DE1062150B - Circuit arrangement for monitoring the states of facilities - Google Patents

Description

GERMAN

INTERNAT. KL. G 08 C

PATENT OFFICE

S55238VIIId / 74b

REGISTRATION DATE: SEPTEMBER 24, 1957

NOTICE
THE REGISTRATION
AND ISSUE OF THE
EDITORIAL: JULY 23, 1959

In the railway safety system, arrangements are common that are used for remote control or remote monitoring of signals, track sections or the like. Continuous interrogation of the mentioned facilities cause in short successive time intervals.

When monitoring or remote control of many devices distributed along a route, z. B. of signals, track sections or the like. The task is now to one or more reporting or To transmit command signals per device over a common line.

Attempts have already been made to assign a separate frequency to each message or command signal in order to to be able to distinguish the signals mentioned from one another. With this procedure, however, are different Difficulties associated. Above all, the use of many frequencies is a considerable effort necessary. There are z. B. one or more generators for each device to generate the various Frequencies and the appropriate screening media required. The sieve means are both on the Sending and receiving side required. Furthermore, the bandwidth that is available on a line, in particular can be transmitted via a pupinized line. As a result, can only a correspondingly small number of devices on a certain route is controlled or monitored will. However, the longer the monitoring devices, the greater the number of monitoring devices Total distance is. Also the use of line amplifiers in non-pupinized lines does not bring about any significant improvement in this regard.

The invention is based on the object of monitoring as many devices as possible on a route or to be able to control. The effort should be substantial compared to the known arrangements be reduced.

To solve this problem, a circuit arrangement is suitable in which the to be monitored Facilities are assigned to monitoring stations, which are connected to each other via a double line as well are connected to a control center and to a clock. In this circuit arrangement, the Monitoring of the various facilities by transmitting clock pulses to each Stations as well as to the control center and of message or command signals from the station also to the control center over the same line.

According to the invention, this circuit arrangement is characterized in that, for counting the clock pulses which are transmitted simultaneously with reporting or command signals, in the clock generator in a circuit arrangement for monitoring
the states of facilities

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dr.-Ing. Hans-Ulrich Meyer, Braunschweig,
has been named as the inventor

a counter, preferably a binary counter, is provided for each station and in the control center, in addition, one or more message signals of different frequencies during the clock pulses be transmitted.

So there is a certain period of time within a query cycle for each message or command signal assigned. This period is measured for each station by the relevant clock pulse. Included a signal can now be used for every message or for every command, which during this period is sent out. But it is also possible to send messages and commands from a station or for to transmit a station by reporting a certain condition through a certain signal is, while another state is characterized by the fact that no signal is emitted./

An advantageous embodiment of the circuit arrangement according to the invention is that the Clock feeds the double line at one end via a clock counter with clock pulses, while the control center, which is provided with a central counter, is connected to the other end of the double line is, and that each equipped with a similar station counter stations between Clock and control center are connected to the line, all counters by the clock pulses be switched further synchronously and each station during a specific clock pulse assigned to it Emits message signals, which the control center evaluates.

The inventive arrangement of the clock at one end of the common double line and the control center at the other end of the double line has the advantage that both the clock pulses and the reports submitted by the individual stations

909 578/252

or command signals are transmitted in the same direction over the double line. This results in namely that both the clock pulses and the message signals arrive at the control center at the same time. This has the advantage that runtime differences between clock pulses and message signals are excluded are.

Another advantage of the invention is that all counters, ie the clock counter, the station counters and the central counter and the structure of the stations, are designed in the same way. Furthermore, the use of the binary-coded counting method, which is known per se, has the advantage that each counting chain with η steps can count up to 2 η clock pulses. In contrast to the decadic counting method, this means that counting levels can be saved.

Under certain circumstances, it is useful to include the counting volume of such a binary counting chain in itself known way to limit in order to adapt the counting volume to the number of devices to be monitored. It is advisable to limit the counting volume in such a way that between every two interrogation cycles a pause is provided which lasts for a certain number of clock pulses.

The invention and further details are described in more detail with reference to FIGS. 1 to 5, namely shows

1 shows the circuit arrangement according to the invention as a block diagram,

2 shows a simplified pulse diagram,
3 shows the clock generator used as a block diagram,

4 shows one of the stations assigned to the facilities to be monitored as a block diagram,
5 shows the control center as a block diagram.
In FIG. 1, according to the invention, a clock generator TG is connected to a double line DL at one end. The other end of the same line DL is connected to a center Z. Distributed over the length of the line, stations ST1, ST 2, ST3 to STn are now connected to the double line DL at any distance. The following is an arrangement with z. B. one hundred monitored facilities described for example. However, the invention is not limited to this. Rather, given the appropriate dimensioning of the clock generator, the stations and the control center, a corresponding number of devices can be controlled or monitored.

The clock generator TG now sends out a clock frequency f 1, which reaches all stations ST and the control center Z, as the corresponding arrows are intended to indicate. Each station sends one or more specific message signals of the frequencies / 2 or / 3 during a very specific clock pulse assigned to it. These message signals f2, / 3 are differentiated from one another in the control center Z according to the chronological order of their arrival.

The simplified pulse diagram shown in FIG. 2 shows clock pulses of the frequency f 1 as well as message signals of the frequencies / 2, / 3 in their course during the time t. A single clock pulse is supposed to last here during time T 1 and is made up of the pulse current IPA and the pulse pause IP . The message or command signals of frequencies f2, / 3 are composed in the same way. However, the message signals are offset in time with respect to the clock pulses in such a way that the pulse flow of the message signal begins during the pulse flow of the clock pulse and ends during the pause of the clock pulse.

The clock frequency can be 100 Hz, for example. Each clock pulse thus has a duration of T equal to 10 msec. Of this, the pulse current IPA is sent for 5 msec with the frequency / 1. The IP interpulse period is also 5 msec long.

3 now shows a clock generator TG according to the invention, namely a buzzer TSM is provided, which here emits 100 Hz, for example, and thus controls a clock pulse shaper stage TIF. This clock pulse shaper stage TIF is designed here as a bistable multivibrator which is known per se. It can, for example, consist of two controllable elements, e.g. B. transistors or from a gas-filled tube. The clock pulse shaper TIF now emits square-wave pulses to control the clock generator counter chain TZK . The clock counting chain is also constructed in a manner known per se from bistable flip-flops T1, T2 to T1 . The side connections of a bistable stage are unbalanced control inputs, one of which is used for setting and the other for resetting the stage. The connection led from above to the middle of a step belongs to a symmetrical or alternating control input, via which the step is toggled with each pulse. The remaining connections at the top and bottom of such a stage are its outputs. Since the clock counting chain TZK here z. B. is composed of seven levels, it has a counting volume of 2 ⁷ = 128 counting steps.

Should z. B. a hundred devices are monitored, the clock counting chain TZK counts a hundred clock pulses and feeds them to the double line DL . When the clock pulse corresponding to the ordinal number of the last station - here station 6 "T100 - is reached, the further feeding of the double line with clock pulses is interrupted for a certain time in order to identify a distance between each new interrogation cycle. This is achieved by opening the outputs of certain stages the Taktgeberzählkette TZK the inputs El, E2, E3 of a coincidence gate TK feed, the last station corresponding clock pulse, a signal appears at its output a when reaching the atomic number, which causes the interruption of the supply of the two-wire line via a blocking gate TS. Meanwhile counts the Taktgeberzählkette TZK the pulses emitted by the buzzer TSM continue up to the hundred and twenty-eighth clock pulse. During a query cycle, which here lasts from the first to the hundredth clock pulse, the blocking gate TS controls a generator TGi, which supplies the frequency fl , in such a way that for the duration of each pulse amp litude IPA of a clock pulse, this frequency / 1 is fed to the line DL via an amplifier TV. After the clock pulse corresponding to the last station has been reached, the blocking gate TS blocks further control of the generator TG1. The pause, which lasts from the hundredth to the twenty-eighth clock pulse, is used to be able to bring the counters in the stations and in the control center back to a certain zero position, so that synchronism of all counters is always guaranteed. The amplifier TV also ensures that the clock generator is well matched to the double line DL. It may be useful to stabilize the output voltage of the amplifier TV.

4 shows a station as it is assigned to the devices to be monitored in the circuit arrangement according to the invention. Each station contains a pulse shaper SIF as well as one

5 6

Station counting chain SZK. The pulse shaper SIF and formers SIF are used in the zero position. The station counting chain SZK are in the same way; however, it is expedient to also build the amplifier, as it is described for the corresponding elements of the SV1 during the pause by the voltage of the blocking gate SG appearing on the output clock with reference to FIG . The circuit is now made in such a way that each status 5 controls its blocking range. The rectifier tion through a transformer SÜ with the double SL2 is ineffective as long as counting impulses DL is connected, namely the frequency, ie at the restricting input ESE of the frequency / 1 of the clock impulses via the secondary blocking gate SG there is such a potential during the arrival of the winding SWl of the transformer SU and via a clock pulse that no reset voltage amplifier SVl, rectifier SL 1 and a white can appear at the filter 5 "Fl matched to this frequency and via the IO output of the blocking gate SG.

teren amplifier SV 2 to the input of the pulse The reset voltage at the output of the blocking former SIF. The pulse shaper SIF now controls gate SG is maintained until all counting stages on the one hand Stationszählkette SCC as well as an input of the counting chain SCC and the pulse shaper in the SIF gear SE 1 of a mixing gate SMG. It also feeds 15 zero position. If in this the pulse shaper SIF an input SB 1 of the co-moment at any input of the mixing gate an incidence gate SKG. The other inputs of the co-voltage is available, no reset voltage incidence gate SKG can appear in each station individually at the output of the blocking gate SG ,
according to a dual code with the outputs of the The reset voltage is statically fed to the counter via the individual counting stages of the station counting chain SZK ver 30 SZL. That has the bond. This coded interconnection has the advantage that a counting chain with a defective number sequence that the relevant coincidence gate SKG stages, which does not return to the zero position, is only held at a specific position at a station, so that this station does not have any wrong one of the associated ones Can submit station counting chain SZK to his messages. This holding the output SA emits a control pulse, that is, the defective counting stage is caused by the fact that at the coincidence gate SKG can at its output SA relevant input of the mixing gate SMG, which only emit a pulse if at all of its the defective stage the counting chain is connected, one of the inputs has an identical, prescribed voltage that is also present at the output of the mixer. This control pulse causes the delivery of the gatters and appears as a result of the locking signal, here z. B. the frequency / 2, / 3 via the 30 gate SG can be fed back to the defective stage via the line secondary windings SW 2, SW3 of the transformer SÜ SZL .

to the double line DL, in that the control- Another advantage of the invention is

impuls the generators SGf 2 and SGf 3 depending on the station using the same counter

on contacts SKI, SK2 . This may also be the case with several clock pulses

Contacts SKI and SK2 are able to submit 35 messages through the relevant. Be for this purpose

device to be monitored actuated. You can continue to the same counting chain of the station concerned.

for example, from a line signal, a soft tere coincidence gate connected accordingly

or the like. Be made dependent. Another individual assignment can now be made to the same code.

z. B. the two states "track free" and "track connection with the outputs of the station

sets «through the closed contacts SKI or 40 counting chain.

SK2 are shown. Under certain circumstances, a control center Z is now shown in FIG. 5, but it is expedient to provide a further contact, which is connected by means of a transformer ZU to the double line which controls a further frequency generator DL . The transformer ZU also has permitted. This has the advantage that even in the event that three secondary windings ZWl, ZW2 and ZW3. The that the message signals are not issued, a 45 filter ZFl, ZF2 and ZFZ ensure that the over-control signal is sent. This means that every time the clock pulse frequency / 1 and the Fre clock pulse are transmitted, a statement is made to the control center, and / 2, / 3 of the message signals are quenzen. The clock pulses can therefore be monitored in the control center, whether a step has now passed through an amplifier ZVIl, a counter in a station, rectifier ZL1 and an amplifier ZV 12. This means that every query cycle that uses a 50 pulse shaper ZIF. This pulse shaper corresponds to the disturbed step contained, to be determined immediately. the pulse formers in the clock T and in the be-The other inputs of the mixing gate SMG are written station ST. Likewise, the central counting chain ZZK controlled by the outputs of the individual bistable counting stages pulse shaper ZIF corresponds to the station counting chain SZK connected. Mixing the counting chains already described. The counting chain gatter SMG can always send a pulse to its 55 ZKK , controlled by the clock pulses, output SAG synchronously, if a prescribed voltage is applied to any of its with the counting chain of the clock and the number inputs. chains of stations. Certain outputs of this voltage at the output SAG of the central counting chain ZZK are now connected to the inputs SMG and the locking gate SG opens if it is connected to a mixing gate ZMG . In addition, a restrictive input 60, designated by a point, is the input of this mixing gate at an output of the ESE when no voltage is present. The locking gate SG pulse shaper ZIF connected. The mixing gate ZMG always supplies a voltage to work back in the same way as it was described for the station mixing control of the counting chain SZK and the pulse shaper gate SMG , that is, it feeds the SIF into the zero position when an input of a blocking gate ZG is connected to the rectifier . No pulses arrive at output SL2. That is the case if 65 of this blocking gate then appears during the pause between each two interrogation cycles, as described with reference to FIG two query counting chain ZZK and the pulse shaper ZIF in the circulating interrupted. This period of time is returned to the zero position. During the transmission, the return of the counting chain SZK and the pulse 70 of clock pulses passes through the rectifier

ZL 2 at the restricting input EZE of the blocking gate ZG a voltage that prevents the creation of a reset voltage at the output of the blocking gate ZG.

An equal number of coincidence gates Z5T1 to ZSTn via amplifier V according to the dual code used are now connected to the level outputs of the central counting chain ZZK according to the number of devices to be monitored, ie according to the number of connected stations. In Fig. 5 only the circuit of the coincidence gate ZST 1 is shown in order to ensure the clarity of the circuit diagram. According to the code used, the other coincidence gates ZST are also to be connected to the outputs of the individual counting stages of the counting chain ZZK . This connection takes place in such a way that in each specific working state of the counting chain another coincidence gate ZST emits a pulse at its output ZA which identifies the associated station and, in cooperation with the message signals of the same station, via further coincidence gates ZKIl, ZK 12 to ZKnI, ZKn2, evaluation relays ZRU, ZR12, ZRnI and ZRn2 respond.

The message signals are fed via amplifiers ZV2 \, ZF22 and rectifiers ZG2, ZGZ or amplifiers ZV 31, ZF32 to the coincidence gates ZKH, ZK 12 ... provided for each station in the control center.

Because of the large number of coincidence gates connected to the outputs of the counting chain ZZK, it is expedient to provide the amplifiers V between the outputs of the counting chain or the output of the pulse shaper and the inputs of the relevant coincidence gates ZST .

The evaluation relays ZRIl, ZR12. . . are provided with a certain delay, such that an energized relay remains energized at least until the end of the next interrogation cycle. This ensures that the message signals can trigger a continuous message. The setting of the relays can also be done in such a way that these relays only pick up after the second or third successively arriving message signal and only drop out after the second or third message signal. This has the advantage that a single interference pulse cannot cause an error message.

Under certain circumstances, the number of coincidence gates required in a control center, as provided in the invention, can be reduced by forming groups which are connected to the counting chain ZZK via a multiple circuit.

Claims (14)

Claims: 55 1. Circuit arrangement for remote monitoring of the states of facilities to which monitoring stations are assigned, which are connected to each other and to a control center and to a clock generator via a double line by transmitting clock pulses from a clock generator to the individual stations and to the control center and message signals from the stations also to the control center via the same line, characterized in that for counting the clock pulses (Tl, T2 ...), which are transmitted simultaneously with message or command signals (J2, f3) , in the clock generator (TG) in each station (5Tl, 5T2...) And in the control center (Z) a counter (TZK, SZK, ZZK), preferably a binary counter, is provided, with one or more message signals of different frequencies (f 2, f 3) be transferred. 2. Circuit arrangement according to claim 1, characterized in that the clock generator (TG) feeds the double line (DL) at one end via a counter (TZK) with clock pulses, while the center (Z) also provided with a counter (ZZK) the other end of the double line (DL) is connected, and that the stations (5Tl, 5T2 ...) each equipped with a similar counter (SZK ) between the clock (TG) and the control center (Z) are connected to the line (DL) , with all counters being switched on synchronously by the clock pulses and each station emits message signals during a specific clock pulse assigned to it, which the control center evaluates. 3. Circuit arrangement according to claim 1 or 2, characterized in that each station (STl, ST 2... ) During a certain clock pulse assigned to it with the help of a coincidence gate (SKG) emits message signals, such that when the relevant station is paid (5T) associated clock pulse at the output (5 ^ 4) of the coincidence gate (SKG) a control pulse appears, which causes the output of the message signals (/ 2, / 3). 4. Circuit arrangement according to claim 1 or 2, characterized in that each station (STl, ST 2...) During a certain clock pulse assigned to it is able to emit message signals that the counters (SZK) of all stations (5 "T) each begin their counting from an individual zero position, each counter emitting a control signal upon reaching the clock pulse assigned to its station, which causes the transmission of the message signals. 5. Circuit arrangement according to one of An ^ Proverbs 1 to 4, characterized in that counting chains are provided as counters (ZZK, TZK, SZK) in the center (Z), in the clock (TG) and in the stations (5T) The working state can be switched from stage to stage in a stable manner by the clock pulses, with each working state of a counting chain representing a binary-coded statement for the ordinal number of the respective transmitted clock pulse. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that the clock (TG) contains a pulse generator (TSM), a pulse shaper (TIF) and a clock counting chain (TZK) , the counting chain being one of the number of stations to be monitored ( ST) counts the corresponding number of clock pulses and feeds them to the double line (DL) and, when the clock pulse corresponding to the ordinal number of the last station is reached, interrupts the further supply of the double line (DL) with clock pulses in order to identify a distance between each new interrogation cycle for a certain time. 7. Circuit arrangement according to claim 6, characterized in that the outputs of certain stages of the clock counter chain (TZK) feed the inputs of a coincidence gate (TK), at the output (A) of which it is reached Ordinal number of the last station corresponding clock pulse appears, which causes the interruption of the supply of the double line via a locking gate (TS) for a period of time during which the counting chain continues to count until it reaches its counting volume. 8. Circuit arrangement according to one of claims 1 to 5, characterized in that each station (STl, ST2 ... ) Contains a pulse shaper (SIF) and a station counting chain (SZK) from which certain stage outputs together with an output of the pulse shaper (SIF ) feed the inputs of a coincidence gate (SKG) , at the output (SA) of which a pulse to control the delivery of message signals only appears if the associated station counting chain has assumed a counting position corresponding to its station. 9. Circuit arrangement according to claim 8, characterized in that the control pulse appearing at the output (SA) ao of the coincidence gate (SKG) of a station (ST) causes the output of message signals in that this control pulse signal generator (S Gf 2, SGf 3) switches that feed the double line (DL) message signals of certain different frequencies (/ 2, / 3). 10. Circuit arrangement according to claim 8 and 9, characterized in that each station (6Tl, ST2 ...) is connected to the double line (DL) by means of a transformer (SÜ). 11. Circuit arrangement according to claim 10, characterized in that a secondary winding (5 "I ^ 1) of the transformer (S Ü) via a filter (SFl) tuned to the frequency (/ 1) of the clock pulses and via an amplifier (SVl, SV2) and rectifier (SL 1) feeds the input of the pulse shaper (SIF) in the station, to whose output the relevant station counting chain (SZK) and an input (SE 1) of a mixing gate (SMG) is connected, the other inputs of the mixing gate (SMG ) are connected to outputs of the relevant counting chain (SZK) and the output (SAG) of the mixing gate (SMG) in turn feeds a blocking gate (SG) , the restricting input (ESE) of which to the pulse 4-5 shaper (SIF), preferably via a rectifier (SL2) is connected in such a way that during the pauses between two interrogation cycles caused by the counting chain of the clock, a reset pulse appears at the output of the blocking gate (SG) , which is an input of the individual stages of the counting chain ( SZK) and the pulse shaper (SIF) and as a result causes the counting chain to be reset to the zero position. 12. The circuit arrangement according to one of claims 1 to 5, characterized in that the central station (Z) other than the Zentralzählkette (ZZK) also contains a pulse shaper (ZIF) which controls the counting chain (ZZK) and together with outputs of the individual stages of the counting chain is connected on the one hand to the inputs of a mixing gate (ZMG) and on the other hand together with further stage outputs of the counting chain to the inputs of coincidence gates (ZSTl, ZST2 ... ), the number of which corresponds to the number of stations, so that a different one in each specific working state of the counting chain Coincidence gate (ZSTl, ZST2...) Emits a pulse at its output, which identifies the associated station and, in conjunction with the message signals of the same station, via further coincidence gates (ZKIl, ZK 12...) Evaluation relay (Zi? 11, ZR12. .) controls.. 13. Circuit arrangement according to claim 12, characterized in that one input of a blocking gate (ZG) is connected to the output of the mixing gate (ZMG) , the other restricting input (EZE ) of which is connected to the pulse shaper (ZIF) in such a way that this input in the pause between two interrogation cycles no blocking potential is received, so that the potential appearing at the output of the blocking gate (ZG) causes the counting chain (ZZK) and the pulse formers (ZIF) to be reset to zero. 14. Circuit arrangement according to one of the preceding claims, characterized in that the counting chains in the pauses between two query cycles in the zero position for as long be held until all stages of the counting chains have taken their zero position. 1 sheet of drawings & 909 578/252 7.59