DE2346395A1 - MONITORING SYSTEM - Google Patents

Description

SOClETE INDUSTRIELLE DE LIAISONS ELECTRJQUES P 072 01

Monitoring vstera

The invention relates to a monitoring system for monitoring of changes in the status of one or more devices that are assigned to a central station.

Changes in the status of one or more devices to be monitored can open, for example, through an electrical change ( or closing a contact) or through a mechanical change (relative movement of two objects).

The various facilities previously used for the continuous or discontinuous monitoring included, for example, the use of an interrogation signal, which by a series of pulses is formed by the central station were sent to the devices to be monitored as well as the acquisition of this query signal in all assigned devices, and accordingly the number of pulses received and counted in each device became one or more predetermined processes in that one Device triggered, the ordinal number of which corresponded to the number of pulses transmitted by the central station. These processes could in particular include a return signal to the central station,

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which indicated that a predetermined process was being observed in the Device has been triggered.

The present invention is based in particular on the object Simplified means to indicate which are on the one hand economical and on the other hand effective to a monitoring of a device under consideration in accordance with an interrogation signal issued in a central station, with the Query can be renewed periodically in the rest.

A connection channel, for example a double line such as a pair of telephone calls, is to be provided, which is carried out by the central station and run in the vicinity of different points to be monitored, and at each of these A facility or device should be provided in order to achieve the desired monitoring.

In the steady state, the double line provided in this way serves to continuously transmit an alternating current, and this alternating current is appropriately rectified in each device to be monitored and is used to charge an accumulator battery to form a supply of electrical energy that is used when interrogating the status of the device or devices to be monitored through the central station.

Determination of the device, the operational status of which is to be checked would like, is not done by storing a certain number of pulses in the device, which corresponds to the ordinal number of the Device on the line under consideration, but on the determination of the temporal position of the continuously transmitted pulses with respect to a precisely specified point in time.

Among the difficulties overcome by this invention are also to be mentioned those difficulties that result from the interference signals which are used for monitoring Conduction are induced. Other difficulties are also overcome.

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"O _

sore, as will be apparent from the following description.

The following is the use of the invention for monitoring a certain number of points of a distribution network for electrical energy explained. You know it in this case is required to quickly determine a point where, for example, the turning off of a switch has occurred, and this information should be passed on as quickly as possible to the central station, so that the electrical current of the distribution network can be restored at the point under consideration.

Some electrical power distribution networks can have a significant impact Have length and contain a large number of points where switches are installed to facilitate localization to allow mistakes. For example, if a switch is designed to work at one point on the network up to one To work such a shutdown process, an operator must go to the point under consideration in order to remedy the errors, and considerable difficulties arise, particularly in busy business hours.

The invention avoids these and other disadvantages, as will become apparent from the following description.

According to one characteristic of the invention, the investigation of a fault, for example the interruption by a switch, is activated a point of the distribution network for electrical energy is reached by a synchronous query system, which with a constant Speed of, for example, one step per second works. This means that a given device can be completed in one second it is queried that it emits a response signal and that the signal received is identified in the central station and if necessary is held in a memory. The query then continues at one step per second until the complete query period for the η points of the network under consideration has been completed, i.e. that the devices under consideration

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have been checked.

The central device transmits during the idle period, i.e. outside of the storage and interrogation periods, a special signal is continuously transmitted on the said double line, for example through a voltage of 70 V at 50 Hz is represented and after the local rectification for charging the provided in each device Accumulator batteries are used.

As will be seen later, each device contains a rechargeable battery, a battery charger for the charging current of the accumulator battery, which acts on the equipment with the local voltage when carried out by the central device a command for the start of the detection of an electronic switch, as well as logic circuits, which process the response signal from the device in question.

Various control and display elements allow above all one Local examination of the device, as will emerge from the description.

The central station is a completely stationary facility provided, which is formed by various supply circuits that are connected to a local voltage source for 220 V and 50 Hz are connected. The essential parts of this facility are as follows:

"an electronic scanner, the commissioning of which is triggered manually by a pressure switch provided in the central station will;

the circuits for receiving and identifying the state the contacts of various devices;

a memory device which stores the incoming volatile signals stores the devices provided along the double line for as long as necessary;

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Output elements that indicate the status of each device;

a supply device, - through which a current can be generated on the double line, which is used to charge the accumulator batteries the device is intended;

a general utility covering the entirety of the central station equipment. "

The new system uses, as will be shown, a double line, which approximates the course of the power cable follows, which connects one or more of the points of the power distribution network to be protected.

This double wire is formed by a pair of twisted telephone wires and can be used for power transmission at the same time as the cable be relocated.

In the following preferred embodiments of the invention are explained with reference to the drawings; it represent:

1 shows a central station which connects a loop of several devices P1, P2 ... Pn;

Fig. 2 shows a network with a central station, which several in series connected devices Pl, P2, ... Pn connects;

Figs. 3 and 4

Timing diagrams for explaining the invention;

Figures 5A and 5B

on the one hand, the establishment of the central station and, on the other hand, the establishment of a device;

Figures 6A, 6B and 6C

Devices according to FIG. 6D, which the establishment of a

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Device in detail a;
Fig. 7 shows an apparatus device with two printed circuit boards;

Figures 8A and 8B

Devices according to FIG. 8C with a logic circuit in the devices, wherein from FIG. 8 the reception of the signals and Fig. 8B shows the logic circuit;

Figures 9A and 9B

Arrangements according to FIG. 9C with a control circuit, which interrogation signals on the line to the devices to be interrogated gives up;

Figures 10A and 10B

signal processing means in the central station;

11 shows a device for transmitting information on the double line for the device of FIGS. 10A and 10B;

12 shows a control device for display at the central station and

13 shows the supply device for the central station.

Fig. 1 and 2 each show a central station ST, which is connected by a double line, the a number of devices Pl, P2, P3 ... Pn connects to the central station according to FIG. 1 in a loop or according to FIG. 2 in series. The devices Pl / P2, P3, ... Pn are each arranged in the vicinity of the devices which they are to monitor, for example the device to be monitored are stimulated to cause the opening or closing of a circuit in the monitoring device.

Fig. 3 shows the timing diagram of the central station and Fig. 4 that of one of the devices to be monitored.

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Figure 5A. and 5B each schematically represent the one in the central station ST and in any device to be monitored, for example the device Pl.

In Fig. 5A, the devices to be monitored Pl, P2, P3, ... Pn connecting line L fed in the central station ST by means of a transformer T whose primary winding is fed by the network becomes' and its secondary winding in the line L an alternating voltage of, for example, 70 V in the exemplary embodiment.

The line L transmits the query signals to various devices Pl, P2, P3 ... Pn and receives response signals from the devices
by means of a sensor CP.

In parallel with the line L is a thyristor Th, which is a control circuit COC is assigned, which is actuated by a cyclically operating interrupter IC.

A logic circuit CL is on the one hand with the sensor CP and
on the other hand connected to a supply circuit CA which
is fed by zv / ei transformer Tl and T2, the only one
Primary winding is fed by the network.

Finally, the logic circuit CL η has output lines 1, 2,
3 ... n, which are assigned to the display devices CAPl, ... CAPn, and their lines Sl .... Sn are connected to display devices AFl ... AFn, which indicate the state of the devices to be monitored in accordance with an on the interrupter Specify the interrogation signal acting on the IC.

Fig..5B schematically shows the device of one of the devices to be monitored. The monitoring device is parallel to the line L and contains a rest switch 11-12. A changeover switch INV with three contacts 1, 2, 3 sets the one to be monitored
Device, for example a switch.

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Normally, the voltage on the line L continuously charges a battery B by means of a charger CHA. An error display device INV is assigned a circuit which operates a thyristor ThI. A device is provided which can carry out a local check and contains a rectifier RE and a switch Is to ensure proper function check with the local facility.

FIGS. 6A, 6B and 6C are arranged and explain in accordance with FIG. 6D the establishment of a device. As shown in these figures, the various circuit elements are indicated by labels Designated CI-I, CI-2, CI-3, CI-4. These labels are provided in sufficient numbers and represent the number of devices Pl, P2, P3 ... Pn to be monitored and these devices assigned ordinal numbers in the invoice.

The power is supplied via the network S through the two transformers Tl and T2 and through rectifier bridges PrI and Pr2. In the block CI-I there are two semiconductor elements TrI and Tr2. Finally, a switch Ic is provided for triggering an operating period and a switch Iar that controls the monitoring operation the device stops.

Fig. 7 shows schematically the installation of a device P, in which there is a switch IND whose rest position R or whose working position T is to be monitored.

The device P is parallel to the double line L, which can consist of a pair of twisted lines, as in telephone networks be used. This line ends on the left in the drawing in the central station, where the monitoring takes place.

The circuit CI-A is with a battery AC and a display unit V connected> which allows the proper functioning of the facility to be indicated by clicking on the local Presses pressure switch B, which is assigned to a rectifier Rs

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and is connected to a circuit CI-A through two induction coils Ll and L2 and a parallel capacitor C.

For an explanation of the mode of operation, reference is made to FIGS. 8A and 8B. and refer to the timing diagram in FIGS .

In the following it is assumed that FIGS. 8A and 8B are adjacent to one another in such a way that 8A is to the left of FIG. 8B and the conductors 1, 2, 3 ... to the right of FIG. 8A are the conductors I ¹ , 2 ¹ , 3 ¹ correspond to the left in Fig. 8B. The clock and counting circuits in the devices P1, P2 ... P3 are constructed in the same way as that of the central station. The transistors' Q3 and Q4 produce signals at 50 Hz which control a series of frequency dividers.

At the output of the circuit CI-8 form the signals with the frequency of 1 Hz the clock of the system. The circuits DU and DD No. 4 and No. 5 successively divide the frequency by 10 and connect in pairs the decoded outputs of the decoding circuits CI-2 and CI-3, so that square wave signals with a duration of 1 s are obtained selected from the possible signals at the start of the count.

During the rest period, i.e. without one from the central station Monitoring command, the central station continuously maintains an alternating voltage of, for example, 70 V on the double line 50 Hz upright, which ensures the charging of the batteries in the devices Pl, P2 ... Pn. The circuits containing the devices are therefore usually without tension. At the moment when a query command is issued by pressing a button on the central station is caused, the half-periods of the voltage of 70 V and 50 Hz are separated by 200 ras. This will make the Monitoring devices for the devices Pl, P2 ν. . Pn with Voltage supplied.

The counting decades DU and DD for the devices and those of the

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Central stations are held at zero until the end of the 200 ms. * At this point the synchronous counting begins at the central station and at the various ones provided along the line Devices. Figs. 3 and 4 clearly show the sequence of operations. Figure 3 illustrates a timing diagram for the central station ST and FIG. 4 shows a time sequence diagram for a device to be monitored, for example the device Pn.

The number 1 in Fig. 3 indicates the change in voltage when the central station by a pulse of 11 ms resets to zero.

Line 2 represents the supply of devices P1, P2 ... Pn. It can be seen that the trigger command begins at time t. The pulse trains with 200 ms correspond to the triggering, for example when a device Pn + 1 responds.

The line 3 symbolizes the case in which by the query pressure switch in the central station ST all of the devices Pl, P2 ... Pn is set to zero, what the up / down counters that are in the devices. Lines 4, 5 and 6 indicate how to identify a device, which for example corresponds to a device Pn. Lines 7 and 8 show how one is considered according to the state of the flip-flops The corresponding display device at the central station is enlightened or not enlightened.

Lines 9, 10, 11, 12 and 13 represent the identification of a device Pn + 1, the actuation of the circuits CI and finally the lighting or non-lighting of the corresponding display devices at the central station.

The timing diagram is now corresponding to any Device, for example the device Pn-I explained.

The line 1 corresponds to the moment in which one is at the

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Central station ST presses the query pressure switch, which corresponds .einem switch-on command generated by a pulse train is shown with a duration of 200 ms. Thereafter, the interrogation cycle of the status is assigned to the central station ST Devices triggered. The devices of the devices are supplied with a voltage of 5 V, for example.

The line 3 symbolizes the case that the up / down counter of the various devices is set to zero.

Line 4 symbolizes how to identify the number of a device or decoded. If at the end of η seconds a pulse train of η seconds is detected on a device to be identified it is known that the device sending this pulse train the device is Pn-I.

The line 5 symbolizes the case in which there is no error indicate, and the line 6 symbolizes the case of one indicated by the position of a pulse train with 200 ms Error outside the time interval from Is.

Figures 7, 8 and 9 illustrate different distributions of pulses over time according to the error status or the absence of errors.

In FIG. 4, CHR represents the clock pulses and N corresponds the end of the polling cycle.

An interrogation cycle on the state of the devices Pl, P2 ... Pn is generated by the fact that positive on line L for 200 ms Half waves are suppressed. This is how the decades of each device become Pl, P2 ... Pn started and the response signal of each device Pl, P2 ... Pn leads to a short circuit in the line L. at the level of the device for 200 ms.

With no response information on the line, the signal is

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- Ll -

sinusoidal at the terminals of the line.

The two transformers TR1, TR2 deliver proportional ones Amplitude information corresponding to the positive sine half-waves of the current. The transistor Q8 in Fig. 9B is turned off, and everyone becomes its base tension because of equilibrium Maintain conduction and diode D7 acts as a zener diode and maintains a potential slightly above that of the Pulses at the emitter of the transistor.

During the response signals from the devices, the current on line L creates an asymmetry in favor of the positive half-waves and the negative half-waves keep a practically constant amplitude. The information therefore appears via the emitter of the transistor QB ^ which is turned on. At the collector of the Transistor Q6 appears 10 pulses at an interval of 20 ms each, which in turn correspond to the output signals of each device. The pulses are processed in a manner to be described.

Figures 9A and 9B show how the control circuits of the line are energized in response to an interrogation of the central station ST and how the time zero of the triggering of the query period over, the state of the devices Pl, P2 ... Pn is determined.

With regard to the supply of voltage, the entirety of the transistors Q6, Q1 and Q8 in FIGS. 9A and 9B constitute a breaker. The voltage of the battery is applied to the emitter of transistor Q7 through terminal 4 and the output 7 of this static switch is on the left in Fig. 9A. To operate the switch it must first receive a positive pulse at the base of transistor Q6 through resistor R7. When this positive pulse arrives, transistor Q6 becomes conductive. The transistor Q6 saturates and the base of the transistor Q7 is applied in such a way that the transistor Q7 becomes conductive. When transistor Q7 is conductive, transistor Q8 also becomes conductive. As can be seen from the figures, the transi-

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Q6 and Q8 perturb a common point, so that the arrangement is relatively symmetrical with respect to the base of transistor Q7 so that when transistor Q8 is conductive, transistor Q7 is conductive remains, i.e. you can put the whole device into operation, even if the pulse at the base of transistor Q6 ver ~ -dwinds ".

The following explains how to get the originated from the line Transmits information to the base of transistor Q6. This takes place through the two transistors Ql and Q2 in the following Way: by suppressing the positive sine half-waves or at least one of these half-waves one gets one Information on the collector of transistor Q2. However, it is also necessary that the suppression of the two Sirius half-waves, i.e. the interruption of the circuit does not lead to an undesired signal.

The static switch is also called an electronic switch here and contains:

a start control circuit having transistors Ql and Q2;

the actual switching device with the transistors Q6, Q7 and Q8

the hold control circuit with transistor Q9.

The transistor Q2 is fed by the transistor Ql and is usually saturated at zero collector potential.

The trigger command from the central station ST via the interrogation cycle the state of the devices Pl, P2 ... Pn is achieved by suppressing ten positive half-sine waves on line L. As a result, the transistor Ql is blocked and the transistor Q2 is fed via the resistor R8. The first negative half sine wave after blocking the transistor Ql blocks the transistor Q2 and thus provides information for the system which is used for

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Commissioning of the device the positive half-waves with preservation the negative half-waves of the network must suppress. This avoids switching over the battery when you have the supply the line switches off.

The first pulse from transistor Q2 brings transistor Q6 in the saturation and the base of the transistor Q7 receives the potential zero via the resistor R20 / so that this transistor is conductive will. Transistor Q8 is then saturated as its base is fed and transistor Q7 becomes conductive even then State held after the information from the line L has decayed.

When information "halt" from the logic circuit at the terminal 15 arrives, the transistor Q9 causes the transistor to turn off Q8 and thus also of transistor Q7, so that the supply is switched off.

If a query cycle on the status of the devices Pl, P2 ... Pn before the normal end of the cycle, which is stopped by pressing the zeroing switch on the central station Is exercised, the negative sine half waves of the line L are suppressed while the pressure switch is pressed. The potential at the emitter of the transistor Q10 causes the supply of the device under consideration to be switched off. In Figs. 8A and 8B the counting decades are labeled 9, 8, 5 and 4. It can be seen that the connections 2 and 3 together with the collector of the Transistor Q6 are connected. Through the connections 2 and 3 the decades are under tension and the points 2 and 3 are on one Level 1 held, i.e. in the case under consideration at a potential of 5 V, and at this moment the decades are at zero set, if it did not already have this counter reading " When the terminals 2 and 3 have a zero level, i.e. a potential of 0 V, the decades begin to count. At the moment of tripping, it is triggered by a thyristor ThI and the transistors Consider the circuit formed by Q 5 and Q6. You can see that the

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Grid electrode of the transistor ThI with the terminal 13 in the 9A and 9B, i.e. any positive half sine waves are received through this point. in the Reading moment, i.e. for the duration of the trip cycle If the circuit is under voltage, there is no voltage at the grid electrode of the thyristor ThI, if provided becomes that the positive half-waves are suppressed. Since the thyristor ThI does not conduct, the transistors also conduct Q5 and Q6 do not. The collector of transistor Q6 has a potential of 5 V. This means that the decades are kept in the counting state for the duration of the information transmission, i.e. for 200 ms.

The end of the information given, i.e. the period of 200 ms, is now considered. The first positive half sine wave, which occurs, causes the thyristor ThI to conduct and the transistors Q5 and Q6 go into the thickening. So it was missing a level value zero on the logic inputs 2 and 3 of each of the counters, i.e. from the moment in which the 200 ms have been counted down, the first information of the counter decades has appeared, that is, they begin to count and in the stated Way to continue counting.

A signal with a duration of 200 ms arrives on the line every second, between 200 ms and 400 ms for each Second unit is, pluralhe each device Pl, P2, ... Pn identifies. For example, there are checked signals of 200 ms at output 6, which, however, are between 600 ms and 800 ms with respect to of the original time of each second. The period is repeated every second on all devices Pl, P2 ... Pn der Line L. The signals are transmitted via outputs 22 and 23 and the normally closed contact or the normally open contact of the display switch INV directed. Therefore, a signal is received at point 21 every second, which corresponds to the six of gates 4, 5 or 6 or three of the gates 1, 2 and 3 follow, depending on the position of the contacts

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and this takes place for all devices Pl, P2 ... Pn. The information now arrives at 21 at the input terminal 2 of the gates 1, 2, 3 of the circuit according to FIG. 12 and at the other input information arrives which corresponds to each device. This information arises from the combination of the outputs of the two decoders 2 and 3 of FIGS. 8A and 8B, which are connected to the counter decades DU and the decades DD for the units digits according to FIG. 8B. A device can be selected according to its position, ie its ordinal number, through the connections Cd. In this way you can differentiate between each device »If you take the gate 3, 4, 5 or 6 of the circuit CI-I, which is connected to one point of the decoder CI-2, you feed the decoder 5 for the units and digits at one point of the decoder 4 for the tens. However, there is a correspondence between the two, ie if you get "two" at the decoder 4, this corresponds to 22. In other words, it is the device 22 which responds at the end of the 22nd second. This information is sent to the input of gate I ₁ . 2, 3 of the circuit CI-6, if there is a match between the signals of the two inputs. This gate emits an output signal. The device can only provide information once when you come across the character corresponding to its number and this character lasts Is, and during this time you receive information of 200 ms, which is arranged according to the position, which is at the circuit outputs 22 or 23 occurred, corresponding to the contact state, which normally corresponds to the contact position of INV. From here, 200 ms of information is output on line L and the status of the device is identified by a square pulse of 200 ras width that occurs at 20. The thyristor ThI, which is parallel to the line, is controlled by the transistor 33. The information is now sent to the line, since information lasting 200 ms has suppressed 10 half-sine waves. The device under consideration has therefore done its work, and all that remains is the work, the supply

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switch off. After the operating period, all devices receive likewise through the connections Cd a number, in the same way for each device, which the holding order is equivalent to. Each device has a different number, which corresponds to the sequence of its response function. There is a Hold order, for which every device has the same number, and this process works through the decoder Gates 1, 2, 12 and 13 of the circuit CI-I of the Pig. 8A and 8B. This information comes from the circuit via terminal 24 and terminal 15 and causes transistor Q9 to conduct is, so gets into saturation and then its collector receives the potential zero and thereby blocks transistor Q8 will. From transistor Q8 one arrives at the starting point, i.e. that the base of transistor Q7 is no longer fed and the Transistor Q7 is blocked.

The local test of each device Pl ... Pn should "determine whether the corresponding device is in a proper operating condition. This review is a quick test of that can be carried out by an operator who checks the facilities of each device. If the establishment is faulty is, i.e. if you don't get the information you want or if you don't get any information at all or if even the line is faulty, it must be remedied. There is simply a pressure switch at the height of each device B, which can be seen in FIG. The pressure switch B operates manually, otherwise it operates automatically. It the positive half-sine waves are thus suppressed. The operator presses the switch for half a time Second or one second and pressing and releasing the pressure switch B causes the device to be supplied with voltage and then responds. This has no meaning for the central station. When the thyristor ThI is used again, it is not in a closed short circuit, and there are two diodes connected in series and subjected to a voltage you get one in the middle of the two diodes

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Voltage for controlling the transistors Ql and Q2 according to FIGS. 9A and 9B, which transistors in turn the display device V Food. Every time a correct response signal arrives for 200 ms, the indicator lamp lights up and the operator, who carries out this process is therefore certain: the supply and the meters are working, i.e., that there is a risk that the counters will malfunction. However, this risk is very small because the counter is perfect are reliable organs.

The information originating from the devices is processed in their chronological order by the arrangement according to FIG. 11, which transmits the information.

The two transmitters TR1 and TR2 are connected to the line L, and a detector system is connected to their secondary windings. The transmitters should generate two pieces of information, one of which shows the intensity fluctuations on the line. One information consists of a signal which is proportional to the fluctuations in the negative component of the current, and the other signal corresponds to the positive components, ie the negative components of the current are detected by the transmitter TR2 and the positive components by the transmitter TR2 .. The negative components should normally remain constant as one only acts on the positive components. At the diode D5, ie finally at the base of the transistor Q5, pulses occur at the frequency of a time period, which have an identical amplitude corresponding to the devices Pl, P2 ... Pn, which emit response signals or emit no such signals, or even how the devices that are in operation and those that are not in operation. The information passing through the transistors Q5 and QA charge the capacitor C4, and a positive constant DC voltage is produced at the terminals of the capacitor C4, the level of which is proportional to the negative fluctuations in the current, ie is ultimately proportional to the charge of the battery. At the transformer TRl, in which the changes to the

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positive components of the current in the absence of Äntv / ortsignalen from the devices arrive, the pulses have a level equal to that of the pulses transmitted by the transmitter TR2 be delivered, since it is a sinusoidal current. At this moment the peaks of these appear Information according to the positive components at the emitter of transistor Q8 with the same amplitude as the voltage the terminals of the capacitor C4, i.e. with the value of the base voltage at the same transistor Q8. Because the transistor Q8 as well as transistor Q7 and transistor Q6 are blocked, a potential of zero is obtained at point 16. It will now It is assumed that the devices respond, i.e. that while these devices respond, the positive components of the current are reduced increase, and this means that the "! pulses on the diode D8 are larger and that at this moment the transistor Q8 becomes leading "

The transistor becomes conductive every time it receives a pulse. That is, if the transistor receives 10 pulses _(it delivers 10. corresponding pulses, as do the transistors Q7 and Q6, and that means that 10 pulses are received at terminal 16 every time a device responds of 200 ms, this means that you get a relative position with respect to these pulses, and if you cut off 10 positive half sine waves you get 200 ms. Each time a station responds, corresponding pulses are obtained, as shown in FIGS. 10A and 10B. The ten pulses arriving at 22B pass through gates 1, 2, 3, 12, 13 of device CI-3 and through gates 11, 12, 13 of the device CI-16 and then operate a pulse counter which has a different role than the aforementioned counters This circuit CI-17 is formed by a circuit dividing by five, which is a circuit dividing by two tion follows. In order to switch off interference effects on the line L, for example inductive influences, when these impulses

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occurs, ie finally receives more impulses than is necessary, the counting of 5 impulses is started and the following impulses are only counted when 5 impulses are received. The circuit CI-17 is automatically reset to zero after every second. This means that when a train of pulses arrives at point 1 of circuit CI-17, the pulses at terminal 12 of the same circuit appear in the form of a square-wave pulse if fewer than 5 pulses are recorded. As a rule, 10 pulses are obtained, ie more than 5 impulses, but if for any reason an interfering impulse occurs between the two impulses, these are not counted .. Information is obtained at position 12, which normally represents 200 ms, since the fifth impulse is waiting for the count This information is sent through the two gates to two inputs, to gates 8, 9, 10, 11 of device CI-2 and gates 3, 4, 5, 6 of device CI-2 the two devices is present a certificate from the establishment CI-14 .Information, ie that pulses to the rhythm of one pulse per second occur. It is therefore possible to obtain _/ split times, and for this reason can be seen in the height of the devices emit time values that are less than 200 ms, so that information from the circuit CI-14 is obtained at the two free inputs of the two gates, which open each of the two gates during every second, but during a time-defined square pulse, one gate being gated on for a time between 200 and 400 ms and the other gate being gated on for a time between 600 and 800 ms. Because of the symmetry to the central station, the information coming from the line is sent to gates 3, 4, 5 at 6 or to gates 8, 9, 10 and 11 at 8, depending on whether they are at the beginning or at the end of the second in which the circuit responds. Therefore, information appearing here and finally at 2A and 3A indicates that a sequence of response signals has been received, with the received signals at the beginning of the

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Second or at the end of another second, but at the moment you don't know which devices they belong to.

The manner in which a device is identified is shown in FIG. The circuit of FIG. 12 becomes formed by a number of flip-flops 12, for example four times two flip-flops, each pair of flip-flops the Allocation of the response signal of a device to an interrogation signal allowed.

The scheme shown allows four devices to be viewed. So there are two rows of flip-flops that go through the gates 1, 2, 3 and 11, 12, 13 of the circuit CI-6 are controlled will. One gate is determined by information from the circuit 3A and the other by information from the Circuit 2A in Figures 5A and 5B which occurs at 20B and 18B is controlled. That is a first logic condition. The second logic condition is obtained as follows: on the inputs 11 and 12 of the gate 11, 12, 13 of the circuit CI-4 are from the Information originating from decoders CI-5 was recorded. This means that each pair of flip-flops receives a number and with two flip-flops it is necessary that during the counting process at the Number that is assigned to the flip-flop, and that on the other hand, information is obtained that is either at 2OB or 18B should occur, i.e. at this moment you change the state of one or the other flip-flop and this says that at that moment through the transistors of the pair of amplifier transistors one or the other indicator light is controlled.

The invention is not limited to the exemplary embodiment described above. They can also be used for other monitoring tasks, for example for monitoring a distribution network use for gas or oil. It is also used for chemical processes, Te, xti! Processes or other manufacturing processes suitable.

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-ZZ-

It can be seen that the embodiment described above concerns the case in which one is satisfied with a yes / no answer for each device, but one can use the invention also use if you want to receive multiple answers and even graduated answers.

It follows that the present invention is not limited to the exemplary embodiments described, but that it is generally usable and also includes the modifications familiar to the person skilled in the art.

In summary, the structure and function of the invention Describe the system as follows:

The invention relates to a monitoring system with a central station _{/ in} order to monitor changes in the operating status of one or more devices that are assigned to this central station.

A central station (Fig. 5A) continuously feeds accumulator batteries B, which are arranged in one or more of the devices (Fig. B) By operating a switch IC, a certain number suppressed by half periods, whereby those devices are queried, which by the accumulator batteries disconnected from the charge B are fed. A control circuit COC, a logic circuit CL and a sensor CP are provided which Memory and display circuits CAPl ... CAPn are assigned for the response signals of the devices, and the error display device to be monitored INV contains circuits CHA, COM-ELECT and CRE. An interrogation cycle with the duration "T" equals η χ t, where η is the Number of devices and t is the query time for each device there the state of this device is indicated by the position of an amount of pulses that is defined within the time unit t.

The invention is particularly suitable for monitoring distribution networks for electrical energy.

409829/0626

Claims (9)

Patent claims: Monitoring system with a central station for monitoring one or more of these associated devices, with a current path, for example a double line, which connects the devices to the central station for the transmission of query signals from the central station and for the transmission of response signals from each of the devices, characterized in that from the central station (ST) an interrogation signal is transmitted, which triggers the transmission of a signal to all devices (Pl, P2 ... Pn) of an interrogation period, the duration of which is T η times the interrogation time unit "t" for each device and the ordinal number and the state of each device is determined by measuring the time elapsed from the origin of the interrogation signal to a moment in which a response signal is received at the central station, the duration of which corresponds to the time unit "t", and within this time unit the position of another Signals the status of the observed device (open or close ßen. · a contact) and the number "n" of time units "t ^M from the origin of the interrogation signal to the moment of receipt of the response signal indicates the ordinal number of the corresponding device Pn. 2. Monitoring system according to claim 1, characterized in that at the central station (ST) and at each of the devices to be monitored (Pl ... Pn) decade counters (DD, DU) are provided for pulses. 3. Monitoring system according to claim 1, characterized in that the current path (L) is a double line is that continuously from the central station (ST) an alternating current for charging accumulator batteries (B) in each device transmits by means of rectifier circuits. 409 8 2 9/0626 4. Monitoring system according to claim 3, characterized in that the charging current of the Akkumulatorbatterxen (B) in each device for the duration of an interrogation period about the status of the arrangement of the double line (L) assigned Device is interrupted. 5. Monitoring system, characterized in that that the central station (ST) has a feed device for delivering the feed voltage to the double line (L), the feed voltage for the local logic circuit (CL) and a Y voltage for supplying indicator lamps, an arrangement of Logic circuits the delivery of an interrogation signal on the double line and the processing of the then received Information allows control circuitry to display the appropriate information after processing the information received or allow use of this information to control actuators and a control and display device for the received signals. 6. Monitoring system, characterized in that that each device (Pl, P 2 ... Pn) assigned to the double line (L) has an accumulator battery (B) and a corresponding charger (CHA) and an electronic switch (COM-ELECT) that switches off the voltage until the central station a command to trigger an interrogation period about the state of the devices takes place, a logic circuit (CL) the Every device evaluates response signal and control and Display elements (COC) a local check of each device allow. 7. Monitoring system according to claim 1, characterized in that the synchronous progression of the decade counter at the central station (ST) and the various devices (Pl, P2 ... Pn) triggered by a clock signal formed by the frequency of the alternating current that feeds the central station. 409829/0626 8. Monitoring system according to claim 1, characterized in that the command to start a query period with respect to the status of the devices (Pl, ... Pn) is triggered in the central station and is successively transmitted to each device during a time unit, for example one second , ie in η seconds in the case of η
Devices. 9. Monitoring system according to claim 1, characterized in that the beginning of a query period about the state of the devices (Pl ... Pn) by a transformation of the
Feed current for the double line is triggered, which results in the suppression of half-waves of the current during
a predetermined period of time. A09829 / 0626