DE2207274B2 - Catalytic gas prodn - by decomposition of liquid esp oxygen from hydrogen peroxide - Google Patents

Abstract

Between the main storage tank for H2O2 and the catalytic decomposer tank is a buffer tank sub-divided into two compartments; the first is fed via stop valve and non return valve from the reservoir and connected via upper NRV (gas) and lower NRV (liq) in the party wall to the second compartment which feeds the decomposer via gas-press. operated regulator valve and NRV. The gas press. is derived from a feed-back line from the outlet side of the decomposer and this press. is also applied to one port of a three-way cock fitted in the roof of the first compartment of the buffer, the alternative inlet port of which is vented to atmos. The system, once started, operates cyclically for topping up the two buffer compartments and the decomposer from the main storage reservoir due to operation of the automatic, press. controlled valves. A wide range of refinements to the basic system may be added. the three way cock is controlled by a float in the first buffer. PTFE membranes are used in the main regulator valve and ceramic bead spacers in the decomposer.

Description

The invention relates to a pneumatically or hydraulically actuated quantity control valve, which within of a housing has three spaces, of which a first space provided with a supply opening for receiving the regulating medium and a second room for receiving the medium to be regulated and the third room between these two rooms is determined by the other two rooms each is hermetically separated by a movable membrane, the effective area of the space for the regulating medium closing membrane is larger than the effective area of the space for the The membrane to be closed off the medium and the two membranes for power transmission are rigidly connected to one another.

Quantity control valves for regulating the flow of a medium are known. Such valves can operated pneumatically or hydraulically. A disadvantage of these valves is that There are parts that are mechanically displaceable in relation to one another and which are opposed to one another by means of sealing rings

must be sealed (see. US-PS 32 52471 and

GB-PS 5 25 226). A reliable seal is

especially in the case of corrosive media and media that decompose easily catalytically. In addition, such valves, due to the friction between the seal and the moving parts, a relatively large hysteresis, which leads to a sluggish control behavior

The object of the invention is to provide a pneumatic or

ίο hydraulically operated volume control valve of the above described type, which has three spaces separated from one another by movable membranes, so to design that it does not have these disadvantages and that in particular by the seal given difficulties can be avoided.

According to the invention, this is achieved by im Flow control valve at least two openings for the passage of the medium to be regulated through the second space are provided and that the free flow cross-section of the medium to be controlled in the second room by changing the position of the space that closes this room against the third room, movable membrane is changeable.

In the flow control valve according to the invention, the medium to be controlled, ie the medium whose flow rate or amount is controlled, is hermetically separated from the regulating medium, ie the medium which effects the control, by two membranes. This means that no parts moving against one another have to be sealed in the valve. This not only has the advantage that seals are no longer required, but above all the disadvantages and difficulties that arise when using seals and the need to seal parts moving against one another. In the flow control valve according to the invention, for example, through the use of diaphragms, which make a seal between parts moving against one another superfluous, no frictional forces occur. Thereby, the hysteresis of the valve is small, and the valve controls already after at small pressure changes, for example, even at pressure changes of about + 10 ³ N / mm ^2. As a result of the lack of parts that move mechanically against one another and are in frictional contact with one another, the flow control valve according to the invention has further advantages, in particular when it is used to regulate corrosive or easily decomposable media. For example, the valve can advantageously be used to regulate the flow of hydrogen peroxide (H2O2) to a HjCh decomposer, which is used to generate oxygen. It guarantees a leak-free inflow.

The flow control valve according to the invention can be operated pneumatically or hydraulically, d. throat Regulating medium, gases or vapors as well as liquids can be used. The two For power transmission, diaphragms of the valve are advantageously connected to one another via a stamp. The stamp is provided with a return spring.

The return spring can advantageously be designed as a helical spring arranged in the third space, which sits with one end on a housing projection and acts with the other end on the stamp. the The spring force of the return spring is advantageously adjustable.

In the flow control valve according to the invention, at least one of the in the Second room opening openings at their mouth be designed as a valve seat, and on the

A membrane closing off the second space against the third space can be a suitable one for this valve seat Be attached to the valve cone. If two openings open into the second space, the opening is preferably through which the liquid is fed to this space, designed as a valve seat at its mouth the second room has more than two openings, so it serves advantageously an opening for supplying the liquid while the liquid is passed through the remaining openings is removed again. In this way, with the help of the 1 ο Flow control valve, for example, liquid can be fed to several consumers at the same time.

As already mentioned, the effective areas of the two diaphragms of the flow control valve are of different sizes. The effective area is understood to mean the area of the membrane on which the pressure of the respective medium acts. The ratio of the effective area of the two membranes to one another depends on the desired control range of the flow control valve. If the control range is, for example, between approximately 24 and 40 N / cm ² , the effective areas are approximately 40 cm ² and 30 cm ^2, respectively. The spring force of the spring used also depends on the desired control range of the flow control valve. In the above-mentioned control range, for example, a helical spring with a spring constant of about 30 N / mm is used. The spring travel is about 2 mm.

The membranes used, like the other parts of the flow control valve, must of course be resistant to the media with which they come into contact, i.e. h _M they must not be attacked by these media. It has proven advantageous if the membranes are made of polytetrafluoroethylene. This is especially true when controlling liquids such as H2O2. Of course, other materials can also be used, each of which is specifically tailored to the respective medium, for example.

Due to its design, the flow control valve according to the invention is particularly advantageous for Applications in which the medium to be controlled and the medium to be controlled have the same pressure.

The invention will be explained in more detail with the aid of a figure of an exemplary embodiment.

The figure shows in section an exemplary embodiment of a quantity control valve according to the invention. The valve housing 10 consists of three components, the upper part 11, the middle part 12 and the Lower part 13, which are held together with screws 14. When assembling the valve between the components 11 and 12 inserted a membrane 15 and between the components 12 and 13 a membrane 16. Die Diaphragms are made of polytetrafluoroethylene, while for the other components of the control valve corrosion-resistant steel is used.

The middle part 12 has a large continuous opening that is separated from the membranes 15 or 16 is completed, creating a room 17. The space 17 is ο via a narrow channel 33 in the wall of the middle part 12 is connected to the atmosphere and thus exerts a kind of buffer effect. The upper part 11 and the lower part 13 each have a recess, which are closed by the membranes 15 and 16, where rooms 18 and 19 are created. The room 18 is used to accommodate the regulating medium, the room 19 for Recording of the medium to be controlled. The regulating medium is the space 18 through an opening 20 in the Upper part 11 fed during the supply and discharge of the medium to be controlled to and from the space 19 by two Openings 21 and 22 in the lower part 13 take place. The mouth of the opening 21 in the space 19 is as Valve seat 32 is formed

In the room 17 there is a stamp 23, which with the both membranes 15 and 16 is connected. For this purpose, the membranes are each attached to the The stamp is placed on top and covered with cover rings 24 and 25, which are then covered with screws 26 and 27 on the stamp 23 are attached. In the embodiment of the flow control valve shown in the figure, the Cover ring 24 is not attached directly to the punch 23, but rather by means of the screws 26 with an adjusting ring 28 connected, which is attached to the punch 23 by means of a thread. The membranes 15 and 16 are, as shown in the figure, movable together with the stamp.

The punch 23 is provided with a spring 29 which rests at one end on the adjusting ring 28 and on the the other end rests on a housing projection 34, d. H. on a part of the Middle part 12. Together with the cover ring 25, a cover plate 30 is at one end of the punch 23 The cover plate 30 is provided with an elevation that acts as a valve cone that matches the valve seat 32 31 is formed

As already mentioned, the quantity control valve according to the invention can then be used particularly advantageously when the medium to be controlled and the medium to be controlled have the same pressure. So can the flow control valve used, for example, to regulate the supply of hydrogen peroxide to a decomposer in which the hydrogen peroxide is catalytically decomposed into oxygen and water. As regulatory In this case, the medium used is advantageously the oxygen formed during the decomposition, which is supplied to space 18 is fed. The medium to be controlled, d. H. the hydrogen peroxide, flows through the room 19. A H2O2 decomposer for the production of oxygen For example, proposed in DT-OS 22 07 273. This oxygen generator shows pressure feedback as a result Oxygen and hydrogen peroxide have the same pressure. The pressure feedback will therefore made to enable automatic operation of the oxygen generator and to the Avoid using auxiliary energy.

The flow of hydrogen peroxide through the valve or through the space 19 is initially unhindered when the system is started up. From a pressure of, for example, about 24 N / cm ² , the free flow cross-section of the medium to be controlled in this space is reduced as a result of the increasing pressure. D. That is, the plunger 23 moves in the direction of the valve seat 32. The reason for this is that the regulating force of the valve is dependent on the prevailing pressure, on the difference in the effective areas of the two diaphragms and on the spring force of the spring. The effective areas of the membranes are in each case the areas of the membranes that are not clamped between the components 11 and 12 or 12 and 13. The regulating force arises from the difference between the force of the spring and the force that results from the differently sized effective areas of the two diaphragms, which are subjected to the same pressure. When the pressure rises, the control force acts in the direction of the valve seat; the control force presses via the adjusting ring 28 on the plunger 23 with the valve cone

31, wherein the gap between the valve seat 32 and the valve cone 31 is reduced and the flow rate of H2O2 by reducing room 19. at as the pressure decreases, the direction of the control force is reversed, since the spring force is the force that changes results from the membranes acted upon with the same pressure, predominates; this will open the valve again.

By turning the adjusting ring 28, the bias of the spring 29 can be modified and thus the Control range of the valve can be changed. For this purpose, the upper part 11 of the valve is separated from the central part 12 removed and the adjusting ring 28 rotated together with the membrane 15. The membranes 15 and 16 point at the points that come to rest on the screws 14, holes; but the membranes can be in these areas can also be slotted.

The flow control valve according to the invention has, for example, a diameter of about 100 mm and a height of about 50 mm. It can always be used when the flow of a medium should be controlled pneumatically or hydraulically.

1 sheet of drawings

Claims (4)

Patent claims: 1. Pneumatically or hydraulically actuated flow control valve within a housing has three rooms, of which a first, provided with a supply opening room for receiving of the regulating medium and a second room is intended to accommodate the medium to be regulated and the third room between these two rooms of the other two rooms each is hermetically separated by a movable membrane, the effective area of the den Space for the regulating medium closing membrane is larger than the effective area of the Space for the membrane closing off the medium to be controlled and the two membranes for power transmission are rigidly connected to one another, characterized in that at least two openings (21, 22) for the implementation of the closed regulating medium are provided through the second space (19) and that the free flow cross-section of the medium to be controlled in the second room (19) by changing the position of this room against the third space (17) closing, movable membrane (16) is variable. 2. Quantity control valve according to claim 1, characterized in that the two membranes (15, 16) are connected to one another via a punch (23) provided with a return spring (29). 3. Quantity control valve according to claim 2, characterized in that the return spring (29) as one in the third space (17) arranged coil spring is formed, which with one end on a Housing projection (34) sits and acts with the other end on the punch (23). 4. Quantity control valve according to one of claims 1 to 3, characterized in that at least one% of the two openings (21, 22) opening into the second space (19) at their mouth as a valve seat (32) is formed and that the second space (19) closes off from the third space (17) A valve cone (31) that matches this valve seat (32) is attached to the membrane (16).