The invention relates to a membrane valve, particularly for fluid media, having a valve body, a membrane, a pressure piece and a drive for the pressure piece, wherein the membrane is coupled to the pressure piece by means of a connecting element, wherein the connecting element comprises a wall projecting from the membrane in the direction of the pressure piece, wherein a laterally projecting latch hook is provided on one side of the wall and on the other side is provided a free space, so that the wall can get out of the way for connecting the latch hook with a corresponding receptacle.
There are known membrane valves that have a valve body having an inflow and an outflow (DE 20 2005 002 152 U1). Furthermore, the valve bodies comprise a valve seat sealable by a membrane, wherein the membrane is connected by a connecting element with a pressure piece of a drive. The known membranes can be made in one or two layers. From WO 2010/025 905 A1 is known a single-layer membrane, which may also be formed integrally with the connecting element or on which can be formed the connecting element. The membrane is made of the same plastic material as the valve body, namely of polyethylene (PE). In addition, the valve body and the membrane are connected fixedly to each other by ultrasonic welding in a fluid-tight valve body unit which can be coupled with the drive.
Due to the fixed connection of the valve body, the membrane and the connecting element to a sealed valve body unit, it is possible to form the valve body unit as a disposable unit, and to integrate the membrane valve into a disposable hose system or pre-sterilizable pharmaceutical system. The valve body unit can therefore be formed in a cost-effective way as a disposable or single-use valve body unit and be coupled to a reusable drive or connected to it. The firm connection of the membrane and the valve body seals the valve body unit during the transport phase. This avoids contamination of the valve chamber or the environment.
Due to the firm connection of the connecting elements with the membrane, the membrane can not only be pushed into its closed position but also pulled into its open position, so that the valve chamber in the valve body can be designed to be relatively large in volume and thereby, for example, a sufficiently large volume flow can be achieved for the tube systems of filtration equipment. However, it has turned out that the achievable lift between the closed and open positions is limited, because otherwise the coupling of the pressure piece and the connecting element is unintentionally released as the connecting element disengages due to too high pressure.
The invention is therefore based on the technical task to provide a membrane valve in which the membrane can perform a greater lift without the risk that the connecting element and thus the membrane decouples from the pressure piece.
This technical task is solved in a membrane valve of the type mentioned according to the invention, in that a fixed pin is provided which, with the valve seat of the valve body lifted off the membrane, engages into the free space behind the wall and, particularly in the case of the membrane resting on the valve seat, protrudes from the free space.
In the membrane valve according to the invention, the membrane is connected by a latch hook to the pressure piece, so that the coupling easily occurs in that the connecting element is snapped together with the membrane on the pressure piece. When closing the membrane valve, this type of connection does not pose any danger. If the membrane valve is opened, the membrane of the pressure piece is lifted by the connecting element from the valve seat by applying a pull to the connecting element. However, a simple snap-in connection can be released unintentionally. In the inventive solution, this is prevented in that the wall which carries the latch hook cannot get out of the way because of the pin that is present in the free space, and thus the latch hook cannot come out of its seat in the receptacle. This allows much higher tensile forces to be exerted on the connecting element and the membrane to be removed from the valve seat.
A preferred embodiment of the invention provides that the connection element is formed cup-shaped and the opening is in the direction of the pressure piece. Thereby, the forces acting on the connecting element can be easily distributed over the circumference. The connecting element is designed in the manner of a hollow locking pin.
In a further development of the membrane valve according to the invention, the cup-shaped connecting element comprises a circular cylindrical pin, wherein on its outer circumference is or are arranged the latch hook(s). Advantageously, the pressure piece is surrounded by a fixed sleeve in which the pressure piece can be moved. The sleeve thus forms a sliding sleeve for the pressure piece.
In a preferred embodiment, a transverse pin is mounted in the sleeve. This transverse pin is stationary as the sleeve itself. For receiving the transverse pin, the pressure piece comprises a breakthrough transverse to its direction of movement, which is penetrated by the transverse pin. In addition, the stationary pin is mounted on the transverse bolt. The stationary pin in turn passes through the pressure piece in its direction of movement and in the direction of the membrane. In this way, inside the displaceable pressure piece is a stationary element, which cooperates with the cup-shaped connecting element and in particular engages in it.
The free end of the fixed pin is formed in such a manner that, with the membrane lifted from the valve, it engages in the cup-shaped connecting element and bears against the inner surface of the wall. Thereby, a shift of the wall is prevented so that the latch hook does not disengage from the receiving recess even under high tensile forces. With the membrane resting on the valve seat, only when the free end of the fixed pin emerges from the cup-shaped connecting element, the connecting element and thus the membrane can be decoupled from the pressure piece and, for example, exchanged.
Further advantages, features and details of the invention become obvious from the dependent claims and the following description in which a particularly preferred embodiment is described in detail with reference to the drawing. The features shown in the drawing and mentioned in the description and/or in the claims may be essential to the invention individually or in any combination.
In the drawings:
The membrane 22 is supported on a projecting shoulder 34 of the valve body 20 which protrudes over the valve seat 32 and seals the valve body 20 relative to the drive 14 and the environment. In the embodiment, the valve body 20 is formed of polypropylene (PP), and the membrane 22 of a thermoplastic elastomer (TPE). Other materials and material combinations are possible and the invention is not limited to the aforementioned materials.
On its back side 35 facing away from the valve body 20, projects from the membrane 22 the connecting element 24 coaxially connected with the membrane 22, in particular integrated by a 2-K injection molding process, having a greater width than the valve seat 32. With the membrane valve 10 closed, the membrane 22 is formed convexly toward the valve seat 32, wherein the corresponding valve seat 32 is also formed convexly toward the membrane 22. The membrane 22 and the valve body 20 are connected to each other liquid-tight and gas-tight, in particular by ultrasonic welding, in the region of the shoulder 34.
The drive unit 16 has a substantially cup-shaped housing 36 with an adjusting spindle 38 movable in its longitudinal direction. The housing 36 can be put in a known manner from the inside, for example, on a control cabinet plate 40 and fastened from the outside by the adapter 18. On the free end 42 of the adjusting spindle 38 is screwed a pressure piece 44, whose free end in turn can be latched and unlatched with the connecting element 24.
The second region 50 of the connecting element 24 facing away from the membrane 22 is formed cup-shaped and as a locking pin 52 which serves for fastening the connecting element 24 on the pressure piece 44. For this purpose, the locking pin 52 comprises axial slots 54, whereby a total of three walls or fingers 56 are formed, which are provided at their free ends with locking lugs 58 which project radially outward. In addition, the locking pin 52 is formed hollow as a hollow pin 59. The locking lugs 58 have a distal insertion bevel 60 and a proximal shoulder 62 for locking in the pressure piece 44. The pressure piece has a receiving bore 63 (
Furthermore, it is apparent that a sliding sleeve 64 is arranged in the adapter 18, which sleeve is located coaxially to the axis of the pressure piece 44 in which the pressure member 44 is displaceable. This sliding sleeve 64 is provided with a transverse bore 66 in which a cross-bolt 68 is mounted. This cross-bolt 68 also passes through the pressure piece 44 in its breakthrough 70 extending transverse to its direction. Finally, in the pressure piece 44 is provided a coaxial bore 72, in which is mounted a sliding pin 74, whereby the pin 74 is also penetrated by the cross-bolt 68. The sliding sleeve 64, the cross-bolt 68 mounted therein and the pin 74 mounted on the cross-bolt 68 are stationary relative to the pressure piece 44, i.e. they do not perform the displacement movements of the pressure piece 44. This has the result that during the opening operation of the membrane valve 10, in which the membrane 22 is lifted from the pressure piece 44, the pin 74 remains above the locking pin 52 and the locking pin 52 comes closer to the pin 74 and finally the pin 74 engages in the cup-shaped locking pin 52.
This position of the locking pin 52, which it occupies in the open position of the membrane valve 10 is shown in
The engagement of the pin 74 starts from a lift height of 1.8 mm. Since the pin 74 at the extended pressure piece 44 does not engage the locking pins 52, a change of the membrane 22 is no problem, because the walls or fingers 56, the fingers 56 can be freely disengaged from undercuts in the pressure piece 44 bent radially inward and. It can be transmitted to the membrane 22 so much higher tensile forces.
The engagement of the pin 74 starts from a lift height of approximately 1.8 mm. Since with the extended pressure piece 44 the pin 74 does not engage in the locking pin 52, an exchange of the membrane 22 is no problem, because the walls or fingers 56 are bent radially inward and the fingers 56 can be freely disengaged from the undercuts in the pressure piece 44. There can thus be transmitted so much higher tensile forces to the membrane 22. Another advantage is seen in the fact that, since in the adapter 18 (or the spacer) the sliding sleeve 64 is used as a separate component, the membrane valve 10 can be easily mounted. Furthermore, the sliding sleeve 64 serves for exact and frictionless guiding of the pressure piece 44. A locking of the locking pin 52 is thus guaranteed even with a slanting membrane valve 10 with deviations at which the locking pin 52 may also lie eccentrically or the locking pin 52 is slightly out of round.
The valve body 20 can be used as a single-use valve body unit, for example in sterile pharmaceutical clean rooms or in the food industry. As a reusable valve body 20, it may be used in any conceivable area in which plastic valves can also be used.
Number | Date | Country | Kind |
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10 2012 222 062.3 | Dec 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/072665 | 10/30/2013 | WO | 00 |