DE2336110B2 - Circuit arrangement for voltage regulation and current limitation in a free-running flyback converter with thyristor shutdown - Google Patents

Description

output voltage of the flyback converter is determined. The control principle for the output voltage is based on the switching transistor being switched off prematurely and, in addition to the regulation, also provides protection for the switching transistor against excessive output currents. _s

The more precise sequence in the control mechanism in the known circuit arrangement results from the following: The thyristor in the known circuit arrangement is a thyristor tetrode two control electrodes: one on the anode side (Anode.igate) and a cathode-side (cathode gate). It is controlled via the between the anode gate and the anode standing voltage. To influence this voltage, i. H. to control the ignition timing, When this voltage reaches the ignition voltage, two options are available: On the one hand the potential at the anode gate can be changed - if the output voltage of the flyback converter is too high if it is lowered -, on the other hand, the potential in the anode can be changed - if it is too high Current of the switching transistor increases the anode potential. The interaction of the two trigger the ignition Criteria - too high current of the switching transistor, too high output voltage - consists in opposing control of the two potentials. the difference of which trigger the ignition. This difference becomes larger in both cases mentioned, and the ignition riding point occurs earlier.

The cathode gate has no function in the steady state of the circuit. But with that the Thyristor does not ignite when starting the circuit, the cathode gate must be biased negatively. This is done with the diode D7.

If the voltage regulation fails in the known circuit, i. H. can have too large an output voltage of the flyback converter no longer cause or cause a potential reduction at the anode gate of the thyristor If the output voltage is too low a significant increase in the anode gate potential, then a The thyristor ignition required to limit the current can only be triggered by an increased increase of the anode potential. But then the d / u required current can flow through the switching transistor ui. become permissible high.

The present invention is based on the object the interaction of the two criteria triggering the ignition of the thyristor - too high Current of the switching transistor, output voltage of the flyback converter too high - to improve. The two Criteria should be able to support each other in their effects without their trigger mechanisms for can adversely affect thyristor ignition.

In order to achieve this object, the invention is given in a circuit arrangement of the type mentioned at the outset suggested that the connection point of the control path of the switching transistor with the first ohmic resistance is on the reference potential of the comparison DC voltage and thus between the ignition electrode and the cathode of the thyristor, the series connection of the first and second ohmic Resistance comes to lie that a second DC reference voltage with such polarity to the second ohmic resistance is placed, that this second ohmic resistance is a reverse voltage for the thyristor leads, both of which ohmic through the collector current of the comparison transistor to the second Resistance generated voltage as well as the output current of the switching transistor at the first Ohmic resistance generated voltage is opposite, with a certain value of the Collector current of the comparison transistor: and / or the output current of the switching transistor these from them The generated voltages compensate the reverse voltage and after exceeding a threshold voltage let the thyristor ignite.

In the circuit arrangement according to the invention, the two voltages which trigger ignition are connected in series in the same direction and both cause ignition in the same direction. In contrast to the known comparison circuit, the collector current of the comparison transistor when the output voltage is too high of the flyback converter is larger and thus the potential at the control electrode of the thyristor is higher. This means that if the voltage regulation fails, the triggering mechanism of the other criterion - the excessive current of the switching transistor - is not counteracted. By providing the reverse voltage If the output voltage of the flyback converter is too low, this is due to the too low Voltage against the current limiting effect is limited.

The two trigger mechanisms support each other as in the known circuit arrangement but do not affect each other adversely. The maximum current through the switching transistor is independent can be determined by the voltage regulation. In addition, by providing the reverse voltage, the The starting point of the regulation and thus the ignition point more precisely than with the known circuit arrangement determine.

F. An advantageous embodiment of the invention is that the second reference DC voltage to an ohmic voltage divider is placed, which consists of the second and a third ohmic resistor exists and whose division point is connected to the ignition electrode of the thyristor. This allows you to use the reverse voltage at the second ohmic resistor and adjustable via the voltage divider ratio more precisely determine the ignition timing of the thyristor.

The invention is to be explained in more detail using an exemplary embodiment shown in the drawing will:

A DC voltage source, for example a leads directly rectified AC mains voltage, terminals 1 and 2, of which terminal 2 is on Mass lies. An ohmic resistor 3 leads from terminal 1 to a reference potential! for the comparison DC voltage. The emitter of a switching transistor 4 of the npn type is connected to this reference potential. Whose collector is connected to a terminal 27 of a winding 5 of a transformer 6, which with a the other connection is grounded. The base is connected to terminal 1 via the switching path of a thyristor 7 tied together. The base also leads via the series connection of a diode that is polarized in parallel with the emitter-base diode Diode 8 with a capacitor 9 connected in parallel, an ohmic resistor 10 and a feedback winding 11 of the transformer 6 to the reference potential.

The ignition electrode of the thyristor 7 leads via an ohmic resistor 12 to the collector of a comparison transistor 13 of the pnp type. Its emitter is connected to the reference potential via an ohmic resistor 14. There is also one on the emitter Zener diode 22 which supplies the first DC reference voltage

connected.

With one connection of a winding 15, the other connection of which is at the reference potential, are two oppositely polarized diodes 16 and 17 connected, each via a capacitor 18 and 37, respectively lead to the reference potential. The comparison DC voltage is applied to the capacitor 18 and to the capacitor 37 an oppositely directed voltage from which the second DC reference voltage is obtained.

The series connection of an ohmic resistor 19, an ohmic one, is parallel to the capacitor 18 Voltage divider 20 and an ohmic resistor 21. With the tap of the ohmic voltage divider 20 the base of the comparison transistor 13 is connected. Also lies between the emitter and the diode 16 the Zener diode 22. The series circuit of an ohmic resistor 23 is parallel to the capacitor 19 with a Zener diode 24, the series connection of two ohmic resistors 25 and 26 in parallel with the Zener diode 24. The ohmic resistor 26 comes between the reference potential and the ignition electrode of the thyristor 7 to lie.

The connection 27 and another connection 28 of the winding 5 of the transformer 6 each lead over Rectifiers each with one output 29 or 30. The rectifiers each consist of a series diode 31 or 32, from an ohmic cross resistor 33 or 34 and from a cross capacitor 35 or 36. It several such connections with the corresponding outputs are possible, at which the respective DC output voltages are removed.

The diode 16 generates the comparison DC voltage that corresponds to the output DC voltages of the transformer 6 is proportional and is on the capacitor 18. In the comparison transistor 13, this comparison DC voltage is compared with the first DC reference voltage stabilized by the Zener diode 22. The comparison transistor 13 also serves as a control amplifier. Its output current flows through the ohmic Resistance 26.

The second DC reference voltage across the capacitor 37 is stabilized by the Zener diode 24 and divided down with the ohmic voltage divider 25, 26. There is thus a part on the ohmic resistor 26

ίο this second DC reference voltage. Through her It acts as a reverse voltage for the ignition electrode.

Both the collector current supplied by the comparison transistor 13, that through the ohmic resistance 26 flows, as well as the output current of the switching transistor 4, which flows through the ohmic resistor 3, generate a voltage between the ignition electrode and the cathode of the thyristor 7, which is the reverse voltage can compensate and possibly exceed so far that a threshold voltage is exceeded and the thyristor 7 is ignited. The triggering moment for the ignition is either a closed large output current of the switching transistor 4 or a current of the comparison transistor 13, which the result the output voltage of the flyback converter is too high. The comparison transistor 13 decreases, for example if the output voltage of the flyback converter is too high, the effective reverse voltage in the firing circuit of the thyristor 7. As a result, a lower current at the ohmic resistor 3 is sufficient to ignite the thyristor 7 allow. The switching transistor 4 is switched off earlier, so that the stored in the core of the transformer 6 magnetic energy is reduced and the output voltage of the flyback converter drops again.

1 sheet of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for voltage regulation and current limitation in a free-running DC flyback converter with thyristor disconnection, with the DC voltage source a first ohmic resistor, the switching path of a switching transistor and a winding of a Transformer is in series, the control path and the switching path common Pole of the switching transistor is connected to the first ohmic resistor, and a feedback winding of the transformer is in the control circuit of the switching transistor, which continues to be parallel for series connection of the first ohmic resistor and the control path of the switching transistor the switching path of a thyristor and the ignition electrode of the thyristor with the collector of a comparison transistor is connected, which compares one of the flyback converter output voltage proportional comparison voltage with a first DC reference voltage the thyristor then ignite and thus switch off the switching transistor when the output voltage of the Flyback converter exceeds a predetermined value, the output current of the switching transistor voltage generated at the first ohmic resistor influences the ignition point, and in addition, the ignition electrode of the thyristor via a second, in the collector circuit of the comparison transistor lying ohmic resistance with a reference potential for the comparison DC voltage is connected, characterized that the connection point of the control path of the switching transistor (4) with the first ohmic resistance (3) is on the reference potential of the comparison DC voltage and thereby between the ignition electrode and the cathode of the thyristor the series connection of the first (3) and second (26) ohmic resistance comes to lie that a second reference DC voltage is placed with such polarity on the second ohmic resistor (26) that this second Ohmic resistor (26) leads to a reverse voltage for the thyristor (7), which both the dpn Collector current of the comparison transistor (13) generated at the second ohmic resistor (26) Voltage as well as that through the output current of the switching transistor (4) at the first ohmic Resistance generated voltage is opposite, with a certain value of the collector current the comparison transistor (13) and / or the output current of the switching transistor (4) these voltages generated by them compensate for the reverse voltage and after exceeding a Schwellenspannur.g let the Th ;, ristor (7) ignite. 2. Circuit arrangement according to claim I, characterized in that the second reference DC voltage is connected to an ohmic voltage divider, which consists of the second and a third Ohmic resistance (25, 26) and its division point with the ignition electrode of the thyristor (7) is connected. 3. Circuit arrangement according to claim 1 or 2, characterized in that the second reference DC voltage stabilized with a Zener diode (24) The invention relates to a circuit arrangement for voltage regulation and current limitation in a free-running DC flyback converter with thyristor disconnection, with the DC voltage source a first ohmic resistor, the switching path of a switching transistor and a Wickh'jig of a transformer is in series, the pole common to the control path and the switching path of the switching transistor is connected to the first ohmic resistor, and a feedback winding of the transformer in the control circuit of the switching transistor is still parallel to the series connection the switching path from the first ohmic resistor and the control path of the switching transistor of a thyristor and the ignition electrode of the thyristor with the collector of a comparison transistor connected via the comparison of one of the flyback converter output voltage proportional comparison voltage with a first DC reference voltage then ignite the thyristor and thus the switching transistor can be switched off when the output voltage of the flyback converter exceeds a specified value, wherein the voltage generated by the output current of the switching transistor at the first ohmic resistor the ignition timing is also influenced, and in addition to which the ignition electrode of the thyristor has a two th, lie in the collector circuit of the comparison transistor the ohmic resistance is connected to a reference potential for the comparison DC voltage. Such a circuit arrangement is known and for example in the magazine "Funk-Technik" 1971. No. 20, pp. 782 and 784. For the use case of a power supply unit for a television set is there such a circuit arrangement according to its function with »self-oscillating flyback converter with triggered shutdown «. This »triggered Shutdown «results in a favorable switching behavior of the switching transistor. Without this shutdown it would the switching transistor, controlled solely by the feedback, only due to the decreasing base current "starved". The disconnection with the thyristor by short-circuiting the feedback winding, however, not only results in a defined and clear switch-off behavior of the switching transistor, but also an extremely simple control option. The output voltage of the flyback converter can easily be regulated via the ignition point of the thyristor. By comparing a comparison DC voltage that is representative of the output voltage of the flyback converter is, with a stabilized reference DC voltage and this with the help of a control amplifier at the same time acting comparison transistor, the ignition timing of the thyristor can be influenced. the Comparison DC voltage is sent via a voltage divider to the base and via a voltage divider Zener diode connected to the emitter of the comparison transistor. The collector is with the ignition electrode of the thyristor and connected to the reference potential via an ohmic collector resistor. Falls below the collector current and thus the voltage generated by it at the collector resistor a threshold value, then the thyristor is triggered. In addition, the point in time of ignition still depends on the voltage, which is determined by the output current of the switching transistor is generated at the ohmic resistor in series with the switching path of the thyristor will. The ignition point is therefore determined by the level of the output current of the switching transistor and by the