JP6683514B2 - Power converter - Google Patents

Description

  The present invention relates to a power conversion device.

  Conventionally, an inverter with a winding switching function is known. For example, in Patent Document 1, two sets of inverter circuits and two switches are provided to switch between Y-connection operation and Δ-connection operation.

JP-A-1-34198

Patent Document 1 does not mention any control other than the PWM control as the control method of the inverter circuit.
The present invention has been made in view of the above problems, and an object thereof is to provide a power conversion device capable of improving the maximum torque of a rotating electric machine.

  The power converter of the present invention converts power of a rotating electric machine (10) having coils (11, 12, 13) of a plurality of phases, and includes a first inverter (20) and a second inverter (30). And a high potential side connection line (51), a low potential side connection line (55), and a control unit (65).

The first inverter includes a first upper arm element (21 to 23) provided on the high potential side and a first lower arm element (24 to 46) provided on the low potential side of the first upper arm element for each phase. It is connected to one end (111, 121, 131) of the coil and the voltage source (40).
The second inverter includes a second upper arm element (31 to 33) provided on the high potential side and a second lower arm element (34 to 36) provided on the low potential side of the second upper arm element for each phase. And is connected to the other ends (112, 122, 132) of the coil.
The high potential side connection line connects the positive side of the voltage source, the high potential side of the first upper arm element, and the high potential side of the second upper arm element.
The low potential side connection line connects the negative side of the voltage source, the low potential side of the first lower arm element, and the low potential side of the second lower arm element.
The control unit controls the first inverter and the second inverter to perform Y connection control for controlling the coils of a plurality of phases to be in a Y connection state, or an H bridge circuit that makes the coils of a plurality of phases independent of each other. Bridge control is performed to control the applied voltage.

A control unit is, as the number of revolutions of the rotary electric machine performs Y-connection control in the case than the upper limit value or the upper limit value that can be output is even lower rotational speed side than the value of the low output side in Y connection control, when the rotational speed of the rotary electric machine is the high rotational speed side than the value of the lower output than the upper limit value or the upper limit value that can be output at the Y-connection control, the H-bridge circuit to separate the coils of a plurality of phases By controlling the applied voltage for each phase, “the first upper arm element and the first lower arm element of the first inverter are complementarily provided for each half cycle of the sine wave current as the phase current flowing in each phase of the coil. A switching pattern in which a current flowing in the positive direction and a return current according to the positive direction of the current flow in the coil are turned on and off by keeping the second upper arm element and the second lower arm element of the second inverter on and off. And, "First Inn The first upper arm element and the first lower arm element of the motor are kept on and off in a constant manner, and the second upper arm element and the second lower arm element of the second inverter are complementarily turned on and off, thereby flowing in the coil in the negative direction. A switching pattern in which a current and a return current according to the negative direction of current flow are flown . "

In the present invention, by connecting the first inverter and the second inverter with the high-potential-side connecting line and the low-potential-side connecting line, each phase is regarded as an independent bridge circuit, and the voltage applied to the coil for each phase. Bridge control is possible .

It is a schematic block diagram which shows the power converter device by 1st Embodiment of this invention. FIG. 3 is an explanatory diagram illustrating a drive area of the motor generator according to the first embodiment of the present invention. FIG. 3 is an explanatory diagram illustrating Y connection control and bridge control according to the first embodiment of the present invention. FIG. 4 is a U-phase circuit diagram during bridge control according to the first embodiment of the present invention. It is an explanatory view explaining bridge control by a 1st embodiment of the present invention. FIG. 6 is an explanatory diagram illustrating an operation during balanced bridge control according to the first embodiment of the present invention. FIG. 6 is an explanatory diagram illustrating an operation during unbalanced bridge control according to the first embodiment of the present invention. It is a schematic block diagram which shows the power converter device by 2nd Embodiment of this invention. It is a schematic block diagram which shows the power converter device by 3rd Embodiment of this invention. It is a schematic block diagram which shows the power converter device by 4th Embodiment of this invention.

Hereinafter, a power converter according to the present invention will be described with reference to the drawings. Hereinafter, in a plurality of embodiments, the substantially same configurations are denoted by the same reference numerals, and description thereof will be omitted.
(First embodiment)
The power converter according to the first embodiment of the present invention is shown in FIGS.
As shown in FIG. 1, the rotary electric machine drive system 1 includes a motor generator 10 as a rotary electric machine and a power converter 15.

  The motor generator 10 is a so-called "main motor" that is applied to an electric vehicle such as an electric vehicle or a hybrid vehicle and generates torque for driving a drive wheel (not shown). The motor generator 10 has a function as an electric motor for driving the drive wheels and a function as a generator that is driven by kinetic energy transmitted from an engine and drive wheels (not shown) to generate electric power. In the present embodiment, the case where the motor generator 10 functions as an electric motor will be mainly described.

  The motor generator 10 is a three-phase alternating current rotating machine, and has a U-phase coil 11, a V-phase coil 12, and a W-phase coil 13. Hereinafter, the U-phase coil 11, the V-phase coil 12 and the W-phase coil 13 will be appropriately referred to as "coils 11 to 13". Further, a current flowing through the U-phase coil 11 is referred to as a U-phase current Iu, a current flowing through the V-phase coil 12 is referred to as a V-phase current Iv, and a current flowing through the W-phase coil 13 is referred to as a W-phase current Iw. Regarding the currents flowing through the coils 11 to 13, the current flowing from the first inverter 20 side to the second inverter 30 side is positive, and the current flowing from the second inverter 30 side to the first inverter 20 side is negative.

The power converter 15 converts the power of the motor generator 10, and includes the first inverter 20, the second inverter 30, the high potential side connection line 51, the low potential side connection line 55, the control unit 65, and the like. Prepare
The first inverter 20 is a three-phase inverter that switches the energization of the coils 11 to 13 and has switching elements 21 to 26. The second inverter 30 is a three-phase inverter that switches the energization of the coils 11 to 13 and has switching elements 31 to 36.
The switching element 21 has a transistor 211 and a diode 221. Similarly, the switching elements 22 to 26 and 31 to 36 have transistors 212 to 216, 311 to 316 and diodes 222 to 226 and 321 to 326, respectively.

  The transistors 211 to 216 and 311 to 316 are IGBTs (insulated gate bipolar transistors), and the on / off operation is controlled by the control unit 65. When the transistors 211 to 216 and 311 to 316 are turned on, energization from the high potential side to the low potential side is allowed, and when turned off, the energization is cut off. The transistors 211 to 216 and 311 to 316 are not limited to IGBTs, and may be MOSFETs or the like.

  The diodes 221 to 226 and 321 to 326 are freewheeling diodes that are connected in parallel to the transistors 211 to 216 and 311 to 316, respectively, and allow energization from the low potential side to the high potential side. For example, the diodes 221 to 226 and 321 to 326 may be built in the transistors 211 to 216 and 311 to 316, such as MOSFET parasitic diodes, or may be externally attached. .

  In the first inverter 20, the switching elements 21 to 23 are connected to the high potential side and the switching elements 24 to 26 are connected to the low potential side. The high potential sides of the switching elements 21 to 23 are connected to the positive electrode of the battery 40, and the low potential sides of the switching elements 24 to 26 are connected to the negative electrode of the battery 40.

  One end 111 of the U-phase coil 11 is connected to the connection point of the U-phase switching elements 21 and 24, one end 121 of the V-phase coil 12 is connected to the connection point of the V-phase switching elements 22 and 25, and the W-phase One end 131 of the W-phase coil 13 is connected to the connection point of the switching elements 23 and 26 of. That is, the first inverter 20 is connected between the one ends 111, 121, 131 of the coils 11, 12, 13 and the battery 40.

In the second inverter 30, the switching elements 31 to 33 are connected to the high potential side and the switching elements 34 to 36 are connected to the low potential side.
The other end 112 of the U-phase coil 11 is connected to the connection point of the U-phase switching elements 31 and 34, and the other end 122 of the V-phase coil 12 is connected to the connection point of the V-phase switching elements 32 and 35. The other end 132 of the W-phase coil 13 is connected to the connection point of the W-phase switching elements 33 and 36.

  Hereinafter, in the first inverter 20, the switching elements 21 to 23 connected to the high potential side are “first upper arm elements” and the switching elements 24 to 26 connected to the low potential side are “first lower arm elements” as appropriate. And Further, in the second inverter 30, the switching elements 31 to 33 connected to the high potential side are referred to as “second upper arm element”, and the switching elements 34 to 36 connected to the low potential side are referred to as “second lower arm element”. To do.

The battery 40 is connected to the first inverter 20. In the present embodiment, no voltage source such as a battery is provided on the second inverter 30 side.
The capacitor 43 is a smoothing capacitor connected between the first inverter 20 and the battery 40.
The current detector 45 detects the phase currents Iu, Iv, Iw. In the present embodiment, a current detection element such as a Hall element is provided for each phase as the current detection unit 45.

The high potential side connection line 51 connects the positive electrode side of the battery 40, the high potential side of the first upper arm elements 21 to 23, and the high potential side of the second upper arm elements 31 to 33. In other words, the high potential side connection line 51 is a connection wiring that connects the high potential side of the inverters 20 and 30 without passing through the motor generator 10.
The low potential side connection line 55 connects the negative electrode side of the battery 40, the low potential side of the first lower arm elements 24 to 26, and the low potential side of the second lower arm elements 34 to 36. In other words, the low potential side connection line 55 is a connection wiring that connects the low potential side of the inverters 20 and 30 without passing through the motor generator 10.

  The high potential side connection line 51 is provided with a switch 52 capable of switching between conduction and interruption between the first inverter 20 side and the second inverter 30 side. The switch 52 may be a mechanical type, a semiconductor switch or the like as long as it can switch between conduction and interruption between the first inverter 20 side and the second inverter 30 side.

The control signal generation unit 60 has a first driver circuit 61, a second driver circuit 62, and a control unit 65.
The control unit 65 is mainly composed of a microcomputer and performs various arithmetic processes. Each processing in the control unit 65 may be software processing by executing a program stored in advance by the CPU, or may be hardware processing by a dedicated electronic circuit.
The control unit 65 controls the first inverter 20 and the second inverter 30. Specifically, based on command values related to driving the motor generator 10, such as the torque command value trq ^* and the current command values Iu ^* , Iv ^* , Iw ^*, etc., the transistors 211-216 of the switching elements 21-26, 31-36. , 311 to 316 are generated and output to the driver circuits 61 and 62.

  The first driver circuit 61 generates and outputs a gate signal for controlling the on / off operation of the transistors 211 to 216 according to the control signal from the control unit 65. The second driver circuit 62 generates and outputs a gate signal for controlling the on / off operation of the transistors 311 to 316 according to the control signal from the control unit 65. By turning on / off the transistors 211 to 216 and 311 to 316 according to the control signal, the DC power of the battery 40 is converted to AC power and supplied to the motor generator 10. As a result, the drive of the motor generator 10 is controlled by the control unit 65 via the first inverter 20 and the second inverter 30.

  Hereinafter, appropriately controlling the on / off operation of the transistors 211 to 216 and 311 to 316 of the switching elements 21 to 26, 31 to 36 is simply referred to as controlling the on / off operation of the switching elements 21 to 26, 31 to 36. In the present embodiment, the switching elements 21 to 26, 31 to 36 can be independently turned on and off by the driver circuits 61 and 62.

The drive control of the motor generator 10 will be described. In the present embodiment, the rotation speed and torque of the motor generator 10 are “drive request”. As shown in FIG. 2, the drive region is divided into three regions, a first region R1, a second region R2, and a third region R3, according to the rotation speed and torque of the motor generator 10. The first region R1 is a region where the torque is equal to or lower than the switching threshold value trq_th and is on the low rotation speed side. The second region R2 is a region where the torque is equal to or lower than the switching threshold value trq_th and is on the high rotation speed side. The boundary value Bth between the regions R1 and R2 is an upper limit value that can be output by Y connection control described later. The boundary value Bth may be a value on the output side lower than the upper limit value that can be output by the Y connection control, based on the efficiency of the Y connection control and the efficiency of the three-phase balanced bridge drive, both of which will be described later.
The third region R3 is a region where the torque is larger than the switching threshold value trq_th. The switching threshold value trq_th is an upper limit value that can be output when the currents of the coils 11 to 13 are three-phase balanced currents. Here, it is assumed that the three-phase balanced current is a predetermined value or less such that the absolute value of the three-phase sum of the phase currents Iu, Iv, and Iw can be regarded as zero.

  When the torque and the rotation speed of the motor generator 10 are in the first region R1, the control unit 65 controls the switching elements 21 to 26, 31 to 36 and the switch 52 so that the coils 11 to 13 are in the Y connection state. The control that brings the coils 11 to 13 into the Y connection state is referred to as “Y connection control”. Specifically, as shown in FIG. 3A, the switch 52 is opened, all the phases of the second upper arm elements 31 to 33 are turned on, and all the phases of the second lower arm elements 34 to 36 are turned off. , The second inverter 30 is neutralized. In the first inverter 20, the switching elements 21 to 26 are controlled according to the drive request of the motor generator 10, for example, by PWM control. For example, when the second inverter 30 is neutralized and the switching elements 21, 25, 26 of the first inverter 20 are turned on, a current flows through the path indicated by the arrow A1.

  When the torque and the rotation speed of the motor generator 10 are in the second region R2 or the third region R3, the switch 52 is closed. As shown in FIG. 4, by closing the switch 52, each phase can be regarded as an independent H bridge circuit. Each phase is regarded as an independent H-bridge circuit, and controlling the applied voltage for each phase is called "bridge control". For example, when the switching elements 21, 25, 26, 32, 33, and 34 are turned on by the bridge control, the current in the path indicated by the arrow A2 in FIG. 3B flows.

  Details of the bridge control will be described with reference to FIG. Hereinafter, the U-phase will be mainly described, but the V-phase and the W-phase are substantially the same except that the phases are deviated. As shown by an arrow A11 in FIG. 5A, when a current in the forward direction is applied to the coil 11, the first upper arm element 21 and the second lower arm element 34 are turned on, the first lower arm element 24 and the second upper arm element 24 are turned on. The arm element 31 is turned off.

As shown by an arrow A12 in FIG. 5B, when a negative current is applied to the coil 12, the first lower arm element 24 and the second upper arm element 31 are turned on, and the first upper arm element 21 and the second lower arm element 21 are turned on. The arm element 34 is turned off.
If the ON / OFF states of the switching elements 21, 24, 31, and 34 are other than the patterns shown in FIGS. 5A and 5B, the reflux current flows according to the energization direction.

In the present embodiment, since the switching elements 21 to 26 and 31 to 36 can be independently switched on and off, the degree of freedom in current control is increased by controlling the three phases as independent H bridge circuits.
Hereinafter, bridge control so that three-phase balanced currents flow through the coils 11 to 13 is called "balanced bridge control", and bridge control so that three-phase unbalanced currents flow is called "unbalanced bridge control". .

  When the torque and the rotation speed of the motor generator 10 are in the second region R2, the switch 52 is closed and balanced bridge control is performed so that three-phase balanced currents flow through the coils 11 to 13. Here, in the Y connection control and the balanced bridge control, since it is controlled so that a balanced current is passed through the coils 11 to 13, it can be said to be “balanced control”. The regions R1 and R2 in which the equilibrium control is performed are referred to as “equilibrium regions”.

  FIG. 6 shows an example in which balanced bridge control is performed. In FIG. 6, (a) is the phase currents Iu, Iv, Iw, (b) is the torque, and (c) is the U-phase voltage Vu. The U-phase voltage Vu is a potential on the first inverter 20 side with respect to the second inverter 30 side of the coil 11. In addition, FIG. 6D is a switching pattern of the first upper arm element 21, (e) is the first lower arm element 24, (f) is the second upper arm element 31, and (g) is the second lower arm element 34. Is. In FIG. 6, the switching element 21 is described as “U1 upper”, the switching element 24 is described as “U1 lower”, the switching element 31 is described as “U2 upper”, and the switching element 34 is described as “U2 lower”. The same applies to FIG. 7.

When the positive U-phase voltage Vu is applied, the switching elements 21 and 24 of the first inverter 20 are complementarily turned on and off by the PWM control according to the drive request. Further, the second upper arm element 31 is turned off and the second lower arm element 34 is turned on. As a result, a positive current flows through the U-phase coil 11.
When applying the negative U-phase voltage Vu, the first upper arm element 21 is turned off and the first lower arm element 24 is turned on. In addition, the switching elements 31 and 34 of the second inverter 30 are complementarily turned on / off by the PWM control according to the drive request. As a result, a negative current flows through the U-phase coil 11.
The V-phase and the W-phase have similar switching patterns that are out of phase by 120 °.
As a result, as shown in FIG. 6A, three-phase balanced currents flow through the coils 11 to 13.

  In the present embodiment, the Y connection control and the balanced bridge control can be switched by switching the opening / closing of the switch 52 and changing the on / off control of the switching elements 21 to 26 and 31 to 36. By using balanced bridge control instead of Y connection control, it is possible to output a region on the higher rotation speed side. As shown in FIG. 6B and FIG. 7B, the torque fluctuation can be suppressed by passing the three-phase balanced current through the coils 11 to 13 as compared with the case of passing the three-phase unbalanced current.

When the torque and the rotation speed of the motor generator 10 are in the third region R3, the switch 52 is closed and the unbalanced bridge control is performed. In the present embodiment, the unbalanced bridge control corresponds to the "unbalanced control", and the third region R3 in which the unbalanced bridge control is performed is the "unbalanced region".
By changing the current flowing through the coils 11 to 13 into a three-phase balanced sine wave current and using an unbalanced current, the torque that can be output can be increased. Therefore, the torque in the third region R3 that cannot be output with the balanced current is output. It is possible.

FIG. 7 shows an example in which unbalanced bridge control is performed to output the torque in the third region R3. As shown in FIG. 7A, when outputting the torque in the third region R3, the trapezoidal current is controlled to flow through the coils 11 to 13 instead of the sine wave current.
When a current in the forward direction is passed through the coil 11, the switching elements 21 and 34 are switched at a duty according to a drive request, and the switching elements 24 and 31 are turned off.
At the timing Xu1 at which the U-phase current Iu is switched from positive to negative, the switching elements 24 and 31 are switched on and the switching elements 21 and 34 are switched off. The timing Xu1 is a timing at which the electrical angle becomes 180 °. In order to prevent the reflux or the like, the switching elements 24 and 31 are turned on and the switching states of the switching elements 21 and 34 are continued until the U-phase current Iu reaches a desired value. The duration of this switching state is determined by the inductance L of the motor generator 10 and the like. After the U-phase current Iu reaches a desired value, the switching elements 24 and 31 are switched with a duty according to a drive request.

At timing Xu2 at which the U-phase current Iu is switched from negative to positive, the switching elements 21 and 34 are switched on and 24 and 31 are switched off. The timing Xu2 is a timing at which the electrical angle becomes 0 °. In order to prevent recirculation and the like, the switching elements 21 and 34 are turned on and the switching elements 24 and 31 are turned off until the U-phase current Iu reaches a desired value. Same as time.
The V-phase and the W-phase have similar switching patterns that are out of phase by 120 °.

  By passing a three-phase unbalanced trapezoidal wave current through the coils 11 to 13, as compared with the torque trq_s when a three-phase balanced sine wave current indicated by a broken line is applied as shown by a solid line trq_b in FIG. 7B. However, although there is pulsation, a large torque can be output on average. In addition, the instantaneous maximum torque can be increased as compared with the case where a three-phase balanced sinusoidal current is passed.

  As described above, the power conversion device 15 of the present embodiment is for converting the power of the motor generator 10 having the coils 11 to 13 of multiple phases, and includes the first inverter 20, the second inverter 30, and The high potential side connection line 51, the low potential side connection line 55, and the control unit 65 are provided.

The first inverter 20 includes, for each phase, first upper arm elements 21 to 23 provided on the high potential side and first lower arm elements 24 to 26 provided on the low potential side of the first upper arm elements 21 to 23. It has, and is connected to one end 111, 121, 131 of the coils 11, 12, 13 and the battery 40.
The second inverter 30 includes the second upper arm elements 31 to 33 provided on the high potential side and the second lower arm elements 34 to 36 provided on the low potential side of the second upper arm elements 31 to 33 for each phase. It has and is connected to the other ends 112, 122, 132 of the coils 11, 12, 13.

The high potential side connection line 51 connects the positive electrode side of the battery 40, the high potential side of the first upper arm elements 21 to 23, and the high potential side of the second upper arm elements 31 to 33.
The low potential side connection line 55 connects the negative electrode side of the battery 40, the low potential side of the first lower arm elements 24 to 26, and the low potential side of the second lower arm elements 34 to 36.

The control unit 65 controls the first inverter 20 and the second inverter 30.
When the torque of the motor generator 10 is less than or equal to the switching threshold value trq_th, the control unit 65 performs balance control so that a balanced current flows through the coils 11 to 13. When the torque of the motor generator 10 is larger than the switching threshold value trq_th, the control unit 65 performs unbalance control so that the unbalance current flows through the coils 11 to 13.

  In the present embodiment, by connecting the first inverter 20 and the second inverter 30 with the high potential side connection line 51 and the low potential side connection line 55, each phase is regarded as an independent bridge circuit and the coil Bridge control for controlling the applied voltage for each phase is possible. With the bridge control, the degree of freedom in current control is increased, and an unbalanced current can be passed through the coils 11 to 13. The maximum torque that can be output can be improved by performing unbalanced control instead of balanced control.

At least one of the high potential side connection line 51 and the low potential side connection line 55 is provided with a switch 52 capable of connecting and disconnecting the first inverter 20 side and the second inverter 30 side. In the present embodiment, the switch 52 is provided on the high potential side connection line 51. By providing the switch 52 and disconnecting the first inverter 20 side and the second inverter 30 side by at least one of the high potential side connection line 51 and the low potential side connection line 55, Y connection control becomes possible.
In the present embodiment, the switch 52 is provided on the high potential side connection line 51, and the switch of the low potential side connection line 55 is omitted, so that both the high potential side connection line 51 and the low potential side connection line 55 are opened and closed. The number of parts can be reduced as compared with the case where a container is provided.

The equilibrium control region, which is a drive region for performing the equilibrium control, includes a first region R1 on the low rotation speed side and a second region R2 on the higher rotation speed side than the first region R1. Further, the region where the unbalance control is performed is the third region R3.
When the drive request of the motor generator 10 is in the first region R1, the switch 52 is opened, the second inverter 30 is set to the neutral point, and the Y connection control is performed to control the first inverter 20 according to the drive request.
When the drive request of the motor generator 10 is in the second region R2 or the third region R3, the switch 52 is closed and bridge control is performed to control the voltage applied to the coils 11 to 13 for each phase.
The high efficiency region differs depending on the control. Therefore, the drive efficiency of the motor generator 10 can be improved by switching the control according to the drive region.

(Second embodiment)
The second embodiment of the present invention is shown in FIG.
As shown in FIG. 8, the rotary electric machine drive system 2 of the present embodiment includes a motor generator 10 and a power converter 16.
The power conversion device 16 is different from the power conversion device 15 of the first embodiment in that the switch 56 is provided on the low potential side connection line 55 and the switch 52 of the high potential side connection line 51 is omitted. .

In the present embodiment, when the drive request is in the first region R1 and the Y connection control is performed, the switch 56 is opened and all the phases of the second lower arm elements 34 to 36 are turned on, so that the second inverter is turned on. 30 is neutralized.
When the drive request is the second region R2 or the third region R3 and the bridge control is performed, the switch 56 is closed.
Other structures and details of control are the same as those in the first embodiment.
Even with this structure, the same effect as that of the above-described embodiment can be obtained.

(Third Embodiment)
A third embodiment of the present invention is shown in FIG.
As shown in FIG. 9, the rotary electric machine drive system 3 of the present embodiment includes a motor generator 10 and a power converter 17.
In the power conversion device 17, the switch 52 is provided on the high potential side connection line 51, and the switch 56 is provided on the low potential side connection line 55.

In the present embodiment, when the drive request is for the first region R1 and the Y connection control is performed, at least one of the switches 52 and 56 is opened. When the switch 52 is opened and the switch 56 is closed, the second inverter 30 is neutralized by turning on all the phases of the second upper arm elements 31 to 33, and the switch 52 is closed and the switch 56 is turned on. When it is opened, all the phases of the second lower arm elements 34 to 36 are turned on so that the second inverter 30 becomes the neutral point. That is, the arms to be turned on for all phases are selected according to the switches 52 and 56 to be opened.
When both the switches 52 and 56 are opened, the second inverter 30 is turned on regardless of whether all phases of the second upper arm elements 31 to 33 or all phases of the second lower arm elements 34 to 36 are turned on. Can be neutralized.
When the drive request is the second region R2 or the third region R3 and the bridge control is performed, both the switches 52 and 56 are closed.
Other structures and details of control are the same as those in the first embodiment.
Even with this structure, the same effect as that of the above-described embodiment can be obtained.

(Fourth Embodiment)
A fourth embodiment of the present invention is shown in FIG.
As shown in FIG. 10, the rotary electric machine drive system 4 of the present embodiment includes a motor generator 10 and a power converter 18.
In the power converter 18, the switch 52 of the first embodiment is omitted. That is, in the power converter 18, neither the high potential side connection line 51 nor the low potential side connection line 55 is provided with a switch, and the first inverter 20 side and the second inverter 30 side can be separated. Can not. Therefore, in the present embodiment, since the Y connection control cannot be performed, the region R1 in FIG. 2 is set to the balanced bridge control instead of the Y connection control.
Other structures and details of control are the same as those in the first embodiment.
In this embodiment, since the switches for the high potential side connection line 51 and the low potential side connection line 55 are omitted, the number of parts can be reduced. Further, the same effect as that of the above-described embodiment is obtained except that the Y connection control cannot be performed.

(Other embodiments)
(A) Voltage Source In the above embodiment, a lithium ion battery or the like is illustrated as the voltage source. In other embodiments, the voltage source may be a lead acid battery other than a lithium ion battery, a fuel cell, or the like.
(B) Rotating electric machine
In the above embodiment, the rotary electric machine is a motor generator. In another embodiment, the rotating electric machine may be a motor that does not have the function of a generator, or may be a generator that does not have the function of a motor. Further, the rotary electric machine of the above embodiment has three phases. In other embodiments, the rotating electric machine may have four or more phases.
Further, in the above-described embodiment, the rotating electric machine is the main motor of the electric vehicle. In another embodiment, the rotary electric machine is not limited to the main motor, but may be a so-called ISG (Integrated Starter Generator) having both a starter function and an alternator function, or an auxiliary motor. Further, the power conversion device may be applied to a device other than the vehicle.
As described above, the present invention is not limited to the above-described embodiment, and can be implemented in various forms without departing from the spirit of the invention.

10: Motor generator (rotary electric machine)
11-13 ... Coil (winding)
15-18 ... Power converter 20 ... 1st inverter 21-23 ... 1st upper arm element 24-26 ... 1st lower arm element 30 ... 2nd inverter 31-33 ... -Second upper arm element 34 to 36 ... Second lower arm element 40 ... Battery (voltage source)
51 ... High potential side connection line 55 ... Low potential side connection line 65 ... Control unit

Claims (4)

A power converter for converting electric power of a rotating electric machine (10) having coils (11, 12, 13) of a plurality of phases,
For each phase, a first upper arm element (21 to 23) provided on the high potential side and a first lower arm element (24 to 26) provided on the low potential side of the first upper arm element are provided. A first inverter (20) connected to one end (111, 121, 131) of the coil and the voltage source (40);
For each phase, a second upper arm element (31 to 33) provided on the high potential side and a second lower arm element (34 to 36) provided on the low potential side of the second upper arm element are provided. A second inverter (30) connected to the other end (112, 122, 132) of the coil;
A high potential side connecting line (51) connecting the positive side of the voltage source, the high potential side of the first upper arm element, and the high potential side of the second upper arm element,
A low potential side connecting line (55) connecting the negative side of the voltage source, the low potential side of the first lower arm element, and the low potential side of the second lower arm element,
Y connection control for controlling the first inverter and the second inverter so that the coils of the plurality of phases are in the Y connection state, or an H bridge circuit that makes the coils of the plurality of phases independent, A control unit (65) for performing bridge control for controlling the applied voltage,
Equipped with
Wherein,
When the rotation speed of the rotary electric machine is on the lower limit side of the upper limit value that can be output by the Y connection control or a value on the output side lower than the upper limit value, the Y connection control is performed ,
Wherein when the rotation speed of the rotary electric machine is the Y upper-limit value output at connection control or high rotation speed side than the value of the lower output than the upper limit, the to independent coils of the plurality of phases By controlling the applied voltage for each phase as an H bridge circuit, every half cycle of the sine wave current as the phase current flowing in each phase of the coil,
Complementarily turning on / off the first upper arm element and the first lower arm element of the first inverter, and making the on / off of the second upper arm element and the second lower arm element of the second inverter constant. According to the switching pattern, a current flowing through the coil in the positive direction and a return current according to the positive direction of the current flow,
By turning on and off the first upper arm element and the first lower arm element of the first inverter constant, and turning on and off the second upper arm element and the second lower arm element of the second inverter complementarily. A switching pattern in which a current flowing in the negative direction in the coil and a return current according to the negative direction of the current flow are caused to flow,
A power converter that performs balanced bridge control. The control unit is
  When the rotation speed of the rotating electric machine is higher than the upper limit value that can be output by the Y connection control or higher than the lower output value than the upper limit value, the coils of the plurality of phases are independent. By controlling the applied voltage for each phase as an H bridge circuit, every half cycle of the sine wave current as the phase current flowing in each phase of the coil,
  A switching pattern for complementarily turning on / off the first upper arm element and the first lower arm element of the first inverter, turning off the second upper arm element of the second inverter, and turning on the second lower arm element. When,
  A switching pattern for turning off the first upper arm element of the first inverter, turning on the first lower arm element, and complementarily turning on and off the second upper arm element and the second lower arm element of the second inverter. When,
  The power conversion device according to claim 1, wherein the power conversion device performs balanced bridge control. The high potential side connection line and said at least one of the low-potential-side connection line, the first inverter side and the second inverter side and the disengaging can switch (52, 56) is according to claim 1 or provided The power converter according to 2 . The control unit is
When the drive request of the rotating electric machine is on the low rotation speed side, at least one of the switches is opened, the second inverter is neutralized, and the first inverter is controlled according to the drive request. With Y connection control,
The power converter according to claim 3 , wherein when the drive request is on the high rotation speed side, the switch is closed and the bridge control for controlling the voltage applied to the coil for each phase is performed.

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