DE1955701B2 - Flasher circuit alternately flashes AC signal lamps - using triac coupled directly to AC and thyristor oscillator controlling second full wave rectifier - Google Patents

Abstract

The flasher circuit alternately flashes two a.c. signal lamps using a thyristor and a triac. The triac is coupled between the first lamp and one supply terminal and is controlled from a main transformer first secondary. The output of the transformer second secondary is rectified and used to supply the transistor control circuit that turns a thyristor on and off. The thyristor determines the voltage applied by a second rectifier bridge to the second lamp. The second rectifier bridge is connected to the same supply points as the first lamp and triac. The thyristor and its control circuit operate together as an oscillator.

Description

The invention relates to an electronic switching device for alternating flashing of alternating current Signal lamps using a control voltage for a first or second closed circuit when the control voltage is switched on or off. Such switching devices are generally used for identification in railway signal systems of different operating states, e.g. B. for controlling substitute signals required.

In the simplest case, the switching devices mentioned can be built with a relay that is operated by the keyed control voltage is actuated. One or the other lamp circuit is connected to a working or normally closed contact of the relay switched. However, such a switching device has the disadvantage that in the absence of a control voltage one circuit remains permanently closed and thus the one in this one The signal lamp lights up continuously. In addition, the relay contacts are subject to wear, the requires undesired maintenance for the switching device.

The use of electronic contacts in such electrical flasher signalers is already out of the DT-AS 11 59 823 known and further described in DT-AS 10 90 556. The last-mentioned explanatory document deals with an electrical switching device for alternate flashing of two signal lamps, in contrast, the flasher signal generator is self-controlled as in the subject of the first-mentioned disclosure document the subject of the application, which is an electronic switching device for alternating Flashing is from AC-powered signal lamps that are externally controlled. The reason for that is that that all switching devices provided in a certain district of a railway system for alternate flashing should work with the same frequency and phase position. However, this way of working is not possible if the individual turn signal heads are self-regulating.

In the second-mentioned previously known electronic switching device for alternating flashing of two signal lamps, the self-controlled switching device consists essentially of a multivibrator circuit with two transistors as electronic switches, each with a signal lamp in their collector circuits is provided. It is disadvantageous with regard to the use in railway safety engineering Systems that in the event of a defect due to a short circuit in the switching path of one of the two transistors, the associated The signal lamp lights up continuously, creating an undesirable signal image. Besides, the Circuit not very suitable, the alternating flashing in frequency and phase position from a central point to influence her.

The electrical flasher signal generator known from DT-AS 11 59 823 is due to the use of a Multivibrator circuit with two controlled by these Power levels for the two signal lamps are also self-regulating and cannot be centrally synchronized will. Each of the power stages consists of a thyristor controlled by a double base diode. in the main circuit of which the switching path of a transistor is located, which also has the double base diode controls and is operated by the multivibrator itself. This circuit is also disadvantageous in that in the event of a defect in the multivibrator circuit, i.e. in an interruption of the control, one of the two signal lamps is constantly lit and therefore also a faulty signal image is generated, which i..i.id At the very least Can lead to stoppages.

For this reason, a switching device is to be created that without mechanical contacts to Controlling the alternate flashing gets by, and then neither of the two signal lamps are switched on remains if the gated control voltage is longer than that for a fault, especially in the event of a fault The blinking pause provided for the signal lamp remains switched off.

According to the invention the object is achieved in that in the second circuit in series with the signal lamp a rectifier bridge circuit is located, the DC branch of which has a thyristor, in which Control circuit, the switching path of a first transistor is connected to the control voltage chargeable capacitor is fed and that the base electrode of the first transistor with the Switching path of a second transistor is connected, the base electrode of which is fed back to the direct current branch and which the first transistor both when the control voltage is switched on and when it is ignited Thyristor blocks. In this switching device, in the first circuit, which is switched on Control voltage should be closed, a triac can be used, which also requires no maintenance.

An embodiment of the invention is explained in more detail with reference to the drawing. The electronic switching device for alternately flashing two signal lamps L 1, L2 essentially consists of two different circuits 10, 20. The alternating voltage for powering both circuits is supplied via terminals 1 and 2. At terminals 3 and 4 there is a control voltage that is keyed with a flashing frequency, in the exemplary embodiment an alternating voltage. This feeds the primary winding Wt of a transformer W. On the output side, this transformer has two galvanically separated windings W2, WX which are sufficient to operate the electronic switching elements of the two lamp circuits 10, 20.

(Supply each control voltage, in the circuit 10 of the signal lamp L I there is a triac 5, which is triggered when the control voltage is present via the voltage divider R \, R2 . If the control voltage is missing, the triac 5 is in a high-resistance state, so that the circuit 10 is then separated is.

The second circuit 20 with the signal lamp Ll should always be closed when the control voltage at the terminals 3.4 is interrupted by the keying. As an electronic switch in this power circuit to is essentially a rectifier bridge circuit GL 2, the alternating current branch connected in series with the signal light L 2 to the terminals 1 and 2 is in the direct current branch of the bridge rectifier circuit GL 2 provided isi a thyristor 6, which in the ignited state short-circuits the direct current branch. A current then flows in circuit 20, the magnitude of which depends on the resistance of signal lamp L 2. In the control circuit of thyristor 6, there is the switching path of a transistor Tl, whose supply energy is taken from a capacitor C2 when the control voltage is switched off. When the control voltage is switched on, the capacitor C2 is charged indirectly via the secondary winding IV3, to which a rectifier bridge circuit GL 1 is connected. The diode D 1 is used for decoupling. The base electrode of the transistor 71 is connected to zero potential via the visual path of a further transistor 72. As soon as the transistor T2 is switched through, the transistor 7 "1 is blocked so that no current can flow in the control circuit of the thyristor 6. Further details of the switching device according to the invention are explained in more detail below together with the mode of operation.

First of all, it is assumed that the control voltage at terminals 3 and 4 has been completely switched off for a long time. The two circuits 10, 20 are then de-energized because, on the one hand, the triac 5 and, on the other hand, the thyristor 6 are not in the conductive state. After switching on the keyed control voltage, control voltage should initially be present at terminals 3 and 4 for the period of the switch-on phase. Then, as already described above, the triac 5 is ignited and the signal lamp L 1 lights up. On the other hand, the control voltage rectified by the rectifying bridge circuit GLl and smoothed by the capacitor Cl acts via the voltage divider R 3, /? 4, RS and 7 on the control input of the transistor T2, which turns on. In addition, the capacitor C2 is charged via the diode D1, and the transistor 71 receives supply energy via the resistors RS and R 6, respectively. However, since the transistor 7 "2 has switched through, the base electrode of the transistor Ti is at zero potential so that it cannot deliver any control current for the thyristor 6. For this reason it is not ignited and the circuit 20 initially remains switched off.

During the subsequent switch-off phase, the control voltage remains switched off and accordingly the circuit 10 through the 1 riac 5 is opened. Since the capacitor C1 has only a very small capacity, its voltage practically approaches the value zero when the control voltage is switched off. The diode D1 prevents further charging from the charged capacitor C2. Since there is no longer any control-effective potential at the base electrode of the transistor T2 , the switching path of the transistor 72 becomes highly resistive. This means that the base electrode of transistor 71 is no longer at zero potential, so that this transistor switches through. From the charged capacitor C 2, in addition to the control current through resistor R 5 for transistor 71, a current flows through resistor R 6, the switching path of the transistor 71, the resistor R 7 and the resistor R 8 or the diodes 7. The voltage drop across the resistor R7 is sufficient to ignite the thyristor 6, which then becomes conductive and closes the circuit 20 indirectly via the rectifier bridge circuit GL 2

The capacity of the capacitor C2 must be dimensioned so that the absorbed during the switch-on phase Charge is sufficient to supply the transistor 71 with energy during the switch-off phase and thereby the continuous ignition of the thyristor 6 i>; guarantee. As a result, capacitors are used, especially at very low flashing frequencies quite high capacitance values have to be used. This would create an undesirable spatial Expansion of the switching device will be inevitable.

It is a known fact that a thyristor must be re-ignited whenever the over current conducted to him becomes zero even for a short time. In the direct current branch of the thyristor 6 of the present Switching device is the current because of the full-wave rectification in each period of the AC voltage for the signal lamp L 2 necessarily twice briefly to zero. It has been assumed that the transistor 71 remains switched through and supplies the thyristor 6 with sufficient control energy. Through this it is re-ignited after each zero crossing. Since after an ignition process to maintain of the current in the direct current branch of the thyristor does not require any additional energy in the control circuit is, the duration of the current in the control circuit of the thyristor via the Schaltstreckc of the transistor 71 are limited, namely to the moments at which the current in the direct current branch of the thyristor becomes zero. This limitation is achieved by a kind of negative feedback. To this Purpose, three diodes 7 are provided in the direct current branch of the thyristor 6, on which when ignited Thyristor 6 a voltage drop occurs, which has a control effect on transistor 72 via resistor A4. As a result, the transistor 72 becomes conductive without the presence of the control voltage and switches the Transistor 71 off.

As soon as the direct current through the thyristor 6 becomes zero, the voltage at the diodes 7 disappears, so that the switching path of the transistor 72 becomes high-resistance again and that of the transistor 71 becomes low-resistance again. The thyristor 6 is ignited again and then blocks its control circuit again as described via the transistor 72. Instead of the three diodes 7, a zener diode can also be free. The resistor R 8, which is connected in parallel with the three diodes 7, has the task of preventing the transistor Tl from being switched off again shortly before the thyristor 6 is switched on. Dvirch the described limited energy extraction from the capacitor C2 for controlling the thyristor 6 is achieved in an advantageous manner that only a relatively small capacitance has to be provided for the capacitor C 2.

If the control voltage at terminals 3 and 4 is interrupted longer than the switch-off phase provides, is the one during the previous switch-on! ase energy stored in capacitor C 2 to

> smokes, and the thyristor 6 can no longer ignite. This ensures that the Sijnallampe L 2 does not light up if the control voltage fails or if the control voltage is constantly switched off.

The invention is not limited to the exemplary embodiment shown. Apart from the use of other electronic components with the same effect, a DC control voltage can also be used instead of the AC control voltage, which is keyed at a flashing frequency. The transformer W, the rectifier bridge circuit GL 1 and the capacitor CI can then be omitted in the switching device according to the invention. Furthermore, more than one signal lamp can be provided in each of the two circuits 10 and 20.

1 sheet of drawings

Claims (1)

Claim: ^ Electronic switching device for alternating flashing of alternating current-fed signal lamps using a control voltage gated at a flashing frequency for a first or second circuit closed when the control voltage is switched on or off, characterized in that in the second circuit (20) in series with the signal lamp (L 2) a Rectifier bridge circuit (GL 2) whose DC branch has a thyristor (6), in whose control circuit the switching path of a first transistor (Tl) is located, which is fed by a capacitor (C2) that can be charged when the control voltage is switched on, and that the base electrode of the first transistor (ΤΊ) is connected to the switching path of a second transistor (Γ2) whose base electrode is fed back to the direct current branch and which blocks the first transistor (Ti) both when the control voltage is switched on and when the thyristor (6) is triggered.