AT17614U1 - LED converter with valley fill circuit and clocked converter - Google Patents

Abstract

LED converter (1) with output terminals (2) for supplying LED loads (3), containing a passive power factor correction circuit in the form of a passive valley-fill circuit (4) having capacitors (5), and a switch (6 ) clocked converter circuit (7) supplied from the output of the passive power factor correction circuit (4), the clocked converter circuit being a buck converter, a boost converter, an inverter, a forward converter or a flyback converter, or a combination thereof, and a modulation circuit (8) cyclically modulating the potential on at least one pole of at least one or all of the capacitors (5) of the passive power factor correction circuit (4).

Description

description

LED CONVERTER WITH VALLEY FILL CIRCUIT AND CLOCKED CONVERTER

The present invention relates to converters for powering LED loads. The invention relates in particular to converters of this type which have a passive valley-fill circuit. The invention also relates to LED modules with such a converter.

So-called valley-fill circuits are a special form of power factor correction circuits and are generally used to filter unwanted harmonics in electronic circuits. Passive valley-fill circuits typically have what are known as smoothing capacitors, which are connected by means of at least one diode. The smoothing capacitors typically charge to half the amplitude of the peak value of the DC voltage supplying the circuit, and then discharge across the load during periods when the DC voltage is below half the peak amplitude.

[0003] Passive Valley Fill circuits are known, for example, from https://de.wikipedia.org/wiki/Valley-Fill-Circuit.

An active valley fill circuit is known, for example, from US 20140340943 A1 and US 9263944 B2 and, in contrast to the passive valley fill circuit, typically has an active element such as a controlled switch.

[0005] Typically, the active valley-fill circuit has one capacitor and the passive valley-fill circuit has two capacitors.

[0006] Known passive valley fill circuits (PVF) have the disadvantage that the current curve resulting from the power consumption of the circuit shows essentially triangular peaks, specifically in the lateral durations in which the mentioned capacitors of the passive valley fill Fill circuit are recharged at a correspondingly high amplitude of the input voltage.

The invention now addresses this problem and provides a solution to at least mitigate this peak-shaped current consumption.

[0008] 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, a converter with output terminals is provided, in particular for supplying LED loads. The converter includes a passive valley-fill circuit that includes capacitors that charge during certain amplitude ranges of the rectified AC supply voltage and discharge across the load during other amplitude ranges.

Starting from this passive valley-fill circuit, a converter circuit clocked by means of at least one switch is supplied, from which the LED load can in turn be supplied.

According to the invention, a modulation circuit is provided which preferably cyclically modulates the potential at at least one pole of at least one or more capacitors of the valley-fill circuit. This modulation of the potential on one side of the capacitors means that the current consumption of the valley-fill circuit is now broadened over a larger time range or a plurality of time ranges by recharging the capacitors.

The modulation circuit can be modulated with the clocking frequency of the switch of the clocked converter circuit. In particular, the modulation circuit can be controlled starting from the clocked converter circuit, ie with a node in the area

be connected to the clocked converter circuit.

Any known clocked converter circuit can be used for the clocked converter circuit, for example a buck converter, boost converter, inverter, forward converter, flyback converter or any combination or hybrid version thereof.

The modulation circuit can in particular have an oscillating circuit, such as a series oscillating circuit, which can be designed as an LCR circuit.

The resonant frequency of the resonant circuit is preferably matched to the frequency of the clocking of the switch of the actively clocked converter circuit, which means that the resonance frequency is essentially in the range of the clocking of the switch of the clocked converter circuit. For example, the resonance frequency can be within a tolerance of 25%, preferably 15%, more preferably 5% of the frequency of the clocking of the switch of the clocked converter.

[0016] The modulation circuit can be designed to achieve a modulation swing of the potential at a connection side of a capacitor which is, for example, 10%-40% of the peak voltage of the modulated potential.

The modulation is preferably high-frequency compared to the frequency of the AC voltage supplying the converter, which is typically supplied to the passive valley fill circuit after rectification.

The converter can also have an active valley fill circuit.

In order to prevent interference from being scattered back to the mains supply as a result of the modulation of the potential, a filter circuit with a low-pass character can be connected upstream of the passive power factor correction circuit, for example between the input and a DC rectifier, the filter characteristic of the filter circuit being tuned in such a way that that frequencies in the range of the modulation frequency are attenuated.

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

FIG. 1 shows the application of the invention with a so-called passive valley fill circuit,

Figure 2 shows another way of connecting the modulation circuit to the passive valley fill circuit, and

Figure 3 shows yet another way of connecting the modulation circuit to the passive valley fill circuit

In FIG. 1, reference numeral 1 generally designates a converter which can operate, for example, an LED load 3 at output terminals 2, 2'.

This converter 1 is fed from an A/C supply voltage 10 which, after rectification by a rectifier circuit 12, is subjected to filtering by a filter circuit 11, 14. The rectified and filtered supply voltage is then fed to a passive power factor correction circuit in the form of a so-called valley-fill circuit 4 . Such passive valley-fill circuits are well known in terms of their structure and function. The circuit shown in the figure is therefore for illustration only. The drawing shows that two capacitors 5, 5' are provided, which are connected in parallel by means of two diodes 15, 15'.

The two capacitors are discharged via a load, which in this case represents a clocked converter circuit 7 as the first stage. This clocked converter circuit 7 is actively clocked by a switch, for example an FET 6 .

The control signal for the switch 6 can be generated by a control circuit 23, which can be fed back from the supply voltage, the valley fill circuit, the clocked converter circuit and/or the LED load, so that the clocking of the Switch 6 by a feedback control (e.g. for control

a constant LED current) can be used. Alternatively, pure forward control of the clocking of the switch 6 can also be provided.

The clocked converter circuit also has a diode 20, an inductance 21.

The output of the clocked converter circuit typically feeds a storage capacitor 22, the voltage of which is then also present at the output terminals 2, 2'.

According to the invention, it is now provided that the potential of the two capacitors 5, 5' in the illustrated case is modulated cyclically.

The potential is modulated at different polarities of the capacitors, ie the negative potential of the capacitor 5' is modulated in the example shown, while the positive potential (generally: the higher potential) is modulated at the capacitor 5.

This cyclical modulation of the potential on one side of each capacitor ensures that the current consumption of the valley-fill circuit 4 is spread by recharging the capacitors over a larger temporal range or multiple temporal ranges, which reduces the overall harmonic distortion (English: total harmonic distortion, THD) of the circuit improved by reducing non-linear distortion.

In the exemplary embodiment shown, the modulation is generated starting from a node 26 of the clocked converter circuit 7 .

To be more precise, a resonant circuit (oscillating circuit), in particular in the form of a series resonant circuit as shown, is connected to the node 26 of the clocked converter circuit 7 with an ohmic resistor 19 , a capacitor 18 and an inductor 17 .

The switching of the switch 6 of the clocked converter 7 excites this series resonant circuit 9, which thus results in a voltage modulation of a potential of the capacitors 5, 5' with the frequency of the resonant frequency of the series resonant circuit 9.

The resonant frequency is of course tuned to the switching frequency of the switch 6, which is typically clocked at high frequency. This means that the clocking of the switch 6 and thus also the resonant circuit and the modulation of the potential at a connection of the capacitors 5, 5' takes place at a frequency which is significantly higher (for example in the kilohertz range) than the frequency of the A/ C supply voltage 10 or the rectified A/C supply voltage which is present at the input of the passive valley fill circuit 4 .

In order to prevent interference with the frequency of the modulation of the potential of the capacitors being scattered back to the mains voltage side, a filter circuit 11 tuned to the modulation frequency is provided with an inductor 13 and a capacitor 14, which typically has a low-pass character and thus interference attenuates in the range of the modulation frequency.

The modulation circuit can be designed in such a way that a modulation swing in the order of 10-40% of the peak voltage is generated at the corresponding potential of the corresponding capacitor. Expressed in absolute terms, this can mean, for example, that the modulation range is 20V-400V with a peak voltage of 400V.

In the example shown, the modulation circuit is coupled to the clocked converter circuit 7 that follows the passive valley fill circuit 4.

However, the modulation can also be generated in some other way, for example by a modulation controlled by the control circuit 23 .

In the exemplary embodiment of FIG. 1, the modulation circuit 8 is connected to a branch 5, 15' of the passive valley fill circuit and a diode 16 connects the two branches.

Figure 2 shows an alternative way of connecting the modulation circuit 8 at

which, as can be seen, are provided with two diodes 30, 31, which connect the two branches of the passive valley fill circuit, with the modulation circuit 8 being connected to the middle point 32 of these bridge diodes 30, 31, so that the capacitors 5, 5' are recharged at this middle point he follows.

Figure 3 shows another alternative way of connecting the modulation circuit 8, in which, similar to the example in Figure 2, two diodes 30, 31 are provided which connect the two branches of the passive valley fill circuit, the modulation circuit 8 being Midpoint 32 of these bridge diodes 30, 31 is connected, so that the capacitors 5, 5' are recharged at this midpoint. In addition, the modulation circuit 8 is connected to the connection point 34 via a further pump capacitor 33 at the positive output of the rectifier circuit 12 . A pump diode 35 is arranged between the connection point 34 and the passive valley fill circuit with the upper connection of the capacitor 5′. This additional arrangement of the pump capacitor 33 at the positive output of the rectifier circuit 12 and the pump diode 35 forms a so-called active charge pump circuit, which can contribute to a further improvement in the harmonic distortion of the circuit.

Claims (10)

Expectations 1. LED converter (1) with output terminals (2) for supplying LED loads (3), having send: - A passive power factor correction circuit in the form of a passive valley-fill circuit (4) having capacitors (5), and - A converter circuit (7) clocked by means of at least one switch (6), which is supplied from the output of the passive power factor correction circuit (4), the clocked converter circuit being a buck converter, a boost converter, an inverter, a forward converter or a flyback converter, or a combination thereof, and - A modulation circuit (8) which cyclically modulates the potential on at least one pole of at least one or all of the capacitors (5) of the passive power factor correction circuit (4). 2. LED converter according to claim 1, characterized in that the modulation circuit (8) modulates the clocked converter circuit (7) with the frequency of the clocking of the switch (6). 3. LED converter according to one of the preceding claims, characterized in that the modulation circuit (8) is controlled starting from the clocked converter circuit (7). 4. LED converter according to one of the preceding claims, characterized in that the modulation circuit (8) has an oscillating circuit (9), in particular a series oscillating circuit such as an LCR circuit. 5. LED converter according to claim 4, characterized in that the resonant frequency of the resonant circuit (9) is within a tolerance of 25%, preferably 15%, more preferably 5% of the clocking frequency of the switch (6) of the clocked converter (7) lies. 6. LED converter according to any one of the preceding claims, characterized in that the modulation circuit (8) is designed to achieve a modulation range of 10% to 40% of the peak voltage of the modulated potential. 7. LED converter (1), in particular for supplying LED loads (3), having: - a passive power factor correction circuit (4) having capacitors (5), and - a converter circuit (7) clocked by a switch (6) and powered from the output of the passive power factor correction circuit in the form of a valley-fill circuit (4), and - Wherein the converter (1) is designed such that the potential at least one pole of at least one or all of the capacitors (5) of the passive power factor correction circuit (4) is cyclically modulated. 8. LED converter according to one of the preceding claims, characterized in that the modulation is high-frequency compared to the frequency of the converter (1) supplying AC voltage (10). 9. LED converter according to one of the preceding claims, characterized in that the passive power factor correction circuit (4) is preceded by a filter circuit (11), preferably with low-pass character. 10. LED converter according to any one of the preceding claims, characterized in that the LED converter further comprises an active valley fill circuit. 3 sheets of drawings