WO2001029433A2 - Device for dynamically monitoring pressure differences - Google Patents

Abstract

The invention relates to a device for dynamically monitoring pressure differences in at least two pressure pipes (207, 211), preferably in safety valves of pneumatically operated consumers. The inventive device is characterized in that, if the pressure in the two pressure pipes is equal, the restoring force of the at least one readjusting spring (205) together with the pressure force acting upon the pressure surface (A2) facing the at least one readjusting spring is larger than the pressure force (a1) acting upon the pressure surface facing away from the readjusting spring, thereby maintaining the piston-cylinder unit (202) in its rest position. The piston-cylinder unit changes to a storage position even if the pressure force acting upon the pressure surface facing the at least one readjusting spring (205) is reduced only for a short time. In said storage position, the pressure force acting upon the pressure surface facing away from the readjusting spring (205) is larger than the sum of the elastic force and the pressure force acting upon a third entrance surface (A3) when again impinged upon with a pressurized fluid. The piston-cylinder unit can only be restored from the storage position to the rest position by removing the pressure acting upon the pressure surface facing away from the readjusting spring.

Description

Device for dynamic monitoring of pressure differences

The invention relates to a device for dynamic monitoring of pressure differences in at least two pressure lines.

Such devices combine in particular for dynamic monitoring of valves, in particular safety valves for pressure-medium-operated consumers with two parallel-connected, one working piston and one valve plate each connected to this, each of which can be switched by a pilot valve assigned to it, as described, for example, in DE 196 22 198 AI emerges. The one emerging from DE 196 22 198 AI A device for dynamic monitoring is characterized in that a mechanical switching element which can be pressurized is connected to two mutually assigned points of two directional control valves, by means of which a safety valve can be blocked at different pressures at these two points.

It is advantageous with this device that no electrical or electronic components are required to monitor the valve, which in turn can be prone to failure.

However, this device has a relatively complex mechanical structure, which is complex to manufacture and can be prone to failure.

The object of the invention to provide a device for the dynamic monitoring of pressure differences in at least two pressure lines, preferably at safety-valves ^¬ is to further develop the effect on air-powered loads in that without any electrical and / or mechanical parts by pneumatic means not only a reliable and quick detection of a pressure difference, but it is also possible to store a detected pressure difference even if this pressure difference only occurred for a short time.

This object is achieved according to the invention in a device for dynamic monitoring of the type described in the introduction by the features of claim 1 and has the advantage that piston-cylinder units can be manufactured in a simple manner and enable reliable operation. Besides the piston, the spring and the diaphragm, no mechanical parts are required.

It is particularly advantageous that the piston-cylinder unit can only be returned to the rest position from its storage position by preferably manually removing the pressure acting on the pressure surface facing away from the spring. As a result, pressure differences are not only recognized, but to a certain extent stored, so that even if there is no longer a pressure difference and the pressure in both pressure lines is the same, an error that has occurred is still stored or can be determined.

Advantageous embodiments of the invention are the subject of the dependent claims. For example, it is advantageous that the pressure surface arranged on the side facing away from the spring is formed by an actuating membrane of the piston-cylinder unit. In this way, in particular no leaks can occur between the two pressure lines or in the piston-cylinder unit. In addition, the pressure surface can also be formed by a piston with a sealing element, which can be a lip ring, for example.

In principle, the piston-cylinder unit can be designed in a wide variety of ways. An advantageous embodiment provides that the piston-cylinder unit has at least two connections, one of which is connected to the atmosphere and the other of which is connected in the rest position of the piston-cylinder unit to the valve line facing the return spring and which in the storage position of the piston-cylinder unit to the is connected to the atmosphere. In this way, a safety valve, as can be seen, for example, from DE 196 22 198 AI, can be directly controlled via this connection in a particularly advantageous manner, so that it remains in a switch position in which an actuation of a pressure difference in the two lines by the safety valve to be controlled device, for example a press, is not possible.

In this case, it can preferably be provided that the pressure on the side remote from the spring pressure acting face by ventilation, preferably by means of a Magnetven ^¬ TILs or by means of a mechanically, for example by a key switch operable valve is degradable or when the total system pressure is removed.

Further advantages and features of the invention are subject of the following description and the drawings ^¬ representation of an embodiment.

The drawing shows: Fig. 1 is a device making use of the invention in the rest position and

Fig. 2 shows the device shown in Fig. 1 in memory division.

A device for dynamic monitoring of pressure differences in at least two pressure lines in the form of a signal storage valve, shown in FIGS. 1 and 2, comprises a housing 200 with two connections 207, 211 which can be connected to pressure lines (not shown). In the housing 200, a piston 202 is displaceable in an opening of the housing 200 against the restoring force of restoring springs 205.

The device further comprises two connections 208, 210, one of the connections 208 depending on the position of the piston 202 being connectable either to the connection 207 or to the connection 210, which in turn is connected to the atmosphere.

The piston 202 is closed on its side facing away from the return springs 205 by a membrane 201 which is fastened to the housing 200 and forms an effective pressure surface AI with which the piston 201 can be acted upon by a pressure prevailing at the connection 211

On which the spring 205 facing side of the piston 202, the effective pressure surface is formed by the TE on this Be ^¬ more, formed by a seat 209 of the piston pressure surface A2 202nd The spring force generated by the return springs 205 holds the piston 202 in its rest position shown in FIG. 1. For this purpose, the piston 202 has sealing surfaces 203 on its side facing away from the return springs 205, which cooperate with the valve seat 209.

On its side facing the return springs 205, the piston 202 also has a sealing surface 204 which interacts with a valve seat 206.

The device shown stores a signal whenever there is pressure at port 211 and no pressure at port 207, or when there is a pressure difference here, as will be described in more detail below.

If the two connections 207 and 211 are pressurized, the piston 202 remains in its rest position shown in FIG. 1. The spring force of the return springs 205 and the pressure force on the surface A2, which is generated by the fluid pressure at the connection 207 and acts on the valve seat 209, result in a resultant force in the rest position, which hold the piston 202 against a force which is caused by the fluid pressure, that occurs on the membrane 201. It is understood that the two effective areas AI, A2 and the spring constant are selected so that the effective area A2 minus the effective area AI at the same pressure at the connections 207 and 211 result in a resulting compressive force which is selected that the piston 202 m remains in its rest position. In this rest position, the same fluid pressure is present at port 208 as at port 207. Port 210 is connected to the atmosphere or permanently without pressure.

The memory function of the device is as follows. If the fluid pressure at port 207 and thus at port 208 drops - a pressure difference can be determined by the interaction of the area AI, A2 and the spring force of the springs 205, at which a storage process is to be initiated - only the spring force remains resulting force from the lower pressure opposite port 211 at ports 207 and 208 to hold piston 202 in its rest position. However, since the voltage applied to the diaphragm 201 pressing force, the spring force and the resultant force of the lower pressure over the terminal 211 to the terminals 207 and 208 predominates, since the terminal 211 continues to beat with a pressure beauf ^¬, the piston moves 202 m the storage position shown in Fig. 2 down towards the valve seat 206 mt of the flat A3.

If a fluid pressure is again present at the connections 207 and 208 or the pressure rises again, only a small upward force arises, which is formed from the product "seat area A3 of the valve seat 206 times fluid pressure". The seat area A3 of the valve seat 206 is dimensioned in such a way that this force together with the force generated by the return springs 205 generated force is not sufficient to move the piston 202 against the downward force, which is formed by the product "fluid pressure times membrane area AI". A pressure equalization between connection 207 and connection 211 does not lead to the resetting or deletion of the memory function of the device in the rest position. The pressure difference that has occurred remains to a certain extent stored by the position of the piston which connects the connection 208 to the atmosphere through the connection 210.

Device reset, i.e. a quenching function can only be achieved in that the space above the membrane 201 is vented through the connection 211, so that the springs 205 and the fluid pressure applied to the seat surface A3 move the piston 202 back up to its initial or rest position. In this case the stored signal is deleted. The ventilation can be carried out, for example, by a solenoid valve or also by a mechanically operated valve, for example also by means of a key switch.

The device can also be reset by switching off the system pressure. This can e.g. the solenoid valve or the mechanically operated valve, which is operated, for example, by means of a key switch, is dispensed with.

The advantage of the device described above is ^¬ see to that it can be produced easily, because little moving parts reliable Function enables and particularly in that a pressure drop at the inlet 207, even after the pressure in this line has been restored, is not only ascertainable, but can be stored until the device is reset by manual actuation.

Claims

claims

1. Device for dynamic monitoring of pressure differences in at least two pressure lines, preferably in safety valves for consumers operated by compressed air, characterized in that a piston-cylinder unit is provided with at least two opposite, differently sized effective pressure areas (AI, A2), one of which by the one pressure line and the other through the other pressure line can be pressurized with pressurized fluid and with a piston (202) which is movable against the restoring force of at least one restoring spring (205) such that the restoring force of the two pressure lines at the same pressure at least one return spring (205) together with the pressure force applied to the pressure surface (A2) facing the at least one return spring (205) is greater than the pressure force applied to the pressure surface (AI) facing away from the return spring (205), so that the piston-cylinder unit in ^{remains in} their rest position and that the piston-cylinder unit at one also only a short-term reduction of the pressure force applied to the side facing the at least one return spring (205) changes into a storage position in which the pressure force applied to the pressure surface (AI) facing away from the at least one return spring (205) is greater than the sum of the spring force and the pressure force applied to a third inlet surface (A3) during re-application with pressurized fluid and that the piston-cylinder unit can be returned to the rest position from the storage position only by removing the pressure (AI) acting on the return spring (205) facing away from the return spring (205) is.

2. Device according to claim 1, characterized in that the arranged on the at least one return spring (205) facing away from the pressure surface (AI) is formed by an actuating membrane (201) of the piston-cylinder unit.

3. Apparatus according to claim 1, characterized in that the arranged on the at least one return spring (205) facing away from the pressure surface (AI) is formed by a sealing element, preferably by a lip ring, a piston of the piston-cylinder unit.

4. Device according to one of claims 1 to 3, since ^¬ characterized in that the piston-cylinder unit has at least two connections (208, 210), one of which is connected to the atmosphere and whose another in the rest position of the piston-cylinder unit is connected to one of the at least one return spring (205) facing connection (207) and in the storage position of the piston-cylinder unit is connected to the connection (210) connected to the atmosphere.

5. Device according to one of claims 1 to 3, characterized in that the pressure force acting on the at least one reset eder (205) facing away from the pressure surface (AI) by venting preferably by a solenoid valve or by a mechanically actuated valve or by removing the entire System pressure is degradable.