DE1277918B - Circuit arrangement for generating two switching pulses for bistable switching means - Google Patents

Description

Circuit arrangement for generating two switching pulses for bistable Switching means The invention relates to a circuit arrangement for generating two Switching pulses for bistable switching means. Switches can be used as switching means electromechanical design, magnetic switches or switches with purely electronic ones How it works can be understood. The only requirement is a bistable behavior the switching means, d. H. after the end of a switching pulse, the switching means must Remain in the new working position caused by the impulse. To reset Another impulse is necessary to return to the original position.

The circuit arrangement is characterized in that according to the invention a relay with two response circuits is provided, the first of which through a the switching element initiating the pulse generation is activated and the second contact contains both the relay and the bistable switching means in such an arrangement, that he is in a working position after the fall of the first response circuit switched relay is closed, and that a contact of the relay so in a Control circuit of the bistable switching means is inserted that the switching means the two switching impulses are received by the relay responding twice.

In principle, therefore, a doubling of the pulse is effected, in which case it is more advantageous Way the generation of the second pulse from the actuation of the relay and the bistable Switching means depends during the generation of the first pulse and accordingly a there is a fixed temporal assignment between the two pulses.

The initiation of the pulse generation can be done both by one in one Response circuit of the relay lying contact as well as by changing the flow in the armature of the relay with the help of an additional winding or one brought in from the outside Additional field. The circuit is not related to certain embodiments of the Contacts of the bistable switching means bound. Contacts are not the only ones mechanical design in question, but are also magnetic or electronic To use contact devices. For example, a protective gas contact can be known Build-up by a magnetic field created by the current change of an active electronic Component is built up in a bistable multivibrator, in a working position be switched.

The bistable switching means need to switch properly Pulses of certain minimum durations. These minimum durations differ depending on the Design of the individual switching means in part considerably. To the circuit arrangement to be able to use according to the invention for all forms of switching means is in an advantageous development of the invention, a failure delay for the relay provided that, depending on their dimensions, a more or less long Pulse duration allows. For this purpose, in a known way, connected in parallel via a contact, charged capacitors or short-circuit windings are provided. When applied a circuit arrangement according to the invention for different types of bistable Switching means can also be used advantageously through a controllable design the drop-out delay can be achieved.

To achieve an iling break, which in many cases is aimed at Between the two pulses, a device can be used to delay the pick-up of the relay are provided. The insertion of an NTC thermistor has proven to be particularly advantageous into the second response circuit, as this does not affect the first tightening process will. The provision of adjustable series resistors also allows for variability the length of the pulse pause and thus a versatile application of the circuit arrangement can be achieved.

The exact mode of operation of the circuit arrangement according to the invention is shown on the basis of FIG. 1 and 2 illustrated. It is assumed here that with the circuit arrangement according to the invention a lock in a pneumatic tube system should be controlled.

In pneumatic tube systems with very long routes, cans, z. B. at suction air-fed receiving stations, from an area of high negative pressure in enter an area with normal atmospheric pressure. To discharge the Bushing is one with between the two pressure areas two doors Integrated lock. A valve is used here to change the pressure in the lock chamber used, which consists of a four pipe socket having housing and one in its Center pivoted between two positions with the help of a magnet Flap exists. The valve represents a bistable switching means, i. H. to switch the flap from the rest position to the working position and back is each an impulse certain length required.

The mode of operation and arrangement of the valve in the pneumatic tube system is based on the in F i g. 1 described the traffic schemes shown.

The bush, which is sucked in in the tube R, hits the door T. 1 on. In the lock chamber S there is also negative pressure. The door T 1 is therefore relieved and the sleeve can enter the lock S. After entering the rifle closes the door T 1, for example under the action of a spring, and the Fahrrohrkontaktf is operated. This switches the valve magnet VM to a different position, in which he connects the lock chamber S with outside air, so that the negative pressure is canceled will. This relieves the load on door T2 and the bushing extends. After exit the sleeve, the valve must be switched back to the rest position, since the lockS must be made ready to receive again for the next rifle.

The valve magnet is controlled by the circuit arrangement according to FIG. 2.

The sleeve entering the lock chamber S actuates the contact tube f and thus closes the first group of claims I of the relay A. Since the Fahrrohrkontaktf is only actuated briefly, relay A drops out again immediately, but is in its fall through the parallel connected via the contact al to a second winding of the relay Capacitor r1 delayed in its fall. Since a contact vm of the valve magnet VM has prepared the second response circuit II after switching it, this can Relay A pull in again immediately after it has dropped out. To achieve a sufficient Pause between falling off and tightening, in which outside air via valve V flow in and the can leave the lock S via door T2 is for Pull-in delay an NTC thermistorHL switched on in the second response circuitII. The contact2, which interrupts the circuit during the second tightening process and thus a final tightening of the relay A would prevent, is by the Capacitor C 2 bridged by a charging current at the moment of dropping off a2 causes the relay to finally pull in.

The resistor R 2 is used to limit the discharge current.

With the circuit arrangement according to the application can therefore be with very little effort one for many purposes of control, regulation and counting achieve required pulse multiplication.

Claims (6)

Claims: 1. Circuit arrangement for generating two switching pulses for bistable switching means, characterized in that a relay (A) with two Response circuits (I, II) is provided, of which the first (1) by a pulse generation introductory switching element (1) is activated and the second (II) contacts both the relay (A) and the switching means (VM) in such an arrangement that he after the fall of the first response circuit (1) in a working position switched relay (A) is closed, and that a contact (a3) of the relay (A) so inserted into a control circuit of the switching means (VM) that the switching means (VM) receives the two switching impulses by responding twice to the relay (A). 2. Circuit arrangement according to claim 1, characterized in that a device (C1, al) known per se for achieving a fall delay of the relay (A) is provided with a view to actuating the switching means (VM) sufficient width of the switching pulses is selected. 3. Circuit arrangement according to claims 1 or 2, characterized in that that in the second response circuit (11) of the relay (A) circuit elements (HL) are provided are the one with regard to the desired pause between the two switching pulses cause the selected pick-up delay of the relay (A). 4. Circuit arrangement according to claim 3, characterized in that as circuit elements (HL) NTC thermistors are used. 5. Circuit arrangement according to claims 1 to 4, characterized in that that the contact (vm) of the switching means contained in the second response circuit (11) (VM) is arranged in series with a break contact (a2) of the relay (A). 6. Circuit arrangement according to claim 5, characterized in that the normally closed contact (a 2) of the relay (A) is bridged by a capacitor (C2), during the second response process of the relay (A) after the break contact has been removed (a2) a change in charge also briefly energizes the relay (A).