DE907386C - Circuit arrangement for remote control systems - Google Patents

Description

Circuit arrangement for remote control systems The invention relates to a Circuit arrangement for remote control systems with a variety of batteryless, on one Connecting line in series arranged branch points to which switching means are assigned are that when influenced by the control or monitoring point from the Switch through the connection line to the next branching point. The invention is based on the task of having such a circuit arrangement in each of the branch points to carry out two switching operations one after the other.

It is assumed that the connecting lines are very long of, for example, over zoo km in length and thus the last junctions are at a great distance from the control or monitoring point. As a result of the with the distance increasing voltage drop are the known arrangements, at those in the branch points the through-switch relays in bridge to the two wires of the connection line remain switched on, not usable unless that a high voltage is used in the control unit. The previously known arrangements of this type are also used for systems in which switching operations are carried out continuously one after the other must be carried out at all branch points, because of the after switching existing circuits for the switching relay and the associated Power consumption uneconomical.

The invention shows an arrangement that can be used with low power requirements in a simple and reliable manner, at the branch points a very long connecting line one after the other each two switching operations perform. You achieve this in that in each branch to implementation two consecutive switching processes two influenced via the connecting line, Direction-dependent relays are provided with one winding end Earth are connected and one of which is grounded at one pole, the other responds when the other pole of the unearthed battery of the monitoring station is grounded, and that a relay is also assigned to each branch point, depending on from the response of the relay controlling the second switching process with disconnection of the two relays from the connecting line, the latter to the next branching point switches through.

Further features of the invention are that shown in the drawing Refer to the exemplary embodiment.

Apparatus B i to B 28 and bi to Ö28 located in receivers E i to E 28, for example, are to be operated one after the other from a transmitter G via the common lines L i, L 2, L 3. The retirement of the plant is then to be restored. During operation, the respective recipient reached and the operation of his devices should be displayed in the transmitter.

The encoder has an indexing mechanism with the drive magnet D and the switching arms a and b. The lamps KL i to KL 28 identify the receivers, the lamps BL and ÖL the relays B and Ö in the receivers. The lamp ÜL indicates by its flickering that the system is energized and the contact K is in motion. The latter is, for example, a clockwork with a contactor whose current closures and interruptions after actuation of the switch "On" and response of the relay E cause all receivers with their devices to be connected to the common connection line one after the other.

A relay chain with the relays P i to P 4 ensures in connection with the relay chain of the relays H i to H4 that the relays B and Ö of two consecutive receivers in the correct order and without one of these relays being omitted, one after the other to the connecting cable outgoing from the encoder can be switched on and operated. Since a relay H responds every time contact is made by the contact system K and a relay P responds every time each relay B or Ö is actuated, in the order Hi with Pi, HZ with P2, etc., the actuation of both relay chains moves forward evenly until all four sets of the two neighboring receivers have responded. Once this is done, both relay chains return to their rest position and perform the same task with the relays B, Ö and Pol of the next two receivers. If, in the event of a fault caused by a line break or poor contact, e.g. B. from b 21, the relay P 3, which should be actuated via this contact, does not pick up, since the relay H3, which otherwise responds at the same time with P 3, has picked up, via the h 3V contact through the intermediary of a relay W that Alarm signal AL and Schn triggered, which draws attention to the malfunction. Furthermore, since the reception control is shut down at the same time and the disturbed receiver and its apparatus are indicated by the lamp signaling in the transmitter KL and BL or ÖL, which indicates the progress of the receiver operations, the error can be rectified easily and quickly. The mentioned safety measure for the correct adherence to the sequence in the apparatus actuation is increased significantly that the first relay, z. B. B i and B 2, from two neighboring receivers control their respective relays P i and P 3 of the relay chain with opposite polarity, so that it can not happen that, for. B. in the event of a fault in the holding contact of the relay P i, this relay can be made to respond not only by B: i of the first receiver but also by B ?, of the second receiver.

Since this ensures the correct sequence of operation of the apparatus, there is also a guarantee that after the second relay Ö of a receiver has responded, the switching of the receiver line, which is effected by means of a polarized relay pole , from the receiver being controlled to the next receiver to be operated will work properly he follows.

A particular advantage of the subject matter of the invention should be pointed out: the actuation battery in the transmitter is not grounded when the system is in the rest position. The relays B and Ö of the receiver are connected to earth. As soon as one of these devices is excited, its earth receives the pole that results from the device's excitation circuit. So z. B. B i, which was excited with the positive pole of the battery, the negative pole on its earth. This negative pole is now used to excite P i, which is connected to the positive pole. This change of polarity is only possible because all receivers operate only one device B or Ö of a receiver at the same time. This has a very favorable effect on the resetting of the polarized relay pole i to pole 28 , so this has the low resistance to earth at one end of the winding, while at the other end of the winding by connecting the lines L ?, and L 3 in parallel through s VI and z for the time it is reset, the line resistance is reduced to half the resistance of a line. This ensures that the polarized relay Pol, which are all reset at the same time, respond with certainty.

The following description of the operating processes is intended to explain the concept of the invention in more detail. After the switch "On" has been switched on and the relay E has been activated, the following current processes develop during the current closures and interruptions of the contactor K I. Contact closure via K i. Relays A and UR receive response current via K, wV and A '.

2. Lamp @ 1L lights up via contact iiy. Since ÜR is only operated as a function of K and independently of E and: consequently ÜL flickers, no special reference is made to UR and irTL in the following. 3. Relay A i picks up via a III and resistor Wi i.

4. Relay B i in the first receiver is actuated by the battery current from the positive pole via a IV, xi IV, s I, line L i, ö i II, pole i, resistor Wi 2, rectifier Gr i, winding Bi, earth, x i VI, aV to the negative pole. B i closes its contacts b i IV, bi VI in order to switch on high-voltage contactors and the like or measuring lines, the measured values of which are transmitted to the transmitter via special lines, not shown here.

5. Relay An speaks to via a VI and resistance Wi 3.

6. Relay H i picks up over Wi 4, e VI, a II, t III, h i I, pi I and holds over h i I, t III, a i I, e VI and Wi 4.

7. Relay P i receives response current from the positive pole via P i, rü III, P i II, h i II, an III, t II, rü I, line L 2, b 1 1, resistance Wi 5, earth, x iVI, aV to the negative pole. It holds up above yii III, P i II and resistance Wi 6.

B. Relay A 2 is excited via a i V.

G. Relay An drops out due to a short circuit across a 2I. The switching arms a and b of the transmitter selector are on contact i.

ok KL i, the identification lamp KL i for the first receiver lights up via eII and the switching arm b to contact i.

ii. BL, the identification lamp BL for relay B lights up via y I, e IV and a i VI. BL in connection with KZ i indicates that the relay B i, that is, has been actuated in the first receiver. The following changes take place due to the following interruption of contact in K.

12. Relays A, ÜR are switched off by K. 13. Relay Bi drops by interruption via a IV. 14. Relay A i is short-circuited by aIII and falls behind.

15. Relay H i is caused to drop out by a i I.

16. Relay Y responds via a 2III, w I, a III and resistance Wi i, because A 2 is still energized as a drop-out delay relay.

17. Relay X picks up via s III, e I, vV, y II, windings X and Y1 and resistor Wi7.

18. Relay X i receives response current via t I and xVI. The receiver line Li and earth are polarized by relay X i.

i9. Relay A 2 is switched off by a i V and drops out with a delay.

2o. Relay Y drops due to an interruption via a2111. 21. Relay Y pulls on, after the short circuit of the winding YII has been canceled by vV, via sIII, eI, winding YII, contact xIV, winding X, winding YI, and resistor Wi7.

22. BL is switched off by a i VI and y I. IL Contact closure via K: Relays A and A i pick up (see 1 1 and 1 3) 23. Relay Ö i receives response current from the negative pole via aV, xi IV, s I, line L i, ö i II, pole i, Resistance like, rectifier Gr2, winding Ö i, earth, x i VI, a IV to the positive pole. It persists over Wi 2, ö i II, line L i, s I, xi IV, aV. Ö i closes special circuits via its contacts ö i IV and ö i V1 like B i. Relay on responds (see I5).

24. Relay H2 picks up via Wi4, eVI, aII, tIII, h i I, pi I, k2 I and p 2. It is held via h 2I, PII, hiI, tIII, aiI, eVI and Wi4.

25. The polarized relays P2 and Pol i receive their response current in series from positive earth via winding Pol i, Wi 8, ö i I, line L 2, rü I, t II, an III, h2II, winding P2, yüV and Tig to the negative pole. Relay A 2 responds (see I8). Relay on (see I9).

26. OIL lights up above y I, e IV and a i VI and, in conjunction with KZ i, identifies the apparatus Ö i. The following break in contact in K results in current changes described below. Relay A drops out (see I12).

27. Relay Ö i drops due to interruption of a V and a IV. Relay A i falls back (see I14).

28. Relay H 2 is caused to drop out by a i I. Relay V picks up (see I16).

29. Relay X drops out due to a short circuit across v V and yII, while relay Y still holds via winding YI. 30. Relay Xi drops through xVI.

31. Selector magnet D receives response current and via xII, yVI and wIII switches his arms a and b from contacts i to contact l = e 2. Relay A 2 and Y fall (see I ig and 12o).

32. Relay Y drops due to the interruption of the current flow via YI via vV. As a result, the selector magnet D is de-energized.

33. KL2, the identification lamp KI. 2 for the second receiver lights up via eII and switch arm b on contact 2. KL i has gone out.

34. The OIL lamp is switched off by a i VI. The connection line L i is switched from the first receiver and switched to the second receiver by Pol =. III. Contact closure via K: Relays A and AI pick up (see I i and 1 3) 35. Relay B2 in the second receiver receives response current from the positive pole via a IV, xi IV, s I, line L i, ö i II, pole i , ö 21I, Pole, Wi 2, rectifier Gr i, winding B 2, earth, x i VI, a V to the negative pole. Relay on picks up (see I5).

36. Relay H3 picks up over 14'i 4, e VI, a II, t III, h II, PII, h 2I, P2, h31 and P 3. It holds up over h31, P2, h21, PII, hII, tIII, aiI, eVI and Wi4.

37. The polarized relay P3 receives response current from the positive pole via a IV, x i IV, s I, line L i, ö i II, pole i, ö 21I, pole ?, resistor Wi 2, rectifier Gr3, resistor Wi 5 , b 2I, line L2, yü I, tII, anIII, h311, winding P3, rüV, resistance Wig to the negative pole. Relay A 2 responds (see I8). Relay on (see I9). The BL lamp lights up (see I ii). The KZ 2 lamp lights up (see 1133).

Contact interruption via K: Relay A drops out (see 112) 38. Relay B 2 drops through a IV. Relay A i drops (see 114).

39. Relay H3 drops through ai I. Relay V picks up (see 116). Relays X and X i pick up (see I I7 and I i8). Relays A 2 and V drop (see I zg and 1: 2o). Relay Y picks up (see I21). The BL lamp goes out (see I22).

IV. Contact closure via K: Relays A and A i pick up (see I i and 1 3) 40. Relay Ö 2 receives response current from the negative pole via aV, xi IV, s I after the polarity of the line L i has been reversed by relay X i , Line L i, ö i II, pole i, ö 2I1, poles, resistance Wie, rectifier Gr2, winding Ö 2, earth, xi VI, a IV to the positive pole. It persists over Gy 2, Wi 2, ö 2 I, Pol i, ö i II, line L i, sl, xiIV, aV. Relay on responds (see I5).

41. Relay H4 picks up via Wi4, eVI, a11, tIII, h II, PII, h21, P2, h31, P3, h41 and P4.

42. The polarized relays P 4 and poles receive their response current in series from plus via aIV, xi VI, earth, winding Pole, Wi 8, ö 2I, line L2, yiiI, t11, anIII, h411, winding P4, rüV, Wi9 to the negative pole. Relay A 2 responds (see 18). Relay Ait drops (see I9). The OIL lamp lights up (see I126). Lamp KL2 lights up (see I133).

Contact interruption via K: Relay A drops out (see I12).

43. Relay Ö 2 drops through a V. Relay A i drops (see 114). 44. Relay H q. drops through a i I. Relay V picks up (see 116).

45. Relay R Ü picks up via v Il, a i I, t III, h i I, PII, h2I, P2, h3I, P3, h4I, P4, h4IIIundsII. 46. P i falls back through yii III.

47. P2, P 3 and P4 receive current in the opposite direction via rii IV and yii V and return their armatures to their original rest position. Relay R LT is switched off by P i I, p: z, p 3 and P 4 from the positive feed. Relays X and X i drop (see 1129 and 1130).

48. Voter magnet D switches its arms to contacts 3rd relay A 2 and V fall (see I 1g and I 2o). 49. Relay Y drops (see I132).

5o. KZ 3 lights up to indicate the third recipient. KL 2 has gone out. OIL has gone out (see I134). The connecting line L i is disconnected from the first and second receivers via pol i and po12 and switched to the third receiver. After the relays P i to P 4 have been reset by R Ü, both relay chains with the relays H and P are back in their starting position, from which they switch on the relays B 3, Ö 3, B 4 and Ö 4 of the third and monitor and regulate the fourth recipient. This is repeated until the relay O28 has been switched on in the last, for example 28th receiver, by closing the contact. If, during the subsequent power interruption, relay Y responds briefly and causes relay X to drop back earlier than relay Y , then selector D is switched one step forward (see I131), and its arms a and b reach contacts 29.

51. Relay T picks up via eII and switching arm b on contact 29.

52. Lamp KZ 29 lights up above t VI. Relays A, A i and A 2 have dropped out (see 112, 114 and I19). The OIL lamp has gone out (see I134). The next time the contact closes via K, the following current processes develop: Relays A, A i, An and A 2 are activated (see I1, 13, 15, 1 8 and I9). The relays H and P of the two relay chains are switched off by tII and tIII.

53. Relay Z receives response current from the positive pole via a IV, xi IV, s I, line L i via the contacts ö and pole of all receivers and its winding Z to negative earth, lamp BL lights up (see I11). Contact interruption via K When relays A, A i, A 2 drop out, relay V is briefly energized, causing relays X, X i and Y to respond (see 112, 114, 116, 117, 118, I19, 12o; I21). The BL lamp goes out (see I22). The next contact closure via K causes the following: Relays A, A z, An, A 2, T and Z are activated (see 11, 13, 15, 18, 19, 1V51 and 1V53). Relay Y remains energized (see I129). Lamps KZ 29 and OIL light up (see 1V52 and 11 26). The following interruption of contact via K resets all receivers to their rest position: Relays A, A i, A 2, Y drop back (see 112, 114, I 19 and I132). As a result of the brief response of Y and the fact that X falls behind rather than Y, the selector II is switched forward again by one step, so that its switching arms a and b come into contact with contacts 30.

54. Relay S responds via eII and switch arm b to contact 30. Via its contact s V it connects the windings of S and T in parallel, so that the latter remains attracted.

55. Lamp KL3o lights up above IV.

56. Selector D runs over his self-interrupter b, the switching arm a and the contact s IV in the Stellüngi. Lamps KZ 3o and OIL have expired. The lines L 2 and L 3 are connected in parallel via the contacts s V1 and z. The polarized relays Pole i, Pole , etc. to pole 28 receive current from the positive pole to negative earth, ie from the opposite direction, speak to and apply via the contact s VI and the contacts ö i I, ö 2 1 etc. to ö 281 their contacts Pol i, po12 etc. to Pol28 return to their starting position. If the contact is continued via K, the first recipient is then controlled first. Fault message In the event of a contact fault in line L2 or in a receiver, e.g. B. in contact bi 1, the associated relay P can not respond. Since the contact P i I is not switched over, but the relay H i is picked up via ai I, the 1st winding of the relay W via Wi 4, e VI, a II, t III, h II, PII, h i V , yii II and an II excited. Relay W continues with its second winding via eIII and wII. The Schnarrer Schn and the lamp AL are activated as alarm signals via wIV and wVI. Since the progression of the voter has been prevented by w III, the KZ lamp can easily be used to determine which receiver was activated when the fault occurred. The Schnarrer Schrt can be switched off using the Tr switch. Once the fault has been eliminated, the system must be brought to the zero position before it can be put back into operation.

By moving the switch R it becomes relay S and via sV the relay T actuated (see IV54) -The selector D then moves to its zero position (see IV56). This is indicated by the lighting up of the lamp KI_z.

Claims (7)

PATENT CLAIMS: i. Circuit arrangement for remote control systems with a multitude of batteryless branch points arranged in series on a connecting line, to which switching means are assigned which, when they are influenced by the control or monitoring point, switch through the connecting line to the next branch point, characterized in that in each branch point for carrying out two successive switching operations two current-direction-dependent relays (B, Ö) are provided which are influenced by the connecting line and which are connected to earth at one end of the winding and of which one (e.g. Bi) when one pole is earthed (positive pole), the other ( E.g. Ö i) responds when the other pole (negative pole) of the unearthed battery of the monitoring point is grounded, and that a relay (pole i to pole 28) is also assigned to each branch point that, depending on the response of the relay controlling the second switching process (Ö ) with disconnection of the two relays (B, Ö) from the conn connection line connects the latter to the next branching point. 2. Circuit arrangement according to claim i, characterized in that control devices (K, A, X) of the monitoring point automatically bring about the two remote control or measuring processes and the switching of the connecting line one after the other at all branch points of the connecting line. 3. Circuit arrangement according to claim i, characterized in that the response of the remote control or switching means (B, Ö) controlling remote measurement processes in the branch points through contacts (b I, ö I) the switching means is reported back to the monitoring point. 4. Circuit arrangement according to claim i to 3, characterized in that the circuits controlled by the feedback contacts (b i I, b 2I, etc.) alternate in their polarity in the successive branch points. 5. Circuit arrangement according to claim 3 and 4, characterized in that the feedback contacts (b I, ö I) switching means (P i to P4) control the monitoring point, which in cooperation with other switching means (H i to H4, M further switching operations to the Prevent branch points if there is a fault, e.g. in the cables or contacts. 6. Circuit arrangement according to claims 3 to 5, characterized in that the switching means for monitoring of the feedback consist of relay chains (Pi to P4, Hi to H4) that contain the feedback monitor the four switching processes of two consecutive branch points and then to monitor the same switching processes of the next two branch points come into effect again. 7. Circuit arrangement according to claim i and 2, characterized in that control devices (A, V, X, Y) of the monitoring point control a selector (D) for switching on the signal circuits assigned to the branch points (KZ z, -KZ 2 etc.).