DE633296C - Remote control and telecommunication device with electromagnetically driven stepping mechanisms to be set in synchronous operation - Google Patents

Description

Remote control and telecommunication device with to be set in synchronous operation, Electromagnetically Driven Stepper Mechanisms The present invention relates to a remote control and signaling device to be set in synchronous operation electromagnetically driven stepping mechanisms, the command and the Signaling circuits via the in-phase set contact arms of the stepping mechanisms get lost. In such remote control systems one has so far of the use apart from any display devices that make the stepping mechanisms equal after completing the selection in the monitoring body to report. It was believed entitled to do so; because with the mutual synchronization of the stepping mechanisms there is a kind of positive control, in which there is generally an end position cannot be reached if the stepping mechanisms fall out of step. so but it has been shown that even with remote control devices with power surges With each step, the direction of the stepping devices is changing Incorrect settings can occur due to the fact that a stepping mechanism suddenly not one step, but two steps behind. In this In this case, the stepping mechanisms are switched on without the surveillance officer the stepping out of step by shutting down the encoder stepping mechanism receives. One could now think of the further switching process of the encoder stepping mechanism to indicate in the monitoring station by lamps, in such a way that each step one another signal lamp is assigned, whereby only that lamp lights up in each case at which the contact arm of the voter is currently located. This arrangement has however, the disadvantage that a reliable indication of the synchronization of the stepping mechanisms cannot be obtained. Another option would be through a special loop circuit over the individual selector contacts of the stepping mechanism of both stations the simultaneous closing and reopening of this circuit to monitor on the individual contacts. However, this arrangement would have the disadvantage that additional lines are required and that a relatively large effort at switching means is required. On the other hand, of course, is that use of acoustically acting devices, such as telephones, for example, extraordinary undesirable, dä-eiririial with an acoustic. error, for example when = counting feedback pulses, can occur, and on the other hand therefore, because the surveillance officer is bound to a specific whereabouts is what of course in larger switchgear a quite undesirable condition would mean.

Although it has already been suggested in the literature, an acoustic To use feedback of the position of the set rotary selector in remote control systems, where <read the hearing and speaking device of the normal telephone set for feedback the selection made and the position of remote-controlled switches. Since in this known device the pulses simply with a number or Dial can be given here at any time via a line Occurring glitch a wrong selection take place, of course, if any possible to avoid. On the other hand, this known facility is at the donor location there is only one number disc table apparatus and it therefore remains for the determination a correct setting of the receiving stepping mechanism no other choice than to monitor this acoustically, this known arrangement makes use of previously mentioned as disadvantageous pulse rate method, with a two-digit Number of participants the individual impulses of each point through the pitch of two tone generators, for example a buzzer and a horn. There the dial is already withdrawn to its rest position at the end of the election, so is at this well-known establishment of the surveillance officers exclusively on his memory instructed regarding the call feedback: Since also the surveillance officer in this If the number of impulses has to count for each digit, they are repeated in spite of them Call feedback, false releases cannot be avoided.

According to the present invention, however, is a remote control device created that does not have these disadvantages, i.e. at the time the command is executed the absolute setting of the Geberlind receiver stepping mechanism with each other can be compared. F-in another advantage of the arrangement according to the present Invention over the known arrangements is that each digit is one The decimal position of a participant number can be identified by a different optical symbol is done, whereby the annoying counting of feedback pulses is avoided. Allows this is because according to the invention that a remote control device @ ° üit electrical @: niagnetically driven stepping switch to be set in synchronous operation - "'keh, the command and signaling circuits via the contact arms set in phase These switching mechanisms run, is designed so that to enable an optical Indication of the achieved setting of the stepping devices via a remote line Alternating currents are sent in such a way that each through bank contacts of the stepping mechanisms simulated digit of a decimal place of a one-digit or multi-digit subscriber number a particular AC frequency is assigned, and that one on the different frequencies dependent only on the positions of the step-by-step switching mechanism of the outstations Responding measuring device repeats the values of the individual decimal places one after the other brings to the display. In addition to the aforementioned advantages, it is used for remote control devices with step-by-step control units that progress in synchronous operation still have the essential advantage achieved that it is the surveillance officer when the giver and receiver stepping mechanism falls out of step is made possible to determine which of the two stepping mechanisms remained behind is. This enables the surveillance officer to identify any occurrences from the outset Localizing circuit faults in the overall system, which is common to all Facilities with synchronously controlled stepping mechanisms is not possible and therefore no meaning for remote control devices with number disk impulses because you cannot determine how much after the dial has expired Pulses the dial really sent out.

An exemplary embodiment of the invention is shown schematically in the drawing shown. Fig. I shows an embodiment of the invention and Fig. Z a Detail of the circuit shown in Fig. I.

In the lower part of Fig. I, the details of a remote control system are shown as far as is necessary for an understanding of the invention. This system drops a selector A in the monitoring station and a selector A 'in the remote control station. Each of the voters has several contact banks. with the associated switching arms s, n, i and e. These selectors are connected to one another by four lines s', i, c 'and g' which run between the stations. The line s' contains a pair of polarized relays p and -p ', one of which is arranged in each station and which are used to synchronize the selectors A and A' . The line c ', which connects the switching arms of the contact banks c of the selector A and A' , is used to transmit yaw current surges, by which switching operations are triggered in the remote station. The line i, which connects the switching arms of the contact banks of the two selectors with one another, is used to transmit current surges through which the display device in the monitoring station is controlled. The line g 'is a common return or earth line for all circuits between the two stations.

It is assumed to explain the invention that the official in of the monitoring station A switch 1q. wants to control in the substation A '. For this purpose it first interrupts the switch 14 that is to be remotely controlled Contacts lq. ' of the selector switch and then closes the contacts of the starter switch k. This makes the selector A of the monitoring station and the selector A 'of the substation switched on synchronously in a known manner by means of the polarized relays p and p ', until they get through the contact i4. ' second working position marked on the selector switch achieved; then the selector A 'in the substation is on the one to be controlled Switch lq. set. For monitoring important switches, where a erroneous operation causes major damage to the system or an interruption of the operation, it is desirable that the official in the The monitoring station also receives a display of the positions of selector A and that tile display regardless of the position of nasty voter A and any other Elenientes of the facility is minimizing the possibility of error is reduced.

According to the present invention, this display is made using the im upper part of the drawing device shown, which with a simple Vibration frequency meter 13 cooperates in the monitoring station, accomplished. This device comprises a transmitter with several vibration generators i 'to io', which are arranged in a known manner, for example in the manner shown in Figure 2, can order interconnected tuning forks. These vibrators cause 38 alternating currents of different frequencies in their output windings: These windings are connected in parallel and arranged so that they carry the alternating current Apply via the capacitors 21 to the lines c 'and i. In the monitoring station the frequency meter 13 is connected to these lines via the capacitors 22: so that it is based on the frequency of the generated by any of the vibrators i 'bis io 'generated electricity. Of course, if necessary, suitable amplifier means in that from the windings 38 to the frequency meter 13 running circuit must be switched on.

There are several selection relays to control the vibration generator i 'to io' S provided, each of which corresponds to a position -of the selector A 'and energizes is when the voter A 'occupies the associated position. On the wave of the voter A 'an additional switching arm is provided, which runs over a contact bank t, of which each contact in the circuit of one of the relays S is arranged. each of the Selection relay has one or more contacts, each of which is in the excitation circuit one of the tuning fork generators is arranged. These current circuits are periodic closed by means of a rotary selector i9, which is described below.

In the form shown, the rotary selector i9 consists of a selector of the same type as the selector A and A ', and it has three switching arms B, C.' and D. The arm D is used to control the excitation circuits of the tuning forks. The switching arms B and C, in cooperation with the relays to be described later, represent the switching device for the rotary selector.

Assume that the voters A and A 'in the above-described manner in the second. Working position have been switched. If one of the selectors A or A ' leaves his rest position, a circuit is interrupted, which starts from the negative pole of the battery 15 via the rest position contact and the switching arm of contact bank c of selector A, line c', switching arm and rest position contact of contact bank c of selector A. ', the winding of the relay 2o to the positive terminal of the battery i 5' runs. The relay 2o is de-energized as a result, and it closes its contact by means of the armature. This closes the drive circuit for the rotary selector i9, and the switching arm D then briefly closes each of the excitation circuits of the tuning forks, which have been selected by the selection relay S, in such a way that the frequency meter in the monitoring station in resonance with the frequency or frequencies of the transmitted currents vibrates and thereby indicates the position of the remote-controlled selector.

When the relay 2o is de-energized, the following circuit is closed: positive pole of battery 23, _contact of relay 2o, switching arm C in the normal position, winding of relay 24, lower contact of relay 25, negative pole of battery 23. Relay a4 responds and applies here the rotary magnet 26 shunted to its winding. The rotary magnet 26 turns its armature. This interrupts his own circuit and at the same time switches the switch arms B, C, D clockwise to the first contact. The first contact of the contact banks occupied by the cooperating switch arms B and C are both connected with the same polarity as the rest position contacts of these contact banks, and as a result the rotary magnet 26 is again excited and the switch arms B, C, D are switched to the second contact. In this position, the relay 24 is short-circuited via the switching arm C and the second contact of the associated contact bank, which is connected to the same pole of the battery as the other end of the coil of the relay 24. After a certain time, the relay drops out and thereby closes a circuit that starts from the zero point of the battery 23 via the right resting body cycle of the relay 24, the winding of the polarized relay a5, the switching arm B and the second contact of the associated contact bank to the negative pole of the Battery 23 runs. The polarized relay 25 then moves its armature to the upper position and thereby switches one side of the winding of the relay 24 from the negative pole of the battery 23 and to the positive pole of the battery 23. The relay 24 is then energized again, and as a result it leads to the further excitation of the rotary magnet 26 and the switching of the switching arms B, C and D to the third contact of the associated contact banks. When the switching arm C is switched from the second to the third contact, it switches one terminal of the relay 24 from the negative pole of the battery 23 to the positive pole of this battery, whereby this relay is again short-circuited and brought to waste. Its anchors are returned to the right position after a certain period of time. and again a circuit for the relay 25 is closed. However, since the switching arm B is now on the third contact, the polarity of the current in the relay 25 is reversed, and the relay puts its armature back into the position shown. Since the contacts of the contact banks overflowing from the switching arms.B, C are alternately connected to points of opposite polarity, these switching operations are repeated as long as the contact of the relay 2 0 is closed; that is, as long as the selectors A and A 'are in a working position, the switching arms B, C and D are continuously switched on via their associated contact banks.

Since in the present case the selector A 'is in its second working position, the following circuit is closed for the winding of the relay S2: Negative pole of the battery 23, switching arm and second contact of the contact bank t, winding of the relay S2, line 27, zero point of the battery 23. The relay S2 controls an excitation circuit for the vibration generator 2 '. This circuit extends from the negative terminal of the battery 23, the conduit 28, the vibration generator 2 ', the contact of relay S2, the contacts 29 and 3o the overflowing of the shifting arm D contact bank selector 1 9 and the line 27 to the zero point of the battery 23 Therefore, if the switching arm D occupies either the contact 29 or the contact 30, the excitation circuit for the vibrator 2 'is closed and an alternating current is applied to the frequency meter 13, the frequency of which is determined by the generator 2' and to which the corresponding vibrating tongue 2 of the frequency meter 13 responds. This indicates to the official that voter A 'is in the second working position.

Assume that voter A 'has been set to the twelfth contact. The switching operations are the same as those described above, with the exception that the relay S12 is excited via the twelfth normally open contact of the contact bank t. This relay controls two excitation circuits; firstly that for generator i 'and secondly that for generator 2'. The circuit for the generator i 'contains the left contact of the relay S12 and the contacts 29 and 3o of the shifting of the selector D 1 9 associated contact bank. The excitation circuit for the generator 2 'contains the right contact of the relay S12 and the contacts 3 i and 32 of the contact bank belonging to the switch arm D. Therefore, when the switching arm D first runs over the contact 29, the generator i 'is activated and then the generator 2' is activated when the contact 31 is overrun. There is then a pause during which no generator is energized. The switching arm then runs over the contact 30 and excites the generator i '. Then the contact 32 is overrun and. the generator 2 'is energized. The officer in the monitoring station noticed when observing the frequency meter 13 that the contact spring i and the contact tongue 2 are actuated in quicker succession and that afterwards an interruption takes place, after which the actuation of the contact reeds i and 2 is repeated again in quick succession. It is thus indicated to him that voter A 'is on the twelfth contact.

Assume now that voter A 'places on the twenty-first contact. The relay 2i is excited and thereby the excitation circuits for the generators i 'and 2' are closed again. In this case, however, the excitation circuit of the generator 2 'is connected to the contacts 29 and 30 via the left contact of the relay 21 and the excitation circuit of the generator i' is connected to the contacts 31 and 32 via the right contact of the relay 2i. In this case, therefore, when the selector D rotates, first the vibrating tongue 2 and then in quick succession the vibrating tongue i are made to respond, whereupon an interruption takes place. The repeated speaking of these tongues in the order 2, i indicates to the official that voter A 'is on the twenty-first contact.

Assume that voter A 'is on the twenty-second contact. Then the relay S i is energized. This relay connects the excitation circuit of generator 2 'via its left contact to contacts 29 and 30 and via its right contact to contacts 31 and 32. When the rotary selector D is running, the @' ibrationszuiige 2 is therefore operated twice in quick succession, and thereafter an interruption occurs. This announcement is repeated over and over, indicating to the officer that voter A 'is on the twenty-second contact. It is eisichtlich that this ad is different from that when the voter A 'is on the second contact, there are less likely to vibrate in this case the tongue? In about equal intervals and.

It should be noted that each relay S is designed as a delay relay is. The time delay of these relays is such that they do not respond when the switching arm of the contact bank t quickly from the rest position to any working position is switched on, but only respond when this switching arm finally opens a chosen contact comes to rest.

It can be seen that each group created by your transmitter of alternating current surges contains as many current surges as there are digits in the position of the voter A 'corresponding number are included. When in the remote controlled Station several voters are used, the position of the voters can be displayed Numbers contain more than two digits. These positions can of course by using so many armatures on the selector relay S, - provided as positions are, and by an equal number of contact sets in groups 29, 31 and 30, 32 are displayed. It may be desirable that, if a large number of positions is to be displayed, during each cycle of the selector D only one group is transmitted by pulses, d. h .. that one of the contact groups 29, 31 and 30, 32 comes to an end. In any case, the break between the groups must be longer than the pause between two electric surges in a group. In this way the power surges are clearly divided into different groups, which are easy can be read as position numbers on the frequency meters 13.

Of course, the speed at which the rotary selector moves D rotates, can be set by changing the time delay of the relay 24. Furthermore, the duration of each alternating current surge as well as the duration of the pause between successive power surges by changing the number of contacts in each Contact set and by suitable spacing of the contacts or the contact sets 29 and 30 and 3o and 31 can be set in the contact banks.

In Fig. 2 the circuit of a tuning fork vibration generator is shown. This arrangement is known per se, and it comprises an excitation coil 33 which is shunted to the battery terminals 301. When this coil is energized, is a change in the over of the one lying on the terminal 3.4 of the pole Battery, the adjustment knob 35, the primary winding of the transformer 36 to the other Pole of battery running current called. This change in current in the transformer 36 calls a current in the loop circuit 3-; come here, which in turn the tuning fork is influenced in such a way that it continues to vibrate, and consequently becomes an alternating current is generated in the output circuit 38.

It goes without saying that instead of the tuning fork, other vibration generators can kick. For example, the vibration generator i 'to io' by a single vibration generator, for example an electrode tube, 'be replaced, wherein the frequency determination circuits running over the contacts of the relay S and the switching arm D. for example with short-circuit parts of the inductance of the tuned circuit of the generator can be connected and thereby the frequency of the generated vibrations can be changed. In this case the oscillator would work for usually vibrate at a frequency to which the frequency meter r 3 does not respond.

Claims (1)

PATENT CLAIMS: i. Remote control and telecommunication device with electromagnetically driven stepping mechanisms to be set in synchronous operation, the command and signaling circuits running over the contact arms of these switching mechanisms, which are set in phase. characterized in that, to enable a visual display of the achieved setting of the stepping mechanisms in the branch office, alternating currents are sent over a long-distance line in such a way that each digit reproduced by bank contacts of the stepping mechanisms. a decimal place of a one- or multi-digit subscriber number is assigned a certain alternating current frequency of a frequency generator located in the external unit and that a measuring device that responds differently to the different frequencies in the monitoring station repeatedly displays the values of the individual decimal places one after the other. ?. Circuit arrangement according to Claim i, characterized in that a frequency meter (i3) known per se with vibrating tongues is used to display the selector positions in the monitoring station (A). 3. Circuit arrangement according to claim i, characterized in that the frequency display device and also the frequency generating device are connected in branches (on the capacitors 21, 22) from the connecting lines (ä, c ') provided for other purposes between the two stations. q .. Circuit arrangement according to Claims i to 3, characterized in that a special vibration generator (33 to 38) is provided for each digit. 5. Circuit arrangement according to claim i to q., Characterized in that the selector in the remote-controlled station (A ') has an additional contact bank (t), to the contacts of which relays (z. B. S21) are connected, which when they are actuated Prepare the excitation circuit of the vibration generator for those frequencies that correspond to the digits of the respective voter position number. 6. Circuit arrangement according to claim i to 5, characterized in that the excitation circuits for the vibration generator (i 'to io') are alternately closed and opened via a stepping mechanism (B, C, D). 7. Circuit arrangement according to claim i to 6, characterized in that in the selector positions which correspond to a multi-digit number, the excitation circuits for the vibration generator (i 'to io') are connected to contacts of the relays (S "to S22) and the stepping mechanism ( B, C, D) are connected so that when the stepping mechanism rotates there is a short pause between the individual digits of the number and a longer pause between each repetition of the number Stepping mechanism (B, C, D) delay relays are provided for the purpose of making the running speed of the stepping mechanism and thus the pause between the digits and numbers adjustable. the voting of which is changed according to the position of the voters of the remote control station.