AT513221A1 - DC converter - Google Patents

Abstract

The invention relates to a DC-DC converter, in which by means of two semiconductor switches (3, 4), such as transistors, cyclically an active energy storage, such as an inductor (5), is chargeable and dischargeable. The invention is characterized in that in order to avoid overvoltages to each of the two semiconductor switches (3, 4) a parallel branch is provided with at least two components connected in series, namely with a capacitor (6, 9) and a diode (7, 10 ), as well as a two resistors common resistance (12), by means of a switch (13) optionally parallel to - seen from the energy storage (5) - the first component of the one or the other parallel branch switchable.

Description

1 201128838

Description DC-DC converter Technical field

The invention relates to a DC-DC converter, in which by means of one or more semiconductor switches, such as IGBT or MOSFET, cyclically at least one active energy storage, such as an inductor, is rechargeable and dischargeable.

A DC-DC converter, also referred to as a DC-DC converter, denotes an electrical circuit which converts a DC voltage (input voltage) supplied at the input into a DC voltage with a higher, lower or inverted voltage level (output voltage). The implementation is carried out by means of a periodically operating electronic switch and one or more energy storage devices. The inductance used to buffer the energy (inductive converter) consists of a coil or a transformer transformer. In contrast, transducers with capacitive storage (capacitive transducer) are referred to as charge pumps.

The subject invention is preferably applied to boost converters and / or buck converters. Both embodiments use an inductance, such as a storage choke, as a buffer for the energy. In a boost converter, the output voltage is always greater than or equal to the input voltage, in a buck converter the output voltage is always less than or equal to the input voltage.

Such up and / or down converters are used in chargers, for example, chargers for electric cars. 2/14 2 201128838

State of the art

As the switching speeds of the transistors (e.g., IGBT, FET, SIC-FET), which are most commonly used as semiconductor switches, become larger and larger, the parasitic inductances in the leads to the DC-DC converter cause ever greater overvoltages in the form of voltage spikes across the transistor. In order to reduce these overvoltages, it is necessary to modify the circuits and / or install additional circuits.

One possible modification of the existing circuit is to increase the gate resistance at the transistor. As a result, however, the advantage of the fast transistor is destroyed and the switching losses increase.

A first additional circuit consists in the wiring of the transistor with an RC element, that is, a resistor R and a capacitor C. The turn-off of the transistor are thus partially transferred to the RC element, but the turn-on and conductive losses increase because the RC element is discharged quickly.

A second additional circuit consists in the wiring of the transistor with an RCD element (also referred to as RCD snubber circuit), which comprises a diode D in addition to the RC element. This diode makes it possible to reduce the losses in the resistance of the RCD member. By increasing the resistance of the RCD member, the losses resulting from the discharge of the capacitor of the RCD member in the switch can be reduced.

Known embodiments of the RCD member have at least the disadvantage that they are used in a device which both as a buck converter (buck converter), such as for charging a battery, and as a boost converter (boost converter), such as for supporting the power grid from a battery Example with a regenerative charger, must be arranged twice. 3/14 3 201128838

Presentation of the invention

It is an object of the present invention to provide a DC-DC converter, which ensures the damping of the overvoltage of a semiconductor switch, in particular a transistor, with an RCD gate both when operating as a buck converter and when operating as a step-up converter and which with fewer components than conventional DC-DC converter manages.

This object is achieved by a DC-DC converter having the features of patent claim 1. Advantageous embodiments of the invention are defined in the respective dependent claims.

According to claim 1, it is provided that to avoid overvoltages to each of the two semiconductor switches, a parallel branch is provided with at least two series-connected components, namely with a capacitor and a diode, and a two semiconductor switches common resistance, by means of a switch optionally in parallel for - seen from the energy storage - the first component of one or the other parallel branch is switchable.

This can be compared to conventional DC-DC converters, a resistance, such as a power resistance in the range of 10 W, can be saved and thus construction volume, component costs and power loss.

Depending on whether the first component is the capacitor or the diode in both parallel branches, viewed from the energy store, the common resistor is connected in parallel to either one of the capacitors or one of the diodes.

The diode of the parallel branch is - viewed from the energy storage - arranged in the forward direction, ie opposite to the forward direction of the freewheeling diode of the semiconductor switch. 4/14 4 201128838

A simple embodiment of the invention relates to the fact that the resistor is connected to a point which lies between the energy store on the one hand and the branch point of the two lines to the semiconductor switches on the other.

In a combined up and down converter (buck), there are two controllable semiconductor switches, one between the positive pole and the coil (buck) for buck converter function, one between the buck and coil connection point and the negative pole (parallel to the coil with capacitor) for the function as boost converter (boost converter).

The switch for switching the resistor can be designed as a relay, which has the advantage that the control of a relay is easier to implement than a drive for a transistor.

The inventive method for operating a DC-DC converter with two controllable

Semiconductor switches, namely a Tiefsetzschalter and a Hochsetzschalter, provides that for the operation as a buck converter (buck converter) only the Tiefsetzschalter is turned on and the resistor is connected to that parallel branch, which is arranged parallel to the Tiefsetzschalter. For operation as a boost converter (boost converter) it is provided that only the boost switch is turned on and the resistor is connected to that parallel branch which is arranged parallel to the boost switch.

Brief description of the figures

To further explain the invention, reference is made in the following part of the description to the figures, from which further advantageous embodiments, details and further developments of the invention can be found. Show it:

FIG. 1 shows a schematically illustrated DC-DC converter according to the prior art with resistors in parallel with the capacitors,

FIG. 2 shows a schematically illustrated DC-DC converter according to the invention with a resistor which can be connected in parallel with the capacitors,

FIG. 3 shows a schematically illustrated DC-DC converter according to the prior art with resistors in parallel with the diodes;

Figure 4 shows a schematically illustrated DC-DC converter according to the invention with a resistor which can be connected in parallel with the diodes.

Embodiment of the invention

In Fig. 1, an inventive up and down converter (up and down converter) is shown. A conventional step-up and step-down converter in its basic circuit comprises only the input capacitor 1, the output capacitor 2, the step-down switch designed as a so-called step-down transistor 3, the step-up switch designed as a so-called step-up transistor 4, and the coil (inductance) 5 as the active energy store.

For Tiefsetzertransistor 3 and 4 Hochsetzertransistor each freewheeling diode is connected in anti-parallel.

In the step-down mode, the current from commutating transistor 3 changes (commutates) to the free-wheeling diode, which is antiparallel to the step-up transistor 4. In boost mode, the current from commutating transistor 4 transitions (commutates) to the free-wheeling diode, which is antiparallel to buck converter transistor 3. These freewheeling diodes are usually integrated in the housing of an IGBT-s, but can also be arranged antiparallel to the IGBT and have their own housing. 6/14 6 201128838

The CD element according to the invention, that is to say the branch parallel to the transistor, is arranged in the immediate vicinity of the transistor to be protected.

The parallel branch which protects the buck converter transistor 3 consists of the components capacitor 6 and diode 7 and is connected in parallel to the step-up transistor 4, or parallel to the series circuit of coil 5 and output capacitor 2. In this case, capacitor 6 and diode 7 are connected in series with each other , the capacitor 6 is arranged in the current flow direction of the step-up transistor 4 (here from the upper positive pole to the lower negative pole) after the diode 7. Parallel to the capacitor 6, the resistor 8 is connected. In another embodiment, which is shown in Fig. 3, the resistor 8 is connected in parallel with the diode 7.

The parallel branch, which protects the boosting transistor 4, consists of the components capacitor 9 and diode 10 and is connected in parallel to the buck converter transistor 3. In this case, the capacitor 9 and diode 10 are connected in series with each other, the capacitor 9 is arranged in the current flow direction of the step-down transistor 3 (from the emitter to the collector) after the diode 10. Between capacitor 9 and diode 10, the resistor 11 is connected. In another embodiment, which is shown in Fig. 3, the resistor 11 is connected in parallel with the diode 10.

When the DC-DC converter as shown in Fig. 1 or 3 as a down-converter (buck) works, such as when a battery connected to the output is to be loaded, it works from right to left. In this case, only the Tiefsetzertransistor 3 is clocked (turned on), the Hochsetzertransistor 4 remains off. If the DC-DC converter from Fig. 1 or 3 as a boost converter (jack-up) work, it works from left to right. In this case, only the boosting transistor 4 is clocked (turned on). 7/14 7 201128838

In the embodiment according to the invention according to FIG. 2, in contrast to FIG. 1, only a single resistor 12 is provided whose supply line branches off from a point which lies between the coil 5 on the one hand and the branching point of the two lines to the semiconductor switches 3, 4 on the other hand. It is connected to a switch 13 which can connect the resistor to one of two lines 14, 15. The first line 14 leads to the parallel branch, which is arranged parallel to the step-down transistor 3, namely to a point which lies after the capacitor 9, that is, between diode 10 and capacitor 9. The resistor 12 can thus be connected in parallel with the capacitor 9.

The second line 15 leads to the parallel branch, which is arranged parallel to the Hochsetzertransistor 4, namely to a point which lies after the capacitor 6, ie between the diode 7 and capacitor 6. The resistor 12 can thus be connected in parallel to the capacitor 6.

In the embodiment according to the invention of FIG. 4, the positions of diode 10 and capacitor 9 are reversed compared to FIG. Likewise, the positions of diode 7 and capacitor 6 are reversed. Thus, as shown in FIG. 4, the resistor 12 may be connected to the switch 13 either parallel to the diode 10 or parallel to the diode 7. Compared to the embodiment in Fig. 3, one of the two resistors 8, 11 can be saved.

In principle, the switches 13 for the resistors 12 in all embodiments according to the invention can be designed as electromechanical switches (relays) or as electronic switches.

List of Reference Numerals: 1 input capacitor 2 output capacitor 3 down converter transistor 8/14 201128838 9/14 4 step-up transistor 4 5 coil 6 capacitor 7 diode 8 resistor 9 capacitor 10 diode 11 resistor 12 resistor 13 switch 14 first line 15 second line

Claims (5)

9 DC-DC converter, in which by means of two semiconductor switches (3, 4) cyclically at least one active energy storage, such as an inductance (5), is chargeable and dischargeable, characterized in that to avoid overvoltages to each of the two semiconductor switches (3 , 4) a parallel branch is provided with at least two components connected in series, namely with a capacitor (6, 9) and a diode (7, 10), as well as a common resistor (12), which is connected by means of a switch (13 ) optionally parallel to the - from the energy storage (5) seen from - the first component of one or the other parallel branch is switchable. 2. DC-DC converter according to claim 1, characterized in that the resistor (12) is connected to a point which lies between the energy store (5) on the one hand and the branch point of the two lines to the semiconductor switches (3, 4). 3. DC-DC converter according to claim 1 or 2, characterized in that the switch (13) for switching the resistor (12) is designed as a relay. 4. A method for operating a DC-DC converter according to one of claims 1 to 3 with two controllable semiconductor switches, namely a Tiefsetzschalter (3) 10/14 10 201128838 and a Hochsetzschalter (4), characterized in that for operation as a buck only the Tiefsetzschalter ( 3) is switched on and the resistor (12) is connected to that parallel branch, which is 5 parallel to the Tiefsetzschalter (4). 5. A method for operating a DC-DC converter according to one of claims 1 to 3 with two controllable semiconductor switches, namely a Tiefsetzschalter (3) and a Hochsetzschalter (4), characterized in that 10 for operation as a Hochsetzer only the Hochsetzschalter (4) is turned on and the resistor (12) is connected to that parallel branch which is arranged parallel to the boost switch (3). 11/14