WO2014033013A2 - Dc-dc converter - Google Patents

Abstract

A DC-DC converter (1) includes an unloading circuit (9) comprising a series resonant circuit (11, 12) to prevent loading during switching.

Description

 description

DC-DC converter The invention relates to a DC-DC converter.

A DC-DC converter, also referred to as a DC-DC converter, DC-DC converter or DC-DC converter, is an electrical circuit that converts a DC voltage provided at an input into a DC voltage provided at an output with a higher, lower, or inverted voltage level.

From the relevant specialist literature, so-called resonantly switched potential-separating DC-DC converters in full-bridge technology are known. These DC-DC converters are usually operated at a constant switching frequency in the so-called phase-shift method. Here, a respective half-bridge or its semiconductor switch with a clock or Ansteuersignalsignal with the switching frequency and an on-off ratio of 1: 1 is operated. A power flow control is achieved via a suitable adjustment of the phase position of the two clock signals.

The ratio of the switching frequency to a resonant frequency of a load circuit, which is applied to a voltage generated by the half-bridges determines an operating mode of the DC-DC converter with characteristic Schaltentlastungsarten for the semiconductor switches of the half-bridges. In principle, three operating modes can be distinguished: A first operating mode is the subresonant operation, in which the switching frequency is lower than the resonance frequency. Here, the semiconductor switches of the half-bridges in ZCS mode (Zero Current Switch, ie turning off at zero current) operated. A second mode is the quasi-resonant operation in which the switching frequency corresponds approximately to the resonant frequency. One of the half bridges operates in ZCS mode mode and the other of the half bridges in ZVS mode (Zero Voltage Switch, ie switching on at zero voltage).

The third operating mode is the over-resonant operation, in which the switching frequency is greater than the resonance frequency. The half bridges are each operated in ZVS mode.

Due to parasitic effects, semiconductor switches in the form of insulator gate bipolar transistors (IGBTs) can only be usefully used in conjunction with ZCS operation and metal oxide semiconductor field effect transistors (MOSFETs) only in conjunction with ZVS operation.

Since, for cost reasons, only IGBTs are used as semiconductor switches at DC link voltages of more than 450V, conventionally the sub-resonant mode of operation in conjunction with ZCS is mandatory. The disadvantage here, however, that the semiconductor switches must turn hard on freewheeling diodes of the complementary semiconductor switch. This is associated with additional switching losses due to the so-called recovery currents of the freewheeling diodes. Only the use of expensive silicon carbide diodes, which have negligible recovery currents, could reduce the additional switching losses.

Another disadvantage of the operating mode described is also an increased voltage gradient and thus additional losses in the overall system.

The invention has for its object to provide a DC-DC converter, in particular a resonant switched potential-separating DC-DC converter, which provides an increased power density compared with conventional DC-DC converters and has more degrees of freedom in electrical and mechanical design.

The invention solves this problem by a DC-DC converter according to claim 1.

The DC-DC converter has a first half-bridge with a first semiconductor switch and a second semiconductor switch, wherein the first and second semiconductor switches are connected in series between a first input voltage terminal and a second input voltage terminal, wherein between the first and the second input voltage terminal an input DC voltage (also as intermediate circuit voltage) is present. The DC input voltage may have a voltage level greater than 450V.

Furthermore, the DC-DC converter has a second half-bridge with a third semiconductor switch and a fourth semiconductor switch, wherein the third and fourth semiconductor switches are connected in series between the first input voltage terminal and the second input voltage terminal.

The first half-bridge and the second half-bridge are conventionally used to generate a square-wave voltage from the input DC voltage, so that in this respect reference is also made to the relevant specialist literature.

The DC-DC converter further has a load circuit with a load circuit resonance frequency, which is acted upon by the square-wave voltage generated by means of the two half-bridges.

A control unit of the DC-DC converter is used to control the semiconductor switches of the first and the second half-bridge, in particular in such a way that a specifiable level of an output equalizer is obtained. Adjusting voltage, for example, by conventionally a phase angle between drive signals is set appropriately. In that regard, reference is also made to the relevant specialist literature. The DC-DC converter has a discharge circuit. The relief circuit comprises a third half-bridge comprising a fifth semiconductor switch and a sixth semiconductor switch and a series resonant circuit having a capacitor and a series-connected coil. The fifth and sixth semiconductor switches are connected in series between the first input voltage terminal and the second input voltage terminal, and the series resonant circuit is connected between a connection node of the fifth and sixth semiconductor switches and the connection nodes of the third and fourth semiconductor switches.

The discharge circuit enables operation of the DC-DC converter in the region of the load circuit resonance frequency, without resulting in an unfavorable switching load of the semiconductor switches. The control unit may be designed to control the semiconductor switches of the third half-bridge in such a way that, when a switching state of the semiconductor switches of the second half-bridge, a current through that semiconductor switch of the second half-bridge, which is turned off, is minimized, in particular no current flows, so that the second half-bridge is operated due to the appropriately controlled discharge circuit as a result in ZCS mode.

The control unit may further be configured to cause a change in the switching state of the semiconductor switches of the first half-bridge at a time during which no current flows through that semiconductor switch of the first half-bridge which is switched off, ie the first half-bridge is conventionally operated in ZCS mode , The control unit may be further configured to drive the semiconductor switches of the first, the second and the third half-bridge with a switching frequency corresponding to the load circuit resonance frequency, ie the DC-DC converter is operated quasi-resonant.

The control unit may be further configured to turn on the first semiconductor switch of the third half-bridge during recurring first time periods, during the first time periods the first semiconductor switch of the second half-bridge is turned on and the second semiconductor switch of the second half-bridge is turned off and off outside of the first time ranges, and turn on the second semiconductor switch of the third half-bridge during recurring second time periods, wherein during the second time ranges the first semiconductor switch of the second half-bridge is turned off and the second semiconductor switch of the second half-bridge is turned on and off outside the second time ranges.

The series resonant circuit of the relieving circuit, by suitable choice of the components, may have a series resonant circuit resonant frequency which is typically in a range between twenty times the load circuit resonant frequency and one hundred times the load circuit resonant frequency.

The semiconductor switches may be Insulated Gate Bipolar Transistors (IG-BTs).

The load circuit may have a, for example, potential-separating, transformer or transformer with at least one primary winding and at least one secondary winding.

The load circuit may further comprise a rectifier circuit which is designed to convert the voltage output from a voltage across the at least one secondary winding of the transformer or transformer. To create tension. Between a connection node of the first and the second semiconductor switch and a connection node of the third and the fourth semiconductor switch, the at least one primary winding of the transformer, possibly with other intermediate-connected or looped components, looped.

The rectifier circuit may be a synchronous rectifier, which is operated synchronized to the first and / or second and / or third half-bridge.

The invention will be described in detail below with reference to the drawings. This shows schematically:

1 shows a DC-DC converter with a discharge circuit,

FIG. 2 shows a time characteristic of signals of the one shown in FIG

 DC-DC converter,

3 shows a first alternative embodiment of a load circuit of the DC-DC converter shown in FIG. 1, FIG.

4 shows a further alternative embodiment of a load circuit of the DC-DC converter shown in FIG. 1; FIG. 5 shows a further alternative embodiment of a load circuit of the DC-DC converter shown in FIG

Fig. 6 shows an alternative embodiment of a rectifier circuit shown in Figures 1 to 5.

1 shows a DC-DC converter 1 in full-bridge connection with a first half-bridge 2 and a second half-bridge 5 for generating a square-wave voltage UR from a Zwischenkreisspan- UZK with a voltage level of more than 450V, wherein a load circuit 13 of the DC-DC converter 1 is supplied with the thus generated square-wave voltage UR. In that regard, reference is also made to the relevant specialist literature.

The first half-bridge 2 comprises: a first semiconductor switch in the form of an IGBT 2a and a second semiconductor switch in the form of an IGBT 2b, wherein the first and second semiconductor switches 2a, 2b are connected in series between a first input voltage terminal 3 and a second input voltage terminal 4 are, between the first and the second input voltage terminal 3, 4 an input DC voltage or DC link voltage UZK is present.

The second half-bridge 5 comprises a third semiconductor switch in the form of an IGBT 5a and a fourth semiconductor switch in the form of an IGBT 5b, the third and fourth semiconductor switches 5a, 5b being connected in series between the first input voltage terminal 3 and the second input voltage terminal 4. The semiconductor switches 2a, 2b, 5a, 5b, 10a, 10b are conventionally connected in parallel with respective free-wheeling diodes.

The load circuit 13 comprises: a transformer 6 having a primary winding 6a and a secondary winding 6b, a rectifier circuit 7, which is designed to generate from a voltage at the secondary winding 6b of the transformer 6, the DC output voltage UA, and capacitors 14, 20 and 24 and coils 15, 16, 17, 18, 19 and 23 connected as shown, with the coils 16, 17, 18 and 19 representing non-ideal characteristics of the transformer 6 and not implemented as discrete components.

The primary winding 6a is connected in series with the capacitor 14 and the coil 15 between a connection node N1 of the first and second Semiconductor switch 2a, 2b and a connection node N2 of the third and fourth semiconductor switch 5a, 5b looped.

The transformer 6 has a center tap, at which an output reference potential is present. Rectifier diodes 21 and 22 of the rectifier circuit 7 cause a voltage rectification, wherein the thus rectified voltage is suppressed by means of the coil 23 and buffered by means of the capacitor 24. A control unit 8, for example in the form of a microprocessor, is used to control the semiconductor switches 2a, 2b, 5a, 5b of the first and second half-bridges 2, 5 in such a way that a specifiable or desired level of the output direct voltage UA is set. A discharge circuit 9 has a third half-bridge 10. The third half-bridge 10 comprises a fifth semiconductor switch in the form of an IGBT 10a and a sixth semiconductor switch in the form of an IGBT 10b and a series resonant circuit with a capacitor 1 1 and a series-connected coil 12, wherein the fifth and the sixth semiconductor switches 10a, 10b in series are looped between the first input voltage terminal 3 and the second input voltage terminal 4 and the series resonant circuit 1 1, 12 between a connection node N3 of the fifth and sixth semiconductor switch 10a, 10b and the connection node N2 of the third and fourth semiconductor switch 5a, 5b is looped. The semiconductor switches 10a and 10b are driven by the control unit 8.

Fig. 2 shows a timing of signals of the DC-DC converter 1 shown in Fig. 1 (i.e., a logic signal state over time).

Here, S1 denotes a drive signal for the semiconductor switch 2a, S2 \ a drive signal for the semiconductor switch 2b (in complementary S3) a drive signal for the semiconductor switch 5a, S4 a drive signal for the semiconductor switch 5b (in complementary representation), S5 a drive signal for the semiconductor switch 10a, S6 a drive signal for the semiconductor switch 10b, VS1 a voltage dropping on the semiconductor switch 2a , iS 1 a current through the semiconductor switch 2a, ID1 a current through the freewheeling diode of the semiconductor switch 2a, VS3 a falling voltage at the semiconductor switch 5a, iS3 a current through the semiconductor switch 5a and iD3 a current through the freewheeling diode of the semiconductor switch 5a.

The control unit 8 generates the drive signals S1 to S6 with a switching frequency which corresponds approximately to the load circuit resonance frequency, for example 100 kHz. In other words, the DC-DC converter 1 is operated quasi-resonantly, the half-bridge 2 conventionally operating in the ZCS mode mode, i. a change in the switching state of the semiconductor switches 2a, 2b of the first half-bridge 2 is effected at a time during which no current flows through the semiconductor switch of the first half-bridge 2, which is turned off. Due to the relief circuit 9 is also a transient resonant switching relief (ZCS) and the second half-bridge 5 in both current directions possible.

For this purpose, by suitably generating the signal S5, the control unit 8 switches on the first semiconductor switch 10a of the third half-bridge 10 during recurring first time ranges ZB1, during which the first semiconductor switch 5a of the second half-bridge is turned on and the second semiconductor switch 5b of the second half-bridge is switched off.

Accordingly, by suitably generating the signal S6, the control unit 8 turns on the second semiconductor switch 10b of the third half-bridge 10 during recurring second time ranges ZB2 while of which the first semiconductor switch 5a of the second half-bridge is turned off and the second semiconductor switch 5b of the second half-bridge is turned on. A portion of the current that would flow in a conventional DC-DC converter via the freewheeling diodes of the complementary semiconductor switches, according to the invention taken from the relief circuit 9 and its resonant circuit and also released again, so that switching losses are reduced in the freewheeling diodes.

As can be seen from the time course of the currents iS3 and iD3, a resonance frequency of the series resonant circuit of the discharge circuit 9 is substantially greater than the switching frequency of the control signals S1 to S6. The resonant frequency of the load circuit 13, i. Corresponding to the switching frequency of the control signals S1 to S6, in the example according to FIG. 2 is approximately 100 kHz. Accordingly, the half-bridges 2 and 5 and their semiconductor switches are clocked. The resonance frequency of the series resonant circuit of the discharge circuit 9 for a transient-resonant operating case, however, is significantly higher and is typically 2 to 10 MHz. The higher the resonance frequency of the series resonant circuit of the relief circuit 9 is selected, the lower the voltage drops in the system resulting from dead times of the resonance process become. The upper limit depends on the properties of the semiconductor switches, in particular the lifetime of the charge carriers in the barrier layer.

Therefore, the DC-DC converter 1 can be operated in the region of the load circuit resonance frequency, whereby an optimal utilization of the semiconductor switches and the magnetic components can be achieved. In addition, the combination of phase-shift control and switching frequency variation makes it possible to optimize the dynamic behavior of the DC-DC converter 1 with respect to load jumps. FIGS. 3 to 5 show an alternative embodiment of the load circuit 13 shown in FIG.

Thus, FIG. 3 shows a load circuit variant 13 'with an arrangement of capacitors 20a and 20b over the secondary winding 6b for limiting a voltage increase at the rectifier diodes 21 and 22, which has a favorable effect on their recovery behavior.

By minimizing a voltage gradient within the load circuit 13 ', the series-side effective series inductance can be reduced to the stray inductance of the transformer 6 so that components can be saved.

4 shows an embodiment of the load circuit 13 ", in which a split transformer 6 'is provided to increase the transmittable power, which is connected as a so-called power train, ie there are two series-connected primary windings 6a_1 and 6a_2 and two provided are secondary windings 6b_1 and 6b_2 connected in parallel The elements 16 to 19 are correspondingly present twice (in each case designated x_1 or x_2)

5 shows a complete powertrain concept 13 ", in which the parallel connection takes place on the secondary side only after smoothing reactors 23_1 and 23_ 2. FIG. 6 shows an alternative embodiment of the rectifier circuit 7 with synchronous rectification shown in FIGS. In the rectifier circuit in the form of a synchronous rectifier 7 'shown in FIG. 6, the diodes 21 and 22 of the rectifier circuit 7 are replaced by n-channel MOSFETs 21' and 22 '. The commutation (temporal change of the current path) via the parasitic body diodes of the MOSFETs 21 'and 22', wherein at low output voltages (eg 3.3V) and parallel circuits of MOSFET and silicon Schottky diode can be used in a component housing. In the subsequent Leitendphase the MOSFET 21 'and 22' is turned on. Since a MOSFET is basically a unipolar component, the current direction is irrelevant at first. This creates a parallel connection of the rail resistance (Rdson) and body diode when switched on. The resulting voltage gap can be so small with suitable dimensioning that the body diode no longer carries electricity. The Leitendverluste be greatly reduced.

In Rückkommutierung the MOSFET 21 'or 22' is switched off again shortly before the primary-side bridge voltage change. Thus, the current flows exclusively through the body diode. Subsequently, it is commutated to the other MOSFET 21 'or 22' via the body diode.

The switching or driving of the MOSFETs 21 'and 22' takes place via a drive circuit 21 'a or 22'a. The drive circuits 21 'a and 22'a are supplied with a signal 21' b or 22'b for turning on or off the MOSFETs 21 'and 22', respectively. The signals 21 'b and 22'b are synchronized with the control of the primary-side bridges 2, 5 and 10 according to the resulting secondary current flow.

Claims

claims

1. DC-DC converter (1), comprising:

 - a first half-bridge (2), comprising:

 - A first semiconductor switch (2 a) and

 a second semiconductor switch (2b),

 - wherein the first and the second semiconductor switch (2a, 2b) are connected in series between a first input voltage terminal (3) and a second input voltage terminal (4), wherein between the first and the second input voltage terminal (3, 4) an input DC voltage (UZK) pending,

 a second half bridge (5), comprising:

 a third semiconductor switch (5a) and

 - A fourth semiconductor switch (5b), wherein

 the third and fourth semiconductor switches (5a, 5b) are connected in series between the first input voltage terminal (3) and the second input voltage terminal (4), the first half-bridge (2) and the second half-bridge (5) generating a square-wave voltage ( UR) are formed from the input DC voltage (UZK),

 - A load circuit (13, 13 ', 13 ", 13"') with a load circuit resonance frequency, which is acted upon by the square-wave voltage (UR), and

 a control unit (8) for controlling the semiconductor switches (2a, 2b, 5a, 5b) of the first and second half bridges (2, 5) in such a way that a specifiable level of a DC output voltage (UA) is established,

 marked by

 - a discharge circuit (9), comprising:

 a third half-bridge (10), comprising:

 a fifth semiconductor switch (10a) and

a sixth semiconductor switch (10b) and - A series resonant circuit having a capacitor (1 1) and a series-connected coil (12), wherein

 the fifth and sixth semiconductor switches (10a, 10b) are connected in series between the first input voltage terminal (3) and the second input voltage terminal (4), and

 - The series resonant circuit (1 1, 12) between a connection node (N3) of the fifth and the sixth semiconductor switch (10a, 10b) and the connection node (N2) of the third and the fourth semiconductor switch (5a, 5b) is looped.

2. DC-DC converter according to claim 1, characterized in that the control unit (8) is designed to

 - To drive the semiconductor switches (10a, 10b) of the third half-bridge (10) such that when changing a switching state of the semiconductor switch (5a, 5b) of the second half-bridge (5), a current through that semiconductor switch of the second half-bridge (5), the off is minimized.

3. DC-DC converter according to claim 1 or 2, characterized in that the control unit (8) is adapted to cause a change in the switching state of the semiconductor switch (2 a, 2 b) of the first half-bridge (2) at a time during which no current through that semiconductor switch of the first half-bridge (2) flows, which is turned off.

4. DC-DC converter according to one of the preceding claims, characterized in that the control unit (8) is designed to

the semiconductor switches (2a, 2b, 5a, 5b, 10a, 10b) of the first, the second and the third half bridges (2, 5, 10) are provided with a switching freewheel to control the frequency corresponding to the load circuit resonance frequency.

5. DC-DC converter according to one of the preceding claims, characterized in that the control unit (8) is adapted to

 - turn on the first semiconductor switch (10a) of the third half-bridge (10) during recurring first time periods (ZB1) during which the first semiconductor switch (5a) of the second half bridge is turned on and the second semiconductor switch (5b) of the second half bridge is turned off and outside the first time ranges (ZB1) off, and

 to turn on the second semiconductor switch (10b) of the third half-bridge (10) during recurring second time periods (ZB2) during which the first semiconductor switch (5a) of the second half-bridge is turned off and the second semiconductor switch (5b) of the second half-bridge is turned on and outside the second time ranges (ZB2) off.

6. DC-DC converter according to one of the preceding claims, characterized in that the series resonant circuit (1 1, 12) of the discharge circuit (9) has a Serienschwingkreis- resonant frequency which is in a range between twenty times the load circuit resonant frequency and the hundredfold load circuit resonant frequency.

7. DC-DC converter according to one of the preceding claims, characterized in that the semiconductor switches (2a, 2b, 5a, 5b, 10a, 10b) are insulated gate bipolar transistors.

8. DC-DC converter according to one of the preceding claims, characterized in that the load circuit (13, 13 ', 13 ", 13"') comprises:

 - A transformer (6, 6 ') with at least one primary winding (6a;

 6a_1, 6a_2) and at least one secondary winding (6b; 6b_1, 6b_2) and

 a rectifier circuit (7) which is designed to generate a DC output voltage (UA) from a voltage at the at least one secondary winding (6b; 6b_1, 6b_2) of the transformer (6, 6 '),

 wherein between a connection node (N1) of the first and second semiconductor switches (2a, 2b) and a connection node (N2) of the third and fourth semiconductor switches (5a, 5b) the at least one primary winding (6b; 6b_1, 6b_2) of the transformer ( 6, 6 ') is looped.

9. DC-DC converter according to claim 8, characterized in that the rectifier circuit is a synchronous rectifier (7 ').

10. DC-DC converter according to claim 9, characterized in that the synchronous rectifier (7 ') in synchronism with the first to third half-bridge (2, 5, 10) is operated.