KR20170073128A - Hydraulic valve - Google Patents

Abstract

An embodiment of the present invention relates to a hydraulic valve wherein a hydraulic valve in which a spool is switched by a pressure of a fluid is provided with a flow passage formed in the spool and through which a fluid passes, a back pressure chamber disposed at one side of the spool, A switching pressure chamber disposed on the other side of the spool and a flow path provided on one end of the spool opposite to the back pressure chamber for varying a flow path of fluid passing between the flow path and the back pressure chamber, And a check part for moving the moving speed of the spool moving to the chamber relatively faster than the moving speed of the spool when moving from the switching pressure chamber toward the back pressure chamber.

Description

Hydraulic Valve {HYDRAULIC VALVE}

An embodiment of the present invention relates to a hydraulic valve, and more particularly, to a hydraulic valve in which a spool is moved by a pressure of a fluid.

Generally, the hydraulic valve moves the inner spool due to the inflow or discharge of the fluid. Specifically, the hydraulic valve feeds the fluid to the selected device, allowing the selected device to operate.

Accordingly, when a plurality of devices are connected to the hydraulic valve, the spool inside the hydraulic valve is switched so that fluid is supplied to any one of the plurality of devices in accordance with the pressure of the fluid.

However, in general, when the spool of the hydraulic valve is switched to supply fluid to any one of the plurality of apparatuses, and when returning to the original position or the neutral position again, the transfer speed of the spool is the same.

That is, when the feed speed of the spool at the time of change and the feed speed of the spool at the time of neutral or return are the same, the operator stands by until the neutral or spool feed is returned to the original position. Such waiting time is required not only for the fatigue of the operator but also for the unnecessary time in the work process.

That is, the conventional fluid valve has a problem that the responsiveness is reduced when the spool is returned to the neutral position or the original position after switching the spool.

Embodiments of the present invention provide a fluid valve that can improve the transfer speed of the spool when the spool is returned to its neutral or original position after switching of the spool.

According to the embodiment of the present invention, the hydraulic valve in which the spool is switched by the pressure of the fluid includes a flow passage formed in the spool and through which the fluid passes, a back pressure chamber disposed at one side of the spool, A switching pressure chamber disposed on the other side of the pressure chamber, and a flow passage provided on one end of the spool opposite to the back pressure chamber to change a flow path of fluid passing between the flow path and the back pressure chamber, And a check part for moving the moving speed of the moving spool relatively faster than the moving speed of the spool when moving from the switching pressure chamber toward the back pressure chamber.

The check unit may include a check body provided at a hollow portion of the spool, the hollow portion of which is formed at one end of the spool, a first orifice provided at one side of the check body and communicating with the flow path, A check elastic member provided at one end of the spool so as to restrict movement of the check elastic member and the check body, and a plug provided at one side of the check body and the first orifice And a second orifice formed in an intersecting direction and selectively communicating with the flow passage by the check elastic member.

Alternatively, the check unit may include a check body installed at a spool hollow formed at one end of the spool and having a hollow shape, a first orifice installed at one side of the check body and communicating with the flow path, and a second orifice provided at the other side of the check body A check elastic member provided at one end of the spool so as to restrict movement of the check elastic member and the check body; and a check elastic member provided on an outer peripheral surface of the check body, And a second orifice selectively communicating with the flow path by a member.

Also, the second orifice may have a groove formed along the longitudinal direction of the check body radially from the center of the check body.

Further, the cross-section of the groove may be a square.

Alternatively, the cross-section of the groove may be deeper than the width.

Alternatively, the cross-section of the groove may be wider than the depth.

According to the embodiments of the present invention, the fluid valve effectively improves the conveyance speed of the spool, thereby effectively improving the responsiveness when the spool is returned to the neutral position and the running position.

1 is a view illustrating a hydraulic valve according to an embodiment of the present invention.
2 is a view showing a check body according to a first embodiment of the present invention.
Fig. 3 is a longitudinal sectional view of Fig. 2. Fig.
4 is a view showing a check body according to a second embodiment of the present invention.
Fig. 5 is a longitudinal sectional view of Fig. 4. Fig.
6 is a view showing a check body according to a third embodiment of the present invention.
Fig. 7 is a longitudinal sectional view of Fig. 6. Fig.
8 is a view showing a check body according to a fourth embodiment of the present invention.
Fig. 9 is a longitudinal sectional view of Fig. 8. Fig.
FIG. 10 and FIG. 11 are views showing a switching operation of the hydraulic valve according to an embodiment of the present invention.
12 is a diagram illustrating a neutral or running return operation of a hydraulic valve according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures are shown exaggerated or reduced in size for clarity and convenience in the figures, and any dimensions are merely illustrative and not restrictive. And to the same structural elements or parts appearing in more than one drawing, the same reference numerals are used to denote similar features.

The embodiments of the present invention specifically illustrate ideal embodiments of the present invention. As a result, various variations of the illustration are expected. Thus, the embodiment is not limited to any particular form of the depicted area, but includes modifications of the form, for example, by manufacture.

Hereinafter, a hydraulic valve 101 according to an embodiment of the present invention will be described with reference to FIG.

1, the hydraulic valve 101 in which the spool 200 is switched by the pressure of the fluid according to the embodiment of the present invention is connected to the oil passage 210 and the back pressure chamber 300, A pressure chamber 400, and a check unit 500.

The flow path 210 is formed in the spool 200 and flows into the hydraulic valve 101 or through the fluid discharged from the hydraulic valve 101. Specifically, the flow path 210 guides the movement of the fluid introduced from the tank through the valve body 100 of the hydraulic valve 101, or guides the fluid inside the valve body 100 to be discharged to the tank. In addition, the flow path 210 is formed so that the fluid outside the spool 200 communicates with the inside of the spool 200.

That is, the spool 200 is installed inside the valve body 100 and moves along the inside of the valve body 100 according to the pressure of the fluid.

The back pressure chamber 300 is disposed at one side of the spool 200. In addition, the back pressure chamber 300 reserves the fluid that has flowed through the flow path 210, and feeds the spool 200 by the pressure of the stored fluid. Specifically, the back pressure chamber 300 may be disposed at one side of the valve body 100.

The switching pressure chamber 400 is disposed on the other side of the spool 200. Specifically, the switching pressure chamber 400 further includes a spool elastic member 420, a connecting member 410, and a switching pressure passage 430

The switching pressure passage 430 supplies the fluid to the other side of the spool 200 and provides power to move the spool 200 from the switching pressure chamber 400 toward the back pressure chamber 300. That is, the fluid introduced through the switching pressure passage 430 is a working fluid for moving the spool 200 from the switching pressure chamber 400 toward the back pressure chamber 300.

The spool elastic member 420 is disposed on the other side of the spool 200 and provides an elastic force when the spool 200 is moved. The spool elastic member 420 is compressed when the fluid flows from the switching pressure passage 430 so that the spool 200 is moved from the switching pressure chamber 400 to the back pressure chamber 300, When the fluid does not flow into the pressure chamber 430, the spool 200 is expanded and moved from the back pressure chamber 300 toward the switching pressure chamber 400.

The connecting member 410 connects the other end of the spool 200 to the spool elastic member 420. Specifically, the connecting member 410 allows the elastic force of the spool elastic member 420 to be transmitted to the spool 200.

The check unit 500 is disposed at one end of the spool 200. Specifically, the check unit 500 is installed at one end of the spool 200 opposed to the back pressure chamber 300 to vary the flow path of the fluid passing between the flow path 210 and the back pressure chamber 300. The check unit 500 may be configured such that when the moving speed of the spool 200 moving from the back pressure chamber 300 to the switching pressure chamber moves from the switching pressure chamber 400 toward the back pressure chamber 300, It is relatively faster than speed.

That is, when the spool 200 moves from the back pressure chamber 300 to the switching pressure chamber 400, the check unit 500 checks the flow rate of the fluid discharged from the back pressure chamber 300 through the flow path 210 to the tank The spool 200 is formed to be relatively larger than the flow rate of the fluid discharged into the flow path 210 through the back pressure chamber 300 when the spool 200 moves from the switching pressure chamber 400 to the back pressure chamber 300.

The check unit 500 checks the flow rate of the fluid discharged from the back pressure chamber 300 to the switching pressure chamber 400 through the flow path 210 and stored in the back pressure chamber 300, So that the spool 200 can move from the back pressure chamber 300 to the switching pressure chamber 400 quickly. That is, the check unit 500 can quickly return the spool 200 to the neutral position or the original position, thereby effectively solving the problems due to the fatigue of the operator and unnecessary time in the work process.

For example, the hydraulic valve 101 according to an embodiment of the present invention may be installed in a construction machine such as an excavator. Specifically, the hydraulic valve 101 performs a traveling hybrid operation in which the traveling operation and the front actuator (one of the bucket cylinder, the arm cylinder, the boom cylinder, and the pivoting device) are simultaneously performed, In the case of stopping and performing only the traveling operation, the returning speed to the neutral position of the spool 200 is improved as compared with the conventional hydraulic valve, so that the traveling operation can be effectively performed.

Accordingly, the hydraulic valve 101 of the present invention effectively solves the problems due to the fatigue of the operator and the unnecessary time in the work process due to the quick response to the neutral of the spool 200 and the faster response than the conventional hydraulic valve .

1, the check unit 500 of the hydraulic valve 101 according to the embodiment of the present invention includes a check body 510, a first orifice 521, (530) and a plug (540).

The check body 510 may be installed at one end of the spool 200. Specifically, the check body 510 may be installed in the spool hollow 230 having one end of the spool 200 formed in a hollow shape. The spool hollow 230 may be formed in a hollow shape so that one end of the spool 200 opposed to the back pressure chamber 300 communicates with the flow path 210. That is, the spool hollow 230 may be formed to guide the fluid introduced into the spool 200 through the flow path 210 into the back pressure chamber 300 to be stored therein.

The spool hollow 230 guides the fluid stored in the back pressure chamber 300 to be discharged through the flow path 210 to the tank or flows into the back pressure chamber 300 through the flow path 210 .

The check body 510 can be moved along the inside of the spool hollow 230 by the pressure of the fluid stored in the back pressure chamber 300 or the pressure of the fluid flowing from the flow path 210. Specifically, the check body 510 may be formed in a hollow shape as shown in Fig. 1 described above.

The first orifice 521 may be formed at one side of the check body 510 to communicate with the flow path 210. Specifically, the first orifice 521 may be formed at one side of the check body 510 to allow the flow path 210 and the back pressure chamber 300 to communicate with each other.

The check elastic member 530 is installed on the other side of the check body 510 to provide an elastic force to move the check body 510. 3, the check elastic member 530 may be partially inserted into the check elastic member installation area 501 formed by enlarging the inner diameter of the area where the first orifice 521 is formed, have.

The plug 540 may be installed in the spool hollow 230 formed at one end of the spool 200. The plug 540 supports the remaining portion of the check elastic member 530 and extends in the direction of the back pressure chamber 300 of the check elastic member 530 and the check body 510 moving along the inside of the spool hollow 230 It is possible to restrict movement over a certain distance.

Specifically, the plug 540 may be installed adjacent to the back pressure chamber 300 rather than the check body 510. The plug 540 is formed to have a hollow plug flow path 541 so that the flow path 210 can be communicated with the first orifice and the back pressure chamber 300.

A sealing member 500 is provided between the outer circumferential surface of the plug 540 and one end of the spool 200 so that the coupling between the spool 200 and the plug 540 can be effectively performed.

The check body 511 according to the first embodiment of the present invention may further include a second orifice 522 as shown in FIGS.

The second orifice 522 may be formed on one side of the check body 511 in a direction crossing the first orifice 521. Specifically, when the first orifice 521 is formed in a direction parallel to the center axis of the check body 511, the second orifice 522 may be formed in a direction crossing the center axis of the check body 511.

Further, the second orifice 522 can be selectively communicated with the flow path 210 by the check elastic member 530. Specifically, the second orifice 522 can be opened when the check body 511 is moved toward the back pressure chamber 300 by the fluid introduced through the flow path 210 and the check elastic member 530 is pressed have. The check elastic member 530 varies the path of the fluid passing between the flow path 210 and the back pressure chamber 300 so that fluid flows through the first orifice 521 or the first orifice 521 and the second orifice 522 ). ≪ / RTI >

That is, the fluid introduced through the flow path 210 is stored in the back pressure chamber 300 through the first orifice 521 and the second orifice 522, and the neutralization and return operation of the spool 200, So that the spool 200 can be effectively pressed from the back pressure chamber 300 toward the switching pressure chamber 400.

When the spool 200 moves in the direction of the back pressure chamber 300 from the switching pressure chamber 400, the second orifice 522 expands the check elastic member 530 and blocks the communication with the flow path 210 . Specifically, the check body 511 is formed adjacent to the spool hollow 230 so that movement of the check body 511 from the back pressure chamber 300 toward the switching pressure chamber 400 can be restricted by the check engagement step 240 having a narrow inner diameter have.

That is, when the spool 200 moves from the switching pressure chamber 400 toward the back pressure chamber 300, the fluid stored in the back pressure chamber 300 communicates with the flow path 210 through only the first orifice 521 It can be discharged to the tank.

More specifically, the amount of the fluid flowing into the first orifice 521 through the back pressure chamber 300 is greater than the amount of fluid flowing into the back pressure chamber 300 through the first orifice 521.

The first orifice 521 and the second orifice 522 can flow the first orifice 521 and the second orifice 522 into the back pressure chamber 300 through the fluid passage 210 The movement of the spool 200 in the direction in which the spool 200 is neutralized or returned can be accelerated.

When the spool 200 moves from the switching pressure chamber 400 to the back pressure chamber 300, the fluid stored in the back pressure chamber 300 is discharged to the tank through the flow path 210 only through the first orifice 521 .

In other words, since the area through which the fluid flows into the back pressure chamber 300 is larger than the area discharged from the back pressure chamber 300, the moving speed can be effectively improved when the spool 200 is neutralized and returned.

In addition, the check body 513 according to the second embodiment of the present invention may further include a second orifice 522 as shown in FIGS.

The second orifice 522 may be formed on the other side of the check body 513. The second orifice 522 may be formed radially from the center of the check body 513 in the longitudinal direction of the check body 513 along the longitudinal direction of the check body 513.

The second orifice 522 is formed on the other side of the check body 513 and is connected to the spool hollow 230 and has a spool hole 250 and a spool hollow 230 The check body 513 slides and communicates with the flow path 210.

The cross section of the groove formed in the second orifice 522 in the direction orthogonal to the central axis of the check body 513 formed in the check body 513 according to the second embodiment may be rectangular.

That is, the second orifice 522 having a square cross-sectional groove is moved in the direction of the spool expulsion hole 250 by the fluid introduced through the passage 210 to open the passage body 210, . At this time, the fluid introduced through the flow path 210 may be introduced into the back pressure chamber 300 through the first orifice 521.

Alternatively, the second orifice 522 having a square cross-sectional groove may be formed by the expansion force of the check elastic member 530 when the spool 200 is transferred from the switching pressure chamber 400 toward the back pressure chamber 300, The check valve 230 is formed adjacent to the spool hollow 230 so as to restrict movement in the direction of the change-over pressure chamber 400 by the check engaging jaws 240 having an inner diameter narrower than the spool hollow 230, 210 may be shut off. At this time, the fluid stored in the back pressure chamber 300 passes through the first orifice 521 and can be discharged to the tank through the flow path 210.

In addition, the check body 514 according to the third embodiment of the present invention may further include a second orifice 522 as shown in Figs. 6 and 7. Specifically, the check body 514 according to the third embodiment may be the same as the check body 513 according to the second embodiment, the operation method, and the arrangement structure of the second orifice 522.

The cross section of the groove formed in the second orifice 522 in the direction orthogonal to the central axis of the check body 514 formed in the check body 514 according to the third embodiment may be deeper than the width. For example, the groove cross-section of the second orifice 522 may be a substantially U-shape that is deeper than the width.

In addition, the check body 512 according to the fourth embodiment of the present invention may further include a second orifice 522 as shown in Figs. 8 and 9. Specifically, the check body 512 according to the fourth embodiment may be the same as the check body 513 according to the second embodiment, the operation method, and the arrangement structure of the second orifice 522.

The cross section of the groove formed in the second orifice 522 in the direction orthogonal to the central axis of the check body 512 formed in the check body 512 according to the fourth embodiment may be wider than the depth. For example, the groove cross-section of the second orifice 522 may be about a "U" shape that is wider than the depth.

Hereinafter, the operation of the hydraulic valve 101 according to an embodiment of the present invention will be described with reference to FIGS. 1 and 10 to 12. FIG.

A working fluid capable of moving the spool 200 from the switching pressure chamber 400 to the back pressure chamber 300 is supplied to the switching pressure passage 430 as shown in Figs. At this time, the pressure of the supplied working fluid can compress the spool elastic member 420 disposed in the back pressure chamber 300 and move the spool 200 to the switching position.

The fluid introduced into the back pressure chamber 300 through the switching pressure passage 430 compresses the spool elastic member 420 and moves the spool 200 from the switching pressure chamber 400 toward the back pressure chamber 300 . Specifically, one end of the spool 200 on which the check unit 500 is installed is moved to one side wall of the back pressure chamber 300.

At this time, the check body 510 is rotated by the pressure of the fluid stored in the back pressure chamber 300 and discharged to the external tank through the flow path 210 formed in the spool 200 and the restoring force of the check elastic member 530 And the check jaw 240 is formed. Accordingly, the second orifice 522 formed in the check body 510 is disconnected from the flow path 210.

The fluid stored in the back pressure chamber 300 sequentially passes through the plug flow path 210, the first orifice 521, and the flow path 210, and is discharged to the outside tank.

When the spool 200 is moved in the direction of the back pressure chamber 300 from the switching pressure chamber 400 in the excavator as in the above-described case, the front combined actuator may be in a traveling complex operation state in which the front actuator is starting to move.

Hereinafter, as shown in FIG. 1 and FIG. 12, operation of the hydraulic valve 101 applied to the excavator will be described when the operation of the front actuator is completed and the operator is selected as the running or neutral state.

The supply of the fluid flowing into the switching pressure passage 430 is stopped and the pressure of the fluid applied to the switching pressure passage 430 becomes equal to the atmospheric pressure.

In this case, the compressed spool elastic member 420 is expanded, and the spool 200 is moved in the direction of the switching pressure chamber 400 from the back pressure chamber 300.

The fluid flows from the external tank through the flow path 210 formed in the spool 200. At this time, the inflow fluid slidably moves the check body 510 from the spool hollow 230 toward the spool discharge hole 250. Accordingly, the check body 510 is slid in the direction of the spool expulsion hole 250 and compresses the check elastic member 530.

At this time, not only the first orifice 521 but also the second orifice 522 are communicated with the flow path 210.

That is, the fluid introduced from the flow path 210 is supplied to the back pressure chamber 300 through the first orifice 521 and the second orifice 522 so that the spool 200 is discharged from the back pressure chamber 300 to the switching pressure chamber 400). ≪ / RTI >

More specifically, the feed speed of the spool 200 when the spool 200 of the hydraulic valve 101 is changed from the back pressure chamber 300 to the traveling or neutral state in which it is moved in the direction of the switching pressure chamber 400 is controlled by the hydraulic pressure valve 101 The traveling speed of the spool 200 may be relatively faster than the traveling speed of the spool 200 when the spool 200 moves from the switching pressure chamber 400 toward the back pressure chamber 300.

That is, the feed speed of the spool 200 returning to the running or neutral state is relatively faster than the case of changing to the traveling complex state, effectively reducing the fatigue of the worker and unnecessary work time consumption.

The hydraulic valve 101 according to the embodiment of the present invention is configured such that the return speed of the spool 200 is returned to the spool 200 in the traveling complex state when the check valve 500 is returned to the neutral or running state, Can be made faster than the conveying speed of the moving spool 200, so that it is possible to reduce not only the fatigue of the operator but also unnecessary requirements in the working process.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. will be.

It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive, the scope of the invention being indicated by the appended claims, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

101: Hydraulic valve 200: Spool
230: Spool hollow 300: Back pressure chamber
400: switching pressure chamber 500: check part
510, 511, 512, 513, 514: check body 521: first orifice
522: second orifice 530: check elastic member
540: Plug

Claims (7)

A hydraulic valve in which a spool is switched by a pressure of a fluid,
A flow path formed in the spool and through which the fluid passes;
A back pressure chamber disposed at one side of the spool;
A switching pressure chamber disposed on the other side of the spool; And
And a control unit that is provided at one end of the spool opposite to the back pressure chamber and changes a moving path of the fluid passing between the back pressure chamber and the back pressure chamber so that the moving speed of the spool, Which is relatively faster than the moving speed of the spool when moving from the switching pressure chamber toward the back pressure chamber,
. The method of claim 1,
The check unit,
A check body provided in the hollow of the spool, the hollow of which is formed at one end of the spool;
A first orifice provided at one side of the check body and communicating with the flow path;
A check elastic member provided on the other side of the check body to provide an elastic force to move the check body;
A plug installed at one end of the spool to restrict movement of the check elastic member and the check body; And
And a second orifice formed on one side of the check body in a direction crossing the first orifice and selectively communicated with the flow path by the check elastic member,
. The method of claim 1,
The check unit,
A check body provided in the hollow of the spool, the hollow of which is formed at one end of the spool;
A first orifice provided at one side of the check body and communicating with the flow path;
A check elastic member provided on the other side of the check body to provide an elastic force to move the check body;
A plug installed at one end of the spool to restrict movement of the check elastic member and the check body; And
And a second orifice formed on an outer peripheral surface of the check body and selectively communicated with the flow passage by the check elastic member,
. 4. The method of claim 3,
The second orifice
And a groove formed along the longitudinal direction of the check body is formed radially from the center of the check body. 5. The method of claim 4,
Wherein the groove has a rectangular cross-section. 5. The method of claim 4,
Wherein a cross-section of the groove is deeper than a width. 5. The method of claim 4,
Wherein a cross section of the groove is wider than a depth.

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