DE4201744A1 - Extra circuit for LV halogen lamp adaptor - carries out forced interruption of oscillation at end of each mains half-wave - Google Patents

Abstract

The circuit adaptor is of half-bridge converter type, and has a short circuit for energising a LV halogen lamp. The circuit reacts to each operational mode, such as normal operation over a large load range, as well as to operation with overload and short circuit. In order to exclude a continuous oscillation over more than one mains half-wave, an extra circuit actuates a forced interruption of the oscillation at the end of each mains half-wave. Pref. a pnp-transistor charges, in inverse operation, a capacitor via a resistor, the capacitor being charged during the mains half-wave to a voltage of a Zener diode in parallel with the capacitor. USE/ADVANTAGE - Firm coupling of adaptor converter even at very large power and short circuit, limited to single mains half-wave oscillation.

Description

The invention relates to an additional circuit in one Switched-mode power supply according to the preamble of patent claim 1. Low-voltage halogen lamps are powered by a transformer or switched-mode power supply that supplies current and voltage put. With a switching power supply that is in the load range of a maximum load to minimum load in a ratio of 2: 1 works by appropriate dimensioning of the be knew half-bridge converter and the known short circuit circuit the necessary functions, such as tearing off the Vibration of the half-bridge converter with regulating entry fen to fulfill the short circuit and also also brightness control through variable phase control to reach. However, this known circuit is not able to handle large load ranges in a 5: 1 ratio to ensure the aforementioned functions.

The invention is therefore based on the object set circuit for a switching power supply to operate Nieder Developing halogen lamps that cause solid Coupling the half-bridge converter also the switching power supply with very large outputs and short circuits no more as a network half-wave swings through and then new again must be ignited.  

This object is achieved by the in the license plate of the specified features solved.

The advantages achieved by the invention are that now also for large load ranges of switching networks share the above type for low-voltage halogen lamps full protection is achieved. Possible flickering of the closed lamps and short-circuit hazards safely avoided.

An embodiment of the invention is shown in the drawing figures 1 to 6 and is explained in more detail below in connection with the known circuitry features. It shows:

Figure 1 is a schematic diagram of a known half-bridge converter with ignition circuit.

FIG. 2 resulting waveforms from FIG. 1;

Fig. 3 is a schematic diagram of a known short circuit;

FIG. 4 shows a resulting waveform from FIG. 3;

Fig. 5 is a schematic diagram of the additional circuit according to the Invention in connection with the known circuitry features of Figs. 1 and 3;

Fig. 6 resulting waveforms of Fig. 5.

Referring to FIG. 1, the AC line voltage is rectified 230 volts at the rectifier GL and each half cycle starts at the beginning, the capacitors C _1, C ₂ and R _Z of the ignition capacitor C _Z charge. If the voltage at C _Z exceeds the ignition voltage of the diac, a current flows into the base of transistor T ₂ ; the transistor T ₂ closes and draws current from C ₁ via T _{r1 on the} primary side and T _{r2 on the} primary side. The feedback windings of the toroidal transformer T _r2 are polarized so that there is now a voltage at the base-emitter path of the transistor T ₂ , which supports the current flow, but a reverse voltage is present at the base-emitter path of the transistor T ₁ . At the collector of T ₂ the voltage is very close to ground potential; C _Z is therefore discharged via diode D. The state continues until the toroidal transformer T _r2 saturates. The current through T ₂ decreases, the voltage at point C rises, and thus the closing of T ₁ and the opening of T _{2 are} initiated. So it is a self-oscillating half-bridge circuit. From the resulting waveforms of Fig. 2 it can be seen that at the end of the half-wave due to the low voltage at point A and thus also in the middle, formed from the capacitors C ₁ and C ₂ , the current through T _r1 and T _r2 not is more sufficient to generate a necessary base voltage in the coupling turns for closing the transistors. The vibration breaks off. After charging the ignition capacitor C _Z, the cycle begins again.

The respective starting of the oscillation has the advantage that a variable Phases cut by changing the time constant of R _Z and C _Z in a relatively simple manner and thus also obtains a brightness control for the circuit.

In the meantime, a circuit has also become known for secondary-side short-circuit protection, as is shown in FIG. 3 with the resulting waveform in FIG. 4. From this it can be seen that in the event of a short circuit the capacitor C _{L is} charged via the resistor R _L (R _L «R _A ; R _B ). The transistor T _K closes and prevents charging of C _Z. There is no vibration initiation during the discharge time of the capacitor C _L. At the end of the discharge phase, the on-resistance of the collector-emitter path of the transistor T _K becomes higher and finally the voltage at C _Z reaches the breakdown voltage of the diac. Fig. 4 shows the short-time operation of the transistors over half a network half-wave τ _n , the pause time (for heat dissipation) can be dimensioned via the resistors R _A and R _B and is current proportional.

The moment when larger power ranges from the switching network be challenged with this simple scarf problems. Prerequisite for perfect function in all situations the vibration is torn off because only in this case can the short circuit regulate intervene or can a brightness control by varia blen phase control. As at the beginning This condition can already be mentioned in a performance assessment rich in a ratio of 2: 1 through appropriate dimensions tion of the half-bridge and the short-circuit circuit reached with a performance range in the ratio 5: 1 however, no longer, for the following reasons: the feedback must be one even with a low collector flow so firmly that with the first firing pulse on The natural vibration at the beginning of the network half-wave  puts. If this were not the case, one would get a change selfless swinging use of the flickering of the Hellig would make the connected lamps noticeable. With However, the firmer coupling required is also used for Available base voltage from the feedback winding at the end of the half wave and thus the current in the Base larger so that even with small collector emitters tensions the natural vibration is maintained. The Ignition pulse is no longer present, the circuit oscillates continuously, and in the event of a short circuit or a large overload, this leads to destroy the transistors.

On the other hand, the U _{BE of} the transistors decreases with the existing heat during device operation. As a result of this and due to the heat-related increase in I _C / I _B , the threshold from which a swinging takes place slips down to small values. This means that when this start-up occurred in the cold state when there was a short circuit, it can also happen with increasing heat at full load. It is also necessary that the short circuit is maintained, otherwise a start of the device with cold lamps would take long times with the relatively simple construction of the half-bridge converter.

For these aforementioned reasons, it must be concluded that only a forced interruption of the oscillation in the zero crossings of the network half-wave can overcome the difficulties without having to accept other losses in the quality of the known circuit. This interruption of the oscillation in the zero crossing of the network half-wave is subject-matter of the invention and as an additional circuit 5 c in Fig. 5 in connection with the previously described self-oscillating half-bridge circuit 5 a and short circuit 5 b Darge provides.

The wiring of this additional circuit 5 c is to be carried out with appropriately dimensioned electronic components. From the bridge voltage E ( FIG. 5a), C _LE is charged to the Zener diode voltage as long as the potential at E is higher than at the Zener diode ZD. This can be done without further res via an inverse operation of the transistor T _LE , so that in this case the resistor R _V2 from the scarf device can be omitted. If the voltage at point B ( FIG. 5a) drops below the Zener voltage, the collector-emitter path of the transistor T _{LE is} closed and a current flows into the base of the transistor T _U. The collector-emitter path of the transistor T _U closes and at the base of the transistor T ₂ only the voltage U _{CESAT of} the transistor T _U remains, and thus a _{further oscillation} of the half-bridge circuit is prevented. The discharge time τ _E ( FIG. 6) of the capacitor C _LE via the resistor R _V1 and the base-emitter path of the transistor T _U is in any case shorter than the charging time of the ignition capacitor C _Z via the resistor R _Z ( FIG. 5a), so that this additional circuit does not change anything in normal operation on the oscillation time per half-wave of the half-bridge circuit. In any mode, that is normal operation over large Lastbe rich, operation with overload, short circuit directly, etc., this additional circuit 5 c guarantees a forced shutdown of the oscillation at the end of the network half-wave, so that the influence of the ignition with C _{Z is} preserved. This of course also continues to offer the possibility of dimming manually by increasing the series resistor R _Z ( FIG. 5a) or automatically dimming down when the temperature rises in the device by inserting a PTC thermistor between R _Z and C _Z. In the event of a continuous direct short circuit at the converter secondary terminals or a short circuit at the end of a connected secondary line, the additional circuit according to the invention limits the oscillation to half a network half-wave; then he gives himself a pause until the next ignition, which is determined from the charge level and discharge time of R _L C _L and C _L R _A R _B.

Claims (3)

1. Additional circuit in a switching power supply with half-bridge converter principle and short-circuit protection for low-voltage halogen lamp controls, which responds to any operating mode, such as normal operation over a wide load range, as well as operating with overload and short circuit, characterized in that to avoid continuous vibration An additional circuit ( 5 c) causes a forced interruption of the oscillation at the end of each network half-wave via more than one network half-cycle. 2. Additional circuit according to claim 1, characterized in that via a resistor (R _V2 ) a capacitor (C _LE ) during the mains half-wave to the voltage value of the Zener diode (ZD) connected in parallel with (C _LE ) from the capacitive center (C ₁ , C ₂ ) the half-bridge circuit ( 5 a) is charged and at the end of the half-wave via a pnp transistor (T _LE ), the base voltage of which is then lower than the emitter voltage, and via a discharge time-determining resistance (R _V1 ) is discharged so that the collector of the pnp transistor drives a current into the connected base of an npn transistor and with the then closing collector-emitter path of the npn transistor the base-emitter path of a switching transistor (T ₂ ) during the discharge time ( τ _E ) is short-circuited ( Fig. 6). 3. Additional circuit according to claim 1 and 2, characterized in that the transistor (T _LE ) charges the capacitor (C _LE ) via the resistor (R _ST and R _V1 ) in inverse operation and the resistor (R _V2 ) is omitted.