FI61113C - FOERFARANDE FOER STYRNING PERIPERA APPARATER I EN FJAERRKOMMUNIKATIONSANLAEGGNING MEDELST TVAO ELLER FLERA STYRANORDNINGAR - Google Patents

Description

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JgfijB IBJ (11) UTLAGG NINGSSKRI FT ° '' ° • c («) Patent granted 10 05 1932 pQy / Fatent meddelat ^ (51) Kv.lk./lnt.CI. H 04 Q 3/54 ENGLISH I - FI N LAN D (21) P »Mnttih» k «rmi * -l * Mnttn« öki »nf 751392 pi) H« k «ml $ pllvl— AnsAknlnpdtg 13-05-75 (23) Alkuplivi— Giltifhetsdtf 13-05-75 (41) Tullut lulklMksI —Bllvitoffwitllg 23-02-76

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Switzerland-Switzerland (CH) 11U80 / 7 ^ (71) Siemens-Albis Aktiengesellschaft, Albisriederstrasse 2 ^ 5, CH-80U7 Zurich, Switzerland-Switzerland (CH) (72) Gerhard Wolfer, Oberengstringen, Switzerland-Switzerland (CH) (7) ^) Oy Kolster Ab (5 ^) Method for controlling peripheral equipment in a remote information system by means of two or more control devices - Förfarande för styrning peripherera apparater i en fjärrkommunikationsanläggning medelst tva eller flera styranordningar

The present invention relates to a method for controlling peripheral devices in a remote communication device, in particular a centrally controlled remote communication relay device, by means of two or more identical control devices.

For safety reasons, it is customary to equip the control devices required for controlling remote information systems in multiples, so that one control device is always in use and the others are ready for use. The control device then operates until the monitoring device higher than all control devices detects a fault in the control device in use, switches it off and puts the other control device in operation.

This method is adversely affected by the fact that the readiness of the backup control devices cannot be checked, which reduces the certainty.

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Furthermore, in the case of electromechanical control devices, a rather uneven consumption of private control devices follows, because the control device in continuous use apparently achieves substantially higher switching numbers than the backup control device to be used only in the event of a fault.

The object of the invention is to provide a method which, without high costs, guarantees the safe readiness of all control devices and at the same time offers the possibility of detecting disturbances and locating faulty devices without an upper monitoring device.

According to the invention, this is achieved in such a way that the control devices, of which only one at a time controls all controllable peripherals and switching points until an error occurs or the control device is deactivated, switch periodically and each time the control device switches on when switching, the first time element determining the switching duration is activated simultaneously with the second time element of the second control device, which second time element has a larger time constant than the first time element; then this control device and the connected peripherals, as well as k all switching points are automatically switched on and thus the second control device or the previous control device is reactivated.

According to a further preferred embodiment of the invention, when the first time element of the control device currently in use is omitted, the second control device is switched on by means of its own second time element simultaneously with the error message.

Another further embodiment of the invention ensures that, depending on the nature of the fault in the respective peripheral device or switching point, the respective switching point and the associated peripheral devices switch on from operation for a predetermined period of time or for the duration of the fault.

Furthermore, in order to limit the errors, an advantageous use of the method according to the invention is planned, which is characterized in that the addresses and operating states of the peripherals, switching points and the respective control device written in the main memory are handed over as statistics.

The method according to the invention thus allows, in a very simple manner, each control device to be always ready for use by means of alternating commissioning, the electromechanical elements included in the control devices to be as uniform as possible, mutual monitoring by means of the Self-3 61313 control devices and the possibility of locating faulty devices or branches.

In connection with the drawing, the method according to the invention will be explained in more detail below by means of an example. Fig. 1 shows a remote information device with three control devices, Fig. 2 a device with two control devices, Fig. 3 a device with three control devices and Fig. 4 a statistical representation of the indicated operating modes.

In the remote communication apparatus shown in Fig. 1, each of the three control devices ST is connected to a common main memory SP and all switching points S. The peripheral devices P to be controlled are connected in groups to a fixed connection point S. Each peripheral device P is individually connected to its switching point S. ST. The detection device A connected to the main memory SP collects the statistics and operating states of the peripherals P, the connection points S and the respective control device ST written in the memory SP for the statistics. This statistic can then be retrieved from output device A or reported via the data screening device.

Figure 2 shows an arrangement provided with two identical control devices ST1, ST2, each of which has e.g. a first time element ZG1 and a second time element ZG2 having a longer time constant relative to the first time element ZG1, and an E-relay connected to the time elements ZG1, ZG2 via logic gate circuits T1 to T5. This E-relay symbolizes the ON state of the control unit in operation and the OFF state in sleep mode. Instead of the electromechanical relays E shown in the control devices of Figure 2, electronic relays can, of course, just as well be used. Each control device naturally further comprises switching elements and connections which are not shown in Figure 2 for simplicity, such as for the actual control of the peripherals P and the connection points S, for further routing of data to the main memory, etc.

In each control device, the winding of the relay E is electrically connected on the one hand to the other terminal (-) of the supply voltage and on the other hand to the output of the logic AND gate T4. From the AND gate T4, the first input is electrically connected via a logic inverter T5 to an error detector not shown and the second input to the output of the logic OR gate T1. From the logic OR gate T1, the first input is electrically connected to the output of the logic AND gate T2 4 61113 and the second input can be connected to the second terminal (ground) of the supply voltage via the second time element ZG2 and the operating side of the changeover contact e in the second control device. From the logic AND gate T2, the first input is electrically connected to the second terminal (ground) of the supply voltage via the rest side of the changeover contact e of the second control device and the second input can be connected to the second terminal (ground) via the logic inverter TJ, the first time element ZG1 and the operating contact e of the own control device.

Next, the operation of the switching device according to Fig. 2 will be briefly explained. In the control device receiving the drive, relay E is energized and disconnects on the one hand its own time element ZG1 and on the other hand also the second time element ZG2 of the control device not in use. The first time element ZG1 gives its time until the end of the logic "0" to the connected inverter TJ and this in turn gives the logic "1" AND gate T2 to the second input.

Since the first input of the AND gate T2 of the current control device also has a logic "1" because there is no error message in the inverting device TJj and no relay E in the current control device is energized, the relay E in the current control device can remain energized through it. At the end of the time period of the first time element ZG1, the logic "1" given by this enters, after the inversion taking place, through the inverter T3 as a logic "0" AND the second input of the gate T2, which is relayed by the relay E. When the relay E in the control device in use so far is released, the logic "1" reaches the first input of the AND gate T2 via the rest side of the changeover contact e in the control device not in use, whereupon it starts operating when its own relay E wakes up.

If the first time element ZG2 fails, the operation of the control device in question takes place according to the commissioning of the respective second control device provided by its own second time element ZG2.

Figure 3 shows an arrangement with three identical control devices BT1, ST2, ST3, each of which has e.g. likewise, the first time element ZG1 and the second time element ZG2 having a longer time constant with respect to the first time element ZG1, and an E-relay connected to the time elements ZG1, ZG2 via the logic gate circuits T1 to T4. This E-relay symbolizes the ON state of the control device in question in operating mode and the OFF state in sleep mode. Furthermore, each control device comprises a release-retarding preconditioning relay V and a change-over relay U. Here, too, each of the electromechanical relays E, U and V shown in the control devices of Fig. 3 can be replaced by an electronic relay. which are not shown in Figure 3 for simplicity, such as for the actual control of the peripherals P and the connection points S, for further transfer of data to the main memory, etc.

In each control device, the winding of the relay E is electrically connected on the one hand to the other terminal (1) of the supply voltage and on the other hand to the output of the logic AND gate T4. From the AND gate T4, the first input is electrically connected via a logic inverter T5 to an error detector not shown and the second input to the output of the logic OR gate T1. From the logic OR gate T1, the first input is electrically connected to the output of the logic AND gate T2. The second input of the OR gate T1 is the working side of the second time element ZG2, the disconnecting diode D1, the rest side of the changeover contact UI and both the other control devices. (down). From the logic AND gate T2, the first input is electrically connected via the working contact v2 and the rest contact u2 to the working side of the changeover contact u3 and to the second ground side of the changeover contact u3 and the ground side of the changeover contact e2. The second input of the AND gate T2 can be connected to the second terminal (ground) of the supply voltage via the logic inverter T3, the first time element ZG1 and the working contact el. The fast-decelerated second winding end of the preconditioning relay V can be connected on the one hand via the working contact v1 and e3 and on the other hand through the disconnecting diode D2, the rest side of the changeover contact ui and in one of the two other control devices on the other side of the changeover contact e2. The second winding end of the preconditioning relay V as well as the second winding end of the changeover relay U are electrically connected to the first terminal (-) of the supply voltage. The second winding end of the relay U can be connected to the other terminal (ground) of the supply voltage via the start switch TT.

The mode of operation of the switching arrangement according to Fig. 3 roughly corresponds to the mode of operation shown in connection with Fig. 2, therefore only the mode of operation of the additional switch elements in Fig. 3 need be discussed here.

Claims (4)

6 61113 The preconditioning relay V always starts in each control device that is subsequently activated, via the disconnecting part D2, the changeover contact ui rest lever and the connection of the relay E excited in the current operating device via the operating side of the changeover contact e2 to the supply voltage. Relay V is energized in the control device in use via working contacts vl and e 3 until relay E is released. The change-over relay U operated by the switch U causes the control device in question to be disconnected via the rest contact u2, whereby the change-over contacts u1 and u3 guarantee the alternate activation of both control devices in use. The example in Figure 4, which illustrates the statistical representation of the operating modes due to the errors that occur, shows how recurring errors can be detected and the sources of the error can be located. Thus, for example, in lines 101, 107, 111 and 118, during control event 2, error type A always occurs, regardless of the control device ST1 or ST2, but always in connection with the switching point S3 and the peripheral equipment P12. Furthermore, in lines 104 »108 and III during control event 3, the same type of error A also occurs independently of the control device ST1 or ST2, but always in connection with the switching point S3 and the peripheral device P13. Since the other peripherals PII, P15 connected to the connection point S3 are not indicated in the error list, it is not possible to confirm whether these are involved in the control event at all. Thus, there is one possibility that the error sources are in the switching point S3 or in both the peripherals P12 and P13. A method for controlling peripheral devices in a telecommunication device, in particular a centrally controlled telecommunication device, by means of two or more identical control devices, the peripheral devices grouped together in each group at any one time only one controls all controllable peripherals (P) and switching points (s) until a fault occurs or the control unit (ST) is deactivated, switches periodically and each time the control unit (ST) switches on, the switching points (S) separate all connected peripherals P) from the control device (ST), that when the first control device (ST) is switched on, the first time element (ZG1) determining the duration of the switching 7 61113 is activated at the same time as the second control device (ST). with the second time element (ZG2), the second time element (ZG2) having a larger time constant than the first time element (ZG1), that if the error still occurs in the current control event Peripherals (P), switching points (S) and control device (ST) both the addresses and the operating modes are written to the main memory (SP) and that this control device (ST) and the connected peripherals (P), as well as all switching points (S), then switch on automatically and thus the second control device (ST) or the previous control device ( ST) is re-enabled. Use of a method for limiting errors according to Claim 1, characterized in that the addresses and operating modes of the peripherals (P), switching points (S) and the respective control device (ST) written in the main memory (SP) are handed over by the handover device (A) connected to the main memory (SP). STATISTICS, Method according to Claim 1, characterized in that when the first time element (ZG1) of the control device (ST) currently in use is omitted, the second control device (ST) is switched on by means of its own second time element (ZG2) simultaneously with the error message. Method according to Claim 1, characterized in that, depending on the nature of the fault in the peripheral device (P) or the switching point station (S), the respective switching point (S) and the associated peripheral devices (P) switch on for a predetermined period or duration of the fault. 8 61113