DE29507638U1 - Valve - Google Patents

Description

Description; Area Regler GmbH, Kempener Str. 18, 47918 Tönisvorst

Valve

The invention relates to a valve with a flow channel passing through a valve housing, a valve seat in the flow channel and a closure member that is movable relative to the valve seat, the closure member comprising a membrane.

Such valves are used in particular in the process industry, for example in the chemical, biochemical and petrochemical sectors. In these areas, particular importance is attached to the sterility of such valves. This is at risk if parts of the valve, for example the valve rod, protrude from the valve housing and must be sealed in this area by sliding seals.

Valves are known in the prior art which conventionally have a valve housing with a flow channel running through it, with a valve seat arranged in the flow channel. A closure element - usually consisting of a valve cone and a valve rod connected to it - works together with the valve seat and can be moved relative to the valve seat in order to control the volume flow through the valve (see "STlRIPAC" valves from Rohr Armaturen AG, Muttenz/Switzerland). An annular membrane is provided for sealing the housing, which is clamped to the outside of the valve housing and to the closure element on the inside. Due to this sealing, the flow channel of the valve can be easily sterilized and remains sterile even during operation, since no disruptive substances can penetrate into the flow channel from the outside, i.e. via the housing outlet of the valve rod.

If the known valve is used at high pressures, the diaphragm is subjected to high loads because a correspondingly large differential pressure acts on it. The space on the side of the diaphragm facing away from the flow channel is open to the outside so that any leaks can be detected. However, this is not sufficient for the valve to operate safely.

In addition, there are the classic diaphragm valves, in which the closure element consists of a valve rod and a diaphragm attached to the lower end, whereby the diaphragm serves to control the process fluid. Such diaphragm valves cannot be used at high pressures due to the large surface area of the diaphragm. In addition, there is the problem here that damage to the diaphragm goes unnoticed.

Another problem with valves containing membranes is that the maximum deflection is concentrated at the clamping points. However, sharp crystals of aggressive media usually build up at these points, particularly when installed vertically, and lead to premature wear, with the result that the membranes have to be replaced at regular intervals.

The invention is therefore based on the object of designing a valve of the type mentioned at the outset in such a way that an improved service life is achieved.

This object is achieved according to the invention in that the membrane encloses a cavity system between its clamps, preferably at a distance from them. This cavity system leads to a changed bending characteristic with the result that the deflections in the immediate vicinity of the clamps are reduced to a minimum. Accordingly, the wear problems described above are solved. The valve has a significantly longer service life.

In a particularly preferred embodiment, the cavity system is used according to the invention for a leak indicator. For this purpose, the cavity system is connected to a leak indicator device. If the membrane on the side of the flow channel is damaged, process fluid penetrates into the cavity system, whereby this is made noticeable from the outside by the leak indicator device. In this way, a membrane rupture or damage can be detected early from the outside so that countermeasures, such as replacing the membrane, can be taken.

The leak detection device can be designed as a sight glass that is connected to the cavity system. Instead, however, a pressure sensor that is pneumatically connected to the cavity system and coupled to the leak detection device can also be provided. Alternatively or in combination with this, a moisture sensor that is connected to the cavity system and connected to the leak detection device can also be provided.

To produce the cavity system, the membrane can consist of two membrane disks that lie on top of one another and have spaced-apart areas. One of the two membrane disks can be designed to be recessed on the inside, preferably the membrane disk on the support cavity side that is subject to less stress. To space the membrane disks apart, it is possible to provide spacers on the inside and/or outside that limit the cavity system. Alternatively or in combination, spacers can also be present in the cavity system.

The cavity system can be designed as a single cavity. However, it can also consist of interconnected channels that extend, for example, as ring grooves in the circumferential direction and/or in a star shape, i.e. radially.

The invention is applicable to all types of valves that have a membrane that is exposed to the process medium. These include in particular the classic membrane valves, but also those in which the membrane is clamped on the outside of the valve housing and on the inside of the closure member. The invention is particularly advantageous when a seal is arranged between the closure member and the valve housing on the side of the membrane facing away from the flow channel, which seal encloses a closed support cavity with the membrane, which is filled with an incompressible, deformable support medium, whereby the closure member on the side of the membrane facing away from the flow channel has such a shape that the volume of the support cavity remains essentially constant when the closure member moves. In this case, damage to the membrane is also indicated on the back, since the support medium then penetrates into the cavity system and leads to an indication by the leak detection device.

The invention is illustrated in more detail using an embodiment in the drawing. Show it!

Figure 1 a vertical section through the lower part

a valve according to the invention;

Figure 2 shows a section of the illustration according to Figure 1

with damage to the membrane on the flow channel side;

Figure 3 shows the section according to Figure 2 with support cavity

lateral damage to the membrane;

Figure 4 shows a longitudinal section through a diaphragm valve and

Figure 5 shows a cross section through the diaphragm valve according to

Figure 4.

The valve 1 shown in particular in Figure 1 has a valve housing 2 through which a flow channel 3 passes. The flow channel 3 is formed by a vertical inlet nozzle 4 protruding from below, a valve seat 5, a valve cavity 6 and an outlet nozzle 7 adjoining it horizontally.

The valve housing 2 is divided into a lower housing part 8 and an upper housing part 9, whereby the lower housing part 8 and the upper housing part 9 lie on top of one another at the separating surface 10 and are clamped together by means of several cylinder screws 11 which are distributed around the circumference. A guide space 12 with a cylindrical cross-section is formed in the upper housing part 9, in which a closure member 13 is guided.

The closure member 13 has a valve body 14 that projects into the valve chamber 6 at the bottom and a differential piston 15 arranged above it, as well as a valve rod 16. The valve rod 16 projects into the valve body 14 and is screwed there via a thread 17 in such a way that the valve body 14 is clamped against the differential piston 15 and this in turn is clamped against a shoulder 18 on the valve rod 16 in the area of the upper end of the differential piston 15. The valve rod 16 passes through a housing neck 19 and is guided there in a guide sleeve 20. Its end that projects outwards is provided with a connecting thread 21, via which the valve rod 16 can be connected to a diaphragm drive, for example.

In this area, the valve rod 16 is surrounded by a valve yoke 22, which is welded onto a base plate 22a. This is clamped against the top of the upper housing part 9 by means of a grooved nut 22b. A bellows 23 protects the exit of the valve rod 16 from the housing neck 19 against the ingress of contamination.

An annular groove is formed in the wall of the guide chamber 12, in which a sliding seal ring 24 designed as a quad ring is inserted. It rests on the outside of the differential piston 15. Another sliding seal ring 25 rests on the outside of the valve rod 16 and is arranged in an annular groove in the housing neck 19. Both sliding seal rings 24, 25 enclose the guide chamber 12, which connects to a control channel

26, which is closed to the outside by means of a screw plug

27 is blocked. After removing the screw plug 27, the control channel 26 can be used to check whether liquid has penetrated into the guide chamber 12.

The valve chamber 6 is closed at the top by a diaphragm ring 28. This is clamped in a sealing manner on the inside between the valve body 14 and the differential piston 15 and on the outside between the lower housing part 8 and the upper housing part 9. The diaphragm ring 28 is flexible and elastic, so that the vertical mobility of the closure member 13 is not significantly influenced by it.

The diaphragm ring 28 and the lower sliding seal ring 24 enclose a support cavity 29 which is completely filled with an incompressible support fluid. The support cavity 29 also includes a filling channel 30 which is closed off from the outside by a screw plug 31. The support fluid forms a counter-cushion to the process fluid which flows through the flow channel 3 during operation and prevents the diaphragm ring 28 from bulging and thus being subjected to high tensile stresses. As a result, the valve 1 can also be used in processes with high operating pressures. The support fluid preferably consists of an inert substance and can contain a physiologically harmless lubricant. This ensures a long service life of the lower sliding seal ring 24.

The special shape of the differential piston 15 has led to

ge that the volume of the support cavity 29 remains constant during the vertical movement of the closure member 13. For this purpose, the differential piston 15 has a shoulder 32, over which the cross section of the differential piston 15 is reduced towards the diaphragm ring 28. When the closure member 13 moves in the opening direction, i.e. upwards, the volume portion of the differential piston 15 that protrudes into the support cavity 29 is reduced above the shoulder 18, so that in the upper region of the support cavity 29 there is an increase in volume that corresponds to the reduction in volume caused by the raising of the diaphragm ring 28. When the closure member 13 moves downwards in the closing direction, the displacement effect caused by the retraction of the upper part of the differential piston 15 into the support cavity 29 compensates for the increase in volume due to the downward movement of the diaphragm ring 28.

The membrane ring 28 is constructed in two parts, i.e. it consists of two membrane disks 33, 34 lying on top of one another, which have the same inner and outer diameter. The upper membrane disk 33 is recessed in the area between the valve housing 2 and the closure member 13, so that a ring cavity 35 is formed. To prevent it from being compressed under pressure, spacers - for example designated 36 - are arranged in the ring cavity 35. These can be metal elements or wires.

In this view, the annular cavity 35 extends to the left into the clamping between the lower housing section 8 and the upper housing section 9, where it is connected to a leakage channel 37. This continues in the upper housing section 9 into a blind hole 38, into which a leakage screw 39 is screwed. This is penetrated by a vertical channel 40, which is connected to the leakage channel 37 and opens into a cavity at the top, which is enclosed by a sight glass 41. The sight glass 41 is attached to the leakage screw 39 using a cap nut 42.

In Figure 2 it can be seen that the lower membrane disk 34 has damage 43. Due to this damage 43, the process fluid passing through the flow channel 3 penetrates into the ring cavity 35. It flows via the leakage channel 37, the blind hole 38 and the vertical channel 40 into the cavity enclosed by the sight glass 41. In this way it can be observed from the outside whether the membrane ring 28 is damaged.

In Figure 3, the upper membrane disk 33 has damage 44. In this case, the support fluid in the support cavity 29 penetrates into the ring cavity 35 and also reaches the cavity enclosed by the sight glass 41. If the support fluid has a different color than the process fluid, the sight glass can be used to determine not only that there is damage 43, 44 to the membrane ring 28, but also on which side the membrane ring 28 is damaged, i.e. whether the upper or lower membrane disk 33, 34 is broken.

The valve 51 shown in Figures 4 and 5 has the structure / of a typical diaphragm valve. It has a valve housing 52 with a flow channel 53 that passes through it essentially horizontally. At both ends of the flow channel 53, the valve housing 52 is limited by a flange 54, 55 {. On the inside, the flow channel is provided with an all-round

coating 56 as corrosion protection. In the middle of the flow channel 53, a molded part 57 protrudes, the upper side of which forms a type of valve seat.

The valve housing 52 is divided into a lower housing part 58 and an upper housing part 59. The flow channel 53 runs essentially in the lower housing part 58. This has an opening in the middle, which is closed by the hood-like upper housing part 59. A membrane 60 is clamped between the lower housing part 58 and the upper housing part 59 in a sealing manner with its outside. It is in the closed position, i.e.

it rests against the molded part 57 and thereby blocks the connection between the two parts of the flow channel 53 when the membrane 60 is raised.

The membrane 60 is attached to a valve spindle 61 in the middle. The valve spindle 61 has a thread 62 on the outside. A support body 63 is screwed onto its lower end, the underside of which rests against the back of the membrane 60 and supports it. .... .

A spindle guide 64 is fitted into an opening on the top of the housing upper part 59, which has a thread on the inside into which the thread 62 of the valve spindle 61 fits. By turning the valve spindle 61 in one direction, it can be raised together with the membrane 60 and lowered in the other direction. For the rotary movement, the valve spindle 61 has a handwheel 65 on the top, which is connected in a rotationally fixed manner to the valve spindle 61 and is clamped against a cover 67 by means of a nut 66. The cover 67 rests on the outside of the spindle guide 64 via a sealing ring 68 and in this way prevents the thread 62 from being exposed to dust or the like.

The membrane 60 is constructed in several parts, i.e. it essentially consists of two membrane disks 69, 70 lying on top of one another, which have the same outside diameter. On the outside, a spacer ring 71 is clamped between the two membrane disks 69, 70. On the inside, the two membrane disks 69, 70 are also kept apart in the area of the connection to the valve spindle 61 by a spacer projection 72. The spacer ring 71 and spacer projection 72 ensure that an annular cavity 73 is created between the two membrane disks 69, 70. It also contains spacers - designated 74 for example - in order to keep the distance between the two membrane disks 69, 70 constant in the middle area of the annular cavity 73, even under operating pressure.

As can be seen from Figure 5, the ring cavity 73 in this view extends to the right into the clamping between the upper housing part 59 and the lower housing part 58. A sleeve 75 is formed there, which extends to a leakage screw 76. A sight glass nut 77 is screwed onto this leakage screw 76, which has a sight glass not shown in detail here.

If the lower membrane disk 70 is damaged, the process fluid passing through the flow channel 53 penetrates into the annular cavity 73. It then flows from there via the sleeve 75 and the leakage screw 76 to the sight glass nut 77. Determining the presence of the process fluid in the sight glass nut 77 then indicates that the membrane 60 is damaged and must be replaced.

Claims (14)

Claims: Area Regler GmbH, Kempener Str. 18, 47918 Tönisvorst Ventil 1. Valve (1, 51) with a flow channel (3, 53) passing through a valve housing (2, 52), a valve seat (5) in the flow channel (3) and a closure member (13, 60, 61) that is movable relative to the valve seat (5), the closure member including a membrane (28, 60), characterized in that the membrane (28, 60) encloses a cavity system (35, 73) between its clampings. 2. Valve according to claim 1, characterized in that the cavity system (35, 73) is spaced from the clamps. 3. Valve according to claim 1 or 2, characterized in that the cavity system (35, 73) is connected to a leak detection device (41, 77). 4. Valve according to claim 3, characterized in that the leak indicator device is designed as a sight glass (41, 77) which is connected to the cavity system (35, 73). 5. Valve according to claim 3, characterized in that a pressure sensor is provided which is pneumatically connected to the cavity system (35, 73) and is coupled to the leak detection device. 6. Valve according to claim 3, characterized in that a humidity sensor is provided which is connected to the cavity system (35, 73), which is connected to the leak detection device. 7. Valve according to one of claims 1 to 6, characterized in that the membrane (28, 60) consists of two membrane disks (33, 34, 69, 70) lying on top of one another, which have spaced-apart regions to form the cavity system (35, 73). 8. Valve according to claim 7, characterized in that one of the two membrane discs (33, 34, 69, 70) is recessed on the inside. 9. Valve according to one of claims 1 to 8, characterized in that the cavity system (35, 73) is limited on the inside and/or outside by spacers (71, 72). 10. Valve according to one of claims 1 to 9, characterized in that spacers (36, 74) are present in the cavity system (35, 73). 11. Valve according to one of claims 1 to 10, characterized in that the cavity system (35, 73) consists of interconnected channels. 12. Valve according to one of claims 1 to 11, characterized in that the valve is designed as a diaphragm valve (51). 13. Valve according to one of claims 1 to 11, characterized in that the membrane (28) is attached on the outside to the valve housing (2) and on the inside to the closure member (13). 14. Valve according to claim 13, characterized in that on the flow channel (3) On the side of the membrane (28) facing away from it, a seal (24) is arranged between the closure member (13) and the valve housing (2), which seal encloses with the membrane (28) a closed support cavity (29) which is filled with an incompressible, deformable support medium, the closure member (13) on the side of the membrane (28) facing away from the flow channel (3) having such a shape that the volume of the support cavity (29) remains essentially constant when the closure member (13) moves.