PL7697B1 - Phone network. - Google Patents

Description

The present invention relates to telephone equipment, and more particularly to self-operating telephone equipment, intended to service small provincial exchanges which may possibly be left unmanned. However, some features of the invention can also be applied to other types of telephone equipment. The invention consists essentially of a device which releases the local telephone apparatus automatically when it is turned off for any reason. If, for example, the subscriber picks up the handset of his telephone, but does not turn the dial, then after a certain period of time the relevant cord circuit is released. In a similar way, if the calling party fails to hang his handset on the hook after the call is terminated, if the calling party has hung up his handset in place, the connected handsets are automatically released after a certain period of time. when a connecting line is connected to a line to another off-site private switchboard, the apparatuses connected to the connecting line are released after some time has been called out. The above device also includes the case where a developing state is produced on the line, caused by a connection error, and then the apparatus connected to said error line is released. This device is of great importance in the case of unmanned air handling units of the type mentioned. In automatic control units with a relatively large number of apparatuses and having a service, it is good to arrange a trigger line on which a permanent short-circuit is created, so that it is tied to the connecting beam, thanks to which, after hearing the appropriate alartml, you can Immediately detect the erroneous lines. However, in the case of an unmanned station, this would incapacitate a relatively large number of apparatuses, which, however, is completely prevented by the above-mentioned device. The invention still consists in a device that switches off each line, which is not in a strict order. If, for example, a certain line is in a state of continuous triggering caused by an error or any other cause, then the line is disconnected after some time. Similarly, in the event that the above condition is formed on the tie line, the incapacitating apparatus starts to operate to switch off the line in question. The above incapacitation is done by a special device. Thus, if a local junction circuit has been tied for a certain period of time, then circuit changes occur which cause the special incapacitation relay to search for the erroneous line. This line is marked with a specific potential, led by a string to a terminal located on the strip of the associated finder relay. The connecting line and the subscriber's line are provided with an additional relay which, when released by the incapacitating relay, locks on the loop on the line, making it at the same time busy. The removal of a loop or an error releases the said closing relay, bringing the line into an active state. It should also be noted that one and the same incapacitating apparatus is used for connecting lines and subscriber lines. The invention also includes a device *. * Fi that disconnects the lines connecting at both ends. Thus, if a permanent short circuit occurs on the connecting line, then the operation of the device at the input end disables the lines at that end and releases the device parts associated with it, and at the same time a signal is transmitted to the distant end of the line to disconnect the output end of the line. Simultaneously, the calling line release device associated with the connecting line at the downstream end is operative. The invention still includes an 11-rule which has caused the subscriber to generate a persistent call state on the associated line, then then, after incapacitating the connecting line, it returns to its active state, simultaneously with the automatic release of the subscriber's line, in the manner described above. The individual activities are carried out in such a way that the above-mentioned actions are achieved with regard to the connecting line. A permanent short circuit on the connecting line incapacitates these lines at the inlet end and at the same time releases the associated string. Said signal, transmitted simultaneously with the above connecting line, immediately releases the calling line bonded with the connecting line at the exit end and simultaneously produces at the end of the output line connecting the permanent call state. After the joining line has been brought to its most active state, the incapacitation device located at the entry end is released and the call produced at the exit end is lifted, with the result that the joining line is brought into an active state once more. . At the same time, the subscriber line on which the short circuit of the connecting string was formed is connected in the usual way to the local string circuit. Until the short circuit is removed within a specified time, the said cord locks the lines in the manner mentioned above. If, however, the error is on the joining line, then calling, - 2-wire at the end of the entrance, causes the local cord to associate with the joining line. Until the error is corrected, the connecting line is incapacitated also at the exit end of the incapacitating apparatus used in the previous cases. single and multiple. The connections of line relays, inertia relays and signal relays, placed in a loop formed on the line at the exit end, are described below. The invention also includes a device for transmitting a signal to the central control center when necessary, in such a way and that the signal in question is effective, whether it is received by the manual or automatic station, and at the same time clearly indicates the source of the failure, that is, the provincial automatic transmitting the signal. Local calls to the central office or vice versa may, however, be interrupted, if all the control panel lines are busy, so that a supervisory signal can be transmitted to the station. A device for generating the time interval between feeds and connection periods is simultaneously used to transmit signals to the central exchange. A relay used for this purpose and shown in Fig. 2, to measure the time interval after which it takes place. is incapacitated, and at the same time serves to transmit the signal to the main station, if necessary. The above relay is also used simultaneously to interrupt the call taking place between the local and the main switch, in order to transmit the signal to the central switch if necessary. Some of the features of the invention described below are not covered by the present provisions. as they are the subject of related patent No. 6688. All other features of the invention will emerge from the following description with reference to the accompanying drawings which show one embodiment of the invention. In these figures, Fig. 1 shows connecting local circuit for an automatic provincial installation; Fig. 2 shows the circuits: developing, damaging and monitoring, used in the said installation; Fig. 3 shows the circuit of the line connecting two provincial automatic switchboards of the type shown in the remaining figures; Fig. 4 shows the disabling relay and the combination circuits used in the provincial automatic switchboard having no connecting line; Fig. 5 — disabling relay used in an installation provided with line convenience devices; Fig. 6 shows a small change of the local connecting circuit used in connection with the lines belonging to the branched private station, since this circuit replaces the line circuit shown in Fig. 1 with respect to all lines of said branch private exchange except for the line o - more stable, thanks to which, if necessary, a search is carried out in the group belonging to the discovered private station; FIG. 7 shows another linear interconnecting circuit provided with multiple counter devices, the circuit of which is described in the aforementioned Patent No. 6688, and is therefore given below. Fig. 2 should appear below Fig. 1 with the left side of Figs. 4 or 5, and Figs. 3, 6 and 7 should be considered separately. As regards Fig. 1, when the handset is on the substation is taken off the hook, the line relay Lr .., located on the trigger line SL, starts operating, energizing the relays Zr and Cr in the correct circuit. The "c" end, placed on the finder rails, is connected to - 3 - one winding of the breaking relay Cor. The Cr relay leads to one of its contacts a circuit used to set the stepping magnet SM in motion along the finder line, which This circuit runs to the battery through the pin D of the stage relay, the protective resistor, the breaking contact and the SM winding, the front contact of the Cr relay, the disconnecting plug BJ and the rear contact of the test relay Pr to the ground. The stepping magnet then starts to operate. , and the finder line searches * After reaching the trigger line, the circuit from ground is closed by: proper resistor, second contact of the Cr relay, winding of the Tr relay, contacts of the disconnecting plug BJ, contact E of the stepping relay, upper contact outside ¬, lower inner and rear relay Vr, brush "c", front contact breaker Lr and through relay winding Cor, shunted against resistance n non-inductive. When Tr wakes up, the SM slows down and the searchline stops. The Sr relay is excited in series with the SM, and the Tr, closing its forward con- tact, keeps itself excited independently of the contacts Cr. Cor excites and maintains the connection with the terminal "c" on its forward contact, the relay the linear power switch turns off, and Lr Zr and Cr are released one after the other, but only after Sr closes the circuit passing through the relay No. In the case of a double test, the operation of the one-test relay turns on the resistance of this relay parallel to the second relay winding, which then drops. The coils of the step relay Ir are connected via the two front contacts of the Sr relay and the brushes "a" and "b" to the trigger line. Ir forms a circuit for the left release winding of the relay with a delay which, when energized a direct connection between the Tr relay and the "c" toothbrush is created on its frontal contact. This circuit is independent of the ball Dm of the step relay open at position 2. On the forward contact of the relay Sr, the circuit is closed by the ball A, the breaking contact of the SSM step relay and both relay windings Br. Relay Br energizes and closes the SSM magnet circuit, The stepping relay travels one step, finds the same closed circuit in position 1 - ^ 2 and moves to position 2. Relay Ur with delay energized is now energized by a circuit extending from the ground through: the lower internal contact C of the step relay and the low-resistance winding belonging to the relay Tsr (Fig. 2) which activates the toner discs, while Ur makes the connection through its front contacts and two large resistors a toner disc with a cord. The receiver sends the first series of pulses and each time the relay Lr is released, the circuit through the ball B closes, the rear contact of the relay Ir, the resistance, the windings of the transmitters Fr and Ar. The above pulses set the sensitive relay Fr into action, and the delayed release relay Ar keeps Br energized. The relay Br does not release until a series of pulses have passed, and the step relay remains on its forward contact for a longer period of time. On one of its front contacts, Fr closes the excitation circuit for the stepping magnet Sml of the chooser, the circuit of which passes through the right rear contacts of the indicator Xr. On the left front contact of the relay Fr a circuit is closed, extending from the ground by: the rear contact of the relay Jr, interrupting contacts of step magnets, SM'2 and SMlt, front contact of Fr relay, secondary winding of Dr relay, windings of Fr and Ar relays, up to the battery, i.e. that Fr and Dr are energized - for the entire time the Smx magnet is energized and * o until the magnet opens - 7 'tfo of the breaking contact. Thus, while Ir remains on the back contact for a time sufficient to excite the sensitive relay Fr, advance one step takes place regardless of the time required by the step magnet to operate. , which decelerates with a delay, becomes more reliable because with each pulse it receives current for a certain minimum period of time independent of the state of the line. Moreover, the above device causes that the relay Dr is energized for a given period of time regardless of time, the time during which the Ir relay can keep its forward contact open, a very constant stepping circuit is obtained at the same time, which is peculiarly important in this type of device, since the Ar relay may not be of the lag type lagging, i.e. this relay may open its circuit after a relatively short time from the moment of the last impulse, thus gaining the time lag between The brush of the SM relay stops at the position corresponding to the first series of pulses, and when the Ar relay is released, Br opens the circuit for the SSM and the staging relay moves to position 2 - V2. The circuits formed in the 2 -% and 3 positions for excitation in the transmitters Vr, Xr and Kr or to transfer the trigger to the connecting line or to the control unit's output socket are the same as the circuits described in the related British patent No. 197 797. The line devices are described below. It should be noted that the UR relay, being in position 2 - V2, is energized, and after opening its circuit, it keeps the brushes es i / 3 in open for a time sufficient for the stepping relay to move out of position 3, so that in the event of a relay operation Kr will not be sent to the line where the relay has stopped. As a result of the joint excitation of the transmitters Xr, Vr and Kr, one of the magnets SML or SM2 is inserted into one of the so-called normal positions, from which, due to unit pulses, the transmitter moves to the set line. Due to the different arrangement of balls, it should be noted that in the event that the relay Br is to be held on the connecting line, or in the event of the release of "0" during position 3 of the step relay, its circuit runs: through the front contact of the relay Sr, the ball F and the contact rear relay Jr. In this position, the winding of relay Jr is connected by contacting C with the relay starting the connecting line or calling "0" r, therefore relay Jr is not put into operation. If the relay stops at position 2 for more than 30 seconds, the cord is then released automatically by the relay Er and the common device for timing the individual steps shown in Fig. 2. This device will be described in when describing this figure, so it is enough to mention that the relay circuit is closed by: contact B of the stage relay, upper internal and front contacts of relay No., back contact of relay Pr, windings and contacts the relay Er, which is closed to contact on the timing device, indicated in Fig. 2, in the normal position, or when set in motion at given intervals. The relay Er may therefore be activated only when said time-regulating device passes after the contact, and then this relay closes on its contact, which results in a preliminary break, and produces a ready-made circuit which, after a given period of time, can start run if relay Er is not released. This circuit determines the path to bring the full potential to the end "d", and at the same time the common device sets in motion an incapacitation relay that searches for the correct end "d". During this time interval, no jumper line or an "O" call can be formed, nor can the relays search for a "C" line. When this terminal is reached, the incapacitation relay activates its own relay. which: closes towards the line, cuts off the line relay and releases the cord circuit. In position 4 of the stepping relay, the circuit may already accept unit pulses which can be transmitted to the magnets SJIfi or SM2, placed in the circuit described and this will help After the unit pulses have passed and Ar is released, the stepping relay moves from position 4 to position LO. The line is now tested and a search can be made on the PBX or provincial headquarters in the same way as this described in the related earlier application No. 197797, because the circuit allows searching for line 4 - PBX in the group. It should also be noted that the relay Jr is provided with the necessary shunt winding. inductive so that the relay does not respond to the current ringing while the handset is hanging on the hook, and therefore the resistance placed in series with the Jr relay, operating to look for in the PBX or provincial headquarters, is different When the line is free and the relay Vr is released, then the relay Jr is energized in the circuit running through: relay back contact Vr, upper external and upper internal contact of the step relay N, relay winding Pr, because relay Br is in motion through the circuit running through: relay front contact Jr and upper internal contact A. The stepping relay then moves through the 10% position to trigger position 11, in which a circuit dedicated to the common relay Rsr runs through a special resistance. starting the development (Fig. 2) and passing through the ball G to the ground through the relay winding Pr and through the ball FG, the lower internal contact and the relay winding Jr, which is released during the operation of the relay initiating the call. The ringing current passes through the ringing relay Rr and the ball R to the substation called and then back through the ball G to the windings of the relays Pr, Jr and their inductive shunt windings. If the ring-initiating relay is connected to the ringing current through a capacitor, then the ringing current may pass through a suitable resistance even if the ringing current does not return along the line of the calling parties. Figure 6 shows the circuit. linear for all lines except for the last group of PBX, provincial switchboard. The additional relay Cor is added here only in special cases. Fig. 6 has nothing to do with the present invention and is provided here for the purpose of completing the description. the caller may be produced by the apparatus shown in Fig. 2. If desired, however, a small calling machine may be used, and the relay Jr and Er may be made to be connected to the circuit of said machines. does not exceed, for example, 500 Q, then the relay Rr can be omitted, because the relay Jr will be- - 6 - he will measure the ringing circuit. On longer lines Jr, nothing could work, but the Rr relay can provide operation on lines having a resistance of 1000 ft. The Rr relay can also be used when using the lines of the talking parties. When the called steep corresponds, the grading indicator moves from position 11 to position 15, and the relay Pr is energized at position 12 by looping of the evoked line. If counting of local calls is required, then the circuits marked with dotted lines are added. and the areas marked with a cross are removed. If we suppose that we have a counter device, then when the step relay goes to position 11-13, the circuit closes to excite the meter relay MR by batteries powered by ball D and the highest contacts of the relay No. The relay Mr then operates and produces on one of its forward contacts the connection of an additional metering battery to the terminal "c" and a connection on its contact which breaks the circuit preceding the circuit, in order to keep the relay Tr in working condition. The other end of the relay winding Tr connects at the next forward contact of the relay No. to ground, so that if the relay Tr deviates a little, releasing its front contact for a moment, then it does not break its circuit , but it wakes up again immediately. current in the relay circuit Tr, both during operation and during the release of the Mr. The active meter MS located on the subscriber's line operates in the circuit running from the battery through: terminal "c" and brush "c", front contact of relay No. and relay winding Or to an additional meter battery. Sensitive relay Or interrupts the circuits of relays starting on its contacts. Cr so that when another local call occurs during the counting, the linear finders stop and the test does not take place, so that nothing interferes with the operation of the counter, which, however, could be the case if the trial relay Tr was excited and the resistance was shorted by which it works. For both units of 70 lines (subscribers) there is one relay Or, which is also active during the operation of the meter under the influence of the connecting line via the TLC conductor or the switch line. After making a connection to the input end of the connecting line, i.e. the line between With two identical exchanges, the same circuit serves to move the limit relay on the binding line, instead of activating the counter by means of the said relay, the said relay produces a circuit calculating the time elapsed from the beginning of the conversation and required to start the counter at the output end. A description of this device will be given a little later. If, despite the called line connecting, local calls are not counted (written), then the numerator cannot be connected to the end "c", and thus it switches between the end "d" and the earth. The string counting circuit therefore serves only to send the calculation to the output end of the connecting line. It should also be noted that in this case a dual voltage counter battery is required to activate the counter connected to the ground. on the calling side, the Ir relay is released, and the Dr. relay is also released. The relay Tr then disconnects from the brush "c" and releases the short-circuiting relay Sr, which opens its closing circuit, triggers the -7-release of the relay No. The stepping relay moves to position 16, from which position when SM2 is set, this relay returns to its normal position.The staging relay then shifts to position 17, in which relay SM1 returns to its normal position, because the circuits returning these relays to their normal position are the same as described in the English cognate prior application No. 190797, the only difference being that the successive positions have been shifted to enable counting * If, after the caller has suspended the handset, the calling party does not break the call, then the Er may be excited by a common timing device to incapacitate the trigger line and release the line as previously indicated. It also appears in talk position 15 through the rear contact of the relay Pr and the front contact of the relay Er. It follows from the above that the relay Er may energize at the end of the call if the common timing relay closes its circuit in time, but it is essentially the property of the present device that said relay should not be maintained. in the excited state for more than 30 sec. If the command line is busy, then relay Vr remains excited at step relay position 10, relay Jr cannot operate, and the step relay cannot advance. At position 10 of the step relay, the circuit is closed by: the lower external contact B, and the appropriate resistance, in order to set the busy sign in motion. This circuit is arranged in such a way that the string relay Ur connects intermittently with the contact B and, when excited, sends a sign to the line. It should be noted, however, that if the seizure sign is to be of a frequency other than that of the toner disc, then a separate relay should be provided instead of a common resistance, which relay connects a separate circuit of the seizure sign with the line. ¬ chawke, thereby releasing the Ir and Dr relays, and thus the Tr, Sr and Nr relays, then the stepping relay moves from position 10 to position 16. The counter circuit described previously is opened by the relay No. . In order to facilitate the description, we assume that line 70 does not exist or is also turned off, so if the connection reaches this terminal, then a common circuit, not shown in the figure, starts working, sending a special signal (about 7 clicks per second). ) to the developing side as a mark. As for Figs. 2 and 4, they represent the common perimeters needed to produce the target and occupancy marks, and the bell circuit for the device shown in Fig. 1, where the line incapacitating device is shown, which has a permanent short circuit or a line that remains on after the handset is hung by the called side. The toner dial mark is produced here in the manner customary used in small exchanges. In order to produce an occupancy mark, there are relays that start the same circuit as is applied to the toner dial, but with such intervals that the operation of the oscillating relays is minimized. If, however, the sign occupied differs from the tone of the diode disc in terms of frequency, then this circuit should run differently, and each cord circuit should have an additional relay. For generating the ring current, a device is usually used because it is sufficient for such small installations. The alarm signal is sent to the remote central exchange via one of the cables of the local exchange. However, since the cable in question is used in both directions so that it can be engaged in the alarming process, there is a device that interrupts the connection established and produces a trigger condition through the cable to the switchboard, thereby giving separate signal. In this way it is easy to break an existing connection in a provincial installation, because the signal from the main office must wait until the connection is removed. The device for this purpose varies depending on whether the main exchange has a manually operated or self-operating switch. The circuit marked with broken lines works in the event of a connection to a switchboard and then the connection marked with the cross must be removed. For an existing connection to be disconnected first, the alarm circuit is arranged so that the wire fJb "of the cable opens and closes. at certain time intervals and simultaneously that the potential of the wire at "a" changes at the same time intervals except for the first pause. Thanks to the above device, in the event of an existing connection from a provincial installation, the connection is interrupted, and after the connection of the wire "a" with the ground, a call is made in the switchboard. If a register is used, the break in the wire "i" remains unaffected. , since the register step relay is kept active by the wire "a", so that a constant signal passes through the register of the switchboard. If an existing connection has left the switchboard, breaks in the wire "6" will begin after the calling party frees up, the call starts and a steady signal appears in the free register. If the control panel is of the manual type, the circuit changes so that it produces a constant ground through the wire "a" and a slow vibrating signal on the wire "&", which signal can be obstructed by the characteristic tone. sending a certain number of clicks to the fónje as indicated in the figure. Whenever the fuse blows, the alarm circuit closes, and this circuit closes also in the event that the ringer current source fails to perform its task. a group of delayed relays is envisaged so that when the bell circuit is closed, the relay permanently connected to the bell current source is de-energized and an alarm is sent to the switchboard. Delayed relays are used, so that the oscillating relays are only used when it is necessary to send a ringing current. To incapacitate a line that shows a permanent short circuit, special relays included in the the string circuit shown in Fig. 1. The common circuits include: a stepping meter relay, a special line finder called a permanent fault finder, or the incapacitation relay shown in Figs. 1, 4 or 5 and one relay per each When the local string circuit is connected to the line, or when the calling steep does not slow down, the string relay mentioned above is energized as soon as the common time-measuring relay is in one of its This relay then closes to the common commencement relay and the timing relay, and advances with the aid of the relay with the anchor oscillating gradually, one stroke every six seconds, then a position is reached in which common auxiliary relays are triggered if any of the above-mentioned relays in the string are energized in the course of no more than eg 30 seconds. Forgetting these common relays, the 9-circuits are triggered by triggering the relays for the called "O" or the connecting line so that only the finder of permanent faults can turn. An appropriate potential is generated at the appropriate end of a continuous line, so that after the line finder has reached this end, the seeker stops and sets the auxiliary relay in the local circuit into motion. This last relay then closes towards the line, as a result of which the local cord circuit becomes free and the common continuous search circuit becomes free. Below is a detailed description of the invention, referring to the ball of the step relay, I mean the stepping relay shown in Fig. 1, because there are no other step relays. The tone of the toner dial when the string stepping relay shown in Fig. 1 is in position 2, the relay Ur arises in series with the common relay Tsr at the beginning of the occupation sign and the dial tone of the given circuit. Tsr closes the dial tone circuits, which circuits are marked with thicker dotted rectangles in the upper right part of the drawing. After the local string shown in Fig. 1 reaches the position LO, the circuit running from the ground is completed by ball B (Fig. 1) and the appropriate resistance to the common relay Ar shown in the figure, which relay it has a non-inductive shunt resistance connected to the rear contact of said relay so that the latter acts with a delay. The above relay creates a local circuit for the relay Br. If the non-inductive shunt resistance is removed from the relay Ar, the latter is released with a delay. The relay Br also has a non-inductive shunt resistance on its rear contact and therefore acts with a delay. When Br is excited, this shunt resistance is removed and the relay is released with a delay. At the forward contact of relay Br, the circuit of the relay Cr is closed, which in turn completes the circuit of the relay Cr. There is a separate contact on both of these relays for each local cord, closing the circuit from the ball B of the grading relay to the Ur relay (Fig. 1), as a result of which the Tsr relay shown in the figure is excited so that and a tone is sent to the originating line. The Ar relay winding is short-circuited on one relay Crx contact. This relay is released with a delay, then it is also released with a delay Br, and then the transmitters Cr, Crlf Ur and Tsr are released, producing an intermittent tone. If any other string is in position 2, and its corresponding relay Ur is connected via the Tsr relay, a continuous tone is produced but only in the string whose stepping relay is in the disc position, while the string at The occupancy position receives an uninterrupted tone. If the number of strings is small then the Cr relay may be skipped and its left contact may be placed on the Cr relay as indicated. The secondary device marked with E, B, t, r is under the control of the key O. D. K. Tons of unreachable numbers. If a call is made to a number that cannot be connected, the calling station receives a special tone, consisting of seven clicks per second, via the common relays Hr and Ir. In order to facilitate the description, it is assumed that the line No. 70 in the local string circuit is disconnected. The circuit is of the kind that makes it possible to move the cord bell relay Rr through the wire "b" and the resistance towards the battery. The cord then passes into the talk position, and the battery opposes the winding battery JO-relay Pr, which the winding remains de-energized. Relay Hr is connected by high resistance to wire "a", whereby this relay is excited by the secondary relay winding Pr of the string. The circuit therefore has such a resistance that it cannot excite the relay Pr. The sensitive relay Hr creates a circuit for the relay Ir via its front contact. The Ir relay, when energized, short-circuits the Hr relay, so that Hr and Ir send out a slow humming sound and the change in potential in wire "a" sends a separate signal to the side causing a separate signal. A bell circuit. in Fig. 2 In the local cord ringing position, the Rsr relay, which initiates the ringing and located in this circuit, is connected by a special high resistance to the string ball G, and then by one relay winding Pr and a parallel non-inductive resistance with earth The relay Rsr energizes and produces a local circuit for the relay Dr1 which in turn closes the circuit for the vibrating relay Rir which measures the time, which relay closes and opens the bell circuit at appropriate intervals. similarly to English application, patent No. 208 073. The bell circuit consists of a vibrating relay and a transducer, what will not be specifically described here. The timing relay keeps the Dr relay energized at ringing intervals so that when a new call is started, a ringing current is sent immediately to the line. The secondary device denoted by E, E, r, D, F, r and E, G, r exists here as well as in the case of the tone circuit, and changes to this device are under the control of the key O. R. K. Timing alarm circuit. If the bell current source fails to perform its function, an alarm is sent to the remote main control panel in which relay Xr in this figure is energized in a circuit through the Ir relay back contact, the Kr relay front contact and the Br front contact. Relay Jr is permanently connected to the source of the bell current. This relay always remains energized during the formation of the bell current, in order to short-circuit the winding of the relay Kr by its front contact. If Jr did not keep its front contact closed, the delayed Kr relay will be activated in the circuit running through the front contact of the Dr * relay because it is additionally required to keep the bell circuit vibrating relays in the off state when the ring current is not needed, so prevent the alarm from being sent to the control panel when the ring circuit is established and before the Jr relay energizes. To achieve this, the Kr relay is short-circuited by the contact of the Rir timing relay at the time of the pitch pause, while the Jr relay, during the ring interval, is operated at a speed such that it can be caught by the delayed Kr relay. . Then the Ir relay is released and opens late. This operation repeats itself at the beginning of each ringing interval. As soon as the fuse blows, the Xr relay energizes. immediately as a result of Fa's cessation. The signal to the control panel is then sent via one of the existing cables. It is also assumed that the connections between the main headquarters and the provincial installation are made by cables for the automatic receiving and sending of the connections, so that the pro-conditional installation does not need servicing. If the main switchboard is operated manually, the dial connection determination is made in one of the operator's positions, since the emergency signal may reach the line when there is already a call on it, so it is necessary to part of the connection made in of the provincial installation, the way of connecting the "c" end of the said cable with the ground and turning off the "6" wire has been released. The existing connection in the exchange is deleted first, and the device sending the alarm signal depends on the device in the main exchange. The central line is marked on the left side of Fig. 2 by the conductors E, and the conductors E4, E5, E6 denote the wires "a", "b", "c" respectively. Corresponding wires "a", "b", "C" belonging to the local line are marked with //, 12, 13. Wires r of the distant manual switchboard are marked with continuous lines in the figure below. Through one of the contacts of the relay Xr a common stepping relay is set in motion, and by means of the air relay a slow gradual movement of this relay is made, which will be described in more detail below. The wire "b" running from the cable to the switchboard E, S is connected via the left external contact of the relay Xr with a group of terminals of the stepping relay, which at certain intervals connects and deactivates the lines, as a result of which slow pulses are generated in the switchboard via the monitoring relay of the calling side or the called side. The wire "er" of cable E4 is connected via the retarder Re to earth. The tone of the unreachable number described previously can also be connected to the wire "a". After the connection existing in the switchboard is removed, such a signal appears by itself on the line relay. Due to the connection of the earth with the wire "c", connection of the site If the main switchboard is completely automatic, the alarm circuit follows the broken lines by means of additional relays Wr and Xrl, but the connections marked with crosses are removed. Additional relays are used to meet all possible conditions on the lines in question. If, for example, the cable is busy at the time of alarming, it is sufficient to only release the connection to the switchboard by temporarily breaking the line, if, of course, the call comes from outside the switchboard. If, on the other hand, the call originates from the control unit, the pause must continue or repeat until the calling party is released, and then a call is generated on the line and continues until an alarm is triggered to attract the attention of the operator. However, it is necessary that the said call should not be released at each line break, and for this purpose the relay Xr sets the time measuring relay in motion at the moment when the relay Wr opens or closes the wire at certain intervals. corresponding to the position of the timer. At the same time, the wire "a" disconnects from the ground and connects to the battery by the contacts that start breaking the circuit, belonging to the relay W, and by the left contact of the relay Xr . This last connection can be established only after creating a single break in the wire "a", which is done by the relay Xrl, which, when released, switches itself into the circuit with the right contact of the relay Xr. starts working as soon as the cable is engaged by a call entering the switchboard, then the Wr relay picks up first and the switchboard connection is released.After the common relay advances one step, the Xrl relay energizes again. before the Wr relay happens to slow down; the wire "a" is connected to earth by the rear contact of the Wr relay, in front of it. If the step relay rises up in a register or cord associated with the line of the central station, this relay establishes a connection to earth via wire "6". Then, the timing relay Wr energizes and the wire "6" opens, but at the same time the secondary winding of the stepping relay in the control unit maintains the connection via the wire "a" to the battery. After a certain interval, a constant trigger signal appears in the control panel. If the call comes from the main panel, it is important, that the wire "6" opens when the developing side is released. The timing relay then slows down and the control unit starts to trigger. After the local string stepping relay has reached position 2, the string relay Er energizes if, of course, the common timing relay is in one of its inoperative positions. Relay Er then closes a circuit through the common relay Ur, as shown in the figure, so that both relays are kept energized as long as the step relay of the given cord remains in position 2, the relay Ur produces, by means of one of its actions On the front contacts, the circuit for the timing relay, and in its left contact, the circuit for the step magnet SM. In the latter circuit, the relay Vr is connected in parallel, which aims to keep the magnet circuit SM closed only for the time needed to excite the magnet, and not during the period in which the relay measuring the time is kept. ¬ meshes the circuit closed so that the stepping magnet is prevented from overheating. Consequently, the SM advances one hundred every six seconds. If the string relay Br (Fig. 1) is kept energized for more than 30 seconds, the stepping magnet reaches the position closing the circuit extending from its brush "a" via the left outer front contact of the relay Er (Fig. 1). and through the relay windings ZR and YR, which relays are common to one group of strings. During normal operation the step relay remains in said position for about six seconds. The relay Zr opens on its rear contact the circuits common to zero calls and lines. In this group of cords, the grounding of said circuits is made by means of conductors such as ZC. Relay Zr produces through its contact the front circuit that incapacitates the relay shown in Figs. 4 or 5. Relay Yr connects the batteries to the terminal "D" of the discussed string by means of one of its contacts and contacts of the relay Er given in Fig. 1. In the installation on the 70 lines described here, two g ranks of ropes and hence two groups of grading circuits. The circuit for the driving magnet of the incapacitation relay shown in Fig. 4 is closed by the contact of the trial relay Ar (Fig. 4) and the front contact of the relay Zr (Fig. 2). The winding of the relay Ar (Fig. 4) is grounded through the second contact of the relay Zr. The Ar relay is such that it does not affect the terminal "d" on which the "O" or connecting line is called, i.e. when the circuit closes through a relay winding such as Pr on the string, and the Ar relay operates when the terminal "D" is connected to the battery through the forward contact of the relay Yr and a small protective resistance. The same series of actions is performed when using the relay given in Fig. 4, but not the relay given in Fig. 5, the latter described 3). In the case of an installation that does not have a binding line, the relay shown in Fig. 4. The SS conductors belong to the subscriber line and are associated with an additional with the line transmitter Lir and the terminals a, b, c, d, belonging to the line on the finder bar. The conductors leading to the finder are shown in the upper right corner of Fig. 4. Earthing made from the right contact of the relay Zr (Fig. 2) excites the feed magnet SM of the incapacitation relay. The relay searches until the designated terminal "d" is formed, then the relay Ar is energized according to the previously determined circuit running from the relay Yr (Fig. 2), through the contacts of the relay Er (Fig. 1), the terminal "d" "string, the end" d "of the driving circuit breaker, the winding of the relay Ar and then to the ground on the left contact of the relay Zr (Fig. 2). The relay Ar, when excited, creates a circuit through its front contact and In order to excite the Lir relay proper to the Unji, this relay is connected on one of its front contacts with the wire "B" of the line, and at the same time the wire "a" is connected by the second front contact of the Lir relay with the ground. is kept energized as long as there is a short circuit on the line. The conductor "c" connects directly to the ground through the second forward contact of the Li-r relay, as a result of which the cut-off relay releases and the line relay holds. is in the off state. The earth wire "c" releases each of the 2 local cords on this line in a well-known manner. Then the cord is released and the stepping relay moves to position 2, so that the timing device and the common apparatus are also released, and the incapacitation relay is out of order, remaining in its last position. The earth is connected by smooth forward contact of Lira with each of the test terminals, such as TT, which are therefore kept in a busy state. By using the second front contact, a local signal can be applied, if necessary, so as to indicate immediately the line on which the Lira relay is closed. After the release of the relay Ur of the common time regulator (Fig. 2), the magnet SM (Fig. 2) returns via its back contact to its inactive position. The same device serves to release the apparatus under the control of the called party within a certain period of time. To this end, the release of the connecting apparatus is directly under the control of the calling party and also under the control of the called party, within certain time limits prior to release. This is of great importance since it prevents the binding apparatus from being tied up by the calling party. . Thus, if the called subscriber hangs up the handset when the calling subscriber has not, the cord circuit remains in position 15 and the relay Er energizes again due to the release of the relay Pr, the circuit being the same as before. The timing relay works as before and if the calling subscriber fails to hang the handset within a certain period of time, say 30 seconds, then the call is automatically released and the line disconnects. The subsequent removal of the short circuit restores the line to the active state. Fig. 3 shows a connecting line circuit intended to connect two identical, provincial automatic installations having local connecting circuits of the type shown in Figs. 1 - 14 - If one of the lines above kind of broke, there would be considerable inaccuracies in the exchange, as this exchange is not normally serviced * Even if an alarm is sent immediately to the main exchange, it will still take some time before the error is corrected so that in the meantime period of time, the operation of the device may be completely defective, In the device shown in Fig. 3, the erroneous connecting line is disconnected at both ends, and all devices associated with it are released from the force of things, if the inaccuracy is sufficient to run line relay and creating a call. A significant advantage of this device is that the apparatus used to incapacitate subscriber lines is simultaneously used to incapacitate binding lines, so in the event of an error occurring when a line is not engaged, a call is generated at one or both line ends. As a result of the above, the local cord circuit is bound to it by itself, and after a certain time has elapsed, the incapacitating apparatus shown in Fig. 5 begins to operate to release the apparatus associated with it and incapacitate the line connecting at both ends. The device is of the kind that disconnecting one end immediately produces a triggering state at the other end, so that the incapacitating apparatus at this last end operates normally after a certain period of time, after removing the error the line becomes Another important feature of the circuit in question consists in the fact that the connecting line is automatically released when this line is taken by the subscriber's line on which the error occurred, or by the subscriber himself as a result of undisputed When the earphones are hooked on the hook, a cycle of operations similar to that described above takes place, namely: local cord 'at the entry end of the connecting line, after holding it for a defined period of time, disconnects the connecting line and at the same time reverses the current in this line to release the subscriber's line and create a call persistent state at the exit end of the linking line. If the joining line itself is broken, indeed the exit end is inerted, and if the joining line is okay, an occupied state is produced at the upstream end whereby a triggered state is created at the exit end. The damaged subscriber's line is of course disabled as previously described. The circuit of the connecting line by which the upstream action is achieved is arranged so that a line relay at one end of the line switches between "b" and the batteries, while a line switch at the other end switches between the conductor " a "and the lands. The operation of the relays used to disconnect the line, together with the incapacitating relay, will lead to the conductor "a" or "6" of the potential needed to actuate the line relay at the far end. When connecting a local call to the input end line, the loop closes at the output end of the line through a counter relay and a relay with differential winding. The current is diverted from said loop to release the differential relay and thereby release the apparatus associated therewith. The momentary increase in this loop current is used to count at the output end. A detailed description of the device performing the counting on a connecting line of the above type is given in the English declaration already mentioned. The present invention relates to an incapacitation and automatic release device as explained above, but in order to explain these actions exactly, it is given in _ 15 - below is a description of the circuits given in Fig. 3. A calling subscriber who wishes to access the connecting line leading to a particular switch determines the indicated number with the dial, and as a result of the above, the lower dialing relay, shown in Fig. 1, turns one step towards a specific group. contacts, such as contacts marked with O. As a result of the above, the battery is connected at the end "d" of the line finder in the circuit running from the left relay winding Pr, by: ball K, lower contacts of transmitters Mr and Kr, brush / until the line finder brush F. Then the OFS conductor is grounded by searching for relay Pr, ball G, upper contacts of transmitters Mr, Kr, brush £ 2, brush e, left contact of relay R to OFS conductor. each gT is assigned, as has already been said, in the case of calls to the operator, at the central office or other provincial automatic installation, by means of a connecting line. in each case, however, the earthing is placed on different conductors in order to set in motion: the servicing finder relays, the panel finder relays or, as in the present case, the connecting line finder relay given in Fig. 3. We suppose here that the terminal "d" of finder FS1 is determined and that ground is located on the conductor of the connecting line, which conductor in Fig. 3 is denoted by conductor B, C. The CBC conductor corresponds to the conductor CFS in Fig. 1. Relay Er (Fig. 3) excites on the visible circumference. If the control panel is so large that it requires two groups of string circuits, then one such group can be associated with the BO conductor and the transmitters Er and Gr, and the other group will then be associated with the BCIf conductor with transmitters. ERl and Grl. Each circuit of the connecting line will then be provided with two searching relays FSt and FS2, as can be seen in the figure. Relays Er and Gr are common to all circuits of lines belonging to a particular group of strings, for the number of groups The strings and the number of groups of appropriate devices can of course be enlarged as needed. The excitation of the relay Er triggers the closure of the circuit from the ground to the anchor ZC which is associated with the relay Zr given in Fig. 2 by the left contact of the relay Cor, left Er relay contact, Crl relay right contact, Gr relay winding, batteries and to ground. Relay Gr starts to operate and completes the circuit to set relay Gr in motion, whereby line finders for inactive joining lines belonging to the group begin to search for the trigger line. Operation of the Er relay places the ground from ZC on the AC conductor. This grounding can be used for supervisory purposes, for example to indicate that searchers are searching. The devices of the Erl and Grl transmitters operate in the same way as the Er and Cr transmitters. In addition, a ground is placed on the right contact of the relay Grl in order to activate the relay Mr on the visible circuit and this obviates the right contact of the relay Cor. The relay Mr completes a circuit visible to the relay Kr, which converts the circuits to the brushes of the first line finder into the circuits to the brushes of the second line finder. The relay Mr also converts the circuit of the trial relay Tr from the first line finder to the circuit from the second finder. The Or relay is used to incapacitate all actuating circuits belonging to the group of switching lines; Thus, if all lines connecting a given group are occupied, the circuit leading to the contact ZC opens on the contacts of the Cor relays, and the lead of the battery, along the conductor AC to the appropriate device, causes excitation of the relay Or, aiming at - placing the shunt winding between the transmitters Ert and ERU, which prevents the commencement of further triggers. Now, as before, we assume that the calling subscriber secured a local cord and determined the number of the connecting line and that the earthing connected to the BC A connected string to set in motion the Cr relay, which completes the circuit, needed to excite the SM feed magnet, and passing through: batteries, magnet winding SM, left contact of relay Mr, self-breaking contacts of magnet SM and of the magnet SMt, the left contact of the relay Cr, the left contact of the relay Dr, and to the ground at the left contact of the relay Tr. The advancing magnet works and releases in order to rotate the searching relay FS ± to one stage, until the designated line is found, then the circuit from the battery to the "n" ^ xj terminal is closed. ^ J. \ Right contact Relay Mr right winding of relay Tr, right contact of relay Dr, right contact of relay Cr and to the ground on contact of relay Lr. Relay Tr operates in this circuit and breaks the above-designated driving magnet. it also closes the visible circuit from the end "d". This relay also removes the shunt from the relay Fr, so that the relay Fr is energized in series with the driving magnet. However, due to the high resistance of the relay Fr, the magnet SM does not work. Excitation of the relay Fr closes the visible circuit that runs from the ground and its contacts: the right winding of the relay Xr and the winding of the relay Br, and then to the battery. Relays Br and Xr awake. The relay Br is switched on through the calling line to the winding of the relay Ir, which in turn excites itself on the subscriber's loop. The relay Ir closes the circuit by means of the right contact of the relay Fr in the excited state. The relay Br at its lowest contact connects the ground to the terminal c * of the finder, as a result of which the local cord circuit is released and the subscriber line becomes busy. The Br relay closes at its highest contact the visible circuit for the right relay winding Cor. The relay Br transmits on its lower upper contacts a talking circuit on the connecting line, using the capacitor indicated in the drawing. The excitation of the Cor relay removes the previously determined ground for relay Gr, which releases and removes the ground from the Cr relay, which in turn releases at its right internal contact, and the Cor relay creates, if necessary, a closing circuit for relay Mr, breaking at the same time the initial circuit holding this relay on its right outer contact. Grounding on the right inner contact of Cor also creates the excitation circuit. relay Dr, which then completes the circuit at its left internal contact to make ground connection, which circuit runs from the highest contact of relay Br to the end "c" of the input finder relays associated with the jumper line, thereby making the jumper busy. excitation of the Ir relay, the circuit closes to turn on the battery by: relay left contact Ar, relay left contact Ir and relay top 17 - the innermost contact of relay Br on conductor A or on the upper conductor of the connecting line. the Lrx line relay energizes at the far end of the line (on the left side of the figure). As a result of the Lrlt relay excitation, the battery is energized via the right coil winding Cor and the right relay contacts Lrx at the end "c" of the strip B2 belonging to this area. The scout finder. The Lr relay places the grounding on its left contact on the SWX wire which sets the searchers in motion. The searchers associated with the strings belonging to a separate group are then set in motion and searched for the calling line connecting. In this regard, the connecting line may be considered as the auto-trigger of the subscriber line. Upon reaching the line, the Corx relay energizes while energizing the Dr2 relay on the visible perimeter by means of its left inner contact. The Drx relay interrupts on its left inside contact the circuit of the line relay Zlf and on its right inside contact closes the corresponding circuit for the Cor relay which is excited by the conductor "c" running to the cord. The cord circuit continues as it was after ¬ Known in connection with Fig. 1, also after preparing the circuits, the subscriber receives the dial tone using the connecting line. The subscriber can then erase the number of the set line in the remote exchange: At each opening of the subscriber's short circuit, as a result of terminating the dialing , relay Ir (Fig. 3) releases in the usual way. Relay Ir opens on its right contact the circuit of relay Fr, but since this relay operates with a delay, no circuit changes take place. Relay Ir opens on its right contact. Left contact the main circuit running to the cord, which also causes the Ar and Xr relays to drop. The left contact of the Ir relay re-closes transfers the battery connection from the left contact of relay Ar on the wire "g" of the line, and hence the wire stepping relay (corresponding to relay Ir in Fig. 1) starts operating again immediately as one winding of this relay is connected between ground and wire "a" . The above device enables the exact reproduction of the pulses. The cord circuit actuates the tipping relays and connects via the line to the called party. Dialing and deceleration follow in the usual manner. Counter operation. If only the subscriber's counter is needed, then circuits marked with dashed lines are created and the connections marked with crosses are deleted, whereby the transmitters Yr, Yrx and the relay Zr are introduced. If the called subscriber answers, then the string connected circuit, in view of the existing connection with the strip B2 in Fig. 3, connects the Booster batteries or the auxiliary generator to the conductor "c" by means of the relay Or shown in Fig. 1. The Booster's battery sets the indicator Yr19 in motion, and the battery connects with the Yrx relay contact through the wire "a". After considering the circuits in connection with the circuits in Fig. 1, we will see that the above action will cause an increase in the current flowing along the line, which current will cause the Zr to operate. Relay Zr removes the grounding r of the finder relay wire "c" at the output end of FS1 or SF2t and connects the Booster battery to the OC conductor to this conductor. The Booster battery is inserted into this conductor by an Or relay (Fig. 1). Relay Or as already mentioned, it opens the circuit of all the finder relays so that the connections are not interfered with by these relays when removing the speech potential from the wire "c \ Booster battery connected to the wire of the wire" c "starts a normal subscriber counter, such as for example MS (FIG. 1). The tie circuit can be arranged so as to achieve easy multiple operation of the Counter. Such circuits are shown in Fig. 7 and are the subject of the related English declaration mentioned previously. Incapacitating the Hnji joining at its entry end. Let us first assume that the firing came from the right side of Fig. 3 towards the sironfe of the left Fig. 3 and that the local cord circumference shown in Fig. 1 is connected to the strip B2. If now the conditions of permanent calling arise on the connecting line, which may be the result of a bleed on the subscriber's line or as a result of a permanent short circuit on the subscriber's line, then after a certain time the time-measuring relay, shown in Fig. 2, sets the relays Yr and Zr (Fig. 2) in motion as already described. Fig. 5 can now be regarded as on the left side of Fig. 2, and therefore grounding will be applied to the two conductors shown on the right side of Fig. 2. 5 and this through the visible circuit, which will now close by the self-breaking contact of the driving magnet SM of the incapacitating relay, which will then start looking for the damaged line. At the same time, the operation of the relay Yr (Fig. 2) connects the batteries with The folder "d" of the finder relay associated with the local cord, i.e. other words, the battery is connected to the end "d" of the strip B2 shown in Fig. 3. Conductors a, b, c, d associated with the list B2 ii found below the latter, they are connected with the appropriate conductors a, b, c, d, shown in the upper left corner of Fig. 5. It can be seen from the above that the string circuit carries the batteries from the contacts of the relay Yr (Fig. 2) at the end "d" of the incapacitation relay given in Fig. 3. After the incapacitation relay reaches the terminals marked, the relay Ar is excited by the battery by means of d and stops the driving magnet. The relay BR energizes to the circumference. day visible. The relay connects on its right-hand contact the batteries, connected to the wire "a" (Fig. 5), to the wire "a" of the connecting line. The same relay hisses on its left external contacts to the ground wire "c" bonded to the corresponding conductor in Fig. 3. Relay L1r1 is excited in the visible circuit running through its right winding and turns on with its two windings in series in The Lx rt relay then connects the earth to the terminal "c" of the B2 strip in order to free the string circuit and take the connecting line. As the cord is released, the battery and ground are removed from the shutdown relay as described. The ground connection path to the L ± r19 relay right contacts, the test terminal TT, associated with the connecting line on the dial at the switchboard, becomes busy. The connection of the battery with the wire "a" and the earth with the wire "b" of the connecting line, thanks to the incapacitation relay, causes a reversal of the current flowing on the connecting line. After the time measuring relay (Fig. 2) leaves the contacts, through which the incapacitation relay has been triggered, the relays Br and Ar of the incapacitation relay are released, and the battery and ground are removed from the wires "a" "b" of the connecting line. The ZRx relay now completes the circuit from the battery through: the two series windings of the relay L ± rlf loop the line and to ground through the left external contact of the relay L ± Ti and the resistance. This resistance prevents a short short circuit of the battery used with the wire "a" - 19 - running from the incapacitation relay. As for the distant end of the line, the reversal of the loop current through the Zr, Xr, Ar relays causes the relay to release Xr due to equilibrium. The release of the Xr relay causes the release of the Fr relay and hence the Br relay which, when released, removes all connections to the finder relay FS1 or FS2 on its three lower contacts. they are of the nature that they do not have their normal position, that is, they do not return to that normal position. The Br relay removes the ground holding the Cor relay at its highest contacts. The Cor relay, so the Dr and Mr relays are released when necessary. Relay Br opens on its top contacts the connecting line, thereby releasing the relay Ar. If now the connecting line itself is okay, then there is no connecting line on the line. short-circuits, and the previously determined closing circuit through the relay L x R ± opens. Upon release of the incapacitation relay at the upstream end, the incapacitation relay L1f mt is released, whereby the connecting line becomes active again. If, on the other hand, a permanent short-circuit at the upstream end is caused by a connecting line, the break caused by the relay Br will have no effect since, due to the fault, another circuit is generated by a short-circuit for the relay Lx rx. This circuit starts working as soon as the incapacitation relay is released at the upstream end. At the same time, connecting the ground via the incapacitation relay to the conductor "b" of the connecting line causes the relay Lr to operate at the output end. As a result, a triggered condition is created and the connecting line is interrupted on the bar B1 by local triggering. the following takes place in the same way as for a normal call, and the connecting line is disconnected at the output end until the line error is cleared, which is before the usual period of time, e.g. 30 seconds, has elapsed. the transmitters incapacitating the lines are switched on in such a way that their two windings are connected in series with the ground on their external contacts by shorting the fault line. Removing this short circuit gradually causes the release of both transmitters. If we suspect that an error or a short circuit constantly, necessitating the disconnection of the connecting line at the entry end, were caused by the subscriber's line associated with at the output end with the FS1 or FS2 relay, the release of this line by the release path of the Br relay produces a call state at said end. The subscriber's line is therefore taken up by the local line, and if the call is released or the fault is removed, the line is disconnected in the usual manner after a predetermined time has elapsed. If the connection is made from the left side to the right side in FIG. 3, the same series of steps will follow. It should be noted that in this case excitation of the relay Br causes a grounding running from the relay Ar and aimed at excitation of the linear relay Lr through the wire "6". The connection of the battery with the wire "a" and the earth with the wire "b" "Through the incapacitation relay, it reverses the loop current again to release the Xr1 relay and energizes, as before, the Lrx relay. The Lv rx and Lr transmitters can be closed if necessary as described previously. at both ends of the connecting line are the same and operate in the same way. Relays Lt rt and Lr can be provided with contacts causing the start of the diary - 20 - Laji causing the alarm, immediately after a certain time. EN EN EN EN

Claims (4)

1. Patent claims. 1. A telephone network, characterized by a device that disconnects the line from the network as soon as a permanent closed circuit is formed on it, or in the event of a closed circuit or a ground fault appearing on the line, releasing the apparatus connected to the said line, 2. Telephone network according to claim 1, characterized by the fact that calls taking place between automatic and semi-automatic control units run on two-wire interconnecting cables and that it includes a device which, in the event of the emergence of a closed circuit on said fixed cable, disconnects the cable at both ends . 3. Telephone network according to claim A device according to claim 1 or 2, characterized in that it comprises a device which, if the called subscriber releases his set while the calling subscriber has not yet done so, releases the devices connected to the calling line after a certain period of time. 4. Telephone network according to claim A device according to any one of claims 1, 2 or 3, characterized by a device which releases said cable when an interconnecting cable is engaged across a line having a permanent short circuit or fault. 5. Telephone network according to claim 1 to 4, characterized by the fact that each of its lines is provided with a separate device and a device which makes the device in motion when a permanent connection (short circuit) or error occurs on the line, because this device may disconnect the lines. 6. A telephone network according to claim 5. The method of claim 5, characterized in that said device is released when said short circuit or error is removed. 7. Telephone network according to claim The telephone network according to claim 5 or 6, characterized in that said device comprises a relay which closes by a short circuit on a line. 5, 6 and 7, characterized by the fact that said line device signals the occurrence of a line short circuit or an error. 9. Telephone network according to claim A device according to claim 1, characterized by the fact that the triggers are produced by a automatic or semi-automatic switchgear and that it contains a device which, in the event of a fault or permanent short circuit on the developing line, causes the automatic switchgear to engage the damaged line and disconnect me from the net. 10. Telephone network according to claim A device according to claim 9, characterized in that it includes a device that can disconnect the subscriber or an interconnecting cable at both ends if necessary. 11. Telephone network according to claim 1-10, characterized by the fact that said incapacitation device also releases the automatically attached apparatuses. 12. Telephone network according to claim 1 - 11, characterized by the fact that said incapacitation device also releases the apparatus used in the call for a certain period of time, under the control of the called subscriber. 13. Telephone network according to claim 1-12, characterized by the fact that said incapacitating and releasing device attached to the line also serves to release the developing apparatus occupying the interconnecting cable at its distant end. 14. Telephone network according to claim 2-13, characterized by the fact that said copper conductor is disconnected at its distal end by means of a device which causes that when the cable is disconnected at the local end, a continuous evoking state is created at the distal end, which is gradually broken . Telephone network according to Claim 14, characterized in that the interconnecting cable is disconnected at its distal end by an apparatus similar to the apparatus used at the local end of the cable to disconnect it, 16. Telephone network according to claim 14 . The method of claim 9, characterized in that the automatic switch connects to a line under the control of the timing device, which device defines the line and sets the search device into motion after a predetermined time. 17. Telephone network according to claim 16, characterized in that the line is determined by the path of applying the appropriate voltage to the terminal attached to said line, and it is on the strips of the line finder that the tension is applied to the higher end by means of a local connecting apparatus associated with the line. 18. Telephone network according to claim 16 and 17, characterized by the terminal to which the voltage is applied is used to activate the calling line of the duty officer, serving the network or other switchboards. 19. Telephone network according to claim 3 to 18, characterized by the fact that when the device in question is released, the developing line becomes disconnected. 20. Telephone network according to claim 19, characterized by the fact that said subscriber line is disconnected by a device also used to release the paired device. 21. Telephone network according to claim 2 and 9-20, characterized by the fact that it comprises devices which cause the detached line to release automatically after the removal of a fault or a permanent connection from the line. 22. Telephone network according to claim The method of claim 4, characterized in that said self-release of a developing line at the end of said cable is performed by a device disengaging the cable at its local end and creating a developing condition at its distal end. 23. Telephone network according to claim 22, characterized by the fact that said cable becomes free when the calling line is released. 24. A telephone network according to claim A telephone network according to claims 1 - 23, characterized in that it is provided with interconnecting cables of the above type and that the incapacitating device acts on the cable in both directions, 25. A method according to any one of the preceding claims, characterized in that it comprises copper cables of the above type and that the release device automatically acts on the cable in both directions. 26. Telephone network according to claim 1, 24 and 25, characterized in that it comprises interconnecting cables which operate in such a way that the line relay switches at one end between the wire and the ground, and the line relay at the other end switches between the other wire and batteries. 27. Telephone network according to claim 26, characterized in that it has relays capable of keeping the cable busy, whereby both said relays are connected between one and the same cable wire and batteries. 28. Telephone network according to claim 1 - 27, characterized in that it has two-wire interconnecting cables and that the chute on said cable is closed at the output end by a differential relay, as a result of which a reverse current at the distant end of the loop de-energizes the associated apparatus and generates this end evoking. 29. Telephone network according to claim 28, characterized in that said loop is closed by a meter relay and that the actuation of the relay is made using booster batteries, and that from the far end of the line through the line itself. 30. Telephone network according to claim A device according to claim 1, characterized in that it comprises a device for sending a supervisory signal from the local exchange to the central exchange, and a device for commencing an existing connection with the central exchange for this purpose. 31. Telephone network according to claim 30, characterized in that the monitoring signal sending device simultaneously serves to generate time intervals between the individual connection operations. 32. Telephone network according to claim 30 and 31, characterized in that said signal sending device comprises a device for supplying batteries and ground at intervals to one or both sides of the line. 33. Telephone network according to claim 30, 31 and 32, characterized by the fact that the terminating device also serves to send said supervisory signal. International Standard Electric Corporation. Deputy: M. Skrzypkowski. patent attorney.FIG I. Cor ii a doojdogdoo oo boaaooo o? a aa pDDoaaaaoa o a tfb a to from oaoo a o \ 4l.4Z4 $ # A5.46.fim4Sl4a * i. * ~ 60 poaooDooogoa To the patent description No. 7697. Ark. 2. r / c?. To patent specification No. 7697. Ark. 3. 4 * - ^ 1 1 figuref * FIG. 3. To patent description No. 7697. Ark. 4. m-i ^ joci F3c. G.rJ \ \ 1 r- ^ ZL LrJi QC 3 ^ -yy ^ i9iJs ^ Lg ^ AJ (iL ^ 9999 (l) 6 iii i ii ^ yy ^^^ g ??????????? ???? Print by L. Boguslawski, Warsaw, PL PL