DE4235262A1 - Ceramic slider valve for use with compressed air - has guide element with two opposed surfaces areas giving pre-set ratio arranged so compression force acting on valve discs results proportionately from force dependent force component - Google Patents

Abstract

Ceramic slider valve having a ceramic guide element (22) with two oppositely placed surface regions (A1, A2). The first region (A1) is directed away from the valve discs (6,8) and the second region (A2) is directed towards the valve discs. The ratio (A1/A2) of the surface areas, which are subject to the impact of fluid pressure, is so arranged that the compression force (F) acting to press the valve discs together results, at least in part, proportionately from a pressure-dependent force component. ADVANTAGE - Enables the actuation force to be considerably reduced, whereby the pressure dependency is more accurately definable.

Description

The present invention relates to a slide valve for Pressure media, especially for compressed air, with a valve housing with at least two connections for the pressure medium as well as with two arranged in the valve housing Ceramic material, sealingly adjacent to each other, Valve having control openings and / or recesses washers, one of them fixed in the valve housing th way disc and one for switching the connections rela tiv to the way disc movable and by means of an actuating element movable control disc.

Such a slide valve is from DE-38 32 481 A1 known. With this as a longitudinal slide valve (also Paral lelschieberventil) trained valve is the movable control disc on the side of a piston-like  Actuator supported, the actuator in turn guided longitudinally in the valve housing is. This is disadvantageous in that between the bet cleaning element and the valve housing a relatively large Friction occurs, so that a large axial actuation force (displacement force) required for valve actuation is. Usually the valve housing and / or the actuator made of plastic, which leads to that the friction occurring between these parts "unsi cher ", i.e. in terms of magnitude hardly determinable and before is predictable, so that the actuating force of the valve to valve can vary widely. In the case of a magnet termed valve this leads to a strong and thereby also large, heavy and expensive electromagnet must be used, at least for the "greatest possible friction" or the maximum expected Actuating force is to be interpreted. In the known valve the displacement force is also strongly pressure-dependent, since when pressurized, always use the valve disks with it be pressed against each other, so that also which when moving between them as well as that in Area of the actuating element occurring frictional force increases, which leads to an increase in the displacement force.

From DE 38 08 899 A1 it is in a rotary valve Switch valve known, at least one of the disc-shaped Ceramic valve elements to generate a contact pressure its upper facing away from the other valve element to consciously apply the pressure medium to the surface. Also this leads to a pressure dependence, i. H. at increasing pressure to an increase in actuation force.

The present invention is based on the object to improve a generic slide valve so that the operating force is significantly reduced, while also very precise with regard to their pressure dependence should be definable.

According to the invention, this is due to the characteristic feature le of claim 1 reached.

Thus, according to the invention, the control disk is only thereby led that they between the fixed way disc and the guide element according to the invention practically "turned spans ", so that an indirect guidance through the Betä Cleaning element can be omitted. This makes it unnecessary a piston-like guide of the actuating element, so that the actuating element is advantageously designed in this way can be that it is practically frictionless in the Ventilge engages housing and there to take with the control disc connected is. Since practically no more friction between rule the valve housing and the actuator occurs, the not exactly determined is advantageously omitted bare frictional force between these parts. This is the Actuating force essentially only depends on the Frictional forces between the movable control disc and the way disc on the one hand and the Füh invention on the other hand. These force components are each but because of the smooth surfaces of the ceramic material only very small and also except by the invention neatly definable. Because of the two opposite, pressurizable areas the guide element can be a pressurized resulting portion (pressure-dependent force component) of the Define the contact pressure between the valve disks very precisely  be kidneyed, in a simple way by interpretation the area areas or their size ratio. Will the two surface areas are of equal size, so results there is advantageously a pressure independence of those Contact pressure, the "base contact force" preferably from a mechanical spring element is generated, because then yes the pressure-dependent force component through compensation Becomes zero. By different interpretation of the size of the Area areas can be achieved that the contact pressure either based on the pressure-dependent force component of the basic contact pressure when pressurized increases proportionally or the base contact force reduced decoratively decreases in proportion to pressure. This described Constancy or these pressure-dependent changes in the pressure Force then act accordingly on the actuation due to the valve.

The invention thus leads to the advantage that the actuator power by reducing the internal friction (the moving parts) of the valve is very low, and also in a simple way - depending on the requirements - a print dependency (constancy with changing pressure ratio sen), a pressure proportional increase or even a pressure proportional drop in operating force can be achieved can. It can therefore - when using an electromagnet as an actuator - advantageously a very small one lighter and less expensive magnet can be used where by itself the cost of the valve according to the invention reduce overall so that the slight majority hardly any effort for the additional ceramic guide element has a significant meaning. In addition, they are through Invention achievable, small, compact construction volume and that  reduced weight of the valve an essential anyway Advantage over those known from the prior art Slide valves.

Further advantageous design features of the invention are contained in the subclaims.

The invention will now be explained in more detail below with the aid of several preferred exemplary embodiments. Since each of FIGS. 1 to 5 shows a simple, basic sectional view of one of several alternative embodiments of the slide valve according to the invention. Here, in the different figures of the drawing, the same parts and components are always provided with the same reference numerals, so that any description of a part that may occur only once also applies analogously with respect to the other drawing figures, in which this part also has the corresponding reference number he knows.

In the exemplary embodiments explained below, han it is a longitudinal slide valve for pressure air, but the invention is by no means be limits, but can in principle also with rotary valve valves and hydraulic valves are used.

As can be seen initially in Fig. 1, an OF INVENTION dung according gate valve 1 has an only partially dargestell tes valve housing 2 having an inner housing chamber 4 in which two sealingly abutting ceramic valve disks, and that a stationarily mounted paths disc 6 and a relatively movably guided on this Control disc 8 , are net angeord. The valve housing 2 has - in the illustrated embodiment of a 3/2-way valve for compressed air - three connections, namely a pressure connection P, a consumer connection A and a ventilation connection E. In the case of an embodiment for a hydraulic pressure medium, instead of the ventilation connection E to provide a tank return connection.

The connections A and E of the valve housing 2 , which cannot be seen in the drawing, are sealed off via a profile seal 10 into continuous control openings 12 , 14 of the washer 6 . The control disc 8 has in this embodiment from Fig. 1 on their side facing the way disc 6 a control recess 16 which covers the mouth area of both control openings 12 and 14 of the way disc 6 in the Darge first switching position of the valve, so that the connections A and E are connected. By means of an actuating element 18 , the control disc 8 is displaceable in the direction of arrow 20 in a second switching position, not shown, in which the control disc 8 only covers the mouth region of the control opening 14 connected to the vent connection E and thereby closes, the consumer connection A then via the control opening 12 opens freely into the housing interior 4 , into which the pressure port P also opens, so that the ports P and A are connected.

According to the invention is now also made of ceramic material, disc-shaped guide element 22 vorgese hen, which rests with a flat guide surface 24 on the way disc 6 facing away, also flat surface of the control disc 8 that the latter "sandwiched" between the way disc 6 and the inventive guide tion element 22 is held and is slidably guided.

The guide element 22 is seen within the housing inner chamber 4 in the direction of movement of the control disk 8 held stationary (z. B. between inside housing approaches 26 ), but in a direction perpendicular to the direction of movement is basically at least slightly movable gela so that via the guide element 22 one pressing force F acting perpendicular to the valve disks 6 , 8 can be generated. This contact force F is made up according to the Invention from a "basic contact force" F _K and a pressure-dependent force component. The base-contact force F _K is preferably generated by a spring element 28, wel ches on the valve discs 6, 8 side facing away from the guide element 22 between it and the valve housing 2 is arranged under spring-elastic pretension, wherein the basic contact pressure is preferably - as illustrated - has a fixed, constant value or is variable via mechanical cal, the bias of the spring element 28 adjusting means (not shown).

To generate the pressure-dependent force component, it is now provided according to the invention that the guide element 22 has two surface areas A1 and A2 which are opposite one another in the direction perpendicular to the plane of movement of the control disk 8 and thus can be pressurized in opposite directions, specifically one facing away from the valve disks 6 , 8 Surface area A1 and an opposite, second surface area A2 facing valve disks 6 , 8 . When these areas are pressurized, two opposite forces F ₁ and F ₂ result from the relationship F = pA, the difference of which then gives the pressure-dependent force component, the sum of this pressure-dependent force component and the base contact force F _K then actual contact force F results.

According to the invention, the pressurizable surface areas A1 and A2 of the guide element 22 can now be designed such that either A1 = A2, A1 <A2 or A1 <A2. This can then be achieved that the contact force F is independent of pressure, ie always corresponds to the basic contact force F _K , if namely the pressurizable surface areas A1 and A2 are the same size, because then the opposite forces F ₁ and F _{2 are} due in their opposite direction. If, on the other hand, the surface area A1 is designed to be larger than the area A2, then F ₁ also results in F ₂ , so that the base contact pressure F _{K is} increased in proportion to the pressure when pressure is applied. In a third possible case, the area A2 facing the valve disks 6 , 8 can be designed to be larger than the area area A1, as a result of which the difference in the forces F ₁ and F ₂ creates a pressure-dependent force component which counteracts the basic contact force F _K , so that when the pressure is applied, the contact pressure is reduced in proportion to the pressure based on the basic contact pressure.

These described changes in the contact pressure F then have a corresponding effect on a shifting force F _V required for shifting the control disk 8 , the shifting force resulting from the relationship F _V = 2 · F · µ (µ = friction coefficient).

The inventive guide the control disk 8 between the paths disc 6 and the Füh invention approximately element 22, the actuator 18 may be is advantageously at be formed as a simple push rod which is substantially free of friction of the valve body is guided into the housing interior space 4 through an opening 29th The actuating element 18 can be sealed in the area of the opening 29 against the valve housing 2 , so that then only a slight sealing friction occurs. However, it is particularly advantageous if the actuating element 18 is guided through the opening 29 with circumferential play and thus completely without friction, in which case an electromagnet is preferably connected on the side of the opening 29 to the valve housing 2 in such a way that the housing inner chamber 4 Via the opening 29 of the Ventilge housing 2 is connected in terms of pressure to an armature space of the electromagnet, in which case the housing inner chamber 4 and the armature space practically form a common pressure space which is sealed off from the outside. The actuating element 18 is then connected to an armature of the electromagnet. The electromagnet is not shown in the drawing. This design leads to an extremely low friction and thus also to a very low displacement force F _V.

As already mentioned, in the embodiment according to FIG. 1 the pressure connection P opens into the housing inner chamber 4 , so that this is always under the respective pressure of the pressure medium. In this case, A2 of the guide member 22 of the guide surface 24 results in the second, the valve discs 6, 8 facing, pressurizable space area from the non-covered by the control plate 8 range. An interpretation of this second surface area A2 can be made by varying the size of the guide surface 24 and the surface of the control disk 8 which bears against it. On the valve discs 6, 8 side facing away from the guide member 22 according to the invention seals such abge against the valve housing 2 via a gasket 30 so that on this side of the guide member 22, the first pressurizable surface area A1 fildichtung on the Pro 30 of an always substantially Atmos pressurized, third surface area A3 is separated. This means that the profile seal 30 separates the housing inner chamber 4 from a partial chamber 32 which is always connected to the outside atmosphere. By under different design (size) of the profile seal 30 can thus determine the size of the first surface area A1.

As can also be seen from Fig. 1, 8 side facing away from the discs shaped guide member 22 has, on its valve discs 6, parallel to the guide surface 24 surface 34, and the profile seal 30, which preferably has an approximately ring-shaped circumferential profile, is you tend on the one hand at Valve housing 2 and on the other hand to the water flat surface 34 . The profile seal 30 thereby separates the first surface area A1 from the third surface area A3, which is closed here by the profile seal 30 . Accordingly, the partial chamber 32 is located within the area enclosed by the profile seal 30 . In the sub-chamber 32 1 opens in this embodiment of FIG. Immediately a housing opening 36 through which the sub-chamber 32 is connected to the outside atmosphere, so that the third area A3 is beat with atmospheric pressure beauf.

In the embodiment according to FIG. 1, the spring element 28 is also designed as a prestressed helical compression spring and is arranged inside half of the partial chamber 32 , ie in the area enclosed by the profile seal 30 . The profile seal 30 consists of an annular base portion 38 , which sits on a cylindrical, formed as an annular web, extending inwardly into the valve housing 2 housing portion 40 , and from an obliquely outward in Rich direction of the surface 34 of the guide member 22 and the and on this sealing lip 42 . The annular web-shaped housing section 40 encloses the end of the spring element 28 facing away from the guide element 22 .

The remaining embodiments of FIGS. 2 to 5 correspond in many details to the embodiment according to FIG. 1, so that reference can be made to the above description. In the fol lowing only the essential differences are therefore to be explained in more detail.

In the embodiment according to FIG. 2, the partial chamber 32 for acting on the third surface area A3 with atmospheric pressure - instead of directly via the housing opening 36 - is indirectly connected to the outside atmosphere, namely through a through opening 44 of the guide element 22 , a continuous control opening 46 Control disc 8 , the control opening 14 of the way disc 6 and the vent connection E of the valve housing 2 . Here, the continuous control opening 46 of the control disk 8 on its side facing the guide element 22 has a mouth formed in such a way that it covers the mouth of the through opening 44 of the guide element 22 in both switching positions, so that it is ensured in both switching positions that the sub-chamber 32 with the vent port E is connected. On the other hand, the continuous control opening of the control disk 18 also fulfills its actual task of switching the connections A and E analogously to the control recess 16 according to FIG. 1.

The embodiment according to FIG. 3 corresponds to the embodiment according to FIG. 2, which affects the middle connection of the partial chamber 32 with atmospheric pressure . The arrangement of the spring element 28 in connection with the configuration of the profile seal 30 is different here. Here, the profile seal 30 consists of a cylindrical section 48 and two sealing ring webs 50 that extend radially outwards on the end face. The spring element 28 , which is made of a helical compression spring, sits here - enclosing the cylindrical section 48 - between the sealing ring webs 50 , which are thereby pressed to improve the seal against the respective sealing surfaces of the housing 2 and the guide element 22 . The profile seal 30 is seated with its cylindrical portion 48 here on the cylindrical housing portion 40 , which is here not only as a ring web, but as a bead-like housing section portion.

In the embodiment of Fig. 4, the spring member 28 and the gasket 30 are summarized according to the invention to a one Zigen element by the gasket 30 is formed so elastic that they themselves the Füh approximately element 22 with the basic contact pressure F ^K acted upon, ie, the Spring element 28 forms. In addition, the profile has in each case seal 30 here on both end sides, a sealing lip 42, wherein one of the sealing lips and the other sealing lip located 42 on the valve housing 2 42 to guide member 22, and although there preferably in a groove-shaped annular recess 52 of the guide member 22 sealingly takes hold.

In Fig. 5, yet another alternative is illustrated. In the slide valve 1 shown here is a version "energized closed", the pressure port P and the vent port E were "exchanged", so that the housing inner chamber 4 is always connected to the vent port E and thus to the outside atmosphere. As a result, the pressure port P opens via the control opening 14 of the directional disk 6 , the continuous control opening 46 of the movable control disk 8 and the through opening 44 of the guide element 22 into the sub-chamber 32 , which is divided via the profile seal 30 from the housing inner chamber 4 , always, ie in both Switch positions of the valve. As a result, the first pressurizable surface area A1 of the guide element 22 is formed in the area of the partial chamber 32 , ie in the surface area enclosed by the profile seal 30 . The outside of the profile seal 30 , third surface area A3 and the opposite, not covered by the control disk 8 area of the guide surface 24 are always subjected to atmospheric pressure from the housing inner chamber 4 . The second pressurizable surface area A2 of the guide element 22 is in this case formed by a surface area of the guide surface 24 which is covered by the mouth of the through control opening 46 of the control disk 8 . In this valve design, the control disk 8 closes the pressure connection P in the second switching position, not shown, for which purpose an electromagnet is then continuously actuated, ie switched on. In any case, the connection between the pressure connection P and the partial chamber 32 then remains.

The embodiment of FIG. 5 differs from the other versions also by a different type of Pro seal 30 , which is designed here as an O-ring and in the region of an annular recess on the cylindrical housing portion 40 is seated. The guide element 22 has an approximately cylindrical recess 54 in which the cylindri cal housing section 40 engages together with the profile seal 30 such that the seal is arranged radially between the cylindrical housing section 40 and a peripheral surface of the recess 54 sealing. The spring element 28 is then preferably designed as a helical compression spring and lies — enclosing the cylindrical housing section 40 — in the region lying outside the profile seal 30 on the guide element 22 .

The invention is not limited to the illustrated and described exemplary embodiments, but also includes all embodiments having the same effect in the sense of the invention. In this way, the individual features of the individual versions can be exchanged and combined with one another in any desired or sensible manner. Furthermore, it is also possible in the embodiments according to FIGS. 2 to 4 to interchange the connections P and E in the sense of the embodiment according to FIG. 5, the sealing lips present in each case being designed accordingly toward the pressure side (connection P).

In addition, however, the invention is also not based on the claims 1 defined combination of features limited, but can also by any other combination of certain Defi features of all individual features disclosed overall be kidneyed. This means that basically practically ever of the individual feature of claim 1 omitted or by at least one disclosed elsewhere in the application Single feature can be replaced. In this respect, the An say 1 only as a first attempt at formulation for to understand an invention.

Claims (21)

1. Slide valve for pressure media, in particular for compressed air, with a valve housing ( 2 ) with at least two connections (P, A, E) for the pressure medium and with two in the valve housing ( 2 ), made of ceramic material, sealingly adjoining, control openings and / or recesses (12, 14; 16/46) having valve disks, specifically a way disc ( 6 ) mounted in a fixed position in the valve housing ( 2 ) and one for switching the connections (P, A, E) relative to the way disc ( 6 ) movably guided and movable by an actuator (18) control disc (8), characterized by an on the directional disk (6) facing away side with a planar guide surface (24) on the cam disc (8) rest against the, also composed of ceramic material Füh approximately element ( 22 ), this guide element ( 22 ) being two opposite one another in the direction perpendicular to the plane of movement of the control disk ( 8 ) and in opposite direction Has set directions areas which can be subjected to pressure (A1, A2), namely a first surface area (A1) facing away from the valve disks ( 6 , 8 ) and an opposite second area area (A2) facing the valve disks ( 6 , 8 ), whereby the ratio (A1 / A2) of these pressurizable surface areas is designed in such a way that a pressure disc ( 6 , 8 ) pressing against each other (F) results at least in part from a pressure-dependent force component. 2. Slider valve according to claim 1, characterized in that the pressurizable surface areas (A1, A2) of the guide element ( 22 ) are of equal size, so that the pressure-dependent force component is equal to zero and the contact pressure (F) is therefore independent of pressure. 3. Slider valve according to claim 1, characterized in that the first pressurizable surface area (A1) of the guide element ( 22 ) is designed larger than the opposite de, second surface area (A2), so that the pressure-dependent force component increases the contact pressure (F) pressure-proportional. 4. Slider valve according to claim 1, characterized in that the first pressurizable surface area (A1) of the guide element ( 22 ) is designed smaller than the second surface area (A2), so that the pressure-dependent force component reduces the contact pressure (F) proportional to pressure. 5. Slide valve according to one or more of claims 1 to 4, characterized in that the guide element ( 22 ) on its side facing away from the valve disks ( 6 , 8 ) is sealed against the valve housing ( 2 ) via a profile seal ( 30 ) in such a way that this profile seal ( 30 ) separates the first pressurizable surface area (A1) from a third surface area (A3) which is essentially subjected to atmospheric pressure. 6. Slide valve according to claim 5, characterized in that the profile seal ( 30 ) has an approximately annular circumference and sealingly on the valve housing ( 2 ) and on one of the valve disks ( 6 , 8 ) facing away, preferably flat and to the guide surface ( 24 ) parallel len surface ( 34 ) of the guide element ( 22 ). 7. Slider valve according to claim 5 or 6, characterized in that the first pressurizable surface area (A1) of the guide element ( 22 ) outside the by the profile seal ( 30 ) enclosed surface area and arranged by a pressure connection (P) connected to the housing inner chamber ( 4 ) forth can be pressurized immediately. 8. Slide valve according to one or more of claims 5 to 7, characterized in that the profile seal ( 22 ), the third surface area (A3) forming surface area of the guide element ( 22 ) directly via a housing opening ( 36 ) or indirectly a Durchgangsöff opening ( 44 ) of the guide element ( 22 ), a continuous de control opening ( 46 ) of the control disc ( 8 ), a control opening ( 14 ) of the directional disc ( 6 ) and an outlet connection (E) of the valve housing ( 2 ) is acted upon by atmospheric pressure . 9. Slider valve according to one or more of claims 1 to 8, characterized in that the second pressurized surface area (A2) from a ge over the adjacent control disc ( 8 ) extending area of the guide surface ( 24 ) forms ge and from the housing inner chamber ( 4 ) can be pressurized directly. 10. Slide valve according to claim 5 or 6, characterized in that the first pressurizable surface area (A1) of the guide element ( 22 ) is formed by the surface area enclosed by the profile seal ( 30 ) and in particular indirectly via a through opening ( 44 ) of the guide element ( 22 ) , A continuous control opening ( 46 ) of the control disc ( 8 ), a control opening ( 14 ) of the way disc ( 6 ) and a Druckan connection (P) of the valve housing ( 2 ) can be pressurized with pressure. 11. Slide valve according to one or more of claims 5, 6, 10, characterized in that the second pressurizable surface area (A2) of the guide element ( 22 ) by a from the mouth of the continuous control opening ( 46 ) of the control disc ( 8 ) covered area of the Guide surface ( 24 ) is formed. 12. Slider valve according to one or more of claims 5, 6, 10, 11, characterized in that the third surface area (A3) outside the surface area enclosed by the profile seal ( 30 ) and arranged directly from one with an output connection (E ) connected housing inner chamber ( 4 ) ago with atmospheric pressure. 13. Slider valve according to one or more of claims 1 to 12, characterized in that the valve disks ( 6 , 8 ) and the guide element ( 22 ) to generate an existing base pressure force (F _K ) with an elastic preload voltage to generate are, this elastic pre-tension is preferably generated by a spring element ( 28 ) acting on the guide element ( 22 ) on its side facing away from the valve disks ( 6 , 8 ). 14. Slide valve according to claim 13, characterized in that the spring element ( 28 ) within the area enclosed by the profile seal ( 30 ) between the guide element ( 22 ) and the valve housing ( 2 ) and is preferably designed as a helical compression spring. 15. Slide valve according to claim 13, characterized in that the spring element ( 28 ) is designed as a helical compression spring and the profile seal ( 30 ) enclosing in particular between two radially outwardly extending sealing ring webs ( 50 ) of the profile seal ( 30 ) is angeord net. 16. Slide valve according to claim 13, characterized in that the profile seal ( 30 ) is designed to be elastic in such a way that it itself forms the spring element ( 28 ). 17. Slide valve according to one or more of claims 5 to 16, characterized in that the profile seal ( 30 ) sits on an approximately cylindrical, inwardly into the valve housing ( 2 ) extending housing section ( 40 ). 18. Slide valve according to claim 17, characterized in that the profile seal ( 30 ) projects beyond the cylindrical housing section ( 40 ) in the direction of the guide element ( 22 ) with an annular sealing lip ( 42 ), the sealing lip ( 42 ) preferably in a ring recess ( 52 ) of the guide element ( 22 ) engages sealingly. 19. Slide valve according to claim 17, characterized in that the cylindrical housing portion ( 40 ) with the particular O-ring formed as a profile seal ( 30 ) engages in a cylindrical recess ( 54 ) of the guide element ( 22 ), the spring element ( 28 ) is preferably formed before the cylindrical housing section ( 40 ) enclosing and in the outside of the profile seal ( 30 ) area on the guide element ( 22 ) lying helical compression spring. 20. Slider valve according to one or more of claims 1 to 19, characterized in that for moving the control disc ( 8 ) with this verbun dene actuating element ( 18 ) substantially free of friction through an opening ( 29 ) in the valve housing ( 2 ) is. 21. Slider valve according to claim 20, characterized in that the valve housing ( 2 ) is in particular pressure-tightly connected to an electromagnet such that the housing inner chamber ( 4 ) via the opening ( 29 ) of the Ventilge housing ( 2 ) pressure-wise with an armature space of the elec tromagnet is connected, wherein the actuating element ( 18 ) is connected to an armature of the electromagnet.