JP2021078264A - Power conversion circuit - Google Patents

Abstract

To suppress ringing while preventing short circuit between high potential wiring and low potential wiring.SOLUTION: A power conversion circuit includes: a series circuit in which first switching elements and second switching elements are connected in series between high potential wiring and low potential wiring and third switching elements and capacitors are connected in series and connected to the first switching elements in parallel; and a control circuit for controlling the third switching elements. The control circuit maintains an ON state of the third switching elements from timing before voltage applied to the first switching elements reaches peak voltage up to timing reaching the peak voltage or timing after the peak voltage timing and turns off the third switching elements at timing before stabilization at second voltage after the applied voltage reaches the peak voltage.SELECTED DRAWING: Figure 1

Description

The techniques disclosed herein relate to power conversion circuits.

The power conversion circuit disclosed in Patent Document 1 includes a first switching element and a second switching element connected in series between the high-potential wiring and the low-potential wiring. When the second switching element is turned on, the voltage applied to the first switching element rises. At this time, ringing (vibration of the applied voltage) occurs in the first switching element. In the technique of Patent Document 1, the gate voltage of the second switching element is increased in a part of the period during which the applied voltage of the first switching element increases. This suppresses ringing.

Japanese Unexamined Patent Publication No. 2013-162590

In the technique of Patent Document 1, there is a period in which the gate voltage of both the first switching element and the second switching element is controlled to be equal to or higher than the threshold value. Therefore, within this period, the high-potential wiring and the low-potential wiring may be short-circuited via the first switching element and the second switching element, and a high load may be applied to the power conversion circuit due to the short-circuit current. This specification proposes a technique for suppressing ringing while preventing a short circuit between high-potential wiring and low-potential wiring.

The power conversion circuit disclosed in the present specification includes a high-potential wiring, a low-potential wiring, a first switching element and a second switching element connected in series between the high-potential wiring and the low-potential wiring, and a second. 3 A series circuit in which a switching element and a capacitor are connected in series and connected in parallel to the first switching element, and a control circuit for controlling the third switching element. .. When the second switching element is turned on, the voltage applied to the first switching element rises from the first voltage to the peak voltage, and then drops from the peak voltage to the second voltage higher than the first voltage. The voltage changes so as to be stable at the second voltage. The control circuit keeps the third switching element on from the timing before the applied voltage reaches the peak voltage to the timing when the peak voltage is reached or thereafter, and the applied voltage is the peak voltage. The third switching element is turned off at a timing after reaching the limit and before the second voltage stabilizes.

In this power conversion circuit, the third switching element is turned on when the voltage applied to the first switching element rises toward the peak voltage due to the turn-on of the second switching element. Since the third switching element has a constant on-resistance, the series circuit of the third switching element and the capacitor operates as a snubber circuit. Therefore, when the third switching element is turned on, ringing in the first switching element is suppressed. Further, since the third switching element is turned off before the timing when the applied voltage of the first switching element stabilizes at the second voltage, the applied voltage of the first switching element is immediately changed to the second voltage when the third switching element is turned off. Stable. This suppresses turn-off loss. Further, even if the second switching element and the third switching element are turned on at the same time as described above, the capacitor prevents a short circuit between the high potential wiring and the low potential wiring. As described above, according to this power conversion circuit, ringing can be suppressed while preventing a short circuit between the high-potential wiring and the low-potential wiring.

The circuit diagram of the power conversion circuit 10. The graph which shows the change of each value when the main switching element 22 is turned on. The graph which shows the change of each value when the main switching element 22 is turned off. Circuit diagram of the power conversion circuit path of the modified example.

The power conversion circuit 10 of the embodiment shown in FIG. 1 has a main switching element 21 and a main switching element 22. The main switching element 21 and the main switching element 22 are MOSFETs (metal oxide semiconductor field effect transistors). The power conversion circuit 10 has a high-potential wiring 12, a low-potential wiring 14 (ground wiring), and an output wiring 16. The main switching element 21 and the main switching element 22 are connected in series between the high potential wiring 12 and the low potential wiring 14. The drain of the main switching element 21 is connected to the high potential wiring 12. The source of the main switching element 21 is connected to the output wiring 16. The drain of the main switching element 22 is connected to the output wiring 16. The source of the main switching element 22 is connected to the low potential wiring 14. Although not shown, the output wiring 16 is connected to the motor. The main switching element 21 and the main switching element 22 form a part of the inverter circuit. A DC voltage VH is applied between the high-potential wiring 12 and the low-potential wiring 14 in a direction in which the high-potential wiring 12 has a high potential. The potential of the output wiring 16 changes depending on the operation of the main switching element 21 and the main switching element 22. The inverter circuit converts the DC power applied between the high-potential wiring 12 and the low-potential wiring 14 into AC power, and supplies the AC power to the motor.

The main freewheeling diode 31 is connected in parallel with the main switching element 21. The anode of the main freewheeling diode 31 is connected to the source of the main switching element 21. The cathode of the main freewheeling diode 31 is connected to the drain of the main switching element 21. The main freewheeling diode 32 is connected in parallel with the main switching element 22. The anode of the main freewheeling diode 32 is connected to the source of the main switching element 22. The cathode of the main freewheeling diode 32 is connected to the drain of the main switching element 22.

A series circuit of the sub-switching element 41 and the capacitor 43 is connected in parallel with the main switching element 21. The sub-switching element 41 is a MOSFET. The drain of the sub-switching element 41 is connected to the high potential wiring 12. The source of the sub-switching element 41 is connected to one terminal of the capacitor 43. The other terminal of the capacitor 43 is connected to the output wiring 16. A sub-reflux diode 51 is connected in parallel with the sub-switching element 41. The anode of the sub-reflux diode 51 is connected to the source of the sub-switching element 41. The cathode of the sub-reflux diode 51 is connected to the drain of the sub-switching element 41.

A series circuit of the sub-switching element 42 and the capacitor 44 is connected in parallel with the main switching element 22. The sub-switching element 42 is a MOSFET. The drain of the sub-switching element 42 is connected to the output wiring 16. The source of the sub-switching element 42 is connected to one terminal of the capacitor 44. The other terminal of the capacitor 44 is connected to the low potential wiring 14. A sub-reflux diode 52 is connected in parallel with the sub-switching element 42. The anode of the sub-reflux diode 52 is connected to the source of the sub-switching element 42. The cathode of the sub-reflux diode 52 is connected to the drain of the sub-switching element 42.

The power conversion circuit 10 includes a gate drive circuit 61, a gate drive circuit 62, a drain voltage monitor circuit 71, a drain voltage monitor circuit 72, and a control circuit 80.

The gate drive circuit 61 is connected to the gate of the main switching element 21 and the gate of the sub switching element 41. The gate drive circuit 61 controls the gate voltage Vg21 of the main switching element 21 and the gate voltage Vg41 of the sub-switching element 41.

The gate drive circuit 62 is connected to the gate of the main switching element 22 and the gate of the sub switching element 42. The gate drive circuit 62 controls the gate voltage Vg 22 of the main switching element 22 and the gate voltage Vg 42 of the sub switching element 42.

The drain voltage monitor circuit 71 detects the drain-source voltage Vds21 (hereinafter referred to as the drain voltage Vds21) of the main switching element 21. The detected drain voltage Vds 21 is transmitted from the drain voltage monitor circuit 71 to the control circuit 80. The drain voltage monitor circuit 72 detects the drain-source voltage Vds22 (hereinafter referred to as the drain voltage Vds22) of the main switching element 22. The detected drain voltage Vds22 is transmitted from the drain voltage monitor circuit 72 to the control circuit 80.

The control circuit 80 transmits various commands to the gate drive circuit 61 and the gate drive circuit 62. For example, the control circuit 80 instructs the gate drive circuit 61 to switch between the main switching element 21 and the sub switching element 41. Further, the control circuit 80 instructs the gate drive circuit 62 to switch between the main switching element 22 and the sub switching element 42.

Next, a change in the drain voltage Vds21 of the main switching element 21 when the main switching element 22 is turned on will be described. In the following, a case where the sub-switching element 41 is controlled by the control method of the first embodiment and a case where the sub-switching element 41 is controlled by the control method of the comparative example will be described. In the control method of the comparative example, the sub-switching element 41 is kept off during the turn-on of the main switching element 22. In the control method of the first embodiment, the sub-switching element 41 is switched during the turn-on of the main switching element 22. FIG. 2 shows changes in each value in the control method of the comparative example and the control method of the first embodiment. In FIG. 2, the broken line graph shows the case of the control method of the comparative example, and the solid line graph shows the case of the control method of the first embodiment.

(Comparative Example) As described above, in the control method of the comparative example, the sub-switching element 41 is kept off during the turn-on of the main switching element 22. Therefore, as shown in FIG. 2, the gate voltage Vg41 of the sub-switching element 41 is maintained at a low potential Lo (for example, 0V). In the period before the timing t1, all the main switching elements 21 and 22 and the sub switching elements 41 and 42 are off. In the period before the timing t1, a current is flowing through the main freewheeling diode 31, the drain voltage Vds21 of the main switching element 21 is approximately 0V, and the drain voltage Vds22 of the main switching element 22 is a high voltage VH1 (high). The voltage is substantially the same as the voltage VH between the potential wiring 12 and the low potential wiring 14). At the timing t1, the gate drive circuit 62 raises the gate voltage Vg22 of the main switching element 22 from the low potential Lo to the high potential Hi by the command of the control circuit 80. Therefore, at the timing t1, the main switching element 22 turns on.

When the main switching element 22 is turned on at the timing t1, the drain voltage Vds22 of the main switching element 22 decreases and the drain current Id22 of the main switching element 22 increases after the timing t1. Then, the drain voltage Vds21 of the main switching element 21 rises accordingly. The drain voltage Vds21 of the main switching element 21 once rises to the peak value Vdssp1. The drain voltage Vds21 rises to the peak value Vdssp1 and then rings (vibrates). The drain voltage Vds21 changes to a voltage VH2 lower than the peak value Vdssp1 (a voltage substantially the same as the voltage VH between the high-potential wiring 12 and the low-potential wiring 14) while ringing. After the ringing is attenuated, the drain voltage Vds21 stabilizes at the voltage VH2.

(Example 1) Even in the control method of the first embodiment, in the period before the timing t1, all the main switching elements 21 and 22 and the sub-switching elements 41 and 42 are turned off, and a current is applied to the main freewheeling diode 31. Flowing. At the timing t1, the gate drive circuit 62 raises the gate voltage Vg22 of the main switching element 22 from the low potential Lo to the high potential Hi by the command of the control circuit 80. Therefore, at the timing t1, the main switching element 22 turns on.

When the main switching element 22 is turned on at the timing t1, the drain voltage Vds22 of the main switching element 22 decreases and the drain current Id22 of the main switching element 22 increases after the timing t1. Then, the drain voltage Vds21 of the main switching element 21 rises accordingly. The control circuit 80 turns on the sub-switching element 41 to the gate drive circuit 61 at the timing t2 when the drain voltage Vds22 of the main switching element 22 drops to the reference value Vref1 (for example, 90% of the initial value VH1). Command. Then, the gate drive circuit 61 raises the gate voltage Vg41 of the sub-switching element 41 from the low potential Lo to the high potential Hi, and turns on the sub-switching element 41. When the sub-switching element 41 is turned on, the sub-switching element 41 has a constant on-resistance, so that the series circuit of the sub-switching element 41 and the capacitor 43 functions as a snubber circuit. Therefore, when the drain voltage Vds21 of the main switching element 21 rises, the peak value Vdssp1 formed by the drain voltage Vds21 decreases, and ringing is suppressed. The control circuit 80 turns off the sub-switching element 41 to the gate drive circuit 61 at the timing t3 when the drain voltage Vds22 of the main switching element 22 drops to the reference value Vref2 (for example, a value of 5% of the initial value VH1). Command. Then, the gate drive circuit 61 lowers the gate voltage Vg41 of the sub-switching element 41 from the high potential Hi to the low potential Lo, and turns off the sub-switching element 41. When the sub-switching element 41 is turned off, the function of the snubber circuit is stopped, and the drain voltage Vds21 of the main switching element 21 is rapidly lowered to the voltage VH2 and stabilized.

As described above, by turning on the sub-switching element 41 in the process of turning on the main switching element 22, the ringing that occurs in the main switching element 21 can be suppressed. By suppressing ringing in this way, it is possible to reduce the number of radio noise reduction components added to the circuit, and it is possible to realize miniaturization and cost reduction of the circuit. Further, by reducing the peak value Vdssp1 of the drain voltage Vds21, it is possible to lower the withstand voltage requirement value of the switching element 21, and it is possible to reduce the chip size of the switching element 21 and reduce the cost. it can.

Further, the graph C (graph of the alternate long and short dash line) of FIG. 2 shows the drain voltage Vds21 when the sub-switching element 41 is not turned off at the timing t3 (that is, when the sub-switching element 41 is kept on after the timing t3). It shows a change. In this case, since the snubber circuit continues to function even after the timing t3, it takes time for the drain voltage Vds21 to drop to the voltage VH2. As described above, when the drain voltage Vds 21 changes slowly, the loss generated in the main switching element 21 becomes large. On the other hand, by turning off the sub-switching element 41 when the drain voltage Vds22 drops to a predetermined value as in the first embodiment described above, the drain voltage Vds21 drops to the voltage VH2 relatively quickly while suppressing ringing. Can be made to. As a result, the loss generated in the main switching element 21 can be reduced.

Further, in this control method, the upper sub-switching element 41 and the lower main switching element 22 are turned on at the same time during the period between the timing t2 and the timing t3. However, the capacitor 43 prevents a short circuit between the high potential wiring 12 and the low potential wiring 14. That is, in the control method of the first embodiment, ringing can be suppressed while preventing a short circuit between the high potential wiring 12 and the low potential wiring 14.

When the main switching element 21 is turned on, the sub-switching element 42 is turned on during a part of the period in which the main switching element 21 is turned on, so that the ringing that occurs in the main switching element 22 is caused substantially as in the case of FIG. It can be suppressed.

In the control method of the first embodiment, the sub-switching element is turned off at the timing t3, but the sub-switching element may be turned off when a certain time has elapsed from the timing t3.

Next, a change in the drain voltage Vds22 of the main switching element 22 when the main switching element 22 is turned off will be described. In the following, a case where the sub-switching element 42 is controlled by the control method of the second embodiment and a case where the sub-switching element 42 is controlled by the control method of the comparative example will be described. In the control method of the comparative example, the sub-switching element 42 is kept off during the turn-off of the main switching element 22. In the control method of the second embodiment, the sub-switching element 42 is switched during the turn-off of the main switching element 22. FIG. 3 shows changes in each value in the control method of the comparative example and the control method of the second embodiment. In FIG. 3, the broken line graph shows the case of the control method of the comparative example, and the solid line graph shows the case of the control method of the second embodiment.

(Comparative Example) As described above, in the control method of the comparative example, the sub-switching element 42 is kept off during the turn-off of the main switching element 22. Therefore, as shown in FIG. 3, the gate voltage Vg 42 of the sub-switching element 42 is maintained at a low potential Lo (for example, 0 V). In the period before the timing t11, the main switching element 22 is on, and the main switching element 21 and the sub-switching elements 41 and 42 are off. In the period before the timing t11, a current flows from the output wiring 16 to the low potential wiring 14 via the main switching element 22, the drain voltage Vds22 of the main switching element 22 is approximately 0V, and the main switching element. The drain voltage Vds21 of 21 is a high voltage VH3 (a voltage substantially the same as the voltage VH between the high potential wiring 12 and the low potential wiring 14). At the timing t11, the gate drive circuit 62 lowers the gate voltage Vg22 of the main switching element 22 from the high potential Hi to the low potential Lo by the command of the control circuit 80. Therefore, at the timing t11, the main switching element 22 turns off.

When the main switching element 22 is turned off at the timing t11, the drain voltage Vds22 of the main switching element 22 increases and the drain current Id22 of the main switching element 22 decreases after the timing t11. Further, the drain voltage Vds21 of the main switching element 21 decreases. The drain voltage Vds22 of the main switching element 22 once rises to the peak value Vdssp2. The drain voltage Vds22 rings (vibrates) after rising to the peak value Vdssp2. The drain voltage Vds22 changes to a voltage VH4 lower than the peak value Vdssp2 (a voltage substantially the same as the voltage VH between the high-potential wiring 12 and the low-potential wiring 14) while ringing. After the ringing is attenuated, the drain voltage Vds22 stabilizes at the voltage VH4.

(Example 2) Also in the control method of the second embodiment, the main switching element 22 is on and the main switching elements 21 and the sub-switching elements 41 and 42 are off in the period before the timing t11. In the period before the timing t11, a current flows from the output wiring 16 to the low potential wiring 14 via the main switching element 22. At the timing t11, the gate drive circuit 62 lowers the gate voltage Vg22 of the main switching element 22 from the high potential Hi to the low potential Lo by the command of the control circuit 80. Therefore, at the timing t11, the main switching element 22 turns off. Further, in the control method of the second embodiment, at the timing t11, the control circuit 80 commands the gate drive circuit 62 to turn on the sub-switching element 42. Therefore, at the timing t11, the gate drive circuit 62 raises the gate voltage Vg 42 of the sub-switching element 42 from the low potential Lo to the high potential Hi, and turns on the sub-switching element 42.

After the timing t11, the drain voltage Vds22 of the main switching element 22 increases and the drain current Id22 of the main switching element 22 decreases. At this time, since the sub-switching element 42 is turned on, the series circuit of the sub-switching element 42 and the capacitor 44 functions as a snubber circuit. Therefore, in the control method of the second embodiment, the drain voltage Vds22 and the drain current Id22 change more slowly than the control method of the comparative example. Therefore, when the drain voltage Vds22 of the main switching element 22 rises, the peak value Vdssp2 formed by the drain voltage Vds22 decreases. Also, after the peak value Vdssp2, ringing is suppressed. In the control circuit 80, at the timing when the drain current Ids 22 of the main switching element 22 drops to the reference value Iref (for example, 20% of the initial value) or when the peak value Vdssp2 is detected (timing t12 in FIG. 3). The gate drive circuit 62 is instructed to turn off the sub-switching element 42. Then, the gate drive circuit 62 lowers the gate voltage Vg 42 of the sub-switching element 42 from the high potential Hi to the low potential Lo, and turns off the sub-switching element 42. When the sub-switching element 42 is turned off, the function of the snubber circuit is stopped, and the drain voltage Vds22 of the main switching element 22 rapidly drops to the voltage VH4 and stabilizes.

As described above, by turning on the sub-switching element 42 in the process of turning off the main switching element 22, the ringing that occurs in the main switching element 22 can be suppressed. By suppressing ringing in this way, it is possible to reduce the number of radio noise reduction components added to the circuit, and it is possible to realize miniaturization and cost reduction of the circuit. Further, by reducing the peak value Vdssp2 of the drain voltage Vds22, it is possible to lower the withstand voltage requirement value of the switching element 22, and it is possible to reduce the chip size of the switching element 22 and reduce the cost. it can.

Further, the graph D (graph of the alternate long and short dash line) of FIG. 3 shows the drain voltage Vds22 when the sub-switching element 42 is not turned off at the timing t12 (that is, when the sub-switching element 42 is kept on after the timing t12). It shows a change. In this case, since the snubber circuit continues to function even after the timing t12, it takes time for the drain voltage Vds22 to drop to the voltage VH4. As described above, when the drain voltage Vds22 changes slowly, the loss generated in the main switching element 22 becomes large. On the other hand, by turning off the sub-switching element 42 at the timing t12 as in the second embodiment described above, the drain voltage Vds22 can be lowered to the voltage VH4 relatively quickly while suppressing ringing. Thereby, the loss generated in the main switching element 22 can be reduced.

When the main switching element 21 is turned off, the sub switching element 41 is turned on during a part of the period in which the main switching element 21 is turned off, so that the ringing that occurs in the main switching element 21 is caused substantially as in the case of FIG. It can be suppressed.

In the control method of the second embodiment, the sub-switching element is turned off at the timing t12, but the sub-switching element may be turned off when a certain time has elapsed from the timing t12.

Further, as shown in FIG. 4, the positions of the sub-switching elements 41 and 42 and the capacitors 43 and 44 may be exchanged in the power conversion circuit 10 of FIG.

In the power conversion circuit 10 described above, the switching elements 21, 22, 41, and 42 are MOSFETs, but these may be other switching elements such as an IGBT (insulated gate bipolar transistor).

Further, in the power conversion circuit 10 described above, the main switching element 21 and the main switching element 22 form a part of the inverter circuit, but the main switching element 21 and the main switching element 22 form a part of the DC-DC converter circuit. May be configured.

Although the embodiments have been described in detail above, these are merely examples and do not limit the scope of claims. The techniques described in the claims include various modifications and modifications of the specific examples illustrated above. The technical elements described in the present specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the techniques illustrated in this specification or drawings achieve a plurality of objectives at the same time, and achieving one of the objectives itself has technical usefulness.

10: Power conversion circuit 12: High potential wiring 14: Low potential wiring 16: Output wiring 21, 22: Main switching element 31, 32: Main freewheeling diode 41, 42: Sub switching element 43, 44: Capacitor 51, 52: Sub Freewheeling diode 61, 62: Gate drive circuit 71, 72: Drain voltage monitor circuit 80: Control circuit

Claims (1)

It is a power conversion circuit
With high potential wiring
With low potential wiring
A first switching element and a second switching element connected in series between the high-potential wiring and the low-potential wiring,
A series circuit in which the third switching element and the capacitor are connected in series, and a series circuit connected in parallel with the first switching element.
A control circuit that controls the third switching element,
Have,
When the second switching element is turned on, the voltage applied to the first switching element rises from the first voltage to the peak voltage, and then drops from the peak voltage to the second voltage higher than the first voltage. It changes to be stable at the second voltage,
The control circuit keeps the third switching element on from the timing before the applied voltage reaches the peak voltage to the timing when the peak voltage is reached or thereafter, and the applied voltage is the peak voltage. The third switching element is turned off at the timing after reaching the limit and before the second voltage stabilizes.
Power conversion circuit.

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