DE8914703U1 - Main/secondary filament switch for AC-powered double filament lamps in traffic signal systems - Google Patents

Abstract

The main/standby filament switch is controlled by a main filament monitor. The latter is constructed as an optocoupler (U1) which is coupled on the input side, e.g. in the form of a transformer (T2), to the main filament circuit. The switching transistor of the optocoupler is at a DC voltage and, when it is set, short-circuits a light-emitting diode, which is at a supply voltage, or separates its supply circuit. This light-emitting diode is the transmitting diode of an electro-optically controllable AC switch (U2), whose receiving diodes are connected via the standby filament (NF) of the lamp (L) to the supplying current supply device (T1). When current is flowing through the light-emitting diode, the AC switch switches through an AC switch (TR) arranged in the circuit of the standby filament. The main/standby filament switch has exclusively electronic switches for carrying out the switching processes required. <IMAGE>

Description

Siemens AG

89 G 2 9 2 5 EN

Main/secondary filament switch for AC-powered double filament lamps in traffic signal systems

The innovation also relates to a main/sub.fmdsnum switch according to the generic term of the protection claim i.

Double-filament lamps are almost exclusively used to illuminate the signal lamps in railway signals. One of these lamp filaments is the so-called main filament, over which the bulge usually occurs, and the other is the so-called secondary filament, which is automatically switched on when the main filament burns out and then takes over the task of the burned-out main filament. Main/secondary filament changeover switches are used to switch from the main filament to the secondary filament, which detect the current flowing over the main filament and, when there is no current, i.e. when the main filament has failed, switch the respective secondary filament on. The main/secondary filament monitors are usually designed as relays and are arranged near the signal lamps to be monitored (DE-PS 34 16 612).

In order to keep the costs for such main/secondary thread monitors as low as possible, electronic main/secondary thread switches have already been developed (DE-PS 11 81 792), which do not require the use of expensive special relays. In these electronic main/secondary thread switches, separate indicators are connected to the main and secondary thread circuits of the signal lamps, which detect the lamp current flowing there. As long as the main thread is lit, the indicator controlled by it switches an electronic switch in the supply circuit of the secondary thread to a high resistance and only when the supply current via the main thread falls below a lower limit is the switch in the circuit of the secondary thread closed and the secondary thread switched on. This well-known main/secondary thread switch requires a whole series of electronic and electrical components to operate.

01 01

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components and is therefore relatively complex.

89 G 2 9 2 5 EN

The aim of the innovation is to provide an electronic main/secondary thread switch according to the generic term of claim 1, which requires as few inexpensive components as possible that have been tried and tested in practice and is therefore extremely reliable.

The innovation solves this problem through the characterizing features of claim 1. Advantageous embodiments of the innovation are specified in the subclaims.

An example of the innovation is explained in more detail below using the drawing.

The drawing shows a signal lamp L designed as a double filament lamp with a main filament HF and a secondary filament NF, as used for railway light signals. The signal lamp is fed via cables drawn thick in the drawing from a lamp transformer Tl, for example, located near the signal lamp, which can be connected to voltage as required via supply lines from the remote signal box and thereby supplies the lamp with lamp current. The primary winding of a current transformer T2 is connected in series with the main filament, to whose secondary winding the anti-parallel-connected transmitting diodes of an optocoupler Ul are connected via a current-limiting resistor. If the lamp current flowing through the main filament is sufficiently high, the transmitting diodes of the optocoupler Ul are current-carrying and control an associated switching transistor to the low-resistance switching state. This switching transistor is connected to a direct voltage that can be tapped at the output of a rectifier circuit G, which in the example is derived from the alternating voltage that can be tapped at the secondary side of the power supply device Tl. The

Switching transistor of the optocoupler Ul controls in conductive

state an electronic switch Sl connected downstream, for example a field effect transistor, into the conductive state in which it short-circuits the transmitting electrode of an optoelectronically controllable switching current switch uz} of the eiek-

01 02

··· &iacgr;' ^: j~ '··'··' 89 G 2 S 2 5DE The electronic switch Sl and the transmitting diode of the electronic alternating current switch U2 are also connected to the voltage which can be tapped at the rectifier G.

The electronic AC switch U2 is used to switch an electronic AC switch TR, preferably a triac, arranged in the circuit of the secondary filament NF to a low or high resistance depending on the operating state of the main filament. The receiving diodes of the electronic AC switch

The diodes of the AC switch U2 receive their supply voltage via the secondary filament NF from the power supply device Tl that feeds the lamp. The current flowing through them is set so low by series resistors that the secondary filament does not light up when the transmitting diode of the AC switch U2 is de-energized.

In the assumed configuration, the switch Sl has short-circuited the transmitting diode of the alternating current switch U2. The potential present at the control input of the alternating current switch TR is not able to switch the alternating current switch to low resistance and the secondary filament of the signal lamp L remains dark.

If the main filament HF of the signal lamp burns out, the switching transistor of the optocoupler Ul becomes high-resistance and switches the electronic switch Sl to the non-conductive state. Current now flows through the transmitting diode of the electronic alternating current switch U2 and switches the associated receiving diodes to low-resistance. This supplies the control input of the triac TR with a potential sufficient to switch this switch through. When the triac switches through, the supply circuit of the signal lamp, which is led via the secondary filament NF, becomes low-resistance and the signal lamp lights up via its secondary filament.
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To identify the switched-on secondary filament, an optocoupler U3 is provided, the transmitting diode of which is connected in series with the transmitting diode of the electronic AC switch U2. As long as the main filament of the signal lamp is lit,

01 03

.!. : -y- *·'· ··· 8962 92 5DE the switch Sl shorts the transmitting diodes of the electronic AC switch U2 and the optocoupler U3, so that the switching transistor of this optocoupler has a high resistance. Only when the secondary filament is switched on does the transmitting diode of the optocoupler U3 carry current and the switching transistor has a low resistance.

If you want to monitor the lighting of the main filament of the signal lamp in the signal box, the transmitting diode of a corresponding optocoupler must be connected in series with the switching circuit of the switch Sl or with that of the switching transistor of the first optocoupler Ul.

In the embodiment shown, the electric

electronic switch Sl short-circuits the transmitting diode of the electronic AC switch !J2 when the supply current flows through the main filament HF. However, the arrangement can also be such that in this case the switch Sl breaks the supply circuit for the transmitting diode of this AC switch.

In contrast to the embodiment shown in the drawing, the switching transistor of the optocoupler Ul can also directly short-circuit the transmitting diode of the optoelectronically controllable alternating current switch U2 or break its supply circuit. Due to the ripple of the voltage supplied to the transmitting diodes of the optocoupler Ul, a very low pulsating direct voltage can be tapped off at the switching path of the optocoupler switching transistor. In order to prevent the optoelectronically controllable alternating current switch U2 from switching through as a result of this direct voltage, a capacitor must be connected in parallel to the switching path of the optocoupler switching transistor to smooth out this voltage. If necessary, a Zener diode must be connected in series with the transmitting diode of the optoelectronically controllable alternating current switch U2, the Zener voltage of which must be at least equal to the voltage across the capacitor when the optocoupler switching transistor is switched through. This Zener voltage is added to the forward voltage of the transmitting diode of the optoelectronically controllable AC switch and prevents the passage of the main compartment when the main compartment is lit.

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i 89 G 2 92 5EN

control this switch.

In the above-described embodiment of the innovation, the supply voltage for the anti-parallel connected input diodes of the optocoupler Ul is tapped off from the secondary winding of a current transformer T2, the primary winding of which is in series with the main filament of the signal lamp. In deviation from this embodiment, it is also possible to tap off the voltage for the transmitting diodes of the optocoupler Ul from a load, for example a resistor, which is in series with the main filament of the signal lamp. A single light-emitting diode can also be used as the transmitting diode of the optocoupler Ul.

The new main/secondary thread switch comes with a minimum of inexpensive and proven in practice

electronic components and is designed in such a way that monitoring messages for both the main and the secondary thread can easily be obtained by inserting further electronic components.
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9 Protection claims
1 figure

01 05

Claims (9)

&bull; '"6 89G2S2 5QE Protection claims 1. Main/secondary filament switch for alternating current-fed double filament lamps in traffic signal systems, in particular in railway light signals, with a lamp current-controlled main filament monitor assigned to each signal lamp for switching on the secondary filament when the main filament burns out, characterized in that the main filament monitor is designed as an optocoupler (Ul) in &iacgr; of HaT* ainnon/iesAifin f rane Pnrmof nri cnh on Hon Uoiinf faHon. circuit or is parallel to a load connected in the main filament circuit, that the switching transistor of the optocoupler (Ul) is connected to a direct voltage and in the set state directly or indirectly short-circuits at least one light-emitting diode connected to a supply voltage or breaks its supply circuit, that this light-emitting diode is the transmitting diode of an optoelectronically controllable alternating current switch (U2), the receiving diodes of which are connected to the feeding power supply device (Tl) via the secondary filament (NF) and, when current flows through the light-emitting diode, switch through an electronic alternating current switch (TR) arranged in the feeding circuit of the secondary filament. 2. Main/secondary filament switch according to claim 1, characterized in that the optocoupler (Ul) is connected on the input side via the main filament (HF) of the signal lamp (L) to the power supply device (Tl) of the signal lamp and has two anti-parallel connected input diodes. 3. Main/secondary thread switch according to claim 1, characterized in that the switching transistor of the optocoupler (Ul) in the connected state sets an electronic switch (Sl) for short-circuiting the at least one transmitting diode of the optoelectronically controllable alternating current switch (U2). 4. Main/secondary thread switch according to claim 3, characterized in that the switching path of the opto- 01 06 · t 89 G 2 92 5EN fir coupler switching transistor a capacitor connected in parallel &rgr; is. j 5. Main/secondary thread switch according to claim 3 or 4, d a - i characterized in that with the ij at least one transmitting diode of the optoelectronically controllable
AC switch (U2) a Zener diode is connected in series, the Zener voltage of which is at least equal to the voltage at the '"*'- switching path of the set optocoupler switching transistor .; or tin capacitor. -; 6. Main/secondary thread switch according to claim 1 or 3, d a - ^ characterized in that with the at least a light emitting diode of the optoelectronically controllable AC switch (U2), with the switching path of the electronic
switch (Sl) and/or with the switching distance of the first.
Optocoupler switching transistor, the light emitting diode of at least one further optocoupler (U3) is connected in series, the
Switching transistor used to trigger a monitoring message.
20 7. Main/secondary thread switch according to claim 3, characterized
characterized in that the electronic switch (Sl) is designed as a field effect transistor. 8. Main/secondary thread switch according to one of claims 1 to 7,
characterized in that the supply voltage for operating the direct current components of the
Main/secondary thread switch can be tapped at a rectifier (G) which is connected on the input side to a signal lamp (L) supplying lamp transformer (Tl). 9. Main/secondary thread switch according to claim 1, characterized by
characterized in that the electronic AC switch (TR) is designed as a triac.
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