DE2327320C3 - Reusable eventU - Google Patents

Description

The invention relates to a multi-way valve with a

is axially adjustable in a central hole in the housing Closure member to which a control membrane is assigned at each axial end, which the movable Wall of a control room connected to the control line on the central bore facing away from the side of the control membrane and forms in the region of its two axial ends between the Control diaphragms Holding diaphragms made of plastic with elastic or rubber-like properties are assigned, each with its outer circumference on the housing and with its central area below a radial compressive bias are attached standing on the closure member, and this bistable in its Hold end positions. Valve assemblies with the above features are z. B. from DE-OS 20 61 545 became known, but the mounting membranes shown there have such a shape that they neither can properly perform a snap function, are still able to move the locking member into the Determine end positions.

In the case of the liquid or gas valve according to AT-PS 2 55 856, the valve disk is with the help of a membrane suspended, with which a certain step function can be determined, but a pronounced holding function does not exist. This known membrane is thickened in its central area and faces laterally subsequent weakening zones, so that it gives a wavy picture, otherwise it is asymmetrical formed, so that when snapping over there is a relatively undefined deformation in all areas and no pronounced holding effect can be achieved, quite apart from the fact that as a result of the asymmetry the effect in both directions of movement is also different.

The FR-PS 10 01984 finally shows a membrane-shaped Sealing ring for roller bearings made of thin-walled sheet metal, which has notches that give it a give a certain elasticity to a certain sheet metal thickness, which is necessary because of the possible wear and tear. This sealing ring, which has neither a snap function nor a holding function, has a central part that do not assume different end positions, but only exert a spring effect and no radial forces can accommodate.

The aim of the present invention is against this in creating an arrangement of the type in question in which the retaining membranes not only a flawless and precise, good snap function, but also a safe holding function with regard to the closure member.

For the above purpose it is provided according to the invention in the new arrangement that each retaining membrane between the

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Valve housing clamped to the outer circumference Axis of the closure member has concentric annular reinforcing area that extends between two each serving as an elastic joint is located weakening zones, each through on each side of the Diaphragm are formed exactly opposite one another arranged annular grooves.

The arrangement according to the invention has the advantage that a perfect, good snap action at Achieved simple structure and the closure member in the two end positions determined safely and precisely can be. Set the two weakening cones real joints, while the reinforcement area contained between them is essentially rigid remains and is tensioned between the two joint points and, so to speak, represents a stiffening that the Closure member clamped in its end position The snap function is controlled by the weakening zones fulfilled, in the end positions the reinforcement area acts as a stiffening lever and takes over the hold function.

In the drawing, an embodiment of the subject matter of the invention is shown

F i g. 1 shows a multi-way valve according to the invention in a side view in an axial section and

F i g. 2 a retaining membrane of the multi-way valve according to FIG. 1 in a non-clamped state in a Side view in an axial section

The multi-way valve has in the central bore 1 of the housing 2 is an axially adjustable closure member 3. This closure member is on the one hand on each axial End of a control membrane 4, 5 assigned, which the movable wall of a with the control line 6 and 7 in Connected control chamber 8 or 9, which faces away from the central bore 1 Side of the membrane 4 or 5 is located and which can be acted upon in this way by the control pressure. That Closure member is in the region of its two axial ends within the bore 1 containing it With the aid of retaining membranes 10, U suspended in a floating manner, the outer circumference of which is attached to the housing and are attached to the closure member with their central region and which, viewed from the center of the closure member, the respective control diaphragms 4, 5 are connected upstream in such a way that each retaining membrane 10, 11 has its associated control membrane shields in every position against the working pressure that arrives through line 12. These Haltiungsmembranen are designed so that they Lock member securely determine in the two end positions and move from one end position to the Move over the other end position correctly and snapping precisely under the influence of the control pressure. the special design of these retaining membranes with the purpose of a particularly safe and precise Achieving snap motion will be described in more detail below. The multi-way valve according to F i g. 1 is designed as a five-way valve, the central bore in the valve housing has as M «from the valve to controlling ways. Four poppet valve seats 13, 14, 15, 16 are assigned to the closure member, so there are "n-1" poppet valve seats surrounding the closure member in a coaxial arrangement, leaving free play intended. In contrast, the closure member has three sealing rings 17, 18, 19, ie "n-2" sealing rings. Of these sealing rings, the ring 18 is as Double seat locking piece formed. However, the arrangement can also be made so that "n-1" Sealing rings are provided if all sealing rings are designed as single seat closure pieces

In Fig. 2, the retaining membrane 10 is shown by itself in the non-clamped state. It is closed recognize that each retaining membrane is located between the central region 20 and 20 attached to the closure member the clamped on the valve housing outer circumference 21 has a reinforcement area 22 between two each serving as an elastic joint weakening Zones 23,24 is arranged and has an annular shape Like these weakened zones too. It is further provided that the mounting membranes are under a radial compressive prestress in the installed state, which is approximately in the direction of the arrows 25a, 250 acts This radial preload is achieved by the outer diameter "D" of the membrane is greater than the inside diameter of the valve body on the

Clamping point, that is, greater than "Di" (Fig. 1) The plastic with elastic or rubber-like

properties, e.g. from copolymers with Acrylonitrile or chloroprene polymers are existing retaining membranes as rotationally symmetrical Formed within the manufacturing tolerances, they are absolutely symmetrical, which affects the body Functional accuracy has an advantageous effect The two weakening zones 23, 24 are formed by two concentric annular grooves 26a, 26f> or 27a, 276 with two annular grooves - the annular grooves 26a and 28b and the annular grooves 27a, 276 - lying opposite one another opposite sides of the membrane exactly against each other superior. The retaining membrane consists of a closure member over a certain axial length surrounding sleeve 28, which practically forms the central part of the membrane and which has the shape of a with the Closure member coaxial and on this firmly seated cylinder with axial extension and from one Plate 29, which contains the annular reinforcing area 22 and the two weakening zones 23, 24 and from the area facing the control diaphragm End of the sleeve approximately in the radial direction outwards extends and the outer circumference is clamped on the housing. At the one shown in the drawing In a special embodiment, the plate 29 of the mounting bracket is axially opposite the sleeve 28 Direction according to arrow 30 arranged eccentrically, in that the distances of the longitudinal center plane 31 of the plate to both end-face end planes, that is, the distances a and ösich are 1 to 1.5 to 3 to 3.5. The entire axial length of the sleeve, i.e. the length L, relates to the thickness ß of the plate approximately as 4 to 5 to 1 to 1.5, preferably as 4.5 to 1.2. The relationship between the outer diameter D of the plate and the outer diameter d of the sleeve is roughly 2 to 3 to 1, preferably 10 to 4. The sleeve here has a part in each case that corresponds to the Sealing ring 17 or 19 represents, so that the sealing ring with the retaining membrane, as in F i g. 1 and 2 is integrally connected. The annular grooves can have a rectangular cross section have, with those shown in the drawing Embodiments, the bottom of the ring grooves is light curved inward, these have an inwardly limited by an arcuate contour Cross-section (see Fig. 2). These embodiments may be different from a manufacturing standpoint have special meaning. The depth t of each annular groove is related to the thickness B of the reinforcement area as 1 to 3 to 5, preferably 1 to 4, the width b \ of each R-iri ^ niit vsr is 7ϋΐτϊ «^» ußsnciiirchms ⁰ * '' * ¹ * ^ r \ ** e

Plate roughly like 1 to 20. The distance c of the outer edge of the outer annular groove 26a or 26b from the outer circumference of the plate corresponds roughly to the width of this annular groove, ie the width b 1, while the distance e between the two center lines of the two annular rods increases; The outer diameter D of the plate is roughly 1 to 2 to 3, preferably 1 to 2.5. The distance / between the inner edge of the inner ring groove 27a, 27b and the outer edge of the outer ring groove 26a, 266 corresponds approximately to half the outer radius D / 2 of the plate, the inner edge of the inner ring groove is contained approximately in the circumferential surface of the sleeve. This special design and dimensioning of the retaining membrane has the greatest influence on the precision of the snap movement, which means that the membrane can only arch so much that, on the one hand, the correct and precisely snapping transfer from one end position to the other end position is ensured under all circumstances and on the other hand the service life is not in question even with frequent use, with high switching frequency

The cylindrical inner bore 35 of the sleeve, through which the closure member 3 is inserted, has a diameter d \ which is related to the outer diameter D of the plate as 1 to 6 to 7. This cylindrical inner bore of the sleeve also has an approximately flat cylindrical widening 36 on the side facing away from the sealing ring, which serves to receive an annular collar 37 on the closure member and whose radius r is greater than that of the inner bore of the sleeve by an amount approximately the width of the annular groove is equivalent to. The axial length / 1 of the extension 36 corresponds approximately to the width of an annular groove. At its end face, which represents the sealing ring, the sleeve has an annular projection 40 in the form of a sealing lip, which has an axial length that is approximately 1 to 7 to 9, preferably 1 to 8, relative to the overall length of the sleeve, this ring-like sealing lip compared to the The longitudinal center axis of the sleeve runs obliquely, preferably at an angle of 15 ° to this, in such a way that it extends approximately the jacket of a protruding from the sleeve

ίο Forms a truncated cone extending in the direction of the Sleeve tapered off. This shape of the sealing lip is best shown in FIG. 2 can be found. Serves in use the sealing lip 40 to fit snugly against the closure member, as shown in FIG. 1 can be seen, where they due to its inclined course on the circumference of the closure member rests under a certain bias and thus guarantees a particularly good seal.

In the non-clamped state of the membrane - for example as shown in FIG. 2 - the Longitudinal center plane of the plate at right angles to the longitudinal center axis of the sleeve, the lateral end surfaces of the plate form a right angle with the circumference of the sleeve. In the clamped state of the membrane however, if this takes about the one shown in FIG. 1, which is probably due primarily to the Preload with which the membrane is inserted into the housing and sits in it at the clamping points, can be attributed to: Here the longitudinal center plane of the plate runs obliquely to the longitudinal center axis of the sleeve,

and between obliquely outwards and towards the center of the closure glass seen out, with this longitudinal center axis of the sleeve in the direction of the center of the housing seen an acute angle λ ζ. B. forms from 60-80 °.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Multi-way valve with a closure member axially adjustable in a central bore in the housing, to which a control diaphragm is assigned at each axial end, which forms the movable wall of a control chamber in communication with the control line on the side of the control diaphragm facing away from the central bore and which in the Area of its two axial ends between the control diaphragms are assigned holding diaphragms made of plastic with elastic or rubber-like properties, each of which is fastened with its outer circumference on the housing and with its central area under a radial compressive bias on the closure member and keeps this bistable in its end positions, thereby characterized in that each retaining membrane (10,11) has an annular reinforcing area (22) concentric to the axis of the closure member between the central area (20) attached to the closure member (3) and the outer circumference (21) clamped on the valve housing, de r is located between two weakening zones (23, 24), each serving as an elastic joint, which are each formed by two annular grooves (26a, 266, 27a, 27b) arranged exactly opposite one another on each side of the membrane. 2. Multi-way valve according to claim 1, characterized in that the annular grooves (26a, 26b, 27a, 27b), seen in cross section, have a rectangular shape. 3. Multi-way valve according to claim 1, characterized in that the bottom of the annular grooves (26a, 266,27a, 27b), seen in cross section, is slightly concave. 4. Multi-way valve according to one of claims 1 to 3, in which the Halterungsme mbran from a the closure member over a certain axial length surrounding and a sealing ring forming sleeve in the form of a coaxial with the closure member and firmly seated on this cylinder with axial extension and from a one-piece with the sleeve connected plate, which extends from the area of the end of the sleeve facing the control membrane approximately in the radial direction outward and the outer circumference is clamped on the housing, characterized in that the outer diameter (D) of the plate increases to the outer diameter (d) of the sleeve is approximately 2 to 3: 1, preferably 10: 4, that when the retaining membrane is not clamped, the longitudinal center plane of the plate runs at right angles to the longitudinal center axis of the sleeve and that the outer diameter of the plate is greater than the inner diameter of the valve housing at the clamping point, in such a way that in the clamped state the H aging membrane, seen in longitudinal section, the plate forms an acute angle of 60-80 ° with the longitudinal center axis of the sleeve. 5. Multi-way valve according to one of claims I to 4, characterized in that the depth (t) of each annular groove (26a, 26Z) _1, 27a, 27b) extends to the thickness (B) of the reinforcement area such as 1: 3 to 5, preferably 1 : 4, and the width (b \) of each ring groove is related to the outer diameter (D) of the plate about 1:20, that the distance (c) of the outer edge of the "O Dtnivniit fVLn Ό £ A 1 _{t. M} UUUU Wl l \ lllgllUl ^ KUH ₁ ^ tSLy VUtIl Plate corresponds approximately to the width (b \) of this annular groove and the distance (e) between the center lines of the two annular grooves to the outer diameter (D) of the plate is roughly 1: 2 to 3, preferably 1: 2J and that the distance ( f) between the inner edge of the inner annular groove (27a, 27b) contained approximately in the circumferential surface of the sleeve and the outer edge of the outer annular groove (26a, 266; corresponds approximately to half the outer radius of the plate