DE1209140B - Device for electrical remote ignition and remote monitoring of gas-operated point heaters - Google Patents

Description

Equipment for electrical remote ignition and C remote monitoring of gas-operated point heaters L ' The invention, 1 relates to a Einrichtune, for elec- remote ignition and remote monitoring of gas operated point heaters, which per point several Brentis points and associated electrical tric igniters all over a -cmeinsame, up to the soft tissue area Zündstroinversort # unasleituno supplied with power will. To the Vcriiieidtin,) the freezing of points so- as to prevent the formation of Schpee and Ice sheets on turnouts are known to be turnouts heated, devices for electrical remote ignition and remote monitoring of #_ms-operated turnout heizutiL # cii. those from a large number of lighting points and these associated electrical ignition devices tLinL, cn are therefore in different ways forms of leadership known. In the case of a known Führunosform are the ignition devices of all Burning points connected in parallel. You will need di (usually operated at the same time, namely electrical heated up. However, measures are also knows, with such a facility, the power gen consumption for heating the Zündvorrichtun ' to keep it as low as possible. For this purpose, there is set up a Tliermoumschaller aii-arises, which at Er- \ V ;, poor a previously bridged series resistor into the electrical line, for the igniter heater switches, which is so bernessen that the heating current and thus the heat output of this igniter heater so Nveit is set lierally. that with a warm burning point the flame extinguished by accidental influences will still be reignited with certainty. The up to which 2leaded ZiiiidstromversorYun £ isleitun2 must obviously for simultaneous full operation of all ignition devices. That is expensive and often encountered considerable in practice Difficulties. In practice it often says only one for connecting the ignition devices Si "nalkabel small cross-section available in with a length of up to several kilometers to not wear ; possible voltage losses would. In addition, it is known that with such input directions for electrical remote ignition of gas operated switch heating units also take measures Remote monitoring of -as-operated turnouts- tongues to perform. For this purpose z. B. at the wrote a known execution form troll instrument arranged over which the heating current for dieZündvorrielitungen is conducted and that at Switching on the igniter heaters full deflection shows. Obviously, this is not particularly certain, because the control instrument does not recognize it very precisely lets how many igniters are switched on, d. H. whether one or more lighting points have gone out. For this reason, supplementary measures are usually provided by assigning the mentioned thermal switch to a second circuit which is used for additional ignition control and which is switched by the thermal switch. Obviously, this is an additional considerable expense.

The object of the invention is to create a C el b device for electrical remote ignition and remote monitoring of gas-operated point heaters of the single-level type, which works with low power and consequently without cables with a large cross-section and, moreover, in a simple manner and, in a safe way, allows remote monitoring to be carried out if necessary until an extinguished burning point has been identified. This task is achieved according to the invention in that an ignition point switch is arranged in the switch area at the end of the ignition power supply line, which always connects one of the ignition devices to the ignition power supply line one after the other, as well as by arranging a monitoring and display device which is connected to power - or responds to voltage pulses that arise when the ignition switch is switched on and each of which is assigned to one of the ignition devices and is influenced there.

In detail, the invention can be implemented in various ways. A preferred embodiment that is special because of its simplicity and functional reliability Is important is characterized in that the ignition switch the end a rotary selector and a multivibrator, in particular a transistor multivibrator consists of a power stage, in particular a transistor power stage, drives the rotary selector.

The design of the monitoring and display device is detailed Any within the scope of the invention.

A exporting> approximate shape is characterized in that the monitoring and display device has a lying in the ignition circuit current transformer and a connected downstream via a rectifier sense transistor, an energized with current flowing in the ignition circuit Zündstromimpulsen monitoring relay is arranged in its collector circuit. However, there is also the possibility that the monitoring and display device has a transformer located in its own monitoring circuit coupled to the ignition circuit and a measuring transistor connected downstream of this via a Zener diode, in whose collector circuit a monitoring relay is arranged which is activated when the ignition current pulses flow in the ignition circuit. If the individual flames are to be monitored, it is proposed according to the invention to arrange semiconductor resistors serving as flame monitors at the lighting points and to provide the ignition switch with a second contact path, via which it always successively connects one of the flame monitors to a monitoring circuit in which a voltage divider circuit and this over a Zener diode is connected downstream of a measuring transistor, in whose collector circuit a monitoring relay is arranged, which is activated when current pulses flow in the monitoring circuit.

The monitoring systems described detect the fault of any ignition device without any distinction or identification of the faulty ignition device. In the case of a large number of points with even numerous lighting points, there is a practical need to at least be able to differentiate at which point an ignition fault has occurred. This can easily be achieved within the scope of the invention in that a monitoring relay is assigned to each switch and a fault memory relay is connected downstream of each monitoring relay and a query step unit is provided which scans these fault memory relays and which is connected to a synchronously running display step unit with a downstream memory and display device.

The advantages achieved by the invention are mainly in it see that in the device for remote electrical ignition and remote monitoring of gas operated point heaters according to the invention worked with the lowest power there is actually only one ignition device on the ignition controller supply line lies. In addition, remote monitoring is particularly simple and reliable.

Several exemplary embodiments of the invention are shown in the drawings, namely FIG. 1 from a device according to the invention, the circuit diagram of an ignition point switch, F i g. 2 from a device according to the invention, the circuit diagram of a monitoring and display device for general monitoring , FIG. 3 a and 3 b from a device according to the invention, the circuit diagram of a monitoring and display device with flame monitoring in two variants, and FIG . 4 a block diagram for the monitoring of a large number of turnouts with selective fault indication.

The in F i g. 1 , which is arranged in the switch area at the end of the ignition power supply line, the ignition point switch operates periodically, step-by-step. The step mechanism consists of a rotary selector 1 D W, as it is used in telephone switching technology, and a transistor multivibrator with the essential elements 1 T 1, 1 T 2, which periodically excites the excitation coil SP of the rotary selector via a transistor output stage T3.

The time constants 1R1-1C1 and 1R2-1C2 of the astable multivibrator are selected in such a way that an asymmetrical relationship is created with a pause of a few seconds and an excitation time of fractions of a second, within which the SpulelSp is excited and the contact arm of the rotary selector IDW is switched on. In Fig. 1 , two ignition transformers 1 Tr 1 and 1 Tr 4 are shown, to which glow coils Gl are connected. During the pause time, an ignition transformer is connected to the voltage of the intermediate transformer 1 Tr 3 via the contacts of the rotary selector. Not occupied with ignition devices. Contacts, e.g. B. 5 to 9 of the rotary selector IDW are run through in fast reverse without a pause. For this purpose, the negative half-wave of the alternating voltage of the transformer 1Tr3 is fed to the transistor 1T3 via the voltage divider 1R3 and 1R4 and the series resistor 1R5 and the coil 1Sp of the rotary selector is excited. As soon as the contact arm lifts during the switchover, this voltage supply is interrupted again.

The following explanation of the measures for monitoring and display should be preceded by the following: For general monitoring, the control of the current flow in the ignition device is sufficient, since the reliable ignition of the gas is physically guaranteed in principle. The more extensive form of control, on the other hand, undoubtedly consists in monitoring the burning gas flames. In both cases, the monitoring should take place via a cable consisting of only two wires, with which the switch heating and the ignition power supply can be switched on at the same time. The monitoring, which in the case of railway systems is usually carried out from an interlocking, must be used for any ignition current injection, i.e. H. jointly from the signal box or through a separate local network. The monitoring line is always subjected to a base load, albeit a low one, such as current for a solenoid valve to regulate the gas supply, current of the ignition switch and magnetizing current of the intermediate transformers.

The basic idea of the general surveillance according to fig . 2 now consists in using current or voltage pulses above the constant base load for function control or the absence of these pulses as an error message. The F i g. 2 is based on the case that the monitoring and the ignition power supply take place via the same line from the signal box. In practice, the ignition current is around 2011 / o of the base load on the monitoring line, which also supplies the ignition current. The current gap that arises when switching over to the # -> jiizelticii ignition points infolae Fehlerhalterinterrupty of any ignition circuit is detected by a current transformer and a sensitive Tratisistor amplifier. The current-proportional voltage coming from the current transformer 2 W is fed to the measuring transistor 2 T in a suitable polarity after rectification and smoothing, so that it can carry its full current in the collector circuit and keeps the monitoring relay 2Rel attracted. The voltage at the potentiometer 2P, which is directed in the opposite direction to the rectified converter voltage, serves to compensate for the current base load on the Überwitclitin #, sleitiiii # ,. As soon as the ignition current fails. This leads to a drop in the converter span (y below the compensation voltage that was set on the potentiometer 2P. As a result of the reversed polarity of the control voltage C on the measuring transistor 2 T, the monitoring relay 2) Rel is made to drop.

The contact of the relay activates the visual display 2Lp. The capacitor 2C serves not only to smooth the transformer voltage, but also to delay the measuring device, so that it does not already respond to current gaps that occur with the normal periodic Switching of the ignition switch occur, but only with a faulty one Failure of the Ziiiidsti-omes.

If the ignition current feed is separated from the monitoring, the Monitoring and display device and the ignition switch of two separate Networks powered. The ignition current is. as described above, now on the ignition switch measured and an alternating voltage capacitive in the monitoring circuit as the measured variable coupled. The monitoring circuit carries direct current because it also carries the Switching on from the interlocking takes place by means of a DC relay. In the display device the measuring voltage is then taken from the monitoring power line by a transformer coupled and fed to the measuring transistor via a Zener diode. For the nitessuna and display, what has already been said for the case # lemeins2i-.i, lei-feed applies.

A more detailed form of monitoring includes the control of the burning gas flanime, as explained in F i 2. 3 a and ib. A so-called NTC resistor (semiconductor resistor with negative temperature coefficients of the resistor) 3R., Which is assigned to each ignition point and is never heated by the Flain, is used as a flame monitor. According to F i and 3 a, each ignition point is scanned via a zNNviic contact path of the ignition point switch. With a burning flame, i. H. in a hot state of the NTC resistor, the dividing ratio has changed the of the resistors 3R "and 3R0 Spanmingsteilers formed so that the resistor 3 P, sloping Spaniii.ing exceeds the Zener voltage of the Zener diode 3Z, because the resistance of 3R, substantially The voltage divider 3R, and 3R. is only supplied with voltage via the armature contact-t3D1-1 # -IK of the rotary selector when the ignition switch is switched over, so that with every step of the rotary selector and a burning flame, a short current pulse in the collector circuit of the measuring transistor 3T the current pulses occurs 1. "- # iineii aui the monitoring line -and given ', CC # Il as already aeschildert, aernessen and-ezei-i-C who b C to. But it is also possible, as shown in FIG. i a dar-Z, (set to store the error message in a memory relay 3S, t # Zet '. In1101, ge, of a current input, relay 3 Rel 1 picks up and via normally open contact 31a pulls in monitoring relay Me12 The delay formed by the capacitor 3 C and the resistance of the relay coil is so great that the monitoring relay 3 Rel 2 remains attracted until the next current pulse. The meaning (Y of the fault memory relay 3 SRel is explained in more detail below. Due to the form of monitoring just described, C a) the ignition flame (flame monitor), b) the ignition switch, since the current pulses are also absent if the ZD ignition switch is faulty and this leads to an error message.

The described form of monitoring detects the malfunction of any ignition device without any distinction or identification of the ignition device. In the case of a large number of points with even numerous burning points, there is a practical need for monitoring to be able to distinguish at which point an ignition fault, C has occurred. Of particular importance b is the selective display of the disturbed switch in order not to drive too high the effort. For this purpose, reference is made to F i -. 4 referenced. It is a block diagram, the individual blocks of which have been labeled to simplify this description.

Each switch has its own step sound system of the one described Type of ignition point switchover as well as general monitoring with a monitoring relay and a fault memory relay. Should a malfunction occur at any lighting point occur on the ignition, this is detected by the monitoring relay and the Error stored in the error memory relay, the relay picks up. A so-called Inquiry steps in the area of the turnouts (also a rotary selector with transistor drive or controlled by the armature contact of any ignition point switch) gradually scans the fault memory relays of all turnouts and determines them whether a fault memory relay has picked up.

The information from the Abfraaeschrittwerkes is passed on to a display step mechanism, which is located in a control point that is locally separated from the points to be monitored, generally a central control unit. Both step mechanisms run synchronously. Their respective position corresponds to a certain switch that is being scanned at the moment. The information of the display steps are evaluated in a storage and display device. Abfra "e- and Ad-ESCH rode factory in turn are connected only by a two-core cable also work step run-Synchronisierun- so # #;.. Ie the Felilermeldung be by signals on three Verl" C causes different voltage levels. In the embodiment shown in Fig. 4, the power supply comes from the local network2. Netzl supplies the signal box. The connection between the control station (signal box) and the turnouts is via the two-core cable L. The structure of the entire monitoring corresponds to the arrangement already described.

There are no difficulties for the person skilled in the art to carry out the monitoring methods described largely without contact. d. That is, to replace classic relays with electronic switching elements, in particular bistable multivibrators with transistors and the like. Nothing changes in the principle of monitoring. The circuit with relay contacts has been largely used in this illustration, only for a better understanding of the whole. The susceptibility to failure is a function of the existing switching contacts. Outdoor use in particular requires protective measures against harmful climatic influences. By using semiconductor components instead of mechanical contacts, operational reliability can be increased significantly. How far this transistorization should be carried out is solely a question of the economic outlay.

In the circuit diagram F i g. 3 b is, for example, the block diagram for the electrical monitoring according to FIG. 3 a shown. The time constant of a circuit arrangement known as MonovibratorM is chosen so large that the voltage pulses arriving at the input of the monovibrator when the flame is burning prevent the monostable multivibrator from being switched back. Only the absence of the following voltage pulse enables the monovibrator to tilt back and thereby control the downstream bistable fault memory F.

Claims (2)

Claims: 1. Device for electrical remote ignition and remote monitoring of gas-operated point heaters, which has several burning points and associated electrical ignition devices for each point, all of which are supplied with power via a common ignition power supply line leading to the point area, characterized by one in the point area at the end of the ignition power supply line arranged ignition switch, which always successively connects one of the ignition devices to the ignition power supply line, as well as by a monitoring and display device, which responds to current or voltage pulses that arise with the switching of the ignition switch and each of which is assigned to one of the ignition devices and is influenced there . 2. Device according to claim 1, characterized in that the ignition point switch consists of a rotary selector and a multivibrator, in particular a transistor multivibrator which drives the rotary selector via a power stage, in particular a transistor power stage. 3. Device according to claim 1 or 2, characterized in that the monitoring and display device has a current transformer located in the ignition circuit and a measuring transistor connected downstream of this via a rectifier, in the collector circuit of which a monitoring relay is arranged which is attracted to ignition current pulses flowing in the ignition circuit. 4. Device according to claim 1 or 2, characterized in that the monitoring and display device has a transformer in its own monitoring circuit coupled to the ignition circuit and C CD has a measuring transistor connected downstream of this via a Zener diode, in its collector circuit a at im Ignition circuit flowing ignition current impulses attracted monitoring relay is arranged. 5. Device according to one of claims 1 to 4, characterized in that the monitoring and display device has semiconductor resistors arranged at the burning points and serving as flame monitors, and the ignition point switch is provided with a second contact path via which it always successively connects one of the flame monitors to a monitoring circuit , in which a voltage divider circuit and this downstream via a Zener diode is a measuring transistor, in the collector circuit of which is arranged a monitoring relay that is attracted to the current pulses flowing in the monitoring circuit. 6. Device according to one of claims 3 to 5, in which each switch is assigned a monitoring relay, characterized in that each monitoring relay is followed by a fault memory relay and an interrogation stepper which scans this fault memory relay is provided which is connected to a synchronously running display stepper with a downstream memory and display device connected. & C Publications considered: German Patent No. 1088 998.