JP7152578B2 - DC power supply and air conditioner - Google Patents

Description

The present invention relates to a DC power supply device and an air conditioner.

2. Description of the Related Art Electric trains, automobiles, air conditioners, and the like are equipped with a DC power supply that converts an AC voltage into a DC voltage. A DC voltage output from the DC power supply is converted into an AC voltage having a predetermined frequency by an inverter, and this AC voltage is applied to a load such as a motor. Such direct-current power supply devices are required to improve power conversion efficiency and save energy.
In view of this, a DC power supply apparatus has been proposed, such as Patent Document 1, which performs power factor improvement, harmonic suppression, and DC voltage boosting when converting an AC power supply into a DC power supply. Further, Patent Literature 2 proposes a DC power supply device that switches between a full-wave rectification mode, a voltage doubler rectification mode, a partial switching mode, and a high-speed switching mode in order to improve the power factor in the entire load range.

JP-A-11-164562 JP-A-2003-153543

Both of the DC power supply devices described in Patent Documents 1 and 2 have a reactor, but the reactor tends to increase in weight and volume as the inductance value increases. Therefore, if a reactor with a large inductance value is applied, there arises a problem that a direct-current power supply device and a device such as an air conditioner including the DC power source device become large-sized and expensive.
SUMMARY OF THE INVENTION It is an object of the present invention to provide a compact and inexpensive DC power supply and an air conditioner.

In order to solve the above problems, the DC power supply device of the present invention performs switching to appropriately short-circuit a reactor connected to an AC power supply that outputs an AC voltage with an effective value of 100 V or more and 230 V or less, and the reactor to the AC power supply. a rectifying circuit that converts the AC voltage into a DC voltage and applies it to a load; One of the second operation modes in which switching is performed 80 times or more is selected based on a comparison result between a load correspondence amount, which is an amount that increases or decreases according to an increase or decrease in the load, and a predetermined threshold. and a control unit for controlling the amplitude of the circuit current flowing from the AC power supply to be larger than the previous value when the operation mode is switched from the second operation mode to the first operation mode. It is characterized by having a function to

ADVANTAGE OF THE INVENTION According to this invention, a compact and inexpensive DC power supply device and an air conditioner can be realized.

1 is a schematic configuration diagram showing a DC power supply device according to an embodiment of the present invention; FIG. FIG. 4 is a diagram showing paths of current flowing through a circuit when diode rectification is performed when an AC power supply voltage has a positive polarity; FIG. 4 is a diagram showing paths of current flowing through a circuit when diode rectification is performed when the AC power supply voltage has a negative polarity; FIG. 4 is a diagram showing paths of current flowing through a circuit when synchronous rectification is performed when an AC power supply voltage has a positive polarity; FIG. 4 is a diagram showing paths of current flowing through a circuit when synchronous rectification is performed when the AC power supply voltage has a negative polarity; FIG. 4 is a waveform diagram of a power supply voltage, a circuit current, and a drive pulse of a MOSFET during synchronous rectification; FIG. 4 is a diagram showing paths of current flowing through a circuit when a power factor correction operation is performed when an AC power supply voltage has a positive polarity; FIG. 4 is a diagram showing paths of current flowing through a circuit when a power factor correction operation is performed when the AC power supply voltage has a negative polarity; FIG. 10 is (a) a waveform diagram of a power supply voltage, (b) a waveform diagram of a circuit current, (c) a waveform diagram of a drive pulse, and (d) a waveform diagram of another drive pulse when partial switching (two shots) is performed; . (a) a waveform diagram of a power supply voltage, (b) a waveform diagram of a circuit current, (c) a waveform diagram of a drive pulse, and (d) a waveform diagram of another drive pulse. FIG. 10 is a diagram showing the duty ratio of a MOSFET when high-speed switching is performed; FIG. 10 is a diagram showing the relationship between MOSFET duties when high-speed switching is performed and dead time is taken into consideration; FIG. 4 is a diagram showing the relationship between AC power supply voltage and circuit current when high-speed switching is performed; FIG. 4 is a diagram showing the duty of a MOSFET when considering a current phase delay due to a reactor when the AC power supply voltage is of positive polarity; FIG. 10 is (a) a waveform diagram of an AC power supply voltage, (b) a waveform diagram of a circuit current, (c) a waveform diagram of a drive pulse, and (d) a waveform diagram of another drive pulse in partial switching. FIG. 10 is a diagram showing partial switching waveforms when the input power is 700 W; FIG. 10 is a diagram showing partial switching waveforms when the input power is 1800 W; It is a figure which shows an example of the relationship between power consumption, DC voltage, and an operation mode. (a) Waveform diagram of AC power supply voltage and circuit current in partial switching mode, (b) Waveform diagram of AC power supply voltage and circuit current in high-speed switching mode. FIG. 5 is a diagram showing another example of the relationship between power consumption, DC voltage, and operation mode; FIG. 5 is a diagram showing still another example of the relationship between power consumption, DC voltage and operation mode; 1 is a front view of an indoor unit, an outdoor unit, and a remote controller of an air conditioner according to the present embodiment; FIG. It is a schematic block diagram of the DC power supply device by a modified example. FIG. 11 is a schematic configuration diagram of a DC power supply device according to another modification; FIG. 11 is a schematic configuration diagram of a DC power supply device according to still another modification;

[Overview of embodiment]
In a DC power supply device with a rated voltage of 200 V to 230 V and 4000 W or less, the inductance of the reactor used in the DC power supply when performing partial switching with a wide switching interval is often 9 mH to 20 mH, and high-speed switching with a narrow switching interval In many cases, the inductance of the reactor used for the DC power supply is 500 μH to 6 mH. This is because when partial switching is used, the ON time of switching is long and the short-circuit current tends to increase, so the inductance value must be increased to suppress harmonics. This is because the inductance value can be reduced because the time is short and the short-circuit current is small.

In addition, the above-mentioned Patent Document 2 proposes a DC power supply device that switches between a full-wave rectification mode, a voltage doubler rectification mode, a partial switching mode, and a high-speed switching mode, but how to set the inductance value of the reactor It was not mentioned whether it is preferable to do so.

Since the inductance value of the reactor is large in the partial switching DC power supply device as described above, the size of the DC power supply device becomes large, resulting in an increase in cost.
In addition, there is a problem that the number of times of switching is increased in the high-speed switching direct current power supply, and the efficiency is deteriorated. In order to improve the APF (Annual Performance Factor) of DC power supply units used in air conditioners in particular, low load and high efficiency are required, but high-speed switching DC power supply units are not suitable for improving APF. Also, at high load, high output voltage is required to increase the rotation speed of the compressor used in the air conditioner, but if partial switching is used at this time, it is not possible to satisfy the harmonic current standard.

Therefore, the present embodiment provides a compact and inexpensive DC power supply that is highly efficient at low loads, supplies high output voltage while suppressing harmonic currents at high loads, and improves the power factor over the entire load range. The object of the present invention is to provide an air conditioner using this DC power supply.

[Configuration of Embodiment]
Hereinafter, the configuration of a DC power supply device according to one embodiment of the present invention will be described in detail with reference to each drawing.
FIG. 1 is a configuration diagram of a DC power supply device 1 according to this embodiment.
As shown in FIG. 1, the DC power supply 1 is a converter that converts an AC power supply voltage supplied from an AC power supply VS into a DC voltage Vd and outputs this DC voltage Vd to a load H (inverter, motor, etc.). . The input side of the DC power supply device 1 is connected to the AC power supply VS, and the output side is connected to the load H.

The DC power supply 1 includes a reactor L1, a smoothing capacitor C1, diodes D1, D2, D3 and D4, MOSFETs (Q1 and Q2) as switching elements, and a shunt resistor R1. Diodes D1, D2, D3, D4 and MOSFETs (Q1, Q2) form a rectifier circuit 10. FIG.
The MOSFETs (Q1, Q2) are switching elements, the diode D3 is a parasitic diode of the MOSFET (Q1), and the diode D4 is a parasitic diode of the MOSFET (Q2). Also, the saturation voltages of MOSFET (Q1) and MOSFET (Q2) are lower than the forward voltage drops of diodes D1 and D2 and parasitic diodes D3 and D4.

The DC power supply 1 further includes a current detection unit 11, a gain control unit 12, an AC voltage detection unit 13, a zero cross determination unit 14, a load detection unit 15, a step-up ratio control unit 16, and a DC voltage detection unit. 17 , a converter control section 18 and a power supply circuit 19 . The power supply circuit 19 generates a power supply voltage of 15V for driving the MOSFETs (Q1, Q2) and a control voltage of 5V for driving a control IC (not shown) such as a microcomputer from the DC voltage.

Diodes D1, D2 and MOSFETs (Q1, Q2) are bridge-connected. The anode of the diode D1 is connected to the cathode of the diode D2, and its connection point N1 is connected to one end of the AC power supply VS via the wiring hb.

The source of MOSFET (Q1) is connected to the drain of MOSFET (Q2). The source of the MOSFET (Q1) is connected to one end of the AC power supply VS via the connection point N2, the wiring ha and the reactor L1.
The anode of diode D2 is connected to the source of MOSFET (Q2).
The drain of MOSFET (Q1) is connected to the cathode of diode D1.

Also, the cathode of the diode D1 and the drain of the MOSFET (Q1) are connected to the positive electrode of the smoothing capacitor C1 and one end of the load H via the wiring hc. Further, the diode D2 and the source of the MOSFET (Q2) are connected to the negative electrode of the smoothing capacitor C1 and the other end of the load H via the shunt resistor R1 and the wiring hd, respectively.

The reactor L<b>1 is provided on the wiring ha, that is, between the AC power supply VS and the rectifier circuit 10 . This reactor L1 stores the power supplied from the AC power supply VS as energy, and releases this energy to boost the voltage.

In this embodiment, the inductance value of reactor L1 is set to 3 to 6 mH.
This is because if it is less than 3 mH, the harmonic current increases during the partial switching operation, which will be described later, and the harmonic current standard cannot be satisfied. Also, if it is larger than 6 mH, the reactor L1 becomes large and expensive. A reactor with a structure in which a copper wire or an aluminum wire is wound around an electromagnetic steel sheet can be reduced in size by about 30% by reducing 12 mH to 6 mH.

The smoothing capacitor C1 smoothes the voltage rectified through the diode D1 and MOSFET (Q1) to obtain a DC voltage Vd. The smoothing capacitor C1 is connected to the output side of the rectifier circuit 10, the positive side is connected to the wiring hc, and the negative side is connected to the wiring hd.

The MOSFETs (Q1, Q2), which are switching elements, are on/off controlled by commands from the converter control section 18, which will be described later. By using MOSFETs (Q1 and Q2) as switching elements, switching can be performed at high speed, and by passing current through MOSFETs with a small voltage drop, it is possible to perform so-called synchronous rectification control. Conduction loss can be reduced.

Conduction loss can be further reduced by using a superjunction MOSFET with a small on-resistance as the MOSFETs (Q1, Q2). Here, a reverse recovery current is generated in the parasitic diode of the MOSFET during short-circuit operation. In particular, the parasitic diode of the superjunction MOSFET has a problem that the reverse recovery current is larger than that of the normal MOSFET, and the switching loss is large. Therefore, switching loss can be reduced by using MOSFETs with a short reverse recovery time (trr) as the MOSFETs (Q1, Q2).

Since the diodes D1 and D2 do not generate a reverse recovery current even during active operation, it is preferable to select diodes with a small forward voltage drop. For example, it is possible to reduce the conduction loss of the circuit by using a general rectifier diode or a high-voltage SiC (Silicon Carbide)-Schottky barrier diode.
The shunt resistor R1 has the function of detecting the instantaneous current flowing through the circuit.
The current detector 11 has a function of detecting an average current flowing through the circuit.

The gain control section 12 has a function of controlling a current control gain Kp determined from the circuit current effective value Is and the DC voltage step-up ratio a. At this time, by controlling Kp×Is to a predetermined value, the DC voltage Vd can be boosted a times from the AC power supply voltage vs.

The AC voltage detection unit 13 detects an AC power supply voltage vs applied from the AC power supply VS, and is connected to wires ha and hb. AC voltage detection unit 13 outputs the detected value to zero-cross determination unit 14 .

The zero-cross determination unit 14 determines whether the value of the AC power supply voltage vs detected by the AC voltage detection unit 13 has switched between positive and negative, that is, whether it has reached a zero-cross point, that is, determines the timing of the zero-cross. It has the function to The zero-cross determination section 14 also has a function as a polarity detection section that detects the polarity of the AC power supply voltage vs. For example, the zero-cross determination unit 14 outputs a signal of '1' to the converter control unit 18 during a period when the AC power supply voltage vs is positive, and outputs a signal of '1' to the converter control unit 18 during a period when the AC power supply voltage vs is negative. Output a signal of 0'.

The load detection unit 15 is composed of, for example, a shunt resistor (not shown) and has a function of detecting current flowing through the load H. When the load H is an inverter or a motor, the rotational speed of the motor and the voltage applied to the motor may be calculated from the load current detected by the load detection unit 15 . Further, the modulation factor of the inverter may be calculated from the DC voltage detected by the DC voltage detection unit 17 described later and the voltage applied to the motor. The load detection unit 15 outputs the detected values (current, motor rotation speed, modulation factor, etc.) to the boost ratio control unit 16 .

Boost ratio control unit 16 selects a boost ratio a of DC voltage Vd from the value detected by load detection unit 15 and outputs the selection result to converter control unit 18 . Then, the converter control unit 18 performs switching control by outputting drive pulses to the MOSFETs (Q1, Q2) so as to boost the DC voltage Vd to the target voltage.

The DC voltage detection unit 17 detects a DC voltage Vd applied to the smoothing capacitor C1, and has its positive side connected to the wiring hc and its negative side connected to the wiring hd. DC voltage detection unit 17 outputs the detected value to converter control unit 18 . The value detected by the DC voltage detection unit 17 is used to determine whether or not the voltage value applied to the load H has reached a predetermined target value.

The control block M including the converter control unit 18 is, for example, a microcomputer, reads a program stored in a ROM (Read Only Memory), develops it in a RAM (Random Access Memory), and outputs it to a CPU (Central Processing Unit). is designed to perform various processes. Converter control unit 18 selects MOSFET (Q1, Q2) on/off control. The processing executed by converter control unit 18 will be described later.

[action mode]
Next, operation modes of the DC power supply device 1 of this embodiment will be described.
The operation modes of the DC power supply 1 are roughly classified into (1) diode rectification mode (third operation mode), (2) synchronous rectification mode (another third operation mode), and (3) partial switching mode (third operation mode). 2 operating mode), and (4) high-speed switching mode (first operating mode). The partial switching mode and the high-speed switching mode are modes in which the converter performs active operation (power factor improving operation), and by causing a power factor improving current to flow through the rectifier circuit 10, the DC voltage Vd is boosted and the power factor is improved. mode. For example, when the load of an inverter, motor, or the like is large, the DC voltage Vd is often boosted. In addition, as the load increases and the current flowing through the DC power supply 1 increases, the harmonic current also increases. Therefore, in the case of a high load, it is preferable to boost the voltage in the partial switching mode or the high-speed switching mode to reduce the harmonic current, that is, to improve the power factor of the power supply input.

≪Diode rectification mode≫
A diode rectification mode (third operation mode) is a mode in which full-wave rectification is performed using four diodes D1 to D4. In this mode, MOSFET (Q1) and MOSFET (Q2) are off.
FIG. 2 shows current paths flowing through the circuit when diode rectification is performed when the AC power supply voltage vs is of positive polarity.
In FIG. 2, the circuit current is flows in the direction indicated by the dashed arrow during the positive half-cycle period of the AC power supply voltage vs. That is, the circuit current is flows in the order of AC power supply VS→reactor L1→parasitic diode D3→smoothing capacitor C1→shunt resistor R1→diode D2→AC power supply VS.
FIG. 3 shows current paths flowing through the circuit when diode rectification is performed when the AC power supply voltage vs is of negative polarity.
In FIG. 3, the circuit current is flows in the direction indicated by the dashed arrow during the period of the negative half cycle of the AC power supply voltage vs. That is, the circuit current is flows in the order of AC power supply VS→diode D1→smoothing capacitor C1→shunt resistor R1→parasitic diode D4→reactor L1→AC power supply VS.

≪Synchronous rectification mode≫
In order to perform highly efficient operation for the aforementioned diode rectification, the operation mode for performing synchronous rectification control is called a synchronous rectification mode (other than 3rd operation mode).

FIG. 4 is a diagram showing current paths flowing through the circuit when synchronous rectification is performed when the AC power supply voltage vs is of positive polarity.
In FIG. 4, the circuit current is flows in the direction indicated by the dashed arrow during the positive half-cycle period of the AC power supply voltage vs. That is, the circuit current is flows in the order of AC power supply VS→reactor L1→MOSFET (Q1)→smoothing capacitor C1→shunt resistor R1→diode D2→AC power supply VS. At this time, the MOSFET (Q2) is always off and the MOSFET (Q1) is always on. If the MOSFET (Q1) is not in the ON state, the circuit current is flows through the parasitic diode D3 of the MOSFET (Q1) as in the diode rectification operation described above. However, the parasitic diode of a MOSFET usually causes a large conduction loss due to a large voltage drop. Therefore, it is possible to reduce the conduction loss by turning on the MOSFET (Q1) and causing a current to flow through the on-resistance portion of the MOSFET (Q1). This is the principle of so-called synchronous rectification control. The timing for starting the ON operation of the MOSFET (Q1) is from the timing of the zero cross when the polarity of the AC power supply voltage vs switches from negative to positive. The timing at which the MOSFET (Q1) is turned off is the timing at which the polarity of the AC power supply voltage vs switches from positive to negative.

FIG. 5 is a diagram showing paths of current flowing through the circuit when synchronous rectification is performed when the AC power supply voltage vs is of negative polarity.
In FIG. 5, the circuit current is flows in the direction indicated by the dashed arrow during the period of the negative half cycle of the AC power supply voltage vs. That is, the circuit current is flows in the order of AC power supply VS→diode D1→smoothing capacitor C1→shunt resistor R1→MOSFET (Q2)→reactor L1→AC power supply VS. At this time, the MOSFET (Q1) is always off and the MOSFET (Q2) is always on. It should be noted that the ON operation of the MOSFET (Q2) is started at the timing of the zero cross when the polarity of the AC power supply voltage vs switches from positive to negative. The timing at which the MOSFET (Q2) is turned off is the timing at which the polarity of the AC power supply voltage vs is switched from negative to positive.
By operating the DC power supply device 1 as described above, highly efficient operation becomes possible.

FIGS. 6A to 6D are waveform diagrams of the AC power supply voltage vs, the circuit current is, and the driving pulse of the MOSFET during synchronous rectification.
FIG. 6(a) shows the waveform of the AC power supply voltage vs, and FIG. 6(b) shows the waveform of the circuit current is. FIG. 6(c) shows the driving pulse waveform of the MOSFET (Q1), and FIG. 6(d) shows the driving pulse waveform of the MOSFET (Q2).
As shown in FIG. 6A, the AC power supply voltage vs has a substantially sinusoidal waveform.
As shown in FIG. 6(c), the drive pulse for the MOSFET (Q1) becomes H level when the polarity of the AC power supply voltage vs is positive, and becomes L level when it is negative.
As shown in FIG. 6(d), the drive pulse for the MOSFET (Q2) is opposite to the drive pulse for the MOSFET (Q1). H level.
As shown in FIG. 6B, the circuit current is flows when the AC power supply voltage vs reaches a predetermined amplitude, that is, when the AC power supply voltage vs is larger than the DC voltage Vd.

≪High-speed switching mode≫
Next, a high-speed switching mode (second operation mode) for boosting the DC voltage Vd and improving the power factor will be described.
In this operation mode, the MOSFETs (Q1, Q2) are switching-controlled at a certain switching frequency, the circuit is short-circuited via the reactor L1 (hereinafter referred to as power factor improvement operation), and the short-circuit current (hereinafter, power factor The DC voltage Vd is boosted and the power factor is improved by passing an improved current). As a guideline for the number of switching times, it is preferable to perform switching at least 80 times in a half cycle of the power source, avoiding 2 kHz to 8 kHz where human hearing is sharp. First, the operation when a power factor correction current is passed will be described.

In the case of synchronous rectification in the positive cycle of the AC power supply voltage vs, the current flow is as shown in FIG. 4 and the operation of the MOSFETs (Q1, Q2) is as described above. At this time, as shown in FIG. 6B, the circuit current is is distorted with respect to the power supply voltage. This is because the current flows only when the DC voltage Vd becomes smaller than the AC power supply voltage vs and the characteristics of the reactor L1.
Therefore, the power factor correction current is passed through the circuit a plurality of times to bring the circuit current closer to a sine wave, thereby improving the power factor and reducing the harmonic current.

なお、式（１）においてＩ_spは、力率改善電流ｉｓｐの実効値である。 FIG. 7 is a diagram showing the path of the power factor correction current isp that flows when the MOSFET (Q2) is turned on in a positive cycle of the power supply voltage.
The path of the power factor improvement current isp is in the order of AC power supply VS→reactor L1→MOSFET (Q2)→diode D2→AC power supply VS. At this time, the energy represented by the following formula (1) is stored in the reactor L1. This energy is released to the smoothing capacitor C1, thereby boosting the DC voltage Vd.

Note that I _sp in equation (1) is the effective value of the power factor improvement current isp.

The current flow when synchronous rectification is performed in the negative cycle of the AC power supply voltage vs is as shown in FIG. 5, and the operation of the MOSFETs (Q1, Q2) is as described above.

FIG. 8 is a diagram showing a path when the MOSFET (Q1) is turned on in a negative cycle of the power supply voltage to allow the power factor correction current isp to flow.
The current path is in the order of AC power supply VS->diode D1->MOSFET (Q1)->reactor L1->AC power supply VS. Also at this time, energy is stored in the reactor L1 as described above, and the energy boosts the DC voltage Vd.

FIGS. 9A to 9D are waveform diagrams of the AC power supply voltage vs, the circuit current is, and the drive pulse of the MOSFET when the power factor correction current is passed twice (referred to as two shots). If the number of times the power factor correction current is conducted is two times, this corresponds to the later-described "partial switching mode" instead of the "high-speed switching mode". For simplification, the waveform when the number of conduction times is two will be described.
FIG. 9(a) shows the waveform of the AC power supply voltage vs, and FIG. 9(b) shows the waveform of the circuit current is. FIG. 9(c) shows the driving pulse waveform of the MOSFET (Q1), and FIG. 9(d) shows the driving pulse waveform of the MOSFET (Q2).
As shown in FIG. 9A, the AC power supply voltage vs has a substantially sinusoidal waveform.

As shown in FIG. 9(c), the driving pulse for the MOSFET (Q1) becomes H level when the polarity of the AC power supply voltage vs is positive, and becomes L level pulse twice at a predetermined timing. When the polarity of the AC power supply voltage vs is negative, it becomes L level, and further becomes an H level pulse twice at a predetermined timing.
As shown in FIG. 9(c), the drive pulse for MOSFET (Q2) is inverted from the drive pulse for MOSFET (Q1). This is because the power factor correction operation and synchronous rectification are combined. For example, when the AC power supply voltage vs is of positive polarity, the MOSFET (Q2) is turned on to perform the power factor improvement operation. After that, after the MOSFET (Q1) is turned off, the synchronous rectification operation is performed during the period in which the MOSFET (Q2) is turned on. In this way, by combining the power factor improvement operation and the synchronous rectification operation, it is possible to operate with high efficiency while improving the power factor.

As shown in FIG. 9B, the circuit current is rises when the AC power supply voltage vs is positive and the driving pulse of the MOSFET (Q2) becomes H level, and the AC power supply voltage vs is negative and It rises when the driving pulse of MOSFET (Q1) becomes H level. This improves the power factor.

For example, when the AC power supply voltage vs is positive, the current path during the power factor improvement operation is as shown in FIG. FIG. 2 shows the current path when the MOSFET (Q2) is turned off and the MOSFET (Q1) is turned on to switch to the synchronous rectification operation.

Note that this power factor improvement operation may be combined with the above-described diode rectification operation. That is, when the AC power supply voltage vs is of positive polarity, the current path during the power factor improvement operation is as shown in FIG. After the MOSFET (Q2) is turned off, the current path when the parasitic diode D3 is turned on and switched to the diode rectification operation is as shown in FIG.

FIGS. 10A to 10D are waveform diagrams of AC power supply voltage vs, circuit current is, and MOSFET drive pulse when high-speed switching is performed.
FIG. 10(a) shows the waveform of the AC power supply voltage vs, and FIG. 10(b) shows the waveform of the circuit current is. FIG. 10(c) shows the driving pulse waveform of the MOSFET (Q1), and FIG. 10(d) shows the driving pulse waveform of the MOSFET (Q2).
As shown in FIG. 10(a), the AC power supply voltage vs has a substantially sinusoidal waveform.

In the high-speed switching mode, for example, when the power supply voltage has a positive polarity, the MOSFET (Q2) is turned on and the MOSFET (Q1) is turned off during the power factor improvement operation, thereby causing the power factor improvement current isp to flow. . Next, the MOSFET (Q2) is turned off and the MOSFET (Q1) is turned on. The reason why the MOSFETs (Q1, Q2) are switched between on and off depending on the presence or absence of the power factor improvement operation is that synchronous rectification is performed. In order to simply perform the high-speed switching mode, the MOSFET (Q1) should always be in an off state and the MOSFET (Q2) should be switched at a constant frequency.

However, at this time, if the MOSFET (Q1) is also in an off state when the MOSFET (Q2) is off, the current will flow through the parasitic diode D3 of the MOSFET (Q1). As described above, this parasitic diode has poor characteristics and a large voltage drop, resulting in a large conduction loss. Therefore, in this embodiment, when the MOSFET (Q2) is off, the conduction loss is reduced by turning on the MOSFET (Q1) to perform synchronous rectification.
A circuit current is (instantaneous value) flowing through the DC power supply 1 can be expressed by the following equation (2).

Furthermore, rewriting this formula (2) results in the following formula (3).

Equation (4) shows the relationship between the circuit current is (instantaneous value) and the circuit current effective value Is. The is (instantaneous value) is the value detected by the shunt resistor R1, and the circuit current effective value Is is the value detected by the current detection section 11. FIG.

Transforming the equation (3) and substituting the equation (4) yields the following equation (5).

Assuming that the reciprocal of the step-up ratio is the right side, the following equation (6) is obtained.

Furthermore, the duty d of the MOSFET can be expressed as in Equation (7).

From the above, by controlling Kp×Is shown in equation (6), it is possible to boost the AC power supply voltage effective value Vs a times, and the duty d (duty ratio) of the MOSFET at that time is expressed by the equation ( 7) can be given.

FIG. 11 is a diagram showing the on-duty relationship of drive pulses for MOSFET (Q2) and MOSFET (Q1) in a power supply voltage half cycle (positive polarity). The vertical axis of FIG. 11 indicates the on-duty, and the horizontal axis indicates the half cycle time of the positive polarity power supply voltage.

The on-duty of the drive pulse for the MOSFET (Q1) indicated by the dashed line is proportional to the AC power supply voltage vs. The on-duty of the drive pulse for the MOSFET (Q2) indicated by the two-dot chain line is obtained by subtracting the on-duty of the drive pulse for the MOSFET (Q1) from 1.0.

In FIG. 11, as shown in equation (7), the larger the circuit current is, the smaller the duty d of the drive pulse for the MOSFET (Q2) that performs the switching operation to flow the power factor improving current. The smaller is, the larger the duty d of the drive pulse for the MOSFET (Q2). The duty d of the drive pulse for the MOSFET (Q1) on the side that performs synchronous rectification is opposite to the duty d of the drive pulse for the MOSFET (Q2).
In practice, dead time should be taken into account in order to avoid vertical short circuits.

FIG. 12 is a diagram in which the on-duty of the driving pulse of the MOSFET (Q2) in consideration of the dead time in the power supply voltage half cycle (positive polarity) is added with a solid line. The vertical axis in FIG. 12 indicates the on-duty, and the horizontal axis indicates the half cycle time of the positive polarity of the AC power supply voltage vs.
When a predetermined dead time is given in this way, the duty of the drive pulse for the MOSFET (Q2) is reduced by this dead time.

FIG. 13 is a diagram showing the relationship between the instantaneous value vs of the AC power supply voltage vs and the circuit current is (instantaneous value). The solid line indicates the instantaneous value vs of the AC power supply voltage vs, and the dashed line indicates the instantaneous value of the circuit current is. The horizontal axis of FIG. 13 indicates the half cycle time of the positive polarity power supply voltage.

As shown in FIG. 13, high-speed switching control makes both the instantaneous value vs of the AC power supply voltage vs and the circuit current is (instantaneous value) substantially sinusoidal, thereby improving the power factor.
The duty d _Q2 of MOSFET (Q2) is shown in the following equation (8).

The duty d _Q1 of MOSFET (Q1) is shown in the following equation (9).

Also, looking at the relationship between the power supply voltage and the current, the power factor is in a good state because the circuit current is is controlled to have a sinusoidal waveform. It should be noted that this assumes a state in which the inductance of the reactor L1 is small and there is no current phase lag with respect to the power supply voltage. If the inductance of the reactor L1 is large and the current phase lags behind the voltage phase, the duty d should be set in consideration of the current phase.

FIG. 14 is a diagram showing the duty of the MOSFET (Q2) when the current phase delay due to the reactor L1 is considered when the AC power supply voltage vs is of positive polarity. The vertical axis of FIG. 14 indicates the duty of the MOSFET (Q2), and the horizontal axis indicates the half cycle time of the positive polarity power supply voltage.

The solid line indicates the duty of the MOSFET (Q2) when the current phase delay due to the reactor L1 is not considered. A dashed line indicates the duty of the MOSFET (Q2) when considering the current phase delay due to the reactor L1. By controlling in this way, even if the inductance of the reactor L1 is large, the current can be controlled in a sinusoidal shape.

So far, the case where high-speed switching and synchronous rectification are combined has been described. Note that high-speed switching and diode rectification may be combined as described above. That is, when the AC power supply voltage vs is of positive polarity, the MOSFET (Q1) is always off and only the MOSFET (Q2) is switched at high speed. Even if the control is performed in this way, the effect of improving the power factor can be obtained.

≪Partial switching operation≫
As described above, by performing high-speed switching operation, the circuit current is can be shaped into a sine wave, and a high power factor can be ensured. However, the higher the switching frequency, the greater the switching loss.

As the input to the circuit increases, the harmonic current also increases, making it difficult to satisfy the regulation value for higher-order harmonic currents. Conversely, when the input is small, the harmonic current also becomes small, so there is a case where it is not particularly necessary to secure the power factor. In other words, it can be said that the harmonic current should be reduced by ensuring the optimum power factor while considering the efficiency according to the load conditions.
Therefore, in order to improve the power factor while suppressing an increase in switching loss, a partial switching operation should be performed.

In the partial switching mode (first operation mode), unlike the high-speed switching operation, the power factor improvement operation is performed at a predetermined frequency. This is an operation mode for boosting the DC voltage Vd and improving the power factor by performing an improvement operation. Compared to the high-speed switching operation, the number of times of switching of the MOSFETs (Q1, Q2) is less, so the switching loss can be reduced. As a guideline for the number of switching times, it is preferable to avoid 2 kHz to 8 kHz, where human hearing is sharp, and to perform switching once or more and 20 times or less per half cycle of the power supply.

The partial switching operation will be described below with reference to FIG.
FIGS. 15A to 15D are diagrams showing the relationship between the drive pulse for the MOSFET (Q1), the AC power supply voltage vs, and the circuit current is in the cycle when the AC power supply voltage vs is positive.
FIG. 15(a) shows the AC power supply voltage vs, and FIG. 15(b) shows the circuit current is. FIG. 15(c) shows the drive pulse for MOSFET (Q2), and FIG. 15(d) shows the drive pulse for MOSFET (Q1).
As shown in FIG. 15(a), the AC power supply voltage vs is substantially sinusoidal.
The dashed-dotted line in FIG. 15(b) shows the ideal circuit current is in a substantially sinusoidal shape. At this time, the power factor is most improved.

For example, when a point P1 on the ideal current is considered, the slope at this point is di(P1)/dt. Next, let di(ton1_Q2)/dt be the slope of the current when the MOSFET (Q2) is turned on over time ton1_Q2 from the zero current state. Further, let di(toff1_Q2)/dt be the slope of the current when it is turned off for time toff_Q2 after being turned on for time ton1_Q2. At this time, control is performed so that the average value of di(ton1_Q2)/dt and di(toff1_Q2)/dt is equal to the slope di(P1)/dt at point P1.

Next, similarly to the point P1, the slope of the current at the point P2 is set to di(P2)/dt. Then, let di(ton2_Q2)/dt be the slope of the current when the MOSFET (Q2) is turned on over the time ton2_Q2, and di(toff2_Q2)/dt be the slope of the current when the MOSFET (Q2) is turned off over the time toff2_Q2. . As in the case of point P1, the average value of di(ton2_Q2)/dt and di(toff2_Q2)/dt is made equal to the slope di(P2)/dt at point P2. After that, this process is repeated. At this time, the circuit current is can be approximated to an ideal sine wave as the MOSFET (Q2) switches more times.

The reason why the switching of the MOSFET (Q1) and the MOSFET (Q2) is complementarily switched in this manner is that the partial switching operation and the synchronous rectification operation are combined.
In some cases, partial switching operation and diode rectification operation may be combined.

<<How to switch operation mode 1>>
FIG. 16 shows the operation waveform when the input voltage is 200 V, the inductance value of the reactor is 5.3 mH, the input current is 4 A, and the power consumption is 700 W, and the power is turned on three times (that is, partial switching mode). FIG. 17 shows operation waveforms when the input current is 10A and the power consumption is 1800W. For input currents of 4A and 10A, the 1st to 40th harmonics are as shown in Table 1. Table 1 also lists the regulation values of harmonic current (for example, regulation values according to IEC 61000-3-2).

According to Table 1, as the input current increases, the harmonic current increases and the regulation value of the harmonic current cannot be satisfied. For example, according to Table 1, the third harmonic is approximately 3.864 A when the input current is 10 A, exceeding the regulation value (approximately 2.987 A). Therefore, if the operation mode is switched from the partial switching mode to the high-speed switching mode when the input current (or power consumption) increases, the regulation value of the harmonic current can be satisfied. More specifically, FIG. 18 shows the relationship between power consumption, DC voltage Vd, and operation mode.

In FIG. 18, the DC voltage Vd is lower than √2 times the AC power supply voltage effective value Vs. In this example, converter control unit 18 (see FIG. 1) selects the partial switching mode if power consumption P (total power consumption including DC power supply 1 and load H) is less than predetermined threshold value Pth, When the power consumption P reaches or exceeds the threshold value Pth, the high-speed switching mode is selected. As described above, in the present embodiment, the inductance value of the reactor L1 is 3 to 6 mH, and by adopting this range, even in the partial switching mode, if the load is low, the regulation value of the harmonic current can be satisfied. Satisfied.

Here, the determination as to whether or not the power consumption P is equal to or greater than the threshold value Pth does not necessarily have to be strict. That is, even if it is determined that the power consumption P is "greater than or equal to the threshold value Pth" when the actual power consumption P is slightly lower than the threshold value Pth, no particular problem occurs. Therefore, various methods other than directly measuring the power consumption P can be adopted. For example, "whether or not the effective value of the circuit current is exceeds a predetermined value" detected by the current detection unit 11 is determined, and this determination result is used as the determination result of "whether or not the power consumption P is equal to or greater than the threshold value Pth". can be used in place of

Moreover, the load information detected by the load detection unit 15 can also be used. For example, when the load H is a motor or an inverter, it is determined whether or not the circuit current is equal to or greater than a predetermined value, whether or not the motor current is equal to or greater than a predetermined value, and whether or not the current flowing through the inverter is equal to or greater than a predetermined value. "whether or not the rotational speed of the motor is equal to or higher than a predetermined rotational speed", "whether or not the modulation rate of the inverter (the peak value of the output voltage of the inverter/DC voltage Vd) is equal to or higher than a predetermined modulation rate or not, or "whether the DC voltage Vd is equal to or lower than a predetermined threshold voltage", instead of the determination result of "whether the power consumption P is equal to or higher than the threshold value Pth". , can be used to switch between partial switching mode and fast switching mode. The power consumption P, the circuit current is, the motor current, the current flowing through the inverter, the rotation speed of the motor, the modulation factor of the inverter, the DC voltage Vd, etc., are amounts that increase or decrease according to the increase or decrease of the load. Therefore, these amounts are collectively called "load corresponding amount".

When switching the operation mode from the partial switching mode to the high-speed switching mode, the DC voltage Vd may suddenly rise. This is because the fast switching mode has a higher power factor than the partial switching mode. When the power factor increases, even if the amplitude of the circuit current is is the same as in the partial switching mode, more energy is supplied to the smoothing capacitor C1, and the DC voltage Vd may be boosted abruptly.

In order to avoid such a sudden change in the DC voltage Vd, when switching from the partial switching mode to the high-speed switching mode, it is possible to control the circuit current is to be lower than the normal value (previous value). preferable. A specific example of manipulating the circuit current is is shown in FIGS. 19A and 19B are waveform diagrams of AC power supply voltage vs and circuit current is in partial switching mode and high-speed switching mode, and the peak value of circuit current is is indicated by a dashed line. As shown, the peak value in the fast switching mode is lower than the peak value in the partial switching mode. In this way, at the moment of switching from the partial switching mode to the high-speed switching mode, the on-time is adjusted so that the peak of the circuit current is in the high-speed switching mode is lower than the circuit current is in the partial switching mode. By switching, it is possible to suppress fluctuations in the DC voltage Vd.

Similarly, when switching from high-speed switching to partial switching, contrary to the above-described case, it is preferable to adjust the ON time so that the amplitude of the circuit current is becomes larger than the normal value (previous value). This makes it possible to prevent a drop in the DC voltage Vd.
Furthermore, by switching each control at the timing of the zero crossing of the power supply voltage, it is possible to stably switch the control.
That is, the control unit (M)
Before switching the operation mode from the first operation mode (partial switching mode) to the second operation mode (high-speed switching mode), the peak value of the circuit current (is) flowing from the AC power supply (VS) is higher than the previous value. a function to control to be low,
Before switching the operation mode from the second operation mode (high-speed switching mode) to the first operation mode (partial switching mode), the peak value of the circuit current (is) flowing from the AC power supply (VS) is higher than the previous value. and a function of controlling to increase.

<<How to switch operation mode 2>>
When the load H is a high load, the DC voltage Vd may be increased (particularly higher than √2 times the AC power source voltage effective value Vs). In such a case, it is preferable to select the high-speed switching mode as the operation mode. The reason for this is that if the partial switching mode is employed in a state where the DC voltage Vd is higher than √2 times the effective value Vs of the AC power source voltage, the harmonic current will increase. FIG. 20 shows an example of the relationship between power consumption, DC voltage Vd, and operation mode when DC voltage Vd is changed according to power consumption.

In FIG. 20, when the power consumption P is equal to or less than a predetermined value P3, the DC voltage Vd is equal to or less than √2·Vs. Then, when the power consumption P reaches a predetermined value P4 or higher, which is higher than the predetermined value P3, the DC voltage Vd reaches a predetermined value higher than √2·Vs. When the power consumption P is in the range of the predetermined values P3 to P2, the DC voltage Vd increases monotonically as the power consumption P increases.

In FIG. 20, a threshold value Pth, which is a boundary value for switching between operation modes (partial switching mode and high-speed switching mode), is lower than a predetermined value P3. From this, it can be seen that the high-speed switching mode is always adopted when the DC voltage Vd is higher than √2·Vs. As described above, in the present embodiment, the reactor L1 is 3 to 6 mH, and the threshold value Pth should be set within a range in which the standard value of the harmonic current can be satisfied in the partial switching mode by the reactor L1. As a result, the standard value of the harmonic current can be satisfied while suppressing the inductance value of the reactor L1 to 3 to 6 mH.

≪How to switch operation mode 3≫
Efficiency can be increased by adopting the synchronous rectification mode when the load H is a low load. Therefore, it is preferable to allow the synchronous rectification mode to be used when the load is low. FIG. 21 shows an example of the relationship between power consumption, DC voltage Vd, and operation mode when realizing this.

In FIG. 21, similarly to FIG. 20, if the power consumption P is equal to or less than the predetermined value P3, the DC voltage Vd is equal to or less than √2·Vs. Then, when the power consumption P reaches a predetermined value P4 or higher, which is higher than the predetermined value P3, the DC voltage Vd reaches a predetermined value higher than √2·Vs. When the power consumption P is in the range of the predetermined values P3 to P2, the DC voltage Vd increases monotonically as the power consumption P increases.

Also in the example of FIG. 21, the threshold Pth2, which is the boundary value for switching between the partial switching mode and the high-speed switching mode, is lower than the predetermined value P3. Furthermore, in the example of FIG. 21, the threshold value Pth1, which is even lower than the threshold value Pth2, is the boundary value for switching between the synchronous rectification mode and the partial switching mode. That is, if P<Pth1, the synchronous rectification mode is selected, if Pth1≦P<Pth2, the partial switching mode is selected, and if Pth2≦P, the high-speed switching mode is selected. In this example, if partial switching mode and fast switching mode are employed, synchronous rectification operation may or may not be performed. Also, a diode rectification mode may be applied instead of the synchronous rectification mode.

18, 20, and 21, the value of the DC voltage Vd shown in each example is the value in a steady state, and there are It does not include transient fluctuations due to fluctuations, etc.

[Operation of air conditioner and DC power supply]
FIG. 22 is a front view of an indoor unit, an outdoor unit, and a remote controller of an air conditioner according to this embodiment.
As shown in FIG. 22, the air conditioner A is a so-called room air conditioner, and includes an indoor unit 100, an outdoor unit 200, a remote controller Re, and a DC power supply (not shown) (see FIG. 1). The indoor unit 100 and the outdoor unit 200 are connected by a refrigerant pipe 300, and the room in which the indoor unit 100 is installed is air-conditioned by a well-known refrigerant cycle. Also, the indoor unit 100 and the outdoor unit 200 exchange information with each other via a communication cable (not shown). Furthermore, it is connected to the outdoor unit 200 by wiring (not shown) and supplied with AC voltage via the indoor unit 100 . The DC power supply device is provided in the outdoor unit 200 and converts AC power supplied from the indoor unit 100 side into DC power.

The remote controller Re is operated by the user to transmit an infrared signal to the remote controller transmitter/receiver Q of the indoor unit 100 . The content of this infrared signal is a command such as a request for operation, a change in set temperature, a timer, a change in operation mode, and a request to stop. The air conditioner A performs air conditioning operations such as a cooling mode, a heating mode, and a dehumidification mode based on these infrared signal commands. In addition, the indoor unit 100 transmits data such as room temperature information, humidity information, and electricity bill information from the remote controller transmitter/receiver Q to the remote controller Re.

The operation flow of the DC power supply installed in the air conditioner A will be described. A DC power supply device reduces harmonic current and boosts a DC voltage Vd by highly efficient operation and an improved power factor. As described above, there are four operation modes: diode rectification mode, synchronous rectification mode, high-speed switching mode, and partial switching mode.

For example, if the inverter or motor of the air conditioner A is considered as the load H, the DC power supply should be operated in the synchronous rectification mode if the load is small and efficiency-oriented operation is desired.

When the load increases and it is desired to boost the voltage and secure the power factor, it is preferable to adopt the high-speed switching mode as the operation mode of the DC power supply. Also, when the load is not so large as in the case of rated operation of the air conditioner A, but it is desired to increase the voltage and secure the power factor, it is preferable to adopt the partial switching mode. Note that the partial switching mode and the high-speed switching mode may be combined with either diode rectification or synchronous rectification.

As described above, when the load H is a motor or an inverter, the parameters representing the magnitude of the load include, in addition to the power consumption P, the current flowing through the inverter or motor, the modulation rate of the inverter, the rotation speed of the motor, and the circuit current. is or DC voltage Vd or the like can be adopted.

For example, if the magnitude of the load is equal to or less than the threshold #1 (corresponding to the threshold Pth1 in FIG. 21), the DC power supply is operated in the synchronous rectification mode, and the threshold #1 exceeds the threshold #2 (to the threshold Pth2 in FIG. 21). Countermeasure) In the following cases, it is preferable to operate in a partial switching mode (combining either diode rectification or synchronous rectification). Also, if the magnitude of the load exceeds threshold #2, the DC power supply should be operated in a fast switching mode (either a combination of diode rectification or synchronous rectification).

As described above, the DC power supply can reduce the harmonic current while performing highly efficient operation by switching to the optimum operation mode according to the operating range of the air conditioner A.

In this embodiment, an example using super junction MOSFETs as MOSFETs (Q1, Q2) has been described. By using switching elements using SiC (Silicon Carbide)-MOSFETs or GaN (Gallium nitride) as the MOSFETs (Q1, Q2), it is possible to achieve even higher efficiency operation.

In this way, by providing the air conditioner A with the DC power supply device of the present embodiment, the air conditioner A can be configured to be small and inexpensive, has high energy efficiency (that is, APF), and is highly reliable. can. Even if the DC power supply device of this embodiment is installed in equipment other than an air conditioner, it is possible to provide a highly efficient and highly reliable equipment.

[Modification]
The present invention is not limited to the embodiments described above, and various modifications are possible. The above-described embodiments are illustrated for easy understanding of the present invention, and are not necessarily limited to those having all the described configurations. Also, part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Moreover, it is possible to delete part of the configuration of each embodiment, or to add or replace other configurations. Possible modifications to the above embodiment are, for example, the following.

The DC power supply 1 of the above embodiment may be modified like a DC power supply 1a shown in FIG. A rectifier circuit 10a in FIG. 23 has diodes D1 to D4 forming a full-wave rectifier circuit. These are independent diodes, not parasitic diodes. MOSFETs (Q3, Q4) are connected in parallel to the diodes D3, D4. Also in this modification, the reactor L1 is 3 to 6 mH. According to this modification, the loss in the diode rectification mode can be made smaller than in the above embodiment.

Further, the DC power supply 1 may be modified like a DC power supply 1b shown in FIG. A rectifier circuit 10b in FIG. 24 has diodes D1 to D4 forming a full-wave rectifier circuit. Furthermore, diodes D5 to D8 constituting another full-wave rectifier circuit are connected between the connection points N1 and N2, and the switching element Q5 is connected to the output terminal of the latter full-wave rectifier circuit. By switching the on/off state of the switching element Q5, the short/open state of the connection points N1 and N2 can be switched. Also in this modification, the reactor L1 is 3 to 6 mH. According to this modified example, the number of switching elements can be reduced more than the above embodiment.

Further, the DC power supply 1 may be modified like a DC power supply 1c shown in FIG. In this modified example, it is assumed that the AC power supply VS has an effective value of 100 to 115V. In FIG. 25, smoothing capacitors C2 and C3 are connected in series and their connection point is connected to a connection point N1 between diodes D1 and D2. Thereby, the rectifier circuit 10c included in this modified example constitutes a voltage doubler rectifier circuit. Also in this modification, the reactor L1 is 3 to 6 mH.
23 to 25, the configurations of the omitted parts are the same as those in FIG.

Furthermore, high-speed trr type elements are used as the MOSFETs (Q1, Q2), and high-efficiency operation is possible by specifically using elements with a trr of 300 ns or less.

Also, the smaller the on-resistance of the MOSFETs (Q1, Q2), the higher the synchronous rectification effect. Specifically, by setting the on-resistance to 0.01Ω or less, high-efficiency operation is possible.

Some or all of the above configurations, functions, processing units, processing means, etc. may be realized by hardware such as integrated circuits. Each of the above configurations, functions, etc. may be realized by software by a processor interpreting and executing a program for realizing each function. Information such as programs, tables, and files that implement each function can be placed in a recording device such as a memory or hard disk, or a recording medium such as a flash memory card or DVD (Digital Versatile Disk).

In each embodiment, control lines and information lines indicate those considered necessary for explanation, and not all control lines and information lines are necessarily indicated on the product. In fact, it may be considered that almost all configurations are interconnected.

<Appendix>
The contents of the claims as originally filed in the parent application of the parent application of this application are as follows.
[Claim 1]
a reactor connected to an AC power supply that outputs an AC voltage with an effective value of 100 V or more and 230 V or less;
A rectifying circuit that converts the AC voltage to a DC voltage and applies it to a load while performing switching to appropriately short-circuit the reactor to the AC power supply;
Either a first operation mode in which switching is performed 1 time or more and 20 times or less in a half period of the AC voltage or a second operation mode in which switching is performed 80 times or more in a half period of the AC voltage. a control unit that selects a mode based on a comparison result between a load correspondence amount, which is an amount that increases or decreases according to an increase or decrease in the load, and a predetermined threshold;
and an inductance value of the reactor is 3 mH or more and 6 mH or less.

[Claim 2]
further comprising a smoothing capacitor connected between the rectifier circuit and the load for smoothing the DC voltage;
The rectifier circuit has first and second diodes and first and second switching elements,
The first switching element has a third diode that is a parasitic diode and has a saturation voltage lower than the forward voltage drop of the third diode,
The second switching element has a fourth diode that is a parasitic diode and has a saturation voltage lower than the forward voltage drop of the fourth diode,
the cathode of the first diode and one end of the first switching element are connected to the positive electrode side of the smoothing capacitor;
The anode of the first diode and the cathode of the second diode are connected to one end side of the AC power supply,
the other end of the first switching element and one end of the second switching element are connected to the other end of the AC power supply via the reactor,
the anode of the second diode and the other end of the second switching element are connected to the negative electrode side of the smoothing capacitor;
The control unit is configured in an operation mode in which the first switching element and the second switching element are complementarily turned on in synchronization with the polarity of the AC voltage, or in which both the first and second switching elements are turned off. At least one of the operation modes in which rectification is performed by the first to fourth diodes is set as a third operation mode, and one of the first to third operation modes is selected according to the load correspondence amount. 2. The DC power supply device according to claim 1, further comprising a function of selecting one of the operation modes.

[Claim 3]
The control unit
A function of controlling the peak value of the circuit current flowing from the AC power supply to be lower than the previous value before switching the operation mode from the first operation mode to the second operation mode;
and a function of controlling the peak value of the circuit current flowing from the AC power supply to be higher than the previous value before switching the operation mode from the second operation mode to the first operation mode. 3. The DC power supply device according to claim 1 or 2.

[Claim 4]
When the DC voltage is more than √2 times the effective value of the AC voltage,
The DC power supply device according to any one of claims 1 to 3, wherein the second operation mode is selected as the operation mode.

[Claim 5]
The control unit
Having a zero-cross determination unit that detects the timing of the zero-cross of the AC voltage,
switching the operation mode from the first operation mode to the second operation mode or from the second operation mode to the first operation mode at the timing of the zero cross detected by the zero cross determination unit; The DC power supply device according to any one of claims 1 to 4, characterized by the following.

[Claim 6]
The load includes an inverter and a motor,
The load correspondence amount is any one of power consumption, circuit current flowing from the AC power supply, current flowing in the motor, current flowing in the inverter, rotation speed of the motor, modulation rate of the inverter, or DC voltage. The DC power supply device according to any one of claims 1 to 5, characterized in that:

[Claim 7]
the rectifier circuit includes a plurality of diodes for converting the AC voltage to the DC voltage;
The direct-current power supply device according to any one of claims 1 to 6, wherein at least part of the diodes are SiC-Schottky barrier diodes.

[Claim 8]
The rectifier circuit includes a plurality of switching elements for converting the AC voltage to the DC voltage,
The DC power supply according to any one of claims 1 to 7, wherein at least part of the switching elements are switching elements using any one of superjunction MOSFET, SiC-MOSFET, or GaN. Device.

[Claim 9]
Equipped with the DC power supply device according to any one of claims 1 to 8,
An air conditioner characterized by:

1, 1a, 1b DC power supply device 10, 10a, 10b rectifier circuit 14 zero cross determination unit H load M control block (control unit)
P power consumption C1 smoothing capacitors D1 to D4 diodes (first to fourth diodes)
H Load L1 Reactor M Control block (control unit)
P Power consumption (load capacity)
Q1, Q2 MOSFETs (first and second switching elements)
VS AC power supply Vd DC voltage Vs AC power supply voltage effective value (rms value)
is circuit current (circuit current)
vs AC power supply voltage (AC voltage)

Claims (6)

a reactor connected to an AC power supply that outputs an AC voltage with an effective value of 100 V or more and 230 V or less;
A rectifying circuit that converts the AC voltage to a DC voltage and applies it to a load while performing switching to appropriately short-circuit the reactor to the AC power supply;
Either a first operation mode in which switching is performed 1 time or more and 20 times or less in a half period of the AC voltage or a second operation mode in which switching is performed 80 times or more in a half period of the AC voltage. a control unit that selects a mode based on a comparison result between a load correspondence amount, which is an amount that increases or decreases according to an increase or decrease in the load, and a predetermined threshold;
A function of controlling the amplitude of the circuit current flowing from the AC power supply to be larger than the previous value when the operation mode is switched from the second operation mode to the first operation mode. and a DC power supply. 2. The circuit according to claim 1, further comprising a function of adjusting the ON time of the circuit current flowing from the AC power supply when switching the operation mode from the second operation mode to the first operation mode. A DC power supply as described. 3. The DC power supply device according to claim 1, wherein the second operation mode is selected as the operation mode when the DC voltage is made equal to or greater than √2 times the effective value of the AC voltage. . The DC power supply device according to any one of claims 1 to 3, wherein an inductance value of the reactor is 3 mH or more and 6 mH or less. The load includes an inverter and a motor,
The load correspondence amount is any one of power consumption, circuit current flowing from the AC power supply, current flowing in the motor, current flowing in the inverter, rotation speed of the motor, modulation rate of the inverter, or DC voltage. The direct-current power supply device according to any one of claims 1 to 4, characterized in that: Equipped with the DC power supply device according to any one of claims 1 to 5,
An air conditioner characterized by:

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