DE19948747A1 - Safety reset system of pneumatic valve actuator, includes compressed air reservoir for resetting - Google Patents

Abstract

The local compressed air reservoir (3) is filled by a compressor (4) operated from the compressed air mains. This is connected via a pressure reducer to the supply line (17) of the actuator (2).

Description

The invention relates to a device for safety reset of a pneumati rule actuating device, in particular a valve actuator, the Device has a compressed air reservoir with which the actuating device is resettable.

Such well-known devices are used to guarantee afford that in the event of failure of the actuation energy, d. H. a failure of the compressed air supply supply, the valve to be operated is still brought into the switch position can, which is defined as a safety position. Such a security provision is therefore necessary to prevent complex systems with a Large number of valves to be switched on in the event of a malfunction in uncontrolled operating states can kick.

The well-known compressed air reservoir for safety reset are directly from the Compressed air network charged and have a storage volume that is a multiple of the volume of the pneumatic actuator is also around in the event of a malfunction a certain volume flow from the compressed air reservoir until the end of the Ver adjustment movement of the actuator still a sufficient pressure in the memory, d. H. ensure a sufficient drive torque of the actuating device.

The compressed air reservoir is usually activated via an electrically controlled valve the supply line to the actuator connected to under pressure failure to release the stored compressed air for an emergency operation. With the help special control measures are taken to ensure that after a safety reset the actuation of the valve into the other, d. H. "Unsafe" switch position can only take place again when the network pressure is like that is available. This ensures that due to the then how of the filled compressed air reservoir at any time with a safety reset Help of the memory is possible.

A disadvantage of this known device is that the compressed air reservoir requires considerable installation space, which often requires separate attachment to standard  moderate actuators required. These additions are undesirable and cause not inconsiderable costs.

As an alternative to the safety reset using a compressed air reservoir also a provision via spring systems, usually helical compression springs Coil springs, generally known. The springs can either be in the drives be integrated or attached to the outside in modular construction.

Since the springs move from the "safe" in each time the actuator is adjusted the "unsafe" position must be tightened, an increased energy requirement caused. Furthermore, the actuator must be made much larger be placed because the force required to operate the valve is around - with the Actuating path increasing - force to tension the springs must be increased. This typically results in a doubling of the construction volume and often also the manufacturing costs.

Since the springs are tensioned with every actuation, they have to last be interpreted firmly, because a spring break would the safety function of the one override direction. A corresponding oversizing of the springs is therefore inevitable, which leads to a further increase in the operating force.

While with a rapid pressure drop, e.g. B. as a result of a pipe burst, the Si security provision with the help of springs shows good behavior Problems when the network pressure drops gradually, as it does with the Failure of the compressor is typical. When falling below a certain network pressure there is a beginning adjustment of the actuator in Direction of the "safe" switch position, as that caused by the network pressure Actuating force is less than the restoring force of the springs. As a consequence, that the actuator and thus the associated valve an undefined Intermediate position. Such intermediate positions can be uncalculated security risks, as the effects of such undefined Switching states, especially in complex systems, can hardly be estimated.  For this reason, the pressure in the compressed air network must be monitored by a special monitor system are constantly observed, which in turn translates into an increase in costs voices.

The invention has for its object a device for safety reset propose a pneumatic actuator, which is characterized by ei feature a small space requirement and allows the size of the loading Actuator compared to constructions with a spring return to the right reduce. Furthermore, the device should be inexpensive to manufacture and none require complex control or monitoring technology.

Starting from a device of the type described at the beginning, this will be open surrender according to the invention solved in that the compressed air reservoir by means of a the compressed air network operated compressor can be charged via a pressure min dereinrichtung is connected to the supply line of the actuating device.

Due to the charging of the storage device usually to a multiple of the network pressure, the storage volume compared to storage that is only on the Pressure level in the compressed air network are significantly reduced. Therefore is an integration or a direct extension of such a compressed air reservoir in or to the actuating device easily possible.

Since the charging of the memory is operated with the help of one of the compressed air network itself compressor, no external drive of the compressor is required. A lot the compressor takes more of the energy it needs directly from the compressed air network, which usually also applies to the air to be compressed, since it is already there is pre-compressed to network printing.

The pressure reducing device ensures that in the event of a safety security provision, d. H. a compressed air withdrawal from the store, the supply line and the actuating device not with the full storage pressure  be struck, for example, to overload the actuator or other components.

Compared to the known devices with a spring return, the Be Actuating device can be made significantly smaller, since return springs are not are necessary and therefore do not have to be constantly excited. In Ver same to the known devices with one loaded only on network pressure Memory, the device according to the invention is characterized by the drastically right reduced installation space. Mains operated compressors are well known and white sen in typically self-regulating properties, so that both on one separate compressor drive as well as complicated control technology can be.

Therefore, the device according to the invention is also suitable for. B. for retrofitting for double-acting actuators with a safety function to be equipped.

According to one embodiment of the invention, it is provided that a switching element a pneumatically actuated and electrically controllable valve of the actuator supply device can only be acted upon by the network pressure if the pressure in the compressed air reservoir exceeds a minimum value. This prevents after a safety reset, the valve is switched back to the "unsafe" position occurs before the compressed air reservoir is loaded to a level that allows a new security reset at any time.

The aforementioned valve of the actuating device is more typical a so-called standardized NAMUR valve according to the regulation VDI / VDE 3845. This is a standardized interface between the Actuator and its environment.

Developing the invention further, it is proposed that the switching element of the pneumatically operated and electrically controllable valve of the actuator  The system pressure can only be applied when the pressure in the memory the pressure set on the downstream side of the pressure reducing device exceeds a certain factor.

Compared to a comparison of the storage pressure with an absolute value offers a Comparison with the pressure on the downstream side of the pressure reducing device the possibility of activating the valve of the actuator with compressed air de switching element even with different network pressures or a change to leave the downstream pressure on the pressure reducing device unchanged sen.

The compressor is advantageously a stepped piston valve poet who is characterized by a simple structure and after building a compression due to its geometry-dependent pressure ratio sets and after a pressure drop in the memory automatically with the Ver seal begins. With such compressors, compaction races can easily be achieved score of 20.

A particularly advantageous development of the invention is that the Compressor a pressure integrated in a common cylindrical housing has air storage.

The manufacturing costs can be further reduced if the compressor, the Compressed air accumulator, the pressure reducing device and a switching valve for charging supply of the switching element of the valve of the actuating device to a structural unit are summarized.

To further reduce the manufacturing costs, it is proposed that a Compressed air reservoir and housing forming a cylinder space of the compressor and / or a compressor piston made of a glass fiber reinforced thermoplastic Plastic material are made.

The invention is described below using an exemplary embodiment of a device device for security provision, which is shown in the drawing, explained in more detail. It shows:

Fig. 1 shows the circuitry structure of the device in the form of a sketch and

Fig. 2 shows a longitudinal section through a structural unit from the compressor and compressed air reservoir and other elements.

A device shown in Fig. 1 for safety reset of a pneumatic actuating device 2 in the form of an actuator for a valve comprises a compressed air reservoir 3 , a compressor 4 , a pressure reducing device 5 , a switching valve 6 and various line sections and check valves.

The actuating device 2 has a in a cylinder space 7 axially movable and pressurizable piston 8 on both sides, which causes actuation of a valve, also not shown, between two end positions via a mechanism, not shown. A valve 9 is connected to the actuating device 2 to form a structural unit, which essentially corresponds to the NAMUR type according to VDI / VDE 3845. This valve 9 can be actuated pneumatically against the force of a spring 10 and can be controlled electrically with the aid of a valve body designed as an armature and arranged in a coil 11 for the compressed air required for switching.

Compared to a non-modified NAMUR valve, a line section 12 for supplying compressed air to a switching element located inside the valve 9 is not directly connected to a compressed air source 13 . Rather, the line section 12 is pressurized with compressed air depending on the position of the switching valve 6 , the function of which will be explained in more detail later.

In normal operation with a compressed air reservoir 3 and sufficient ho hem pressure of the compressed air source 13 , the switching valve 6 establishes a connection between a line section 14 and the line section 12 , so that in this case compressed air at the NAMUR valve for switching it depending on the electrical Signal applied to the coil 11 .

In the event of failure of the electrical control of the actuating device, the electromagnetically actuated valve body completes the pressurized air of the switching element of the valve 9 , so that the switching element falls due to the spring 10 into the switching position shown in FIG. 1. As a result, the left half of the cylinder chamber 7 is pressurized with compressed air and the piston 8 is moved into the position defined as "safe". As soon as the electrical control is functional again, the piston 8 of the actuating device 2 and thus the valve can be brought back into the other position.

In the event of a sudden drop in the pressure in the line network, the air under high pressure in the compressed air reservoir 3 flows via the line section 15 , the pressure reducing device 5 , a check valve 16 and a supply line 17 to the valve 9 of the actuating device 2 , if it is considered necessary to move the valve to be switched to the safety position. For this purpose, the electrical signal on the coil 11 must be switched off in order to cause the spring 10 to switch the switching element of the valve 9 into the position shown. In this case, the air coming from the compressed air reservoir 3 causes the piston 8 and thus the valve to be brought into the “safe” position. Another check valve 18 prevents compressed air from escaping into unpressurized areas of the network.

If the pressure in the line network is restored, this pressure is applied to the compressor 4 via a line section 19 . This starts automatically with the compression and filling of the compressed air reservoir 3 via a line section 20 and only ends its compression work automatically when the pressure in the compressed air reservoir 3 is greater than the pressure in the line network by a certain factor. This factor is determined by the geometry of the step piston of the compressor 4 and in the present case is approximately 20. For safety reasons, the device is provided with a safety pressure relief valve 21 .

An operation of the operating device 2 is possible again only when the switching valve 6 opens the pressure air supply to valve 9 via the line sections 14 and 12. FIG. The switching valve 6 is therefore always compared between the pressure in the compressed air reservoir 3 and the outflow side of the pressure reducing device 5 . Once the memory pressure than the downstream dereinrichtung on the Druckmin is greater than 5 set pressure, it depends on the downstream side of the pressure reducing device 5 at no additional pressure rise more. While this constant pressure acts on a large area of the switching element of the switching valve 6 , only a much smaller area is applied by means of the higher storage pressure on the opposite side of the switching element. Due to this geometry, an approx. 16- to 17-fold increase in the network pressure in the compressed air reservoir 3 is required until the switching valve 6 , starting from the shown safety position, switches to the position in which the compressed air supply to the NAMUR valve of the actuating device 2 is released becomes. From this moment on, the actuating device 2 can again be switched as a function of the electrical signal on the coil 11 .

FIG. 2 shows a longitudinal section through a compressor 4 designed as a step piston compressor, which together with a self-switching compressor valve 22 , the safety valve 21 , the pressure reducing device 5 and the switching valve 6 forms a structural unit.

Starting from the compressed air source 13 , the air flows through the compressor valve 22 into a left-hand compressor chamber 23 in order to transfer the rotationally symmetrical stepped piston 24 to the right-hand dead center position shown. The compressor piston 24 compresses with its nose 25, which is reduced in cross section, in a section of the compressor chamber which is adapted to it, starting from the pressure level of the network, to a multiple of this value, the air being passed through a check valve into an inner compressor chamber located inside the nose 25 26 is transferred. As soon as the compressor piston 24 has swept a control edge 29 located in the housing 28 with its left end face 27 , compressed air passes through the control line 30 to the right side of the switching element of the compressor valve 22 , so that it switches over and then via the line section 31 the stepped right end face 32 of the compressor piston 24 is pressurized with compressed air. This is also acted upon by compressed air in the region of the end face 33 of the nose 25 via the line section 34 . Thus, there is a piston movement to the left, in which the pre-compressed air is compressed further in the compressor chamber 26 and passes via a line 34 'into a central guide pin 35 in the storage chamber 36 . Once the left end 32 of the compressor piston 24, the right control edge has passed over 37, the left side of the compressor valve is supplied with compressed air 22 so that it comes to a renewed automatic switching of the compaction terventils 22 via the control line 38 in turn.

The oscillating movement of the compressor piston 24 is repeated until an equilibrium state is reached due to the increasing pressure in the storage space 36 , which is determined solely by the area ratios on the compressor piston 24 . In the present case, an approximately 20-fold increase in the network pressure is achieved.

The integrated pressure reducing device 5 supplies the left side of a switching piston 40 in the switching valve 6, which is also integrated, via a line 39 . The switching piston 40 is pressed into its right dead center position by a spring and in this position separates the line section 14 connected to the compressed air source 13 from the line section 12 leading to the NAMUR valve. As soon as the pressure acting on the small right end face of the switching piston 40 in the storage space 36 of the compressed air reservoir 3 reaches about 16- to 17 times the pressure set behind the pressure reducing device 5 , the switching piston 40 moves from its right into the left dead center position and releases a connection between the line sections 14 and 12 , so that compressed air actuation of the NAMUR valve is possible depending on the electrical signal on the coil.

In order to realize low manufacturing costs, both the storage space 36 and the compression space 23 enclosing the housing 28 as well as the sealing piston 24 and the guide mandrel 35 are made of a fiberglass-reinforced plastic material. Control and regulation devices are just as little necessary for the operation of the compressor 4 as the supply with an external energy beyond the compressed air connection. Due to the selected geometry, the pressure in the storage space 36 corresponds to approximately 20 times the pressure in the compressed air network after it has reached a steady state.

Claims (7)

1. A device for safety reset of a pneumatic actuating device ( 2 ), in particular a valve actuator, the device ( 1 ) having a compressed air reservoir ( 3 ) by means of which the actuating device ( 2 ) can be reset, characterized in that the compressed air reservoir ( 3 ) by means of of a compressor operated via the compressed air network ( 4 ) can be charged, which is connected via a pressure reducing device to the supply line ( 17 ) of the actuating device ( 2 ). 2. Device according to claim 1, characterized in that a switching element of a pneumatically actuated and electrically controllable valve ( 9 ) of the actuating device ( 2 ) can only be acted on with the network pressure when the pressure in the compressed air reservoir ( 3 ) exceeds a minimum value. 3. Device according to claim 2, characterized in that the switching element of the pneumatically actuated and electrically controllable valve ( 9 ) of the actuating device ( 2 ) can only be acted upon with the network pressure when the pressure in the compressed air reservoir ( 3 ) is on the outflow side the pressure reducing device ( 5 ) set pressure increases by a certain factor. 4. Device according to one of claims 1 to 3, characterized in that the compressor 4 is a staged piston compressor. 5. Device according to claim 4, characterized in that the compressor ( 4 ) has a compressed air reservoir ( 3 ) integrated in a common cylindrical housing ( 28 ). 6. Device according to claim 4 or 5, characterized in that the United poet ( 4 ), the compressed air reservoir ( 3 ), the pressure reducing device ( 5 ) and a switching valve ( 6 ) for acting on the switching element of the valve ( 9 ) of the actuating device ( 2nd ) are combined into one unit. 7. Device according to one of claims 1 to 6, characterized in that a compressed air reservoir ( 3 ) and a compressor chamber ( 23 ) of the compressor ( 4 ) forming the housing ( 28 ) and / or a compressor piston ( 24 ) made of a glass fiber reinforced thermoplastic material consist.