JP2019122088A - Three-phase boosting rectification unit, inverter device, air conditioner, control method of three-phase boosting rectification unit, and program - Google Patents

Abstract

To provide a three-phase boosting rectification unit which can operate for an elongated life with simple control.SOLUTION: A three-phase boosting rectification unit 1A includes: a rectification circuit 10, a positive electrode side main diode Da, a negative electrode side main diode Db, a positive electrode side switching element 11a, and a negative electrode side switching element 11b, and comprises: a booster circuit 11 capable of outputting an intermediate voltage; a positive electrode side capacitor Ca; and a negative electrode side capacitor Cb. The three-phase boosting rectification unit 1A further comprises a booster circuit control unit 12 for alternately switching between a first mode in which a first switching control signal is transmitted to the positive electrode side switching element 11a and a second switching control signal is transmitted to the negative electrode side switching element 11b and a second mode in which a second switching control signal is transmitted to the positive electrode side switching element 11a and the first switching control signal is transmitted to the negative electrode side switching element 11b.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a control method and program of a three-phase boost rectification unit, an inverter device, an air conditioner, and a three-phase boost rectification unit.

  The air conditioner (air conditioner) mainly includes an inverter device that generates load (motor) driving AC power for freely driving a motor of the compressor. A well-known inverter device temporarily converts a three-phase AC voltage input from a commercial power supply (for example, AC 200 V three-phase AC power supply) into a DC voltage through a rectifier circuit (converter), and desires the DC power. Converted to AC power for motor drive.

  For example, Patent Document 1 discloses a three-phase power converter of an air conditioner having a boost circuit operable in a boost mode.

Republished WO2015 / 033345

The three-phase power converter disclosed in Patent Document 1 controls the switching element so as to suppress the voltage unbalance between the two capacitors in order to extend the life.
However, since the three-phase power converter disclosed in Patent Document 1 is controlled by detecting the output voltages of the two capacitors, the control becomes complicated.

  An object of the present invention is to provide a control method and program of a three-phase boost rectification unit, an inverter device, an air conditioner, and a three-phase boost rectification unit capable of extending the life of a three-phase boost rectification unit with simple control. It is in.

  The three-phase boost rectifier unit according to the first aspect rectifies a three-phase AC voltage supplied from a three-phase AC power supply, and outputs a rectified voltage between a positive electrode output line and a negative electrode output line; A positive side main diode having an anode connected to the positive output line, a negative side main diode having a cathode connected to the negative output line, and a positive side switching element connected between a connection point and the positive output line And a negative electrode side switching element connected between the connection point and the negative electrode output line, and an additional voltage is a single voltage which is a DC voltage equivalent to one time of the amplitude of the three-phase AC voltage. A booster circuit capable of outputting an intermediate voltage added to a DC voltage, a positive side capacitor connected between the cathode of the positive side main diode and the connection point, the connection point, and the anode of the negative side main diode Connected between A second switching control capable of sending a first switching control signal capable of charging the negative electrode side capacitor and the negative electrode side capacitor to the positive electrode side switching element, and charging the positive voltage side direct current voltage on the positive electrode side capacitor; A first mode for sending a signal to the negative side switching element and a second mode for sending the second switching control signal to the positive side switching element and a first switching control signal to the negative side switching element And a booster circuit control unit for switching to

  The three-phase boost rectification unit according to the second aspect is the three-phase boost rectification unit according to the first aspect, wherein the boost circuit control unit switches each time the first mode and the second mode are activated.

  In the three-phase boost rectification unit according to the third aspect, the boost circuit control unit switches whether to send the first switching control signal to the positive electrode side switching element or to send the first switching control signal to the negative electrode side switching element. The three-phase boost rectification unit according to the first or second aspect, further comprising: a switching unit that switches whether to send a second switching control signal to the negative electrode side switching element or to send it to the positive electrode side switching element.

  In the inverter device of the fourth aspect, the load is driven as desired by the three-phase boost rectification unit according to any one of the first to third aspects and a DC voltage output from the three-phase boost rectification unit. And an inverter circuit for converting the load driving AC voltage into the load driving AC voltage.

  An air conditioner according to a fifth aspect comprises the inverter device according to the fourth aspect, and a motor rotationally driven based on the load driving AC voltage output from the inverter circuit as the load. .

  Further, in the control method of the three-phase boost rectification unit of the sixth aspect, the three-phase AC voltage supplied from the three-phase AC power supply is rectified, and the rectified voltage is output between the positive electrode output line and the negative electrode output line A positive side main diode whose anode is connected to the positive side output line, a negative side side main diode whose cathode is connected to the negative side output line, a connection point between the connection point and the positive side output line A positive voltage side switching element, and a negative electrode side switching element connected between the connection point and the negative electrode output line, and an additional voltage is a direct current voltage equivalent to one time the amplitude of the three phase alternating current voltage And a positive side capacitor connected between the cathode of the positive side main diode and the connection point, and the connection point and the negative side. With the anode of the main diode A control method of a three-phase boost rectifier unit comprising: a negative electrode side capacitor connected between: a first switching control signal capable of charging the additional voltage to the negative electrode side capacitor is sent to the positive electrode side switching element; Implementing a first mode for sending a second switching control signal capable of charging the positive voltage side DC voltage to the positive electrode side capacitor to the negative electrode side switching element; and using the second switching control signal as the positive electrode side switching element And alternately performing the second mode of sending and sending the first switching control signal to the negative switching element.

  The program according to the seventh aspect rectifies a three-phase AC voltage supplied from the three-phase AC power supply, and outputs a rectified voltage between the positive electrode output line and the negative electrode output line, A positive side main diode having an anode connected to the output line, a negative side main diode having a cathode connected to the negative output line, and a positive side switching element connected between a connection point and the positive output line; A single voltage DC voltage having a negative voltage side switching element connected between the connection point and the negative electrode output line, wherein the additional voltage is a DC voltage equivalent to 1 time of the amplitude of the three phase AC voltage Between a positive electrode capacitor connected between the cathode of the positive main diode and the connection point, and between the connection node and the anode of the negative main diode. Negative electrode connected to And sending a first switching control signal capable of charging the additional voltage to the negative electrode side capacitor to the positive electrode side switching element, and providing the single-voltage DC voltage to the positive electrode side. A first mode for sending a second switching control signal capable of charging a capacitor to the negative electrode side switching element, and sending the second switching control signal to the positive electrode side switching element, the first switching control signal for the negative electrode side switching element Function as a step-up circuit control unit that alternately switches between the second mode of sending and the second mode of sending.

  According to one aspect of the present invention, it is possible to extend the life of the three-phase boost rectification unit with simple control.

It is a figure showing the circuit composition of the inverter device concerning an embodiment. It is a figure showing functional composition (1st mode) of a booster circuit control part concerning an embodiment. It is a figure which shows the function structure (2nd mode) of the booster circuit control part which concerns on embodiment. It is a figure which shows the relationship of each switching control signal which the voltage booster circuit control part which concerns on embodiment outputs. It is a figure which shows the operation | movement at the time of 1st mode of the voltage booster circuit which concerns on embodiment. It is a figure which shows the operation | movement at the time of 2nd mode of the voltage booster circuit which concerns on embodiment. It is a flowchart of the control method of the three phase boost rectification unit of embodiment.

Embodiment
Hereinafter, a three-phase boost and rectification unit according to an embodiment of the present invention and an inverter apparatus including the three-phase boost and rectification unit will be described in detail with reference to FIGS. 1 to 6.

(Circuit configuration of inverter device)
The inverter device 1 is mounted on an outdoor unit of an air conditioner (air conditioner) 90. Inverter device 1 outputs a load driving AC voltage (three-phase AC voltage) according to a separately input rotational speed command to a three-phase AC motor (motor 4) for driving the compressor of the outdoor unit. Do. The inverter device 1 rotationally drives the three-phase AC motor (motor 4), which is a load, at a desired number of revolutions, based on the load driving AC voltage.
The inverter device 1 converts the three-phase AC voltage supplied from the three-phase AC power supply 3 which is a commercial power source into the load driving AC voltage and outputs it. Here, the three-phase AC power supply 3 is, for example, an AC voltage of 200 V AC (effective value 200 V) and a frequency of 50 Hz (or 60 Hz), and three phases consisting of R phase, S phase, and T phase different from each other by 120 °. Output the AC voltage of the phase. Hereinafter, the AC voltage of each phase which the three-phase AC power supply 3 outputs is also described as “R-phase AC voltage”, “S-phase AC voltage”, and “T-phase AC voltage”, respectively.

  As shown in FIG. 1, the inverter device 1 includes a three-phase boost rectifier unit 1A, an inverter circuit 20, and an inverter circuit control unit 21.

The three-phase boost rectifier unit 1A rectifies the three-phase AC voltage supplied from the three-phase AC power supply 3 and outputs "DC voltage Vdc". A DC voltage Vdc which is an output voltage of the three-phase boost rectification unit 1A is output between the positive output terminal Qa and the negative output terminal Qb shown in FIG.
The three-phase boost rectifier unit 1A according to the present embodiment has a function as a boost rectifier circuit that outputs a voltage larger than the maximum value of the input three-phase AC voltage.

The inverter circuit 20 converts the DC voltage Vdc output from the three-phase boost rectification unit 1A into a load driving AC voltage for driving the motor 4 to rotate. The inverter circuit 20 includes three pairs of two switching elements connected in series between the positive output terminal Qa and the negative output terminal Qb. Here, the switching element is, for example, a power transistor such as an insulated gate bipolar transistor (IGBT). Each pair of switching elements connected in series is provided corresponding to each of three phases for rotationally driving a three-phase AC motor (motor 4).
The inverter circuit 20 further includes a motor current detection unit 22.
The motor current detection unit 22 detects a current (motor current) to be returned to the three-phase boost rectification unit 1A. The motor current detection unit 22 outputs the detection result of the detected motor current to the inverter circuit control unit 21 as a detection signal.

The inverter circuit control unit 21 is a control IC (a so-called microcomputer or the like) that controls on / off of each switching element constituting the inverter circuit 20.
The rotation number command is input to the inverter circuit control unit 21 from the host device. The inverter circuit control unit 21 receives a detection signal of the motor current from the motor current detection unit 22.
While monitoring the motor current, the inverter circuit control unit 21 drives the inverter circuit 20 so that the rotational speed of the motor 4 becomes the rotational speed indicated by the rotational speed command. Here, the inverter circuit control unit 21 controls the inverter circuit 20 based on generally known PWM (Pulse Width Modulation) control.

(Configuration of three-phase boost rectifier unit)
As shown in FIG. 1, the three-phase boost rectification unit 1A includes a rectification circuit 10, a boost circuit 11, and a boost circuit control unit 12. The three-phase boost rectification unit 1A further includes a reactor L and two capacitors (positive electrode side capacitor Ca and negative electrode side capacitor Cb).

The rectifier circuit 10 rectifies the three-phase AC voltage supplied from the three-phase AC power supply 3 and outputs it as a rectified voltage Vac.
Under control of the booster circuit control unit 12, the booster circuit 11 can output a voltage larger than the maximum value of three-phase AC voltages input from the three-phase AC power supply 3 as a DC voltage Vdc.
The rectifier circuit 10 and the booster circuit 11 are connected to each other on the positive electrode side via the reactor L by the positive electrode output line α. The rectifier circuit 10 and the booster circuit 11 are further connected to each other at the negative electrode side by the negative electrode output line β.

The reactor L smoothes the current flowing to the positive electrode output line α.
In the following description, the positive electrode output line α is a line in which the first positive electrode output line α1 and the second positive electrode output line α2 are connected in series via the reactor L.
Therefore, the rectifier circuit 10 outputs the rectified voltage Vac between the first positive electrode output line α1 and the negative electrode output line β.

  The booster circuit 11 includes a positive side main diode Da, a negative side main diode Db, a positive side switching element 11a, and a negative side switching element 11b.

The two capacitors (positive electrode side capacitor Ca and negative electrode side capacitor Cb) are connected in series between the outputs of the booster circuit 11.
Specifically, the positive electrode side capacitor Ca is connected between the cathode of the positive electrode side main diode Da and the connection point N. The negative electrode side capacitor Cb is connected between the anode of the negative electrode side main diode Db and the connection point N.
In the present embodiment, although the positive electrode side capacitor Ca and the negative electrode side capacitor Cb have the same capacitance value in order to simplify the description, they may have different capacitance values.

(Rectifier circuit)
The rectifier circuit 10 will be described in detail.
The rectifier circuit 10 has three input terminals (R-phase input) corresponding to each phase of three-phase AC voltages (R-phase AC voltage, S-phase AC voltage and T-phase AC voltage) supplied from the three-phase AC power supply 3 Input from each of the terminal QR, the S-phase input terminal QS, and the T-phase input terminal QT) and rectified.

Each of the R-phase AC voltage, the S-phase AC voltage, and the T-phase AC voltage oscillates with a period Tc while being out of phase with each other by 120 °.
The rectifying circuit 10 includes six rectifying diodes (positive side R-phase rectifying diode 10Ra, negative side R-phase rectifying diode 10Rb, positive side S-phase rectifying diode 10Sa, negative side S-phase rectifying diode 10Sb, positive side T-phase rectifying diode 10Ta and It is comprised by negative electrode side T phase rectification diode 10Tb).

  The positive side R-phase rectifier diode 10Ra and the negative side R-phase rectifier diode 10Rb of the rectifier circuit 10 rectify the R-phase AC voltage input from the three-phase AC power supply 3 through the R-phase input terminal QR. Specifically, the positive electrode side R phase rectification diode 10Ra is connected in the forward direction from the R phase input terminal QR to the first positive electrode output line α1. The negative electrode side R phase rectification diode 10Rb is connected in the forward direction from the negative electrode output line β to the R phase input terminal QR.

  The positive side S-phase rectifier diode 10Sa and the negative side S-phase rectifier diode 10Sb of the rectifier circuit 10 rectify the S-phase AC voltage input from the three-phase AC power supply 3 through the S-phase input terminal QS. Specifically, the positive side S-phase rectifying diode 10Sa is connected in the forward direction from the S-phase input terminal QS to the first positive output line α1. The negative side S-phase rectifier diode 10Sb is connected in the forward direction from the negative output line β to the S-phase input terminal QS.

  The positive side T-phase rectifier diode 10Ta and the negative side T-phase rectifier diode 10Tb of the rectifier circuit 10 rectify the T-phase AC voltage input from the three-phase AC power supply 3 through the T-phase input terminal QT. Specifically, the positive side T-phase rectifying diode 10Ta is connected in the forward direction from the T-phase input terminal QT to the first positive output line α1. Further, the negative electrode side T-phase rectifying diode 10Tb is connected in the forward direction from the negative electrode output line β to the T-phase input terminal QT.

(Boost circuit)
The booster circuit 11 will be described in detail.
In the present embodiment, the booster circuit 11 can operate in the “boost mode”. In the "step-up mode", a DC voltage equivalent to one time the amplitude of the three-phase AC voltage input from the three-phase AC power supply 3 is used as the DC voltage Vdc which is the output voltage of the three-phase boost rectifier unit 1A. The operation of outputting a voltage larger than the voltage and smaller than the DC voltage equivalent to twice the amplitude of the three-phase AC voltage is referred to.
Here, in the following description, the DC voltage Vdc corresponding to the amplitude of the three-phase AC voltage is described as “single-voltage DC voltage Vdc1”, and is larger than the DC voltage equivalent to one time the amplitude of the three-phase AC voltage, A DC voltage Vdc smaller than a DC voltage equivalent to twice the amplitude of the three-phase AC voltage is described as an “intermediate voltage Vm” to distinguish (Vdc1 <Vm <2 · Vdc1). For example, when the three-phase AC power supply 3 outputs an AC voltage of 200 V AC, the single-voltage DC voltage Vdc1 is 20012 V, and the intermediate voltage Vm is larger than 200√2 V and smaller than 400√2 V.

  Therefore, by operating in the step-up mode, the step-up circuit 11 can output the intermediate voltage Vm obtained by adding the additional voltage Vad to the first boosted DC voltage Vdc1. In the present embodiment, the additional voltage Vad is smaller than the single-voltage DC voltage Vdc1.

The positive main diode Da is connected in the forward direction from the positive output line α of the rectifier circuit 10 to the positive capacitor Ca. Specifically, the anode of the positive electrode side main diode Da is connected to the second positive electrode output line α2, and the cathode of the positive electrode side main diode Da is connected to the positive electrode side capacitor Ca.
The negative main electrode Db is connected in the forward direction from the negative capacitor Cb to the negative output line β of the rectifier circuit 10. Specifically, the anode of the negative electrode side main diode Db is connected to the negative electrode side capacitor Cb, and the cathode of the negative electrode side main diode Db is connected to the negative electrode output line β.

The positive electrode side switching element 11a and the negative electrode side switching element 11b are each a power transistor.
The positive electrode side switching element 11a is connected between the positive electrode output line α (the second positive electrode output line α2) and the connection point N. The negative electrode side switching element 11 b is connected between the negative electrode output line β and the connection point N.
The positive side switching element 11 a and the negative side switching element 11 b are on / off controlled by a switching control signal output from the booster circuit control unit 12.

In the case of this embodiment, the positive electrode side switching element 11a and the negative electrode side switching element 11b are IGBTs, respectively.
In this case, the collector of the positive electrode side switching element 11a is connected to the second positive electrode output line α2, and the emitter of the positive electrode side switching element 11a is connected to the connection point N. Furthermore, the emitter of the negative electrode side switching element 11b is connected to the negative electrode output line β, and the collector of the negative electrode side switching element 11b is connected to the connection point N.
The switching control signal is applied from the step-up circuit control unit 12 to the gate of the positive electrode side switching element 11a, whereby the positive electrode side switching element 11a is on / off controlled.
Similarly, the switching control signal is applied from the step-up circuit control unit 12 to the gate of the negative electrode side switching element 11b, whereby the negative electrode side switching element 11b is on / off controlled.

(Boost circuit controller)
The booster circuit control unit 12 will be described in detail.
The booster circuit control unit 12 is a control IC (a so-called microcomputer or the like) that controls the booster circuit 11.
As shown in FIGS. 2 and 3, the booster circuit control unit 12 functionally includes a first switching signal generation unit 12a, a second switching signal generation unit 12b, and a switching unit 12c.
The booster circuit controller 12 can operate in the first mode or the second mode.
Whether the step-up circuit control unit 12 operates in the first mode or the second mode may be set by a command in the step-up circuit control unit 12 or a command from the outside of the step-up circuit control unit 12 It may be set.
The first switching signal generator 12a generates a first switching control signal SGa capable of charging the additional voltage Vad to the positive electrode side capacitor Ca or the negative electrode side capacitor Cb.
The second switching signal generation unit 12b generates a second switching control signal SGb capable of charging the positive double-sided DC voltage Vdc1 to the positive electrode side capacitor Ca or the negative electrode side capacitor Cb.

In the first mode, the booster circuit control unit 12 sends the first switching control signal SGa to the positive electrode side switching element 11 a to charge the negative electrode side capacitor Cb with the additional voltage Vad.
Furthermore, in the first mode, the booster circuit control unit 12 sends the second switching control signal SGb to the negative electrode side switching element 11b to charge the positive electrode side capacitor Ca with the single-voltage DC voltage Vdc1.

In the second mode, the booster circuit control unit 12 sends the second switching control signal SGb to the positive electrode side switching element 11a to charge the negative electrode side capacitor Cb with the single-voltage DC voltage Vdc1.
Furthermore, in the second mode, the booster circuit control unit 12 sends the first switching control signal SGa to the negative electrode side switching element 11b to charge the positive electrode side capacitor Ca with the additional voltage Vad.

  The booster circuit control unit 12 switches the first mode and the second mode alternately. The switching timing may be set inside the booster circuit control unit 12 or may be set from outside the booster circuit control unit 12. In the present embodiment, the booster circuit controller 12 is configured to switch between the first mode and the second mode each time the booster circuit controller 12 is activated.

In the present embodiment, the booster circuit control unit 12 generates the first switching control signal SGa from the first switching signal generation unit 12 a so that the positive electrode side switching device 11 a and the negative electrode side switching device 11 b are alternately turned on. A second switching control signal SGb is generated from the second switching signal generator 12b. The booster circuit control unit 12 sends the generated first switching control signal SGa and the second switching control signal SGb to the booster circuit 11 as a command to operate in the booster mode.
The first switching control signal SGa and the second switching control signal SGb are signals for controlling on / off of the positive electrode side switching element 11a and the negative electrode side switching element 11b, and more specifically, the positive electrode side switching element 11a, the negative electrode It is a signal input to each gate terminal of the side switching element 11b.
As a result, the boost circuit control unit 12 causes the three-phase boost rectification unit 1A to function as a boost rectification circuit by alternately turning on the positive electrode side switching element 11a and the negative electrode side switching element 11b.
In this case, the three-phase boost rectifier unit 1A outputs the intermediate voltage Vm as the DC voltage Vdc.

In the first mode, the booster circuit control unit 12 charges the negative electrode side capacitor Cb with the additional voltage Vad, and charges the positive electrode side capacitor Ca with the single-voltage DC voltage Vdc1, so that the three-phase boost rectifier unit 1A receives the intermediate voltage. Output Vm.
On the other hand, in the second mode, the booster circuit controller 12 charges the negative voltage side capacitor Cb with the single-voltage DC voltage Vdc1 and charges the positive electrode side capacitor Ca with the additional voltage Vad. Output intermediate voltage Vm.

The switching unit 12c functionally includes a first switch 12ca and a second switch cb.
The first switching control signal SGa generated from the first switching signal generator 12a is input to the first switch 12ca.
The second switching control signal SGb generated by the second switching signal generator 12b is input to the second switch 12cb.

  In the first mode, as shown in FIG. 2, the switching unit 12c switches the output of the first switch 12ca to the positive electrode side switching element 11a side, and outputs the first switching control signal SGa to the positive electrode side switching element 11a. Furthermore, in the first mode, the switching unit 12c switches the output of the second switch 12cb to the negative electrode side switching element 11b side, and outputs the second switching control signal SGb to the negative electrode side switching element 11b.

  In the second mode, as shown in FIG. 3, the switching unit 12 c switches the output of the first switch 12 ca to the negative electrode side switching element 11 b side, and outputs the first switching control signal SGa to the negative electrode side switching element 11 b. Furthermore, in the second mode, the switching unit 12c switches the output of the second switch 12cb to the positive electrode side switching element 11a side, and outputs the second switching control signal SGb to the positive electrode side switching element 11a.

(Operation of three-phase boost rectifier unit)
The overall operation of the three-phase boost rectifier unit 1A will be described.
As described above, the booster circuit control unit 12 outputs the first switching control signal SGa and the second switching control signal SGb, and alternately turns on the positive electrode side switching element 11a and the negative electrode side switching element 11b.

FIG. 4 shows the relationship between the first switching control signal SGa and the second switching control signal SGb. The horizontal axis represents time, and the vertical axis represents voltage.
In the present embodiment, each of the first switching control signal SGa and the second switching control signal SGb has a rectangular wave having an amplitude of 5V.

The first switching control signal SGa (upper graph) shown in FIG. 4 is a signal that the first switching signal generation unit 12a outputs toward one of the positive electrode side switching element 11a and the negative electrode side switching element 11b. .
The second switching control signal SGb (the lower graph) shown in FIG. 4 is a signal that the second switching signal generation unit 12 b outputs toward the other of the positive electrode side switching element 11 a and the negative electrode side switching element 11 b. .

  In the present embodiment, each of the first switching signal generation unit 12a and the second switching signal generation unit 12b is a period (phase 60 °) obtained by dividing the period Tc (phase 360 °) into six. The first switching signal generating unit 12a and the second switching signal generating unit 12b alternately turn on the positive electrode side switching element 11a and the negative electrode side switching element 11b in each of the periods T1 to T6. Each period is not limited to a period obtained by dividing the period Tc into six, and any period may be used as long as the period Tc is divided by an arbitrary number.

The first switching control signal SGa has an on signal and an off signal alternately.
The second switching control signal SGb has an on signal and an off signal alternately.
Each ON signal is applied to each gate of the positive electrode side switching element 11a and the negative electrode side switching element 11b to turn on each element of the positive electrode side switching element 11a and the negative electrode side switching element 11b.
The respective off signals are applied to the gates of the positive electrode side switching element 11a and the negative electrode side switching element 11b, and the respective elements of the positive electrode side switching element 11a and the negative electrode side switching element 11b are turned off.

The first switching control signal SGa is an on signal in part of the period T1, and is an off signal in the remaining period. In this embodiment, in the period T1, the on signal is output in the first half 50% and the off signal in the second half 50%.
The first switching control signal SGa is an off signal throughout the period T2.
Furthermore, the first switching control signal SGa has signals similar to those in period T1 in periods T3 and T5, and has signals similar to those in period T2 in periods T4 and T6.

The second switching control signal SGb is an off signal throughout the period T1.
The second switching control signal SGb is an on signal throughout the period T2.
Furthermore, the first switching control signal SGa has a signal similar to the period T1 in the period T3 and the period T5, and a signal similar to the period T2 in the period T4 and the period T6, respectively.

(First mode)
The operation of the three-phase boost rectifier unit 1A in the first mode will be described.
FIG. 5 shows the flow of current in the booster circuit 11 in the first mode.
First, in the period T1, the booster circuit control unit 12 turns on the positive electrode side switching element 11a by the first switching control signal SGa and turns off the negative electrode side switching element 11b by the second switching control signal SGb. Then, as shown in FIG. 5, a current I1 flows from the rectifier circuit 10 to the booster circuit 11. The current I1 charges the negative electrode side capacitor Cb by sequentially flowing through the reactor L, the positive electrode side switching element 11a, the negative electrode side capacitor Cb, and the negative electrode side main diode Db.
At this time, the negative electrode side capacitor Cb is charged to the additional voltage Vad in the ON period of the pattern of the first switching control signal SGa shown in FIG.

After the charging of the negative electrode side capacitor Cb in the period T1 is completed, in the period T2, the booster circuit control unit 12 turns off the positive electrode side switching element 11a by the first switching control signal SGa and the negative electrode by the second switching control signal SGb. The side switching element 11b is turned on. Then, as shown in FIG. 5, a current I2 flows from the rectifier circuit 10 to the booster circuit 11. The current I2 charges the positive electrode side capacitor Ca by flowing through the reactor L, the positive electrode side main diode Da, the positive electrode side capacitor Ca and the negative electrode side switching element 11b in order.
At this time, the positive electrode side capacitor Ca is charged up to the single-voltage DC voltage Vdc1 in the ON period of the pattern of the second switching control signal SGb shown in FIG.
On the other hand, since the negative electrode side capacitor Cb is blocked by the negative electrode side main diode Db, even if the negative electrode side switching element 11b is turned on, the charge charged in the period T1 is maintained in the negative electrode side capacitor Cb. Therefore, the negative electrode side capacitor Cb maintains the additional voltage Vad.

After the charging of the positive electrode side capacitor Ca in the period T2 is completed, in the period T3, the booster circuit control unit 12 turns the positive electrode side switching element 11a on again by the first switching control signal SGa and the second switching control signal SGb. The negative electrode side switching element 11b is turned off. As a result, the negative electrode side capacitor Cb is charged again with the additional voltage Vad.
On the other hand, since the positive electrode side capacitor Ca is blocked by the positive electrode side main diode Da, even if the positive electrode side switching element 11a is turned on, the charge charged in the period T2 is maintained in the positive electrode side capacitor Ca. For this reason, the positive electrode side capacitor Ca maintains the single-voltage DC voltage Vdc1.
Thereafter, similar operations are repeated in the subsequent periods T4, T5, T6, T1, T2 and so on.

Therefore, in the first mode, the positive voltage side capacitor Ca is charged with the single-voltage DC voltage Vdc1, and the negative electrode side capacitor Cb is charged with the additional voltage Vad. As a result, the three-phase boost rectifier unit 1A outputs the intermediate voltage Vm as the DC voltage Vdc.
In the present embodiment, the first switching control signal SGa is turned on in the first half 50% of the periods T1, T3 and T5 and turned off in the second half 50%. Therefore, the additional voltage Vad is a voltage equivalent to 50% of the first-voltage DC voltage Vdc1, and the intermediate voltage Vm is a voltage equivalent to 1.5 times the first-voltage DC voltage Vdc1.

(Second mode)
Next, the operation of the three-phase boost rectifier unit 1A in the second mode will be described.
FIG. 6 shows the flow of current in the booster circuit 11 in the second mode.
First, in the period T2, the booster circuit control unit 12 turns on the positive electrode side switching element 11a by the second switching control signal SGb and turns off the negative electrode side switching element 11b by the first switching control signal SGa. Then, as shown in FIG. 6, a current I 3 flows from the rectifier circuit 10 to the booster circuit 11. The current I3 charges the negative electrode side capacitor Cb by sequentially flowing through the reactor L, the positive electrode side switching element 11a, the negative electrode side capacitor Cb and the negative electrode side main diode Db.
At this time, the negative electrode side capacitor Cb is charged up to the single-voltage DC voltage Vdc1 in the ON period of the pattern of the second switching control signal SGb shown in FIG.

After the charging of the negative electrode side capacitor Cb in the period T2 is finished, in the period T3, the booster circuit control unit 12 turns off the positive electrode side switching element 11a by the second switching control signal SGb and the negative electrode by the first switching control signal SGa. The side switching element 11b is turned on. Then, as shown in FIG. 6, a current I 4 flows from the rectifier circuit 10 to the booster circuit 11. The current I4 charges the positive electrode side capacitor Ca by flowing through the reactor L, the positive electrode side main diode Da, the positive electrode side capacitor Ca, and the negative electrode side switching element 11b in this order.
At this time, the positive electrode side capacitor Ca is charged to the additional voltage Vad in the ON period of the pattern of the first switching control signal SGa shown in FIG.
On the other hand, since the negative electrode side capacitor Cb is blocked by the negative electrode side main diode Db, even if the negative electrode side switching element 11b is turned on, the charge charged in the period T2 is maintained in the negative electrode side capacitor Cb. Therefore, the negative electrode side capacitor Cb maintains the single-voltage DC voltage Vdc1.

After the charging of the positive electrode side capacitor Ca in the period T3 is finished, in the period T4, the booster circuit control unit 12 turns on the positive electrode side switching element 11a again by the second switching control signal SGb, and by the first switching control signal SGa. The negative electrode side switching element 11b is turned off. As a result, the negative voltage side capacitor Cb is charged again with the single-voltage DC voltage Vdc1.
On the other hand, since the positive electrode side capacitor Ca is blocked by the positive electrode side main diode Da, even if the positive electrode side switching element 11a is turned on, the charge charged in the period T3 is maintained in the positive electrode side capacitor Ca. For this reason, the positive electrode side capacitor Ca maintains the additional voltage Vad.
Thereafter, similar operations are repeated in the subsequent periods T5, T6, T1, T2, T3...

Therefore, in the second mode, the positive electrode side capacitor Ca is charged with the additional voltage Vad, and the negative electrode side capacitor Cb is charged with the single-voltage DC voltage Vdc1. As a result, the three-phase boost rectifier unit 1A outputs the intermediate voltage Vm as the DC voltage Vdc.
Also in this case, as in the first mode, the first switching control signal SGa is turned on in the first half 50% of the periods T1, T3 and T5 and turned off in the second half 50%. Therefore, the intermediate voltage Vm is a voltage equivalent to 1.5 times the single-voltage DC voltage Vdc1.

(Operation and effect of the present embodiment)
In the first mode, the three-phase boost rectification unit 1A of the present embodiment switches the positive electrode side switching element 11a and the negative electrode side switching element 11b to set the positive DC capacitor Vdc1 to the positive electrode side capacitor Ca and the negative electrode side capacitor Cb. The additional voltage Vad is charged to output the intermediate voltage Vm.
Further, in the second mode, the three-phase boost rectification unit 1A of the present embodiment switches the positive electrode side switching element 11a and the negative electrode side switching element 11b to set the additional voltage Vad to the positive electrode side capacitor Ca and one to the negative electrode side capacitor Cb. The doubled DC voltage Vdc1 is charged to output an intermediate voltage Vm.
Furthermore, the three-phase boost rectifier unit 1A of the present embodiment alternately switches between the first mode and the second mode, and outputs an intermediate voltage Vm.

Usually, the lifetime of the semiconductor element or the capacitor becomes shorter as the flowing current is larger.
If the three-phase boost rectifier unit 1A continues to output the intermediate voltage Vm in only one of the first mode and the second mode without switching between the first mode and the second mode, each of the positive side The current flowing to the element and the current flowing to each element on the negative electrode side are not balanced. In this case, among the elements of the three-phase boost rectification unit 1A, the life of each element on the side where a large amount of current flows is shortened as compared to the other electrode side.

On the other hand, the three-phase boost rectifier unit 1A of the present embodiment merely switches the first mode and the second mode alternately, and continues to output the intermediate voltage Vm, with the current flowing in each element on the positive electrode side. And the current flowing through each element on the negative electrode side are balanced.
Therefore, it is possible to extend the life of the three-phase boost rectification unit 1A with simple control.

Furthermore, in the present embodiment, the three-phase boost rectification unit 1A switches between the first mode and the second mode each time the boost circuit control unit 12 is activated. That is, the three-phase boost rectification unit 1A switches between the first mode and the second mode using the activation of the boost circuit control unit 12 as a trigger.
Therefore, it is not necessary to newly generate a trigger signal for switching, and the life of the three-phase boost rectification unit 1A can be extended with simpler control.

Furthermore, in the present embodiment, the switching unit 12 c switches between the first mode and the second mode by switching the output to the positive electrode side switching element 11 a and the output to the negative electrode side switching element 11 b. Therefore, the booster circuit control unit 12 fixes the switching control signal generated from the first switching signal generation unit 12a to the first switching control signal SGa, and the second switching control signal generated from the second switching signal generation unit 12b It can be fixed to the switching control signal SGb. Therefore, the control of the first switching signal generator 12a and the second switching signal generator 12b is simple.
Therefore, it is possible to extend the life of the three-phase boost rectifier unit 1A with simpler control.

<Control method of three-phase boost rectifier unit>
A control method of the three-phase boost rectifier unit 1A of the above embodiment will be described with reference to FIG.

  First, the three-phase boost rectification unit 1A activates the boost circuit control unit 12 (step ST10). At this time, the booster circuit control unit 12 waits for the output of each switching control signal under internal control.

  Following ST10, the booster circuit control unit 12 sets the output state of the booster circuit 11 to the first mode (step ST20). In the case of the three-phase boost rectifier unit 1A, the switching unit 12c switches the output of the first switch 12ca to the positive side switching element 11a side and switches the output of the second switch 12cb to the negative side switching element 11b side.

  Following ST20, the first mode is implemented (step ST30). In the case of the three-phase boost rectifier unit 1A, the first switching control signal SGa and the second switching control signal SGb are output to the boost circuit 11 in a state where the first mode is set. Thereby, the booster circuit control unit 12 sends the first switching control signal SGa to the positive electrode side switching element 11a, and charges the negative electrode side capacitor Cb with the additional voltage Vad. Furthermore, the booster circuit control unit 12 sends the second switching control signal SGb to the negative electrode side switching element 11b, and charges the positive electrode side capacitor Ca with the single-pressure DC voltage Vdc1. Therefore, the three-phase boost rectifier unit 1A boosts the voltage to the intermediate voltage Vm and outputs it.

  Following ST30, the booster circuit control unit 12 stops the output of each switching control signal under internal control (step ST40). At this time, the input of the three-phase AC voltage from the three-phase AC power supply 3 may be stopped, and the output from the three-phase boost rectification unit 1A may be stopped.

  Following ST40, the three-phase boost rectification unit 1A starts up the boost circuit control unit 12 again (step ST50). At this time, the booster circuit control unit 12 waits for the output of each switching control signal under internal control.

  Following ST50, the booster circuit control unit 12 sets the output state of the booster circuit 11 to the second mode (step ST60). In the case of the three-phase boost rectifier unit 1A, the switching unit 12c switches the output of the first switch 12ca to the negative electrode side switching element 11b and switches the output of the second switch 12cb to the positive electrode side switching element 11a.

  Following ST60, the second mode is implemented (step ST70). In the case of the three-phase boost rectification unit 1A, the first switching control signal SGa and the second switching control signal SGb are output to the boost circuit 11 in the state set to the second mode. As a result, the booster circuit control unit 12 sends the second switching control signal SGb to the positive electrode side switching element 11a, and charges the negative electrode side capacitor Cb with the single-voltage DC voltage Vdc1. Further, the booster circuit control unit 12 sends the first switching control signal SGa to the negative electrode side switching element 11b to charge the positive electrode side capacitor Ca with the additional voltage Vad. Therefore, the three-phase boost rectifier unit 1A boosts the voltage to the intermediate voltage Vm and outputs it.

  Following ST70, the booster circuit control unit 12 stops the output of each switching control signal under internal control (step ST80). At this time, the input of the three-phase AC voltage from the three-phase AC power supply 3 may be stopped, and the output from the three-phase boost rectification unit 1A may be stopped.

  Following ST80, the process returns to ST10, ST10 is performed, and the steps following ST10 are repeated.

<Modification>
In the above embodiment, the switching unit 12 c switches between the first mode and the second mode by switching the output to the positive electrode side switching element 11 a and the output to the negative electrode side switching element 11 b. As a modification, the first switching signal generator 12a and the second switching signal generator 12b may switch and output the first switching control signal SGa and the second switching control signal SGb, respectively.

  In the above embodiment, each on signal is a 5 V rectangular wave, but any signal may be used as long as each of the positive electrode side switching element 11 a and the negative electrode side switching element 11 b can be turned on.

In the above embodiment, in each of the periods T1, T3, and T5, the first switching control signal SGa is an on signal in the first half 50% and an off signal in the second half 50%. If the part of the period is an on signal and the remaining period is an off signal, the distribution of the on signal period and the off signal period may be any distribution.
As a modification, in each of the periods T1, T3 and T5, the first switching control signal SGa is an on signal in a period less than the first half 50% (or a first half 50% or more) in each period, and an off signal in the remaining periods. It may be
As another modification, in each of the periods T1, T3 and T5, the first switching control signal SGa is an ON signal in the middle (or the second half) period in each period, and an OFF signal in the remaining periods. It is also good.

  In the present embodiment, the additional voltage Vad is smaller than the single-voltage DC voltage Vdc1, but as a modification, the additional voltage Vad may be larger than the single-voltage DC voltage Vdc1. As another modification, the additional voltage Vad may be the same voltage as the single-voltage DC voltage Vdc1 as long as the current flowing to each element on the positive electrode side and the current flowing to each element on the negative electrode are different. .

  In the above embodiment, the booster circuit controller 12 sets each mode following activation of the booster circuit controller 12 (ST10, ST50). As a modification, the booster circuit control unit 12 may set each mode when the booster circuit control unit 12 is stopped (ST40, ST80).

  In the above embodiment, the ST10, ST40, ST50 and ST80 are implemented by the three-phase boost rectification unit 1A, but as a modification, the operator may implement any of the steps, or the three-phase boost rectification An apparatus outside the unit 1A may be implemented.

In the above embodiment, the switching unit 12c is provided in the boosting circuit control unit 12. However, as a modification, a switching unit is provided as a separate unit in the wiring between the boosting circuit control unit 12 and the boosting circuit 11. May be
Furthermore, in this case, another device may control the switching unit 12c, or an operator may control the switching unit 12c. That is, in the control method of the three-phase boost rectification unit 1A, ST20 and ST60 may be implemented by another device or may be implemented by the operator.

  In the above embodiment, an IGBT is used as the switching element, but as a modification, a bipolar transistor, a power MOSFET or the like may be used. Furthermore, a switching element using SiC, GaN or the like may be used.

  In the above embodiment, a program for realizing various functions of the booster circuit control unit is recorded in a computer readable recording medium, and the computer system reads the program recorded in the recording medium and executes the program. It is good also as what performs various processing by this. Here, the processes of various processes of the CPU of the computer system are stored in a computer readable recording medium in the form of a program, and the various processes are performed by the computer reading and executing this program. The computer readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, and the like. Alternatively, the computer program may be distributed to a computer through a communication line, and the computer that has received the distribution may execute the program.

  Although the embodiments according to the present invention have been described above, this embodiment is presented as an example, and is not intended to limit the scope of the invention. This embodiment can be implemented in other various forms, and various omissions, replacements and changes can be made without departing from the scope of the invention. It is intended that the embodiments and the modifications thereof are included in the invention described in the claims and the equivalent scope as well as included in the scope and the gist of the invention.

1: Inverter device 1A: Three-phase boost rectification unit 3: Three-phase AC power supply 4: Motor 10: Rectification circuit 10Ra: Positive side R-phase rectification diode 10Rb: Negative side R-phase rectification diode 10Sa: Positive side S-phase rectification diode 10Sb: Negative side S phase rectifier diode 10Ta: Positive side T phase rectifier diode 10Tb: Negative side T phase rectifier diode 11: Step-up circuit 11a: Positive side switching element 11b: Negative side switching element 12: Step-up circuit controller 12a: First switching signal Generation unit 12b: second switching signal generation unit 12c: switching unit 12ca: first switch 12cb: second switch 20: inverter circuit 21: inverter circuit control unit 22: motor current detection unit 90: air conditioner (air conditioner)
Ca: positive electrode side capacitor Cb: negative electrode side capacitor Da: positive electrode side main diode Db: negative electrode side main diode L: reactor N: connection point Qa: positive electrode side output terminal Qb: negative electrode side output terminal QR: R phase input terminal QS: S Phase input terminal QT: T-phase input terminal α: positive electrode output line α1: first positive electrode output line α2: second positive electrode output line β: negative electrode output line

Claims (7)

A rectifier circuit that rectifies a three-phase AC voltage supplied from a three-phase AC power supply and outputs a rectified voltage between the positive electrode output line and the negative electrode output line;
A positive side main diode having an anode connected to the positive output line, a negative side main diode having a cathode connected to the negative output line, and a positive side switching element connected between a connection point and the positive output line And a negative electrode side switching element connected between the connection point and the negative electrode output line, and an additional voltage is a single voltage which is a DC voltage equivalent to one time of the amplitude of the three-phase AC voltage. A booster circuit capable of outputting an intermediate voltage added to a DC voltage;
A positive side capacitor connected between the cathode of the positive side main diode and the connection point;
A negative capacitor connected between the connection point and the anode of the negative main diode;
The first switching control signal capable of charging the additional voltage to the negative electrode side capacitor is sent to the positive electrode side switching element, and the second switching control signal capable of charging the single-voltage DC voltage to the positive electrode side capacitor is the negative electrode side Step-up circuit control that alternately switches between a first mode for sending to a switching element and a second mode for sending the second switching control signal to the positive side switching element and sending the first switching control signal to the negative side switching element Department,
Three-phase boost rectifier unit with.   The three-phase boost rectification unit according to claim 1, wherein the boost circuit control unit switches between the first mode and the second mode each time it is activated.   The booster circuit control unit switches whether to send the first switching control signal to the positive electrode side switching element or to the negative electrode side switching element, and sends the second switching control signal to the negative electrode side switching element The three-phase boost rectification unit according to claim 1, further comprising: a switching unit that switches whether to send to the positive electrode side switching element. A three-phase boost rectifier unit according to any one of claims 1 to 3;
An inverter circuit for converting a DC voltage output from the three-phase boost rectifier unit into a load driving AC voltage for driving a load as desired;
An inverter device comprising: An inverter device according to claim 4;
A motor that is rotationally driven based on the load driving AC voltage output from the inverter circuit as the load;
An air conditioner equipped with A rectifier circuit that rectifies a three-phase AC voltage supplied from a three-phase AC power supply and outputs a rectified voltage between a positive electrode output line and a negative electrode output line, and a positive electrode side with an anode connected to the positive electrode output line A main diode, a negative side main diode whose cathode is connected to the negative electrode output line, a positive side switching element connected between a connection point and the positive electrode output line, a connection point and the negative electrode output line And a negative voltage side switching element connected between, and boosting capable of outputting an intermediate voltage obtained by adding an additional voltage to a single voltage DC voltage which is a DC voltage equivalent to 1 time of the amplitude of the three-phase AC voltage. A circuit, a positive side capacitor connected between the cathode of the positive side main diode and the connection point, and a negative side capacitor connected between the connection point and the anode of the negative side main diode Three-phase boost A method of controlling a flow unit,
The first switching control signal capable of charging the additional voltage to the negative electrode side capacitor is sent to the positive electrode side switching element, and the second switching control signal capable of charging the single-voltage DC voltage to the positive electrode side capacitor is the negative electrode side Implementing a first mode of sending to the switching element;
Implementing a second mode of sending the second switching control signal to the positive side switching element and sending the first switching control signal to the negative side switching element;
A control method of a three-phase boost rectifier unit which alternately carries out. A rectifier circuit that rectifies a three-phase AC voltage supplied from a three-phase AC power supply and outputs a rectified voltage between a positive electrode output line and a negative electrode output line, and a positive electrode side with an anode connected to the positive electrode output line A main diode, a negative side main diode whose cathode is connected to the negative electrode output line, a positive side switching element connected between a connection point and the positive electrode output line, a connection point and the negative electrode output line And a negative voltage side switching element connected between, and boosting capable of outputting an intermediate voltage obtained by adding an additional voltage to a single voltage DC voltage which is a DC voltage equivalent to 1 time of the amplitude of the three-phase AC voltage. A circuit, a positive side capacitor connected between the cathode of the positive side main diode and the connection point, and a negative side capacitor connected between the connection point and the anode of the negative side main diode Three-phase boost The computer of the flow unit,
The first switching control signal capable of charging the additional voltage to the negative electrode side capacitor is sent to the positive electrode side switching element, and the second switching control signal capable of charging the single-voltage DC voltage to the positive electrode side capacitor is the negative electrode side Step-up circuit control that alternately switches between a first mode for sending to a switching element and a second mode for sending the second switching control signal to the positive side switching element and sending the first switching control signal to the negative side switching element Program to function as a department.

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