EP2715923A2

EP2715923A2 - Snubber circuit for dc-dc voltage converter

Info

Publication number: EP2715923A2
Application number: EP12711885.9A
Authority: EP
Inventors: Stefan Koch; Jian Tian
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2011-05-27
Filing date: 2012-04-03
Publication date: 2014-04-09
Also published as: DE102011076573A1; US20140126247A1; WO2012163575A3; WO2012163575A2; CN103563229A; CN103563229B

Abstract

The invention relates to a DC-DC voltage converter (1), having a transformer (2) having a primary winding (2a) and a secondary winding (2b, 2c) having a centre tap, an output inductor (3), which is connected to the centre tap and to a first output connection (9a), a synchronous rectifier circuit (4) having two synchronous rectifier switches (14a, 14b), each of which is connected to the terminal taps of the secondary winding (2b, 2c), and which are designed to produce a rectified output voltage on a second output connection (9b), and a snubber circuit (5) that is switched by means of the synchronous rectifier circuit (4). In this case, the snubber circuit has two diodes (16a, 16b), each of which is coupled to the terminal taps of the secondary winding (2b, 2c), a capacitor (6), which is coupled to the two diodes (16a, 16b) and which is designed to store resonant oscillation energy arising in the synchronous rectifier circuit (4), and a discharge circuit (7) comprising a series circuit containing a discharge switch (18) and a resistor (17), wherein the discharge circuit (7) is coupled between the first output connection (9a) and the capacitor and is designed to selectively feed back stored charge in the capacitor (6) to the first output connection (9a).

Description

Description title

Snubber circuit for DC-DC converter

The invention relates to a snubber circuit for a DC-DC converter, in particular for a center rectifier with synchronous rectification.

State of the art

For DC voltage conversion, for example, to supply a

Niedervoltbordnetzes a vehicle, are usually

Synchronous rectifier circuits used. The used for this purpose

Power semiconductor switches, for example, MOSFETs, have a lower loss voltage than diodes, especially at higher DC currents, whereby the

Efficiency of the rectifier can be increased. Due to the output capacitance of blocked semiconductor switches, it can lead to the phenomenon of "secondary ringing", ie the occurrence of undesired currents in the case of galvanically decoupled synchronous rectifiers

Oscillations of the current or voltage come. In this case, a resonance between the leakage inductance of the secondary side of the transformer with the

secondary side inductance and the output capacitance of the semiconductor switch. Conventional synchronous rectifiers therefore have attenuators, so-called

"Snubber-members" on which load the oscillation energy of the oscillations when a critical voltage limit is exceeded to a capacity. For example, passive snubber elements may consist of a series connection of a capacitor with a resistor which, as an RC erase combination, is connected in parallel with

Semiconductor switch can be switched. In contrast, active snubber elements have, in addition to the capacitor, a further semiconductor switch, via which the excess charge can be dissipated when a critical amount of charge on the capacitor is exceeded, for example, back into the secondary-side vehicle electrical system. The document US 6,771, 521 B1 discloses an active snubber circuit for a synchronous rectifier with a damping capacitor, which via a

Semiconductor switch can be discharged switchable. The document US 5,898,581 discloses a center-rectifier circuit with an active snubber circuit, wherein an inductive element on a

Snubber capacitor stored oscillation charge can be fed back into the rectifier circuit.

Conventional snubber circuits, for example those disclosed in US 5,898,581, are designed for high voltages and high energies, respectively

To keep power losses low (so-called "lossless snubber"). In particular, the inductive components commonly used in buck converters such as

Snubber chokes are associated with high unit costs because the components themselves are expensive and continue to cause high manufacturing costs in assembly.

DISCLOSURE OF THE INVENTION The present invention according to one embodiment provides a

A DC-DC converter, comprising a transformer having a primary-side winding and a secondary-side winding with a center tap, an output inductance, which is connected to the center tap and a first output terminal, a

Synchronous rectifier circuit having two synchronous rectifier switches, which are respectively connected to the end taps of the secondary side winding, and which for generating a rectified output voltage to a second

Output terminal are designed, and a connected via the synchronous rectifier circuit Snubberschaltung. The snubber circuit in this case has two diodes which are each coupled to the end taps of the secondary side Wcklung, a capacitor which is coupled to the two diodes, and which is adapted to store resonant vibrational energy in the synchronous rectifier circuit, and a discharge circuit of a series circuit a discharge switch and a resistor, wherein the discharge circuit is coupled between the first output terminal and the capacitor and is adapted to selectively feed stored charge in the capacitor back into the first output terminal.

Advantages of the invention

One idea of the present invention is to provide a snubber circuit for a

DC converter, which in applications in which due to the low energy during secondary ringing and the reverse recovery (reverse recovery) power losses are negligible, easier and

are more cost-effective to produce. These are inductive components such as a Snubber choke of an active snubber circuit by a current-limiting

Resistance replaced. The power losses in this resistance are negligible in terms of degree of control. Another idea of the present invention is to provide a freewheeling diode in the

Do not feed back path of the capacitor, since no inductive components are used.

Further features and advantages of embodiments of the invention will become apparent from the following description with reference to the accompanying drawings.

Brief description of the drawings

Show it:

Fig. 1 is a schematic representation of a DC-DC converter according to an embodiment of the invention, and

Fig. 2 is a schematic representation of a DC-DC converter according to another embodiment of the invention.

1 shows a schematic representation of a DC-DC converter 1. The DC-DC converter 1 comprises a transformer 2 having a primary-side winding 2a and a secondary-side winding, which is divided by a center tap into two sections 2b and 2c. The transformer 2 may be designed, for example, for converting a high-voltage into a low-voltage and, for example, have a winding ratio between primary-side and secondary-side Wecklung of over one, in particular 10: 1. The winding ratio of the two secondary-side winding sections 2b and 2c may be equal to one.

In particular, the winding ratio can be one, that is, the two secondary-side winding sections 2b and 2c have the same Wcklungszahl.

The center tap is connected via a secondary-side inductance 3 with a first output terminal 9a. The two end taps of the respective secondary-side winding sections 2b and 2c are connected on one side to two inputs of a synchronous rectifier circuit 4, and on the other hand to two inputs of a active snubber circuit 5. The DC-DC converter 1 realizes a

Center-point rectifier circuit with active synchronous rectification.

The synchronous rectifier circuit 4 is configured to receive one of the end-side taps of the respective secondary-side winding sections 2b and 2c on the

Transformer 2 secondary side voltage to tap and convert via a suitable interconnection in a DC voltage at a second output terminal 9b. In other words, during the operation of the DC-DC converter 1 between the output terminals 9a and 9b, a DC output voltage can be tapped.

Between the synchronous rectifier circuit 4 and the second output terminal 9b, a shunt resistor 4a can further be provided, at which the output current to the second output terminal 9b can be measured. Between the first and the second output terminal 9a, 9b, a DC voltage intermediate circuit 8 can also be provided, which can serve for voltage smoothing.

The snubber circuit 5 has two snubber elements 5a and 5b, which are each connected to the end-side taps of the secondary-side Wcklung 2b, 2c of the transformer 2. The snubber elements 5a and 5b are designed to

Voltage spikes, which may occur at the inputs of the synchronous rectifier circuit 4, intercept and deliver it to a snubber capacitor or capacitor 6. The secondary-side winding 2b, 2c has a leakage inductance, whereby voltage oscillations, so-called "secondary ringing", can occur between the output capacitance of the elements of the synchronous rectifier circuit 4 and the leakage inductance. The occurring vibration energy is stored at a predetermined voltage across the snubber elements 5a and 5b on the capacitor 6. The capacitor 6 can be realized, for example, over a certain number of capacitors connected in parallel, for example, six parallel-connected ceramic capacitors.

When the capacitor 6 has received a predetermined amount of charge, that is, when the voltage applied to the capacitor 6 has exceeded a predetermined threshold value, the energy stored on the capacitor 6 can be fed via a discharge circuit 7 back into the DC-DC converter 1. The feedback via the discharge circuit can preferably take place during a period during which the synchronous rectifier circuit 4 is in a freewheeling state. FIG. 2 shows a DC-DC converter 1 according to FIG. 1 in greater detail. The DC-DC converter 1 can have between the DC intermediate circuit 8 and the second output terminal 9b a circuit breaker 13a, which is designed to separate the DC-DC converter 1 from a connected low-voltage network. The circuit breaker 13a can, for example, two

Field effect transistors are constructed. Furthermore, the DC-DC converter 1 comprises a polarity reversal protection switch 13b, which is designed to ensure protection against reverse polarity at the output terminals 9a, 9b. Of the

Polarity reversal switch 13b can also be, for example, two

Field effect transistors are constructed.

At a junction between the shunt resistor 4 a and the circuit breaker 13 a, a connection to ground, for example to a housing 12, can be made via a capacitor 1 1 in order to ensure the electromagnetic compatibility of the housing

DC-DC converter 1 to ensure.

The synchronous rectifier circuit 4 is shown in FIG. 2 by two

Synchronous rectifier switches 14a and 14b implemented. Everyone who

Synchronous rectifier switch 14a, 14b has an active switching element and a freewheeling diode connected in parallel therewith. It is clear that the free-wheeling diode may be the parasitic diode of the active switching element itself when using semiconductor switches. It may further be provided to provide passive snubber elements in parallel to each switching element, for example, as shown in Fig. 2, RC quenching combinations with a series circuit of a capacitor and a

Resistor be provided in parallel to the active switching element and the freewheeling diode.

The snubber circuit 5 comprises two snubber elements 5a and 5b

Parallel circuits of a respective diode 16a and 16b and a capacitor 15a and 15b. Whenever a threshold voltage is exceeded at the inputs of the synchronous rectifier switches 14a, 14b, excess (oscillating) charge is discharged to the capacitor 6 via the diodes 16a, 16b. Exceeds the voltage at the

Capacitor 6 a predetermined voltage value, the charge can be actively fed via a discharge switch 18 by a Wderstand 17 in the DC-DC converter 1. Due to the low secondary side voltages in the

DC-DC converter 1, the power losses in the current-limiting resistor 17 are negligible. In an alternative embodiment it can be provided that a diode (not shown) is arranged between the resistor 17 and the node between the secondary inductance 3 and the first output terminal 9a. Such a diode can be used to disturbs such as

Voltage fluctuations of the low-voltage network to the capacitor 6 to minimize.

Control of the discharge switch 18 can be accomplished by allowing a discharge of the capacitor 6 during the freewheeling phase of the active switching elements, i. of the

Synchronous rectifier switch 14a and 14b takes place. The typical period of a snubber event at one of the synchronous rectifier switches 14a and 14b may be less than 5 με, for example. Furthermore, the charge transport of the resonant oscillations to the capacitor 6 can be completed, for example, after 1 με. Thus, the maximum discharge duration may be 4 με, in a time interval between 1 με and 5 με after a closure of the synchronous rectifier switch 14a or 14b. During this period, the discharge switch 18 may be additionally opened under the condition that the voltage across the capacitor 6 exceeds a predetermined value, for example, 10% of the voltage across the primary-side winding 2a of the transformer 2, by the charge stored on the capacitor 6 on the

Resistor 17 and possibly a freewheeling diode to the first output terminal 9 a dissipate.

The synchronous rectifier switches 14a, 14b used, the circuit breakers 13a, 13b and the discharge switch 18 can each have semiconductor switches, such as field-effect transistors (FETs). In the embodiments shown, the semiconductor switches are each shown as self-blocking n-MOSFETs (n-type metal oxide semiconductor field-effect transistors, but it is also possible to provide other semiconductor switches in appropriate form, for example in the form of IGBTs (Insulated Gate Bipolar Transistors), JFETs (Junction Field Effect Transistors) or p-MOSFETs (P-type Metal Oxide Semiconductor Field-Effect Transistors).

Claims

Claims 1. DC-DC converter (1), with:

a transformer (2) having a primary-side winding (2a) and a

Secondary winding (2b, 2c) with center tap;

an output inductor (3) connected to the center tap and a first one

Output terminal (9a) is connected;

a synchronous rectifier circuit (4) having two synchronous rectifier switches (14a, 14b) respectively connected to the end taps of the secondary side circuit (2b, 2c) and which is for generating a rectified one

Output voltage at a second output terminal (9b) are designed; and a snubber circuit (5) connected via the synchronous rectifier circuit (4), comprising:

two diodes (16a, 16b) respectively coupled to the end taps of the secondary side winding (2b, 2c);

a capacitor (6) coupled to the two diodes (16a, 16b) and configured to store resonant vibrational energy occurring in the synchronous rectifier circuit (4); and

a discharge circuit (7) of a series connection of a discharge switch (18) and a resistor (17), said discharge circuit (7) being coupled between said first output terminal (9a) and said capacitor (6) and being adapted to store stored charge in said discharge circuit Capacitor (6) selectively fed back into the first output terminal (9a).

2. DC-DC converter (1) according to claim 1, wherein the discharge circuit (7) further comprises a in series with the Wderstand (17) connected freewheeling diode.

3. DC-DC converter (1) according to any one of claims 1 and 2, wherein the

Synchronous rectifier circuit (4) further comprises two RC elements, which are respectively connected in parallel with the two synchronous rectifier switches (14a, 14b).

4. DC-DC converter (1) according to one of claims 1 to 3, wherein the

Winding ratio of the primary-side (2a) to the secondary-side winding (2b, 2c) of the transformer (2) is greater than one.