DE9112880U1 - Valve block - Google Patents

Description

Honor

The invention relates to a valve block, in particular for aggressive fluids and/or fluids with higher temperatures.

In biotechnology, pharmaceuticals and medical technology, plastic valves with separating membranes are often used when there are high requirements for chemical and thermal resistance.

To set up a fluidic control system in which several valves are connected to one another and form a valve block, the individual valves are connected to one another using hoses or pipes. The disadvantage here is that assembly and piping are very costly; this design also creates many interfaces and thus a high risk of leaks. Temperature resistance also poses difficulties, particularly with regard to thermal sterilization.

According to another practical embodiment, block housings are used in which several valves or valve seats are machined. The internal channels connecting the valves to one another are also machined. This reduces the number of connections, but the disadvantages are the high machining effort due to machining, high material usage and thus high weight, as well as a high reject rate due to the integrated valve seats. Finally, if a valve fails, the entire block must be replaced, which results in high spare parts costs and a high time expenditure for replacement.

The invention is based on the task of avoiding the aforementioned

Disadvantages of creating a valve block that is easier to manufacture and in which the individual valves can be installed, removed, checked and replaced individually.

According to the invention, this is achieved in that the valve block consists of a plurality of valves and a connecting strip connecting them, in which the connecting channels for connecting the individual valves to one another are formed.

The connecting strip preferably consists of a plastic material, into which the connecting channels are molded during production, e.g. by injection molding. The connecting strip is expediently provided with injection-molded connecting pieces, which are also attached to the connecting strip by means of ultrasonic welding.

Advantageously, metallic electrodes are used in the connection strip before and after a valve (in relation to the flow direction of the fluid), which are electrically connected to an evaluation circuit and whose circuit can be closed by the (electrically conductive) fluid. When the valves are closed, the circuit is interrupted, but if a valve no longer seals sufficiently, a leakage flow occurs that closes the circuit, which triggers an alarm, for example, so that the defective valve can be identified and replaced. The electrodes serve as detectors and the electrical current flow is monitored with the help of the evaluation circuit. Each of the individual valves, also called a valve cartridge here, is designed in the form of a complete valve with a valve seat and closing element, and it can be individually connected to the connection.

connection strip. Each valve cartridge is advantageously provided with a metal electrode on the end of the counter-armature facing away from its closing element, which is electrically connected to an electrode in the connection strip via an evaluation circuit, whereby the circuit of the two electrodes can be closed by the (electrically conductive) fluid. This allows the armature dead space to be monitored for possible leakage as a result of a crack in the valve's closing element, since the aforementioned circuit is closed by the leaking fluid and an alarm can be triggered as a result.

The electrode, which is designed in the form of a metal pin, is expediently injected into a plastic electrode holder, which is attached to the counter-anchor by means of a snap lock, which also serves to axially fix a magnet.

An exemplary embodiment of the invention is explained below with reference to the drawing, in which

FIGURE 1 shows schematically in section a valve cartridge according to the invention.

FIGURE 2 shows a schematic cross-section of a connecting strip with two flanged valve cartridges according to Figure 1.

Figure 1 shows a valve cartridge 10 with a housing 12 made of plastic, which has an inlet 14, a valve seat 16 and an outlet 18.

A membrane 20 forming a closing element closes and opens the valve seat 16 by means of its sealing plug 22. The membrane 20 has an annular sealing bead 24 on its circumference, which is held between a shoulder of the housing 12 and a retaining ring 26, also made of plastic.

The housing 12 is provided with three snap hooks 28 which are arranged at equal angular intervals around the circumference of the housing and which, as shown, grip over the surface of a base plate 30 provided with suitable openings, against the underside 32 of which the housing 12 abuts, so that the housing is positively connected to the base plate 30.

A magnetic closure sleeve 34 is firmly connected to the base plate 30 by means of suitable beads or flanges, in which a magnetic armature 36 is arranged so as to be axially displaceable, the head 38 of which is embedded in the sealing plug 22 of the membrane 20, whereby the magnetic armature 36 is connected to the membrane 20 in a form-fitting manner. A compression spring 40 presses the magnetic armature 36 and thus the membrane 20, 22 constantly against the valve seat 16. The compression spring 40 is in turn supported on a stationary counter-armature 42, which is connected to the magnetic closure sleeve 34 in a form-fitting manner by means of a flange. The armature, counter-armature and magnetic closure sleeve are enclosed by an electromagnet 44, which, although not shown, is connected to a suitable voltage source, whereby the magnetic armature 36 can be switched in a known manner. When the electromagnet 44 is excited, the magnet armature 36 is raised against the force of the spring 40 until it strikes the counter-armature 42, whereby the valve seat 16 is opened and the fluid can flow from the inlet 14 to the outlet 18.

The counter anchor 42 is provided with a central bore 48, into the upper end facing away from the locking element

a sealing element in the form of a plastic sleeve 50 is inserted. An electrode 52 in the form of a metal pin, which is injected into a plastic electrode holder 54, engages from above in the bore of the sleeve, which opens into the central bore 48 of the counter-armature 42. The electrode holder 54 is fastened to the upper end of the counter-armature 42 by means of a snap lock 56, whereby the electrode holder 54 also secures the electromagnet 44 against axial displacement on the magnetic sleeve 34.

Figure 2 shows a section through a connecting strip 60 made of plastic, to which a valve cartridge 10 is flanged at the top and bottom, as shown in Figure 1. The longitudinal direction of the connecting strip 60 extends transversely to the plane of the drawing in Figure 2, and for example, five valve cartridges 10 can be flanged one behind the other on the top and bottom of the valve strip 60, so that such a valve block is then made up of a connecting strip and ten valve cartridges 10.

As shown, the valve cartridges 10 are attached to the connecting bar by means of screws 62 and nuts 64, which are inserted into side housing pockets of the housing 60.

The connecting strip 60 is provided with a supply channel 66 for the supply of a fluid, which opens into a longitudinal channel 68 running transversely to the plane of the drawing. A transverse channel 70 branches off from the latter for each valve cartridge 10, which opens into the inlet 14 (Figure 1) of the associated valve cartridge 10. The outlet 18 of each valve cartridge 10 is connected to an outlet channel 72 assigned to it, which in turn is connected to an outlet hose line

connected.

The supply channel 66 is connected to a supply hose line 76, the hose end of which is pushed over a conical bushing 78, which in turn is inserted with this hose end into a correspondingly conically expanding connection piece 80 and is pressed against the latter by means of a union nut 82 which is screwed onto the connection piece 80. The connection piece 80 is connected to the connection strip 60 by means of ultrasonic welding.

O-rings 84 and 86 are installed between each valve cartridge 10 and the connecting bar 60 for sealing.

A central metallic electrode 90 is also built into the connecting strip 60, which borders on the longitudinal channel 68. The electrode can also be embedded in the connecting strip 60 by means of ultrasonic welding, with an O-ring 92 being inserted between the electrode 90 and the connecting strip 60 for sealing due to the different thermal expansion of steel (electrode) and plastic (connecting strip).

Furthermore, a metallic electrode 94 is provided for each valve cartridge 10, which is also built into the connecting strip 60 and is connected to the outlet channel 72 assigned to each valve cartridge 10. The electrode 94 can be attached to the connecting strip 60 in a similar manner to the electrode 90.

The electrodes 52, 90, 94 make it possible to monitor the individual valve cartridges 10 for leaks. The central electrode 90 and each individual electrode 94 are electrically connected to an evaluation circuit 96. When the valves are open

the circuit is closed by the electrical conductivity of the fluid via the supply channel 66, the cross channel 70, the inlet 14, the open valve seat 16, the outlet 18 and the outlet channel 72. When the valves are closed, the circuit is interrupted. However, if a valve cartridge no longer seals sufficiently, a leakage flow occurs, which closes the circuit between the central electrode 90 and the individual electrode 94 in this defective valve cartridge 10. This provides an evaluable signal to the evaluation circuit 96, e.g. to trigger an alarm, whereby the defective valve can be identified and replaced.

In addition to the tightness monitoring of each valve cartridge 10, its armature dead space can also be monitored for possible leakage as a result of a diaphragm tear. In the event of a leak as a result of a diaphragm tear 20, the armature dead space within the magnetic closure sleeve 34, i.e. the annular space 46 and the bore 48 in the counter-armature 42, is filled with the operating fluid. The sealing element 50 seals the bore 48 to the electrode 52. However, as soon as the fluid touches the metal electrode 52, an electrical circuit is closed, for example the electrical circuit between the electrodes 52 and 90, which are electrically connected to the evaluation circuit 96, which in turn provides an evaluable signal that can be used to trigger an alarm.

The prerequisite for this type of leakage monitoring is that the connecting strip and the other parts that come into contact with the fluid are made of a non-conductive plastic, but on the other hand the operating fluid is electrically conductive.

Each valve cartridge 10 is designed as a complete valve with a valve seat and closing element, which is pre-assembled as a complete unit and can be tested as such. The valve cartridge can be easily installed and removed and individually replaced. This leads to shorter maintenance times and lower spare parts costs. Furthermore, since each valve cartridge can be tested individually, testing the entire valve block is considerably easier for the manufacturer. The valve cartridge is versatile and can also be used for other connecting strips with corresponding installation dimensions.

The connecting strip and the connecting pieces are manufactured using an injection molding process and welded together using ultrasound. A high-temperature-resistant plastic is used as the material. Compared to machined connecting blocks, there are advantages such as a compact, space-saving structure and a flow-optimized design of the internal fluidic connection channels. The selected plastics (PES or PEEK) allow for high thermal loads and allow thermal sterilization of the device with the valve block thanks to their temperature resistance. There is also a significant saving in material and weight, and consistent quality in terms of geometry and surface finish can be achieved. Furthermore, thanks to injection molding, manufacturing costs can be reduced in a surprising way.

The electrical monitoring system gives the valve block a high level of safety.

Claims (8)

A 15 878 isprüche 1. Valve block, in particular for aggressive fluids and/or fluids with a higher temperature, characterized in that it consists of a plurality of valve cartridges (10) and a connecting strip (60) connecting them, in which the connecting channels (66, 68, 70) for connecting the individual valve cartridges (10) are formed. 2. Valve block according to claim 1, characterized in that the connecting strip (60) consists of a plastic material. 3. Valve block according to claim 2, characterized in that the connecting strip (60) including its molded connecting channels (66, 68, 70) are injection molded. 4. Valve block according to one of the preceding claims, wherein the connecting strip is provided with connecting pieces for hose connections, characterized in that the injection-molded connecting pieces (80) by ultrasound to the connecting bar (60) are welded on. 5. Valve block according to one of the preceding claims, characterized in that metallic electrodes (90, 94) are installed in the connecting strip (60) before and after a valve cartridge (10), which are electrically connected to an evaluation circuit (96) and whose circuit can be closed by the fluid. 6. Valve block according to one of the preceding claims, characterized in that each valve cartridge (10) is designed as a complete valve with valve seat (16) and closing element (20) and that the valve cartridges (10) are individually inserted into the connecting strip (60) can be installed and removed from it. 7. Valve block according to claim 6, wherein each valve cartridge is provided with an electromagnetically actuated movable armature connected to the closing element and a stationary counter-armature, characterized in that a metallic electrode (52) is arranged at the end of the counter-armature (42) facing away from the closing element (20), which is electrically connected to the evaluation circuit (96), to which the electrode (90) in the connecting strip (60) is also electrically connected to form a detector device, and that the circuit of the two electrodes (52, 90) can be closed by the fluid. 8. Valve block according to claim 7, characterized in that the electrode (52) designed in the form of a metal pin is injected into an electrode holder (54) made of plastic, which is fastened to the counter-armature (42) by means of a snap closure (56) and at the same time serves for the axial fixation of the magnet (44).