DE419723C - Circuit arrangement for counting connections of different values in telephone systems - Google Patents

Description

Circuit arrangement for counting connections of different values in telephone systems. Patented in the German Empire on September 1, 1923.

According to the Union Treaty of June 2, 1911, priority is due to this application
of the application in the United States of America dated September 11, 1922.

The present invention relates to a circuit of one of the calling subscriber line Circuit arrangement for telephone systems, associated electrolytic counter through in which connections of different values are used connection devices or The purpose of this is to produce switchgear associated with the lines special, the crediting of one of the values depending on the value of the manufactured connectors each established connection ent- ι dung via a higher or lower speaking fee is closed in particularly simple resistance. The by and expediently to enable circuit higher or lower re-achievements This is due to the fact that the current levels have different strengths of the

The current flowing through the meter causes the electrolytic meter to degrade in a shorter or longer period of time, so that in the case of high-quality connections, depending on the high fee to be paid for them, the meter is broken down in a shorter time than in the case of low-value connections with lower charges , whereby a high ίο resistor is switched on in the counting circuit.

The advantages achieved by the arrangement according to the invention are particular from the avoidance of impulse transmitters! 5 as well as time switches that in the known facilities for the purpose of crediting the individual connections the fees to be paid have an effect on the metering circuit. Furthermore, when applying the invention during the The duration of a conversation does not have any period of time that is not counted.

The counter which can be used in the exemplary embodiment described below consists, for example, of an electrolytic cell with two silver electrodes, a cathode and an anode. These electrodes are in a silver nitrate solution, with an increase in the weight of the cathode during any period in precise proportion to the current and time. A current of 0.1 amperes deposits 0.4025 g of silver in one hour, and accordingly 4.83 g of silver in 12 hours, while a current of 0.2 amperes deposits 9.76 g of silver on the cathode in 12 hours will. The anode and cathode can be changed after each reading of the meter. In order to offset a certain time fee for a connection of a certain value, it is therefore only necessary to switch on a certain resistor in the counting circuit.

In Figs. 1 and 2 only part of the process for making a connection is shown between two participants required connection devices shown, the is necessary to understand the invention.

It is assumed that the subscriber station A wants to establish a connection with a subscriber in a switching center that can be reached via the connecting line 200/201. After picking up the receiver at subscriber station A , a circuit for line relay 14 of preselector C is closed via line wires 11 and 12. The relay 14 closes a circuit at its contact 20 via the switch relay 13 and the drive magnet 21 lying in series with it. If the preselector C is on an occupied line, then the test contact 36 is earthed, as a result of which the through-switch relay 13 is short-circuited. The drive magnet 21 responds, moves the switching arms of the preselector to the next contact and interrupts its own excitation circuit by opening the normally closed contact. The switching arms of the preselector are indexed step by step until the test arm 32 comes to a free outgoing line, which is characterized in that there is no earth potential at the contact 36. In this case, the through-switch relay 13 responds, separates the speech wires 11 and 12 from the line relay 14 and from earth by opening the normally closed contacts 15 and 18 and switches the speech wires 11 and 12 via the normally open contacts 15 and 18, the switching arms 30 and 33, the Contacts 34 and 37, the wires 38 and 40 and the normally closed contacts 60 and 63 to the surge receiving relay 50 of the first group selector D through. As a result of the high resistance of the through-switch relay 13, the drive magnet 21 cannot be excited by the current flowing through the through-switch relay 13.

The surge receiving relay 50 responds via the subscriber loop and closes a circuit for the delay release relay 51, which prepares the circuit for the solenoid 56 in the known manner and closes the following holding circuit for the preselector C at its contact 64: earth, normally open contact 64, wire 39, Test contact 36, test arm 32, normally open contact 17, through switch relay 13, drive magnet 21, battery, earth. The line relay 14 of the preselector is equipped with delayed armature dropout and consequently opens its contact 20 only after the above-mentioned circuit has been closed.

The calling subscriber now operates his current impulse transmitter according to the first digit of the desired subscriber number, whereby interruptions in the circuit of the relay 50 are caused. Each time the relay 50 drops, the lifting magnet 56 and the control relay 52, which is in series with it and equipped with a delayed armature drop, receives a current surge. The switching arms 69 to 72 of the group selector D are moved, for example, by the series of current impulses that have come into effect

the contact group with contacts 73 to 76 is lifted. The - control relay 52 remains energized during the series of impulses. After closing the head contact 58 at the first S lifting step of the selector, a circuit for the step relay 53 is established: earth, battery, Relay 53, self-breaker contact of the rotary magnet 54, head contact 58, normally open contact of relay 52, normally open contact 64,

ic earth. The relay 53 switches over his upper working contact into a holding circuit and prepares at its lower working contact a circuit for the rotary magnet 54 before. After the

! 5 Impulse series for setting the stroke of the Group selector drops the control relay 52 and closes the circuit for the rotary magnet 54, which the switching arms of the group selector in connection with the brings the first contact set of the selected contact group. At the same time the interrupts Rotary solenoid the holding circuit for the step relay 53, which drops out and the Circuit for the rotary magnet 54 opens. If the first line that can be reached is busy, test contact 74 is earthed, so that the step relay 53 is energized in the following way: Grounded test contact 74, test arm 71, normally closed contact 61, head contact 58, self-break contact of the rotary magnet 54, step relay 53, battery, earth. The step relay responds, closes the circuit for the rotary magnet, which moves the switch arms to the next Contact set moved on. When a free line is found, since no earth is applied to test contact 74, the Step relay 53 does not respond, this speaks against it when crossing busy lines short-circuited through switch relay 55 in the following way: earth, contact 64, Wire 39, through-switch relay 55, head contact 58, self-breaker contact of the rotary magnet 54, step relay 53, battery, earth.

As a result of the high resistance of the through switch relay 55, the step relay 53 does not receive enough current to respond. The relay 55 switches off the wires 38 and 40 from the surge receiving relay 50 and connects them via the normally open contacts 60 and 63, the switching arms 70 and 72, the contacts 73 and 75, the wires 78 and 80, the normally closed contacts of the current reversing relay 100 to the windings of the line relay 101 in the transformer R. The line relay 101 responds through the current through the subscriber loop and closes a circuit for the relay 102 equipped with delayed armature drop at its working contact no. The relay 102 closes a circuit at its contact 113 via the lower winding of the polarized relay 104 and for the delay relay 105. The relay 104 does not yet respond in this circuit. The delay relay 105 responds. At contact 102, a circuit is prepared for the delay relays 103 and 125 and for the lifting magnet 124, which will be described later. At contact 114, the following holding circuit is closed to group selector D and preselector C : Earth, normally closed contact 143, normally open contacts 123 and 114, wire yy, test contact 74, test arm 7, normally open contact 61, wire 39. From here, the holding circuit runs in the manner already described to preselector C. Said circuit is used to keep the relays 55 and 13 energized for the duration of the connection. Furthermore, the relay 102 closes a bridge between the wires 200 and 201 of the connecting line in the following way: wire 200, normally open contact 115, normally closed contact 116, upper winding of relay 104, right winding of choke coil 107, normally open contact 133, wire 201. By closing these Bridge, a circuit for the line relay is closed in the second group selector, not shown, of the remote exchange. This line relay responds and, in cooperation with the delay release relay assigned to it, prepares the setting of the second group selector. The relay 104 cannot yet respond through the circuit just described, since the current flowing through the upper winding is opposite to that flowing through the lower winding. The calling subscriber now operates his impulse transmitter according to the next digit of the desired subscriber number, whereby the circuit of the relay χ 01 in the transformer R is interrupted intermittently. With each drop, the relay 101 opens the bridge between the wires 200 and 201 of the connecting line at the contact 133 and thereby causes interruptions in the circuit of the line relay of the second group selector. The second group selector is lifted and after the end of the series of current impulses it searches in a known manner for a free continuing line. Each time the relay 101 drops out at the transformer R , the following current impulse also comes into effect: earth, normally closed contact 110, normally open contact 112, point 140, from here via control relay 103 to battery and earth and also via break contact 122, head break contact 137/139, delay relay 125, lifting magnet 124, battery, earth, relays 103 and 125 and magnet 124

respond with the first power surge. The relays 103 and 125 are equipped with delayed armature dropout and remain energized during the entire series of current impulses. When it is triggered, the relay 103 closes a new bridge between the wires 200 and 201 via its normally open contact 116, which bridge does not contain the upper winding of the relay 104 and the right winding of the choke coil 107. This bridge between the wires 200 and 201 runs as follows: wire 200, normally open contacts 115, 116 and 133, wire 201. By switching off the winding of the relay 104 and the choke coil 107, a better current impulse transmission to the downstream selectors is achieved. The relay 125 prepares a new circuit of its own when it responds, which is closed in the known manner via the contact springs 137 and 138 of the head contact after the first stroke step of the switching mechanism 6 ". The switching arm 130 of the switching mechanism S for example, in front of the row of contacts 136. After the end of the series of impulses, the relay 125 drops out, switches off the lifting magnet 124 and instead switches on the rotary magnet 127. The calling subscriber now operates his impulse transmitter in accordance with the third digit of the desired subscriber number, with the relay 101 switching current impulses to the rotary magnet 127 and the delay relay 126 of the switching mechanism 6 ″ lying in series with this. The switching arm 130 is thereby set to a contact which is connected to earth via a resistor. After the end of the series of impulses, the delay relay 126 drops out and closes a circuit which runs across one of the grounded resistors 140, 144 or 141, depending on which contact the switching arm 130 of the switching mechanism J? was discontinued. Assuming the switching arm 130 is set to the contact 136, then the circuit runs as follows: earth, resistor 144, contact 136, switching arm 130, normally closed contact 134, normally closed contact of relay 106, winding of relay 106, battery, earth.

The relay 106 responds, opens the circuit for the rotary magnet 127 at its contact 122 and switches over his Make contact 120 in a holding circuit. It also connects at contact 121 the switching arm 130 with the counting core 79.

The calling subscriber now presses- ',

more according to its impulse transmitter '

the remaining digits of the required part j

subscriber number, whereby the dialers required to complete the j connection are set. The requested line is called in a known manner. After the selected subscriber has reported, the call facility is switched off. The called subscriber receives his feed current in a known manner via a bridge relay on the line selector, which controls contacts that cause a current reversal in the speech wires arriving in the line selector, whereby the current direction of the wire 200 and 201 and the upper winding of the relay 104 on the transformer R flowing current is reversed. The relay 104, which was previously not energized, now responds and, at its contact 118, closes a circuit for the current reversing relay 100, which reverses the direction of the current flowing via the wires 80 and 78. Arrangements which are influenced by the current reversal caused by the relay 100 are not shown in the drawings for the sake of simplicity, since they are not necessary for an understanding of the present invention. The relay 100 switches the left winding of the choke coil 107 at its contact 109 in series with the right winding, whereby a better speech communication is achieved. By opening the contact 143, the short circuit of the resistor 145 is canceled and the circuit for the relay 105 is opened at the contact 142. As a result of the delayed armature drop-out of the relay 105, the resistor 145 is temporarily connected to the trip wire 77 . As a result, the short circuit of the relay 42 in the group selector D is canceled, which consisted in the fact that earth was applied via the normally open contact 62 of the relay 55 and via the normally closed contact 143 of the relay 100 in the transformer R at both ends of the lower winding. The relay 42 responds and switches on via its upper winding and the contact 43 in a holding circuit which runs via the trip wire 39. By closing contact 41, the counting circuit is closed as follows: Earth, resistor 144, contact 136, switching arm 130, normally closed contact 134, normally open contact 121, wire 79, contact 76, switching arm 69, normally open contact 41, contact 35, switching arm 31, normally open contact 16, Counter M, electrolytic counter X ₁ battery, earth.

The connection is now established and the participants can speak.

When the above-described counting circuit is closed, the counter M counts the conversation that has come about, while the counter X has an electrochemical effect throughout the duration of the conversation

whose size is determined by the strength of the current flowing in the counting circuit is. The current strength is now dependent on the switched on via the switching arm 130 Resistance.

Only 2 rows of contacts of the switching mechanism S are shown. It goes without saying that when connection selectors with 10 rows of contacts are used, the switching mechanism 6 ″ is also equipped with 10 rows of contacts. FIG. 2 also shows that the same resistor 138 is applied to all contacts of a row of contacts Switching mechanism can, however, also have a different resistance applied to each contact, so that with 100 connection points that can be reached over a decade of the first group selector D, 100 different fees can be charged.

After the conversation has ended, both participants hang up their handset. When the handset is attached to subscriber A , all connection devices are released. The triggering is initiated by the relay 101 in the transformer R. The relay 101 opens the bridge between the wires 200 and 201 when it drops, whereby the voters in the remote exchange are triggered in a known manner.

The delay relay 102 also drops out and opens the holding circuit leading to the group selector D and preselector C via the wire Jj. The relays 55 and 13 drop out, and said selectors are triggered in the known manner. The relay 102 also closes the circuit for the release magnet 128 of the switching mechanism S at its normally closed contact 112, causing it to be triggered. All connection devices are now in the rest position.

The above is the arrangement according to the invention on a network with a large number described by exchanges.

It can of course also be used if the telephone network consists of only 10 or fewer exchanges. In such a case, the use of the switching mechanism S and the relay 106 is not necessary. A resistor will then be applied to contacts 76 in the first group selector, which corresponds to the fee that is to be paid for the respective connection. For example, if group selector D has ten rows of contacts, 10 different resistances can be used. It is then possible to establish connections to 10 different exchanges, the valence of which is different from one another.

Claims (5)

Patent Claims: 1. Circuit arrangement for counting connections of different values in telephone systems, characterized in that the circuit of an electrolytic counter (X) assigned to the calling subscriber line is through switching devices assigned to the connection devices or lines used (e.g. switchgear 5 ", Fig. 2) depending on the value the connection established is closed via higher or lower resistors (138, 144, 140 or 141). 2. Circuit arrangement according to claim ι for telephone systems with dialer operation, characterized in that the switching device for the selection of the in the circuit of the electrolytic 'counter (X) to be switched resistors is controlled by number current surges from the calling station (A). 3. Circuit arrangement according to claim i, characterized in that the resistors to be switched on in the circuit of the electrolytic counter (X) are connected directly to contacts (76) of a connection selector (e.g. group selector D) . 4. Circuit arrangement according to claim 2, characterized in that an auxiliary switching means (relay 106) after the effect of the current impulse series characterizing the required switching center (e.g. the third) and by switching off the setting device (contact 127) from the current impulse transmission device ( Contact 110) prevents the switching device (S) from being influenced by the further series of current impulses to be transmitted by the calling station to complete the connection. 5. Circuit arrangement according to claim 4, characterized in that the auxiliary switching means (106) is excited via the switching device (S) closing the counting circuit and switches itself into a holding circuit for the duration of the connection (at contact 120). 1 sheet of drawings.