DE9417978U1 - Dimmable electronic ballast - Google Patents

Description

Description

The invention relates to a dimmable electronic ballast with a rectifier stage, a boost converter, a push-pull oscillator and an output stage.

Such a ballast enables a reduction in power consumption through electronic control. This is achieved in particular by the boost converter, as a sinusoidal current consumption from the mains is guaranteed.

The object of the invention is to directly control the ballast by means of a light sensor.

This object is achieved according to the invention in that a light sensor is connected to the control input of the push-pull oscillator.

The invention differs from the prior art in that the light sensor influences the control voltage of the push-pull oscillator and thus the frequency. This makes it possible to directly regulate the light output.

A particularly simple circuit is obtained by having the light sensor with a light-dependent resistor and inserting it into a branch of a voltage divider for the control voltage at the control input.

Safe operation of the fluorescent tube is achieved by feeding the voltage of the output stage back to the control input via a gate. This limits the minimum power of the fluorescent tube.

A power adjustment of the boost converter is achieved by the fact that the light sensor is also connected to the feedback branch of the boost converter.

An embodiment of the invention is explained using the associated circuit diagram.

A rectifier stage 1 with a suppression circuit is connected to the AC voltage network. The rectifier stage 1 is shown as a bridge rectifier with full-wave rectification.

In the boost converter 2, a capacitor Cl is charged via a choke Ll. The transistor Tl is triggered by the high frequency voltage of the push-pull oscillator 3. Feedback to the base of the transistor T2 takes place via the resistors Rl and R2. The boost converter ensures a stable operating voltage and a sinusoidal current draw from the mains.

The push-pull oscillator 3 contains two output transistors T3 and T4. The frequency is determined by the internal resistance of the transistor T5, so that the frequency can be influenced by controlling this internal resistance.

An output stage 4 comprises an oscillating circuit consisting of the inductance L2 and the capacitor C3, which is connected in series to the heating coils of the fluorescent tube 5.

A circuit 6 for power supply contains a voltage divider made up of resistors R8, RIO. A light sensor 7 with a light-dependent resistor is connected in parallel to resistor RIO. Resistor R9 is used to adapt the circuit to the characteristic curve of the light sensor. Voltage divider R8, RIO sets the bias voltage of the base of transistor T5 of the push-pull oscillator via D4, so that the frequency of the push-pull oscillator is influenced via the internal resistance of transistor TS. Increasing the frequency leads to a reduction in light output.

The light sensor 7 is connected to ground via resistors R6, R7 and to the base of the transistor T2. As the frequency increases, the base voltage of the transistor T2 is increased, so that the power of the boost converter 2 is reduced. As the illumination measured by the light sensor increases, the resistance of the light sensor is reduced, so that the base voltage at T2 increases. By reducing the base current of the transistor T5, the frequency is increased and the power is reduced. The increase in frequency reduces the current through the fluorescent tube 5 and increases the current

via the capacitor C3, so that increased heating occurs. This creates stable operating conditions. If the lighting intensity is reduced, the direction of change is reversed.

A phototransistor has an inverse dependence of resistance on the illumination, so that the circuit must be designed accordingly.

Line 8 returns the voltage at choke L2 via a gate UlA to the base of transistor T5 to ensure a minimum setting of the illumination at 25% of the tube power.

The resistor R9 is used to adapt to the characteristic curve of the light sensor.

The ballast ensures energy-saving operation depending on the brightness. The illuminance of the fluorescent tube is individually regulated according to the respective light incidence. The circuit ensures that the power factor is always greater than 0.96.

The circuit can be adapted to other light sensors. Replaceable caps for the light sensors allow the pre-selection of an individual lighting value.

Claims (5)

Expectations 1. Dimmable electronic ballast with a rectifier stage, a boost converter, a push-pull oscillator and an output stage, characterized in that a light sensor (7) is connected to the control input of the push-pull oscillator (3). 2. Ballast according to claim 1, characterized in that the light sensor (7) has a light-dependent resistor and is inserted into a branch of a voltage divider for the control voltage at the control input. 3. Ballast according to claim 2, characterized in that the voltage of the output stage (4) is fed back to the control input via a gate (UlA). 4. Ballast according to claim 2 or 3, characterized in that the light sensor (7) is also connected to the feedback circuit of the boost converter (2). 5. Ballast according to one of claims 1 to 4, characterized in that the light sensor is designed as a phototransistor.