DE3424294A1 - Interrogation device for identification of the position of switches - Google Patents

Abstract

Signalling apparatuses (10) are connected to a central interrogation device (1) via a two-wire line loop (8, 9). The interrogation device has a microcomputer (2), a voltage source (3) with polarity reversing switches (4) for producing low-frequency voltage pulses for the signalling apparatuses (10), an ammeter (5) for measuring the instantaneous value of the current flowing in the line loop, and central display means (7) which are allocated to each signalling apparatus. The signalling apparatuses (10) are constructed such that, when an interrogation pulse arrives, the signalling apparatus which is in each case next to the interrogation device responds, the loop to the subsequent signalling apparatuses is interrupted, and the input terminals are connected to the series circuit of the associated signalling switch (13) and a defined resistor (26). When the next pulse occurs, the interruption of the line loop to the subsequent signalling apparatuses is cancelled. Each signalling apparatus has time-dependent elements (23, 25) which prevent the interrogated signalling apparatus responding again throughout the entire interrogation cycle. The microcomputer (2) controls the display means by evaluating the measured current values in accordance with the pulses. <IMAGE>

Description

Interrogator to identify the position of

Switches The invention relates to an interrogation device for identification the position of switches according to the preamble of claim 1.

Facilities of this type are used to centralize a number of devices to monitor whether they are in operation or due to any malfunction have addressed or are in the switched off or idle state or whether they were used for an alarm message, for example. For this purpose, everyone is to be monitored The device is equipped with a signaling switch which, depending on the operating status of the Device is open or closed. Each of these switches a signaling device is assigned. These reporting devices are connected to an interrogator connected, which polls the individual signaling devices in a cyclical sequence and in this way, the status of the signaling switch is determined centrally.

An arrangement of this type is known from DE-OS 31 50 313, for example. This arrangement is designed so that the signaling devices are connected in parallel a two-wire line are connected to a central interrogation device. Each an address is assigned to these signaling devices, which can be set by means of a number setter can be programmed. The interrogator has an address memory, the end from which the individual signaling device addresses are taken and in the form of direct current pulses are given on the two-wire line, so that the respective addressed signaling device can be selected and the status of the signaling switch assigned to it to the interrogation device reports. The consequence of this is that each of the signaling devices must be "inactive", i.e. one requires its own power supply. In addition, the individual reporting devices are due the need to program addresses and compare the ones programmed in with the received address quite complex. In addition to its own control unit with Clock generator requires an additional input module with receiver and transmitter.

This also applies to an alarm system known from DE-OS 28 36 760, in which the control of the individual signaling devices is not central, but through the device queried is followed by the next, but every device must submit his "message" in a signal pattern of his own.

The invention is based on the object of an arrangement of the above named type in such a way that it is inactive in terms of information technology, i.e. as pure query module works and therefore no power supply of its own needed.

This object is achieved by the invention characterized in claim 1 solved.

This means that not only the cyclical incrementation of the Signaling devices, but also the signal output to the control center without special addressing can be done so that it is not necessary to initially do one for each of the signaling devices manual address setting make what a not insignificant requires organizational effort. In addition, through the information technology Passive function of the signaling devices achieved that for the transfer of information from Signaling device for interrogation device no auxiliary power is necessary either permanently available or had to be supplied and stored cyclically. aside from that the feedback via the switch detection is not influenced by the status of the Query cycle, but is automatically activated in the signaling devices. From it the result is a very simple structure with a corresponding reduction in manufacturing costs. In addition, the switching elements, via which the signaling devices are interconnected, have succeeded and with which the respective controlled signaling device switches off the following by using MOSFET transistors with such low voltage losses, that a relatively large number of, for example, 50 signaling devices in a loop over a distance of 2500 m with a supply voltage of 12 V and one Line resistance of 0.036 Ohm / m can be operated. Besides, it's through the type of information evaluation via a resistance measurement in the interrogation device with the help of an integrated microcomputer possible both the number of connected To determine signaling devices as well as the proper ones by comparison with a target value Check the condition of the line loop at any time.

Advantageous refinements and developments of the invention are characterized in the subclaims.

The measure specified in claim 4 makes it possible to that the interrogator in the signaling devices where the signaling switch is closed can control a luminous message.

An embodiment of the invention is described below with reference to FIG Drawings explained in more detail. The figures show: FIG. 1 a basic illustration of the overall arrangement, FIG. 2 shows a block diagram of a signaling device and FIG. 3 shows a pulse diagram of the voltage output by the interrogator to the reporting loop.

According to Fig. 1, the interrogator 1 includes a microcomputer 2, a voltage source 3, semiconductor pole-changing switch 4, an ammeter 5, a Analog-digital converter 6 and an illuminated display panel 7.

About a two-wire loop with the lines 8, 9 are similar built-up signaling devices 10 connected to the interrogation device 1. Each of the reporting devices has its own illuminated display 11 and connecting lines 12 for connection the switch to be monitored (signaling switch) 13 provided. Each of these message counters belongs to a device 14 to be monitored which is only shown schematically.

The basic structure of the signaling devices 10 results from the illustration in Fig. 2. Each signaling device has two input terminals EO, Ei, two output terminals AO, Al and two signaling terminals CO, Ci. With the exception of the interrogator 1 on the closest signaling device, whose input terminals connect directly to the lines 8, 9 are connected and the last signaling device of the signaling device series, its output terminals are open, the output terminals of the respective preceding signaling devices are connected to the Input terminals of the subsequent signaling devices with the same polarity with one another tied together. The line 9 is from the output terminal of the interrogator 1 to the output terminal Al of the last message devices uninterruptible looped through while the line 8 is arranged in each of the signaling devices identical switching means is performed. These consist of the series connection of the NC contact of a switch 16 assigned to a relay 15 and two between the NC electrode and the output terminal AO antiparallel-connected transistors 17 and 18. One electrode of the excitation coil of the relay 15 is connected to the input electrode EO and the other via a switching transistor 19 with the continuous line 9 tied together. The base of the switching transistor 19 is connected to the SchEesser electrode via a diode 20 of the switch 16 and the collector of a transistors 21 connected. The collector this isolating transistor is via a resistor 22 to the input terminal EO and its emitter is connected to the common line 9. The base of the isolation transistor 21 is connected to a timing control element 23, the connection electrode of which is connected to the common Line 9 and the make contact 16 are connected.

The control electrode of the transistor 17 is connected via a resistor 24 with the common line 9 and the control electrode of the transistor 18 with a connected to the first further timing control element 25 connected in parallel. The two Electrodes of the signaling contact 13 of a device 14 to be monitored are connected to the signaling terminals CO, C1 of the signaling device connected. Terminal C7 is connected to the common Line 9 and the terminal CO via a time-dependent resistor 26 to the normally open electrode of contact 16 connected. The CO signaling terminal is also connected in series the light emitting diode 11 and a constant current regulator 27 are connected to the input terminal EO.

Taking into account the timing diagram shown in FIG in the following the function of the arrangement to be purified. Outgoing from time TO, the microcomputer 2 generates through the cyclic control of the Pole changer 4 a pulse train with a pulse duration and a pause duration of 5 msec each at a voltage U of 12 V and a pulse frequency of 100 Hz. The Microcomputer 2 operates the semiconductor pole changing switch 4 in such a way that the line 8 with respect to the line 9 assumes negative values. As a consequence, that the switching transistors 19 of the signaling devices are in a non-conductive state, so that their relays 15 cannot pick up. The changeover switches 16 are therefore located in the position shown and the transistors 17 are conductive. This has to begin with As a result, the LEDs 11 of those signaling devices whose signaling switch 13 are closed. The central illuminated display panel 7 of the interrogation device 1 does not react to this yet. The central display can only then function occur when the status of the signaling switch 13 each of the signaling devices 10 one after the other is queried cyclically. For this purpose, the microcomputer 2 switches the semiconductor pole-changing switch 4 at time T2, so that the lines 8, 9 are now pulses of opposite polarity received, i.e. the line 8 is opposite to the line 9 during the pulse duration positive. The consequence of this is that initially in the first, i.e. the interrogator 1 on the closest signaling device 10 the relay 15 via the now conductive switching transistor 19 is excited. The relays of the following signaling devices receive via the initially still in the position shown, i.e. the input terminal EO with the output terminal AO connecting changeover contact 16 also this positive Voltage pulse, which, however, is no longer conductive due to the blocking resistance of the Transistor 17 occurring voltage drop and the not yet conductive transistor 18 is not sufficient to activate the relays of the following the reporting devices for Bringing appeal. When the relay 15 of the first signaling device is energized, switches the contact 16 reverses and completely disconnects the following signaling devices. Above the normally open contact of the switch 16 are now the timers 23 and 25 in the Operation set so that with the set running time of the timing elements the transistor 18 and the isolation transistor 21 become conductive. This causes the relay 15 to drop out prepared, but holds on to the make contact of the changeover contact 16 and the Diode 20 and the conductive switching transistor 19 initially still themselves.

When the signal contact 13 is closed, the between the signal terminal CO and the normally open electrode of the changeover contact 16 connected time-dependent Resistor 26 effective, so that after about 2 msec between the input terminals EO and E7 a current depending on the size of this resistance flows. This stream will measured by the ammeter 5 of the interrogation device 1, by the analog-to-digital converter 6 digitized and entered into the microcomputer 2. This notes that im controlled first signaling device a current of a certain amount and time dependency flows, which means that the alarm switch 13 is closed. The microcomputer evaluates this message in such a way that the addressed first message device the associated signal lamp of the illuminated display panel 7 is in operation as long as until the result for the signaling device in question in the next query cycle either is confirmed or corrected.

At the end of the positive pulse at time T3, relay 15 drops and its changeover contact returns to the position shown. Through this the switching transistor 19 is blocked and remains due to the time constants of the Time control element 23 in the locked state until the end of the query cycle. Of the Transistor 18 against remains due to the time constants of the Time control element 25 also conductive until the end of the query cycle. In order to is the line 8 between the input terminal EO and the output terminal AO of the respective queried signaling device except for the low contact resistance of the transistor 18 major: go.

When the next positive pulse occurs at time T4, it pulls now the relay 15 of the next signaling device and the process described is repeated accordingly in this and the next following reporting devices. To When the last positive impulse is terminated, there is a pause during which the timing elements 23, 25 reach their original state again with sufficient certainty. While During this pause the negative impulses described at the beginning can take effect, to keep the LEDs 11 of the individual signaling devices in function. After completion After the break, all signaling devices are in their basic state again and a new polling cycle is started can begin as described.

It is of course possible to replace the relay 15 with its switch 16 corresponding electronic switching elements to be used. On the other hand, instead of of the electronic control elements 17, 18, 19, 21 also include electromechanical means used if this proves to be appropriate on a case-by-case basis.

5 claims 3 figures - Empty'ite -

Claims (5)

Claims 1. Arrangement for identifying the position of switches with an interrogator including a microcomputer and a display device and signaling devices assigned to each switch to be monitored (signaling switch), which are connected in series via a two-wire line loop with the interrogation device are connected in such a way that each signaling device automatically responds to its own enables the next signaling device to respond, which is no longer possible shows that the interrogation device (1) emits a pulse (3, 4) to generate low-frequency voltage pulses (query pulses) for the Signaling devices (10), an ammeter (5) for measuring the instantaneous values of the due to the voltage pulses in the line loop total current flowing, an analog-to-digital converter (6) for converting the analog measured current values in digital form and their feed to the microcomputer (2) and controlled by this Has display means, the number of which corresponds to the number of connected reporting devices and the position of the determined as a function of the assigned signaling device Signaling switch (13) come into operation, and that the signaling devices (10) for the purpose their response in cyclical sequence when a pulse occurs three switching means of which the second (ins, 16) and the third (18) with passive timing elements (23, 25) are provided, and the first (17) and the electrically connected in series second switching means (15, 16) respond when a pulse occurs, such that the first switching means (17) with the help of its blocking resistor to the flow of current the following reporting devices so reduced that their switching means no longer respond can and the second switching means (15, 16) itself during the duration of the pulse itself, interrupts the line loop to the following signaling devices and the associated signaling switch (13) via a resistor (26) to the input terminals (E0, El) connects, and thereby its own timing element (23) and the timing element (25) of the third switching means (18), with the result that the second switching means (15, i6) opens after termination of the pulse and for the duration of the entire Query cycle remains open and the third switching means (18) when it occurs of the next pulse responds and the blocking resistance of the first switching means (17) short-circuits for the duration of the entire interrogation cycle. 2. Arrangement according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the first and third switching means are antiparallel-connected transistors (17, 18) and, as the second switching means, one provided with a changeover contact (16) Relays (15) are used. 3. Arrangement according to claim 1 or 2, g e k e n n -z e i c h n e t d u r c h such a control of the pulse generator (3, 4) that between two sampling cycles Pulse pauses of selectable length are inserted. 4. Arrangement according to claim 3, d a d u r c h g e -k e n n z e i c h n e t that the pulse generator consists of a voltage source (3) and one from the microcomputer (2) controlled pole-changing switch (4) for reversing the pole of the interrogation pulses during the breaks is formed between the interrogation cycles, so that one in the circuit of the to be monitored Switch (13) of each signaling device (10) arranged display means in the form of a Light-emitting diode (11) with a constant current regulator (27) when the signal switch is closed (13) responds continuously. 5. Arrangement according to one of the preceding claims, d a d u r c h e k e n n n n e i c h n e t that the circuit in each signaling switch (13) arranged resistor (26) is controlled as a function of time so that it is with a starting with a high value, reaching its normal value after about half the pulse duration.