DE1952986B2 - Bistable fluidic control valve for an oscillator with five ways - Google Patents

Description

The invention relates to a bistable fluidic control valve for an oscillator with five paths according to FIG the preamble of the main claim.

Such a control valve is known from US Pat. No. 76,477. The control valves of this well-known However, Art have the disadvantage that they do not have one when used to build a pneumatic oscillator Have negligible switching time if the control pressure increases progressively. This lack leaves to resolve itself by the fact that for a practically instantaneous change between the time control of the oscillator and the control of the distributor a sequence valve is switched, which the rising Converts control pressure into a sudden pressure pulse, which, however, also entails additional effort requires an additional source of interference.

The invention is therefore based on the object of providing a control valve for the stated purpose create that has special structural advantages, above all is simple and that switches without delay, without that additional resources must be used.

The solution to this problem is done with the characterizing features of the main claim.

The piston valve can advantageously be in the inlet chamber be provided with a cylinder jacket and with a central transverse wall, with each of the one or other connecting channel is closed, and there is also a cheaper constructive AufbaUj., If the valve bodies in the dispensing chambers are shell-shaped.

The control valve is particularly suitable for building a pneumatic double oscillator. Suffice it to do one pneumatic timing device between each exit port and each pneumatic control chamber to insert.

Based on the drawing, in which a single embodiment of the invention is shown, the Control valve on an oscillator with five ways shown and explained, the drawing being a longitudinal section represents

The bistable pneumatic control valve consists of a body 1, which is preferably made of a plastic material is made and consists of a large number of individual parts that are joined together are, although in the drawing the corpus for the sake of simplicity in the representation as contiguous block is reproduced.

Inside the body 1, which has an essentially cylindrical shape with a longitudinal axis of symmetry jf-Af 'and a transverse plane of symmetry y-y', there are several chambers, namely an inlet or middle feed chamber 2, two intermediate outlet chambers 3 and 4, symmetrical to the plane of symmetry y-y ', and two outer outflow chambers 5 and 6, which are also symmetrical to the plane of symmetry yy'.

The middle chamber 2 is connected at its two outer ends via a line or an inlet channel 7, which also connects the chamber to an outer line 8 which connects to a source of compressed air. In the interior of the central chamber 2 there is a slide 9 which is formed by a very easily movable free piston. The slide has a cylindrical piston skirt 9a and a central transverse plate 9b and thus divides the inlet chamber 2 into two parts 2a and 2Zj. The slide 9 represents a flap valve for the connecting openings 10 and 11, which lie on the axis x-x 'and connect the middle chamber to the two middle output chambers 3 and 4. In chambers 3 and 4, there are further flap valves 12 and 13 from key-shaped shape inserted easily displaceable. These flap valves have the task of closing the outflow openings 14 and 15, which establish the connection between the outlet chamber 3 and the outflow chamber 5 on the one hand and the outlet chamber 4 and the outflow chamber 6 on the other.

Output openings 16 and 17, which pass through the body 1, form a connection between the Chambers 3 and 4 and exit lines 18 and 19.

The outflow chambers 5 and 6 are in communication with the free air via openings 21 and 22. In the Chambers 5 and 6 are also piston tappets 23 and 24, which by two slack membranes 25 and 26 can be controlled. The slack membranes close the two outflow chambers 5 in the body and 6 against control chambers 27 and 28, into which a control pressure medium via control openings 29 and 3i

to be introduced.

The mode of operation of the pneumatic bistable cell will now be described independently of its application in a pneumatic double oscillator. If the feed line 8 is brought into connection with a source of compressed air, the piston valve 9, which is very light and practically never occupies an equilibrium position in the middle of the chamber 2, is under the influence of the compressed air against one or the other connection opening 10 or 11 printed assume again as an example, that when supply of compressed air to the chamber 2 of the piston slide 9 even at the opening 11 abuts the two portions 2a and 2b of the center chamber 2 equal to the pressure of the supplied air are exposed, but the air can, the is located in the chamber 2a, act on the entire surface of the piston partition 9b of the piston valve 9, while the pressure in the chamber 2b can only act on the outer ring zone of the piston partition, so that it is understandable that the piston valve 9 continues against the opening 11 is pressed, with the resulting differential pressure. Since the piston valve 9 does not close the opening 10, the chamber 3 also receives the same pressure, whereby the flap valve 12 is pressed out of its seat and the exhaust opening 14 closes, while compressed air from the outlet opening 16 enters the outlet line 18 because the flap valve 13 does not open its seat is pressed, there is in the chamber 4 and thus also in the output line 19 atmospheric pressure.

In the first stable position of the bistable pneumatic cell, there is thus in the output line 18 the pressure of the air supplied while there is atmospheric pressure in the line 19

If a control overpressure is now introduced into the chamber 27, which takes place via the opening 29, the membrane 25 receives this control overpressure on its left side, while atmospheric pressure is present on the right side, whereby the membrane is deformed and bends to the right and thus also the plunger 23 moves. This now passes through the opening 14 and lifts the flap valve 12 from its seat. The chambers 3 and 2a are thus immediately brought into contact with the atmosphere and empty to the same extent as the pressure decreases. In contrast, the chamber 2b can only empty through the annular gap between the piston skirt 9a of the piston valve 9 and the inner wall of the chamber, which happens very slowly, so that the pressure in this chamber is always greater than the pressure in the sub-chamber 2a. Under the influence of the pressure difference resulting therefrom, the piston valve 9 is displaced to the left and lies against the opening 10, which it thus closes. At this moment the connection between the compressed air source and the chamber 3 is interrupted, and the pressure in this chamber 3 and the connected line 18 drops and remains at the value of atmospheric pressure.

At the same time, the output chamber 4 is connected to the input chamber 2 and is filled with the Compressed air. The pressure acting on the flap valve 13 pushes it to the right against its seat, whereby the opening 15 is closed. The compressed air now flows through channel 17 into the Exit line 19. The pneumatic bistable cell hai uainii assumed its two Siäbilc position, in the outlet line 13 is under pressure while in the other outlet line 18 atmospheric pressure prevails

Wi ^r d is now again a control pressure chamber 28 which is supplied via the opening 31 so the just-described operation is running in the reverse direction again from. The membrane 26 moves the plunger 24 to the left, which in turn lifts the flap valve 13 from its seat. The chamber 4 then comes into contact with the atmospheric pressure via the opening 15 and the resulting pressure difference in chambers 2a and 2b ensures that the The piston valve 9 rests against the opening 11 again, so that the pneumatic cell then assumes the first stable position again

In the various possible forms of application, the control of the tappets 23 and 24 can also be implemented in be made in another way, e.g. B. mechanically, hydraulically or electrically.

It will now be described how a double oscillator is created with the help of the bistable pneumatic cell can be realized. For this purpose, the output line 18 is connected to the opening 29 of the control chamber 27 connected via a clock generator which has a controllable throttle point 32, a check valve 33 and a memory 34 contains the controllable throttle 32 and the check valve 33 in parallel are inserted into the line 18 with respect to one another and the memory 34 with the opening 29 via a line 35 connected is. The same is the other output line 19 with the inlet opening 31 of the control chamber 28 connected via a second timing arrangement, which has a controllable throttle point 37, a check valve 38 and a memory 39, the controllable throttle point 37 and the non-return valve 38 are parallel to one another in the line 19 and via the memory 39 and a line 41 with the opening 31 are connected.

The double oscillator just described works as follows:

If the feed line 8 is connected to a compressed air source, one of the output lines becomes the bistable pneumatic cell, e.g. B. the line 18, pressurized as previously has been described. The compressed air that prevails in the output line 18 is controlled by the timing arrangement 32, 33, 34 converted into a delayed control pressure, which is applied to the control chamber 27 via the line 35 is transmitted. This pressure acts on the left-hand surface of the diaphragm 25 and calls a practical instantaneous turning over of the pneumatic bistable cell. From that moment on, the other output line 19 has the overpressure, whereas the output line 18 has atmospheric pressure. Above the check valve 33, the memory 34 can be emptied very quickly. The second timing arrangement 37,38,39 now sets the pressure prevailing in the output line 19 into a delayed control pressure um, which is fed to the control chamber 28 via the line 41. The control pressure acts on the membrane 26 and causes a renewed switching of the bistable pnermatic cell, so that this from the second position returns to the first position. The intended work cycle is in the described manner in front of you, the output lines 18 and 19 alternately receiving the pressure. the delays introduced by the two timing arrangements 32, 33, 34 and 37, 38, 39 are

the independently and can be set completely separately from each other, which can be done by adjusting the throttle points 32 and 37 happens. Optionally, these throttling points 32 and 37 can also have a constant passage cross-section have, and to adjust the delay of the two timing arrangements it is possible to use the Change the volumes of the stores 34 and 39. One of the output channels, in the example shown the channel 18, can with the interposition of an adjustable throttle 42 (in order to increase the amount of air released control) with an organ that periodically uses compressed air

is to be supplied, such as a ventilation mask.

It goes without saying that the exemplary embodiment described can be modified in numerous ways without that this leaves the scope of the invention and that this example is only illustrative. So the bistable cell according to the invention also works with a liquid instead of a gas, in which case the Blow-off openings 21 and 22 through return lines with a reservoir containing the liquid get connected.

1 sheet of drawings

Claims (3)

Patent claims: 1. Bistable fluidic control valve for one Oscillator with five paths, which is constructed symmetrically with respect to its longitudinal center plane, its The inlet opening located in the body is connected to a source of pressurized fluid and a first and a second discharge opening and a first and a second blow-off opening from the body lead out, while the body has a central entrance chamber into which the inlet opening opens and to which via a first and a second connecting channel on both sides of the Entrance chamber a first and second dispensing chamber are connected, from which the dispensing openings lead out, which are also connected to the Aftblasöffpungen via blow-off ducts and in which there are valve bodies with which the connections to the blow-off openings are interrupted can be, with a first and a second plunger outside the first and second, respectively Dispensing chamber are arranged in such a position to the blow-off channels that they penetrate them and in the dispensing chambers are able to lift the valve bodies from the blow-off ducts, for which purpose the optional lifting of the first or the second valve body actuating devices for the Plungers are present, characterized that there is a freely movable piston valve (9) in the input chamber (2), which is in its two end positions the first and second connecting channel (10, 11) closes, and that the Valve bodies (12, 13) in the dispensing chambers (3, 4) are free piston slides. 2. Control valve according to claim 1, characterized in that the piston slide (9) in the input chamber (2) is provided with a cylinder jacket (9a) and with a central transverse wall (9b) with which the first or second connecting channel (10, 11) are lockable. 3. Control valve according to claim 1 or 2, characterized in that the valve body (12,13) in the Dispensing chambers (3, 4) are cup-shaped.