JP6452226B2 - DC-DC converter auxiliary circuit and bidirectional buck-boost DC-DC converter using the auxiliary circuit - Google Patents

Description

  The present invention relates to an auxiliary circuit for improving the efficiency of a DC-DC converter (DC-DC power converter) that converts an input DC voltage into a desired DC voltage and outputs it, and a bidirectional buck-boost DC- using the auxiliary circuit. The present invention relates to a DC converter.

  High-efficiency bidirectional DC-DC power converters are indispensable between high-voltage DC bus lines and low-voltage power storage devices such as batteries in power systems for electric vehicles and hybrid vehicles. In recent years, many researches and developments on circuit systems in which soft switching technology has been actively introduced have been conducted.

  For example, the power transmission function that is not greatly influenced by the battery voltage that varies depending on the remaining energy (SOC) between the drive system and the battery as shown in FIG. It is required from the viewpoint of rate improvement. For this reason, it is expected to realize a multifunctional high-efficiency bidirectional DC-DC converter that can perform step-up / step-down or step-up / step-down operation in two power flows between two DC power sources.

  The auxiliary circuit provided in the DC-DC converter disclosed in Patent Document 1 is for performing a soft switching operation capable of step-up / step-down. However, zero voltage soft switching (ZVS) Circuit. In the case of the DC-DC converter of Patent Document 1, there is a problem that an auxiliary circuit 18 (see FIG. 25) is required for each main switch.

  Further, the auxiliary circuit 17 (see FIG. 26) provided in the DC-DC converter disclosed in Patent Document 2 basically includes a half bridge of an inverter (reverse conductive power connected to one set of a high side and a low side. This is a technology that realizes soft switching of a totem pole structure using a semiconductor switch, and is based on an auxiliary resonant commutated pole (ARCP). That is, by using the electromagnetic energy accumulated in the reactor of the auxiliary circuit, the capacitor connected in parallel with each switch is charged and discharged during the short transition period when the upper and lower switches are switched. This is a ZVS (Zero Voltage Soft-Switching) circuit in which the terminal voltage of the switch gradually increases and decreases before and after switching (on / off) as a result of the operation of slowly charging and discharging the capacitor.

In the case of the DC-DC converter disclosed in Patent Document 2, it is considered that the ripple of the input / output smoothing filter may inevitably increase. In other words, the capacity of the filter capacitor is relatively increased or the heat generation is increased. The reason for this is considered to be a useless operation mode in which the ZVS resonance current generated by the auxiliary circuit is unnecessarily returned to the power supply side.
The DC-DC converters shown in FIGS. 7 and 8 of Patent Document 2 are circuits that can perform step-up and step-down operations in both directions. However, since the two main switches cannot be operated simultaneously, the same power flow is used. It is considered that it is difficult to realize the step-up / step-down operation because the voltage cannot be raised / lowered (step-up / step-down).

U.S. Pat. No. 7,548,435 JP 2013-138574 A

  The present inventors are an auxiliary circuit capable of realizing ZCS (Zero Current Soft-Switching), which is a soft switching technique suitable for a bipolar power device such as an IGBT (Insulated Gate Bipolar Transistor), and electrostatic energy stored in a resonance capacitor in advance. The circuit that can realize the commutation process in which most of the resonance current based on the above is confined by the auxiliary circuit and some resonance current appears only in the main switch was studied.

  The present invention provides a step-up, step-down, step-up / step-down DC-DC converter capable of ZCS operation in a wide range by adding a relatively simple auxiliary circuit, and a step-up / step-down in both power flows between two DC power supplies. It is an object of the present invention to provide a multifunctional high-efficiency bidirectional DC-DC converter capable of step-down or step-up / step-down operation.

In order to achieve the above object, the auxiliary circuit of the DC-DC converter of the present invention includes a series resonant switched capacitor and a ZCS promoting inductor.
In the DC-DC converter , a smoothing inductor and a forward freewheeling diode are sequentially connected in series on the positive electrode side of the input DC voltage, and a boosting switching element is connected between the midpoint of the series connection and the cathode side. In the step-up type, a ZCS promoting inductor is connected in series to the positive electrode side of the step-up switching element, and a series resonance type switched capacitor is connected in parallel to both ends of the series connection structure.
Here, the series resonance type switched capacitor constitutes a series resonance circuit by connecting a resonance inductor and a capacitor in series, and realizes a highly efficient auxiliary switch circuit by soft switching.
Further, ZCS promotion inductor, IGBT against bipolar transistors and freewheeling diodes, such as (insulated gate bipolar transistor), the current at the time of their on / off transition is a soft switching for up and down with an inclination ZCS (Zero This is an inductor for performing Current Soft-Switching.

Also, in the DC-DC converter , a step-down switching element and a smoothing inductor are connected in series in order to the positive side of the input DC voltage, and a reverse free-wheeling diode is connected between the midpoint of the series connection and the cathode side. for a buck type, ZCS promotion inductor in series to the positive side of the freewheeling diode is connected in series, and the series resonant switched capacitor is connected in parallel across the series connection structure,

In the DC-DC converter , a smoothing inductor and a step-down switching element are sequentially connected in series on the positive electrode side of the input DC voltage, and the step-up switching element is connected between the midpoint of the series connection and the cathode side, In the case of a step-up / step-down type in which an anti-parallel connection diode is connected to each of the step-down switching element and the step-up switching element, on the positive side of the switch composed of the step-up switching element and an anti-parallel connection diode connected in reverse parallel thereto A ZCS promoting inductor is connected in series in series, and a series resonant switched capacitor is connected in parallel at both ends of the series connection structure.

  Here, in the series resonance type switched capacitor, it is preferable that a resonance inductor, a resonance capacitor, and a switching element are connected in series from the positive electrode, and a diode is connected in parallel to the switching element.

  The DC-DC converter provided with the auxiliary circuit of the above-described DC-DC converter can be a step-up, step-down, step-up / step-down DC-DC converter capable of ZCS operation over a wide range.

  A bidirectional buck-boost DC-DC converter according to a first aspect of the present invention is a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs the same, and includes a twin half-bridge structure (1a) and both half-bridges. Auxiliary circuits (1b) are provided on the low side of the structure.

(1a) Twin half bridge structure The twin half bridge structure includes a first switching element and a second switching element connected in series, and anti-parallel diodes connected in parallel to the first switching element and the second switching element, respectively. The third switching element and the fourth switching element connected in series, the anti-parallel diode connected in parallel to the third switching element and the fourth switching element, respectively, and the first connection of the first switching element and the second switching element And a smoothing inductor connecting the third switching element and the second connection midpoint of the fourth switching element.

(1b) Auxiliary circuit The auxiliary circuit includes a ZCS promoting inductor connected in series between the low-side second switching element and the first connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. And a ZCS promoting inductor connected in series between the low-side fourth switching element and the second connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. The

  A bidirectional buck-boost DC-DC converter according to a second aspect of the present invention is a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs the same, and includes a twin half-bridge structure (2a) and both half-bridges. An auxiliary circuit (2b) is provided on each of the high side of the structure.

(2a) Twin half bridge structure The twin half bridge structure includes a first switching element and a second switching element connected in series, and anti-parallel diodes connected in parallel to the first switching element and the second switching element, respectively. The third switching element and the fourth switching element connected in series, the anti-parallel diode connected in parallel to the third switching element and the fourth switching element, respectively, and the first connection of the first switching element and the second switching element And a smoothing inductor connecting the third switching element and the second connection midpoint of the fourth switching element.

(2b) Auxiliary circuit The auxiliary circuit includes a ZCS promoting inductor connected in series to the first switching element on the high side, a series resonant switched capacitor connected in parallel to both ends of the series connection structure, The inductor includes a ZCS promoting inductor connected in series to the third switching element, and a series resonant switched capacitor connected in parallel to both ends of the series connection structure.

  A bidirectional buck-boost DC-DC converter according to a third aspect of the present invention is a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs it, and has a twin bridge structure (3a) and both bridge structures. An auxiliary circuit (3b) is provided on each low side.

(3a) Twin half bridge structure The twin half bridge structure includes a first switching element and a second switching element connected in series, and anti-parallel diodes connected in parallel to the first switching element and the second switching element, respectively. The third switching element and the fourth switching element connected in series, the anti-parallel diode connected in parallel to the third switching element and the fourth switching element, respectively, and the first connection of the first switching element and the second switching element A first smoothing inductor that is branched and connected from a point; a second smoothing inductor that is branched and connected from a second connection middle point of the third switching element and the fourth switching element; and a first switching element that is connected in series And both ends of the second switching element, a third switching element connected in series, Both ends of the fourth switching element are connected to each other, and a DC link capacitor is connected to both ends in parallel.

(3b) Auxiliary circuit The auxiliary circuit includes a ZCS promoting inductor connected in series between the second switching element on the low side and the first connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. And a ZCS promoting inductor connected in series between the low-side fourth switching element and the second connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. The

  A bidirectional buck-boost DC-DC converter according to a fourth aspect of the present invention is a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs it, and has a twin bridge structure (4a) and both bridge structures. An auxiliary circuit (4b) is provided on each high side.

(4a) Twin half bridge structure The twin half bridge structure includes a first switching element and a second switching element connected in series, and anti-parallel diodes connected in parallel to the first switching element and the second switching element, respectively. The third switching element and the fourth switching element connected in series, the anti-parallel diode connected in parallel to the third switching element and the fourth switching element, respectively, and the first connection of the first switching element and the second switching element A first smoothing inductor that is branched and connected from a point; a second smoothing inductor that is branched and connected from a second connection middle point of the third switching element and the fourth switching element; and a first switching element that is connected in series And both ends of the second switching element, a third switching element connected in series, Both ends of the fourth switching element are connected to each other, and a DC link capacitor is connected to both ends in parallel.

(4b) Auxiliary circuit The auxiliary circuit includes a ZCS promoting inductor connected in series between the first switching element on the high side and the first connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. And, similarly, a ZCS promoting inductor connected in series between the third switching element on the high side and the second connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure Composed.

  In the bidirectional buck-boost DC-DC converter according to the first to fourth aspects described above, the series resonant switched capacitor includes a resonant inductor, a resonant capacitor, and a switching element connected in series from the positive electrode, and the switching element A diode is preferably connected in parallel.

According to the auxiliary circuit of the DC-DC converter of the present invention, a comparatively simple circuit is added to a wide range of switching elements with respect to the existing step-up type, step-down type or step-up / step-down type DC-DC converter. This has the effect of enabling ZCS operation.
Further, according to the bidirectional buck-boost DC-DC converter of the present invention, it is possible to realize a multi-function high-efficiency bidirectional DC-DC converter capable of performing step-up / step-down or step-up / step-down operation in both power flows between two DC power sources. There is an effect.

Circuit block diagram with auxiliary circuit added to step-up DC-DC converter Circuit block diagram with auxiliary circuit added to step-down DC-DC converter Circuit block diagram with auxiliary circuit added to step-up / step-down DC-DC converter 1 is a circuit block diagram of a bidirectional buck-boost DC-DC converter (L link type) according to the present invention. 2 is a circuit block diagram of a bidirectional buck-boost DC-DC converter (L link type) according to the present invention. 1 is a circuit block diagram of a bidirectional buck-boost DC-DC converter (C-link type) according to the present invention. 2 is a circuit block diagram of a bidirectional buck-boost DC-DC converter (C-link type) according to the present invention. 1 is a circuit configuration diagram of a step-up / step-down DC-DC converter according to a first embodiment. Theoretical operation waveform diagram of the step-up operation of the DC-DC converter of Example 1 Mode transition diagram of step-up operation of DC-DC converter of embodiment 1 Theoretical operation waveform diagram of step-down operation of the DC-DC converter of Embodiment 1 Mode transition diagram of step-down operation of DC-DC converter of Embodiment 1 Switching operation waveform diagram of DC-DC converter of Embodiment 1 FIG. Switching operation waveform diagram of DC-DC converter of Embodiment 1 FIG. Output voltage characteristic diagram of DC-DC converter of Example 1 Output power characteristic diagram of DC-DC converter of Example 1 Circuit configuration diagram of bidirectional buck-boost DC-DC converter (L link type) of embodiment 2 Theoretical operation waveform diagram of one-cycle steady operation of the DC-DC converter of Example 2 Mode transition diagram of one-cycle steady-state operation of the DC-DC converter of Embodiment 2 Switching operation waveform diagram of DC-DC converter of Example 2 FIG. Switching operation waveform diagram of DC-DC converter of Example 2 FIG. Input / output voltage conversion characteristic diagram of the DC-DC converter of Example 2 Output power characteristic diagram of DC-DC converter of Example 2 Block diagram of in-vehicle power supply system with drive system and battery 1 is a circuit configuration diagram of a conventional DC-DC converter. FIG. 2 is a circuit configuration diagram of a conventional DC-DC converter.

  Hereinafter, an example of an embodiment of the present invention will be described in detail with reference to the drawings. The scope of the present invention is not limited to the following examples and illustrated examples, and many changes and modifications can be made.

FIG. 1 shows a circuit block diagram in which an auxiliary circuit is added to a step-up DC-DC converter.
As shown in FIG. 1, the auxiliary circuit 1 added to the step-up DC-DC converter includes a series resonance type switched capacitor 2 and a ZCS promoting inductor 3, and is used to promote ZCS in series with the positive side of the step-up switching element. An inductor 3 is connected in series, and a series resonance type switched capacitor 2 is connected in parallel to both ends of a series connection structure including a boosting switching element and a ZCS promoting inductor 3.

FIG. 2 shows a circuit block diagram in which an auxiliary circuit is added to the step-down DC-DC converter.
As shown in FIG. 2, the auxiliary circuit 1 added to the step-down type DC-DC converter consists of a series resonant switched capacitor 2 and ZCS promotion inductor 3 which, ZCS promotion inductor 3 in series to the positive side of the wheel diode There are connected in series, and the series resonant switched capacitor 2 is connected in parallel across the series connection structure comprising a freewheeling diode and ZCS promotion inductor 3.

FIG. 3 shows a circuit block diagram in which an auxiliary circuit is added to the step-up / step-down DC-DC converter.
As shown in FIG. 3, the auxiliary circuit 1 added to the step-up / step-down DC-DC converter includes a series resonance type switched capacitor 2 and a ZCS promoting inductor 3, and is connected to the step-up switching element and anti-parallel. A ZCS promoting inductor 3 is connected in series to the positive electrode side of the switch composed of a diode, and a series resonant switched capacitor 2 is connected in parallel to both ends of the series connection structure comprising the boosting switching element and the ZCS promoting inductor 3. Connected.
As an embodiment of the series resonant switched capacitor shown in FIGS. 1 to 3, a resonant inductor, a resonant capacitor, and a switching element are connected in series from the positive electrode, and a diode is connected in parallel to the switching element. Structure.

FIG. 4 shows an embodiment of a structure in which a half-bridge structure using two semiconductor switches is connected via an inductor (herein referred to as an L-link twin half-bridge structure) in a bidirectional buck-boost DC-DC converter. The circuit block diagram of is shown.
In the bidirectional buck-boost DC-DC converter shown in FIG. 4, the connection midpoint between the main switch 1 and the main switch 2 connected in series and the connection midpoint between the main switch 3 and the main switch 4 connected in series are smooth. It is an L link type twin half bridge structure connected via an inductor.
In the case of the L-link type, it has a symmetrical structure via a smoothing inductor, and each half bridge (leg) can be boosted or lowered independently by using it as a current source, and power can be transmitted in both directions. .
The main switches 1 to 4 include a semiconductor switch and an antiparallel diode connected in parallel thereto.
The auxiliary circuit 1 in the bidirectional buck-boost DC-DC converter includes a series resonance type switched capacitor 2 and a ZCS promoting inductor 3 and is provided on the low side of each half bridge structure. One auxiliary circuit 1 provided on the low side of the half-bridge structure has a ZCS promoting inductor 3 connected in series between the main switch 2 and the midpoint of connection, and a series composed of the main switch 2 and the ZCS promoting inductor 3. A series resonant switched capacitor 2 is connected in parallel to both ends of the connection structure. In the other auxiliary circuit 1 provided on the low side of the half-bridge structure, the ZCS promoting inductor 3 is connected in series between the main switch 4 and the connection midpoint, and the series consisting of the main switch 4 and the ZCS promoting inductor 3 is connected. A series resonant switched capacitor 2 is connected in parallel to both ends of the connection structure.

FIG. 5 is a circuit block of another embodiment of a structure in which a half bridge structure by two semiconductor switches is connected via an inductor (L link type twin half bridge structure) in a bidirectional buck-boost DC-DC converter. The figure is shown.
The bidirectional buck-boost DC-DC converter shown in FIG. 5 is similar to FIG. 4 in that the connection point between the main switch 1 and the main switch 2 connected in series, and the connection between the main switch 3 and the main switch 4 connected in series. The middle point is an L link type twin half bridge structure connected via a smoothing inductor.
The main switches 1 to 4 include a semiconductor switch and an antiparallel diode connected in parallel thereto.
The auxiliary circuit 1 in the bidirectional buck-boost DC-DC converter includes a series resonance type switched capacitor 2 and an inductor 3 for promoting ZCS, and is provided on the high side of each half-bridge structure, unlike FIG. One auxiliary circuit 1 provided on the low side of the half-bridge structure has a ZCS promoting inductor 3 connected in series on the positive side of the main switch 1, and both ends of the series connection structure comprising the main switch 1 and the ZCS promoting inductor 3. A series resonance type switched capacitor 2 is connected in parallel with each other. The other auxiliary circuit 1 provided on the low side of the half-bridge structure has a ZCS promoting inductor 3 connected in series on the positive side of the main switch 3, and both ends of the series connection structure comprising the main switch 3 and the ZCS promoting inductor 3. A series resonance type switched capacitor 2 is connected in parallel with each other.
When an auxiliary circuit is provided on the high side of the half-bridge structure, it is preferable for practical use that the ZCS promoting inductors 3 of the half-bridge structure are disposed on the main switch 1 and the main switch 3, respectively. The reason for this is that with the above arrangement, in each half-bridge structure, a module in which main switches 1 and 2 are integrated or a module in which main switches 3 and 4 are integrated can be used. This is because there are advantages such as simplification.

FIG. 6 shows a structure in which a half-bridge structure using two semiconductor switches is connected via a DC link capacitor (herein referred to as a C-link type twin half-bridge structure) in a bidirectional buck-boost DC-DC converter. The circuit block diagram of embodiment is shown.
The bidirectional buck-boost DC-DC converter shown in FIG. 6 has a connection midpoint between the main switch 1 and the main switch 2 connected in series and a connection midpoint between the main switch 3 and the main switch 4 connected in series. Connected to the DC power source (V ₁ , V ₂ ) via the smoothing inductor, the main switch 1 and the main switch 2 connected in series, and the main switch 3 and the main switch 4 connected in series are connected. A C link type twin half bridge structure in which a DC link capacitor is connected in parallel at both ends.
In the case of the C link type, a symmetric structure is provided via a DC link capacitor, and each half bridge (leg) can be boosted or lowered independently by using it as a voltage source, and power can be transmitted in both directions. Become. It can be combined with another power source via a converter (DC-DC converter, DC-AC inverter) suitable for the DC link capacitor. That is, it can be applied to a three-port composite power supply system together with the DC power sources (V ₁ and V ₂ ). Furthermore, since power can be transmitted bi-directionally between the ports independently, that is, without mutual interference, it is possible to realize a multi-function power supply system.
The main switches 1 to 4 include a semiconductor switch and an antiparallel diode connected in parallel thereto.
The auxiliary circuit 1 in the bidirectional buck-boost DC-DC converter includes a series resonance type switched capacitor 2 and a ZCS promoting inductor 3 and is provided on the low side of each half bridge structure. One auxiliary circuit 1 provided on the low side of the half-bridge structure has a ZCS promoting inductor 3 connected in series between the main switch 2 and the midpoint of connection, and a series composed of the main switch 2 and the ZCS promoting inductor 3. A series resonant switched capacitor 2 is connected in parallel to both ends of the connection structure. In the other auxiliary circuit 1 provided on the low side of the half-bridge structure, the ZCS promoting inductor 3 is connected in series between the main switch 4 and the connection midpoint, and the series consisting of the main switch 4 and the ZCS promoting inductor 3 is connected. A series resonant switched capacitor 2 is connected in parallel to both ends of the connection structure.

FIG. 7 shows another embodiment of a structure in which a half bridge structure by two semiconductor switches is connected via a DC link capacitor (C link type twin half bridge structure) in a bidirectional buck-boost DC-DC converter. A circuit block diagram is shown.
The bidirectional buck-boost DC-DC converter shown in FIG. 7 has a connection midpoint between the main switch 1 and the main switch 2 connected in series, and a connection midpoint between the main switch 3 and the main switch 4 connected in series, respectively. Connected to the DC power source (V ₁ , V ₂ ) via the smoothing inductor, the main switch 1 and the main switch 2 connected in series, and the main switch 3 and the main switch 4 connected in series are connected. A C link type twin half bridge structure in which a DC link capacitor is connected in parallel at both ends.
The main switches 1 to 4 include a semiconductor switch and an antiparallel diode connected in parallel thereto.
The auxiliary circuit 1 in the bidirectional buck-boost DC-DC converter includes a series resonance type switched capacitor 2 and a ZCS promoting inductor 3 and is provided on the high side of each half-bridge structure. One auxiliary circuit 1 provided on the low side of the half-bridge structure includes a main switch 1 and a ZCS promoting inductor 3 connected in series, and in parallel with both ends of a series connection structure including the main switch 1 and the ZCS promoting inductor 3. A series resonance type switched capacitor 2 is connected. In the other auxiliary circuit 1 provided on the low side of the half-bridge structure, the ZCS promoting inductor 3 is connected in series to the main switch 3, and in parallel with both ends of the series connection structure including the main switch 3 and the ZCS promoting inductor 3. A series resonance type switched capacitor 2 is connected.

An embodiment of the step-up / step-down DC-DC converter of the present invention will be described.
The circuit configuration of the step-up / step-down DC-DC converter is shown in FIG.
In the circuit shown in FIG. 8, the step-up operation of the power flow from the DC voltage source V ₁ to the direct voltage source V _2, it defines the reverse step-down operation. Q ₁ serving as a main switch in the boost _operation, with respect to Q ₂ to which the main switch is in the step-down operation, provided Q ₃ serving as an auxiliary switch in both operations both. In addition, the L _s is inserted into _{Q 1,} series as ZCS promotion inductor to slow the turn-on current of _{Q 1} and _{Q 2,} further zero current and zero voltage soft switching of _{Q 1} and _{Q 2} (Zero Current and Zero Voltage Soft-Switching, to obtain a ZCS turn-on and ZCZVS off of ZCZVS) off and _{Q 3,} has a structure in which the _{Q 3} in series with the resonant capacitor _{C r} and the resonant inductor _{L r} in series.
Then, using the anti-parallel diode D ₂ is turned off at all times the switch unit Q ₂ is in the step-up operation as a circulating diode, while refluxing the antiparallel diode D ₁ and the switch unit is turned off at all times Q ₁ is in the step-down operation Let it be a diode.

The fixed frequency PWM control is used as the power and voltage control method of the bidirectional DC-DC converter of the first embodiment, and the ON periods T _on1 and T _on2 of the main switches Q ₁ and Q ₂ with respect to one period T of the high frequency switching are adjusted, This is realized by controlling the duty ratio d (= T _on1 / T) and d ′ (= T _{on 2} / T), respectively.
Also, the ON period of the auxiliary switch Q _3, can be set as a fixed value from the maximum current of the resonant frequency and the smoothing inductor L _d of the series resonant switched capacitor.

  The theoretical operation waveforms and mode transition diagrams of the step-up / step-down DC-DC converter are shown in FIGS. 9 to 12 for each power flow. In the step-up operation flow, as shown in FIGS. 9 and 10, one high-frequency period is composed of seven sub modes (Mode 1 to Mode 7) to be described later. On the other hand, in the step-down operation flow, as shown in FIG. 11 and FIG. 12, nine sub-modes (Mode 1 to Mode 9) to be described later are configured for one period of the high frequency.

(Boost operation flow)
[Mode 1: Q ₁ ZCS turn-on mode] (t ₀ ≦ t <t ₁ )
When turning on the main switch _{Q 1,} the current _{I Ld} flowing to _{L d} starts commutate from _{D 2} to _{S 1.} At this time, due to the action of L _s , the current i _{Q1 of} Q ₁ gradually rises from the zero current state, and the ZCS turn-on operation of Q ₁ becomes possible. At the same time, the current D ₂ decreases gradually and ZCS turned off when lowered to zero naturally. This section will continue until the completion of the commutation to the S _1.

[Mode 2: L _d energy storage mode] (t ₁ ≦ t <t ₂ )
When commutation to S ₁ is completed at time t ₁ , the current I _Ld flows through the path V ₁ -L _d -L _s -S ₁ and enters a steady state in which magnetic energy is accumulated in L _d . This period continues until you turn on the auxiliary switch Q _3.

[Mode ₃ : Q ₃ ZCS turn-on mode] (t ₂ ≦ t <t ₃ )
At time _{t 2, the} obtaining partial resonance of _{L r} and _{C r} When turning on the _{Q 3.} Thus the current _{i Q3} of _{Q 3} are gradually increased from the state of zero current, to achieve ZCS turn-on operation of the _{Q 3.}

[Mode 4: Partial resonance mode] (t ₃ ≦ t <t ₄ )
When the current i _Q1 flowing through Q ₁ becomes equal to or less than I _Ld at time t ₃ , the current i _Q3 flowing through Q ₃ is commutated from S ₃ to D ₃ and continues the partial resonance.

[Mode 5: Q ₁ , Q ₃ ZCZVS turn-off mode] (t ₄ ≦ t <t ₅ )
When current i _Q1 flowing through Q ₁ commutates from S ₁ to D ₁ at time t ₄ due to resonance that continues from Mode ₄ , both Q ₁ and Q ₃ current flow through antiparallel diodes. If the gate signals of S ₁ and S ₃ are removed during this period, their ZCZVS turn-off operation is realized.

[Mode 6: power supply mode] (t ₅ ≦ t <t ₆ )
At time t ₅ , i _Q1 naturally approaches zero, and at the same time D ₂ becomes forward biased and conducts, and commutation from D ₃ to D ₂ starts. In this case _{D 2} realizes a ZCS turn-on operation.

[Mode 7: L _d energy release mode] (t ₆ ≦ t <t ₇ )
At time _{t 6,} the commutation of the _{D 2} is completed from _{D 3, I Ld} becomes steady state over a route _{V 1 -L d -D 2 -V 2} . At time _{t 7,} returns to Mode1.

(Step-down operation flow)
[Mode 1: Q ₂ ZCS turn-on mode] (t ₀ ≦ t <t ₁ )
At time _{t 0,} when turning on the main switch _{Q 2,} to obtain _{L S,} L r, a partial resonance of _{C r.} Thus the current _{i Q3} of _{Q 3} are gradually increased from zero, to achieve ZCS turn-on of _{Q 3.} At the same time, the current flowing through the D ₁ starts ZCS turn-off gradually reduced reaches zero naturally.

[Mode 2: Partial resonance mode] (t ₁ ≦ t <t ₂ )
After commutation from D ₁ to S ₃ is completed at time t ₁ , partial resonance by L _r and C _r from the previous mode continues. This period continues until the resonant capacitor C _r is charged and its terminal voltage rises to equal V ₂ and the current i _{Q3 in} Q ₃ is zero.

[Mode3: _{L d} energy storage _{mode] (t 2 ≦ t <t} 3)
At time _{t 2, the} a steady state of the power supply through which _{I Ld i Q3} is to _{V 1} is the load from _{V 2} is the power supply becomes zero.

[Mode 4: Q ₃ ZCS turn-on mode] (t ₃ ≦ t <t ₄ )
At time _{t 3,} obtained when turning on the auxiliary switch _{Q 3,} again _L r, a partial resonance of _{C r.} Thus the current _{i Q3} of _{Q 3} are gently rises from zero, to achieve ZCS turn-on of _{Q 3.}

[Mode 5: Q ₂ ZCZVS turn-off mode] (t ₄ ≦ t <t ₅ )
At time _{t 4,} when _{i Q2} becomes zero, the commutation to the _{D 2} of the anti-parallel diode from _{S 2.} Removing the gate signal _{S 2} during this time, to realize ZCZVS turn off of _{Q 2.}

[Mode 6: _{C r} energy release _{mode] (t 5 ≦ t <t} 6)
At time _{t 5,} at the _{i Q2} becomes zero naturally, the current _{I Ld} of _{L d} becomes reflux mode through _{S 3,} the stored energy of the _{C r} starts discharging.

[Mode 7: L _s −L _r —C _r partial resonance mode] (t ₆ ≦ t <t ₇ )
At time _{t 6, v Cr} antiparallel diode _{D 1} of the same time _{Q 1} drops to zero is forward biased, obtaining L _{s, L} r, a partial resonance of _{C r.} At this time, since _{the D 1} of the current _{i D1} is gradually increased, _{D 1} achieves ZCS turn. Further, in this section, i _Q3 gradually starts to decrease due to the resonance current generated in the cell.

[Mode 8: Q ₃ ZCZVS turn-off mode] (t ₇ ≦ t <t ₈ )
At time _{t 7, i Q3} is zero cross to start the commutation from _{S 3} to the anti-parallel diode _{D 3.} Realizing ZCZVS turn off of _{Q 3} upon removal of the gate signal _{S 3} during this time.

[Mode 9: L _d energy release mode] (t ₈ ≦ t <t ₉ )
At time t _8, the resonance-like i _Q3 becomes zero again, S ₃ is already turned off, Q ₃ is not re-conduct, both the energy stored in L _d, the load current, i.e. I _{Ld is} a steady state circulating path of _{L d -V 1 -D 1 -L s} .

  The characteristics of the step-up / step-down DC-DC converter are evaluated by simulation analysis. The circuit parameters and operating conditions are shown in Table 1 below.

  The switching operation waveforms of the active switches at the output of 3 kW for both step-up operation and step-down operation are shown in FIGS. 13 and 14, respectively. From this, it can be understood that the ZCS turn-on and ZCZVS turn-off of the main switch and the auxiliary switch are achieved in the heavy load in the same manner as the above-described operation principle. At light loads, the difference between the peak value of the resonant current and the steady current becomes more significant than at heavy loads, and the effect of conduction loss of the series resonant switched capacitor becomes a problem. On the other hand, ZCZVS turn-off of each switch is gradually realized Become.

  Next, FIG. 15 and FIG. 16 show output voltage characteristics and output power characteristics under the open loop control with respect to the main switch-on ratios d and d ′ for each power flow. From these results, it can be confirmed that both the step-up operation and the step-down operation can adjust the output voltage over a wide range by adjusting d and d ', and can control the output power over a wide range.

An embodiment of the bidirectional buck-boost DC-DC converter of the present invention will be described.
FIG. 17 shows a circuit configuration of a bidirectional buck-boost DC-DC converter (L link type).
The main switch _(Q 1 / Q ₂₎ and the auxiliary switch _{Q 3} to realize their ZCS commutation, further ZCS promotion inductor L _S1, a half-bridge HB1 comprising auxiliary switching cell comprising resonant inductor _{L r1} and a resonant capacitor _{C r1} A herb bridge including a main switch (Q ₄ / Q ₅ ) and an auxiliary switch Q ₆ for realizing ZCS commutation thereof, and an auxiliary switching cell further comprising a ZCS promoting inductor L _s2 , a resonant inductor L _r2 and a resonant capacitor C _r2 and HB2 are formed by being connected via a smoothing inductor L _d.

Thus, the step-up / step-down operation by the independent operation of HB1 and HB2 and the step-up / step-down operation by the combined operation of HB1 and HB2 are possible. As an example, a step-up / step-down operation from the DC voltage source V ₁ to the DC voltage source V ₂ will be described. Q ₁ is a high-side main switch, Q ₅ is a low-side main switch, and Q ₂ and Q ₄ switches parallel diode section as normally off state and _{(D 2,} D ₄₎ to use as a wheel diode. Then, by operating the auxiliary switches (Q ₃ , Q ₆ ) as auxiliary switches of the main switches (Q ₁ , Q ₅ ), Q ₁ / Q ₅ is originally ZCS of Q ₃ / Q ₆ , Obtains ZCS commutation of anti-parallel diodes (D ₂ , D ₄ ). As a result, a bidirectional DC-DC converter that reduces switching loss and effectively suppresses reverse recovery current of the freewheeling diode can be realized with an extremely simple circuit structure.

As an example, a step-up / step-down operation from the DC voltage source V ₂ to the DC voltage source V ₁ will be described. Q ₄ is a high-side main switch, Q ₂ is a low-side main switch, and Q ₁ and Q ₅ The anti-parallel diodes (D ₁ , D ₅ ) are used as free- wheeling diodes. Then, by operating the auxiliary switches (Q ₃ , Q ₆ ) as auxiliary switches of the main switches (Q ₂ , Q ₄ ), Q ₂ / Q ₄ is originally ZCS of Q ₃ / Q ₆ , Obtains ZCS commutation of anti-parallel diodes (D ₁ , D ₅ ).

For the bidirectional buck-boost DC-DC converter, main switches (Q ₁ , Q ₂ , Q ₄ , Q ₅ ) and auxiliary switches (Q ₃ , Q ₆ ) at the time of power conversion from the DC voltage source V ₁ to V ₂ The state is shown in Table 2.
Table 3 shows the states of the main switches (Q ₁ , Q ₂ , Q ₄ , Q ₅ ) and the auxiliary switches (Q ₃ , Q ₆ ) during power conversion from the DC voltage source V ₂ to V ₁ .
Tables 2 and 3 summarize the three types of power conversion, step-up, step-down, and step-up / step-down, respectively.
In the table, ON means “always switched on”, OFF means “always switched off”, and SW means “switching (ON / OFF)”.

Bidirectional buck-boost DC-DC converter of the power control and the method of voltage control fixed frequency PWM control adjusts the on-period _{T ON} of the main switch for the high-frequency switching one period _{T (Q 1, Q 5)} , the duty ratio This is done by adjusting d (= T _ON / T). Note that the ON period of the auxiliary switch, can be designed from the maximum current of the resonant frequency and the smoothing inductor L _d by internal resonant inductor and resonant capacitor of the series resonant switched capacitor cell can be set as fixed for all load range .

FIG. 18 and FIG. 19 show theoretical operation waveforms and mode transition diagrams in the one-cycle steady operation of the bidirectional buck-boost DC-DC converter, respectively. The step-up / down operation is composed of 16 sub-modes (Mode 1 to Mode 16) which will be described later. Will be described below power conversion flows from the DC voltage source V ₁ to V _2. Incidentally, description of the power conversion flows to V ₁ from the DC voltage source V ₂ is omitted.

[Mode 1: Q ₁ , Q ₅ ZCS turn-on mode] (t ₀ ≦ t <t ₁ )
When Q ₁ and Q ₅ are simultaneously turned on at time t ₀ , partial resonances of L _S1 , L _r1 and C _r1 are obtained in HB1. Than this for _{Q 1} current _{i Q1} achieves moderately elevated ZCS turn for _{Q 1} from zero. At the same time, the current flowing through the D ₂ decreases gradually.
On the other hand, the commutation to _{S 5} from _{D 4} In _HB2, current _{i Q5} of _{Q 5} by the action of _{L r2} becomes ZCS turn-on operation of _{Q 5} rises gently from the state of zero current. At the same time, the current of the D ₄ decreases gradually and ZCS turned off when lowered to zero naturally. This section continues until the commutation completion of the S _5.

[Mode 2: Q ₂ ZCS turn-off mode] (t ₁ ≦ t <t ₂ )
After commutation from D ₄ to S ₅ is completed at time t ₁ , in HB 1, the D ₂ conduction current naturally reaches zero due to the partial resonance that continues from the previous mode, and the ZCS turn-off occurs. During this time, the power supply current flows through the path of V ₁ -S ₁ -L _S2 -S ₅ and enters a steady state in which magnetic energy is accumulated in L _d .

[Mode 3: Partial resonance mode] (t ₂ ≦ t <t ₃ )
After the commutation from D ₂ to S ₁ is completed at time t ₂ , the partial resonance due to L _r1 and C _r1 from the previous mode is maintained. Accordingly, the resonance capacitor C _r1 continues to be charged, and when the terminal voltage thereof gradually increases and becomes equal to V ₂ , the current i _{Q3 of} Q ₃ becomes zero.

[Mode4: _{L d} energy storage _{mode] (t 3 ≦ t <t} 4)
At time _{t 3,} when _{i Q2} becomes zero, the supply _current, the steady state of the power supply flows as _{V 1 -S 1 -L d -L S2} -S 5.

[Mode 5: Q ₆ ZCS turn-on mode] (t ₄ ≦ t <t ₅ )
At time _{t 4,} when turning on the auxiliary switch _{Q 6} of HB2, obtaining a partial resonance of _{L S2, L r2, C r2} . Thus the current _{i Q6} of _{Q 6} is gently increased from zero to achieve ZCS turn-on of _{Q 6.}

[Mode 6: S ₆ -D ₆ commutation mode] (t ₅ ≦ t <t ₆ )
At time _{t 5, i Q6} is commutated with partial resonance is continued from the switch unit _{S 6} to the anti-parallel diode _{D 6.}

_[Mode7: S ₅ -D 5 commutation _{mode] (t 6 ≦ t <t} 7)
At time _{t 6,} followed by _{i Q6,} while the commutation from the current _{i Q5} likewise _{S 5} of _{Q 5} to _{D 5} is completed, to continue the partial resonance.

[Mode 8: Q ₃ ZCS turn-on mode] (t ₇ ≦ t <t ₈ )
At time _{t 7,} when turning on the auxiliary switch _{Q 3} of _HB1, obtaining a partial resonance of L _{r1, C} r1. Current _{i Q3} of Q ₃ are increased gradually from zero to achieve ZCS turn-on of _{Q 3.} At the same time, the current flowing through the S ₁ gradually decreases.

[Mode 9: Q ₁ , Q ₅ ZCZVS turn-off mode] (t ₈ ≦ t <t ₉ )
At time _{t 8,} the current _{i Q2} of _{Q 2} is the zero-crossing, to start the commutation from _{S 2} to _{D 2.} Thus, a conducting current is zero _S 1, _{S 5} together with commutation to _{D 5} continuing from Mode7, the ZCZVS turn off of _S 1, _S gate signal ₅ at the same time removing the _Q 1, _{Q 5} during which Realize.

[Mode 10: Q ₆ ZCZVS turn-off mode] (t ₉ ≦ t <t ₁₀ )
At time _{t 9,} when the resonance-like _{i Q1} becomes zero again, _{S 1} is already turned off _{Q 1} is not re-conduct, _{i Q3} by the smoothing action of _{L d} is a constant current. Furthermore, partial resonance of _{L S2,} L _{r2, C} r2 continues, upon removal of the gate signal _{S 6} during this period, to achieve ZCZVS turn off of _{Q 6.}

[Mode 11: L _d energy release mode] (t ₁₀ ≦ t <t ₁₁ )
At time _{t 10,} no re-conduction _{S 5} when _{i Q5} is slowly _zero, and steady state recirculation path of _{L d -L r2 -C r2 -D 5} -S 3 -C r1 -L r1 Become.

[Mode 12: D ₄ ZCS turn-on mode] (t ₁₁ ≦ t <t ₁₂ )
At time _{t 11,} and at the same time _{v D4} drops to zero, the inverse parallel diode _{D 4} of _{Q 4} is forward biased _to obtain a partial resonance of L _{r2, C r2.} At this time, since the current _{i D4} of _{D 4} is gradually increased, _{D 4} achieves ZCS turn. Also, _iQ6 gradually goes to zero.

[Mode 13: L _d energy release mode] (t ₁₂ ≦ t <t ₁₃ )
At time _{t 12,} the _{i Q6} reaches zero, the gate signal _{S 6} has already been removed, _{Q 6} does not conduct. Than this, current is steady state recirculation path of _{L d -D 4 -V 2 -S 3} -C r1 -L r1.

[Mode 14: D ₂ ZCS turn-on mode] (t ₁₃ ≦ t <t ₁₄ )
At time _{t 13,} and at the same time _{v Cr1} drops to zero, the inverse parallel diode _{D 2 Q 2} 'is forward biased, obtaining a partial resonance of _{L S1, L r1, C r1} . At this time, the current _{i D2} of the _{D 2} in order to increase the resonance shape, _{D 2} achieves ZCS turn. At the same time, i _Q3 resonates toward zero.

[Mode 15: Q ₃ ZCZVS turn-off mode] (t ₁₄ ≦ t <t ₁₅ )
At time _{t 14,} the _{i Q3} crosses zero naturally commutated from _{S 3} to the anti-parallel diode _{D 3,} continues to partial resonance from the previous mode. Realizing ZCZVS turn-off of the _{Q 3} by removing the gate signal _{S 3} during this period.

[Mode 16: L _d energy release mode] (t ₁₅ ≦ t <t ₁₆ )
At time _{t 15,} the _{i Q3} reaches zero, because it turns off the gate signal _{S 3} at Mode15, re conduction _{Q 6} are not, the current of the smoothing _inductor, L d _-D 4 -V ₂ It becomes a steady state that circulates through the route of −D ₂ −L _S1 , and returns to Mode 1 again at time t ₁₆ .

The characteristics of the bidirectional buck-boost DC-DC converter were evaluated by simulation analysis. As a premise, the power flow from V ₁ to V ₂ was set. The circuit parameters and operating conditions are shown in Table 4 below.

  First, the switching operation waveforms of the main switch and the auxiliary switch at the time of heavy load and the switching operation waveform at the time of light load are shown in FIGS. 20 and 21, respectively. From the switching operation waveform, it can be seen that the ZCS turn-on and ZCZVS turn-off of the main switch and the auxiliary switch can be achieved at the rated output (at the time of heavy load) similarly to the above-described operation principle. Also, at light load, the difference between the peak value of resonance current and steady current becomes more significant than at heavy load, and the effect of conduction loss inside the series resonance type switch and capacitor becomes a problem, while the ZCZVS turn-off of each switch is It becomes easier to realize.

  Next, FIG. 22 shows a graph showing the input / output voltage conversion characteristics under the open loop condition with respect to the main switch-on time ratio d for each power flow, and FIG. 23 shows a graph showing the output power characteristics. From this result, it is understood that the output voltage adjustment under the step-up / step-down condition is realized continuously by adjusting d, and the load power control is possible.

  The present invention is useful for a bidirectional DC-DC converter mounted on a power supply system of an electric vehicle or a hybrid vehicle.

1 Auxiliary Circuit 2 Series Resonant Switched Capacitor 2a Resonant Inductor 2b Resonant Capacitor 2c Switching Element 2d Diode 3 ZCS Promoting Inductor

Claims (10)

An auxiliary circuit of a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs the converted DC voltage,
In the DC-DC converter, a smoothing inductor and a forward freewheeling diode are sequentially connected in series on the positive electrode side of an input DC voltage, and a boosting switching element is connected between the midpoint of the series connection and the cathode side. For type
The auxiliary circuit is
It consists of a series resonant switched capacitor and an inductor for ZCS promotion,
The ZCS promoting inductor is connected in series to the positive side of the step-up switching element, and the series resonant switched capacitor is connected in parallel to both ends of the series connection structure.
An auxiliary circuit of a DC-DC converter characterized by the above. An auxiliary circuit of a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs the converted DC voltage,
In the DC-DC converter, a step-down switching element and a smoothing inductor are sequentially connected in series on the positive side of an input DC voltage, and a reverse free-wheeling diode is connected between the midpoint and the cathode side of the series connection. For type
The auxiliary circuit is
It consists of a series resonant switched capacitor and an inductor for ZCS promotion,
The ZCS promoting inductor is connected in series to the positive electrode side of the freewheeling diode, and the series resonant switched capacitor is connected in parallel to both ends of the series connection structure.
An auxiliary circuit of a DC-DC converter characterized by the above. An auxiliary circuit of a DC-DC converter that converts an input DC voltage into a desired DC voltage and outputs the converted DC voltage,
In the DC-DC converter, a smoothing inductor and a step-down switching element are sequentially connected in series on the positive side of an input DC voltage, and a step-up switching element is connected between a midpoint of the series connection and a cathode side, In the case of a step-up / step-down type in which an anti-parallel connection diode is connected to the switching element for boosting and the switching element for boosting,
The auxiliary circuit is
It consists of a series resonant switched capacitor and an inductor for ZCS promotion,
The ZCS promoting inductor is connected in series to the positive electrode side of the switch composed of the step-up switching element and the anti-parallel connected diode connected in reverse parallel thereto, and the series resonant type is connected in parallel at both ends of the series connection structure. A switched capacitor is connected,
An auxiliary circuit of a DC-DC converter characterized by the above.   The series resonance type switched capacitor includes a resonance inductor, a resonance capacitor, and a switching element connected in series in order from the positive electrode, and a diode connected in parallel to the switching element. Auxiliary circuit for any DC-DC converter.   The DC-DC converter provided with the auxiliary circuit of the DC-DC converter in any one of Claims 1-4. In a DC-DC converter that converts an input DC voltage to a desired DC voltage and outputs it,
A first switching element and a second switching element connected in series; an anti-parallel diode connected in parallel to each of the first switching element and the second switching element;
Similarly, a third switching element and a fourth switching element connected in series, and antiparallel diodes connected in parallel to the third switching element and the fourth switching element,
A twin half bridge structure comprising a smoothing inductor connecting a first connection midpoint of the first switching element and the second switching element and a third connection element and a second connection midpoint of the fourth switching element;
A ZCS promoting inductor connected in series between the low-side second switching element and the first connection midpoint; a series resonant switched capacitor connected in parallel at both ends of the series connection structure;
Similarly, including a ZCS promoting inductor connected in series between the low-side fourth switching element and the second connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. Bidirectional buck-boost DC-DC converter characterized by the above. In a DC-DC converter that converts an input DC voltage to a desired DC voltage and outputs it,
A first switching element and a second switching element connected in series; an anti-parallel diode connected in parallel to each of the first switching element and the second switching element;
Similarly, a third switching element and a fourth switching element connected in series, and antiparallel diodes connected in parallel to the third switching element and the fourth switching element,
A twin half bridge structure comprising a smoothing inductor connecting a first connection midpoint of the first switching element and the second switching element and a third connection element and a second connection midpoint of the fourth switching element;
A ZCS promoting inductor connected in series to the first switching element on the high side; a series resonant switched capacitor connected in parallel to both ends of the series connection structure;
Similarly, a bidirectional buck-boost DC comprising: a ZCS promoting inductor connected in series to a third switching element on the high side; and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. DC converter. In a DC-DC converter that converts an input DC voltage to a desired DC voltage and outputs it,
A first switching element and a second switching element connected in series; an anti-parallel diode connected in parallel to each of the first switching element and the second switching element;
Similarly, a third switching element and a fourth switching element connected in series, and antiparallel diodes connected in parallel to the third switching element and the fourth switching element,
A first smoothing inductor that is branched and connected from the first connection midpoint of the first switching element and the second switching element, and is branched and connected from a second connection midpoint of the third switching element and the fourth switching element. A second smoothing inductor;
DC link capacitors connected to both ends of the first switching element and the second switching element connected in series, and to both ends of the third switching element and the fourth switching element connected in series, and connected in parallel to the both ends It is a twin half bridge structure consisting of
A ZCS promoting inductor connected in series between the low-side second switching element and the first connection midpoint; a series resonant switched capacitor connected in parallel at both ends of the series connection structure;
Similarly, including a ZCS promoting inductor connected in series between the low-side fourth switching element and the second connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure. Bidirectional buck-boost DC-DC converter characterized by the above. In a DC-DC converter that converts an input DC voltage to a desired DC voltage and outputs it,
A first switching element and a second switching element connected in series; an anti-parallel diode connected in parallel to each of the first switching element and the second switching element;
Similarly, a third switching element and a fourth switching element connected in series, and antiparallel diodes connected in parallel to the third switching element and the fourth switching element,
A first smoothing inductor that is branched and connected from the first connection midpoint of the first switching element and the second switching element, and is branched and connected from a second connection midpoint of the third switching element and the fourth switching element. A second smoothing inductor;
DC link capacitors connected to both ends of the first switching element and the second switching element connected in series, and to both ends of the third switching element and the fourth switching element connected in series, and connected in parallel to the both ends It is a twin half bridge structure consisting of
A ZCS promoting inductor connected in series between the first switching element on the high side and the first connection midpoint; a series resonant switched capacitor connected in parallel at both ends of the series connection structure;
Similarly, a ZCS promoting inductor connected in series between the third switching element on the high side and the second connection midpoint, and a series resonant switched capacitor connected in parallel at both ends of the series connection structure A bidirectional buck-boost DC-DC converter characterized by 10. The series resonant switched capacitor includes a resonant inductor, a resonant capacitor, and a switching element connected in series in order from the positive electrode, and a diode connected in parallel to the switching element. Any bidirectional buck-boost DC-DC converter.