AT17254U1 - DC / DC converter with a damping circuit - Google Patents

Abstract

The present invention relates to a DC voltage converter with connections (2, 3) for supplying a DC voltage to be converted by the DC voltage converter (1), a current path connected in parallel with the connections (2, 3), a first switch (7) and a first coil (6), which are connected in series, has a damping circuit connected in parallel to the first coil (6), which has a first diode (15) and a first capacitor (13) which are connected in series and which has a the terminals (2, 3) and a circuit point between the first coil (6) and the switch (7) is connected, one from a circuit point between the first diode (15) and the first capacitor (13) to the other of the terminals ( 2, 3) leading current path, which has a second diode (16) and a second coil (14) which are connected in series, a second capacitor (17) connected in parallel to the terminals (2, 3), and a control device ( 1 2) to control the first switch (7), wherein the control device (12) is designed to switch off the first switch (7) before the second coil (14), the second diode (16) and the switch (7) flowing current has dropped to zero.

Description

description

DC VOLTAGE CONVERTER WITH A DAMPING CIRCUIT

The present invention relates to a DC-DC converter with a damping circuit. The invention relates in particular to a DC voltage converter for use in an operating device for lighting means such as light-emitting diodes and such an operating device.

[0002] Snubber circuits are often used in voltage converters in order to attenuate disruptive high frequencies and / or voltage peaks that occur in particular when the inductive load is switched off. For this purpose, in the simplest case, a snubber consisting of a resistor and a capacitance is connected in parallel to the switch and / or the inductive load (the energy store of the voltage converter). However, this circuit increases the power dissipation of the voltage converter, so that a compromise must be found between the level of attenuation / voltage limitation and the power dissipation resulting from the additional measure.

US 2014/0362623 A1 discloses a damping circuit for a flyoack converter, in which a current path, which has the switch and the primary winding of the transformer, leads in a known manner from one of the input connections to the other input connection. The damping circuit here has a first diode and a snubber capacitor, which are connected in parallel to the primary winding and a current path leading from a node between the first diode and the first capacitor to the other input connection, which consists of a second diode and a second coil, which are connected in series, is formed on. With the damping circuit, the current can briefly continue to flow through the primary winding via the snubber capacitor and the first diode after the switch has been switched off. After switching on the switch, the snubber capacitor discharges with a current flow through the switch, the second coil and the second diode.

According to US 2014/0362623 A1, in order to reduce the power loss, part of the energy stored in the snubber capacitor is transferred to the secondary side of the flyback converter by means of a second transformer, the second coil being the primary winding of the second transformer.

However, the use of a second transformer makes the DC-DC converter more expensive and prevents the circuit of the DC-DC converter from being miniaturized.

The invention is based on the object of specifying devices and methods which reduce the problems described. The task is, in particular, to provide DC voltage converters and an operating device for operating lighting means which are compact and inexpensive to manufacture and in which high frequencies and / or voltage peaks can be attenuated with low losses.

This object is achieved according to the features of independent claim 1. The invention is further developed by the features of the dependent claims.

According to the present invention, a DC-DC converter terminals for supplying a DC voltage to be converted by the DC-DC converter, a current path connected in parallel to the terminals and containing a first switch and a first coil which are connected in series, one with the first Coil parallel-connected damping circuit, a second capacitor connected in parallel to the terminals and a control device for controlling the first switch. The damping circuit is connected to one of the terminals and a node between the first coil and the switch and has a first diode and a first capacitor which are connected in series.

After the first switch is turned off, the first capacitor absorbs part of the energy stored in the first coil and is charged. After switching on the first switch again, a current flows from the first capacitor, via the first switch, the

second coil and the second diode and the first capacitor begin to discharge. The control device is designed to switch off the first switch before this current has dropped to zero, so that the energy stored in the second coil drives a current through the second diode, the first diode and the second capacitor and charges it. In this way, part of the energy stored in the damping circuit is transferred to the second capacitor connected in parallel to the terminals and made available again to the DC voltage converter for conversion. No additional transformer or an additional primary winding is required for the flyback converter.

The amount of returned energy depends on the control of the first switch or the switching times also on the dimensioning of the first capacitor and the second coil, so that the capacitance of the first capacitor and / or the inductance of the second coil compared to a circuit with a pure damping function is greatly enlarged. In particular with the choice of the inductance of the second coil, the amount of energy returned can be influenced.

The second capacitor can be the smoothing capacitor of a rectifier or power factor correction circuit connected to the terminals, so that no additional capacitor is required. In this way, no additional components are required and only the control of the first switch has to be adapted and, if necessary, a larger first capacitor and a larger second coil have to be provided.

The second capacitor can be charged by the damping circuit always or only at certain times, switching frequencies, load conditions (dimming level) and / or operating conditions (intermittent operation). The intensity of charging or the time at which the first switch is switched off can depend on the switching frequencies, load states and / or operating states or be fixedly predefined, with the control device being designed to switch off the first switch while the second coil and the second coil Diode and the switch increases current flowing or when the current flowing through the second coil, the second diode and the switch reaches its maximum.

By means of the voltage applied to the first capacitor (mean value), the voltage output by the DC voltage converter can be determined, the DC voltage converter having means for detecting the voltage drop across the first capacitor and the control device being designed to at least the voltage output by the DC voltage converter To determine voltage on the basis of the detected voltage, to determine a deviation between the determined voltage and a voltage to be output by the DC / DC converter, and to control the first switch on the basis of the determined deviation.

The damping circuit according to the invention can be used in a large number of DC voltage converters. In particular, the DC voltage converter can be a flyback converter in which the first coil is the primary winding of the transformer of the flyback converter.

The flyback converter can be a synchronous converter in which the diode on the secondary side of the flyback converter is replaced by a second switch controllable by the control device.

The control device can be designed to switch off the second switch after the current flowing through the secondary winding of the transformer of the flyback converter has dropped to zero after switching off the first switch and has reached a negative value.

The connections can be detachable connections or fixed soldered connections, for example on a circuit board.

According to the present invention, an operating device for operating lighting means has one of the DC voltage converters described above.

The invention is explained in more detail below with reference to the accompanying drawings. Show it:

1 shows a first embodiment of a DC voltage converter according to the present invention,

Fig. 2 shows a second embodiment of a DC voltage converter according to the present invention,

3 shows a diagram of the relationship between the voltage output by the DC voltage converter shown in FIG. 2 and the voltage at the snubber capacitor, and

4 shows an embodiment of an operating device according to the present invention.

Components with the same functions are identified in the figures with the same reference symbols.

Fig. 1 shows a simplified circuit of a DC voltage converter 1 according to a first embodiment of the present invention. The DC / DC converter 1 shown is a flyback converter, also called a “fliypack converter”, which transfers electrical energy between an input and an output side by means of a transformer T, which is used for galvanic separation (protective separation) from the mains voltage side with a grounded star point, transmits. With a flyback converter, a DC voltage supplied to the input can be converted into a DC voltage with a different voltage level with little circuitry complexity, the level difference being easily influenced by the choice of the transformer's winding ratio.

At the two input connections 2, 3 of the DC voltage converter 1 shown, a supply voltage is supplied which is a direct voltage or a rectified alternating voltage and which is galvanically decoupled by means of the transformer T and converted into a direct voltage with a different voltage level and applied to two output connections 4, 5 of the DC / DC converter 1 is output. Illuminants, for example LEDs or another converter (not shown) can be connected to the two output connections 4, 5.

The primary winding 6 of the transformer T, a controllable switch 7 and a measuring resistor 8 are connected in series between the first input terminal 1 and the second input terminal 2, which can be connected to ground. The secondary winding 9 of the transformer T and a diode 10 are connected in series between the first output connection 4 and the second output connection 5. A buffer / storage capacitor 11 is coupled in parallel to the output connections 4, 5. Primary and secondary windings 6, 9 of the transformer T have a different polarity / winding direction. The switch 7 is controlled by a control device 12 in order to switch it on and off.

The control device 12 can be an integrated semiconductor circuit or comprise an integrated semiconductor circuit. The control device 12 can be configured as a processor, a microprocessor, a controller, a microcontroller or an application-specific special circuit (ASIC, “Application Specific Integrated Circuit”) or a combination of the named units.

The control device 12 switches the switch 7 on and off again, wherein after switching on a current flows through the primary winding 6 of the transformer T and the measuring resistor 8, which is detected by the control device 12 by means of the voltage drop across the measuring resistor 8 . During the switch-on phase, the diode 10 suppresses a current flow on the secondary side of the transformer T. If the current through the primary winding 6 reaches a threshold value, the control device 12 switches the switch 7 off. After switching off (blocking phase), the energy stored in the primary winding 6 of the transformer T is released or forced via the secondary winding 9 of the transformer T

a current flow on the secondary side through the diode 10. The capacitor 11 is charged, and the lighting means 2 connected to the output connections 6, 7, if applicable, lights up.

According to the present invention, the DC voltage converter 1 has a damping circuit with a capacitor 13, a coil 14 and two diodes 15, 16. The diode 15 and the capacitor 13 form a current path which is arranged parallel to the primary winding 6 and which leads from a connection point between the primary winding 6 and the switch 7 to the input connection 2.

The diode 16 and the coil 14 form a further current path, which leads from a switching point between the switch 7 and the measuring resistor 8 to a switching point between the diode 15 and the capacitor 13, so that the current flow in this path (when open Switch 7) can be detected by the control device 12 by means of the measuring resistor 8. Alternatively, the current path can be coupled directly to the input connection 3.

After switching off the switch 7, a current flows briefly from the primary winding 6, through the capacitor 13 and the diode 15, which charges the capacitor 13 and limits / attenuates the rise in the voltage across the primary winding 6. The diode 15 blocks a discharge of the capacitor 13 via the primary winding 6 after the current has dropped to zero, and the open switch 7 prevents a discharge via the coil 14. During the current flow through the capacitor 13 in the damping phase, that rises through the secondary winding 9 flowing current and drops again after this damping phase. After switching on the switch 7 again, a current flows from the capacitor 13, via the switch 7, the coil 14 and the diode 16, so that the capacitor 13 discharges.

The control device 12 detects the current flowing through the switch 7, which is composed of the current through the primary winding 6 and the current through the coil 14, the diode 16 and the capacitor (discharge current) and switches the switch 7 off when the detected current reaches a predetermined threshold value. The threshold value is selected at least in part so that at the time of switching off the current (discharge current) through the coil 14, the diode 16 and the capacitor has not yet dropped to zero. Such switching off causes a current flow fed by the energy stored in the coil 14 through the diode 16, the diode 15 and a capacitor 17 connected in parallel to the input connections 2, 3, which is charged or additionally supplied with energy by this current flow. This charging current can be detected by the control device 12 by means of the measuring resistor and taken into account when selecting the next switch-on and / or switch-off time of the switch 7.

The capacitor 17 may be part of a rectifier or power factor correction circuit upstream of the DC / DC converter 1 and feeding it, or it may be present in addition to the buffer capacitor of the rectifier or power factor correction circuit. The switch 7 can be switched off and / or switched on at predetermined times and thus also without the detection of the current flowing through the switch 7 or without the provision of the measuring resistor 8, the discharge current not having dropped to zero at the time of switching off .

For a precise control or regulation, a determination of the voltage output by the DC voltage converter is necessary, in particular in the case of changing loads / dimming levels. A direct measurement of the output voltage across the potential barrier created by means of the transformer T is often only possible with great effort using an optocoupler, a second transformer or an additional auxiliary winding.

According to a second exemplary embodiment of the present invention, the voltage UA output by the DC voltage converter is determined by means of the voltage Uc on the capacitor 13. For this purpose, as shown in FIG. 2, the control device 12 additionally detects the voltage Uc directly on the capacitor 13. Alternatively, the detection can be carried out by means of a voltage divider (not shown).

The control device 12 calculates the output from the DC voltage converter

Voltage UA with the equation Ua = a Uc + b, the constants a and b being determined experimentally by the manufacturer or user on the DC voltage converter 1 or a structurally identical DC voltage converter 1 and stored in the control device 12. Alternatively, the manufacturer or user can create a table in an experiment or with the equation which assigns a voltage value UA to each of a plurality of voltage values Uc and store it in the control device 12, which determines the output voltage UA with the table. It is also possible to determine and store an equation or table for different loads / lighting means, the selection of the equation or table to be used by the control device 12 manually by the user or automatically by detection of the loads connected to the DC voltage converter 1 / Light source takes place.

Fig. 3 shows in a diagram the almost linear function Ua = f (Uc), which was determined experimentally for the flyback converter with different voltage or output power settings. The values depend on the dimensioning / design of the flyback converter. With the determined function or the determined table, the voltage UA output by the DC voltage converter 1 can be determined in a simple manner with the measured voltage Uc, without having to provide an additional auxiliary winding or an optocoupler.

The diode 10 on the secondary side can, as shown in FIG. 2, be replaced by a switch 18 controllable by the control device 12. The control device 12 controls the switches 7 and 18 in such a way that they are switched on and off alternately, with a dead time between switching off one switch and switching on the other switch. The switches 7, 18 can be transistors such as IGBTs or MOSFETs. According to one embodiment of the present invention, the control device 12 is designed to turn off the switch 18 after the current flowing through the secondary winding 9 of the transformer T has dropped to zero after the switch 7 has been switched off and has reached a negative value.

4 shows a simplified schematic illustration of an operating device 19 according to an exemplary embodiment of the present invention. The operating device 19 has the DC-DC converter 1 shown in Fig. 1 or 2, a network connection L, N for connecting the operating device 19 to an AC voltage, and a rectifier 20 with power factor correction, which converts the AC voltage to the input connections 2, 3 of the DC voltage converter 1 generated DC voltage, the switching times of the switch, which is switched on and off with a pulse-width modulated control voltage, are selected so that the input current of the rectifier 20 follows a sinusoidal curve that is in phase with the curve of the mains AC voltage. The operating device 19 is used to operate a lighting means 23 connected to the output connections 4, 5, which can comprise a light-emitting diode (LED, OLED) or several LEDs, OLEDs connected in series or in parallel.

Claims (1)

Claims 1. DC voltage converter with Connections (2, 3) for supplying a DC voltage to be converted by the DC voltage converter (1), a current path which is connected in parallel to the connections (2, 3) and has a first switch (7) and a first coil (6) which are connected in series, a damping circuit connected in parallel to the first coil (6), which has a first diode (15) and a first capacitor (13) which are connected in series and which has one of the connections (2, 3) and a node between the first coil (6) and the switch (7) is connected, a current path leading from a junction between the first diode (15) and the first capacitor (13) to the other of the terminals (2, 3), a second diode (16) and second coil (14) which are connected in series , having, a second capacitor (17) connected in parallel to the terminals (2, 3), and a control device (12) for controlling the first switch (7), wherein the control device (12) is designed to switch off the first switch (7) before the second coil (14), the second diode (16) and the switch (7) flowing current has dropped to zero. 2, DC voltage converter according to claim 1, having a rectifier or power factor correction circuit (20) for generating the direct voltage to be supplied to the terminals, the second capacitor (17) being the smoothing capacitor of the rectifier or power factor correction circuit (20). 3. DC-DC converter according to claim 1 or 2, wherein the control device (12) is designed to switch off the first switch (7) while the current flowing through the second coil (14), the second diode (16) and the switch (7) increases. 4. DC-DC converter according to claim 1 or 2, wherein the control device (12) is designed to switch off the first switch (7) when the current flowing through the second coil (14), the second diode (16) and the switch (7) reaches its maximum. 5. DC voltage converter according to one of the preceding claims, comprising means for detecting the voltage drop across the first capacitor (13), wherein the control device (12) is designed to determine at least the voltage output by the DC voltage converter (1) on the basis of the detected voltage, to determine a deviation between the determined voltage and a voltage to be output by the DC voltage converter (1) and the first switch (7) to control based on the determined deviation. 6. DC voltage converter according to one of the preceding claims, wherein the DC / DC converter (1) is a flyback converter and the first coil (6) is the primary winding of the transformer (T) of the flyback converter. 7. DC voltage converter according to claim 6, wherein the flyback converter is a synchronous converter in which the diode (10) on the secondary side of the flyback converter (1) is replaced by a second switch (18) controllable by the control device (12). 8. DC-DC converter according to claim 7, wherein the control device (12) is designed to switch off the second switch (18) after the current flowing through the secondary winding (9) of the transformer (T) of the flyback converter has dropped to zero after switching off the first switch (7) and a negative value has reached. 9. Operating device for operating lighting means (21) with a DC voltage converter (1) according to one of the preceding claims. In addition 4 sheets of drawings