DE1038124B - Circuit arrangement for storing charge units as a function of time and zone, in telecommunication systems, in particular self-dialing systems - Google Patents

Description

GERMAN

The invention relates to a circuit arrangement for storing charge units as a function of time and zone, in telecommunication systems, in particular automatic dialing systems.

Arrangements of this type are already known. In Fig. 1, such a known arrangement, which is also referred to as a time zone counter ZZZ, is shown. The task of a time zone counter is to record the zone defined by a certain code number and, depending on this, to save the conversation time. At the end of the connection, the tariff set resulting from the zone and time is then transmitted in the form of pulses to the respective individual memory element, for example a meter. The zone of the called subscriber is determined by a follow-up drive dm. All identification numbers of locations belonging to the same zone are interconnected and: wired via a zone cable, for example Zone II, to the switching arm of the time switch assigned to the relevant zone, for example ds II. A switch arm ds is required for each zone. The number of contacts of the switching arm dz depends on the maximum permissible duration of the connection, for example 6 or 12 minutes. A tapper as to rotate after mounting of the calling subscriber in free choice to the collective point and then in the interaction with a relay, which gives the pulses over the wire in the zero position. The number of steps from the tariff point to the zero setting then corresponds to the number of charge units. The Ite selector is switched every 5 seconds. From Fig. 1 it can be seen that, for example, a compound of zone II, 4 minutes in length, cost five Ortsgebührenemheiten because the Wählerarm has to make because of the collective point 00:46 five steps.

A disadvantage of this known arrangement is the great expense of switching means and wiring. A special voter arm ds is required for each zone. In addition, for reasons of economy, the time must be limited, since otherwise the dimensions and the number of switching mechanisms would be too large. A shutdown of the respective connection after 6 or 12 minutes was therefore introduced.

According to the present invention, these disadvantages of the known arrangements are avoided by that in one consisting of storage and suction capacitors and a voltage-dependent element Storage device, the individual fee units are stored and after receiving a a certain number of individual fee units a larger fee unit is marked and that the larger fee units through certain charging circuitry for storage

of fee units depending on time and zone, in telecommunications,

especially automatic dialing systems

Applicant:
Josef Dirr, Munich 8, Zaubzerstr. 5

Josef Dirr, Munich,
has been named as the inventor

genes are marked in capacitors and that also the withdrawal of the fee units after the capacitor scoop principle takes place in such a way that the storage capacitors have the corresponding charge Number of charge units is taken. The evaluation and transfer of the fees can only be done in the form of individual fee units or in individual and larger fee units. The differentiation of the respective fee unit can be made by means of current levels, current directions, Alternating currents of different frequencies or pulses of different lengths can be made.

The invention and advantageous embodiments thereof are described in more detail in the following description explained in connection with the drawings. There are only those for understanding the invention required circuits are shown.

In the exemplary embodiment in FIG. 2, a time zone counter is shown in which arrangements based on the capacitor scoop principle are provided as counter elements. The identification number is stored by means of the voter arm dm. The zone assigned to the respective code is defined by appropriate wiring. All outputs of the same zone are combined and led to the output of the selector Ds assigned to the respective zone. After storing the code, the selector Ds is started. This runs freely until a DC circuit is established via the zone wiring, the M relay responds and the DS selector stops. The counting pulse sequences of the various zones are connected to a further armü ^ H of the dialer. When the called subscriber reports, a relay G , not shown, responds to its 16 ^ contact, relay Zr to the one set by the DS selector

809 600/129

3 4

Pulse sequence follows. Zr relay now speaks in the cycle again interrupted. The pulse length of the respective pulse train. The storage of the is determined by the capacitor C5 . After the fee units, of which one is marked when the Zr relay is connected to the number of connections of the discharge capacitor C3, the arrangement according to the capacitor discharge principle is used with the respective storage capacitors C4t to Cn , which correspond to the charge units from the storage capacitor C 2, is at the respective scoop capacitor Cl, the glow lamp GHl and storage capacitor such a voltage that the relay T exists. Every time the glow lamp GH2 is triggered, it ignites. 5 relay in the glow lamp Zr relay is connected to the 2sr contact. With a contact of the same device of the scoop capacitor Cl to the storage cone, the switching of the selector relay WR to capacitor C2 is carried out. After each drop of the next storage capacitor in the Zr relay, not shown, the scoop capacitor Cl is initiated via the ter way. In this way, the rest side of the 2zr contact always takes the same evaluation of the stored large charge input / output voltage. The storage capacitor is also called one.

has a certain output voltage (100 V), which he can receive via the 15 ^ -Con- tuell still stored charge units. The 15p contact is opened before or after the evaluation of the condensate talk of the G relay. The respective charge units stored on the capacitors C 4 to Cn are stored in the storage capacitor after each charge prevailing. For this purpose, the contacts k voltage is a measure of the number of stored 20 of the relay K , not shown, and pulses or charge units. The storage con- a comparison circuit, consisting of the condenser, is connected to one pole of the glow lamp, capacitors Cl and the scoop capacitor C 3 and while the other pole of the glow lamp is connected to a relay N. With 11k , the comparison circuit is constant voltage (-160V) switched on via the 4czr- , 12 & had the storage capacitor C7 contact of the Zr relay is placed. This contact has brought 25 to a certain output potential, with the purpose of controlling the glow lamp only in FIG. The size ratio evaluation circuit is provided, switched on, and with nis of the storage and scoop capacitor is so loaded & the evaluation circuit GH2, ß-relay is measured that, for example, after ze'hn charges are switched on. The evaluation of the individual charge units unit pulses at the glow lamp, the ignition voltage 30, now takes place according to a comparison principle. The off-line. The glow lamp then ignites, the relay T output voltages of the storage capacitors C2 and in the glow lamp circuit comes on. With the Cl , therefore, have a difference from the size of the T relays, ie the larger charge units of the ignition voltage of the glow lamp used. marked. The storage of these large fees, storage and scooping capacitors of both circuits units can be in a selector or selector relay 35 have the same size. If, for example, five connections were made with the or, as shown in the exemplary embodiment, with the 2 ^ r contact, the glow lamp ignites with the help of a selector relay WR and a marker if the 5i contact of a capacitor Ci to Cn also has five connections due to a voltage have taken place. A predetermined size can be made. The selector relay WR whose contact (not shown) is the / relay is switched by one step with a contact of the T relay at each contact 40 then the charge units speak to the registration device of the relay. Further. iV relay in the glow lamp circuit responds via contact 7 s of a relay 5 ", not shown, at which and terminates the forwarding of further charge input evaluation, the consistency impulse is received. Now all the stored impulses are capacitor C 4 at a certain voltage. sent to the registration device, the time zone capacitors C 4 to Cn are dimensioned so that at * 5 counter can be occupied again,
the discharge through the scoop capacitor C3 the- Since in the case of high fees the passing on of the individual number of pulses or the number of fee units, fee pulses result in a very long withdrawal of the time states that were marked in these. zone counter and the over-

When the calling subscriber is hung up, that is, would mean carrying traffic, for example at the end of the call, the individual capacitors, which are expediently 50, impulses in the case of high charges, are discharged. This can be done with the same valency to the registration device for the selector relay WR with which the marking was carried out, for example pulses for a charge in the capacitors C 4 to Cn . that is, ten fee units etc. As a criterion for this, the length of the position can then be taken in the same way as with the single-valued pulses, but in the reverse order in the 55 pulses. The evaluation of the starting position switched back; the same can be done for example in the first group selector, front arm WR from capacitor to capacitor selector or in the subscriber circuit,
switches. In Fig. 3, a memory for storing ground return is used. fee units are shown. 3f contact is

At the beginning of the evaluation is not 60, a contact of the T-relay switches of the individual charges An Inge recorded ^ "-. Relay with its 7i-contact integrated memory of Figure 2. Cl of Schöpfkondendie is to Auswerteeinrichtuing This consists of the sator and C 3 of the storage capacitor.. The evaluation scoop capacitor C 3, to which the charge units of the large charge units is carried out according to a forwarding pulse contact 5 i, the glow lamp comparison principle, as it was already with the explanation GH2, the relay B and the pulse contact 6 i 2. The task of the comparator is to advance the selector arrangement consisting of the scoop capacitor C2, relay WR only after the charging capacitor C 4 has been sent, the pulse contact 4 / pulse 2s. the relay L / is Glimmlampenerzeugende relay as a self-interrupters geschal- circuit is at the neon lamp ignited Austet. With its 8i contact, the pick-up current is turned on. With the 2i contact, the storage

cherkondensator brought to a predetermined output potential. This contact opens at the beginning of the evaluation. With another contact, not shown, of the / relay, the stored large charge unit pulses are passed on. These are identified by longer pulses than with the individual fee units. When using the same pulse relay for the transfer of the individual and larger fee units, this is achieved in that the capacitor determining the pulse time (in Fig. 2 C 5) is increased by connecting a further capacitor C 6 in parallel.

The different marking when using different pulse values for the transmission of the Charge units can also be made by means of current levels, current directions, alternating currents or alternating currents different frequency.

Claims (4)

Claims 1. Circuit arrangement for storing fee units as a function of time and zone in telecommunications, in particular automatic dialing systems, characterized in that the individual fee units are stored in a storage device consisting of storage and scoop capacitors and a voltage-dependent member (Cl, C 2, GUl) and after receiving a certain number of individual fee units, a larger fee unit is marked and that the larger fee units are identified by certain charges in capacitors fC4 to Cn in Fig. 2, C 3 in Fig. 3) and that furthermore the removal of the fee units according to the capacitor scoop principle takes place in such a way that the storage capacitors (C 2, C 4 to Cn, Cl, C 3) are taken from the number of charge units corresponding to their charge. 2. Circuit arrangement according to claim 1, characterized in that for differentiation the different values of the fee units are marked by current levels, Direction of currents, alternating currents of different frequencies or impulses of different lengths he follows. 3. Circuit arrangement according to claim 1, characterized in that the evaluation in Individual charge units based on the condenser scoop principle by connecting a scoop capacitor to a storage capacitor with a contact of the charge units in the form of pulses marking relay (Fig. 2, /) takes place and that the size ratio of Schöpfzu Storage capacitor is dimensioned so that according to the number of parallel circuits that correspond to the number of corresponds to the individual charges stored in the respective storage capacitor, the control voltage is available on the storage capacitor to end the evaluation. 4. Circuit arrangement according to claims 1 and 2, characterized in that for connecting the storage capacitors for the large Fee units switching mechanisms with forward and reverse are provided. Considered publications:
British Patent No. 567,863;
Telecommunications magazine, 1952, issue 8;
Electrotechnical Journal, Issue A, 1952,
Issue 15. 1 sheet of drawings © 809 600/129 8.58