DE1263402B - Low-noise pneumatic control device - Google Patents

Description

Low Noise Pneumatic Control Apparatus The invention relates to a low-noise control device for double-acting pneumatic piston motors with a reversing slide operated by compressed air on both sides, which controls both the supply of compressed air in the working cylinder of the motor as well as the outlet controls and the reversing signals of two mechanically actuated by the piston movement, receives pilot valves designed as pilot-operated check valves.

With the outflow of compressed air directly at the work site, there are outflow noises connected, which can make working conditions difficult in many cases. The the Compressed air is added to the lubrication of the moving parts in pneumatic devices Oil mist is only partially separated in the devices. Part of the oil mist remains in the compressed air and is released into the open with the compressed air flowing out. For reasons of improving working conditions and for hygienic reasons Such a control is therefore desirable wherever immediate No compressed air may escape at the work site of the piston engine.

It is known to use double-acting reciprocating piston engines on both sides Compressed air operated reversing spool, which both the supply of compressed air to the Control cylinders of the engines as well as the exhaust to actuate. Farther various versions of auxiliary control valves are known, which, if they are through the thrust piston movement is actuated mechanically, reversing signals to the compressed air actuated Release reversing spool .. The pilot valves can be separated from the Reversing spools arranged or directly connected to them (German Patent 553 848, French Patent 1271152). There are also special constructions known in which piston engine, reversing spool and auxiliary control valves too are combined in an aggregate (German patent specification 904 858). Pilot valves are essentially 2/2-way valves that work together with throttling points, and 3/2-way valves.

There are also combinations of 2/2-way valves with check valves known, which correspond in their function to pilot operated check valves and which can be used as pilot control valves.

2/2-way valves that work with throttling points and 3/2-way valves can be used to build low-noise pneumatic controls; will. Included must flow out of the pilot valves through additional pipelines Compressed air can be discharged. There are higher costs due to material and assembly costs.

There is no need to lay additional pipelines if combinations of 2/2-way valves with check valves or pilot operated check valves can be used as pilot valves.

These auxiliary control valves do not receive their supply air directly from the Compressed air generator or compressed air network, but from the through the reversing slide controlled working air lines of the piston engines. This will make the Venting of the pneumatic control rooms, compressed air to be discharged into the working air lines which is vented through the changeover slide in the respective switching position will. It is known that the control elements required for such controls the reversing spool in its end positions by locking or by frictional forces unintentional adjustment must be secured because in the time between their Reversals, both control air lines are vented. When the control member of a reversing spool is reversed, the pressurized control room becomes Displaced air. This can only be done via the releasable check valve and the vented working air line of the piston engine escape until the previously vented The working air line of the piston engine is pressurized. It will the pilot operated check valve is closed. But since the control element is up Moved further into the end position, the in the control room and the control air line Air that is located up to the releasable check valve is compressed. The smaller the control space remaining in the end position of the control element or the shorter the The higher the control air line leading from the control room to the check valve the pressure will increase. However, since after the reversal of the Control slide the controlled working air line is vented, the pressure built up in the Control room, in that it overcomes the locking or frictional force of the control member, the same Press back to the central position and thus the flow cross-section of the reversing spool reduce or completely shut off or even all lines within the reversing spool connect with each other. In many cases this prevents the applicability of a such low-noise control of piston engines with reversing spools, which are controlled in the manner shown with pilot operated check valves.

The time for reversing the reversing slide is in such a low-noise control device relatively large, because the ventilation of the control rooms of the reversing spool not only due to the flow resistance in the control air line is delayed from the control chamber to be vented to the auxiliary control valve, but rather also due to the flow resistance in the control air line .of the auxiliary control valve to the reversing valve and through its own flow resistance.

The invention is based on the object of the functional uncertainty, those in the known construction of low-noise control devices with unlockable Check valves occurring as auxiliary control valves, avoid and at the same time to achieve a shortening of the reversing times.

This object is achieved according to the invention in that a double outlet valve for the control air, its valve chambers each with one of the two auxiliary control valves such a control air line leading to one of the control rooms of the reversing slide are connected that each under lower; Pressurized control air line connected to the free atmosphere.

An embodiment of the invention is shown in the drawing and is described in more detail below. It shows F i g. 1 the thrust piston in Moment of extension, F i g. 2 the thrust piston at the moment of reversing, F i g. 3 shows a simplified circuit diagram of a control device according to the invention.

A pneumatic thrust piston motor 1 with a thrust piston 2 sliding therein and with a cam 3 is controlled by a reversing slide 4 by a control member 5 movably arranged therein. When a control air line 6 or 7 is pressurized, this control member 5 is pushed to the left or right by means of pistons 8 and 9, respectively. As a result, working air lines 10 and 11 are connected to a compressed air line 12 and the working air lines 11 and 10 are connected to a ventilation line 13 to which a silencer 14 is attached. A one-way flow control valve 15 is arranged in line 10. This allows the speed to be limited when the thrust piston is extended. Two pilot operated check valves 16, 17 are attached as auxiliary control valves so that their roller levers 18, 19 are pressed down in the end positions of the thrust piston 2 by the cam 3 against the action of springs 20, 21. As a result, back impact elements 22, 23 are lifted from their seats 24, 25, and compressed air can from a control air line 10 a to a control air line 26 and via an open shut-off valve 27 to the control shift lines 7, 7 a or from the control air line 11 a to the control air lines 6, 6a arrive. The control air line 7 is connected to a left control chamber 28 and the control air line 6 is connected to a right control chamber 29 of the reversing slide 4. A double outlet valve 32 contains two sealing disks 35, 36 on a guide part 34 which is movable in the housing 33 and which, when pressed against seats 37 or 38, can block the connection between the valve chambers 30 or 31 to the atmosphere via opening 39.

The mode of operation of the control device shown is as follows: In FIG. 1 shows the position of all control units while the thrust piston 2 is being extended. The control member 5 of the reversing slide 4 is in the right end position. As a result, the working air line 11 and the control air line 11a are connected to the compressed air supply 12 and the working air line 10 is connected to the ventilation line 13. As a result of the pressure difference acting on the thrust piston, the piston moves out, whereby the throttle valve in the throttle check valve comes into effect and limits the thrust piston speed. Since the control air line 11a is pressurized, the non-return element 23 is pressed onto its seat 25 and thus blocks the passage of air to the control air line 6, which is connected to the free atmosphere via the control air line 6a, valve chamber 31 and opening 39. The control air line 10 a is vented via the working air line 10 so that the non-return element 22 has lifted from its seat and the control air lines 7 and 7 a are also vented via the open shut-off valve 27 and control air line 26.

In Fig. 2 is the position of all control units at the moment of reversing of the thrust piston shown from forward return. The cam 3, which is with the Moving the thrust piston, pushes the non-return element 25 from the roller lever 19 Seat 23 from. As a result, the compressed air present in the control air line 11a arrives Via control air line 6 to the right control chamber 29 of the reversing slide 4 and via Control air line 6a to the double outlet valve 32. As a result, the guide part has 34 with the disks 35, 36 moved to the left and the connection between the valve chamber 31 to the open atmosphere via the opening 39 is blocked, but the connection is therefor of the valve chamber 30 via the opening 39 to the free atmosphere. The control element 5 of the reversing slide 4 is in a middle position on the way in the left end position. The working air line 10 and the control air line 10 a are already connected to the compressed air supply via a certain passage cross-section. As a result, the non-return element 22 is pressed against its seat 24. The result the movement of the control member 5 from the control chamber 28 displaced air can not more escape via the check valve 16. But that's what the left control room stands for 28 via the control air lines 7, 7 a with the valve chamber 30 in connection, the is in turn connected directly to the free atmosphere via the opening 39.

The advantages achieved with the invention are that low noise Control devices can be built with great functional reliability, with at the same time, the reversing times of the reversing spool can be kept low.

Claims (1)

Claim: Low-noise control device for double-acting Pneumatic piston motors with a reversing slide valve operated by compressed air on both sides, both the supply of compressed air in the working cylinder of the motor and the The outlet controls and its reversing signals of two by the thrust piston movement mechanically operated pilot valves designed as pilot operated check valves receives a double outlet valve (32) for the Control air, its valve chambers (30, 31) each with one of the two auxiliary control valves (16 or 17) leading to one of the control rooms (28 or 29) of the reversing spool (4) Control air line (7 or 6) are connected in such a way that each under lower Pressurized control air line (7 or 6) connected to the free atmosphere is. Considered publications: German Patent Specifications No. 904 858, 553 848; German Auslegeschrift No. 1017 855; French patent specification No. 1271152. Older patents considered: German patents No. 1230 264, 1230 263.