EP2198357A2

EP2198357A2 - Sliding valve

Info

Publication number: EP2198357A2
Application number: EP08804599A
Authority: EP
Inventors: Stefan A. Drumm; Lothar Schiel
Original assignee: Continental Teves AG and Co OHG
Current assignee: Continental Teves AG and Co OHG
Priority date: 2007-10-02
Filing date: 2008-09-23
Publication date: 2010-06-23
Also published as: US20100243941A1; US8251097B2; WO2009047115A3; WO2009047115A2; DE102008037981B4; DE102008037981A1

Abstract

The invention relates to a sliding valve having a valve slider (1) that can be axially displaced relative to the valve sleeve (3) in order to determine the size of variable passage cross-sections and for establishing a pressurization connection between a high-pressure connection (P) and a working connection (A) and a pressure-reducing connection between the working connection (A) and a low-pressure connection (T), in that control edges running in the circumferential direction are configured on the outer circumference of the valve slider (1), which interact with the control edges (5, 6) of the valve sleeve (3). According to the invention, the control edges (5, 6) of the valve sleeve (3) are configured as edges extending in the circumferential direction relative to the symmetry axis (S), which are a component of a lateral face of the valve sleeve (3).

Description

spool valve

The invention relates to a slide valve according to the preamble of patent claim 1.

From EP 1226478 Bl, such a slide valve for pressure control in a hydraulic circuit is already known, the partially hollow cylindrical, guided in a sleeve valve slide has several peripheral edges, which form in cooperation with a plurality of transverse bores of the sleeve variable hydraulic passage cross sections for pressure build-up and pressure reduction. The disadvantage here is that the areas of the circumferential valve slide edges, which are covered by the webs between the holes of the sleeve, can not be flowed through, so that a relatively large stroke of the valve spool is required to release a large passage cross-section. A further disadvantage results from the fact that the pressure medium, as it flows through the variable pressure build-up passage cross-section, experiences flow velocities whose axial component is directed counter to the flow direction present further downstream. This flow direction reversal can lead to undesirable turbulence and flow noise.

Therefore, it is the object of the present invention to improve a slide valve of the specified type such that even with a small valve spool stroke the largest possible hydraulic passage area can be released. This object is achieved according to the invention for a slide valve of the type indicated with the characterizing features of claim 1.

Further features and advantages of the invention will become apparent hereinafter from the description of an embodiment with reference to a drawing.

The basic construction and the function of the slide valve according to the invention will now be explained with reference to FIG.

The slide valve shown in longitudinal section is used to control the hydraulic pressure at a working port A to values between a low pressure and a high pressure, for which purpose an axially symmetrical valve slide 1 is received linearly movable in a valve sleeve 3. The advantageously very short valve sleeve 3 is fitted pressure-tight in a housing 4, whereby hydraulic chambers are delimited, which are connected to the low and high pressure port T, P and the working port A. The pressure-tight connection of the valve sleeve 3 and housing 4 can be realized in a known manner by static seals, but preferably a press connection - for example, the pressing a steel sleeve into an aluminum housing - which requires no further sealing measures. The pressure ports T, P, A are preferably realized by easy to produce bores.

In the exemplary illustrated first position (pressure reduction position) of the valve slide 1 of the working port A is on the one side hollow drilled valve spool 1 and arranged in the vicinity of the closed end of the valve spool 1 radial bore 9 with the Niederdruckan- Closing T connected. As will be explained below, in a second position (holding position) of the valve spool 1, the working port A is isolated from the two ports P, T, and in a third position (pressure building position) of the valve spool 1, the working port A is connected to the high pressure port P.

These three positions of the valve spool 1 are when operating the valve spool 1 under an acting in the figure to the left on the valve spool 1 Ventilansteuerkraft F in ascending order, with the shutting off and releasing the fluid connections between the pressure ports T, P, A advantageously by two on the front sides of the valve sleeve 3 circumferential low and high pressure control edges 5, 6 takes place.

In the cited prior art, circumferential control edges in the valve slide interact with radial passage windows in the valve sleeve in the lateral surface. Due to the principle, an opening of the hydraulic passage can not take place over the entire length of the slide control edge, because the passage windows in the valve sleeve are limited by webs. Therefore, it is proposed that in the valve sleeve 3 control edges 5, 6 are used for the pressure build-up and dismantling, which cooperate with the Schiebersteuerkanten that the release of the hydraulic passage cross section is uniform over the entire circumference of the guide gap between valve spool 1 and valve sleeve 3. According to the invention, therefore, the control edges 5, 6 of the valve sleeve 3 are formed as circumferential edges in the circumferential direction to the axis of symmetry S, which form a part of the lateral surface of the valve sleeve 3.

A überströmbare over the entire circumference control edge in the valve sleeve could in the cited prior art with Help of internal grooves be improved. However, this results in a manufacturing problem, because these internal grooves can be made only with great effort. This manufacturing problem can be avoided according to the invention in a surprisingly simple way by the control edges 5, 6 of the valve sleeve 3 are moved to the ends of the main bore of the valve sleeve 3 designed as a through hole. As a result, no internal grooves are more finished, but the control edges 5, 6 can be processed easily accessible at the ends of the valve sleeve 3.

To produce particularly cost-effective, the valve sleeve 3, if for the purpose of training the control edges 5, 6 in a particularly simple manufacturing process, only the two ends are ground flat.

Naturally, the greatest pressure medium speeds occur during the flow around control edges. To avoid flow noise, it is beneficial to direct the swirling occurring for flow calming in the largest possible hydraulic space. In the cited prior art, the flow from P to A is disadvantageously directed inwardly into a relatively small space, in addition to a reversal of the main flow direction. It is therefore proposed to let the pressure medium flow from P to A flow from the inside to the outside over the pressure buildup control edge. For this purpose, according to the invention, the high pressure is conducted from the port P through the valve sleeve 3 into an outer groove of the valve slide 1, and thus stands at the pressure buildup control edge "from the inside." For this a circumferential groove 12 forms a hydraulic valve on the valve slide 1 together with the jacket surface of the valve sleeve 3 Annular chamber 15, which via a radial bore 11 in the Ven- tilhülse 3 is permanently connected to the high pressure port P in connection.

The flow from inside to outside is also useful when overflowing the Druckabbausteuerkanten. But this is also the case in the prior art - only that there, the liquid jet is not immediately braked in a large hydraulic chamber, but must first flow into radial bores in the valve sleeve. A circumferential groove 13 in the valve slide 1 therefore forms together with the lateral surface of the valve sleeve 3, a hydraulic annular chamber 16, which is permanently connected via a radial bore 9 in the valve slide 1 with the working port A.

In the slide valve, the volume flow of each closed control edge is reduced by the sealing effect of a gap to an unavoidable leakage volume flow. These columns are releasable in the intended operation, any suspended particles in the pressure medium, which can settle in these columns are flushed away during a pressure control again. In addition, there is also a non-releasable sealing gap between the valve spool 1 and the valve sleeve 3, which prevents unwanted hydraulic connection of the high pressure port P with the low pressure port T. To avoid the settling of suspended particles here is a sealing ring 8 is provided, which reduces the gap flow to virtually zero, thus preventing flooding of dirt particles. The elastomeric sealing ring 8 is preferably inserted in a web 17 of the valve slide 1 which runs around the axis of symmetry S, namely in a groove arranged between the two annular chambers 15, 16, so that a hydraulic separation of the annular chambers 15, 16 is ensured. Of course, a control edge free of the entire circumference can no longer guide the slider. However, there is a simple, but not explicitly shown in Fig. 1 solution, according to which the valve slide 1 within the annular chambers 15, 16 has a plurality of radial projections which project for the purpose of radial guidance of the valve spool 1 within the axial bore of the valve sleeve 3 to the lateral surface , wherein the projections in the circumferential direction with each other and in the axial direction of the annular chambers 15, 16 delimiting circumferential webs 17 are spaced such that the hydraulic flow is not impaired.

In contrast to the cited prior art, in which the circumferential edges on the valve spool interact with flow-through radial bores in the housing, now requires the partially hollow executed piston stem of the valve spool 1 only a through-flow radial bore 9, with the circulating on the valve sleeve 3 low-pressure control edge 5 in order the illustrated pressure reduction position of the valve spool 1 (first position) to establish the pressure equalization between the working port A and the low pressure port T via the hollow piston shaft, while the high pressure control edge 6 is concealed in the illustrated pressure reduction position of the valve spool 1 by the lateral surface of the valve spool 1, whereby the high pressure port P is disconnected from the working port A. The radial bore 9 connects the axial bore in the valve slide permanently with a formed on the outside of the valve slide 1 annular chamber 16. This results depending on the slide movement, a variable passage cross section as a variable connection of the annular chamber 16 to the low pressure port T, which by moving the valve spool 1 relative to Valve sleeve 3 is also lockable. In the shut-off state, the outflow of pressure medium from the working connection A to the low-pressure connection T is prevented except for the leakage which is unavoidable in the case of a gap seal.

Thus, a displacement state of the valve spool 1 is reached, in which - apart from leakage volume flows - neither on the low pressure control edge 5 nor on the high pressure control edge 6, a pressure medium exchange is possible. As a result of this so-called positive overlap in the spacing of the control edges on the valve slide 1 in comparison to the spacing of the control edges on the valve sleeve 3, a hydraulic short circuit, that is to say an undesirable direct hydraulic flow connection from the high-pressure connection P to the low-pressure connection T, is prevented.

In a further displacement of the valve spool 1 relative to the valve sleeve 3, the connection AT remains closed while the connection PA is opened by the trained in the valve sleeve 3 high-pressure control edge 6 and formed in the valve spool 1 high-pressure control edge extending over the entire circumference of the control edges Release the passage opening.

The low-pressure control edge 5 and the high-pressure control edge 6 are preferably formed at the opposite ends of the cylindrical valve sleeve 3 and so make it particularly simple and inexpensive by surface grinding of the cylinder bottom and top surface.

This results as a result of the explained interpretation of the low pressure and high pressure control edge 5, 6 at the ends of the valve sleeve 3 at each of the two control edges 5, 6 in the open position a maximized, annular flow cross-section. Related to the valve spool stroke is so in the Released compared to the prior art much larger passage area, so that with the valve according to the invention a highly dynamic hydraulic control behavior can be achieved.

This results in a maximized, annular flow cross-section with a highly dynamic control behavior, which is immediately fully released, regardless of the size of the working stroke of the valve spool 1.

Furthermore, it is apparent from Figure 1 that at the end face of the housing 4, in which opens the working port A, a valve spring 7 is supported, the reason the valve spool 1 opposite to the Ventilansteuerkraft F in the non-actuated position, in the Ü over the Low pressure control edge 5 the overflow of the pressure medium for pressure equalization between the working port A and the low pressure port T is ensured.

In the case of a valve control force F directed to the left, the closure of the low-pressure control edge 5 is initially effected by the jacket surface of the valve slide 1 before the high-pressure control edge 6 can be released by the valve slide 1 in order to overflow the high-pressure connection P along the tapered section of the jacket surface of the valve slide 1 High pressure control edge 6 to allow the working port A. The overflow between the valve spool 1 and the valve sleeve 3 takes place radially and to a certain extent tangentially from the inside to the outside, over the radial junction of the high pressure port P, the pressure medium is initially deflected axially in the tapered portion along a circumferential groove of the valve spool 1, before it between the valve spool 1 and the high pressure control edge 6 can flow out circularly. The length of the valve sleeve 3 is determined by the axial distance between the low pressure and high pressure control edge 5, 6, whereby the valve spool 1 is guided exclusively between the low pressure and high pressure control edge 5, 6 in the valve sleeve 3. This causes even with a very tight slide fit a smooth movement of the valve spool 1, which is also guided free of transverse forces precisely in the valve sleeve 3.

The valve sleeve 3 is bounded on both sides to the low pressure and high pressure control edge 5, 6 by arbitrarily large selectable chambers 2, 10 in the housing 4, whereby the overflow of the aforementioned two control edges 5, 6, the pressure medium in each case one or the other relatively wide chamber 2, 10th flows, whereby the occurring at the overflow of the edges high flow velocities are reduced, which causes a noise-preventing flow calming, before it reaches the working pressure or low pressure port A, T.

In Figure 1, the left chamber 10 is thus axially limited by the provided with the working port A portion of the housing 4 and the high pressure control edge 6 at the left end portion of the valve sleeve 3, while the right chamber 2 from the low pressure control edge 5 at the right end portion of the valve sleeve 3 to extends axially to the wall of the housing 4.

The slider valve thus presented is thus characterized by small, function-optimized and cost-effective design. Reference symbol

1 valve slide

2 chamber

3 valve sleeve

4 housing

5 low pressure control edge

6 high pressure control edge

7 valve spring

8 sealing ring

9 radial bore

10 chamber

11 bore

12 groove

13 groove

14 transverse bore

15 ring chamber

16 ring chamber

17 footbridge

18 lids

19 stop

Claims

claims

1. slide valve arranged in a housing (4) in which hydraulic connections (A, T, P) are formed, for regulating the hydraulic pressure at a working connection (A) to values between a pressure at a low-pressure connection (T) and a pressure at a high-pressure port (P), with a valve sleeve (3) whose main bore defines an axis of symmetry (S) and a lateral surface, with a rotationally symmetrical valve slide (1) received axially movably in the main bore, the displacement position of which on the valve spool (1) acting Ventilansteuerkraft (F), as well as acting on an end face of the valve spool, pressure exerted by the working port pressure and the force of a return spring (7) is influenced, wherein the position of the valve spool (1) in the direction of the axis of symmetry (S) relative to the valve sleeve (3) the size of variable passage cross-sections of both a pressure build-up connection between the Hochdruckan conclusion (P) and a working port (A) and a pressure reduction connection between the working port (A) and the low pressure port (T) by circumferentially circumferential control edges are formed on the outer circumference of the valve spool (1) with control edges (5, 6 ) of the valve sleeve (3) cooperate, characterized in that the control edges (5, 6) of the valve sleeve (3) in the circumferential direction to the axis of symmetry (S) circumferential edges are formed, which are part of a lateral surface of the valve sleeve (3).

2. Slide valve according to claim 1, characterized in that the main bore of the valve sleeve (3) is formed as a through hole and the control edges (5, 6) are formed by mouths of the main bore in the two end faces of the valve sleeve (3).

3. slide valve according to claim 2, characterized in that the end faces of the valve sleeve (3) are designed as flat surfaces normal to the axis of symmetry (S).

4. Slide valve according to one of the preceding claims, characterized in that a circumferential groove (12) in the valve slide (1) together with the lateral surface of the valve sleeve (3) has a hydraulic annular chamber

(15), which via a radial bore (11) in the valve sleeve (3) permanently to the high pressure port

(P) communicates.

5. Slide valve according to one of the preceding claims 1 to 3, characterized in that a circumferential groove (13) in the valve slide (1) together with the lateral surface of the valve sleeve (3) has a hydraulic annular chamber

(16) which is permanently connected to the working port (A) via a radial bore (9) in the valve spool (1).

6. Slide valve according to one of the preceding claims, characterized in that in a direction of symmetry axis (S) circumferential web (17) of the valve slide (1) between the two annular chambers (15, 16) is formed a groove having a preferably elastomeric sealing ring ( 8) for hydraulic separation of the annular chambers (15, 16) receives.

7. slide valve according to claim 5 and 6, characterized in that the valve slide (1) within the annular chambers (15, 16) has a plurality of radial projections, for the purpose of radial guidance of the valve spool

(1) within the axial bore of the valve sleeve (3) protrude to the lateral surface, wherein the projections in the circumferential direction with each other and in the axial direction of the annular chambers (15, 16) delimiting circumferential webs (17) are spaced such that the hydraulic flow is not affected.

8. slide valve according to claim 1, characterized in that the Ventilansteuerkraft (F) via a mechanical contact force on the valve spool (1) is transmitted, wherein at least one surface of two force-transmitting body, preferably the surface at the end of the valve spool (1) , convex at the point of contact.

9. Slide valve according to one of the preceding claims, characterized in that the valve slide (1) and the valve sleeve (3) are introduced as a preassembled unit in a stepped bore in the housing (4), the working pressure side by a housing-fixed cover

(18) is closed.

10. Slide valve according to claim 8, characterized in that the one formed as a compression spring return spring (7) on the housing-fixed cover (18) and the valve spool (1) is supported.

11. Slide valve according to claim 9, characterized in that in the housing-fixed cover (18) has a stop (19) for Limiting the travel of the valve spool (1) is formed.

12. Slide valve according to claim 11, characterized in that for maintaining the hydraulic flow in the stop position of the valve slide (1) with at least one additional transverse bore (14) or an equivalent thereto radial fluid passage window is provided.