DE1253768B - Circuit arrangement for preventing double assignments of a connection device - Google Patents

Description

Circuit arrangement for preventing double assignments of a connection device The invention relates to a circuit arrangement for preventing double assignments a device accessible via several input relays. Such facilities are particularly needed in telephony, for example if a Multiple occupancy of a crossbar assigned to a large number of participants or the like should be prevented.

In known circuit arrangements of this type, test relays with two windings each are used, each test relay responding via one winding when an input relay is occupied and is then held via the second winding and applies blocking potential to the test wire of the other input relays. Circuit arrangements of this type are complex and costly in view of the requirement for test relays with two windings.

Furthermore, circuit arrangements of the type specified in the introduction are known, in which each input relay is in a test circuit that is a chain of Contains normally closed contacts, whereby the input relay that responds first is the Break contact chains of the other relays. The series connection of a large one The number of normally closed contacts is, however, susceptible to failure, because if a single one fails The entire chain becomes inoperable.

In another known circuit arrangement, the one discussed here Art, each test circuit contains a relay with a glow lamp in series, whereby the input relay that responds first causes an assigned glow lamp to ignite, whereby the potential relationships in the circuit arrangement are so influenced, that prevents the ignition of another glow lamp in another test circuit will. Such switching systems require, if the simultaneous ignition of two Glow lamps should certainly be avoided, a high cost of additional Contacts and can only be used when high operating voltages are present.

Finally, there is already a circuit arrangement for avoidance of double assignments known, in which as well as in the one explained below Invention in the individual occupancy contacts containing circuits of the response or Holding windings of all input relays non-linear resistors, e.g. B. Diodes, as well a series connection of a current source and one common to all input relays Series resistance. In this known circuit there is a double assignment excluded by the fact that the respectively occupied relay apart from one a holding circuit closing contact still closes a second contact, with which it connects the series resistor grounded on the relay side, thus preventing all other relays from being used. The mentioned non-linear resistors or diodes only have a decoupling function.

In contrast to this, in the case of the invention, this results in a double occupancy prevents suitably arranged non-linear elements, e.g. B. Diodes, All excitation circuits, with the exception of the one to be assigned, are given a high resistance so that only the selected circuit has a sufficient response current can lead. In the case of the simultaneous marking of two circuits, in particular only those excited and occupied whose excitation circuit has the lowest number of non-linear ones Contains switching elements or that non-linear switching element, which due to its Characteristic has the lowest resistance.

This operation is achieved according to the invention in a circuit arrangement of the last treated general ax in that a relay different to relay number one another lies in the individual relay circuits in substantially the same non-linear resistors or per a nonlinear resistor with relay-to-relay essentially different non-linear characteristic .

In this way, compared to the known circuit arrangement described last, the saving of a second working contact per relay is achieved and in particular the complication required in the known circuit arrangement, which consists in that the working contacts required for each relay must be designed as follow-up contacts, is avoided.

If in the circuit arrangement according to the invention only a single assignment occurs, the corresponding input relay is assigned without the others Relays are affected somehow. In the case of double or multiple occupancy speaks, as will be explained later, only that relay is on or only that remains Relay energized in a self-sustaining manner, in whose circuit the lowest resistance is effective is, due to the non-linearity of the effective resistances and the applied Coupling of the relay circuits is achieved that the remaining relays only fault current received that is either insufficient to respond or below the retention value so that these relays, if they should have responded, immediately again fall off.

In the circuit according to the invention, a winding wire can each Relays one after the other via a non-linear switching element with the corresponding Winding wire of the next relay and the winding wire of the last relay directly or via a non-linear switching element with the series connection of the power source and series resistor must be connected. Merbei can with each other except for the usual Non-linear switching elements with the same tolerances are used.

In order to work safely even with a large number of input relays To vouch for the circuit arrangement, several circuit arrangements of the described Art can be cascaded in groups.

The invention shall now be based on exemplary embodiments with reference to the drawings will be explained in more detail.

F i g. 1 serves to explain the method of operation of the invention with reference to the in FIG. 2 shown working characteristic of a switching element with non-linear resistance; F i g. 3 shows an exemplary embodiment of the invention in which double or multiple assignments are prevented in holding circuits of the input relays; F i g. 4 finally shows a cascade arrangement of circuit arrangements according to the invention. To explain the basic mode of operation of the invention, FIG . 1 shows two relays R 1, R 2, which are in parallel branches between the two poles + U and - U of a power source. In series with this relay each current branch contains a by a key Tl and T2 respectively indicated occupancy contact, and in the common part of the current path is a series resistor R V in the one current branch is also switched on a circuit Elementd non-linear resistance in series with the relay R 1, which can be, for example, a normal diode, a Zener diode, a VDR resistor, etc., that is to say can have a parabolic characteristic curve or a pronounced kink characteristic curve. In Fig. 2 shows the current-voltage diagram IDIUD of such a switching element in the form of a kink characteristic.

If only one of the keys T1 or T2 is pressed, the associated relay R1 or R2 responds without any influence being exerted on the circuit of the respective other relay. If the key T1 is pressed, the operating point of the diode is at A 1 in FIG. 2, d. H. above the curve kink K. If both buttons TI, T2 are pressed at the same time, both relays receive current, and an increased voltage drop occurs at the series resistor RV , so that the voltage on the series circuit of the winding corresponding to the voltage drop at the winding of the relay R 2 of relay R 1 and diode D is reduced and the operating point of diode D is shifted towards A 2 below the curve kink K. The relay R 1 therefore receives fault current and drops out if it has already picked up.

In the circuit arrangement according to the invention according to FIG. 3 it is assumed that several participants TN 1, TN 2, TN n have access to a crossbar switch via input relays R 1, R 2 ... Rn. Resistors Wl, W2 ... Wn and the response windings I1 of the relays are located in the subscriber loops. The input sides of all response windingslI are connected to one another via decoupling diodes D 1 to D n , and their connection point is connected to the negative pole of the power source via a parallel circuit of normally open contacts rlI, r21 ... rnl of the relays. Each of the relay R 1 to R n further comprising a holding winding I, whose circuit r a closing contact to rn H of the associated relay and a break contact t 1 to tn contains 1. 11 The closure time of the contacts r 1 to rn 11 II is less than the closing time of the contacts r 1 1 to rnI.

The circuit arrangement according to the invention is implemented in these holding circuits, the KontakterlII to rnll, which are in series with the holding windings I of the relays R 1 to R n , act as occupancy contacts and connected with their left side via a series resistor RV to one pole of the power source are. The holding winding wire of the relay R 1 is connected via a diode D 1 to the holding winding wire of the relay R2, the holding winding wire of the relay R 2 via a diode D 2 with the holding winding wire of the relay R 3 (not shown), etc., while the holding winding wire of the last relay R n is connected to the second pole of the power source via a diode D n, which may also be omitted. If an assignment is only made by a single participant, the assigned relay R responds via its response winding 11 and first closes its contact rII in the holding circuit, which runs via its holding winding I and corresponding diodes D, the power source and the resistor RV. Then the contact rI of the relevant relay R1 closes, whereby the response windings II of all relays R 1 to Rn are short-circuited. This has no consequences for the relay R under consideration, because it is held by its holding winding I that has already been excited. In contrast, a later occupancy on the part of other participants is prevented as a result of the short circuit of the response windings 11 of the other relays. After the end of the occupancy, the corresponding isolating contact t is actuated by an isolating relay (not shown), so that the relay R which is assigned in each case drops out and the initial state is reached again.

With simultaneous occupancy by several participants, z. B. the participants TN 1 and TN n speak to the assigned relays R 1, R n first and close their holding circuits via the contacts r1I1 and rnll.

In the holding circuit of the relay R 1 there are several diodes D 1 to D n in series, whereas there is only one diode D n or none at all in the holding circuit of the relay R n. On the basis of the FIG. 1 and 2 explained working principle of the invention with the result that the current through the holding winding of the relay R 1 drops sharply and becomes a fault current, so that the relay R 1 drops out and only the relay R n holds. In general, if the relays R 1 to R n are assigned multiple times in the holding windings 1 of all these relays, with the exception of the one connected to the power source via the smallest number of diodes, fault current will occur, so that only a single relay can hold and thus double occupancy is prevented.

With a large number of input relay R1 to Rn of the entire non-linear resistance in the holding circuit of the RelaisR1, in the circuit arrangement of Figure 3 through the combined effect of the diodes D 1 to D n already be so large that for occupancy of the RelaisR1 the required value of the Holding current no longer comes about. In such cases it is advisable to use the circuit according to the invention in cascade, as shown in FIG. 4 is shown schematically. Here, K groups Grl to Grk of, for example , n subscribers TN 1 to TN n each are analogous to FIG. 3 switched.

The individual switching elements of these groups are in the same way as in FIG. 3 and provided with an additional, preceding group index 1, 2 ... k . Each of the input relays has a third closing contact r1111 to rnIII, these closing contacts being connected in parallel in each group and being in the circuit of a group relay 1G, 2G ... kG. These group relays are for their part analogous to the response windings11 of the input relays R 1 to R n in FIG. 3 interconnected and have holding windings in which make contacts 1 g II to kg II and isolating contacts d 1 to dk are located. The holding circuits of these group relays are analogous to the holding circuits of the input relays R 1 to R n in FIG. 3 interconnected via diodes D. Finally, a starting relay ANL is provided, in whose current path there are parallel-connected work contacts gIll, 2gIII ... kgIII of the group relays and which has a make contact an1 which is in a marking circuit.

Duplicate assignments originating from participants in one and the same group are identified in the manner already explained by the FIG. 3 corresponding circuit arrangement within each group is deleted. For example, if participants TN1 and TNn of group Gr 1 are simultaneously occupied, only relay 1 R n can respond, and group relay 1 G is energized via closing contact lrnlll, which energizes starting relay ANL by closing contact 1 g III . Double assignments by different groups belonging to participants, e.g. B. the participant TN 1 in the group Grl and the participant TNn in the group Grk, lead to the fact that the corresponding group relays 1 G and k G are energized, the selection of that group relay that is to remain energized in an analogous manner in the Holding circuits of these group relays takes place. In the example shown, the group relay k G remains energized and in turn energizes the starting relay by closing its contact kgIll, whereas the group relay 1 G drops out again. The simultaneous excitation of the relay k R n and the group relay k G causes a clear assignment by the subscriber TNn of the group Grk to the exclusion of all other subscribers.

The circuit arrangement according to FIG. 3 can be modified in such a way that the wires of all holding windings 1 of the relays R 1 to R n are led to a common connection point with the power source and between this connection point and the holding windings a different number of switching elements of the same type with non-linear resistors or one switching element each is inserted with a non-linear resistance characteristic different from all the others.

Claims (3)

Claims: 1. Circuit arrangement to prevent double assignments of a device accessible via several input relays, in particular for telephone systems, in the case of the response or holding windings of all input relays containing non-linear resistors, z. As diodes, as well as an all input relay common series connection of a current source and a series resistor are located, characterized in that a relay different to the relay number of mutually substantially identical non-linear resistors or per a nonlinear resistor with relay-to-relay essentially different in the individual relay circuits non-linear characteristic. 2. Circuit arrangement according to claim 1, characterized in that a winding wire of each relay in turn via a non-linear switching element (D) with the corresponding winding wire of the next relay and the winding wire of the last relay (R n) directly or via a non-linear switching element (D n) is connected to the series circuit of the power source and series resistor. 3. Circuit arrangement for preventing double occupancy of a device accessible via a large number of input relays, characterized in that a plurality of circuit arrangements according to claim 1 or 2 are connected in groups in cascade. Publications considered: German Auslegeschriften No. 1151028, 1 149 751, 1 144 776, 1 120 512, 1030 884.