DE401007C - Circuit arrangement for rendering faulty current surges in current surge storage devices undamaged - Google Patents

Description

The present invention relates to a circuit arrangement for surge storage, as they betrieb in telephones with selector, z. B. also as a converter, numerator, etc., to be needed.

The purpose of the invention is to avoid any fault current surges that occur e.g. B. when setting the Current surge storage occurs due to careless operation of the adjustment devices, so to intercept that a correct setting of the registers is guaranteed.

According to the invention this is achieved in that the first receiving current surge storage and switching devices are assigned to the control device of the register, which when fault current surges occur be brought into effect in such a way that the shutdown of the first and the connection of the second surge storage is prevented and from the to be absorbed In the first series of current impulses, as many current impulses are rendered ineffective as fault current impulses are included.

The drawing shows a

game of the invention in the simplest schematic representation omitting all not strictly necessary parts.

The subscriber station 100 has a number switch ιοί and is by means of a double line to a preselection switch mechanism, of which, for the sake of simplicity, only the switch arms 102 and 103 and the fixed contacts 104 and 105

Designated are connected. A connection line is connected to the fixed contacts 104 and 105, which leads to a group or line selector leads, of which only the switching arms 134. and 135 are drawn ". Preselection switches and group or line selectors are well known and therefore not further described. In the lower part of the drawing is a surge storage device shown omitting everything known. With 140, 160 and 180 there are three stepping mechanisms referred to as the surge storage device for receiving the individual series of surge currents to serve. With 141, 142, 143, 144, 161, 162, 163 and 181, 182, 183 are the switch arms and with 145, 164, 184 the individual drive magnets of the stepping mechanism called. The indexing mechanism labeled 120 serves as, control switch to the individual register switchgear 140, 160 and 180 one after the other to be switched on to receive the individual series of impulses, and has four contact arms 121, 122, 123, 124 with corresponding Contact rows and a drive magnet 125.

Assume that subscriber 100 wishes to connect with another subscriber of the self-connection exchange, he takes his handset off the hook, whereby the preselection switch works in a known manner with its switching arms 102 and 103 on the contacts 104 and 105 of a free, to one

Group selector sets the leading connection line. By occupying the group selector, a control switch ι io comes to response, which switches off the connecting line by flipping its contacts 106 and 107 and switches on the impulse relay 108, which causes this to respond in the circuit running through the calling subscriber station. The surge relay 108 closes a circuit for the delay release relay 109 at its normally open contact, and this switches on the relay 111 at its normally open contact. On the right working contact, relay 111 closes a circuit for relay 116: earth, battery, relay 116, contact 136 and switching arm 12t (of the switching mechanism I2o \ right working contact of relay 111, earth. Relay 116 is energized and opens The calling subscriber now uses his dial and sends i the first series of impulses, which corresponds to the first digit of the subscriber number to be called j. As a result, the relay 108 in the loop circuit is intermittently de-energized and transmits the sent jumps to its break contact to the first I current surge memory 140: earth, normally closed contact! of relay 108, left working contact of relay 111, line 117, switching arm 123 and contact 129 of switching mechanism 120 serving as a control switch | switching mechanism 120, normally closed contact of relay! 113, working magnet 145 of first current impulse j Memory 140, line 119, delay trip relay 12, battery, ground. The surge memory is set according to the first series of current pulses sent. The first series of current impulses must always be greater than 1, which will be shown later.
After the first series of impulses has been received, the delay release relay 112 is de-energized and the following circuit is thereby closed: earth, right normally closed contact of the delay release relay 112, relay 114, switching arm 183 and contact 185 of the third surge memory 180, switching arm; 163 and contact 165 of the second Pulse \ memory 160, switch arm 144 and over the single 'made contact of the first Stromstoßspei- j chersi4Q, normally-closed contact of the working magnet 145, magnet 145 of the first work Pulse; Memory, line 119, delay trip relay ■ 112, battery, ground. The relay 114, which has a high-resistance winding, is excited in this circuit, while the low-resistance relay 112 and the working magnet 145 are not excited. Relay 114 closes a circuit on its working contact for the working magnet 125 of the control switch mechanism 120: earth, working contact of the relay ^; 114, contact 126 and switching arm 122, normally closed contact of relay 112, normally closed contact of working magnet 125, working magnet 125 of switching mechanism 120, battery, earth. The working magnet 125 attracts its armature, thereby interrupting the working circuit on it and moving the switching arms 121 to 124 onto the first contacts. By moving the switching arms on the first contacts, the circuit of the working magnet 125 is interrupted at the contact 126, whereby the switching arms remain in this position. At the same time, the circuit for the relay 116 has been opened on the switching arm 121 and contact 136, so that this is also de-energized.

The calling subscriber now operates his number switch again and sends thus the second series of impulses, corresponding to the second digit of the desired subscriber number. The rush relay 108 is de-energized again correspondingly intermittently and transmits the current surges to the following circuit: earth, normally closed contact of relay 108, left working contact of relay 111, line 117, switching arm 123 and contact 130 of the Switching mechanism "120, working magnet 164 of the second Impulse memory 160, line 119, delay trip relay 112, battery, earth. The working magnet 164 is corresponding to the sent rush current series the switching arms 161 to 163 of the second rush current storage 160 a. The delay release relay 112 in this circuit also speaks on and remains energized for the duration of the surge series. After the impulse series is received, the relay 112 is de-energized again and thereby closes the following Circuit: Earth, right break contact of relay 112, relay 114, switch arm 183 and Contact 185 of the third surge memory 180, switching arm 163 and via the set Contact of the second surge storage device 160, normally closed contact of the working magnet 164, Working magnet 164, line 119, relay 112, Battery, earth. The high resistance relay 114 is energized, while the relay 112 and the Working magnet 164 remain in the rest position. Since the relay 112 cannot respond, comes the following circuit for the working magnet 125 of the control switchgear 120 established: earth, battery, working magnet 125, normally closed contact of working magnet 125, left Normally closed contact of relay 112, switching arm 122 and contact 127 of control switchgear 120, Line 190, via the set contact and switching arm 162 of the second impulse storage device, Earth. The control switchgear goes to its second position and remains in this position, because the circuit for the working magnet 125 on the switching arm 122 and contact 127 of the control switchgear is interrupted. Of the

calling subscriber sends the third one by pressing his dial and in our example the last series of impulses. The impulse relay transmits the sent Current surges on the following circuit: earth, left normally closed contact of relay 108, left Normally open contact of relay 11 r, line 117, Switching arm 123 and contact 131 of the control switchgear 120, working magnet 184 of the third register 180, line 119, relay 112, Battery, earth. The working magnet 184 sets according to the number of current impulses sent Switching arms 181 to 183 on the corresponding Contacts on and relay 112 is energized. After the surge current consumption has taken place, the relay 112 is de-energized and thereby the following circuit is closed: earth, battery, working magnet 125 of the control switchgear, normally closed contact of the working magnet 125, normally closed contact of the relay 112, switch arm 122 and contact 128 des Control switchgear 120, set contact and switching arm 182 of the third surge memory 180, earth. The working magnet 125 of the control switching mechanism 120 moves the switching arms 121 to 124 on the third contacts, whereby the circuit for the working magnet 125 is interrupted on the switching arm 122. That Relay 112 is de-energized and closes the following circuit on its right normally closed contact : Earth, normally closed contact of relay 112, relay 114, switch arm 183 and set contact of the third surge memory 180, normally closed contact of the working magnet 184, working magnet 184, line 119, relay 112, battery, Earth. -

In this circuit only the high-resistance relay 114 is energized, the relay 112 and the working magnet 184 are low-resistance and therefore cannot respond.

Depending on the scope of the office, the control switchgear »in the Way, the individual surge accumulators are switched on and save the corresponding ones Series of impulses.

The individual numeric relays, which are used to identify the individual series of current impulses, are connected to the contacts overflowing from the switching arms 141, 142, 143 of the three current impulse stores. These and the other parts of the storage device are, since such devices are known, not shown for the sake of simplicity. After all series of current impulses have been recorded, the contact 118 is closed by a device in some known way, whereby the following circuit is created: earth, battery, relay Γ12, line 119, working magnet 184, normally closed contact of working magnet 184, contact switching arm touched by switching arm 183 183, \ contact 118, earth. The working magnet 184 receives current and causes the switching arms 181 to 183 to be moved on until they have reached their rest position. The current surge series corresponding to the setting of the surge storage device is emitted in a known manner via the switching arm 181 and the associated set of contacts. As soon as the switching arm 183 of the surge storage device 180 arrives in its rest position, i.e. hits contact 185, the circuit for the working magnet 184 is interrupted and the circuit for the working magnet 164 of the surge storage device 160 is closed: earth, battery, relay 112, line 119, working magnet 164 , Normally closed contact of the working magnet 164, contacts and switching arm 163, contact 185 and switching arm 183, contact 118, earth. The working magnet 164 receives current and sets the switching arms 161, 162, 163 in motion, which continue to run into their rest position and when they run out emit a number of current impulses corresponding to the series of current impulses received via the peeling arm 161 and the associated contacts. If the switching arms 161, 162, 163 arrive in the rest position, the switching arm 163 is on contact 165, whereby the working magnet 164 is switched off and the working magnet 145 of the surge storage device 140 is switched on via this last-mentioned contact: relay 112, line 119, working magnet 145 , Normally closed contact of the working magnet 145, contacts and switching arm 144, contact 165 and switching arm 163, contact 185 and switching arm 183, contact 118, earth. The working magnet 145 moves the switching arms 141, 142, 143, 144 into the rest position, delivering the set series of impulses via switching arm 141. The impulse storage devices are in the rest position, and the following circuit is therefore closed: earth, battery, working magnet 125, normally closed contact of the Working magnet 125, line 191, contact and switch arm 124, contact 147 and switch arm 144, contact 165 and switch arm 163, contact 185 and switch arm 183, contact 118 ,. Earth. The working magnet 125 moves the switching arms 121, 122, 123 and 124 of the control switchgear into the rest position.

The above is the mode of operation of the storage device described provided that the number switch is correct; was served. The following is a description of the operation of the arrangement are given if before the first series of impulses is delivered by means of the number switch Coincidentally, an undesired current surge (e.g. bounce current surge when taking off) of the handset from the hook) comes into effect. The rush relay 108 is influenced by such a rush current and transmits

a power surge through the switch arm. 123 and contact 129 of the control switchgear, normally closed contact of relay 113, working magnet 145, line 119, relay 112, battery, earth. The working magnet moves the switching arms 141 to 144 to the first contact. Relay 112 is de-energized in the space following the surge transmission. A circuit is now closed: earth, right break contact of relay 112, switching arm 142 and contact 146 of surge memory 120, left winding of relay 113, battery, earth. The relay 113 is energized in this circuit. The previously described circuit for energizing relay 114 from the end of the series of impulses now runs from: earth, right normally closed contact of relay 112, relay 114, switching arm 183 and contact 185, switching arm 163 and contact 165, switching arm 144 and contact 148, normally closed contact of relay 116 Here, however, the circuit for the relay 114 is interrupted, since the relay 116, as already described, is energized. Therefore, the control switching mechanism 120 cannot be switched further now. If the calling party now served its number switch 101 and \ characterized sends the first current pulse series, the relay is affected accordingly 108th The following circuit is closed by the relay 108 through the first current impulse of the sent series j: earth, normally closed contact of relay 108, left normally open contact of relay 111, line 117, switching arm 123 and contact 129, normally open contact of relay 113, right winding of relay 113, Line 119, relay 112, battery, ground. Relay 112 is energized and opens the circuit for the left winding of relay 113 at its right normally closed contact. Relay 113 remains energized during the first current surge of the series via its right winding and right normally open contact and drops out after this, while the delay relay trained relay 112 keeps its contacts closed and cannot drop out during the current impulse. When the relay 113 is de-energized, the working magnet 145 of the first surge storage device 140 is switched on immediately at its break contact. The now following current impulses of the first series bring the working magnet 145 into effect, and this sets the first current impulse storage device accordingly. The disconnection of the first surge storage device and the successive connection of the further surge storage devices take place in the manner already described.

In the case of the arrangement described in the present exemplary embodiment, it is assumed that that only a fault current surge can be made harmless, and that is what the first contact is for of the first surge storage switchgear; intended. Should the arrangement for the In order to render several fault current surges harmless, the 6g first surge storage to provide the corresponding contacts for it.

Claims (4)

Patent Claims: i. Circuit arrangement for rendering faulty current surges harmless in Impulse accumulators for setting selectors in automatic or semi-automatic Telephone systems, characterized in that the first receiving current surge memory (140) and its Control device (120) switching devices (113,116,148) are assigned which when fault current surges occur, they are brought into effect in such a way that the first one is switched off and the first one is switched on of the second surge storage device is prevented and so many current surges from the first series of surge currents to be recorded can be made ineffective when faulty impulses have been absorbed. 2. Circuit arrangement according to Claimi, characterized in that there are contacts (146) of the first surge storage device (140) connected switching devices (Rego relay 113) when the hit by the Fault current surges on the switching arms set on these contacts (142J the current surge line switch off from the working magnet of the first store and only after so many current surges have been rendered ineffective of the series of current impulses to be recorded, are recorded as fault current surges, connect the current surge line to the drive magnet again. 3. Circuit arrangement according to claim 2, characterized in that under the · Influence of the switching device (120) controlling the surge storage device (Relay 116) in connection with the first memory the incremental circuit of the control switchgear. 4. Circuit arrangement according to claim 2, characterized in that the number the one at the first surge storage device (140) for the connection of switching devices (113), the "ineffective serve the fault current surges, to be provided contacts (146) the number of ineffective corresponds to the current surges to be made. 1 sheet of drawings.