JP2021069165A - Insulation type dc-dc converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a more efficient isolated DCDC converter. An insulated DCDC converter 100 has a first voltage detection unit 40A that detects a voltage value between a first conductive path 1 and a second conductive path 2, and a first current detection that detects a current value of an inductor 13. It is provided with a part 40C. In the insulated DCDC converter 100, the first switch element 20A and the second switch element 20B are connected in series between the first conductive path 1 and the second conductive path 2, to form the first arm A1. The third switch element 20C and the fourth switch element 20D are connected in series between the conductive path 1 and the second conductive path 2 to form the second arm A2. The control unit 40 switches between a first operation in which the first arm A1 is in the advancing phase and the second arm A2 is in the slow phase, and a second operation in which the second arm A2 is in the advancing phase and the first arm A1 is in the slow phase. When the current value is less than a predetermined threshold value, the first arm A1 is operated as a slow phase and the second arm A2 is operated as an advance phase. [Selection diagram] Fig. 1

Description

The present disclosure relates to an isolated DCDC converter.

There is a full bridge circuit as one form of a circuit used in an isolated DCDC converter for high voltage. The full bridge circuit consists of two arms. Of the arms, the arm that turns on and off first is called the phase advance, and the arm that turns on and off later is called the slow phase. In general, the arm on the slow phase side has a larger loss in the elements constituting the arm than the arm on the phase advance side, and an imbalance occurs in the loss between the arms. In Patent Document 1, two types of PWM signals used to drive each of the phase advance arm and the slow phase arm are independently prepared, and each arm is switched at each specific cycle. The loss in the elements constituting each arm is balanced by switching the phase-advancing and slow-phase operations.

European Patent Office No. 1998432

In such a full bridge circuit, a current due to a surge generated on the secondary side may flow to the primary side. Therefore, it is preferable that the isolated DCDC converter incorporates a protection circuit that protects the elements constituting each arm from the current flowing to the primary side due to the surge (hereinafter, also referred to as surge current). For example, as an example of a protection circuit, there is a method of connecting a circuit composed of one inductor and two diodes to a full bridge circuit.

In such a configuration, a configuration in which a protection circuit (clamp circuit) is connected to the leading phase and a configuration in which the protection circuit (clamp circuit) is connected to the slow phase side can be considered. The present inventors have focused on the fact that which is preferable depends on the operating state.

Therefore, the present disclosure provides a more efficient isolated DCDC converter.

The first disclosed isolated DCDC converter is
A transformer with a primary coil and a secondary coil,
A full-bridge type switching circuit including a first switch element, a second switch element, a third switch element, and a fourth switch element, and
A protection circuit having a first diode and a second diode,
A control unit that controls the operation of the switching circuit,
With an inductor
The output circuit connected to the secondary coil and
With
The first switch element and the second switch element are connected in series between the first conductive path and the second conductive path to form a first arm.
The third switch element and the fourth switch element are connected in series between the first conductive path and the second conductive path to form a second arm.
One end of the inductor is electrically connected to a first connection point between the first switch element and the second switch element.
The other end of the inductor is electrically connected to one end of the primary coil, the anode of the first diode, and the cathode of the second diode.
The other end of the primary coil is electrically connected to the second connection point between the third switch element and the fourth switch element.
The cathode of the first diode is electrically connected to the first conductive path,
A phase-shift type isolated DCDC converter in which the anode of the second diode is electrically connected to the second conductive path.
A current detection unit that detects the current value of the current flowing through the output circuit is provided.
The control unit switches between a first operation in which the first arm is in the advancing phase and the second arm is in the slow phase, and a second operation in which the second arm is in the advancing phase and the first arm is in the slow phase. Control is performed, and based on the current value detected by the current detection unit, when at least the current value is less than a predetermined threshold value, the first arm and the second arm are made to perform the second operation.

The second disclosed isolated DCDC converter is
A transformer with a primary coil and a secondary coil,
A full-bridge type switching circuit including a first switch element, a second switch element, a third switch element, and a fourth switch element, and
A protection circuit having a first diode and a second diode,
A control unit that controls the operation of the switching circuit,
With an inductor
The output circuit connected to the secondary coil and
With
The first switch element and the second switch element are connected in series between the first conductive path and the second conductive path to form a first arm.
The third switch element and the fourth switch element are connected in series between the first conductive path and the second conductive path to form a second arm.
One end of the inductor is electrically connected to a first connection point between the first switch element and the second switch element.
The other end of the inductor is electrically connected to one end of the primary coil, the anode of the first diode, and the cathode of the second diode.
The other end of the primary coil is electrically connected to the second connection point between the third switch element and the fourth switch element.
The cathode of the first diode is electrically connected to the first conductive path,
A phase-shift type isolated DCDC converter in which the anode of the second diode is electrically connected to the second conductive path.
A current detection unit that detects the current value of the current flowing through the output circuit is provided.
The control unit switches between a first operation in which the first arm is in the advancing phase and the second arm is in the slow phase, and a second operation in which the second arm is in the advancing phase and the first arm is in the slow phase. Control is performed, and when at least the current value is larger than a predetermined threshold value based on the current value detected by the current detection unit, the first arm and the second arm are made to perform the first operation.

According to these disclosures, a more efficient isolated DCDC converter can be realized.

FIG. 1 is a circuit diagram showing an isolated DCDC converter according to the first embodiment. FIG. 2 is a timing chart showing the timing of switching each of the first switch element, the second switch element, the third switch element, and the fourth switch element on and off in the isolated DCDC converter of the first embodiment. .. FIG. 3 shows an enlarged view of the timing charts of the first switch element and the second switch element at the time T2 in FIG. 2 on the upper side, and shows the voltage applied between the drain and the source of the second switch element at the time T2. The graph showing the change is shown at the bottom. FIG. 4 is a circuit diagram showing a path of current flowing to the primary side and the secondary side of the transformer when the first switch element and the fourth switch element are in the ON state in the isolated DCDC converter of the first embodiment. FIG. 5 shows a state in which the first switch element and the third switch element are on in a state in which the first arm operates as the slow phase side arm and the second arm operates as the phase advance side arm in the isolated DCDC converter of the first embodiment. It is a circuit diagram which shows the path of the current which flows on the primary side of the transformer at the time. FIG. 6 is a circuit diagram showing a path of current flowing to the primary side and the secondary side of the transformer when the second switch element and the third switch element are in the ON state in the isolated DCDC converter of the first embodiment. FIG. 7 shows a state in which the second switch element and the fourth switch element are on in a state in which the first arm operates as the slow phase side arm and the second arm operates as the phase advance side arm in the isolated DCDC converter of the first embodiment. It is a circuit diagram which shows the path of the current which flows on the primary side of the transformer at the time. FIG. 8 shows a state in which the second switch element and the fourth switch element are on in a state in which the first arm operates as a phase-advancing side arm and the second arm operates as a slow-phase side arm in the isolated DCDC converter of the first embodiment. It is a circuit diagram which shows the path of the current which flows on the primary side of the transformer at the time. FIG. 9 shows a state in which the first switch element and the third switch element are on in a state in which the first arm operates as a phase-advancing side arm and the second arm operates as a slow-phase side arm in the isolated DCDC converter of the first embodiment. It is a circuit diagram which shows the path of the current which flows on the primary side of the transformer at the time. FIG. 10 is a timing chart showing the timing of switching each of the first switch element, the second switch element, the third switch element, and the fourth switch element on and off in the isolated DCDC converter of the first embodiment. .. Specifically, at a predetermined time, from the state in which the first arm is the slow phase arm and the second arm is the phase advance side arm, the first arm is the phase advance side arm and the second arm is the slow phase side arm. It is a timing chart which shows the state which switched to the state which operated as. FIG. 11 is an example of experimental results showing the efficiency when the output current is changed when the inductor is connected to the arm on the phase advance side and when it is connected to the arm on the slow phase side.

[Explanation of Embodiments of the present disclosure]
First, embodiments of the present disclosure will be listed and described.
(1) The isolated DCDC converter of the first disclosure includes a transformer, a switching circuit, a protection circuit, a control unit, an inductor, and an output circuit. The transformer has a primary coil and a secondary coil. The switching circuit is a full bridge type including a first switch element, a second switch element, a third switch element, and a fourth switch element. The protection circuit has a first diode and a second diode. The control unit controls the operation of the switching circuit. The output circuit is connected to the secondary coil. The first switch element and the second switch element are connected in series between the first conductive path and the second conductive path to form the first arm. A third switch element and a fourth switch element are connected in series between the first conductive path and the second conductive path to form a second arm. One end of the inductor is electrically connected to the first connection point between the first switch element and the second switch element. The other end of the inductor is electrically connected to one end of the primary coil, the anode of the first diode, and the cathode of the second diode. The other end of the primary coil is electrically connected to the second connection point between the third switch element and the fourth switch element. The cathode of the first diode is electrically connected to the first conductive path. The first disclosed isolated DCDC converter is a phase shift type isolated DCDC converter in which the anode of the second diode is electrically connected to the second conductive path. The isolated DCDC converter of the first disclosure includes a current detection unit that detects the current value of the current flowing through the output circuit. The control unit controls to switch between a first operation in which the first arm is in the advancing phase and the second arm is in the slow phase, and a second operation in which the second arm is in the advancing phase and the first arm is in the slow phase. Based on the current value detected by the current detection unit, the control unit causes the first arm and the second arm to perform a second operation when at least the current value is less than a predetermined threshold value.

Therefore, this isolated DCDC converter can absorb the recovery surge generated in the secondary coil of the transformer by the protection circuit. At the same time, this isolated DCDC converter operates as a slow phase when the current value detected by the current detector is less than a predetermined threshold value (that is, the current flowing through the load is assumed to be relatively small). The current will be supplied to the current through the inductor. At this time, since the magnitude of the current flowing through the inductor is easily maintained by the current flowing through the first diode and the second diode, the effect of reducing the turn-on loss of the first arm operating as a slow phase is enhanced. This makes it easier to realize ZVS (Zero Voltage Switching) of the first arm, so that the efficiency can be increased. In this case, a conduction loss occurs due to the current flowing through the first diode and the second diode, but the advantage of reducing the turn-on loss of the first arm is greater than this conduction loss.

In the present disclosure, "electrically connected" is preferably configured to be connected in a state of being electrically connected to each other (a state in which a current can flow) so that both potentials of the connection target are equal. However, the configuration is not limited to this. For example, "electrically connected" may be a configuration in which both connection targets are connected in a state in which both connection targets can be electrically connected while an electric component is interposed between the two connection targets.

(2) The isolated DCDC converter of the second disclosure includes a transformer, a switching circuit, a protection circuit, a control unit, an inductor, and an output circuit. The transformer has a primary coil and a secondary coil. The switching circuit is a full bridge type including a first switch element, a second switch element, a third switch element, and a fourth switch element. The protection circuit has a first diode and a second diode. The control unit controls the operation of the switching circuit. The output circuit is connected to the secondary coil. The first switch element and the second switch element are connected in series between the first conductive path and the second conductive path to form the first arm. A third switch element and a fourth switch element are connected in series between the first conductive path and the second conductive path to form a second arm. One end of the inductor is electrically connected to the first connection point between the first switch element and the second switch element. The other end of the inductor is electrically connected to one end of the primary coil, the anode of the first diode, and the cathode of the second diode. The other end of the primary coil is electrically connected to the second connection point between the third switch element and the fourth switch element. The cathode of the first diode is electrically connected to the first conductive path. The first disclosed isolated DCDC converter is a phase shift type isolated DCDC converter in which the anode of the second diode is electrically connected to the second conductive path. The isolated DCDC converter of the first disclosure includes a current detection unit that detects the current value of the current flowing through the output circuit. The control unit controls to switch between a first operation in which the first arm is in the advancing phase and the second arm is in the slow phase, and a second operation in which the second arm is in the advancing phase and the first arm is in the slow phase. Based on the current value detected by the current detection unit, the control unit causes the first arm and the second arm to perform the first operation when at least the current value is larger than a predetermined threshold value.

Therefore, this isolated DCDC converter can absorb the recovery surge generated in the secondary coil of the transformer by the protection circuit. At the same time, in this isolated DCDC converter, when the current value detected by the current detector is larger than a predetermined threshold value (that is, the current flowing through the load is assumed to be relatively large), the current flowing through the inductor becomes large. The inductor can store enough energy to realize ZVS in the second arm that operates as a slow phase. Further, by operating the first arm to which the inductor is connected as a phase advance, it is possible to prevent current from flowing between the first diode and the second diode during the reflux period. Therefore, the efficiency can be improved because the conduction loss that occurs when the current flows through the first diode and the second diode does not occur.

(3) The control unit of the isolated DCDC converter of the first disclosure performs the first operation on the first arm and the second arm when the current value is larger than the threshold value based on the current value detected by the current detection unit. I can let you.
According to this configuration, the efficiency can be increased both when the current value is less than a predetermined threshold value and when the current value is large.

(4) The threshold values of the first and second disclosed isolated DCDC converters are the case where the first arm and the second arm are subjected to the first operation and the case where the first arm and the second arm are second. It can be a value based on the output current value when the efficiency, which is the ratio of the output power to the input power, is the same as when the operation is performed.
According to this configuration, by using such a threshold value, the operation of the first arm and the second arm can be appropriately switched so as to increase the efficiency in both the region below the threshold value and the region above the threshold value.
[Details of Embodiments of the present disclosure]

<Embodiment 1>
[Overview of isolated DCDC converter]

The isolated DCDC converter 100 of the first embodiment (hereinafter, also simply referred to as a converter 100) generates electric power for driving an electric drive device (motor or the like) in a vehicle such as a hybrid vehicle or an electric vehicle (EV (Electric Vehicle)). It is used as an output power source. The converter 100 transforms the input voltage Vin given between the first conductive path 1 and the second conductive path 2 to generate an output voltage Vout, which is between the third conductive path 3 and the fourth conductive path 4. Apply to. As shown in FIG. 1, the converter 100 includes a transformer 10, a switching circuit 20 provided between the first conductive path 1 and the transformer 10, and an output circuit connected between the transformer 10 and the third conductive path 3. 30 and a control unit 40 for controlling the operation of the switching circuit 20 are provided. In actual use, a DC power supply (not shown) is connected between the first conductive path 1 and the second conductive path 2, and a load is applied between the third conductive path 3 and the fourth conductive path 4. 6 is connected. Further, an input capacitor 7 for stabilizing the input voltage Vin is connected between the first conductive path 1 and the second conductive path 2.

The transformer 10 includes a primary coil 11 and secondary coils 12A and 12B. The number of turns of the primary coil 11 is N1. The number of turns of the secondary coil 12A and 12B is N2. The secondary coils 12A and 12B are electrically connected in series with each other at the third connection point P3. The turns ratio N of the transformer 10 is represented by N2 / N1.

The switching circuit 20 converts the input voltage Vin, which is a DC voltage given to the first conductive path 1 and the second conductive path 2, into alternating current and supplies it to the primary coil 11 of the transformer 10. The switching circuit 20 has a configuration in which the first switch element 20A, the second switch element 20B, the third switch element 20C, and the fourth switch element 20D (hereinafter, also referred to as switch elements 20A, 20B, 20C, 20D) are fully bridge-connected. Has.

The switching circuit 20 includes switch elements 20A, 20B, 20C, 20D, a first diode 20E, a second diode 20F, and an inductor 13. Various known switch elements can be used for the switch elements 20A, 20B, 20C, and 20D, but it is preferable to use a MOSFET (Metal Oxide Semiconductor Field Effect Transistor).

Each of the switch elements 20A, 20B, 20C, and 20D is provided with parasitic diodes 20G, 20H, 20J, and 20K, which are parasitic components. Specifically, in each of the switch elements 20A, 20B, 20C, and 20D, the cathodes of the parasitic diodes 20G, 20H, 20J, and 20K are electrically connected to the drain side, and the anode is electrically connected to the source side. .. In addition to the parasitic diodes 20G, 20H, 20J, and 20K, a diode may be added as a separate element.

Parasitic capacitors, which are parasitic components, are electrically connected in parallel to each of the switch elements 20A, 20B, 20C, and 20D (not shown). Specifically, one terminal of each parasitic capacitor is electrically connected to the drain of each of the switch elements 20A, 20B, 20C, and 20D, and the other terminal of each parasitic capacitor is electrically connected to the source. .. In addition to the parasitic capacitor, a capacitor may be added as a separate element.

The first switch element 20A and the second switch element 20B are connected in series between the first conductive path 1 and the second conductive path 2 that input an input voltage to the switching circuit 20, and are connected to each other at the first connection point P1. It is electrically connected. The third switch element 20C and the fourth switch element 20D are connected in series between the first conductive path 1 and the second conductive path 2, and are electrically connected to each other at the second connection point P2. In the switching circuit 20, the first arm A1 is composed of the first switch element 20A and the second switch element 20B, and the second arm A2 is composed of the third switch element 20C and the fourth switch element 20D.

The cathode of the first diode 20E is electrically connected to the first conductive path 1 (the conductive path on the high potential side), and the anode terminal of the second diode 20F is electrically connected to the second conductive path 2 (the conductive path on the low potential side). Is connected. The anode terminal of the first diode 20E and the cathode terminal of the second diode 20F are electrically connected. The first diode 20E and the second diode 20F together with the inductor 13 cause a current flowing to the primary side of the transformer 10 due to a surge generated in the fifth switch element 30A and the sixth switch element 30B on the secondary side of the transformer 10. It constitutes a protection circuit 21 that absorbs (hereinafter, also referred to as a surge current).

One end of the inductor 13 is electrically connected to the first connection point P1. The other end of the inductor 13 is electrically connected to the anode terminal of the first diode 20E, the cathode terminal of the second diode 20F, and one end of the primary coil 11 of the transformer 10. The second connection point P2 is electrically connected to the other end of the primary coil 11. The inductor 13 is provided for the purpose of LC resonance with a parasitic capacitor in order to reduce the switching loss generated in the switching circuit 20. The value of the inductance of the inductor 13 is preferably set to a value sufficiently larger than the leakage inductance of the transformer 10 (not shown).

The output circuit 30 rectifies and smoothes the AC voltage appearing in the secondary coils 12A and 12B of the transformer 10 to generate an output voltage Vout which is a DC voltage, and uses this output voltage Vout as the third conductive path 3 and the fourth conductive path 3. It is applied between the road 4 and the road 4. The output circuit 30 includes a fifth switch element 30A, a sixth switch element 30B, a rectified output path 30C, a choke coil 33, and an output capacitor 34. The fifth switch element 30A is connected between one end of the secondary coil 12A of the transformer 10 and the ground path G. The sixth switch element 30B is connected between one end of the secondary coil 12B of the transformer 10 and the ground path G.

One end of the rectified output path 30C is electrically connected to a third connection point P3 where the other end of the secondary coil 12A and the other end of the secondary coil 12B are electrically connected. One end of the choke coil 33 is electrically connected to the other end of the rectified output path 30C. The other end of the choke coil 33 (that is, the end on the side away from the third connection point P3 side) is electrically connected to the third conductive path 3 and electrically connected to the fourth conductive path 4 via the output capacitor 34. Is connected. That is, the choke coil 33 is interposed between the third connection point P3 and the third conductive path 3. The output capacitor 34 is electrically connected between the third conductive path 3 and the fourth conductive path 4. The fourth conductive path 4 is electrically connected to the ground path G.

Various known switch elements can be used for the fifth switch element 30A and the sixth switch element 30B, but it is preferable to use MOSFETs. The drain of the fifth switch element 30A is electrically connected to one end of the secondary coil 12A, and the source is electrically connected to the ground path G. The drain of the sixth switch element 30B is electrically connected to one end of the secondary coil 12B, and the source is electrically connected to the ground path G. Each of the fifth switch element 30A and the sixth switch element 30B is provided with a parasitic diode which is a parasitic component. Specifically, in each of the fifth switch element 30A and the sixth switch element 30B, the cathode of the parasitic diode is electrically connected to the drain side and the anode is electrically connected to the source side.

Among the output circuits 30 having such a configuration, the fifth switch element 30A and the sixth switch element 30B form a rectifier circuit that rectifies the AC voltage appearing in the secondary coil 12A and 12B of the transformer 10. The choke coil 33 and the output capacitor 34 smooth the rectified output appearing in the rectified output path 30C.

The control unit 40 is mainly composed of, for example, a microcomputer, and includes an arithmetic unit such as a CPU (Central Processing Unit), a memory such as a ROM (Read Only Memory) or a RAM (Random Access Memory), an A / D converter, and the like. have. The control unit 40 is configured so that the voltage value of the first conductive path 1 can be grasped by the first voltage detection unit 40A. The control unit 40 is configured so that the voltage value of the third conductive path 3 can be grasped by the second voltage detection unit 40B. The first voltage detection unit 40A and the second voltage detection unit 40B are configured as known voltage detection circuits. The control unit 40 is configured so that the first current detection unit 40C can grasp the current value flowing through the first conductive path 1. The control unit 40 is configured so that the second current detection unit 40D can grasp the current value flowing through the third conductive path 3. The first current detection unit 40C and the second current detection unit 40D are configured as known current detection circuits using, for example, a current transformer or a shunt resistor.

The control unit 40 uses a phase shift method based on the values input from the first voltage detection unit 40A, the second voltage detection unit 40B, the first current detection unit 40C, and the second current detection unit 40D. A PWM signal is output toward each of the gates of 20C and 20D. As a result, the switch elements 20A, 20B, 20C, and 20D perform switching operations by the phase shift method. The control unit 40 is the fifth switch element 30A and the sixth switch based on the values input from the first voltage detection unit 40A, the second voltage detection unit 40B, the first current detection unit 40C, and the second current detection unit 40D. The configuration is such that a switching signal at a predetermined timing can be output toward each gate of the element 30B.

[Operation of isolated DCDC converter]
Next, the operation of the converter 100 will be described. In a vehicle equipped with the converter 100, for example, the ignition switch is switched from an off state to an on state. Then, the control unit 40 outputs a PWM signal to each of the switch elements 20A, 20B, 20C, and 20D, and outputs a switching signal at a predetermined timing to each of the fifth switch element 30A and the sixth switch element 30B.

The converter 100 performs a switching operation by a phase shift method in which the first arm A1 and the second arm A2 operate so that the turn-on and turn-off timings of the switch elements constituting the first arm A1 and the second arm A2 are shifted by a predetermined phase from each other. In the phase shift method, the switch element of one of the first arm A1 and the second arm A2 turns on and off first, and the other arm turns on and off with a predetermined phase delay with respect to this arm. Of the first arm A1 and the second arm A2, the arm on which the switch element turns on and off first is called a phase advance side arm that operates as a phase advance. An arm in which the switch element turns on and off with a predetermined phase delay with respect to the phase-advancing arm is called a slow-phase arm that operates as a slow phase.

Specifically, the converter 100 is between the first switch element 20A and the fourth switch element 20D, between the second switch element 20B and the third switch element 20C, and between the switch elements 20A, 20B, 20C, and 20D. In, the timing of the on / off operation is shifted (see FIG. 2). In FIG. 2, the time between the start point of the time T1 and the start point of the time T2 is the phase θ between the first arm A1 and the second arm A2.

A case where the second arm A2 is the phase-advancing side arm and the first arm A1 is the slow-phase side arm will be described. In this case, as shown in FIG. 2, the switch element 20A of the first arm A1 (that is, the switch element on the low side side) of the second arm A2 is on (after rising and before falling). That is, the on period of the switch element on the high side side) starts. Then, during the off period (after the fall and before the rise), the switch element 20D of the second arm A2 (that is, the switch element on the low side side) is turned off (that is, the switch element 20A on the high side side). On period ends.

A case where the first arm A1 is the phase-advancing side arm and the second arm A2 is the slow-phase side arm will be described. In this case, as shown after the time B in FIG. 10, the switch element 20A of the first arm A1 (that is, the switch element on the high side side) is in the on period (after the rise and before the fall) of the second arm A2. The on period of the switch element 20D (that is, the switch element on the low side side) of the above is started. Then, during the off period (after the fall and before the rise), the switch element 20A of the first arm A1 (that is, the switch element on the high side side) is turned off (that is, the switch element 20D on the high side side). ) On period ends.

In FIG. 2, the first arm A1 is the slow phase side arm, and the second arm A2 is the phase advance side arm. As a result, ZVS can be realized when the switch elements 20A, 20B, 20C, and 20D are switched from off to on, and the converter 100 can be operated with higher efficiency. In FIG. 2, either the high level or the low level of the PWM signal corresponds to the on of the switch elements 20A, 20B, 20C, 20D, and the high level of the PWM signal corresponds to the off of the switch elements 20A, 20B, 20C, 20D. Either the level or the low level corresponds.

Here, focusing on the time T2, a case where the second switch element 20B is switched from off to on in the first dead time will be described. As shown in FIG. 3, a DC input voltage Vin is applied between the drain and the source of the second switch element 20B before the time T2S (that is, the first switch element 20A is on). (See the bottom of FIG. 3). At this time, the DC input voltage Vin is also applied to the parasitic capacitor of the second switch element 20B.

Then, at time T2S, when the first switch element 20A is switched from on to off, no current flows through the first switch element 20A. At this time, LC resonance starts between the parasitic capacitor of the second switch element 20B and the inductor 13, and the voltage between the drain and the source of the second switch element 20B becomes half the magnitude of the DC input voltage Vin. Get closer. The voltage between the drain and the source of the second switch element 20B is closest to 0V at the time T2E when the LC resonance starts and the voltage first drops (see the lower side of FIG. 3). Therefore, ZVS in the second switch element 20B can be realized by setting the time for switching the second switch element 20B from off to on as T2E. The operation of this ZVS is the same when the other time T1, T3, T4, T5, T6, T7, T8 in FIG. 2 and the other switch elements 20A, 20C, 20D are switched from off to on.

[Operation when the current value grasped by the control unit is less than the threshold value]
The control unit 40 inputs the current value of the current flowing through the third conductive path 3 (that is, the current flowing through the output circuit) by the second current detecting unit 40D. The control unit 40 compares the current value input from the second current detection unit 40D (hereinafter, also simply grasped current value) with the threshold value stored in its own memory or the like (hereinafter, simply referred to as the threshold value). To do. The threshold value is determined based on the specifications of the inductor 13 and the transformer 10. The threshold value is when the first arm A1 is operated as the phase-advancing side arm and the second arm A2 is operated as the slow-phase side arm, and when the first arm A1 is operated as the slow-phase side arm and the second arm A2 is advanced. It is a value based on the output current value when the efficiency is the same as when it is operated as the phase side arm.

FIG. 11 shows an example of the result of measuring the efficiency when the inductor is connected to each of the slow phase arm and the advanced phase arm. The present inventors have the ratio of the magnitude of the output power to the input power when the DCDC converter is operated in each of the case where one end of the inductor is connected to the phase-advancing side arm and the case where it is connected to the slow-phase side arm. That is, it was found that the efficiency) is different.

Specifically, as shown in FIG. 11, in a region larger than a predetermined output current value, connecting one end of the inductor to the phase-advancing side arm is more efficient than connecting one end of the inductor to the slow-phase side arm. .. In a region of less than a predetermined output current value, connecting one end of the inductor to the slow-phase side arm is more efficient than connecting one end of the inductor to the phase-advancing side arm. That is, the present inventors have found that the magnitude of the output current is switched at a predetermined value K depending on whether the inductor is connected to the slow-phase side arm or the inductor is connected to the phase-advancing side arm. .. The threshold value stored in the memory or the like of the control unit 40 is based on this value K. That is, the threshold value is the output with respect to the input power when the first arm A1 and the second arm A2 are subjected to the first operation and when the first arm A1 and the second arm A2 are subjected to the second operation. It is a value based on the output current value when the efficiency, which is the ratio of electric power, becomes the same. The threshold value may be the value K itself, or may be a value obtained by adding or subtracting a predetermined value to the value K to provide a margin. When the control unit 40 determines that the input current value is less than the threshold value (that is, the current output toward the load 6 is small), the control unit 40 operates the first arm A1 as the slow-phase side arm and operates the second arm A2. A PWM signal is output toward each gate of the switch elements 20A, 20B, 20C, and 20D so as to operate as a phase-advancing arm. That is, the control unit 40 controls the first arm A1 and the second arm A2 so as to perform the second operation with the second arm A2 as the advancing phase and the first arm A1 as the slowing phase.

Specifically, the first switch element 20A and the fourth switch element 20D of the switching circuit 20 and the second switch element 20B and the third switch element 20C are alternately turned on based on the PWM signal output from the control unit 40. And off repeatedly. As a result, it is possible to operate so as to apply an AC voltage from the DC power supply to the primary coil 11 of the transformer 10 to generate an output voltage on the output circuit 30 side.

First, as shown in FIG. 4, when the first switch element 20A and the fourth switch element 20D are turned on and the second switch element 20B and the third switch element 20C are turned off, the switching circuit 20 side (primary of the transformer 10). A current flows along the path indicated by the arrow C1 on the side). The path indicated by the arrow C1 is the path of the first conductive path 1 → the first switch element 20A → the inductor 13 → the primary coil 11 → the fourth switch element 20D → the second conductive path 2. The inductor 13 stores electrical energy when a current flows through it. A current flows in the path indicated by the arrow C2 on the output circuit 30 side (secondary side of the transformer 10) corresponding to the current flowing in the path indicated by the arrow C1. The path indicated by the arrow C2 is the path of the fourth conductive path 4 → the sixth switch element 30B → the secondary coil 12B → the rectified output path 30C → the choke coil 33 → the third conductive path 3. At this time, it is a transmission period in which electric power is transmitted from the primary side of the transformer 10 to the secondary side of the transformer 10.

Next, the switch elements 20C and 20D of the second arm A2 turn on and off. Specifically, first, the fourth switch element 20D is turned off, and both the switch elements 20C and 20D are turned off. Then, the parasitic capacitor of the fourth switch element 20D is stored, and the electric charge stored in the parasitic capacitor of the third switch element 20C is discharged. Then, the third switch element 20C turns on. Then, the electric energy stored in the inductor 13 causes a current to flow to the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C3 (see FIG. 5). The path indicated by the arrow C3 is the path of the inductor 13 → the primary coil 11 → the third switch element 20C → the first conductive path 1 → the first switch element 20A. Further, the arrow C3 is branched between the inductor 13 and the primary coil 11, and a current also flows in the path of the primary coil 11 → the first diode 20E → the first conductive path 1 (see FIG. 5). At this time, it is a reflux period in which a current flows through an annular path on the primary side of the transformer 10.

Next, the switch elements 20A and 20B of the first arm A1 turn on and off. Specifically, first, the first switch element 20A is turned off, and both the switch elements 20A and 20B are turned off. Then, the parasitic capacitor of the first switch element 20A is charged, and the electric charge stored in the parasitic capacitor of the second switch element 20B is discharged. At this time, the decrease in the current flowing through the inductor 13 is suppressed by the current flowing through the first diode 20E. Then, the second switch element 20B turns on. At this time, since the decrease in the current flowing through the inductor 13 is suppressed, the turn-on loss when the second switch element 20B is turned on is suppressed. A conduction loss occurs when a current flows through the first diode 20E, but even if a conduction loss occurs, there is a great advantage in suppressing the turn-on loss in the second switch element 20B. Then, a current flows through the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C4 (see FIG. 6). The path indicated by the arrow C4 is the path of the first conductive path 1 → the third switch element 20C → the primary coil 11 → the inductor 13 → the second switch element 20B → the second conductive path 2 (see FIG. 6). The inductor 13 stores electrical energy when a current flows through it.

A current flows in the path indicated by the arrow C5 on the output circuit 30 side (secondary side of the transformer 10) corresponding to the current flowing in the path indicated by the arrow C4 (see FIG. 6). The path indicated by the arrow C5 is the path of the fourth conductive path 4 → the fifth switch element 30A → the secondary coil 12A → the rectified output path 30C → the choke coil 33 → the third conductive path 3. When a current starts to flow in the path indicated by the arrow C5, a surge is generated in the fifth switch element 30A and the sixth switch element 30B on the secondary side of the transformer 10. Then, the surge current Sc flows from the second diode 20F toward the other end of the inductor 13 (see FIG. 6). At this time, it is a transmission period in which electric power is transmitted from the primary side of the transformer 10 to the secondary side of the transformer 10.

Next, the switch elements 20C and 20D of the second arm A2 turn on and off. Specifically, first, the third switch element 20C is turned off, and both the switch elements 20C and 20D are turned off. Then, the parasitic capacitor of the third switch element 20C is stored, and the electric charge stored in the parasitic capacitor of the fourth switch element 20D is discharged. Then, the fourth switch element 20D turns on. Then, the electric energy stored in the inductor 13 causes a current to flow to the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C6 (see FIG. 7). The path indicated by the arrow C6 is the path of the inductor 13 → the second switch element 20B → the second conductive path 2 → the fourth switch element 20D → the primary coil 11. Further, the arrow C6 is branched at the second conductive path 2, and a current also flows in the path of the second conductive path 2 → the second diode 20F → the inductor 13 (see FIG. 7). At this time, it is a reflux period in which a current flows through an annular path on the primary side of the transformer 10.

Then, the switch elements 20A and 20B of the first arm A1 turn on and off. Specifically, first, the second switch element 20B is turned off, and both the switch elements 20A and 20B are turned off. Then, the parasitic capacitor of the second switch element 20B is charged, and the electric charge stored in the parasitic capacitor of the first switch element 20A is discharged. At this time, the decrease in the current flowing through the inductor 13 is suppressed by the current flowing through the second diode 20F. Then, the first switch element 20A turns on. At this time, since the decrease in the current flowing through the inductor 13 is suppressed, the turn-on loss when the first switch element 20A is turned on is suppressed. A conduction loss occurs when a current flows through the second diode 20F, but even if a conduction loss occurs, there is a great advantage in suppressing the turn-on loss in the second switch element 20B. After the first switch element 20A is turned on, when a current starts to flow in the path indicated by the arrow C2, a surge is generated in the fifth switch element 30A and the sixth switch element 30B on the secondary side of the transformer 10. Then, the surge current Sc flows from the first diode 20E toward the first conductive path 1 (see FIG. 4). In this way, when the grasped current value is less than the threshold value in the control unit 40, the current flows repeatedly in the paths shown in FIGS. 4 to 7.

[Operation when the current value grasped by the control unit is larger than the threshold value]
When the control unit 40 determines that the grasped current value is larger than the threshold value (that is, the current output toward the load 6 is large), the first arm A1 is operated as the phase-advancing side arm, and the second arm A2 is delayed. A PWM signal is output toward each gate of the switch elements 20A, 20B, 20C, and 20D so as to operate as a side arm. That is, the control unit 40 controls the first arm A1 and the second arm A2 so as to perform the first operation with the first arm A1 as the advancing phase and the second arm A2 as the slowing phase. As a result, the first switch element 20A and the fourth switch element 20D of the switching circuit 20, and the second switch element 20B and the third switch element 20C alternately turn on and off repeatedly.

First, as shown in FIG. 4, when the first switch element 20A and the fourth switch element 20D are turned on and the second switch element 20B and the third switch element 20C are turned off, the switching circuit 20 side (primary of the transformer 10). A current flows along the path indicated by the arrow C1 on the side). The path indicated by the arrow C1 is the path of the first conductive path 1 → the first switch element 20A → the inductor 13 → the primary coil 11 → the fourth switch element 20D → the second conductive path 2. The inductor 13 stores electrical energy when a current flows through it. A current flows in the path indicated by the arrow C2 on the output circuit 30 side (secondary side of the transformer 10) corresponding to the current flowing in the path indicated by the arrow C1. The path indicated by the arrow C2 is the path of the fourth conductive path 4 → the sixth switch element 30B → the secondary coil 12B → the rectified output path 30C → the choke coil 33 → the third conductive path 3. At this time, it is a transmission period in which electric power is transmitted from the primary side of the transformer 10 to the secondary side of the transformer 10.

Next, the switch elements 20A and 20B of the first arm A1 turn on and off. Specifically, first, the first switch element 20A is turned off, and both the switch elements 20A and 20B are turned off. Then, the parasitic capacitor of the first switch element 20A is charged, and the electric charge stored in the parasitic capacitor of the second switch element 20B is discharged. Then, the second switch element 20B turns on. Then, the electric energy stored in the inductor 13 causes a current to flow to the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C7 (see FIG. 8). The path indicated by the arrow C7 is the path of the inductor 13 → the primary coil 11 → the fourth switch element 20D → the second conductive path 2 → the second switch element 20B (see FIG. 8). At this time, it is a reflux period in which a current flows through an annular path on the primary side of the transformer 10.

Next, the switch elements 20C and 20D of the second arm A2 turn on and off. Specifically, first, the fourth switch element 20D is turned off, and both the switch elements 20C and 20D are turned off. Then, the parasitic capacitor of the fourth switch element 20D is stored, and the electric charge stored in the parasitic capacitor of the third switch element 20C is discharged. At this time, the current flowing through the inductor 13 sharply decreases. At this time, since no current flows through the first diode 20E and the second diode 20F, no conduction loss occurs in the first diode 20E and the second diode 20F. Then, the third switch element 20C turns on. Then, a current flows through the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C4 (see FIG. 6). The path indicated by the arrow C4 is the path of the first conductive path 1 → the third switch element 20C → the primary coil 11 → the inductor 13 → the second switch element 20B → the second conductive path 2 (see FIG. 6). The inductor 13 stores electrical energy when a current flows through it.

A current flows in the path indicated by the arrow C5 on the output circuit 30 side (secondary side of the transformer 10) corresponding to the current flowing in the path indicated by the arrow C4 (see FIG. 6). The path indicated by the arrow C5 is the path of the fourth conductive path 4 → the fifth switch element 30A → the secondary coil 12A → the rectified output path 30C → the choke coil 33 → the third conductive path 3. When a current starts to flow in the path indicated by the arrow C5, a surge is generated in the fifth switch element 30A and the sixth switch element 30B on the secondary side of the transformer 10. Then, the surge current Sc flows from the second diode 20F toward the other end of the inductor 13 (see FIG. 6). At this time, it is a transmission period in which electric power is transmitted from the primary side of the transformer 10 to the secondary side of the transformer 10.

Next, the switch elements 20A and 20B of the first arm A1 turn on and off. Specifically, first, the second switch element 20B is turned off, and both the switch elements 20A and 20B are turned off. Then, the parasitic capacitor of the second switch element 20B is charged, and the electric charge stored in the parasitic capacitor of the first switch element 20A is discharged. Then, the first switch element 20A turns on. Then, the electric energy stored in the inductor 13 causes a current to flow to the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C8 (see FIG. 9). The path indicated by the arrow C8 is the path of the inductor 13 → the first switch element 20A → the first conductive path 1 → the third switch element 20C → the primary coil 11 (see FIG. 9). At this time, it is a reflux period in which a current flows through an annular path on the primary side of the transformer 10.

Then, the switch elements 20C and 20D of the second arm A2 turn on and off. Specifically, first, the third switch element 20C is turned off, and both the switch elements 20C and 20D are turned off. Then, the parasitic capacitor of the third switch element 20C is stored, and the electric charge stored in the parasitic capacitor of the fourth switch element 20D is discharged. At this time, the current flowing through the inductor 13 sharply decreases. At this time, since no current flows through the first diode 20E and the second diode 20F, no conduction loss occurs in the first diode 20E and the second diode 20F. Then, the fourth switch element 20D turns on. When the current starts to flow in the path indicated by the arrow C2 after the fourth switch element 20D is turned on, a surge is generated in the fifth switch element 30A and the sixth switch element 30B on the secondary side of the transformer 10. Then, the surge current Sc flows from the first diode 20E toward the first conductive path 1 (see FIG. 4). In this way, when the grasped current value is larger than the threshold value in the control unit 40, the current flows repeatedly in the paths shown in FIGS. 4, 8, 6, and 9.

[Operation when the current value grasped by the control unit changes from a state below the threshold value to a state where it is large]
The control unit 40 determines that the grasped current value has changed from a state of being less than the threshold value to a state of being large. Then, the control unit 40 operates the switch elements 20A, 20B, 20C so that the first arm A1 operates from the slow phase side arm as the phase advance side arm and the second arm A2 operates from the phase advance side arm as the slow phase side arm. , 20D is output as a PWM signal toward each gate. That is, the control unit 40 has a first operation in which the first arm A1 is in the advancing phase and the second arm A2 is in the slow phase, and a second operation in which the second arm A2 is in the advancing phase and the first arm A1 is in the slow phase. Control to switch. For example, as shown in FIG. 10, from time S to time B, the control unit 40 operates the switch element 20A so that the first arm A1 serves as the slow phase arm and the second arm A2 operates as the phase advance side arm. A PWM signal is output toward each of the gates of 20B, 20C, and 20D. From time S to time B, the first arm A1 is delayed by phase θ1 with respect to the second arm A2.

It is determined that the current value grasped by the control unit 40 has changed to a state larger than the threshold value at time B. Then, after time B, the control unit 40 operates each of the switch elements 20A, 20B, 20C, and 20D so that the first arm A1 operates as the phase-advancing side arm and the second arm A2 operates as the slow-phase side arm. A PWM signal is output toward the gate. After the time B, the second arm A2 is delayed by the phase θ2 with respect to the first arm A1. The phases θ1 and θ2 may be the same or different.

At time T6, the switch elements 20A and 20B of the first arm A1 turn on and off. Specifically, first, the first switch element 20A turns off. Then, the parasitic capacitor of the first switch element 20A is charged, and the electric charge stored in the parasitic capacitor of the second switch element 20B is discharged. Then, the second switch element 20B turns on. Then, the electric energy stored in the inductor 13 causes a current to flow to the switching circuit 20 side (primary side of the transformer 10) along the path indicated by the arrow C4 (see FIG. 6).

Then, it is determined that the current value grasped by the control unit 40 has changed to a state larger than the threshold value at time B. Then, at time T7, the switch elements 20A and 20B of the first arm A1 turn on and off. Specifically, first, the second switch element 20B is turned off, and then the first switch element 20A is turned on.

Then, at time T8, the switch elements 20C and 20D of the second arm A2 turn on and off. Specifically, first, the third switch element 20C is turned off, and then the fourth switch element 20D is turned on. Then, a current flows in the path shown by the arrow C1 shown in FIG. In this way, when the grasped current value is larger than the threshold value in the control unit 40, the current flows repeatedly in the paths shown in FIGS. 4, 8, 6, and 9.

Next, the effect of this configuration will be illustrated.
The isolated DCDC converter 100 of the first disclosure includes a transformer 10, a switching circuit 20, a protection circuit 21, a control unit 40, an inductor 13, and an output circuit 30. The transformer 10 has a primary coil 11 and secondary coils 12A and 12B. The switching circuit 20 is a full bridge type including a first switch element 20A, a second switch element 20B, a third switch element 20C, and a fourth switch element 20D. The protection circuit 21 has a first diode 20E and a second diode 20F. The control unit 40 controls the operation of the switching circuit 20. The output circuit 30 is connected to the secondary coils 12A and 12B. The first switch element 20A and the second switch element 20B are connected in series between the first conductive path 1 and the second conductive path 2 to form the first arm A1. The third switch element 20C and the fourth switch element 20D are connected in series between the first conductive path 1 and the second conductive path 2 to form the second arm A2. One end of the inductor 13 is electrically connected to the first connection point P1 between the first switch element 20A and the second switch element 20B. The other end of the inductor 13 is electrically connected to one end of the primary coil 11 and the anode of the first diode 20E and the cathode of the second diode 20F. The other end of the primary coil 11 is electrically connected to the second connection point P2 between the third switch element 20C and the fourth switch element 20D. The cathode of the first diode 20E is electrically connected to the first conductive path 1. The first disclosed isolated DCDC converter 100 is a phase shift type isolated DCDC converter in which the anode of the second diode 20F is electrically connected to the second conductive path 2. The isolated DCDC converter 100 of the first disclosure includes a second current detection unit 40D that detects the current value of the current flowing through the output circuit 30. The control unit 40 switches between a first operation in which the first arm A1 is in the advancing phase and the second arm A2 is in the slow phase, and a second operation in which the second arm A2 is in the advancing phase and the first arm A1 is in the slow phase. Take control. The control unit 40 causes the first arm A1 and the second arm A2 to perform a second operation when the current value is less than a predetermined threshold value based on the current value detected by the second current detection unit 40D.

Therefore, the isolated DCDC converter 100 can absorb the recovery surge generated in the secondary coils 12A and 12B of the transformer 10 by the protection circuit 21. At the same time, when the current value detected by the second current detection unit 40D is less than a predetermined threshold value (that is, the current flowing through the load 6 is assumed to be relatively small), the isolated DCDC converter 100 is set as a slow phase. A current is supplied to the operating first arm A1 via the inductor 13. At this time, since the magnitude of the current flowing through the inductor 13 is easily maintained by the current flowing through the first diode 20E and the second diode 20F, the effect of reducing the turn-on loss of the first arm A1 operating as a slow phase is effective. growing. This makes it easier to realize the ZVS of the first arm A1, so that the efficiency can be increased. In this case, a conduction loss occurs due to the current flowing through the first diode 20E and the second diode 20F, but the advantage of reducing the turn-on loss of the first arm A1 is greater than this conduction loss.

The isolated DCDC converter 100 of the second disclosure includes a transformer 10, a switching circuit 20, a protection circuit 21, a control unit 40, an inductor 13, and an output circuit 30. The transformer 10 has a primary coil 11 and secondary coils 12A and 12B. The switching circuit 20 is a full bridge type including a first switch element 20A, a second switch element 20B, a third switch element 20C, and a fourth switch element 20D. The protection circuit 21 has a first diode 20E and a second diode 20F. The control unit 40 controls the operation of the switching circuit 20. The output circuit 30 is connected to the secondary coils 12A and 12B. The first switch element 20A and the second switch element 20B are connected in series between the first conductive path 1 and the second conductive path 2 to form the first arm A1. The third switch element 20C and the fourth switch element 20D are connected in series between the first conductive path 1 and the second conductive path 2 to form the second arm A2. One end of the inductor 13 is electrically connected to the first connection point P1 between the first switch element 20A and the second switch element 20B. The other end of the inductor 13 is electrically connected to one end of the primary coil 11 and the anode of the first diode 20E and the cathode of the second diode 20F. The other end of the primary coil 11 is electrically connected to the second connection point P2 between the third switch element 20C and the fourth switch element 20D. The cathode of the first diode 20E is electrically connected to the first conductive path 1. The second disclosed isolated DCDC converter 100 is a phase shift type isolated DCDC converter in which the anode of the second diode 20F is electrically connected to the second conductive path 2. The isolated DCDC converter 100 of the second disclosure includes a second current detection unit 40D that detects the current value of the current flowing through the output circuit 30. The control unit 40 switches between a first operation in which the first arm A1 is in the advancing phase and the second arm A2 is in the slow phase, and a second operation in which the second arm A2 is in the advancing phase and the first arm A1 is in the slow phase. Take control. The control unit 40 causes the first arm A1 and the second arm A2 to perform the first operation when the current value is larger than a predetermined threshold value based on the current value detected by the second current detection unit 40D.

Therefore, the isolated DCDC converter 100 can absorb the recovery surge generated in the secondary coils 12A and 12B of the transformer 10 by the protection circuit 21. At the same time, when the current value detected by the second current detection unit 40D is larger than a predetermined threshold value (that is, the current flowing through the load 6 is assumed to be relatively large), the isolated DCDC converter 100 flows through the inductor 13. Since the current becomes large, the inductor 13 can store enough energy to realize ZVS in the second arm A2 that operates as a slow phase. Further, by operating the first arm A1 to which the inductor 13 is connected as a phase advance, it is possible to prevent current from flowing through the first diode 20E and the second diode 20F during the reflux period. Therefore, the efficiency can be increased because the conduction loss that occurs when the current flows through the first diode 20E and the second diode 20F does not occur.

As shown in FIG. 11, when the inductor is connected to the slow-phase arm, the magnitude of the output current is switched at a predetermined value K as compared with the case where the inductor is connected to the phase-advancing arm. In particular, when the output current is greater than a predetermined value K, connecting the inductor to the phase-advancing arm is more efficient than connecting the inductor to the slow-phase arm. The results shown in FIG. 11 show that it was brought about by the above-mentioned actions and effects.

The control unit 40 of the isolated DCDC converter 100 of the present disclosure sets the first arm A1 and the second arm A2 to the first arm A1 and the second arm A2 when the current value is larger than a predetermined threshold value based on the current value detected by the second current detection unit 40D. Make one operation.
According to this configuration, the efficiency can be increased both when the current value is less than a predetermined threshold value and when the current value is large. Further, since the control unit 40 controls the operation of each arm, there is no need for a mechanism for actually switching the connection at one end of the inductor 13. That is, the isolated DCDC converter 100 of the present disclosure can switch the phase advance or the slow phase in each arm without adding a component.

The threshold value of the isolated DCDC converter of the present disclosure is the case where the first arm A1 and the second arm A2 are subjected to the first operation and the case where the first arm A1 and the second arm A2 are subjected to the second operation. It is a value based on the output current value when the efficiency, which is the ratio of the output power to the input power, is the same.
According to this configuration, by using such a threshold value, the operation of the first arm A1 and the second arm A2 can be appropriately switched so as to increase the efficiency in both the region below the threshold value and the region above the threshold value. ..

<Other Embodiments>
The present configuration is not limited to the embodiments described in the above description and drawings, and for example, the following embodiments are also included in the technical scope of the present invention.

In the first embodiment, the control unit 40 switches the operation of the first arm A1 and the second arm A2 at the time B between the time T6 and the time T7, but the operation of the first arm A1 and the second arm A2 is performed. The switching timing may be other timing. When the operations of the first arm A1 and the second arm A2 are switched during the period when the switch elements 20A and 20D are on, the state where the switch elements 20A and 20D are on is continued for a longer time than a predetermined time. I need to let you.

In the first embodiment, the MOSFET is used for the fifth switch element 30A and the sixth switch element 30B, but a diode may be used.

In the first embodiment, the control unit 40 is mainly composed of a microcomputer, but it may be realized by a plurality of hardware circuits other than the microcomputer.

In the first embodiment, the current value detected by the second current detection unit 40E and the threshold value are compared, but the current value detected by the first current detection unit 40C, the first voltage detection unit 40A or the second voltage detection unit The current flowing through the output circuit may be obtained based on the voltage value detected at 40B.

In the first embodiment, from the state where the first arm A1 is the slow phase side arm and the second arm A2 is the phase advance arm, the first arm A1 is advanced when the current output toward the load 6 becomes larger than the threshold value. The second arm A2 is switched to the slow phase arm as the phase side arm. On the other hand, when the current output toward the load 6 becomes smaller than the threshold value from the state where the first arm A1 is the phase-advancing side arm and the second arm A2 is the slow-phase arm, the first arm A1 is delayed. The second arm A2 may be switched to the phase advance arm as the phase side arm.

FIG. 11 illustrates an example of the result of measuring the efficiency when the inductor 13 is connected to each of the slow phase arm and the advanced phase arm, but the present disclosure is not limited to the measurement result.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is not limited to the embodiments disclosed here, but may be indicated by the claims and include all modifications within the meaning and scope equivalent to the claims. Intended.

1 ... 1st conductive path 2 ... 2nd conductive path 3 ... 3rd conductive path 4 ... 4th conductive path 6 ... Load 7 ... Input capacitor 10 ... Transformer 11 ... Primary side coil 12A, 12B ... Secondary side coil 13 ... Inductor 14 ... Excitation inductance 20 ... Switching circuit 20A ... 1st switch element 20B ... 2nd switch element 20C ... 3rd switch element 20D ... 4th switch element 20E ... 1st diode 20F ... 2nd diode 20G, 20H, 20J, 20K ... Parasitic diode 21 ... Protection circuit 30 ... Output circuit 30A ... 5th switch element 30B ... 6th switch element 30C ... Rectification output path 33 ... Chalk coil 34 ... Output capacitor 40 ... Control unit 40A ... 1st voltage detection unit (voltage detection unit) )
40C ... First current detection unit (current detection unit)
100 ... Insulated DCDC converter G ... Ground path P1 ... First connection point P2 ... Second connection point P3 ... Third connection point A1 ... First arm A2 ... Second arm Vin ... Input voltage Vout ... Output voltage

Claims (4)

A transformer with a primary coil and a secondary coil,
A full-bridge type switching circuit including a first switch element, a second switch element, a third switch element, and a fourth switch element, and
A protection circuit having a first diode and a second diode,
A control unit that controls the operation of the switching circuit,
With an inductor
The output circuit connected to the secondary coil and
With
The first switch element and the second switch element are connected in series between the first conductive path and the second conductive path to form a first arm.
The third switch element and the fourth switch element are connected in series between the first conductive path and the second conductive path to form a second arm.
One end of the inductor is electrically connected to a first connection point between the first switch element and the second switch element.
The other end of the inductor is electrically connected to one end of the primary coil, the anode of the first diode, and the cathode of the second diode.
The other end of the primary coil is electrically connected to the second connection point between the third switch element and the fourth switch element.
The cathode of the first diode is electrically connected to the first conductive path,
A phase-shift type isolated DCDC converter in which the anode of the second diode is electrically connected to the second conductive path.
A current detection unit that detects the current value of the current flowing through the output circuit is provided.
The control unit switches between a first operation in which the first arm is in the advancing phase and the second arm is in the slow phase, and a second operation in which the second arm is in the advancing phase and the first arm is in the slow phase. An isolated DCDC converter that controls and causes the first arm and the second arm to perform the second operation when at least the current value is less than a predetermined threshold value based on the current value detected by the current detection unit. .. A transformer with a primary coil and a secondary coil,
A full-bridge type switching circuit including a first switch element, a second switch element, a third switch element, and a fourth switch element, and
A protection circuit having a first diode and a second diode,
A control unit that controls the operation of the switching circuit,
With an inductor
The output circuit connected to the secondary coil and
With
The first switch element and the second switch element are connected in series between the first conductive path and the second conductive path to form a first arm.
The third switch element and the fourth switch element are connected in series between the first conductive path and the second conductive path to form a second arm.
One end of the inductor is electrically connected to a first connection point between the first switch element and the second switch element.
The other end of the inductor is electrically connected to one end of the primary coil, the anode of the first diode, and the cathode of the second diode.
The other end of the primary coil is electrically connected to the second connection point between the third switch element and the fourth switch element.
The cathode of the first diode is electrically connected to the first conductive path,
A phase-shift type isolated DCDC converter in which the anode of the second diode is electrically connected to the second conductive path.
A current detection unit that detects the current value of the current flowing through the output circuit is provided.
The control unit switches between a first operation in which the first arm is in the advancing phase and the second arm is in the slow phase, and a second operation in which the second arm is in the advancing phase and the first arm is in the slow phase. An isolated DCDC converter that controls and causes the first arm and the second arm to perform the first operation when at least the current value is larger than a predetermined threshold value based on the current value detected by the current detection unit. .. The first aspect of claim 1, wherein the control unit causes the first arm and the second arm to perform the first operation when the current value is larger than the threshold value based on the current value detected by the current detection unit. Insulated DCDC converter. The threshold value is based on the input power when the first arm and the second arm are made to perform the first operation and when the first arm and the second arm are made to perform the second operation. The isolated DCDC converter according to any one of claims 1 to 3, which is a value based on an output current value when the efficiency, which is a ratio of output power, becomes the same.

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