced in order to adjust the size of the orifice 5.

When the hydraulic cylinder is developed or manufactured, the performance of the cushioning device is affected when the internal flow rate of the equipment to which the hydraulic cylinder is mounted or the relief setting pressure is changed. The difficulty experienced during tuning as described above is a factor that develops a product or deteriorates the quality of a corresponding part, and also has a problem that parts may be damaged when the hydraulic cylinder is disassembled.

An embodiment of the present invention relates to a hydraulic cylinder in which the process of disassembling the parts of the hydraulic cylinder is unnecessary in order to adjust the cushion performance of the hydraulic cylinder.

An embodiment of the present invention relates to a hydraulic cylinder which can easily work and adjust the cushion performance of the hydraulic cylinder, thereby reducing the time and cost required for the operation.

Embodiments of the present invention relate to a hydraulic cylinder that can shorten the time required to develop a hydraulic cylinder and quickly respond to quality problems caused by peak pressure at the stroke end.

In the hydraulic cylinder according to the embodiment of the present invention,

A cylindrical tube;

A cylinder rod which is moved by the operating fluid flowing in and out of the tube and is driven for extension or contraction;

A piston coupled to one end of the cylinder rod and reciprocating in the tube, the piston dividing the tube into a large chamber and a small chamber;

A flange extending from one end of the tube and having a screw hole communicating with the small chamber and a first flow passage communicating with the screw hole;

A head cover which is fastened to the flange outer end and communicates with the first flow path to form a port through which hydraulic oil flows in and out; And

An orifice block which is interchangeably fastened to the screw hole and which communicates the first flow path and the small chamber with an orifice hole therein, the orifice block is provided with an orifice hole at the end of the stroke, And the amount of the hydraulic oil discharged into the flow path is controlled.

More preferably, the orifice ball

A second flow path formed in the orifice block to communicate with the first flow path,

And a third flow path formed in the orifice block to communicate the second flow path and the small chamber.

The orifice block

A first O-ring mounted on an upper outer surface of the orifice block to prevent hydraulic oil in the second passage from leaking to the outside,

And a second O-ring mounted on a lower outer surface of the orifice block to prevent hydraulic fluid in the small chamber from being discharged to the second flow path through the other flow path except for the third flow path.

The orifice block

A first block that is detachably coupled to the screw hole and has a second flow path communicated with the first flow path and a third flow path communicating the second flow path and the small chamber,

A second block that is detachably coupled to the third flow path lower end of the first block, a fourth flow path that communicates the small chamber and the third flow path is formed in the second block, And a seating hole on which a tool for engaging or separating the third flow path is seated is formed at the lower end of the fourth flow path.

The orifice block

A plug detachably fastened to an upper end of the screw hole,

And a block which is detachably fastened at a predetermined position below the screw hole, wherein the block has a fourth flow path formed therein for communicating the small chamber and the screw hole, and a tool for fastening or separating the block to the screw hole Is formed on the upper end of the fourth flow passage.

And a groove formed at the outer periphery of the orifice block so as to communicate with the second flow path and always communicating the first flow path and the second flow path regardless of the engagement angle of the orifice block with respect to the screw hole .

The orifice block

And a chamfered portion formed at an upper end of the orifice block to facilitate gripping by the tool when the orifice block is fastened or separated from the screw hole.

The orifice block

And a seating groove formed on an upper surface of the orifice block and on which a tool for fastening or separating the orifice block to the screw hole is seated.

The embodiment of the present invention configured as described above has the following advantages.

When controlling the peak pressure generated at the stroke end, the cushion performance is adjusted by replacing only a part of the parts in a state where the hydraulic cylinder is assembled, so that the loss of the material due to the disposal of the parts of the head cover can be prevented.

In addition, since it is easy to adjust the cushion performance of the hydraulic cylinder, the time required for the operation is shortened, so that convenience and practicality can be ensured.

In addition, as the working time and cost required for tuning are reduced, the development of a new hydraulic cylinder is easy, and quality deterioration due to the peak pressure generated at the stroke end can be prevented.

1 is a schematic view of a hydraulic cylinder according to the prior art,
2 is a perspective view of an orifice device mounted on a hydraulic cylinder according to an embodiment of the present invention,
3 is a sectional view of an orifice device mounted on a hydraulic cylinder according to an embodiment of the present invention,
4 is a schematic view of a hydraulic cylinder according to an embodiment of the present invention,
5 is a schematic view of a hydraulic cylinder according to another embodiment of the present invention,
FIG. 6 is a use state of the hydraulic cylinder shown in FIG. 5,
7 is a schematic view of a hydraulic cylinder according to another embodiment of the present invention,
8 is a use state diagram of the hydraulic cylinder shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, which are intended to illustrate the present invention in a manner that allows a person skilled in the art to easily carry out the invention. And does not mean that the technical idea and scope of the invention are limited.

In the hydraulic cylinder according to the embodiment of the present invention shown in Figs. 2 to 4,

A cylinder rod (2) which is stretch-driven or shrink-driven is accommodated movably by a working oil introduced into and discharged from a cylindrical tube (1) through a port.

A piston 3 partitioning the inside of the tube 1 into a large chamber 1a and a small chamber 1b is screwed to one end of the cylinder rod 2 so as to reciprocate in the tube 1 .

A flange 4 formed by welding at one end of the tube 1 has a screw hole 10 communicating with the small chamber 1b and a first flow passage 11 communicating with the screw hole 10 .

A port 7 is formed in the head cover 6 which is detachably connected to the outer end of the flange 4 by means of bolts 12 to communicate with the first flow path 11 to allow the hydraulic fluid to flow in and out.

An orifice block 14 (a thread portion corresponding to the screw hole 10 formed in the outer peripheral edge) for communicating the first flow path 11 and the small chamber 1b with the orifice hole 13 in the inside So as to be replaceable in the hole 10. The amount of the hydraulic fluid discharged from the small chamber 1b to the first flow path 11 is controlled by the orifice hole 13 at the stroke end of the cylinder rod 2. [

As in Figures 3 and 4, the orifice hole 13

A second flow path 13a formed in the orifice block 14 to communicate with the first flow path 11 and a second flow path 13b formed in the orifice block 14 to communicate the second flow path 13a and the small chamber 1b. And a third flow path 13b formed in the second flow path 14.

2 and 3, a first O-ring 15 for preventing the hydraulic oil in the second flow path 13a from leaking to the outside is mounted on the upper outer surface of the orifice block 14. [ A second O-ring 16 for preventing the working fluid in the small chamber 1b from being discharged to the second flow path 13a through the other flow path except for the third flow path 13b, And is mounted on the lower outer side surface.

As shown in FIGS. 5 and 6, the orifice block 14 includes a first block 14a that is detachably coupled to the screw hole 10 by screwing (corresponding to the screw hole 10 on the outer circumference) And a second block 14b which is detachably fastened by screwing to a third flow path 13b formed at the lower end of the first block 14a And a threaded portion corresponding to the screw hole of the third flow path 13b is formed in the periphery).

A second flow path 13a communicating with the first flow path 11 and a third flow path 13b communicating between the second flow path 13a and the small chamber 1b are formed in the first block 14a, Respectively.

And a fourth flow path 17 communicating the small chamber 1b and the third flow path 13b is formed in the second block 14b while the second block 14b is connected to the third flow path A seating hole 18 in which a tool (for example, an L-shaped wrench) is seated is formed at the lower end of the fourth flow path 17.

7 and 8, the orifice block 14 includes a plug 19, which is detachably fastened to the upper end of the screw hole 10 by screwing And a block 20 (a thread portion corresponding to the screw hole 10 is formed on the outer circumference of the block 20) to be detachably fastened at a predetermined position below the screw hole 10 by screwing.

A fourth flow path 17 for communicating the small chamber 1b with the screw hole 10 is formed in the block 20 so that the block 20 is fastened to the screw hole 10 A seating hole 18 on which a tool for separating (referred to as an L-shaped wrench) is seated is formed on the upper end of the fourth flow path 17.

2 and 3, when the orifice block 14 is fastened to the screw hole 10, the first flow path 11 and the second flow path 12, regardless of the fastening angle of the orifice block 14, A groove 21 for always connecting the flow path 13a is formed at the outer peripheral edge of the orifice block 14 so as to communicate with the second flow path 13a.

2, when the orifice block 14 is fastened to or separated from the screw hole 10, a chamfered portion 22 for facilitating gripping by a tool (for example, a monkey wrench) For example.

Although not shown in the drawing, a seating groove on which a tool (for example, a L-wrench) for seating or separating the orifice block 14 to or from the screw hole 10 is seated on the upper surface of the orifice block 14 .

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, examples of using a hydraulic cylinder according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 to 4, when hydraulic oil flows into the large chamber 1a through a port (not shown) and the cylinder rod 2 is moved to the left in the drawing and moved to the stroke end position, A part of the operating oil in which the pressure in the small chamber 1b is raised passes through the orifice block 14 and is discharged to the port 7.

That is, at the stroke end, a part of the operating oil in the small chamber 1b flows through the third flow path 13b and the second flow path 13a of the orifice block 14, the first flow path 11 of the flange 4, - port (7), and is discharged to the outside.

At the same time, at the stroke end, a part of the operating oil in the small chamber 1b flows into the port 7 through the gap 9 between the cylinder rod 2 and the head cover 6 which are opened and closed by the cushion ring 8, . As a result, the hydraulic cylinder is driven to contract.

On the other hand, when the cushion ring 8 is moved to the inside of the head cover 6, the amount of hydraulic oil flowing out of the small chamber 1b is reduced, so that the moving speed of the hydraulic cylinder is retarded at the stroke end.

Due to the stroke end of the hydraulic cylinder, a peak pressure higher than the set relief pressure is generated in the small chamber 1b. At this time, the peak pressure generated in the small chamber 1b can be adjusted by adjusting the size of the orifice hole 13 (referred to as the second and third flow paths 13a and 13b) formed in the orifice block 14 .

That is, the size of the orifice hole 13 can be adjusted without separating the head cover 6 from the flange 4. After the orifice block 14 fastened to the screw hole 10 formed in the flange 4 is separated and the orifice diameter formed so as to maintain an arbitrary set pressure in the small chamber 1b at the stroke end Can be replaced with another orifice block having a different orifice.

When the orifice block 14 is replaced with the screw hole 10 of the flange 4, the second flow path 13a of the orifice hole 13 (consisting of two holes communicating in the + direction) Can always communicate with the first flow path (11) formed in the flange (4).

That is, when the orifice block 14 is fastened to the screw hole 10, the groove 21 formed at the outer periphery of the orifice block 14 presses the first flow path of the flange 4 11 and the second flow path 13a of the orifice block 14 always coincide with each other.

After the orifice block 14 having the orifice hole 13 formed therein is replaced with an arbitrary size in the screw hole 10 as described above, the head cover 6 is fixed to the flange 4), the head cover 6 can be reused.

5 and 6, the orifice block 14 includes a first block 14a detachably engaged with the screw hole 10 of the flange 4, And a fourth flow path 17 which is threadedly engaged with the lower end of the third flow path 13b of the first block 14a and is in communication with the small chamber 1b and the third flow path 13b And the second block 14b.

Accordingly, at the stroke end of the hydraulic cylinder, a part of the operating oil of the small chamber 1b flows through the fourth flow path 17 of the second block 14b, the third flow path 13b of the first block 14a, Passes through the second flow path (13a) in turn, and is moved to the first flow path (11) of the flange (4). At the same time, a part of the operating oil of the small chamber 1b is transferred to the port 7 through the gap 9 between the cylinder rod 2 and the coupling hole of the head cover 6.

When adjusting the size of the orifice for controlling the amount of the hydraulic fluid discharged from the small chamber 1b to the port 7 during the stroke end, the orifice block 14 is inserted into the screw hole 10 of the flange 4 The orifice block having the orifice (referred to as the fourth flow path 17) formed therein can be engaged with the screw hole 10 so as to maintain the set pressure in the small chamber 1b at the stroke end have.

7 and 8, the hydraulic cylinder of the present invention is characterized in that the orifice block 14 includes a plug 19 detachably fastened to the upper end of the screw hole 10, And a block 20 in which the small chamber 1b and the fourth flow path 17 for communicating the screw hole 10 are formed.

A part of the operating oil of the small chamber 1b passes through the fourth flow path 17 and the through hole 10 of the block 20 in order to prevent the flow of the hydraulic fluid from the flange 4 And is transferred to the one flow path 11. At the same time, a part of the operating oil of the small chamber 1b is moved to the port 7 through the gap 9 between the cylinder rod 2 and the head cover 6.

When adjusting the size of the orifice for adjusting the amount of the operating oil discharged from the small chamber 1b to the port 7 during the stroke end, the plug 19 is separated from the screw hole 10 of the flange 4 And the block 20 is separated from the screw hole 10. After the block 20 having the orifice (referred to as the fourth flow path 17) is coupled to the lower end of the screw hole 10 so as to maintain the set pressure in the small chamber 1b at the stroke end, And can be coupled to the plug (19) at the upper end of the screw hole (10).

One; tube
2; Cylinder rod
3; piston
4; flange
5; Orifice
6; Head cover
7; port
8; Cushion ring
9; gap
10; Napong
11; The first euros
12; volt
13; Orifice ball
14; Blocks for orifices
15; First O-ring
16; Second O-ring

Claims (8)

A cylindrical tube;
A cylinder rod which is moved by the operating fluid flowing in and out of the tube and is driven for extension or contraction;
A piston coupled to one end of the cylinder rod and reciprocating in the tube, the piston dividing the tube into a large chamber and a small chamber;
A flange extending from one end of the tube and having a screw hole communicating with the small chamber and a first flow passage communicating with the screw hole;
A head cover which is fastened to the flange outer end and communicates with the first flow path to form a port through which hydraulic oil flows in and out; And
An orifice block which is interchangeably fastened to the screw hole and which communicates the first flow path and the small chamber with an orifice hole therein, the orifice block is provided with an orifice hole at the end of the stroke, And the amount of hydraulic fluid discharged from the hydraulic cylinder is controlled. 2. The apparatus of claim 1, wherein the orifice ball
A second flow path formed in the orifice block to communicate with the first flow path,
And a third flow path formed in the orifice block to communicate the second flow path and the small chamber. 3. The apparatus according to claim 2, wherein the orifice block
A first O-ring mounted on an upper outer surface of the orifice block to prevent hydraulic oil in the second passage from leaking to the outside,
And a second O-ring mounted on a lower outer surface of the orifice block to prevent hydraulic fluid in the small chamber from being discharged to the second flow path through the other flow path except for the third flow path. . 2. The apparatus according to claim 1, wherein the orifice block
A first block that is detachably coupled to the screw hole and has a second flow path communicated with the first flow path and a third flow path communicating the second flow path and the small chamber,
A second block that is detachably coupled to the third flow path lower end of the first block, a fourth flow path that communicates the small chamber and the third flow path is formed in the second block, And a seating hole in which a tool for engaging or disengaging the third flow path is seated is formed at the lower end of the fourth flow path. 2. The apparatus according to claim 1, wherein the orifice block
A plug detachably fastened to an upper end of the screw hole,
And a block which is detachably fastened at a predetermined position below the screw hole, wherein the block has a fourth flow path formed therein for communicating the small chamber and the screw hole, and a tool for fastening or separating the block to the screw hole Is formed at the upper end of the fourth flow path. 3. The apparatus according to claim 2, further comprising a second flow path formed at the outer periphery of the orifice block so as to communicate with the second flow path, and the first flow path and the second flow path are always communicated with each other regardless of the fastening angle of the orifice block with respect to the screw hole Wherein the groove is provided with a groove. 2. The apparatus according to claim 1, wherein the orifice block
And a chamfered portion formed at an upper end of the orifice block to facilitate gripping by the tool when the orifice block is fastened to or separated from the screw hole. 2. The apparatus according to claim 1, wherein the orifice block
And a seating groove formed on an upper surface of the orifice block and on which a tool for engaging or disengaging the orifice block with the screw hole is seated.

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