DE10204433A1 - DC voltage converter e.g. for lamp drive device, includes series resonance circuit operated at constant frequency via inverter - Google Patents

Abstract

A DC voltage converter (1) is supplied with a rectified mains voltage (2) and generates a controlled DC voltage and comprises an inverter (4), a series resonance circuit (5), which is driven with a mainly constant frequency in the region of its resonance frequency by the inverter, and a rectifier (6) for the AC voltage present at the series resonance circuit for generating a rectified output voltage. An Independent claim is given for an electronic ballast for operating a lamp.

Description

The present invention relates to a DC converter for use in one Operating device for lamps and an electronic one Ballast for operating a lamp, especially one Gas discharge lamp.

As a DC voltage source for an electronic Ballast, for example, for a gas discharge lamp usually one connected to the mains voltage Rectifier provided. By the rectifier generated DC voltage is then one DC converter, which is called a PFC converter DC link (PFC = Power Factor Correction) the task has to appear as a quasi-ohmic load to the network and, if necessary, simultaneously the DC voltage to one implement the desired level. The DC converter is the load on the power grid caused by harmonic currents reduce, for example by a pulsed current draw of switching power supplies can otherwise arise.

Various types of direct voltage converters are known from the prior art, which are described, for example, in the book by U. Tietze and Ch. Schenk "Semiconductor Circuitry", Springer-Verlag 1991 , ninth edition, pages 561-586. DC converters according to the prior art usually have in common that they contain at least one clocked switch and at least two memory elements. According to the state of the art, an up converter type is mostly used for electronic ballasts, which - seen from the input to the output - consists of a charging choke in a first series branch, a clocked switch in a first series branch, a diode in a second series branch and a storage capacitor in a second cross branch.

An electronic ballast for one Gas discharge lamp having such a DC voltage converter is also, for example, from US Pat. No. 5,705,897 known.

The object of the present invention is a novel Propose DC converter, which has become Use in control gear for gas discharge lamps suitable. Among other things, there should also be the possibility be created that a regulation of the performance factor (English "Power Factors"), i.e. the cosine of the Phase angle between voltage and current, becomes unnecessary.

This object is achieved by the features of independent claims solved. The dependent claims form the central idea of the invention in particular advantageously further.

According to the invention is therefore a direct voltage converter for use in a control gear for luminaires provided, the DC-DC converter as known with a rectified and harmonic filtered Mains voltage is supplied and a regulated DC voltage generated. According to the invention, the DC converter, one inverter and one Series resonance circuit on which the inverter in the Range of its resonance frequency with essentially constant frequency is driven. Furthermore is a Rectifiers for those connected to the series resonance circuit AC voltage to produce a rectified Output voltage provided.

Furthermore, a control circuit for the inverter be provided, the rectified output voltage and a reference voltage can be supplied. The Control circuit controls the duty cycle of the Inverter to control rectified Output voltage to the reference voltage. This Incidentally, reference voltage can be adjustable to different DC link voltages in the electronic ballast by specifying appropriate To be able to provide reference voltages.

A parallel resonance circuit can also be used Impedance matching between the series resonance circuit and the Rectifier be switched.

The inverter can have two switches on their Connection point (center point) of the series resonance circuit connected.

The inverter can operate at a frequency in the range between 100 kHz and 1 MHz, especially in the range operate between 200 and 600 kHz.

At least the components that make up the series resonance circuit can be implemented as printed circuits.

The output voltage can be inductive before the rectifier be decoupled. The inductive coupling can by means of a high impedance transformer which parallel to the capacity of the series resonant circuit is switched. Alternatively or additionally, the inductive coupling by means of the inductance of the Series resonance circuit inductively coupled coil.

Finally, according to another aspect of the invention also an electronic ballast to operate a Lamp, in particular a gas discharge lamp provided that a DC converter of the type mentioned above having.

Referring to the following detailed description of Embodiments and with reference to the figures the accompanying drawings are now to be further Advantages, features and characteristics of the present Invention will be explained to those skilled in the art.

Fig. 1 is a general schematic view showing a DC-DC converter according to the invention,

Fig. 2 shows a first embodiment of the present invention, and

Fig. 3 shows a DC-DC converter according to a second embodiment of the present invention.

Referring to FIG. 1, first, the basic components are a DC converter 1 according to the invention will now be explained. Such a DC converter 1 can be used, for example, in electronic ballasts (EVGs) in lighting technology.

In particular, the components of such an electronic ballast following the DC voltage converter 1 should only be briefly addressed, since they are well known from the prior art. In lighting technology, especially for low-pressure lamps, a high-frequency AC voltage generated by the electronic ballast is applied directly to the lamp. The generation of the high frequency is realized with a DC / AC converter, which generates a higher-frequency AC voltage from an intermediate circuit voltage (which is just provided by a DC voltage converter). The current limiting function is comparable to that of a conventional ballast by means of at least one reactance connected in series with the lamp in the form of a choke. By connecting a capacitor in parallel to the lamp, a series-parallel resonant circuit is obtained. Half and full bridges as well as a transistor circuit and a forward converter with a divided primary winding can be used as DC / AC converters.

Reference should now be made to the components of the DC voltage converter 1 shown schematically in FIG. 1. The mains voltage 2 is harmonic filtered to a rectifier 3 , such as a bridge rectifier. The DC voltage generated by the bridge rectifier 3 is then fed to the DC voltage converter 1 .

According to the invention, this DC voltage converter 1 (as shown in FIG. 1) has an HF inverter 4 , which applies a high-frequency AC voltage to a series resonant circuit 5 . The essentially constant high frequency of the inverter 4 is in the range of the resonance frequency of the series resonance circuit 5 . As is known, the reactivities of the inductors and capacitors cancel each other out in the case of a series resonant circuit in the event of resonance. Only the ohmic series resistance resulting from the line losses and other losses remains effective. In the event of a resonance, the series resonant circuit 5 is therefore a quasi-ohmic load.

The voltage of the series resonance circuit 5 is finally converted by an output rectifier 6 into a DC voltage DC, by means of which an electrolytic capacitor (electrolytic capacitor) 7 can be charged via a charging resistor 8 . The voltage across the electrolytic capacitor 7 represents the regulated intermediate circuit voltage of the electrical ballast.

As can be seen in FIG. 1, the converted DC voltage generated by the rectifier 6 is fed back to the HF inverter 4 as a signal. Furthermore, a reference _voltage U _{REF is provided} for the HF inverter 4 . Thus, as will be shown in more detail with reference to FIGS. 2 and 3, the output voltage of the rectifier 6 can be regulated to the reference voltage U _REF . On the other hand, it is not necessary to record the power factor, since, as already mentioned, the series resonant circuit 5 represents an inherently ohmic load in the event of resonance.

An implementation of the principle of FIG. 1 will now be explained with reference to FIG. 2. In FIG. 2, a harmonic filter 9 is realized for the Netzpannung U _LINE means of a capacitor C1. This harmonic filter 9 prevents high-frequency components from getting into the network from the electronic ballast. As shown, the harmonic filter 9 is formed, for example, by a capacitor C1 and an inductor L1. A bridge rectifier V1 rectifies the mains voltage to the HF inverter 4 .

In this case, the HF inverter 4 consists of a control unit 10 , which can be designed, for example, as an integrated circuit (IC). This integrated circuit 10 can be supplied with an adjustable reference voltage U _REF and the output voltage as an actual value for regulating the rectified output voltage of the DC voltage converter 1 . The control circuit 10 controls power switches 13 , 14 via drivers 11 , 12 , which can be implemented, for example, as FETs.

The FETs 13 , 14 are controlled with an essentially constant switching frequency in a range, for example, between 100 kHz and 1 MHz. The following series resonant circuit 5 is operated by means of the switches 13 , 14 , which in the case shown consists of an inductor L2 in series with a capacitor C3.

In the exemplary embodiment in FIG. 1, a parallel resonance circuit consisting of an inductor L3 and a capacitance C4 is also connected to the series resonance circuit 5 . This parallel resonance circuit serves to increase the impedance of the DC-DC converter 1, particularly when the input voltage is high. Finally, the output voltage is rectified by an output rectifier 6, which is formed from the diodes V6, V7 and V8.

The circuit shown can be used Achieve a power factor of more than 0.99.

In order now to come to the embodiment of FIG. 2, the essential difference from the embodiment of FIG. 1 is that the rectified output voltage is decoupled inductively. The series resonance circuit consisting of the inductance L2 and the capacitance C3 can thus simultaneously transform the output voltage with respect to the rectified mains voltage upwards or downwards.

As shown, another can be used for inductive coupling Inductance L3 parallel to the capacitance C3 of the higher one Be resonant circuit switched. This parallel to the Capacitance C3 of the series resonance circuit switched Inductance is again in the sense of a decoupling transformer inductively coupled to another coil.

Finally, alternatively, but also in addition to first decoupling point D1 / D2 a second Decoupling point D3 / D4 for the rectified Output voltage may be provided. To realize the second decoupling point D3 / D4 is another Inductance inductive with the inductance L2 of the Series resonance circuit coupled.

Because the HF inverter 4 is operated at high frequency, it is possible to keep the inductance as well as the capacitance of the series resonance circuit low. These components can therefore be implemented inexpensively and in particular also in the form of a printed circuit.

In the embodiment of the invention shown in Fig. 1, a DC voltage at the output of the circuit (DC _out ) in the amount of half the network half-waves at the input of the DC converter. With a line voltage U _LINE of effectively 220 volts, the line half-waves rectified with the bridge rectifier 3 at the input of the DC voltage converter 1 are 330 volts (peak voltage), so that a rectified voltage of 165 volts occurs at the output of the DC voltage converter 1 . This value of 165 volts is achieved by voltage regulation, that is to say the feedback of the rectified output voltage to the HF inverter 4 and more precisely to the control circuit 10 .

The two switches 13 , 14 of the HF inverter 4 are switched on and off alternately, the switch-on times for both switches being essentially the same length.

The output voltage U _Dcout can be varied by changing the switching behavior of the inverter 4, for example by changing the switch-on time of the two switches.

Claims (11)

1. DC voltage converter for use in an operating device for lights, the DC voltage converter ( 4 ) being supplied with a rectified mains voltage ( 2 ) and generating a regulated DC voltage, comprising:
an inverter ( 4 ),
a series resonance circuit ( 5 ) which is controlled by the inverter in the region of its resonance frequency with an essentially constant frequency, and
a rectifier ( 6 ) for the AC voltage applied to the series resonance circuit ( 5 ) to generate a rectified output voltage. 2. DC voltage converter according to claim 1, further comprising: a control circuit ( 10 ) for the inverter ( 4 ), the rectified output voltage and a reference voltage are supplied and controls the switching behavior of the inverter ( 4 ) for regulating the rectified output voltage to the reference voltage. 3. DC voltage converter according to one of the preceding claims,
still showing
a parallel resonance circuit, which is connected for impedance matching between the series resonance circuit ( 5 ) and the rectifier ( 6 ). 4. DC voltage converter according to one of the preceding claims, characterized in that the inverter ( 4 ) has two switches ( 13 , 14 ), at the center of which the series resonance circuit ( 5 ) is connected. 5. DC voltage converter according to one of the preceding claims, characterized in that the rectifier ( 16 ) charges a capacitor. 6. DC voltage converter according to one of the preceding claims, characterized in that the inverter ( 4 ) is operated at a frequency in the range between 100 kHz and 1 MHz, in particular between 200 and 600 kHz. 7. DC voltage converter according to one of the preceding claims, characterized in that at least the components forming the series resonant circuit ( 5 ) are implemented as a printed circuit. 8. DC voltage converter according to one of the preceding claims, characterized in that the output voltage before the rectifier ( 6 ) is coupled out inductively. 9. DC converter according to claim 8, characterized in that the inductive coupling takes place by means of a high impedance transformer which is connected in parallel to the capacitance of the series resonant circuit ( 5 ). 10. DC voltage converter according to claim 8 or 9, characterized in that the inductive coupling takes place by means of a coil inductively coupled to the inductance of the series resonant circuit ( 5 ). 11. Electronic ballast for operating a lamp, in particular a gas discharge lamp, characterized in that it has a direct voltage converter ( 1 ) according to one of the preceding claims.