DE2417628B2 - CIRCUIT ARRANGEMENT FOR A SWITCHING POWER SUPPLY WITH CURRENT LIMITING AND VOLTAGE STABILIZATION - Google Patents

Description

In addition, the timing of the ignition depends still depends on the voltage that flows through the load current of the switching transistor at the one of it Ohmic resistance is generated. If this load current exceeds a predetermined value, then the thyristor also ignited Switching transistor as well as the output voltage of the blocking agent determines the principle of control for the The output voltage is based on the switching transistor being switched off prematurely and also causes the Regulation provides protection for the switching transistor against excessive output current.

The exact process in the control mechanism results from the following:, ₅

The thyristor in the known circuit arrangement is a thyristor electrode with two Control electrodes: one on the anode side (anode gate) and one on the cathode side (cathode gate). The control takes place via the voltage between the anode gate and the anode. To influence this Tension, d. H. to control the ignition point when this voltage reaches the ignition voltage, the two options are available: on the one hand, the potential at the anode gate can be changed - at closed large output voltage of the flyback converter, it is lowered -. on the other hand, the potential of the Anode - if the current of the switching transistor is too high, the anode potential increases Interaction of the two criteria triggering the ignition - too high current of the switching transistor, too high output voltage - consists in opposing control of the two potentials whose Difference trigger the ignition. This difference increases in both cases mentioned, and so does the ignition 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.

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 current required for this can flow through the switching transistor become impermissibly high.

In the known circuit arrangement, the locking device consists of one in the control circuit of the Switching transistor located capacitor, which has a diode from an additional transformer winding is fed. At the moment when the thyristor is ignited is, this capacitor is on the control path of the switching transistor and blocks it reliably.

The present invention is based on the task of the interaction of the two the ignition of the thyristor triggering criteria - too high current of the switching transistor, too high output voltage of the Flyback converter - to improve. The two criteria should be able to support each other in their effect, without their trigger mechanisms for the thyristor ignition being able to adversely affect one another. Of the The complexity of the circuitry for the locking device should be kept as low as possible.

This object is achieved according to the invention in a circuit arrangement of the type mentioned at the beginning solved that the Rückkoppjungswindung except for feedback at the same time both to feed the connected to the control path of the switching transistor Capacitor of the blocking device as well as for feeding a further capacitor via a Another diode is used, the voltage at this further capacitor providing the ignition path of the thyristor provides blocking bias, which a voltage supplied by the comparison circuit and the voltage on which the load current flows ohmic resistance counteract the voltage generated until the trigger voltage of the thyristor is reached.

In order to realize the two above-mentioned mechanisms triggering the triggering of the thyristor is necessary in a circuit arrangement that except for the blocking device for the switching transistor that is missing in her The circuit arrangement mentioned at the beginning has already been proposed (patent application file no. Toe. P 23 36 110.6-32), the ohmic resistance through which the load current of the switching transistor flows between the emitter of the switching transistor and the To put the cathode of the thyristor and the ohmic resistance lying at the collector of the comparison transistor between the ignition electrode of the thyristor and the emitter of the switching transistor. As a result, the two resistors come in series between the ignition electrode and the cathode of the thyristor, with the voltages on them, which are supposed to trigger the thyristor firing, have the same polarity and for the ignition can be added. In contrast to the known comparison circuit, the collector current of the comparison transistor increases when the output voltage of the flyback converter is too high, and thus the Potential at the control electrode of the thyristor higher. This means that if the voltage regulation fails the trigger mechanism of the other criterion - the excessive current of the switching transistor - not is counteracted.

In connection with this proposal, it has also been suggested that the thyristor firing path to give a bias counteracting the ignition. This additional bias is the Transformer removed from the flyback converter, stabilized and connected to the collector resistance of the comparison transistor with opposite polarity. The thyristor can then only be ignited if when the voltage triggering the ignition exceeds this blocking voltage By the provision the additional bias voltage is in the case of a too low output voltage of the flyback converter Effect directed against the current limitation because the voltage is too low. The two Trigger mechanisms support each other as in the known circuit arrangement, but can do not affect each other adversely. The maximum current through the switching transistor is independent of the Voltage regulation can be defined. In addition, by providing the additional bias of the Specify the starting point of the control and thus the ignition point more precisely than with the known circuit arrangement.

The circuit arrangement according to the invention with a blocking device combines the advantageous control mechanism of the previous one, a circuit arrangement without blocking device concerned, proposal with

the advantage that a single winding of the transformer fulfills three functions: It is used to generate the reverse voltage for the switching transistor, the feedback voltage and the ignition of the thyristor counteracting bias on the ignition path of the thyristor. On the one hand, this means relatively little effort for the transformer. On the other hand, it is important for the correct behavior of the flyback converter power supply in the event of a short circuit and when idling that these three voltages are in a certain ratio to one another. According to the prior art or according to the earlier proposal, these voltages are taken from different windings and are therefore not subject to exactly the same proportionality conditions with regard to the output voltage of the flyback converter. By generating these three voltages according to the invention from a single winding of the transformer, there is a close tolerance between the three voltages and the output voltage of the flyback converter.

It is known per se from DT-AS 12 46 097, the feedback winding in a voltage-stabilized flyback converter not only for feedback, but also for feeding a capacitor at the same time to use a diode to generate a DC voltage required in the control device. A control voltage is derived from the feedback winding, with which there is a control of the resistor in the feedback branch limits the current through the switching transistor and the Output voltage of the flyback converter can be kept constant. However, this control function is a complete one other than the regulation in the circuit arrangement according to the invention via a thyristor disconnection.

An advantageous embodiment of the circuit arrangement according to the invention relates to the comparison device. This configuration is already present in the earlier proposal mentioned above, but it applies equally for the present invention.

This embodiment of the comparison device consists on the one hand in the fact that the bias voltage blocking the firing path of the thyristor is applied to a divider resistor of an ohmic voltage divider connected in parallel to the capacitor supplying this bias voltage, and that the output current of the comparison transistor flows through the partial resistance in such a direction that the voltage generated by it blocking bias voltage is opposite to the other, this is specifically realized such that the resistance part is parallel to the series circuit of the ignition gap of the thyristor and from the traversed by the load current of the switching transistor ohmic resistor

The invention is to be explained in more detail using an exemplary embodiment of a circuit arrangement according to the invention shown in the drawing will.

A switching transistor 1 of the npn type has its collector connected to one terminal of a working winding 2 of a transformer 3. The other ^ ₀ connection of this working winding 2 leads to an input terminal 4. The emitter of the switching transistor 1 is connected to one connection of a winding 5 of the transformer 3 and is at a potential which is referred to below as the reference potential A ₅ . The other connection of the winding 5 leads via a diode 6 to a capacitor 7, the other connection of which is at reference potential. The transformer 3 carries a further winding 8 as a feedback winding, the first connection of which is connected to the base of the switching transistor 1 Parallel connection of a capacitor 9 with two anti-parallel connected diodes 10 and 11 and via an ohmic resistor 12 connected in series to the reference potential. In addition, the second connection of the feedback winding 8 leads via a diode 13 to the anode of a thyristor 14 and via the series connection of this diode 13 with a capacitor 15 to the base of the switching transistor 1. The cathode of the thyristor 14 is connected to an input terminal 16 and via an ohmic resistor 17 connected to the reference potential. The ignition electrode of the thyristor 14 is connected to a voltage divider consisting of two ohmic resistors 18 and 19 which, starting from the reference potential, leads via a diode 20 to the first connection of the feedback winding 8. In addition, a capacitor 21 is connected in parallel to the steeper voltage 18, 19.

The divider point of the ohmic voltage divider 18, 19 is still via an ohmic resistor 22 the collector of a comparison transistor 23 of the pnp type connected whose base is connected to the tap of a Ohmic voltage divider, which is parallel to the capacitor 7 and consists of three series-connected ohmic resistors 24, 25 and 26, the middle ohmic resistance 25 as adjustable ohmic voltage divider is formed. In parallel with the capacitor 7 is also the Series connection of a Zener diode 27 with an ohmic resistor 28, the ohmic resistor 28 comes to lie between the emitter of the comparison transistor 23 and the reference potential. Between the A capacitor 29 is connected to the base and the Emkter of the comparison transistor 23.

Another input terminal 30 is connected in series with a diode 31 and a capacitor 32 and connected to the base of the switching transistor 1 by an ohmic resistor 33. Between the There is also a connection point of the diode 31 with the capacitor 32 and the input terminal 16 ohmic resistance 34.

A capacitor 35 is also connected in parallel with the ohmic resistor 17. The series connection of three capacitors 36, 37 and 38 with an ohmic resistor 39 is located between the collector of the switching transistor 1 and the reference potential.

The transformer 3 as a further winding has an output winding 40 which is located to one side to ground and four taps has These taps lead in each case via one of four diodes 41 to 44 to one of four output terminals 45 to 48, wherein the output terminals 45 to 48 on each one of four capacitors 49 to 52 are connected to ground. An ohmic resistor 64 is also connected in parallel with the capacitor 49

The circuit arrangement described so far is drawn with a dashed border and forms a until then A power supply unit that can be implemented as a module with input terminals 4, 16 and 30 and output terminals 45 to 48.

The output of one of four diodes is connected to input terminals 4 and 16 Graetz rectifier 65 and, in parallel, a smoothing capacitor '66, an ohmic resistor 53 and another capacitor 54. The input terminals of the Graetz rectifier 65 are each via a Choke 55, 56 with one of the two terminals one

AC voltage source 57 connected. A fuse 58 is located between one terminal of the mains AC voltage source 57 and the choke 55. In addition, the mains-side connections of the two chokes 55 and 56 are connected to one another via a capacitor 59 and the other two connections are connected to one another via a capacitor 60. The series connection of two capacitors 61 and 62 is parallel to the capacitor 60, their connection point being connected to the ground potential. One pole of the AC voltage connection of the Graetz rectifier 65 is connected to the input terminal 30. An ohmic resistor 63 is located between the other and the choke 56.

The load circuit of the Schaluranüistor 1 now consists of the series connection of the working winding 2, its collector-emitter path, the ohmic resistor 17 and the direct current input with the two input terminals 4 and 16. The actual control circuit consists of the series connection of the base-emitter path of the switching transistor 1, the Ohmic resistor 12, the parallel connection with the diodes 10 and with the capacitor 9 and the feedback winding 8.

The control device with the comparison transistor 23 receives a comparison voltage from the winding 5, the rectified via the diode 6 at the capacitor 7. This comparison voltage is generated via the voltage divider 24, 25 and 26 applied to the base of the comparison transistor 23 and with one through the Zener diode 27 generated reference voltage compared. The collector current des resulting from this comparison Comparison transistor 23 flows through ohmic resistor 18.

This ohmic resistor 18 also corresponds to the division ratio of the voltage divider 18, 19 a part of the voltage across the capacitor 21. This capacitor 21 receives its voltage via the diode 20 and via the feedback winding 8.

The blocking device is formed from the feedback winding 8, from the diode 13 and from the Capacitor 15. This capacitor 15 forms the operating voltage source for the thyristor 14 and blocks in the case of the switched thyristor 14, the control path between the base and the emitter of the Switching transistor 1.

The capacitor 21 is charged with a polarity such that the corresponding voltage across the ohmic resistor 18 blocks the ignition path of the thyristor 14. This blocking voltage is applied to the series connection of the ignition path and the ohmic resistor 17, through which the load current of the switching transistor 1 flows.The collector current of the comparison transistor 23, which flows through the ohmic resistor 18, generates a voltage that is opposite to that of the capacitor 21 is directed The voltage that is generated by the load current at the ohmic resistor 17 is also directed in the opposite direction. The bias voltage at the ohmic resistor 18 blocking the ignition of the thyristor 14 can now be compensated so far both by a correspondingly large collector current of the comparison transistor 23 - triggered by an output voltage of the transformer 3 that is too high - and by an excessive load current through the ohmic resistor 17 that the thyristor 14 is ignited. This is the case when either the load current of the switching transistor 1 or the output voltage of the transformer 3 become too great.

A start-up circuit is formed from the input terminal 30, the diode 31, the capacitor 32 and the two ohmic resistors 33 and 34. The input terminal 30 is connected to the AC mains voltage and supplies via the diode 31 and the AC element 32,33 Mains frequency pulses to the base of the switching transistor 1.

At the output terminals 45 to 48 DC voltages of different levels are taken. The present embodiment sees a complete network separation as shown in the drawing the output side of the transformer 3 before. This network separation can of course, if this The request is not made, nor is it made.

In normal operation, the capacitor 15 is via the winding 8 and the diode 13 on one to the Forward voltage of the diode 13 charged reduced voltage. After switching transistor 1 off, in the winding 8 induces a polarity reversed voltage, which across the capacitor 15 with its smaller opposite voltage is at the working path of the thyristor 14 and clears it.

In the event of a short circuit at one of the outputs 45 to 48, the power pack goes from normal operation to one intermittent operation over. In this operating case, the continuous sequence of load current pulses becomes replaced by short pulses in the cycle of the mains alternating voltage frequency. At the same time the collector voltage is of the switching transistor 1 is greatly reduced, so that it is guaranteed that even in the event of a short circuit, the switching transistor 1 is not damaged. The output short-circuit currents must also not be higher than those for the pure diodes allowable currents, so that a destruction of the diodes is avoided. These short circuit currents are determined by the stored in the transformer 3 in this operating state Energy.

In the event of a short circuit at the output, the peak current of the switching transistor 1 rises sharply. That causes the thyristor 14 to fire and the switching transistor 1 to be switched off. The switching transistor 1 can only switch through again when, on the one hand, the thyristor 14 is extinguished again by discharging the Capacitor 15 and on the other hand a starting pulse to the base of the switching transistor 1 is given. In order to is the number of collector current pulses per unit of time that are fed into the transformer 3 are greatly reduced, so that the energy cannot reach the value that the output diodes 41 to 44

can be so dangerous. With the aid of the diode 31, the two ohmic resistors 33 and 34 and the capacitor 32, pulses of about 5 ms duration are formed from the mains alternating voltage. Collector current pulses of the switching transistor 1 are therefore only possible

Ss during this period of about 5 ms. This measure reduces the short-circuit current considerably. The influence of the holding current of the thyristor 14 is then only slight. This results in pulse groups voi individual collector current pulses follow at intervals vo 20 ms of each other.

A special feature is the limitation of the peak collector current of the switching transistor 1 in the event of overload at one of the outputs 45 to 48. The di ignition blocking bias voltage on the ignition electrode of the thyristor 14 is obtained with the diode 20 in the blocking phase of the flyback converter, ie this is voltage output proportional. In the event of a strong overload, the output voltages drop, which means that auc

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the reverse voltage for the ignition path of the thyristor 14 is reduced. This results in an ignition of the Thyristor 14 even with small peak collector currents and thus a reduction in the output currents in case of overload.

When the load is idle at the outputs, the operating frequency of the power supply increases sharply. Will If the load falls below a minimum, the period of the switching frequency is shorter than the time it is released of the thyristor 14. The thyristor 14 then remains ignited for several periods, so that the oscillation of the flyback converter stops. A renewed

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can only oscillate with the next start-up pulse. This results in groups of pulses at intervals of 20 ms even when idling. The ohmic resistor 64 forms a preload for idle operation and prevents the output voltages from increasing too much when the power supply unit is unloaded.

With the aid of the circuit arrangement according to the invention, a switched-mode power supply can be realized with Current limitation and voltage stabilization both for the two extreme cases of short circuit and open circuit as even with overload. The circuit complexity for this is relatively low.

1 sheet of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for a switched-mode power supply with Current limitation and voltage stabilization with one input for a rectified AC mains voltage and with a self-oscillating one Flyback converter, a switching transistor, a transformer, a control device and a Contains blocking device and an alternating voltage from the rectified AC mains voltage generated, with one winding of the transformer as a working winding in series with the input im Load circuit of the switching transistor and a winding of the transformer as feedback winding in the Control circuit of the switching transistor lie, the control device also having a thyristor, the Working path parallel to the series connection from the control path of the switching transistor, from one of the Load current of the switching transistor through which there is ohmic resistance and from a capacitor belonging to the blocking device, and one is present the ignition electrode of the thyristor connected comparison circuit contains such that at a A reference voltage taken from the transformer and rectified by comparison with a reference direct voltage of the switching transistor is exceeded due to ignition of the thyristor is blocked, the blocking device also contains a diode through which the Capacitor is connected to a transformer winding and can be charged in such a polarity, that its voltage blocks the switching transistor when the thyristor is triggered, characterized in that the feedback winding (8) except for feedback at the same time both for feeding the capacitor (15) connected to the control path of the switching transistor (1) Blocking device as well as for feeding a further capacitor (21) via a further diode (20) is used where the voltage on this further capacitor (21) is the ignition path of the Thyristor («4) supplies blocking bias voltage, which is one supplied by the comparison circuit Voltage and the voltage generated at the ohmic resistor (17) through which the load current flows until the ignition voltage of the is reached Counteract the thyristor (14). 2. Circuit arrangement according to claim 1 with a comparison transistor in the comparison circuit, characterized in that the bias voltage blocking the ignition path of the thyristor (14) at a partial resistance (18) of an ohmic voltage divider (18, 19) connected in parallel with the capacitor (21) supplying this bias voltage stands and that the output current of the comparison transistor (23) the partial resistance (18) in a such a direction that the voltage generated thereby flows through the blocking bias is directed in the opposite direction. 3. Circuit arrangement according to claim 2, characterized in that the partial resistance (18) in parallel to the series connection from the firing path of the thyristor (14) and from the load current of the Switching transistor (1) through which the ohmic resistance (17) flows. The invention relates to a circuit arrangement with current limitation and voltage stabilization with an input for a rectified AC mains voltage and ^with a self-oscillating storage converter which contains a switching transistor, a transformer, a control device and a blocking device and generates an AC voltage from the rectified AC mains voltage, one winding of the transformer as a working winding in series with the input in the load circuit of the switching transistor and a winding of the transformer as a feedback winding in the control circuit of the switching transistor Hegen, the control device also having a thyristor whose working path is parallel to the series connection from the control path of the switching transistor, from an ohmic through which the load current of the switching transistor flows Resistance and from a capacitor belonging to the blocking device and a comparison circuit connected to the ignition electrode of the thyristor contains In such a way that if a reference voltage taken from the transformer and rectified via a comparison with a DC reference voltage is exceeded, the switching transistor is blocked by triggering the thyristor, the blocking device also containing a diode via which the capacitor is connected to a transformer winding and can be charged in such a polarity is that its voltage blocks the switching transistor when the thyristor is triggered. Such a circuit arrangement is known. It is described in DT-OS 21 60 659, for example. One Further description can be found in the magazine "Funk-Technik" 1971, No. 20, pp. 782 and 784. Die The function of the circuit is referred to there as "self-oscillating flyback converter with triggered shutdown". This triggered shutdown results in a favorable switching behavior of the switching transistor. Without such a shutdown, the switching transistor, Controlled solely by this feedback, only on the ground of the decreasing base current »starved«. However, the shutdown with the thyristor by short-circuiting the feedback winding does not only result a defined and clear switch-off behavior of the switching transistor, but also a good control option. The output voltage of the flyback converter can be adjusted via the ignition point of the thyristor with the aid of Regulate the control device well. By comparing an equivalent voltage representative of the Output voltage of the flyback converter, with a stabilized reference voltage and this with the help of a at the same time acting as a control amplifier comparison transistor, the ignition point of the Affect thyristor. The comparison voltage is in the known circuit arrangement via a Voltage divider connected to the base and via a voltage divider with a Zener diode to the emitter of the comparison transistor. The collector is with the ignition electrode of the thyristor connected. It also has an ohmic collector resistor, on which the Kotlektor current generates a voltage. Falls below this Voltage exceeds a threshold value, then the thyristor is triggered. The ignition point is therefore dependent on the level of the output voltage of the flyback converter. The fact that when the thyristor is triggered, the switching transistor is blocked and its output current is no longer can increase, the level of the output voltage of the flyback converter is stabilized.