DE4302207A1 - Diaphragm control valve for heating or water system - has built in safety device in form of material plug which enters into solution if diaphragm fails and effects closure of valve - Google Patents

Abstract

The fluid enters through a port (A) and exits through a second port (B) after passing through a controlled orifice (4). Flow is fed back through a central path (5) formed in the spool (2) and acts on one side of a control diaphragm (10). A second diaphragm (14) is positioned with a spacer unit in between. Within the lower housing is a spring (19) loaded element operating on a piston rod (20). Located between the two is an element of material (24) which separates the piston when dry. In the event of a main diaphragm failure, the material enters into solution and is forced out through a porous material and the valve closes. ADVANTAGE - Provides safe operation in the event of diaphragm failure.

Description

The invention relates to a with a safety device provided diaphragm control valve, in particular pressure reducing valve or overflow valve for heating or domestic water systems, with a housing in which one with a valve seat interacting valve cone via a valve rod with a pressurized by the pressure of a liquid working medium Working membrane and a safety membrane is firmly connected and a spring bar with a pressure on the Counteracting working spring is coupled, being between the working membrane and the safety membrane a membrane space is formed.

The actuators according to the invention are particularly for Pressure reducers and overflow valves in heating and Service water systems provided.

Diaphragm control valves of the type mentioned have two Membranes, namely a working membrane and one Safety membrane. When the working membrane leaks the safety membrane takes on their function. Or that Valve is inserted through the safety membrane Security position brought and shut down. Usually is the safety position for pressure reducers completely tight closing state and for overflow or Safety valves in their fully open condition.

The construction according to patent specification DE 32 35 274 C2 is known.

Here the safety membrane is separated and from the Working membrane installed uncoupled. Under the pressure on acts on the safety membrane, the valve is closed, if the working membrane leaks and stays there closed.

A disadvantage is that if the Safety membrane leaks, the valve under the force  an auxiliary spring that is also present is fully opened again becomes. The security position is therefore no longer present. The This makes the system relatively insecure. At this Construction, the auxiliary spring has to open the valve, otherwise it would be because of the loose connection between working people and valve cone the position of the valve cone as desired and undefined. You cannot have a closing auxiliary spring use, because then the valve is always because of the loose connection would be closed.

The object is achieved by the invention, a To create diaphragm control valve of the type mentioned at which both membranes are firmly connected to the valve stem and the valve rod when the working diaphragm leaks and the spring rod are uncoupled from each other and therefore also the working spring is uncoupled, causing the valve in the safety position arrives.

This is achieved in that the Valve rod and the spring rod by means of one in the Working medium dissolvable mass coupled to transmit pressure force or held coupled, which is arranged in a room, which is in flow communication with the membrane space, such that the mass should the Working membrane from the one entering the gap between the membranes Working medium by loosening the coupling between the rods and Release the valve rod and the valve cone for the Movement to a safety position is resolved. If so If the working membrane leaks, the working medium flows through the hole in the membrane and for example through a hole in the middle membrane plate to the dissolvable mass. This solves get up in the working medium and flow away into the space between the membranes. This is the coupling between the two rods solved and thus the working spring is disconnected and ineffective. Under the pressure of the working medium on the Safety membrane, the valve is tightly closed or open.  

In a particularly preferred embodiment of the invention grips one of the force of the working spring on the valve rod counteracting auxiliary spring, the force of the auxiliary spring is sufficient, the valve cone when the Working membrane and the safety membrane after the dissolution move the dissolvable mass into the safety position. So if the safety membrane leaks and is ineffective has become, the valve is already by the force of the Auxiliary spring also kept tightly closed or open and therefore remains in the case of both membranes leaking Security position.

The invention is preferred based on two Embodiment of the pressure reducer according to the invention explained, which can be seen from the drawing. In the Drawing shows:

Fig. 1, the pressure reducing valve according to the invention in the first embodiment in longitudinal section, and

Fig. 2 is a partial view of the pressure reducing valve according to the invention in the region of the membrane chamber in the second embodiment in longitudinal section.

In the embodiment from FIG. 1, the working medium enters the housing 1 in direction A and flows through the valve opening 4 and then between the valve seat 3 and the valve cone 2 to the outlet, from which it emerges in the direction B. The working medium acts through the impulse line 5 in the valve rod 29 on the working diaphragm 10 and tries to close the valve together with the auxiliary spring 6 . The auxiliary spring is located in the upper membrane chamber 7 in room 8 . The working membrane 10 is clamped between the upper membrane plate 9 and the middle membrane plate 13 . The safety membrane 14 is clamped between the middle membrane plate 13 and the lower membrane plate 15 . The membrane gap is designated by 12 .

In the central diaphragm plate 13 , a pressure chamber 23 is formed in the valve rod 29 , which is filled with the mass 24 which can be dissolved in the working medium and in which the upper end of the spring rod 20 is immersed as a piston which is supported on the dissolvable mass. The pressure chamber 23 is connected via bores 28 in the valve rod to the space 27 adjoining the outer circumference of the valve rod 29 . The space 27 can be annular. The porous blocking element 25 delimiting the space 27 to the membrane interspace 12 prevents the substance of the dissolvable mass 24 from escaping through the bore 26 .

The working spring 19 acts on the spring rod 20 via the bracket 18 . By means of the seal 22 , the pressure chamber 23 is sealed off from the outside against the lower membrane chamber 17 , which is delimited by the safety membrane 14 . When the valve is fully open, the gap H between the stop 161 on the housing wall 16 bordering the lower membrane armature 17 and the stop disc 201 on the spring rod 20 is very small or zero. The vent hole 21 prevents vacuum formation in the membrane chamber 17 .

The pressure chamber 23 , in which the dissolvable mass 24 is located, must be higher than the sum of the gap H with the valve fully open and the valve stroke S. The substance of the dissolvable mass 24 must be readily and quickly dissolvable in the working medium. It is particularly good to use the substance of the dissolvable mass that is otherwise added to the working medium as an additive for quality improvement. These are remedies for hardness and oxygen or the like. For the working medium water, for example, granular table salt or phosphates can be used.

The blocking element 25 must be permeable to the working medium and the dissolved substance of the dissolvable mass 24 , and must be completely impermeable to the dry substance of the dissolvable mass. As a blocking element 25 may be a suitably fine sieve or a porous material such. B. a sintered material can be applied. It is also possible that the pressure chamber 23 is filled with small balls of appropriate quality (stainless steel or the like), and the substance of the dissolvable mass 24 is only in the rooms 27 and 28 and in the dry state the ball accumulation prevents evasion among the pressures transmitted between the rods 20 and 29 holds together, but releases them when the dissolvable mass dissolves in the working medium which, when the working membrane is damaged, is added to the dissolvable mass.

The membrane space 12 initially contains air under ambient pressure. When the working membrane 10 leaks, the working medium flows into the intermediate membrane space 12 and further through the bore 26 in the central membrane plate 13 and through the blocking element 25 into the spaces 27 , 28 and 23 . The dissolvable mass in these spaces is dissolved and pressed out of the pressure space 23 through the porous locking element 25 and the bore 26 into the membrane space 12 under the force of the working spring 19 under the pressure of the sealed spring rod 20 which slidably engages in the pressure space 23 . This means that there is no longer a fixed axial connection or coupling between the two rods. The rods move against each other until the spring rod 20 is stopped by the stops 161 and 201 . The valve rod 29 moves under the force of the auxiliary spring 6 and the force of the safety membrane 14 until the valve is closed and the valve cone 2 touches the valve seat 3 . The auxiliary spring 6 must be so strong that only its force is sufficient to close the valve, even if the safety membrane 14 is leaky and ineffective.

In the embodiment shown in FIG. 2, on the other hand, in the extension of the valve rod 29 and the spring rod 20, a pressure space 23 is formed between them in a sleeve, which is screwed into the lower diaphragm plate and into which the spring rod 20 slidably engages with its upper end. The pressure chamber 23 is connected via bores 28 and 26 to the intermediate membrane space 12 between the membranes. A pot-shaped locking element 25 is arranged in the pressure chamber 23 , a hollow cylinder is formed from the peripheral wall thereof and is supported with its bottom at the lower end of the valve rod 29 . The blocking element 25 covers the mouth of the bores 28 and consists of a porous sintered material which is permeable to the working medium. The cup-shaped locking element 25 is filled with a mass 24 which can be dissolved in the working medium, on which at the open end of the locking element 25 a piston 101 is slidably engaged, the lower end of which is supported on the spring rod 20 by a ball 102 with circumferential play . The piston is guided in the sleeve surrounding the pressure chamber 23 in a sealed, displaceable manner via a guide disk and the seal 22 . Otherwise, the embodiment from FIG. 2 corresponds to that from FIG. 1.

As in the embodiment from FIG. 1, the dissolvable mass 24 is dissolved upon entry of the working medium due to a leakage of the working membrane through the membrane space 12 , the bores 26 , 28 and the porous wall of the blocking element 25 to the dissolvable mass 24 of the working medium and under the pressure of the sealed spring rod 20 is pressed out of the pressure chamber 23 through the bore 26 into the diaphragm space 12 . Thereby, the pressure force-transmitting connection between the spring rod 20 and the valve rod 29 is released, whereby the valve rod 29 moves due to the forces acting on the safety diaphragm pressure down and closes the valve.

Claims (9)

1. With a safety device provided diaphragm control valve, in particular pressure reducing valve or overflow valve for heating or domestic water systems, with a housing ( 1 ) in which a valve cone ( 2 ) cooperating with a valve seat ( 3 ) via a valve rod ( 29 ) with a pressure of one liquid working medium acted upon working diaphragm ( 10 ) and a safety diaphragm ( 14 ) and is coupled via a spring rod ( 20 ) with a working spring ( 19 ) counteracting the pressure on the working diaphragm ( 10 ), between the working diaphragm ( 10 ) and the Safety membrane ( 14 ), a membrane interspace ( 12 ) is formed, characterized in that the valve rod ( 29 ) and the spring rod ( 20 ) are coupled or held in a pressure-transmitting manner by means of a mass ( 24 ) which can be dissolved in the working medium and are held in a space ( 23 , 27 , 28 ) is arranged, which with the membrane space ( 12 ) in flow Connection is such that the mass ( 24 ) when the working diaphragm ( 10 ) leaks from the working medium entering the diaphragm space ( 12 ) by loosening the coupling between the rods ( 20 , 29 ) and releasing the valve rod ( 29 ) and the Valve plug ( 2 ) is released for the movement into a safety position. 2. Diaphragm control valve according to claim 1, characterized in that an auxiliary spring ( 6 ) which counteracts the force of the working spring ( 19 ) acts on the valve rod ( 29 ), the force of the auxiliary spring ( 19 ) alone being sufficient for the valve cone ( 2 ) to leak move the working membrane ( 10 ) and the safety membrane ( 14 ) into the safety position after the dissolvable mass ( 24 ) has dissolved. 3. Diaphragm control valve according to claim 1 or 2, characterized in that the dissolvable mass ( 24 ) is a granular dry substance and the dissolvable mass ( 24 ) receiving space ( 27 ) with the diaphragm space ( 12 ) via a blocking element ( 25 ) in connection stands, which is impermeable to the dry substance, but is well permeable to the working medium and the solution of the mass dissolved in the working medium. 4. Diaphragm control valve according to one of claims 1 to 3, characterized in that the space ( 27 ) in which the dissolvable mass ( 24 ) is arranged is sealed against the external environment via a seal ( 22 ) surrounding the spring rod ( 20 ) . 5. Diaphragm control valve according to one of claims 1 to 4, characterized in that the dissolvable mass ( 24 ) is arranged in a pressure chamber ( 23 ) between the valve rod ( 29 ) and the spring rod ( 20 ). 6. Diaphragm control valves according to claim 5, characterized in that the valve rod ( 29 ) on the spring rod ( 20 ) via a piston ( 101 ) and the dissolvable mass ( 24 ) is supported, which in a locking element ( 25 ) in the form of a hollow cylinder Porous sintered material is arranged, in which the piston ( 101 ) slidably engages. 7. Diaphragm valve according to claim 6, characterized in that the piston ( 101 ) on the spring rod ( 20 ) is supported by a ball ( 102 ). 8. Diaphragm control valve according to one of claims 1 to 7, characterized in that a pressure chamber ( 23 ), which is formed between the valve rod ( 29 ) and the spring rod ( 20 ), is filled with small balls which against the dissolvable mass Stepping out of the pressure chamber ( 23 ) are blocked. 9. Diaphragm control valve according to one of claims 1 to 8, characterized in that the substance of the dissolvable mass ( 24 ) is one which is normally added to the working medium as an additive for quality improvement.