EP0620700A1 - Electronic ballast - Google Patents

Abstract

A circuit arrangement for radio-frequency operation of a low-pressure discharge lamp LL contains a voltage supply 10, a lamp generator 20, a switching transistor T2 and a control circuit 30 having a pulse-width regulator 32. For regulating the width of the switching-on pulses of the switching transistor T2, an instantaneous voltage provided by a current-limiting circuit 34 is compared with a reference voltage, the reference voltage being limited by a voltage limiting circuit 36 when overvoltages occur at the switching transistor T2. The control circuit 30 is supplied, before the discharge lamp LL is switched on, by a starting circuit 40 and, during operation of the discharge lamp LL, by a secondary inductance L10. <IMAGE>

Description

The present invention relates to a circuit arrangement for the high-frequency operation of a low-pressure discharge lamp.

Ballasts for high-frequency low-pressure discharge lamps have the task of controlling the preheating of the lamp electrodes before the discharge lamp is ignited and the lamp operation after the ignition. For this purpose, the current flow in the lamp circuit is determined by the switching behavior of a switching transistor, which in turn is controlled by a control circuit. The following problems occur when operating such ballasts:

The switching transistor has to conduct the current through the lamp circuit both in the preheating phase before ignition of the discharge lamp and during lamp operation. In the event of malfunctions, overvoltages can occur due to the switching inductances contained in the lamp circuit, which can destroy the switching transistor if the reverse voltage is exceeded. It is to reduce the risk of transistor breakdown in the event of overvoltages possible to use transistors with high reverse voltage, which is disadvantageous, however, since such transistors with high reverse voltage are characterized by a deteriorated switching behavior.

However, there is a risk of overvoltages not only during the ignition phase, but also during lamp operation if, for example, the lamp fails or the power is interrupted for other reasons.

Another problem is that reliable ignition behavior and uniform lamp operation can only be achieved if the components used in the lamp circuit correspond as closely as possible to their nominal data and work with long-term stability. This requires the use of relatively expensive components with low manufacturing tolerances.

The object of the present invention is therefore to provide an improved circuit arrangement with which a safe starting behavior of low-pressure discharge lamps and safe lamp operation under protection against overvoltages and overcurrents is made possible.

This object is achieved by a circuit arrangement for the high-frequency operation of a low-pressure discharge lamp with the features contained in the main claim. Advantageous embodiments of the circuit arrangement according to the invention result from the subclaims.

The structure and function of an exemplary embodiment of the circuit arrangement according to the invention are described in detail below with reference to the attached FIG. 1.

1 shows, as circuit components of the circuit arrangement according to the invention, a voltage supply 10, a lamp generator 20, a control circuit 30, which is the pulse width regulator 32, the current limiting circuit 34 and the voltage limiting circuit 36, and a start-up circuit 40. These modules are described in detail below.

The voltage supply is designed as a standard rectifier circuit, which consists of the bridge rectifier D1 - D4 and the downstream smoothing capacitors C1, C2. The rectifier is supplied with mains voltage.

The lamp generator 20 is constructed as a single-ended high-frequency generator with a switching transistor T2. The lamp generator contains a lamp resonant circuit (L1, L2, C4, C5) which is formed by the switching inductance L1 and a series resonant circuit consisting of the resonant capacitor C4, the auxiliary inductor L2 and the heating capacitor C5.

The function of the series resonant circuit (C4, L2, C5) is that when the lamp is not yet ignited, an increased voltage across the capacitor C5 has a favorable effect on the ignition, while on the other hand the auxiliary inductance L2 serves to reduce the lamp current peak value during lamp operation.

The clock frequency of the switching transistor T2 is selected so that it corresponds to the resonance frequency of the lamp resonant circuit (L1, L2, C4, C5).

The power supply to the lamp generator 20 takes place via the lamp electrode LE1 of the low-pressure discharge lamp LL, so that, in the event of lamp failure, e.g. B. by a blown electrode or other interruption, the entire circuit arrangement remains free of voltage.

The switching transistor T2 operated with the resonant frequency of the lamp resonant circuit (L1, L2, C4, C5) is controlled by the pulse width controller 32, which is the actual control component the control circuit forms. The pulse width controller 32 has both the function of generating the switching clock for the switching transistor T2 and also comparing an actual voltage derived from the lamp generator with an internal target voltage and regulating the width of the switch-on pulses of the clocked switching transistor T2 accordingly. The TARGET voltage can be permanently set via an internal reference voltage source REF.

The actual voltage is generated using the current limiting circuit 34. For this purpose, the voltage drop across the emitter resistor R4 of the switching transistor is rectified and smoothed and applied to the control input IST of the pulse width regulator 32. The function of the current limiting circuit 34 is such that when the current through the switching transistor T2 increases, the voltage across the emitter resistor R4 rises, so that the level of the ACTUAL controlled variable increases in comparison with the TARGET voltage, whereupon the pulse width controller 32 increases the width of the switch-on pulses of the switching transistor T2 reduced. This ensures that the current through the transistor T2 and the current through the lamp generator 20 are kept almost constant, so that the power of the fluorescent lamp LL and thus its brightness is constant. As a result, the phenomena, which have an adverse effect on conventional ballasts, such as. B. mains voltage fluctuations or component tolerances (especially in the switching inductances) can be eliminated. The use of cheaper components with higher tolerances is made possible, at the same time avoiding production-related performance differences between several devices provided with the circuit arrangement according to the invention.

The control circuit 30 further includes a voltage limiting circuit 36, which serves to avoid overvoltages on the switching transistor T2. For this purpose, the collector voltage of the switching transistor T2 is applied to the base of the transistor T1 via a voltage divider R2, R3. If one is exceeded critical voltage at the collector of the switching transistor T2, the base-emitter voltage of the transistor T1 is also exceeded, so that it becomes conductive and thus the internal reference voltage applied to the pulse width regulator input SOLL is reduced. The ACTUAL control variable derived from the emitter resistor R4 is compared with a reduced TARGET voltage and the transistor ON time is accordingly reduced until the voltage at the collector of the switching transistor T2 has dropped below the critical value.

The control circuit 30 requires a supply voltage of around 16 V. During the operation of the fluorescent lamp LL, this supply voltage is supplied by the secondary inductance L10 of the switching inductance L1. Before the fluorescent lamp LL is ignited, the supply voltage is provided by the starting circuit 40.

The start-up circuit 40 is connected to the mains voltage supply via the resistors R10, R11 and the lamp filaments LE1, LEZ. The capacitor C7 is charged via the resistors R10 and R11. When the breakdown voltage of the diac D5 is reached, the thyristor T5 is ignited and the energy stored in the capacitor C7 is delivered to the control circuit. As soon as the voltage supply through the secondary inductor L10 supplies sufficient current, the thyristor T5 remains fired. Otherwise, T5 blocks after capacitor C7 has discharged and charging of C7 begins again.

The connection of the charging resistors R10, R11 of the capacitor C7 via the lamp filaments LE means that the circuit cannot attempt to start if the lamp filaments LE1, LEZ are defective. As a result, the functionality of the heating filaments is automatically checked when the lamp is started up, so that the circuit arrangement according to the invention can only start operation with an intact fluorescent lamp LL.

A ballast for operating low-pressure discharge lamps of low power is created by the circuit arrangement according to the invention. This is advantageous because, for. B. the currently valid regulations in Germany allow the operation of electronic ballasts up to an input power of 25 W without a separate circuit for harmonic reduction is necessary.

However, it is possible to provide the voltage supply shown with a radio interference filter depending on the power size and limit value specification.

Circuitry modifications of the illustrated embodiment of the circuit arrangement according to the invention are conceivable. So z. B. the mains voltage supply emitter rectifier shown can be replaced by a corresponding DC voltage supply. Furthermore, it is possible to replace the pulse width controller 32 by a circuit constructed with individual components.

Claims (10)

Circuit arrangement for high-frequency operation of a low-pressure discharge lamp (LL) with a voltage supply (10), a lamp generator (20), a switching transistor (T2) and a control circuit (30), which is an oscillator with a pulse width regulator (32) for generating a switching clock, a current limiting circuit (34) and a voltage limiting circuit (36), wherein the switching transistor (T2) can be controlled with the switching clock in such a way that the low-pressure discharge lamp is operated with an essentially constant power. Circuit arrangement according to Claim 1, characterized in that the lamp generator (20) is formed by a single-ended high-frequency generator with a lamp resonant circuit (L1, L2, C4, C5), the clock frequency of the switching transistor (T2) being equal to the resonant frequency of the lamp resonant circuit (L1, L2, C4, C5). Circuit arrangement according to claims 1 and 2, characterized in that the lamp resonant circuit (L1, L2, C4, C5) is formed by an inductor (L1) and a series resonant circuit, the series resonant circuit comprising an oscillating capacitor (C4) and an inductor (L2) and a heating condenser (C5). Circuit arrangement according to one of the preceding claims, characterized in that the current limiting circuit (34) is suitable for providing an actual voltage at the pulse width regulator (32) which is proportional to the current flow through the switching transistor (T2). Circuit arrangement according to one of the preceding claims, characterized in that the pulse width regulator (32) has a reference voltage source. Circuit arrangement according to one of the preceding claims, characterized in that the pulse width of the switching clock as a function of the actual voltage and the reference voltage can be regulated by the pulse width regulator (32) in such a way that the pulse width is increased when the actual voltage drops. Circuit arrangement according to one of the preceding claims, characterized in that the reference voltage can be changed by the voltage limiting circuit (36) as a function of the voltage applied to the switching transistor (T2). Circuit arrangement according to one of the preceding claims, characterized by a supply circuit of the pulse width regulator, which is formed by a starting circuit (40) before the start of the low-pressure discharge lamp (LL) and by a secondary inductance (L10) of the switching inductance (L1) during operation of the low-pressure discharge lamp (LL) becomes. Circuit arrangement according to Claim 8, characterized in that the starting circuit (40) contains a capacitor (C7) which can be charged by the voltage supply, and a thyristor (T5) which is connected to the voltage across the capacitor (C7) via a diac (D5 ) is ignitable, the voltage on the capacitor (C7) forming the supply voltage of the pulse width regulator (32) after the thyristor (T5) has been ignited. Circuit arrangement according to Claim 9, characterized in that the capacitor (C7) can be charged via a series circuit which is formed by the electrodes of the low-pressure discharge lamp (LL) and two resistors (R10, R11).

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