DE1209334B - Arrangement for switching a counter element through pulses sent by several encoders - Google Patents

Description

Arrangement for advancing a counter by several encoders transmitted pulses The invention relates to an arrangement for switching of a counter by coming from several encoders one after the other or at the same time electrical impulses, with a counter input for each encoder.

Arrangements for summing up different are known Inputs of incoming electrical impulses. There are storage means for each input an incoming pulse is provided. These stores are managed by a central Setup queried cyclically. Every stored pulse leads to this interrogation process to a count for a totalizer.

Circuit arrangements are also used in telecommunications and telephone systems used for so-called call folders, by the single or several at the same time incoming impulses stored by means of bistable polarized relays and in a whole specific order, whereby by a counter-excitation of the other, so far not energized relay is prevented from occurring during the forwarding additional relays go into the working state.

The aim of the invention is an arrangement with several counter inputs, in which the pulses arriving at the various counter inputs are timed apart from one another can arrive independently, i.e. also with mutual overlap, and directly successively stored on a totalizer.

According to the invention, this is achieved in that two counting inputs are used storing the pulses to be counted and also the pulses for the totalizer Generating relays are provided to achieve a defined pulse-pause ratio the counting impulses for the totalizing counter with the automatic and by a mutual electrical interlinking of the relay pairs of all counter inputs one after the other subsequent withdrawal are delayed.

Advantageously, additional central control and Avoided interrogation devices, and the effort is kept extremely low. A Another advantage is the clarity of the arrangement according to the invention in structure and mode of operation, which is achieved by training as a relay chain. These The chain works advantageously only when counting pulses arrive. In the Withdrawal of incoming pulses, empty memories are skipped. This works is particularly beneficial for the counting performance of the arrangement. For an additional Increasing the counting performance can also be expanded by a turn only overflow counting circuit made up of a pair of relays. This will then effective if on a counter input before a previous one is saved Impulse a new counting impulse arrives.

Further details emerge from those shown in the drawing Embodiments. It shows F i g. 1 the circuit diagram of a first embodiment, F i g. 2 shows a second exemplary embodiment modified in comparison.

In Fig. 1 the individual pulse generators are indicated by the contacts 11 ... in . The various counter inputs of the arrangement are labeled El ... En. The operating voltage U is switched on with the switch S. If, for example, a pulse arrives at the input E2 due to the closing of the contact 12, the relay 2A responds through the charging current surge for the capacitor C2 via the rest side of the contact 2b2 . This closes contacts 2a 1 and 2a2. The capacitor C2A ,. which was previously charged via the quiescent side of contact 2a1, now discharges via resistor Wi2A and the winding of relay 2A, so that it only drops out after a certain delay time. Relay 2B is excited via contact 2a4 : At the same time, capacitor C2B is charged via resistor Wi2B. After relay 2A has dropped out, relay 2B also drops out again, delayed by the discharge of capacitor C2B. During the period in which the relay 2A has already dropped out and the relay 2B is still energized, a pulse is sent to the totalizer SZ via the contacts 2b3 and 2a3. The individual counter EZ2 is incremented by the contact 2b4. During the working state of the relay 2B, the pulse input is separated from the winding of the relay 2A by the changeover contact 2b2 and connected to voltage. When relay 2A drops out, the input line is switched back to relay 2A. However, since the capacitor C2 has meanwhile fully charged, the relay 2A can no longer respond, even if the input pulse is still ongoing. The resistor Wi2 is dimensioned so that the relay 2A has a fault current. When the input pulse ends, capacitor C2 discharges through resistor W12.

If impulses arrive at several inputs at the same time, the following processes are triggered: It should be assumed that a pulse arrives at the three inputs El, E2 and En at the same time. Relays 1A, 2A and nA pick up, as already described for input E2, as do secondary relays 1B, 2B and nB. The relay 2A is held by the actuated switch contact nbl via the switchover contact 3b1, which is in rest, and the actuated normally open contact 2a2. The relay 1A is held by the actuated changeover contact 2 b 1 via the actuated normally open contact 1 a2. Only relay nA can drop out after contact nb2 has disconnected the pulse line from relay nA. The relays hA and hB drop out one after the other, as already described for input E2. This advances the totalizer SZ by one step via the contacts hb3 and na3. After relay nB has dropped out, the holding circuit for relay 2A is separated by contact nbl. As already described, relay 2A can now also drop out with a delay. This delay time forms the pulse pause for the totalizer SZ. During the delayed release of relay 2B, the second counting pulse is sent to totalizer SZ via contacts 2b3 and 2a3. After the relay 2B has dropped out, the holding circuit for the relay 1 A is now also separated by the contact 2 b 1. The relay 1A can now also drop out with a delay, the delay time again being equal to the pulse pause of the stored pulses. During the release time of relay 1 B, the third pulse is sent to the totalizer SZ via contacts 1b3 and 1a3. The pulse lengths for withdrawal are determined by the release times of the B relays. With this withdrawal, the corresponding individual counter is incremented by the corresponding b4 contact. After the third pulse has been stored, the arrangement is again in the rest position.

Even if a pulse arrives at two inputs in quick succession, the switching processes described below ensure exact summation. It should be assumed that an impulse arrives first at input El and shortly thereafter at input E2. There are two ways of doing this. The pulse on input E2 comes at such a point in time that relays 2A and 2B have responded before relay 1A has dropped out. In this case, relay 1A is held through contacts 2b1 and 1a2. The relay 2A can therefore drop out immediately and initiate the impulse. This is done as described above. The other possibility is that the relay 2B only picks up when the relay 1A has just dropped out, that is, a pulse is sent out. In this case the relay 2A must not drop out, otherwise a pulse would be lost. The relay 2A is held against ground via the rectifier Gr2 and the contacts 2a3, 1a3 and 1b3. This means that the relay 2A is connected in parallel to the totalizer SZ and is held while the pulse is being given. At the end of the pulse sent out for the input El via the contacts 1b3 and 1a3, the holding circuit via the rectifier Gr2 for the relay 2A is also disconnected. The relay 2A can now drop out and initiate the impulse for input E2. After the two pulses have been transmitted, the arrangement is again in the rest position.

F i g. 2 shows a comparison with FIG. 1 modified embodiment of the invention. The arrangement corresponds essentially to FIG. 1, so that a description of the individual functions is not necessary. The following are the differences compared to FIG. 1 explained. A pulse counter Z1, Z2 ... is assigned to each input. These counters are incremented by the incoming pulses. The discharge resistors Wil, W12 ... for the capacitors Cl, C2 ... are shown in FIG. 2 switched against voltage. Decoupling rectifiers EGrl, EGr2 ... are provided to prevent capacitor discharge via the counters Z1, Z2 ...

The interconnected the input capacitors Cl, C2 ... downstream b2-change-over contacts with their work sites and led to the pulse input EU of the overflow circuit. This overflow circuit in turn consists of a relay pair ÜA and ÜB and corresponds in structure and mode of operation to the other relay pairs. Only the switchover contact is not required and can be used for signaling by the lamp L Ü and the alarm clock WÜ in the event of an overflow. This overflow circuit serves to increase the counting capacity of the arrangement. It becomes effective if a new counting pulse arrives at a counting input before a previous pulse is saved. This counting pulse is fed to the EU input via the b2 changeover contact of the corresponding relay pair, which is in the working position. The pulse counters Z1 ... count all incoming pulses of their counter input, including those that go into overflow. On the other hand, the counters EZ only display the impulses stored by the corresponding relay pair themselves. This makes it easy to identify overloaded counting inputs and, for example, remedy the situation by regrouping an overloaded counting input at the end of the relay chain, since the possible counting performance of the inputs increases after the end of the relay chain.

As shown in FIGS. 1 and 2 can be seen, the arrangement expand to any number of counter inputs.

Claims (9)

Claims: 1. Arrangement for controlling a counting element by means of electrical pulses coming from several transmitters one after the other or simultaneously, one counting input being provided for each transmitter, characterized in that two counting inputs (E) store the pulses to be counted and also the pulses for the totalizing element (counter SZ ) generating relays (A, B) are provided which, in order to achieve a defined pulse-pause ratio of the counting pulses for the totalizing counter (SZ), are delayed during the automatic withdrawal, which is carried out one after the other through mutual electrical interlinking of the relay pairs of all counting inputs. 2. Arrangement according to claim 1, characterized characterized in that the relays each have a winding, two changeover contacts and two working contacts are fitted, with one of the relays (1 B) only having one changeover contact and two working contacts are required. 3. Arrangement according to claim 1 or 2, characterized characterized in that each relay is one of a series circuit of a resistor and a capacity existing delay element to achieve a defined Fall time is assigned. 4. Arrangement according to claim 1 or one of the following Claims, characterized in that in each pulse input a differentiating element, preferably a capacitor connected in parallel with a discharge resistor, looped in is, the discharge resistance is so high that the receiving relay over it can not respond. 5. Arrangement according to claim 1 or the following claims, characterized in that to prevent repeated counting of a long Pulse at a counter input a relay contact (b2) for complete charging of the differentiating capacitor is provided for each input, so that a new counting pulse only after a pause that is equal to the discharge time of the differentiating capacitor, takes effect. 6. Arrangement according to claim 1 or one of the following claims, characterized characterized in that for the relay pair assigned to a counter input via a actuated relay contact (b 1) of the second relay (B) of a subsequent pulse input Associated relay pair there is a holding circuit, so that in the event of a simultaneous storage of pulses to be counted for several inputs one through Pulse withdrawal for the individual pulse inputs occurs when the relay drops out takes place one after the other. 7. Arrangement according to claim 1 or one of the following claims, characterized in that to ensure correct summation also with unfavorable mutual overlapping of the incoming on the different counter inputs Impulse holding circuits via a rectifier (Gr) and a normally open contact (a3) of the first relay of a relay pair per counter input are formed, such that during a pulse withdrawal by the stored pulse a simultaneous withdrawal of stored data in the other relay pairs Impulses is suppressed. B. Arrangement according to claim 1 or one of the following Claims, characterized in that for one that takes place in addition to the total counting Counting of the incoming impulses per counter input, one normally open contact (b4) of the second Relay of the relay pairs for controlling one counter (EZ) each is provided. 9. Arrangement according to claim 1 or the following claims, characterized in that to increase the frequency limit for the incoming pulses overflow counter arrangements (CA, ÜB), which are the same as the other relay pairs, always an overflow counter arrangement for several inputs together, provided and on the input side each to the The working side of the switchover contacts (b2) of the second relay of the relay pairs connected downstream of the differentiating elements are switched on and with the holding circuits are preferably incorporated in the last position in the relay chain (FIG. 2). Considered publications: German Auslegeschriften Nos. 1044 886, 1133 436.