AT17753U1 - Operating circuits for LED loads comprising a half-bridge circuit - Google Patents

Abstract

Operating circuit (BS) for an LED load (LED), comprising: - a half-bridge circuit (HB) with two switches (HS, LS) connected in series, - a series resonant circuit supplied from the middle point of the two switches (HS, LS), - a transformer (GT) whose leakage inductance is part of the resonant circuit or in series with a discrete resonant choke and from whose secondary side terminals for an LED load (LED) are fed, - a control circuit (ST) connecting the switches ( HS, LS) of the half-bridge clocked at high frequency, with the control circuit (ST) superimposing a PWM modulation that is low in comparison to the high-frequency clock, with the high-frequency clock being at a fixed frequency and dimming of an LED load (LED) connected to the terminals by means of feedback control of the duty cycle of the PWM modulation to a changeable target value is achieved, with a current through the LED being reproduced for the feedback control of the control circuit (ST). of the signal is supplied.

Description

description

OPERATING CIRCUITS FOR LED LOADS COMPRISING A HALF-BRIDGE CIRCUIT

The present invention generally relates to the operation of light sources, particularly in the form of LED loads.

From WO 2015/121011 A9 a driver circuit for lamps, in particular for one or more LEDs is already known, in which the lamps are fed by means of a resonant circuit.

[0003] WO 2015/062925 A2 discloses a lamp operating circuit with a clocked converter for digitally setting a color temperature and/or a dimming level.

A self-oscillating converter is known from WO 2014/0679115 A2.

In general, the invention thus relates to an operating circuit for LED loads which have a resonant circuit, preferably a series resonant circuit.

Basically, there is a trend to increase the operating frequency of such LED drivers (ie the operating frequency at which the series resonant circuit is excited) in order to reduce the size of the passive components.

[0007] Such LED drivers with a resonant circuit can of course be dimmed by frequency variation (typically above the resonant frequency), but also via a burst mode, which means that the high-frequency AC voltage exciting the resonant circuit is switched on or off in bursts. is switched off. This is also referred to below as low-frequency PWM (LF-PWM), since the frequency of this switching on and off of the high-frequency frequency packets is relatively low compared to the high-frequency excitation frequency of the resonant circuit mentioned.

With so-called self-oscillators, as taught for example in WO 2014/067915 A2, it is not easy to change the output current and thus the light output of the LED line via frequency variation in comparison to externally controlled resonant circuits. It is therefore known that in such self-oscillating resonant circuits the dimming as well as the setting of the output current range can be produced using a low-frequency PWM.

The invention now proposes solutions such as LED loads can also be operated with high frequency and possibly with a variable frequency.

[0010] This object is solved by the features of the independent claims. The dependent claims develop the central idea of the invention in a particularly advantageous manner.

According to a first aspect of the invention, an operating circuit for an LED load is proposed, the operating circuit having a half-bridge circuit with two switches connected in series. The half-bridge circuit is typically supplied starting from a DC voltage, which can be generated, for example, by rectifiers and, if necessary, filtering an AC voltage, in particular a mains voltage. However, the half-bridge circuit can also be supplied from a battery, for example.

A series resonant circuit is supplied from the middle point of the two switches. A transformer is also provided, the leakage inductance of which is part of the resonant circuit or which is in series with a discrete resonant choke, and from the secondary side of which terminals for an LED load are supplied.

According to the invention, a control circuit is provided which clocks the switch of the half-bridge at high frequency (there is therefore no self-oscillation principle). The control circuit overlays the high-frequency clocking with a comparatively low-frequency PWM modulation (“burst mode*”). The high-frequency clocking can be fixed-frequency, with dimming

an LED load connected to the terminals (i.e. a change in the current through the LED load) is achieved by means of feedback control of the duty cycle of the PWM modulation to a variable setpoint. For feedback control of the control circuit, a signal representing a current through the LED can be fed back to the control circuit.

According to a further aspect of the invention, an operating circuit for an LED load is provided which has a half-bridge circuit with two switches connected in series. A series resonant circuit is fed from the midpoint of the two switches. A transformer is provided, the leakage inductance of which is part of the resonant circuit or which is in series with a discrete resonant choke, and from the secondary of which terminals for an LED load are fed. A switch clocks the switches of the half-bridge at high frequency, with the control circuit superimposing a PWM modulation that is low in comparison to the high-frequency clocking. In this case, the high-frequency clocking can be adjustable by means of forward control. The duty cycle of the PWM modulation is changed using feedback control. A signal representing a current through the LED load is fed to the control circuit for feedback control.

[0015] Yet another aspect of the present invention relates to a driving circuit for an LED load, the driving circuit comprising a half-bridge circuit with two switches connected in series. A series resonant circuit is fed from the midpoint of the two switches. A transformer is provided, the leakage inductance of which is part of the resonant circuit or which is in series with a discrete resonant choke, and from the secondary of which terminals for an LED load are fed. A control circuit clocks the switches of the half-bridge at high frequency, with the control circuit superimposing a comparatively low-frequency PWM modulation on the high-frequency clock ("burst mode").

According to this aspect of the invention, the high-frequency clocking for dimming in a dimming range above a predetermined dimming threshold value or below a certain half-bridge frequency with feedback control is regulated to a predetermined changeable setpoint, while the PWM modulation is carried out with a constant, for example 100%. duty cycle is set.

[0017] In a dimming range below a predetermined dimming threshold value or above a certain half-bridge frequency, the high-frequency clocking has a fixed frequency. Dimming of an LED load connected to the terminals (i.e. a change in the light output or the current through the LED load) is controlled by feedback control of at least one parameter of the PWM modulation (e.g. duty cycle and/or phase angle between PWM and Half-bridge frequency and/or PWM frequency modulation in combination with duty cycle) reaches a changeable setpoint. A signal representing a current through the LED is fed to the control circuit for feedback control.

The high-frequency clocking of the half-bridge preferably takes place in a range between 0.5 and 4 MHz, more preferably 0.5 to 2.5 MHz.

The comparatively low frequency of the PWM modulation can be in a range from 10 to 50 kHz, preferably 15 to 25 kHz.

The control circuit can be a microcontroller, a CMIC (configurable mixed mode integrated circuit) or an ASIC.

Further features, advantages and properties of the invention will now be explained with reference to the figures of the accompanying drawings.

The figure shows schematically an operating circuit according to the present invention.

The figure shows a half-bridge circuit with two series-connected switches HS (HS Side, high potential) and LS (Low Side, low potential), respectively, which are mutually clocked based on control signals generated by a control circuit ST.

As is known, the half-bridge circuit is supplied by a rectified AC or DC voltage Vpoc.

The control circuit ST external or internal dimming signals D can be supplied, which serve as a setpoint for the current through an LED line LED. A series resonant circuit with an inductance L and a capacitor C1 is connected to the half-bridge, with a transformer GT (electrical isolation) also being provided, the leakage inductance of which is part of the resonant circuit. If necessary, the inductance L can also be dispensed with, in this case there is no discrete resonance reactor in series.

On the secondary side of the transformer GT there is usually a rectifier circuit GR, which feeds an electrical storage element such as a further capacitor C2, the voltage of which in turn feeds the LED line LED directly or indirectly (for example via a further converter stage).

Feedback signals from the area of the half-bridge circuit HS, LS can be fed back to the control circuit ST by means of a measuring resistor (shunt) R1. Furthermore, a feedback signal can also be fed back from a shunt R2 in series to the LED line LED, with the latter measurement signal thus reflecting the current through the LED line.

The control unit is designed, in addition to the high-frequency control of the half-bridge inverter HS, LS, to overlay (modulate) a comparatively low-frequency PWM signal so that, depending on the duty cycle of the PWM signal, the "burst" of high-frequency Switching operations of the inverter HS, LS result, which are interrupted by a dead time, in which there is no switching operation of the switches HS, LS of the inverter.

According to the invention, there is therefore an externally controlled half-bridge HS, LS, since the control signals are generated by a control circuit ST. By mixing the change in the half-bridge frequency and the duty cycle of the superimposed PWM signal (burst modes), the LED line can be dimmed, i.e. the current through the LED line can be changed.

In addition, the phase angle between the high-frequency half-bridge frequency and the low-frequency PWM modulation of the current through the LED line can be changed.

For example, according to the invention, operation is possible in which the frequency of the high-frequency clocking of the half-bridge inverter is at a fixed frequency. Dimming is then achieved by means of feedback control (using the signal, for example from the measuring resistor or shunt R2) by changing the duty cycle of the PWM modulation superimposed on the high-frequency clocking and/or changing the phase angles between the PWM modulation and the high-frequency clocking. As I said, the change for dimming is done by feedback control of the PWM modulation to a changeable setpoint D.

[0032] According to a further aspect of the invention, the high-frequency clocking is not fixed-frequency, but can be adjusted by means of pure forward control. This setting can, for example, be dependent on an external signal or, for adaptation, dependent on the identification of the LED line (LED module) used. Again, for dimming, the pulse duty factor of the PWM modulation can then be changed by means of feedback control, a signal representing a current through the LED being fed to the control circuit for the feedback control.

[0033] According to yet another aspect of the invention, the combination of high-frequency clocking/PWM modulation depends on the dimming value to be set. For this purpose, the total dimming range is divided into several dimming ranges. In at least one of these ranges and more precisely above a predetermined dimming threshold value or below a certain half-bridge frequency (but still typically above the resonant frequency), the high-frequency clocking with feedback control is reduced to a predetermined variable target value.

value D regulated. In this case, the PWM modulation is set with a constant duty cycle, for example 100%, so that the dimming takes place solely by changing the high-frequency clocking.

In a further dimming range below a predefined dimming threshold value or above a specific half-bridge frequency, the high-frequency clocking can be set at a fixed frequency. In this case, an LED load connected to the terminals is dimmed by means of feedback control of at least one parameter of the PWM modulation to a changeable setpoint D. The duty cycle of the PWM modulation and/or is used as a parameter of the PWM modulation, for example the phasing between the PWM modulation and the high-frequency switching operations of the half-bridge circuit in question. For feedback control, a signal representing a current through the LED load is fed back to the control circuit.

Claims (6)

Expectations 1. Operating circuit for an LED load (LED), comprising: - a half-bridge circuit with two switches (HS, LS) connected in series, - a series resonant circuit supplied from the middle point of the two switches (HS, LS), - a transformer (GT ), whose leakage inductance is part of the resonant circuit, or which is in series with a discrete resonant choke and from whose secondary side terminals for an LED load (LED) are supplied, - a control circuit (ST) connecting the switches (HS, LS) of the half-bridge clocks at a high frequency, with the control circuit (ST) superimposing a PWM modulation which is low in comparison to the high-frequency clock, with the high-frequency clock having a fixed frequency and dimming of an LED load connected to the terminals by means of feedback control of the duty cycle of the PWM modulation a changeable setpoint is reached, with a signal representing a current through the LED being sent to the control circuit (ST) for the feedback control is led. 2, operating circuit for an LED load, comprising: - a half-bridge circuit with two switches (HS, LS) connected in series, - a series resonant circuit supplied from the middle point of the two switches (HS, LS), - a transformer whose leakage inductance is part of the resonant circuit, or which is in series with a discrete resonant choke and whose secondary side supplies connections for an LED load, - a control circuit (ST) which clocks the switches (HS, LS) of the half-bridge at high frequency, the control circuit ( ST) the high-frequency clocking is overlaid with a comparatively low-frequency PWM modulation, with the high-frequency clocking being adjustable by means of feedforward control, and the duty cycle of the PWM modulation being changed by means of feedback control, with a current flowing through the control circuit (ST) for the feedback control LED reproducing signal is supplied. 3. Operating circuit for an LED load (LED), comprising: - a half-bridge circuit with two switches (HS, LS) connected in series, - a series resonant circuit supplied from the middle point of the two switches (HS, LS), - a transformer (GT ), whose leakage inductance is part of the resonant circuit, or which is in series with a discrete resonant choke and from whose secondary side terminals for an LED load (LED) are supplied, - a control circuit (ST) connecting the switches (HS, LS) the half-bridge clocks at a high frequency, with the control circuit (ST) superimposing a PWM modulation that is low in comparison to the high-frequency clock, - with the high-frequency clock for dimming in a dimming range above a specified dimming threshold value or below a specified half-bridge frequency with feedback control to a specified one variable setpoint is regulated, while the PWM modulation is set with a constant duty cycle, and - in one Dimming range below a specified dimming threshold value or above a certain half-bridge frequency, the high-frequency clocking is fixed-frequency and dimming of an LED load connected to the terminals is achieved by means of feedback control of at least one parameter of the PWM modulation to a changeable setpoint, with the control circuit for the feedback control (ST) a signal representing a current through the LED is supplied. 4. Operating circuit according to one of the preceding claims, wherein the high-frequency clocking is in a range between 0.5 and 4 MHz, preferably 0.5 to 2.5 MHz. 5. Operating circuit according to one of the preceding claims, in which the frequency of the PWM modulation is in a range from 10 to 50 kHz, preferably 15 to 25 kHz. 6. Operating circuit according to one of the preceding claims, in which the control circuit (ST) is a microcontroller, a CMIC or an ASIC. 1 sheet of drawings