DE421519C - Circuit arrangement for traffic observation - Google Patents

Description

The invention relates to a circuit arrangement for traffic monitoring in subdivided voter systems. Such a system should make it possible to monitor the handling of the traffic over certain trunk groups or over individual trunk lines of subdivided telephone systems. The observation can be used for monitoring, fault detection, statistical purposes or the like. A V örbedingung "" Door useful observation is that the subjected to the observation Verbin dungsleitungen_ when an incoming call

"automatically switched through to the observatory and here the identifier of both the connected connection line and the relevant exchange make perceptible. Furthermore, provision must be made that each

ao can only connect one connection line to an observation station.

According to the invention, these requirements are met in that one of the Connection line of a sub-office that is subject to observation when it is occupied is automatically switched through to a centrally located observatory. The Observatory blocking means are assigned to prevent a further connection line from being opened by another switching center the observatory goes through.

On a display device assigned to the sub-office becomes the connection line connected to the observation center and on a display device assigned to the main office the connection line and the relevant sub-office are identified.

In Figs. 1 to 6, an embodiment of the invention is shown. the Fig. 2, 3, 4 and 5 are to be placed next to each other with the corresponding lines, Fig. 1 is above Fig. 2 to lay. Give in this arrangement

the drawings show a complete picture of a circuit arrangement for traffic observation according to the invention. Fig. Ι illustrates the usual switching means that are used for Connection of a calling subscriber in an automatic dialer system are required. Figures 2 and 3 taken together represent those assigned to an observed office Switching means that are used to switch through the connecting lines belonging to this sub-office to the central observation point, to display the connected connection line on the monitored office and to control the switching means that have the same connection line display on the central observatory cause, serve. Figures 4 and 5 together illustrate the switching means on the observing office, which is responsible for a plurality of offices which are subject to the observation all, as shown in Fig. 2 and 3, are equipped and can work together. Fig. 6 shows an observation station with the switching means shown in Figs cooperates to monitor interconnection lines, if desired to unite a special office.

As far as Fig. 1 is concerned, subscriber station A is of the usual type. The | Selection C is a selection of known type j with no rest position. The group selector D is an ordinary lever and rotary selector. An intermediate distributor TB is arranged at a suitable location in the monitored office. A distributor wire, which comprises the wires 102, 103 and 104 • is shown in the drawing and connects the connecting line running to the 1st group selector D with the contacts of the intermediate distributor TB.

Fig. 2 shows in strongly drawn lines the speech wires 236 and 237 of an observation connection line, which runs via Fig. 3 to the central observation point (Figs. 4 and 5). This observation trunk is common to all trunk lines of the same office. As shown in the drawing, it has been assumed that a maximum of 50 connection lines have access to the observation connection line. There are therefore 50 connecting lines (such as, for example, the wires 107, 108 and 109) permanently connected to the contacts of the intermediate distributor TB (Fig. 1). Two relays 201, 211 or 210, 220 are assigned to each such connecting line. One of these relays is used to connect its connection line to the speech wires 236 and 237 and to switch on an indicator lamp, and the other relay is to prevent such a connection from being switched through when the observation connection line is in use.

j These 50 connecting lines with their I corresponding relay sets are in five j Groups of ten each. Each group is with a relay like 245 and with one further relay 255 equipped. Only one of the five relays 245 is on the drawing shown, but the rest not shown are on the same common wire like 245 switched on. These relays each carry ten pairs of relay springs, one pair for each connection line in the group and work on the control of switching means their associated office in order to prepare the switching device for switching through connecting lines. To this end only one relay could be used instead of five, but such a relay would have to be 50 Wear sets of springs, which is not wanted. It should now be a detailed description the mode of action are given.

It should first be explained which switching processes take place when connecting lines occupied while the observation point is free, while afterwards the various processes should be described when the observer go prepared their place to receive calls.

When the observatory is not in use, relay 245 (Fig. 2) is de-energized and also all other such relays (not shown) of the other groups and all other offices. If e.g. a call is made over the connection lines 107, 108 and 109 runs in, the core 109 is earthed. Relay 201 responds. The excitation circuit runs from the grounded wire 109 via the lower winding of the relay 201, the Springs of armature 221 and the lower winding of relay 211 to battery and earth. The excitation winding of the relay 211 has a lot compared to that of the relay 201 low resistance, which is why relay 211 does not respond at this moment. The relay 201 is maintained via its normally open contact 221 and via its upper winding to the battery. If the observation station is ready for observation at the same time, so all relays 245 of the observed office are energized. The excitation of these relays causes the short circuit of the lower windings of all relays 201, which, however, does not the fall of any relay 201 is brought about, since this is through its upper Winding holds. The short circuit, however, causes a relay 211, the momentary is not excited, responds as long as a connection line with the observation

Connection line is connected. It can be seen that relay 201 or any other same relays that are already energized remain energized until their associated Connection line becomes free. This prevents previous calls from having emerging calls converge after the observation station is on standby was brought.

"With regard to Fig. 5, the observer prepares her place by plugging the plug P into the latch / for observation, which activates relay 405 (Fig. 4), as will be shown in detail below. This relay provides an excitation circuit for each relay 226, one of which is in each monitored office, and prepares a circuit for all relays, such as 401 and 410, of which one relay is arranged on the monitored office and assigned to each monitored office. If one only looks at the observed office shown in Fig. 1, 2 and 3, since the other offices are the same, the mode of operation is as follows:

When plugging the latch /, as already mentioned, the officer establishes a circuit for relay 405, which is connected to the grounded I latch spring / via wire 502, via the springs of the release button K, wire 503, which is carried by armature 403 of relay 401 (Fig. 4) controlled _: springs, which runs through the armature 404 of the relay j 41 ο controlled springs via distributor wire 424, on distributor JB and the winding of relay 405 to battery and earth. Relay; 405 responds and prepares a circuit for the excitation windings at contact 407! all inauguration relay as 401 and 410, above. Two of these ten circuits are there ^! placed and run from the grounded battery via resistor 406, the normally open contact 407, wire 408 to contact 429 of the distributor JB, where the circuits branch; one branch runs over distribution wire 431 to the top winding of relay 401 and the other branch runs over distribution wire 427 of the distributor to the top winding of relay 410. Relay 405 also closes an excitation circuit for common ground relay 226. This circuit runs from ; Working contact 411 via wire 412 after contact 428 of distributor JB, via distributor wire 430 to Kontairt 419, where _; the circuit is divided into as many branches as there are observed offices; the branch shown j runs over distribution wire ^! 413, the springs controlled by armature 414 via wire 415, the normally closed contact 316; (Fig. 3), core 318, the right ^Wick-] development of the repeater R, the wire 319, normally closed contact 320, wire 322, normally closed contact 323, wire 324, via the controlled by armature 225 springs and the coil of the relay 226 after battery and earth. relay

226 responds in this circuit and is held in one of contact 323 of the relay 325 (Fig. 3) independent circuits. This circuit runs from the grounded 7u Wire 322 via normally open contact 225 and the winding of relay 226 to battery and Earth. Relay 226 applies ground to common wire 228 when responding. This circuit runs from the grounded normally open contact

227 via wire 228. Furthermore, relay ^: 226 produces a circuit for relay 242, which is connected to the grounded wire 228 via wire 229, the springs, wire; 239 (which contains eight sets of springs controlled by armature 230), via the springs controlled by armature 240, wire 241, via ten identical sets of springs in each group (not shown) and via the winding of relay 242 to battery and * earth runs. Relay 242 responds and provides a circuit for 245 fro, the grounded wire from the joint 228 through ^Ar: beitskontakt extends 243, over core 244 and the coil of relay 245 to battery and ground. Relay 245 and all other similar, the groups second (not _illustrated: provided) to 5 relays assigned to respond and close the lower winding of all relays, such as 201 and 210, just in each group. The observation station is now ready to observe calls.

If the relay 242 did not respond (because a pair of springs, such as the one controlled by armature 230, was open), the observer or the supervisor on the monitored office was made aware of the buzzer B (Fig. 3). This signal circuit runs from the grounded wire 228 via the normally closed contact 243, the wire 246, the normally closed contact 247, the induction coil 248, the wire 349 and the buzzer B to battery and earth. ^{The supervisor hears this buzzer in the handset of the speech set connected by means of the jack 7 1} and the plug / ³¹ and recognizes that the lamps do not light up that a row of contacts is open and must first be found before connecting lines can be observed in this office.

After the observation station is ready for observation, let us first assume that a subscriber of intercom A (Fig. 1) makes a call. When the handset is lifted on station A , a circuit is made over the line wires 110 and in for line relays

112 of selection C closed. When the line relay 112 is energized, the preselector C operates in a known manner to select a free connecting line which, as assumed, is found in the one connecting line going to the group selector Z>. At the end of the free selection, the switching relay 113 responds and switches the calling line through to the 1st group selector Z>. The line release relays 105 and 106 of the group selector D respond in a known manner, and when it is energized, the latter applies earth to the release wire 104 in order to produce the rest of the holding circuit for the preselector C. As is known, ground on wire 104 is held throughout the connection. A circuit is now established from the earthed wire 104 at the intermediate distributor TB, via wire 109, the normally open contact 270, the springs controlled by armature 221 and the lower winding of the relay 211 to the battery. Relay 211 responds and remains in a circuit which runs from the grounded wire 228 via wire 229 to the normally open contact 230 and the upper winding of the relay 211 to the battery and earth. This switching action also removes ground from the portion of the subscriber loop that extends to relay 242. Should it happen that more than one call comes in at the same time, only the relay closest to the common earth would respond and disconnect the holding earth from all other relays of the same type. The armature 231 of the relay 211 applies earth to the single lamp ο via the wire 232 when responding, whereby the single lamp ο lights up. At the contacts 234 and 235, the connecting line wires 107 and. 108 connected to the connecting line cores 236 and 237, between which the left or primary winding of the transformer coil R is connected as a bridge. Recall that the movement of armature 230 severed ground from loop wire 239 that was previously holding relay 242 energized. Relay 242 now drops out again and interrupts the | previously described excitation circuit of the | Relay 245. At the same time, it closes the circuit for buzzer D, which does not respond at the moment, because its circuit is opened by relay 257 a moment later. Relay 245 drops out and removes the short circuit from the lower winding of all relays, such as 201 and 210. Relay 20I now speaks via a circuit from the grounded wire 109 via the lower winding of relay 201, the springs controlled by armature 221 and the lower winding of the Relay 211 after battery on. Relay 201 produces an excitation circuit for the group relay 251 and the transmitter starter relay 257 when it responds. This circuit runs from the grounded normally open contact 222 via the wire 233, the normally open contact 223, wire 250, which is passed through armature 224; controlled springs, the winding of relay j 251, wire 266 and the winding of relay 257 to battery and earth. Relays 251 and 257 both respond. Relay 251 j establishes a holding circuit for itself and for relay 257; This circuit runs from the earthed wire 228 via wire j 229, the normally open contact 224 and the windings of the relays 251 and 257 in series with the battery and earth. Another circuit is established from the grounded wire 228 via the normally open contact 260 of the relay 251 and the wire 261, which runs after the group lamp o and battery, so that this lamp lights up. This lamp, together with the single lamp controlled by relay 211 for supervision of the monitored office, identifies the number of the connection line connected through at the observation station. Relay 257 interrupts the aforementioned buzzer circuit at its contact 247 and grounds wire 259 at its contact 258.

It should be noted that if the connection line which runs via the lines 107 ', 108', 109 'is occupied, this affects the operation of relay 220 and the holding circuit for that relay via wire 239, via the various series contacts of all other relays, such as the Contacts controlled by armature 230 of relay 211, follow the whole group no. 1 Wire 229 and common wire 228 runs to earth, in which case the circuit has nine pairs of contacts would have to run. It can be seen that the holding circuit for the relays, such as 211 or 220, would have to run over 49 sets of contacts before it can reach the earthed common wire 228 would, in the event that the tenth trunk of the fifth group is busy would, if special arrangements were not made. In the present case, this unwanted series holding current is no circuit is eliminated by shorting forward all the groups of row contacts the special group in which the connecting line entered. For this purpose, each group relay with the exception of the first is equipped with an armature, like 263, which when working the common ground wire 228 directly with the Series contacts connects through the first connection relay of the relevant Group can be controlled.

The group relay 251 is at his

Response to its contact 262 creates a circuit for the trunk initiation relay 401 (Fig. 4). This circuit runs from the grounded wire 250 via the normally open contact 262, the wire 264, the normally closed contact 364, the resistor 365, the lower right winding of the transformer coil R, the wire 366, normally closed contact 367, wire 368, normally closed contact 468 and over the upper winding of relay 401 and the previously described circuit to battery and earth. Relay 401 responds and maintains a circuit that starts from the grounded wire 501 of the officer's pawl via wire 502, the springs controlled by the trigger button Ιζ , wire 503, normally open contact 403 and the lower winding of relay 401 to the battery and earth runs. Relay 401 removes earth from the series holding circuit of relay 405 at its contact 403 and interrupts the previously prepared holding circuit for all other trunking relays, such as 410. If two monitoring connection lines try to connect to the central monitoring station at the same time, only relay 401 speaks is closest to the grounded wire 503, thereby interrupting the excitation circuits for all other trunking relays.

When relay 405 drops it switches ground from all of them to the various common Earthing relay, such as 226 (Fig. 2), leading wires, such as 415. This will however not the drop of relay 226 in the office

³ ^ brought about from which a call was switched through. The reasons for this are explained below. Relay 405 also removes the battery from the excitation winding of all exchange initiation relays, which makes it impossible for another exchange to switch on. The movement of the armature 450 of the relay 401 lights up the office indicator lamp, which indicates to the officer the office in which the observation is made.

^ men will; Contact 416 connects surge line 352 to write register PR (Fig. 5); Contact 417 connects the hold and display rush wire 350 to the rush receive relay 520 (Fig. 5); The contacts 414 and 468 connect the observation connection line with the central observation connection line, which runs via the speech wires 506 and 507, the transmitter coils R ¹ and R ² and via contacts of the interrogation switch ^ ³ after the headset of the observation, which enables the officer to be observed while to enter the line as the connection progresses.

With regard to relay 226 (Fig. 2), it should be recalled that this relay was originally energized via the upper voice line 415 (Fig. 3). If the office entry relay 401 (Fig. 4) responds, the earth previously applied to wire 415 by relay 405 is disconnected by the armature 414 and replaced by a new retaining earth which runs over the winding of the introduction relay 504 (Fig. 5). This new circuit leads from wire 415 via normally open contact 414, the speech wire 506, the upper left winding of the transfer coil R ^, wire 505 and the winding of the relay 504 to the grounded wire 503. The closure of this circuit causes, except that they relays 226 energized, as long as the office is subject to observation, the activation of the introduction relay, which causes the introduction lamp 514 to light up. This should show the observation officer that a connection line has been switched to the observation station if the official lamp ι does not light up due to a fault.

The office initiation relay 401 also produces an excitation circuit for the monitoring relay 536, which is supplied by the normally open contact 222 of the relay 201 via wire 233, normally open contact 223, wire 250, normally open contact 262, wire 264, normally closed contact 364 of the relay 300 (Fig. 3), resistor 365 , Lower right winding of the transmitter coil R, _go voice wire 366, normally closed contact 367, voice wire 368, normally open contact 468, wire 507, runs over the lower left winding of the transmitter coil R ¹ and the winding of the monitoring relay 536 to battery and earth. This relay responds and causes the subscriber indicator lamp 513 to light up. Since the ground is applied through relay 201 (Fig. 2) to operate relay 536, it can be seen that the moment the calling party hangs up his or her handset, relays 201 and 536 drop out and extinguish the subscriber indicator lamp.

In addition to the various switching processes triggered by relay 401, the observation officer is automatically switched to the connection line via which the call comes. This switch-on circuit runs as follows: From the observed connection line 102 and 103 via the wires 107, 108 and the working contacts 234 and 235, the wires 236 and 237 to the left winding of the transmitter coil R. From the right or secondary winding of the transmitter coil R. Via the wires 318 and 366, the normally closed contacts 316 and 367, the wires 415 and 368 after the left winding of the transformer coil R ¹ . From the right winding of the transmission coil Z? ¹ after the left winding of the transformer coil R ² . From the right winding of the transfer coil R ² over

the contacts of the inquiry switch Κ} on the officer’s receiver.

The various processes that have been described from the going out of a call to the introduction to an observation station, all take place in quick succession when the calling subscriber lifts his receiver from the hook switch. Immediately thereafter, the connection line display goes ahead, and in a few seconds the subscriber usually dials the desired number Answer of the calling subscriber, the notation of the dialed ■ number as it was displayed on the writing register strip, the recording of the 2ol office and the identification of the connection line observed therein and other recordings resulting from the operating mode. After determining that the calling subscriber has reached the called subscriber, the surveillance officer sets the readiness for the next call again by pressing the release button K. In cases where a malfunction or an unplanned occurrence occurs, the existing ones come to lock Connection (hold), for the purpose of speaking, de r signaling and the activation of the search buzzer, the following various measures are in question, which will now be explained:

Connection line display.

The purpose of this feature is to let the officer at the central monitoring station recognize the connection line on which she is carrying out the observation. As described above, the connection lines in the monitored office are indicated by group and individual lamps. When a call has been switched through, the relay 257 is energized via a circuit previously described and produces an energizing circuit for the rotary magnet 303 of the transmitter 5S. This circuit runs from the earthed working contact 258 via the I wire 259, via the springs controlled by armature 301, the break contact 302 and the winding of the magnet 303 to the earthed j battery. The rotary magnet 303 responds and at its contact 304 removes a short circuit across the winding of the relay 305, which now responds and interrupts the excitation circuit of the magnet 303 at its contact I 302. Magnet 303 again shorts relay 305 and switches its switch arms 306, 307 and 308 forward by one step. A circuit is now closed by the grounded switch arm 308 via the upper winding of the relay 325 to the battery and ground. Relay 325 responds and puts the earth of the switching arm 308 in place of the earth of the wire 259 at its contact 301. Relay 325 receives the rotary magnet 303 when working at a speed which is determined by relay 305. It is held by its lower winding, via the normally open contact 309 to earth on the wire 259. The result is that the rotary magnet 303 and relay 305 work alternately until the switching arm 308 comes to the last earthed contact. At contact 323 of relay 325, the excitation circuit of relay 226 is interrupted, so that if this relay should be de-energized by pressing the release button K. (Fig. 5) on the part of the officer, it cannot be excited again as long as the transmitter SS is outside of its rest position. If this arrangement were not made and another connection line ran up to the observation station before the transmitter SS had reached its rest position, an incorrect connection line display would result. In the present case it was assumed that the connecting line introduced was the first connecting line of the first group of the observed office; As soon as the switching arm 307 of the transmitter SS touches its sixth contact, which had previously been grounded by the group relay 251, a circuit is closed by this grounded contact via switching arm 307, the springs controlled by armature 310, the winding of the relay 311 and the resistor 312 after battery and earth. Relay 311 responds and holds itself to earth via the make contact 310 and the make contact 301 on the earthed switch arm 308. Contact 313 prepares a current impulse circuit that goes from make contact 304 to make contact 313, via wire 314, break contact 315, wire 350, Normally open contact 417, wire 418, runs over the springs of the hold button K}, wire 519 and the winding of the impulse relay 520 to the battery and earth. As soon as the magnet responds again, an earth current surge is emitted from its earthed normally open contact 304 via the circuit described above, which results in a jerky excitation of the surge relay 520. This relay causes the delay relay 521 to be switched on, and when relay 520 drops out, a current surge is transmitted via a circuit that runs from the grounded normally closed contact 522 via the normally open contact 523, the normally closed contact 524 and the winding of the magnet 515 to the battery and earth,

so that the switch arms 527 and 536 of the selector T ^{1 are moved} one step. After a short period of time relay 521 drops out and creates a circuit from the grounded switching arm 527 and its associated contact via the normally closed contact 516, via the springs controlled by armature 529 and the upper winding of the relay 517 to the battery and earth. Relay 517 responds and at its contact 524 switches the surge circuit from magnet 515 of switch T ¹ to magnet 532 of switch T ² . Relay 517 places itself at its contact 52g in a holding circuit which is independent of contact 516 of relay 521.

To return to the mode of operation of the transmitter SS, it should be repeated that its switching arms 306, 307 and 308 are on their sixth contacts when the magnet 303 responds to deliver the first current impulse. When the magnet 303 falls, the switching arms 306, 307 and 30.8 are advanced to their seventh contacts. A circuit is now established from grounded contact 335 and through switch arm 306 and resistor 312 to battery and ground. This short-circuits the battery of the relay 311, so that it drops out and removes the impulse wire 314 from the control of the magnet 303 at the contact 313. The next two steps taken by the transmitter SS are to switch the delay relay 521 to. Allow sufficient time to drop after the first surge or the series of pulses delivered to relay 520. As soon as the switch 307 encounters the contact that is connected to the single lamp ο, relay 311 responds again. The further excitation of the magnet 303 now has the effect of delivering a current impulse to the relay 520 via the route described above, which then responds again and excites the relay 521. Relay 520 now transmits a current surge from the grounded normally closed contact 522 via the normally open contacts 523 and 524 and the winding of the magnet 532 to the battery and earth. The switch T ² thereby switches its switch arms 533 and 534 'one step further. As soon as the relay 521 drops out, the indicator lamps ο (Fig. 5) of the group and single lamps light up, whereby the observation officer is given the identification of the connection line under observation. If the connecting line to be observed is the tenth connecting line in the fifth group, the second and tenth contacts of the switching arm 307 have been grounded. With this assumption, relay 311 responds as soon as switching arm 307 reaches its second contact. The magnet 303 can therefore from five current surges to relay 520; give, whereby the switch T ¹ advances its switching arms to the fifth contact. After the fifth current surge, the de-excitation of the magnet 303 causes the switching arm 306 to come into contact again with its grounded contact 33.5. Relay 311 therefore drops out and switches off the impulse wire. The next two free steps leave enough time for relay 521 to drop out and also to carry out the switching process. When the switching arm 307 reaches its tenth contact, relay 311 responds again, and it is important that ten more current impulses are now delivered to relay 520 before relay 311 can drop out again. The switch T ² has then brought its switch arms to their tenth contacts. When relay 521 drops, group lamp 4 and single lamp 9 light up, indicating that connection line 49 is under observation.

Numbers dial record.

As far as Fig. 3 is concerned, it should be remembered that the left winding of the transmitter coil /? via the wires 236 and 237 in a bridge between the observed connecting line by relay 211. A second bridge containing the polarized relay 376 is connected to the center point of the same winding of the transmitter coil /? tied together. This relay has a very high resistance and does not damage the effectiveness of the line or the surge relay 105 of the group selector D. When a calling party pulls his dial to deliver the various bursts of current corresponding to the desired number, the short circuit presented by the intercoms on station A is removed each time the surge springs operate and the polarized relay 376 responds to the dialing surge without disrupting the call in any way. It should be noted that contact 378 of relay 376 is grounded through wire 264 which is connected to ground through some group relay, currently through group relay 251. So it follows that every time armature 378 is attracted a ground current surge is emitted after the write register PR via a circuit which runs from the wire 379 via normally closed contact 380, wire 352, normally open contact 416, wire 437 and the write register PR to battery and earth. It can thus be seen that the write register records every number dialed by the calling party. Another branch of the electricity we just traced

The surge circuit runs through wire 379 after winding the delay relay 371 and to the grounded battery. This relay remains energized during each series of impulses and opens a point in the primary or left winding of the transmitter coil R at its contact 370. This arrangement is made in order to avoid unbearably loud ticking in the observer's receiver; however, she does not suppress the ticking entirely, in order to let the officer recognize that the digits are being dialed.

The holding.

If, because of a malfunction or some unplanned condition, the observer wishes to keep the observed call, she presses the hold key K}. As a result, the relay 280 speaks in the monitored office via a circuit from the grounded wire 502, via the springs of the signal button K ² , the springs of the hold button K} in the switch position, via wire 418, normally open contact 417, wire 350, normally closed contact 315, wire 314, Break contact 313, wire 353 and the winding of relay 280 to battery and earth. Relay 280 creates a circuit from grounded normally open contact 227 through normally open contact 283 and the winding of relay 275 to battery and ground. Relay 275 responds and applies a 100-ohm inductance-free resistor 288 to its contact 286 via the capacitor 372 of the transmitter coil i ?. This creates a loop between the two sides of the connection line under observation, which prevents the release of a completely or partially established connection, but does not interfere with the transmission. This feature is very desirable in certain cases where it is necessary to hold a call while on a call.

The speaking.

Does the observation officer consider it necessary! with a participant or a supervisor | To enter into speech communication, she presses the talk button K ^s . ³ and the microphone D contains. The observation officer can now either j with the calling subscriber or with the call:

speak to inspector. j

The signal circuits. j

If any inadmissible state is a j

occurs, the elimination of which the observation:

civil servant is responsible, the call is initially;

held in the manner just described. ;

If, after pressing the speech button, the observation officer has informed the calling subscriber that he should hang up and call a little later, she calls the supervisor of the remote office by pressing the signal key K ² - If this key is pressed, the previously mentioned one is activated , circuit running after relay 280! temporarily interrupted, which results in the sending of a ground current surge, which runs from the normally closed contact 283 to the normally open contact 284 and via the lower winding of the relay 270 to the grounded battery. This relay is held parallel to resistor 290 and in a bridge to connecting line cores 236 and 237 at its contact 289 and creates a circuit at its contact 291, which starts from the grounded working contact 282 via the working contact 291, the primary winding 248 of the induction coil /, the Wire 349 and buzzer B runs to battery and earth. The buzzer B responds and calls the supervisor. Note that the secondary winding 293 of the induction coil / is connected in series with the resistor 290 and the winding of the relay 270, which lies between the connection line wires 236 and 237, and therefore, when the buzzer is activated, a buzzer tone is fed to the connection line , which indicates to the observer that the supervisor is called. When the supervisor reports by plugging the plug P ¹ (Fig. 3) into the latch / ¹ , they press the button K ^ at the same time. The short-circuiting effect of the supervisor's headset causes relay 270 to drop out, which in turn switches off the buzzer. You can now speak and the fault can be eliminated.

The search buzzer.

When the supervisor has received the message from the observation officer and has verified the connection line buzzer by means of the indicator lamps, it follows the connection to the faulty point. To make this easier for herself, she creates a search number on the connection. This is the same buzzer tone that the surveillance officer uses to indicate that the surveillance officer has received the call. In this case, however, the supervisor switches it on by pressing the unlocked push button K ⁵ . Relay 270 is thereby re-energized and holds through the trunk battery and ground in the same way as before. The supervisor now enters the established connection at the various dial levels without switching off the condenser of her headset. When she finds the spot where she hires the voter

wants to hold, it switches the search buzzer by using the capacitor of its • The headset short-circuits again, disconnects and informs the observation officer at the same time that she has found the fault, so that the connection line is now from the observation station can be solved from.

The trigger.

ίο If the observation officer wants to trigger the connection line connected to her place, she presses the release button K, disconnects the earth from wires 503 and 510, so that the relays 405, 401, 504 and 226 are triggered. Relay 504 removes ground from introductory lamp 514 at its grounded contact 518 and grounds the trip magnets 530 and 534 of switches T ¹ and T-. These magnets respond and bring the relevant switching arms into the rest position. As soon as the switching arms 527 and 533 reach their rest positions, the holding circuit for relay 517 is interrupted and the relay trips. The switch arm 533 also removes the ground from trunk indicator lamps. Relay 401 removes earth from wire 451 when it drops out at its contact 450, thereby causing the office lamp to go out. Relay 226 removes ground from common ground wire 228 when it drops, causing group relay 251 and drop relay 211 to drop. If the calling subscriber still has his receiver in his hand, the relay 201 does not yet drop out. When the officer releases the unlocked trigger button K , she re-establishes a circuit for energizing the relay 226 in the manner previously described, thereby making the circuit ready for the next call.

It should be noted that during the time a connection is observed, each occupied connection line can only excite its associated relay, such as 210, which is of the battery through its two windings in series with the earthed trip wire. the Excitation of this relay causes its corresponding introductory relay to be switched off

220. The connecting lines currently in use can therefore, if Relay 226 responds again, cannot be switched through, which ensures that that only newly emerging calls to the observatory durchgeschaltc: can be. If heavily subdivided telephone systems with an observatory of the described Kind of equipped, it may prove desirable to switch devices to allow two observers to observe at the same time. This is according to the invention together with a novel way of the Equal distribution of incoming calls between two officers achieved. What the As for Fig. 4, relays 401 ', 410' and 405 'and their associated circuits are the same as those shown in the upper half of the drawing, and the line groups F. correspond to wires 509, 503, 507, 506, 437, 418 and 451 and run to the same switching devices as shown in Fig. 5. If so desired If the arrangement is to be adapted for use by two workstations, the distribution wires are 413, 427, 430 and 431 to be replaced by the distribution wires indicated in dotted lines.

Assume now that the two officers are able to observe connecting lines, and also assume that the officer, whose switching devices are shown in Fig. 5, is the first to put her plug P into the latch /, so responds to relay 405 in the manner described above and opens the excitation circuit for relay 405 'at its contact 421, which, as can be seen, can only respond when the second officer puts in her plug and when relay 405 has dropped out. As soon as the connection line to the observation station is switched through and relay 405 has dropped out again, relay 405 'responds and allows a second connection line to be connected. The excitation of the relay 405 'applies the battery to the common wire 423 via wire 420 and distributor wire 422. Circuits go from the common wire 423 via the excitation winding of each office relay 401, 410 to the connecting line wires 308. Such a circuit runs from wire 423 via the normally closed contact 426, distributor wire 432 to the excitation winding of the relay 410 'and via the normally closed contact 468' to the connecting line core 368. Now suppose that the connecting line connected to the first officer originated from the first office, in which case the office relay 401 responded, the excitation winding of the relay 401 ', which, like relay 401, is assigned to the connected office, is switched off. It can be seen that the excitation winding of relay 401 'is switched off at contact 425 in order to prevent the battery from being connected to wire 368 of the occupied connecting line via the winding of relay 401'. As soon as the second officer has received a connection line, relay 405 'drops out, and relay 405 responds again, provided that the first officer is monitoring another connection line.

Claims (7)

tung is ready. It can be seen that the work of the relays 405 and 405 is 'shifting ' and the calls are thereby distributed between two officers as quickly as the connection lines come in. Local observation. With the arrangement described above, where the observation is carried out at a central location by one or two officers, relatively few connecting lines of a single office can be observed in a given time. In certain cases it may be desirable to carry out the observation in one's own office so that the special traffic characteristics of this individual office can be determined more precisely and in less time than would otherwise be possible. so it contains one of the corresponding arrangements of Fig. 5, the same switching device, which can be used together with the arrangement shown in Fig. 2 and 3, with a pawl P, which is inserted into the pawl / ³ (Fig. 3) got to. The isolating relay 300 responds and disconnects the connecting lines running to the central monitoring station. The mode of operation of this switching device is the same as the central device in that it concerns the observing officer, with the exception that no office and connecting line indicator lamps are provided. Since the observation is being carried out at the same office or exchange at which the connection lines are located, the observation officer can use the connection line indicator lamps of this office. The mode of action differs very little from that of the central observation point. The connecting cable entry lamps are ignited in the same way, namely from the common ground line 228 via the normally closed contact 243, the wire 246, the Normally open contact 247, wire 248 and the lead-in lamp to battery and earth. Sponsorship τ claims: i. Circuit arrangement for traffic monitoring in telephone systems with Voter operation and main and sub-exchanges, characterized in that one subject to observation Connection line (107, 108, 109) of a Sub-office is automatically switched through to a centrally located observation point (Fig. 4, 5) when it is occupied. 2. Circuit arrangement according to claim i, characterized by the observation point (Fig. 4, 5) associated locking means (relay 401), which prevent another connecting line from a other sub-exchange is switched through to the observatory. 3. Circuit arrangement according to claim I, characterized in that the Observation center (Fig. 4, 5) with each exchange to be observed (Fig. I, 2, 3) connected by an observation connection line (415, 368, 352, 35Ό) is. 4. Circuit arrangement according to claim 2 and 3, characterized in that that the observer (Fig. 4, 5) assigned blocking means (401) to the sub-exchanges associated blocking means (226, 242, 245) via the observation link (415, 368, 352, 350) 8t> steer. 5. Circuit arrangement according to claim i, characterized in that on two identical workplaces are provided for the observatory, their switching devices (405, 405 ') the incoming calls as a function of one another alternately feed both workstations. 6. Circuit arrangement according to claim i, characterized in that on one of the sub-office (Fig. 1) assigned display device (Fig. 3) to the observation point connected connecting line (107, 108, 109) and on a display device assigned to the main office (Fig. 5) the connecting line (ro7, 108, 109) and the relevant Sub-office (Fig. 1) must be marked. 7. Circuit arrangement according to claim i, characterized in that on the sub-exchange an auxiliary observation station for the purpose of local observation (Fig. 6) is provided, when it is switched on, the sub-exchange is disconnected from the observation connection line leading to the main observation point (by relay 300). For this purpose 2 sheets of drawings.