DE1293875B - Pulse divider circuit with a bistable relay for telecommunications, especially telephone systems - Google Patents

Description

The invention relates to a pulse divider circuit for telecommunications, in particular telephone systems, consisting of a bistable relay, its winding with a capacitor is firmly in series, this series connection by a Contact of the relay is activated alternately so that each working position the simple pulse contact controlling the clocking process reverses the polarity of the Causes voltage on the capacitor.

Pulse divider circuits have already become known with only a relay and a capacitor are equipped. In a known such Circuit, the relay has at least two windings, one of which is used for formation a self-holding circuit is used. Closing a pulse contact will the charged capacitor depending on two changeover contacts of the relay discharge the second relay winding in alternating directions so that the relay energized or triggered. This circuit has the disadvantage that a relay with at least two windings are required and for controlling the pulse divider circuit a large contact effort in the form of at least two pulse change contacts and a working contact is required to form the holding circle. Furthermore are to identify the state of the pulse divider circuit or for identification additional contacts are necessary for marking points, since the control contacts are Do not allow multiple uses for these purposes. Furthermore, for the size of the Discharge pulse a limit can be set so that the relay after tripping thereby cannot be re-excited.

Furthermore, a pulse divider circuit is known which is used for control a single changeover contact is used, its changeover spring with the series connection the winding of a bistable polarized relay and a capacitor, its an occupancy is connected to the earth potential. Depending on the contact position of the changeover contact is the aforementioned series connection to form a charging circuit for the capacitor alternating with the positive pole of a first source constant Potential or with the negative pole of a second source also constant Connected potential. The discharge circuit of the capacitor runs over the Simple pulse contact controlling the clocking process, whereby the relay is activated with each discharge passes into one or the other state. It can be stated as disadvantageous that that the minimal expenditure on contacts only through an increased expenditure on others Circuit elements as they are, for. B. represent the required two potential sources, is achieved.

The object of the present invention is, in a pulse divider circuit of the type mentioned above without an additional increase in the number of control contacts of the relay to further reduce the effort.

This is achieved in that the fixed series i circuit in the first diagonal of a bridge circuit and the other diagonal to a direct voltage potential, z. B. Office battery, is connected in series with the control contact and that the related of the first diagonal there is one bridge half in one branch with a normally open contact and in the other branch contains a break contact of the relay and that in each branch the other half of the bridge with respect to this diagonal has a resistance.

This circuit arrangement marked in this way only needs a single potential source to switch the relay into one or the other depending on the current direction in the other stable position. The polarity reversal of the voltage on the capacitor is dependent on the actuation of the control contact by the relay's own Contacts of one half of the bridge are controlled automatically. Because the one needed for this purpose Normally open and normally closed contacts of the relay, which advantageously switch load-free, If a switching point is common, they can be converted into a single changeover contact sum up. It is therefore the result of the known arrangement described no increase in the number of contacts when using a single potential source.

From the fact that there is no assignment of the one in series with the relay Capacitor is constantly connected to a fixed potential, but this series connection, which forms a diagonal of a bridge, there is advantageously the possibility of the pair of resistors of one half of the bridge for further tasks at the same time to use. For example, at least one resistor can be connected to one of the divider circuit to be controlled consumers are replaced. Such a consumer can, for. B. be the solenoid of a meter. For example, the one controlling the clocking process Contact is a contact that is actuated depending on the incoming counting pulses is, a counter arranged in this way only counts every second counting pulse that arrives to register.

In a further embodiment of the invention, in one half of the bridge lying consumers one for the discharge current polarized in the forward direction, Current direction-dependent switching element, e.g. B. a rectifier connected in parallel. This makes the capacitor discharge circuit independent of the pulse contact runs, switched so low-resistance that the discharge in a pulsed manner in front of it goes.

In the drawing, an embodiment of the invention is shown, the operation of which is to be explained below: In this exemplary embodiment is a resistance of the pair of resistors in one half of the bridge through the solenoid Z of a counter replaced. The winding of the bistable relay is designated with U, with the capacitor C in series with it, the first diagonal of the bridge circuit forms.

In the idle state of the circuit, i. H. with open control contact i the capacitor C is discharged. It is assumed that the control contact coincides is actuated with the incoming control pulses. If the impulse contact goes into the working position, so a charging circuit for the capacitor is via the rest position of the contact 1 u C closed, the positive pole of the voltage source connected to earth, the resistor R, the series circuit, consisting of the relay U and the capacitor C, via the Contact 1 u and the control contact i runs to the negative pole of the voltage source. The charging current is directed so that the relay U is thereby assumed does not change, so that the relay's own contact 1 u is also in its original position assumed situation remains.

By closing the pulse contact, at the same time, in addition to the charging circuit, another circuit is established via the magnetic coil Z, so that the counter is actuated. After the end of the pulse, ie when the control contact i is open, the capacitor C is discharged via one half of the bridge in a direction opposite to the charging current. The diode D 2 is stressed in the forward direction. Since the resistance value in the discharge circuit is low as a result, an approximately pulse-shaped discharge takes place. The discharge current surge is directed so that the relay U changes its state and thus assumes the second stable position. It opens its contact 1 u and at the same time closes its contact 2 u. The contacts switch without any load. If the pulse contact goes into its working position again, the capacitor in the circuit earth, magnet coil Z, the series circuit consisting of the capacitor C and the relay U, the contact 2 u and the control contact i is charged again in a current direction that is the same as the previous discharge , so that thereby a polarity reversal of the voltage on the capacitor is effected. At the same time there is a current flow from earth, the resistor R and via the working position of the contacts 2 u and i to the negative pole of the voltage source. This means that the second pulse emitted by the pulse contact i does not affect the counter Z. The charging current for the capacitor C, which cannot switch the counter effectively, is directed so that the relay U maintains the state it assumed during the previous discharge, the contact 2 u therefore does not change its position. After the end of the pulse, the pulse contact i is opened again, so that the discharge current impulse is directed in the opposite direction to the discharge impulse occurring during the first impulse pause. As a result, the relay U changes its state and again assumes the other stable position considered as the starting position and closes its contact 1 u again. The diode D 1, which is stressed in the forward direction, forms a path parallel to the magnetic coil Z for the discharge current surge, so that the counter is not actuated. With each further actuation of the pulse contact i, the switching processes take place in an analogous manner. The relay U always returns to its original state after the pulse contact @ has been actuated twice in succession. This halves the number of pulses supplied. In the same way, the counting magnet is only activated with every second pulse.

Such a circuit arrangement according to the invention can accordingly be shown in can be used advantageously in those cases in which, due to a greater distance between the individual reading times, there is a risk that the zero position a call counter is overflowed within this set reading period. With this arrangement, a call counter if required without any difficulty can be assigned, so the counting volume doubles. This particular use case does not require any further auxiliary voltage sources and is easily integrated into the existing one Loop in wiring of the billing meter. When evaluating the fee calculation the meter reading must then be multiplied by a factor of 2.

Claims (4)

Claims: 1. Pulse divider circuit for telecommunications, in particular Telephone systems consisting of a bistable relay, the winding of which with a Capacitor is firmly in series, this series connection through a contact of the relay is alternately switched so effectively that each working position the simple pulse contact controlling the clocking process reverses the polarity of the Causes voltage across the capacitor, characterized in that the fixed series connection is in the first diagonal of a bridge circuit and the other diagonal is on a DC potential, e.g. B. Office battery, in series with the control contact (i) is connected and that the bridge half that is present with respect to the first diagonal a normally open contact (2u) in one branch and a normally closed contact in the other branch (1 u) of the relay (U) and that in each branch of the relative to this diagonal each other half of the bridge is a resistor. 2. Pulse divider circuit according to claim 1, characterized in that the normally open contact and the normally closed contact become a changeover contact of the relay are summarized. 3. Pulse divider circuit according to claim 1 and 2, characterized in that the resistors of one half of the bridge each have a for the discharge current of the capacitor (C) polarized, current direction-dependent Switching element, e.g. B. a rectifier is connected in parallel. 4. Pulse divider circuit according to claim 1, characterized in that a resistor of one bridge half is replaced by a consumer (Z) to be controlled by the divider circuit.