DE102015206982A1 - Bulb converter with balanced output currents - Google Patents

Abstract

It is a light-emitting converter with an LLC resonant circuit provided, starting from the secondary side bulbs, such. An LED track, the LLC resonant circuit comprising: a half-bridge circuit having two series-connected switches driven by a control circuit, a resonant circuit supplied from a mid point of the two switches, and one output the resonant circuit with AC voltage supplied transformer, on the secondary side of each a current path for each of the two polarities of the AC voltage is provided. A detection circuit is provided which detects a signal that reflects currents in the two current paths and / or their ratio, and the control circuit adjusts the timing of the two switches of the half-bridge circuit depending on the signal detected by the detection circuit.

Description

The invention relates to a light source converter for operating at least one light source, preferably at least one LED or LED track. In addition, the invention relates to a method for operating a Leuchtmittekonverters. Furthermore, the invention relates to a lamp converter with an LLC circuit, in which, starting from an AC voltage, a (series) resonant circuit is supplied, which in turn serves to supply a further converter stage for the direct supply of a lighting means. The supply voltage supplied to the luminous means then typically has to be converted into a DC voltage. This can in principle be done for example by a full bridge rectifier. With regard to energetic advantages, however, a rectification starting from a transformer offers itself.

A "light-emitting converter" is an electrical circuit which can be supplied with an input voltage and to the light-emitting means, such as one or more LEDs, connected to be electrically operated so defined.

For example, the prior art is the document WO 2014/060899 A2 known in which a light source converter in 1 is described, which can serve as a starting point of the invention. A similar light source converter is also in 1 shown. A control circuit SE controls an inverter half bridge HB with two switches S1, S2, which are connected in series. As in 1 illustrated, the half-bridge circuit HB is supplied by an input voltage, which is exemplified as a bus voltage V _BUS . Instead of a bus voltage, which is normally a DC voltage, ie a DC voltage, a rectified AC voltage can also be used to supply the half-bridge.

Starting from a midpoint of the half-bridge HB, or the two switches S1, S2, a resonant circuit is now supplied, which is formed in particular of a series circuit of a capacitor C1, an inductance L1 and a second inductance L2a. Starting from the inductance L2a is now a transformer T1 with an AC voltage, d. H. an AC voltage, fed. The transformer T1 has the electromagnetic inductances, coils or windings L2a, L2b, L2c. The inductors L2b and L2c are arranged on the secondary side of the transformer T1. The inductors L2b and L2c are shown as separate inductors, since a center tap M1 is provided on the secondary side of the transformer T1.

Starting from the inductors L2b and L2c, a current path SP1 or SP2 is then supplied in each case. The current paths SP1 and SP2 thus each connect one side of the inductance L2b, L2c to a connection point CP, each current path having a diode for rectification.

The first current path SP1 in this case has the diode D1, while the second current path SP2 has a second diode D2. An induced current I _{SP1 is} transmitted via the first current path SP1 and an induced current I SP2 via the current path _SP2 . On the other hand, with the connection point CP, an output terminal E1 of the luminous converter is connected to, for example, a load LED, e.g. B. a light source and in particular at least one LED can be connected.

Between the connection point CP and the output terminal E1, a smoothing capacitor C2 is further connected to its higher-potential side, wherein the potential-lower side of the second capacitor C2 may be at the secondary-side ground potential of the transformer.

The control circuit SE controls the higher-potential switch S1 of the half-bridge HB via a drive signal HS ("high side" signal), while it controls the potential-lower switch S2 of the half-bridge with a signal LS ("low side" signal). In this case, the control circuit SE switches the switches S1, S2, preferably as transistors, for. B. FET, MOSFET, are formed alternately to provide an AC voltage for the transformer T1 at the midpoint of the half-bridge HB.

In the 1 For example, the primary winding L2a of the transformer T1 is connected to the primary-side ground on its potential-lower side, as is the lower-potential side of the half-bridge switch S2. The current or the voltage through the primary-side inductance L2a is transmitted to the secondary side by the transformer T1, whereby the current I _{SP1 is} induced in the first current path _SP1 and the current I _{SP2 is} induced in the second current path SP2.

Meanwhile, the center tap between the secondary-side inductances L2b and L2c serve to provide currents at the connection point CP which are substantially symmetrical about a zero point.

Via the diodes D1 and D2, a direct current or a DC voltage is provided at the connection point CP in order to operate the load LED. The secondary side ground may be either connected to the primary side ground or provided isolated therefrom.

Altogether, the voltage or the applied voltage at the output terminal E1 depends Current I _SP1 or I _SP2 from the voltage applied to the primary-side inductance of the transformer T1 or the waveform of the voltage. These can be set by changing a timing or switching frequency of the switches S1, S2 or a duty cycle of the half-bridge circuit HB, that is to say in particular a change in the switch-on time duration of the switches S1, S2.

Starting from the in 1 The circuit shown now raises the problem that the inductors L2b, L2c on the secondary side of the transformer T1 (which in particular represent two halves of a single secondary-side inductance) are not exactly symmetrical and do not have the same electrical or symmetrical parameters. This leads to an asymmetric load on the following on the secondary side of the transformer T1 components and in particular of the diodes D1 and D2. It can even happen that only one current path of the current paths SP1, SP2 and thus a diode D1 / D2 is loaded.

The invention now provides a solution that allows, even with dissimilar or asymmetrical inductances L2b, L2c on the secondary side of the transformer T1, an exact form of symmetry of the currents output on the secondary side, ie. H. to achieve the current at the connection point CP and at the output terminal E1. For this purpose, the invention provides a luminous converter and a method for operating a luminous converter according to the independent claims. Further developments of the invention are the subject of the dependent claims.

In a first aspect, a light-emitting converter with an LLC resonance circuit is provided, wherein starting from its secondary side lighting means such. An LED track, the LLC resonant circuit comprising: a half-bridge circuit having two series-connected switches driven by a control circuit, a resonant circuit supplied from a mid point of the two switches, and one output the resonant circuit with AC voltage supplied transformer, on the secondary side of each a current path for each of the two polarities of the AC voltage is provided. A detection circuit is provided which detects a signal that reflects currents in the two current paths and / or their ratio, and the control circuit adjusts the timing of the two switches of the half-bridge circuit depending on the signal detected by the detection circuit.

The detection circuit may comprise at least one detection branch which detects the signal representing the current through at least one signal path.

The at least one detection branch can evaluate a rectified mixed signal.

The at least one detection branch may comprise a sample-and-hold circuit.

The detection circuit may comprise a detection branch for each current path.

The at least one detection branch may comprise a switch that is synchronously clocked with one of the two switches of the half-bridge circuit.

At the at least one detection branch, a voltage and / or a voltage value is detected which is proportional to the current through one of the current paths.

Depending on the signal supplied to the control circuit, the control circuit can change a duty cycle of the half-bridge circuit and, in particular, shorten or lengthen a switch-on period of at least one of the two switches of the half-bridge circuit.

The secondary side of the transformer may have a center tap coupled to a primary side winding of the transformer from which the current paths are powered.

Each current path may include a sense inductance that is electromagnetically coupled to at least a third sense inductance of the sense circuit. The at least one detection branch of the detection circuit may be arranged between a rectifier and filter circuit.

The control circuit can change the control of the two switches of the half-bridge circuit by changing the timing until the control circuit supplied signal corresponds to a desired value and / or the control circuit supplied signals in particular are substantially equal, for. B. have the same signal values.

The control circuit can change the control of the two switches of the half-bridge circuit by changing the timing until a target value for a signal supplied to the control circuit is reached, which in particular represents a ratio of two voltage values.

The detection circuit may have two detection branches whose switches each are clocked synchronously with each one of the two switches of the half-bridge circuit.

The detection circuit may supply two signals to the control circuit, each indicating an electrical parameter representative of the current through a current path, and / or relating the two signals and communicating information about the relationship with the control unit.

In a further aspect, a method for balancing the current flows at the output of an LLC resonant circuit from its secondary side is a lighting means such. The LLC resonant circuit, wherein a control circuit drives two series-connected switches of a half-bridge circuit, and wherein the half-bridge circuit supplies a resonant circuit from a midpoint of the two switches, and starting from an output of the resonant circuit, a transformer is fed with AC voltage, on the secondary side of each of which a current path is provided for each of the two polarities of the AC voltage. A detection circuit detects a signal that reflects currents in the two current paths and / or their ratio, and the control circuit adjusts the timing of the two switches of the half-bridge circuit depending on the signal detected by the detection circuit.

The invention will now be described with reference to the figures. Showing:

1 a circuit arrangement according to the prior art;

2 schematically a circuit arrangement according to the invention;

3 exemplarily a circuit arrangement according to the invention;

4 exemplary detection values.

2 schematically shows a circuit according to the invention. Starting from a supply V, in particular a DC voltage or a rectified AC voltage, z. As a rectified mains voltage, a half-bridge circuit HB is supplied, which supplies a resonant circuit RK with an AC voltage.

The half bridge points, as for 1 described, preferably at least two series-connected switches S1 and S2, which are controlled by a control unit SE. In this case, the potential higher switch can be controlled via the drive signal HS and the potential lower switch via the drive signal LS.

With the resonant circuit RK, the primary-side winding of the transformer T1 is connected. Starting from the secondary-side winding of the transformer T, which has a center tap, which divides the secondary-side inductance quasi into two inductances, at least one current path is supplied. In this current path, a detection circuit ES is integrated, which detects at least one signal that reflects the current in the at least one current path, preferably the currents in two current paths or their ratio. An information reproducing the signal or the signals or the ratio is then fed to the control circuit SE, which changes a duty cycle or a clocking of the switches of the inverter HB as a result of changing the drive signals MS and / or LS.

In 2 the signals V1 and V2 are shown, which are supplied from the detection circuit ES of the control circuit SE. It should be understood that if only the signal representative of the ratio of the current values or only a signal is transmitted to the control unit SE, only this signal from the detection circuit ES must be supplied to the control circuit SE. Starting from the transformer T, the load LED can be supplied electrically.

Details of the circuit according to the invention will now be with a view to the 3a and 3b described.

In 3A is essentially one of 1 corresponding circuit shown. Accordingly, the same reference numerals designate 1 also essentially the same parts of the circuit in 3a , The electrical supply V is in 3a again represented as voltage V _BUS . The essential difference here is that a first detection inductance L3a is connected in the first current path SP1 between the diode D1 and the connection point OP. Furthermore, a second detection inductance L3b is provided in the second current path SP2 between the diode D2 and the connection point CP. Electromagnetically coupled to the first and second detection inductors L3a and L3b is a third detection inductance L3c, which is preferably primary side with respect to the resonant circuit RK and the LLC resonant circuit and the transformer T1, respectively.

The first detection inductance L3a and the second detection inductance L3b form, with the third detection inductance L3c, the converter W1 and, in particular, another transformer. At the third detection winding L3c, therefore, a current dependent on the current through the first detection winding L3a is detected when a current I _{SP1 flows} through the first current path SP1 while one of the current I _SP2 is detected by the second current path SP2 dependent current when the current I _{SP2 flows} through the second current path SP2. Consequently, a current path for the induced currents is provided on the secondary side for each polarity of the primary-side AC voltage.

The current detected at the third detection winding L3c is then supplied to a rectifier GR, which then outputs a rectified current I _sense . According to the invention, the current signal I _sense is now evaluated with regard to an asymmetry of the current component through the current paths SP1, SP2 or through the diodes D1, D2.

As in 3b 1, the current signal I _{sense is} fed from the rectifier to a known filter circuit FS, consisting of a filter resistor RF, a filter capacitance CF and a sensing resistor R _SENS , and evaluated for averaging, so that the mean value I _{sense_avg} of the secondary side of the Transformer T1 flowing current can be utilized as a signal representative of the control of the LED current. The mean value _signal I _{sense_avg} is then used for current regulation, where it is used as an actual signal and the manipulated variable for the clocking of the switches S1, S2 of the inverter HB can be used. Accordingly, the mean value signal I _{sense_avg is fed to} the control _circuit SE as a signal (3).

According to the invention, it is now provided that, prior to averaging, the combined current signal I _{sense is} split into values that are representative of the current through the current paths SP1 and SP2, or the currents occurring at the diodes D1 and D2, respectively. For this purpose, a first detection branch EZ1 is provided, consisting of a series circuit of a third switch S3, which is connected to its potential higher side with the rectifier GR and the filter resistor RF, and a first resistor RH1 and a first capacitor CH1 is formed. Between the first resistor RH1 and the first capacitor CH1, a voltage signal V1 is detected, which reproduces the voltage drop across the first capacitor CH1.

A second detection branch EZ2 of a series circuit of a fourth switch S4, a second resistor RH2 and a second capacitor CH2 is also connected between the rectifier GR and the filter circuit. At this time, the potential higher terminal of the fourth switch S4 is connected to the rectifier GR and the filter resistor RF, while its potential lower side is connected to one side of the second resistor RH2. On the other side of the second resistor RH2, the second capacitor CH2 is connected, which, on the other hand, is at a ground potential. Between the second resistor RH2 and the second capacitor CH2, the measuring signal V2 is detected, which reproduces a voltage drop across the second capacitor CH2.

In the first detection branch EZ1, when the third switch S3 is activated, the current I2 flows, and in the second detection branch EZ2, when the fourth switch S4 is activated, the current I2 flows.

The decisive factor is that the third switch S3 and the fourth switch S4 are controlled synchronously with the switches S1, S2 of the half-bridge HB. For example, the third switch S3 is driven synchronously with the potential higher switch of the half-bridge S1, while the fourth switch S4 is driven synchronously with the potential lower switch S2 of the half-bridge HB. Accordingly, the third switch S3 is driven by the control circuit SE with the drive signal HS, while the fourth switch S4 is driven by the drive signal LS, or vice versa.

The basic idea of the invention is that the currents through the diodes D1 and D2 can be evaluated separately. In the present case, there is a subsequent splitting of the current signal I _sense , since the combination of the two currents I _SP2 and I _{SP1 is} already provided for averaging.

Alternatively, a separate coupled third or fourth detection inductance for evaluation could also be provided for the first detection inductance L3a and for the second detection inductance L3b. Even then, a corresponding voltage or current signal could be communicated to the control circuit SE. It can further be provided that the detection circuit ES determines a ratio from the detection signals V1 and V2 and transmits this as a single signal to the control circuit SE. For this purpose, a corresponding circuit for forming the ratio value can be provided in the detection circuit ES.

Knowing the at least one signal which is supplied from the detection circuit ES to the control circuit SE and which reproduces the currents through the diodes D1 or D2, an asymmetry of the secondary-side inductances L2b, L2c of the transformer T1 in a non-mechanical manner, but be eliminated in a control engineering manner by the supplied value for changing the timing of the half-bridge switches S1, S2 and in particular for changing the duty cycle (or the duty cycles) of the half-bridge HB is used by way of a feedback control for this asymmetry.

Im in 3b In the embodiment shown, the detection signals V1 and V2, which correspond to voltage signals representing the currents through the diodes D1 and D2 respectively, are evaluated by the control circuit SE (in particular IC, ASIC, microcontroller), which then operate the switches S1, S2 of the half-bridge HB controls accordingly. In addition, provision may be made for the detection circuit ES to have its own microcontroller, ASIC or IC, which supplies the feedback signal to a further control unit, whereupon this control unit then changes the control of the inverter switches S1, S2.

The resonant circuit or LLC resonant circuit is used with the center tap tap transformer T1 to achieve a slightly higher efficiency. The problem solved by the invention thus addresses that, depending on the operating point, the current through the secondary windings L2b, L2c may be different. In particular, the invention prevents that the entire output current of the transformer T1 via only one of the current paths SP1, SP2, d. H. flows via one of the secondary-side inductors L2b, L2c, which also represents a significant electrical and thermal load on the transformer T1. While typically the half bridge HB operates with a 50% duty cycle, i. H. that the switches S1, S2 of the half-bridge, with possible consideration of a dead time, are substantially equally active, the solution according to the invention compensates for any asymmetry by correcting the duty cycle of the half-bridge HB, and in particular one On time and / or off duration of the half-bridge switches S1, S2 is changed.

4a C show schematically how different currents in the current paths SP1, SP2 can result in the case of an asymmetry with essentially the same activation of the half-bridge switches S1, S2 by the activation signals LS and HS.

While the detection circuit ES detects the detection signal V1 at the first detection branch EZ1 when, as in FIG 4a and 4b 2, the switch S1 and the third switch S3 are activated by driving by the signal HS, the second detection branch EZ2 detects the detection signal V2 when, as in FIG 4a and 4c shown, the switch S2 and the fourth switch S4 are activated by driving by means of the signal LS.

Accordingly, as in 4d shown, from the detection signals V1 and V2, a deviation .DELTA.V, which reflects the asymmetry. Accordingly, by changing the activation of the half-bridge switches S1, S2, a change of the currents I _SP1 , I _SP2 in the current paths SP1, SP2 can be generated by the change of the drive signals LS, HS. In particular, the variable .DELTA.V can be used as the actual size for the asymmetry, which can then serve the control circuit SE, which is responsible for the control of the half-bridge switches S1, S2.

The current of the secondary inductances L2b, L2c of the transformer T1 is therefore detected via the detection inductances L3a to L3c. As in 3b shown, this AC signal is rectified by means of a rectifier GR, in particular a bridge rectifier. By clocking the switch of the detection branches EZ1, EZ2 man then receives the signals V1, V2, as in the 4b and 4c are shown. In this case, the current in the inductors L3a to L3c behaves synchronously with the switching of the half-bridge switches S1, S2, which are controlled via the control signals LS and HS.

It should be noted that the first resistor RH1 and the first capacitor CH1 is a sample-and-hold circuit. The same is the case for the second resistor RH2 and the second capacitor CH2. Thus, the measurement signal detected via the third or fourth switch S3, S4 is thus respectively fed to a sample holding stage. This produces the detection signal V1, that is, the voltage V1 at the detection point (1), while the detection signal V2, or the voltage signal at the detection point (2) is formed, wherein the signal at the point (1) is proportional to the current through the first detection inductance L3a, while the detection signal V2 is proportional to the current through the second detection inductor L3b.

The detection signals can then be evaluated, for example, with the analog digital converter of a microcontroller, which then changes the duty cycle of the inverter HB until the detection signal V1 at point (1) corresponds to the detection signal V2 at point (2).

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2014/060899 A2 [0003]

Claims (15)

Light source converter with an LLC resonant circuit, starting from the secondary side bulbs (LED), such. B. a LED track, are supplied, the LLC resonant circuit comprises: - a half-bridge circuit (HB) with two series-connected switches (S1, S2), which are controlled by a control circuit (SE), - one from a Mittenpunkt (M1) of the two switches (S1, S2) supplied resonant circuit (RK), and - a starting from an output of the resonant circuit (RK) with AC voltage supplied transformer (T1), on the secondary side of each a current path (SP1, SP2 ) is provided for each of the two polarities of the AC voltage, characterized in that - a detection circuit (ES) is provided which detects a signal (V1, V2), the currents (I _SP1 , I _SP2 ) in the two current paths ( SP1, SP2) and / or their ratio, and - the control circuit (SE) adjusts the timing of the two switches (S1, S2) of the half-bridge circuit (HB) in dependence on the signal (V1, V2) detected by the detection circuit (ES) , A luminous converter according to claim 1, wherein the detection circuit (ES) comprises at least one detection branch (EZ1) which detects the signal representing the current through a signal path (SP1). The luminous converter according to claim 2, wherein the at least one detection branch (EZ1) evaluates a rectified signal (I _sense ). A luminous converter according to claim 2 or 3, wherein said at least one detection branch (EZ1) comprises a sample-and-hold circuit (S3, RH1, CH1). A luminous converter according to one of claims 2 to 4, wherein the detection circuit (ES) has a detection branch (EZ1, EZ2) for each current path (SP1, SP2). A luminous converter according to any one of claims 2 to 4, wherein the at least one detection branch (EZ1) comprises a switch (S3, S4) clocked synchronously with one of the switches (S1, S2) of the half-bridge circuit (HB). A luminous converter according to any one of claims 2 to 6, wherein the at least one detection branch (EZ1) detects a voltage and / or a voltage value which is proportional to the current through the current path (SP1). Lamp converter according to one of the preceding claims, wherein the control circuit (SE) depending on the control circuit (SE) supplied signal (V1, V2) changes a duty cycle of the half-bridge circuit (HB) and in particular a turn-on period of at least one of the two switches (S1, S2) of the half-bridge (HB) shortened or extended. A luminous converter according to any one of the preceding claims, wherein each current path (SP1, SP2) has a sense inductance (L3a, L3b) electromagnetically coupled to at least a third sense inductance (L3c) of the sense circuit (ES). The luminous converter according to one of claims 2 to 9, wherein the at least one detection branch (EZ1) of the detection circuit (ES) is arranged between a rectifier (GR) and filter circuit (FS). Illuminant converter according to one of the preceding claims, wherein the control circuit (SE) changes the control of the two switches (S1, S2) of the half-bridge circuit (HB) by changing the timing until the signal (V1, V1, V2) corresponds to a desired value and / or the control circuit supplied signals (V1, V2) are in particular substantially equal, z. B. have the same signal values. Illuminant converter according to one of the preceding claims, wherein the control circuit (SE) changed the control of the two switches (S1, S2) of the half-bridge circuit by changing the timing until a set value for the signal supplied to the control circuit (SE) (V1, V2) is reached, which in particular reflects a ratio of two voltage values. Lamp converter according to one of the preceding claims, wherein the detection circuit (ES) comprises two detection branches (EZ2, EZ2) whose switches (S3, S4) are clocked synchronously with in each case one of the two switches (S1, S2) of the half-bridge circuit (HB) , Illuminant converter according to one of the preceding claims, wherein the detection circuit (ES) of the control circuit (SE) two signals (V1, V2) supplies, each having a current (I _SP1 , I _SP2 ) by a current path (SP1, SP2) indicate electrical parameters, and / or sets the two signals (V1, V2) in a relationship and transmits information about the relationship to the control unit (SE). A method for balancing the current flows at the output of an LLC resonant circuit starting from the secondary side bulbs such. B. an LED track, the LLC resonant circuit, wherein - a control circuit (SE) two series-connected switch (S1, S2) of a half-bridge circuit (HB) drives, and wherein the half-bridge circuit (HB) starting from a Mittenpunkt (M1) of the two switches (S1, S2) supplies a resonant circuit (RK), and starting from an output of the resonant circuit (RK), a transformer (T1) is fed with AC voltage, on the secondary side of each a current path (SP1, SP2) is provided for each of the two polarities of the AC voltage, characterized in that - a detection circuit (ES) detects a signal (V1, V2), the currents (I _SP1 , I _SP2 ) in the two current paths (SP1, SP2 ) and / or their relationship, and the control circuit (SE) adjusts the timing of the two switches (S1, S2) of the half-bridge circuit (HB) in dependence on the signal (V1, V2) detected by the detection circuit (ES).

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