DE2445080A1 - Blocking oscillator with diode in series with switching transistor - includes resonant circuit to prevent current returning to supply - Google Patents

Abstract

The blocking oscillator has a switching transistor, a transformer and a rectifier in the secondary circuit of the transformer. The primary of the transformer lies in the transistor collector circuit and together with a capacitor forms the resonant circuit. A diode (D1) is connected in series with the transistor (T1) and the capacitor (C1) of the resonant circuit (L1, C1) is connected between the end of the transformer winding end coupled to the transistor and to the emitter of the transistor. The diode prevents current flowing back over the transistor to the supply network after the collector voltage has dropped to zero.

Description

Circuit arrangement for a flyback converter The invention relates on a circuit arrangement for a flyback converter with a switching transistor, a transformer and a secondary rectifier arrangement, the im Collector circuit lying primary transfer winding together with a capacitor forms an oscillating circuit.

In contrast to the ideal flyback converter, which theoretically has no power loss works, the real flyback converter has the problem that during the Switching considerable power losses arise in the transistor.

This is because the current and voltage across the transistor do not match change by leaps and bounds. In this way, current flows while there is or is still a high voltage on the Transistor lies. In general, there is therefore an effort to reduce the switching losses to reduce additional circuit measures.

So it has already been proposed that the primary transfer development should be carried out by to add a capacitor to a resonant circuit. The voltage on the transformer is then roughly sinusoidal and symmetrical around the operating voltage with a small load.

When the voltage at the transistor is zero, a suitable base control is used In each case the transistor switched on just before a positive collector voltage and a Collector current can flow. This will reduce the switch-on losses already significantly reduced. In addition, the resonant circuit capacitor prevents during the turn-off time of the transistor a rapid increase in the collector voltage, so that a relatively small current-voltage product occurs and with it the turn-off losses stay small.

Converter power supplies of the type mentioned must, however, often work with a very wide input voltage range. The circuit must be dimensioned so that the collector oscillation voltage also at the maximum Operating voltage still has a zero crossing. Otherwise the switching transistor was no longer switched on. If, however, there is only a lower operating voltage, so it takes a relatively long time from the zero crossing of the voltage to the renewed one Charging the inductance with the transistor conducting.

Because as soon as the transistor is switched on, the rest can be done through it the stored energy flows back into the network; before charging the transformer inductance the same amount of energy must again be fetched from the network via the transistor will. The transistor is put under additional load as a result, and it is also long idle times reduce the efficiency of the converter.

These dead times fall in particular when the input voltage is low important, since the rise curve of the collector current depends on the operating voltage is. With a low input voltage this rise curve is particularly flat; The lead time until the inductance is charged is correspondingly long.

The object of the invention is to provide a flyback converter with a resonant circuit transformer to improve so that it has particularly low switching losses, in particular the dead times between discharge and charge even with a large operating voltage range the transformer inductance can be kept as low as possible and the interference voltages are reduced as much as possible. According to the invention, this is the case with a flyback converter Type mentioned at the outset achieved in that a diode in series with the switching transistor is arranged.

This diode, which is expediently in the collector branch of the transistor prevents feedback after the collector voltage has crossed zero via the transistor into the network. If the operating voltage is low, the alternating voltage overshoot, so that the stored energy quickly within the resonant circuit is implemented. This shortens the dead time until the transformer winding is charged, the switching sequence and thus the performance of the sperm rectifier increases. In order to the transistor is also prevented from being loaded by additional currents.

In addition, the shorter dead times result in a closer approximation the Schwingsparmung to the sinusoidal; thereby the harmonic content, i.e. the Interference voltage, reduced.

In an advantageous development of the invention, it is also provided that the capacitor of the transformer oscillating circuit between the switching transistor facing coil end and the emitter of the switching transistor is arranged. By this switching measure is achieved so that the primary-side charging capacitors do not are loaded with current pulses with a high edge steepness. The primary sieve means thus receive a higher proportion of the fundamental wave, but a lower proportion of harmonics the switching frequency, so that there is a low interference voltage in the HF range.

Further details of the invention are given below with reference to the description an exemplary embodiment explained in more detail.

1 shows a simple circuit arrangement for a circuit according to the invention Reverse converter, Fig. 2 shows the course of the oscillation voltage and the collector current, once without and once with the diode according to the invention.

1 shows a circuit arrangement for an inventive Medium frequency switching power supply. The mains AC voltage is applied to terminals 1 and 2, which can fluctuate between 100 V and 275 V, for example. Via a bridge circuit B, the mains voltage is rectified, so that the operating DC voltage is applied to terminals 3 and 4 U3 is present. A capacitor C3 is used for primary-side screening.

The operating voltage U3 is on the actual flyback converter, the essentially from the switching transistor Ti, the transformer with the primary winding L1 and the secondary winding L2 as well as the diode D2 exists. To the secondary side The charging capacitor C2 is also used for filtering. This creates at the output terminals 5 and 6 the rectified output voltage UA.

The primary transformer winding L1 forms one with the capacitor Cl Oscillating circuit, the oscillation voltage of which is symmetrical to the DC operating voltage UB. The zero crossing of the approximately sinusoidal oscillation voltage is established via a control loop of the transformer resonant circuit and used to turn on the transistor.

A voltage regulator provides the transistor T1 with a base current for as long until the energy consumed on the secondary side is fed to the transformer winding L1 is. For this purpose, an auxiliary winding L3 is provided on the transformer, which The respective actual value of the secondary voltage via the diode D3 and the resistor Ri forms on capacitor C4. This actual value is fed to the operational amplifier V1 and compared with a target value, which is determined by the Zener diode Z and the resistor R2 is formed. If this voltage regulator determines that the output voltage is too is low, it offers the transistor T1 a corresponding base current.

However, to the transistor T1 only in the area of the zero crossing Controlling the oscillation voltage is still a residual voltage control with the Operational amplifier V2 and the transistor T2 are provided. With the help of the voltage divider R3 and R4, which is the transformation ratio between the primary winding L1 and corresponds to the auxiliary winding L3, a true image is produced on the operational amplifier V2 the voltage generated by the transistor. As soon as the residual voltage on the transistor T1 falls below a certain level, the transistor T2 is blocked and the transistor T1 switched on. The resistor R5 on the op amp causes this to happen already occurs at a voltage slightly above zero.

As mentioned, the transistor is about the base square wave voltage respectively switched on in the area of the zero crossing of the collector voltage. Around this zero crossing To always be able to use, the circuit must be designed so that even at a maximum possible operating voltage still a zero crossing of the oscillation voltage occurs. But it is Operating voltage is then relatively low, so the Collector voltage to zero early; the transistor will then already be switched on, although the energy stored in the resonant circuit has not yet been reduced is. If one now allows that current is fed into the network via the switched-on transistor T1 can flow back, a relatively long dead time elapses before the primary transformer winding LI is reloaded. Through the diode D1 in the collector circuit of the transistor T1 however, this feedback is avoided. This allows the oscillation voltage over the Swing zero point out into the negative range, which becomes stored energy implemented in the resonant circuit itself and thus the inductance can be much faster reloaded.

The effect of the diode D1 is illustrated with the aid of FIG. The course of the oscillation voltage and the collector current is over time applied. Curves a and b show the relationships that exist in a flyback converter prevail without the diode according to the invention.

The oscillation voltage UL increases like the collector voltage at point A. Zero. It is assumed that the operating voltage U3 is relatively low, see above that at point A the peak of the oscillation voltage has not yet been reached.

In hiçt A, i.e. at the zero crossing of the oscillation voltage or shortly before, the transistor is now switched on via the control circuit. Is now the inventive If the diode is not present, the collector current Ic becomes negative and the one that is still present Resonant circuit energy fed back into the network (curve b). However, the same energy must then fed back from the network via the transistor into the resonant circuit will. This takes a relatively long time, especially when the operating voltage is very low, because the increase in the collector current depends on the operating voltage. Only in Point B is the end of the reloading time, so the oscillating circuit has the energy present in point A is taken up again, and only then does it begin actual charging time tL for the transformer winding. The reloading time is the longer, the lower the operating voltage, because on the one hand the zero point of the oscillation voltage the sooner it is reached and since, on the other hand, the slope angle of the collector current depends on the operating voltage. At point C is the charging of the transformer winding ended and the transistor is switched off via the control circuit. The charging time tL is different, depending on how much energy was consumed in the secondary circuit and must be adjusted accordingly.

Curves c and d show the voltage and current ratios when the diode D1 according to the invention is connected in series with the transistor T1 (FIG. 1). The resonant circuit voltage UL again becomes zero at point A, and the transistor becomes switched on. But now the diode is fed back into the network via the transistor prevents the voltage swings into the negative range and the stored Residual energy is converted within the resonant circuit. The collector current needs Therefore, it should not be built up again from scratch, but rather it jumps in Point B equal to a positive value, so that the charging time of the resonant circuit coil starts earlier.

Because of the overshoot of the voltage UL, the dead time becomes significant abbreviated. In addition, the transistor is not loaded with the recharging current.

The circuit must be designed so that the oscillation voltage at maximum Operating voltage U3 is just about zero, so that point A in the apex of the Voltage UL is present. The diode according to the invention is only ineffective in this limit value, since then there is no feedback into the Network done. With all the rest Operating voltage values, especially at very low ones, have the effect shown the diode on. So it is especially useful for a very high input voltage range of Advantage.

The design of the flyback converter with resonance transformer and control loop Fig. 1) furthermore ensures that the power supply is available in the event of a short circuit in an output voltage is switched off. In this case, the voltage at the resonance transformer breaks together, the collector voltage of the switching transistor no longer becomes zero and this means that the switching transistor can no longer be switched on via the internal control circuit Even if the operating voltage is too high, the power supply switches off, since then the collector voltage of the switching transistor is also no longer zero and the switching transistor can no longer be switched on.

The capacitor of the resonance transformer is parallel to the FIG Transistor switched. This is a load on the primary-side screen means with Current pulses with high edge steepness avoided. High frequency harmonics of the switching frequency are therefore only weakly available, so that interference suppression is easily possible.

2 claims 2 figures

Claims (2)

Claims 1. Circuit arrangement for a flyback converter with a switching transistor, a transformer and a secondary rectifier arrangement, the primary transformer winding located in the collector circuit of the switching transistor together with a capacitor forms an oscillating circuit, d a d u r c h e k e n n z e i c h n e t that a diode (D1) in series with the switching transistor (T1) is switched. 2. Circuit arrangement according to claim 1, characterized in that the capacitor (C1) of the resonant circuit transformer (LI, C1) between the switching transistor (T1) facing end of the transmitter coil (L1) and the emitter of the switching transistor is arranged.