JP6329052B2 - Drive device - Google Patents

Description

  The present invention relates to a drive device.

  Conventionally, inverter drive systems for hybrid vehicles are known. For example, in Patent Document 1, two inverters are provided for one motor. In the high voltage mode, the motor is driven by the sum of two power supply voltages by shifting the phase of the fundamental wave component of the pulse width modulation signal by 180 °. In the low voltage mode, one of the upper and lower arms of one inverter is simultaneously turned on for three phases, and the other inverter is controlled by pulse width modulation.

JP 2006-211891 A

Since Patent Document 1 is an inverter drive system for a hybrid vehicle, it is necessary to make two power supply voltages relatively high. Further, in Patent Document 1, there is no mention of power supply to devices that are used at a lower voltage compared to the vehicle main machine, such as accessories and starters. When a load used at a low voltage such as a 12 [V] load is added to the configuration of Patent Document 1, for example, a device such as an alternator needs to be provided separately, which increases the size as a whole.
The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a drive device that can supply power to a load and increase the output of a rotating electrical machine.

The drive device of the present invention includes a rotating electrical machine having a winding, a first inverter, a second inverter, a first control unit, and a second control unit.
The first inverter has a first upper arm element disposed on the high potential side and a first lower arm element disposed on the low potential side, and is connected to one end of the winding, the first power source, and the first load. Is done.
The second inverter has a second upper arm element disposed on the high potential side and a second lower arm element disposed on the low potential side, and is connected to the other end of the winding and the second power source.
The first control unit controls driving of the first inverter.
The second control unit controls driving of the second inverter.
In the first aspect, the voltage of the first power source is equal to or lower than the voltage of the second power source, and the first load is grounded. The second power source and the second control unit are not grounded.
In the second aspect, the second inverter is connected to the second load. The second load is ungrounded.
In the third aspect, the first control unit and the second control unit are power requests that are at least one of a drive request for the rotating electrical machine, a charge state of the first power source and the second power source, and a power supply request for the first load. Accordingly, the drive operation of the first inverter and the second inverter is switched. When the voltage of the first power supply and the voltage of the second power supply are different, the driving operation includes the first inverter connected to the power supply having the lower voltage or the upper arm element of the first phase of the second inverter and the second Turn on the lower arm element of the phase, turn on one of the upper arm element of the first phase or the lower arm element of the second phase of the first inverter or the second inverter connected to the power source having the higher voltage, The power feeding operation for switching on / off at a duty of ½ is included.

  In the present invention, the first power source exchanges power with the rotating electrical machine via the first inverter and supplies power to the load. The rotating electrical machine can be supplied with power from the first power source and the second power source. That is, in the present invention, it can be said that power supply to the load and driving of the rotating electrical machine at a relatively high output are realized by one driving device.

  In addition, since the first inverter and the first power source are provided on one end side of the rotating electrical machine, and the second inverter and the second power source are provided on the other end side, for example, by performing an inversion driving operation, A voltage corresponding to the sum of the first power supply voltage and the second power supply voltage can be applied. As a result, compared to the case where the rotating electrical machine is driven by a single power source, the output of the rotating electrical machine can be increased without a significant increase in current, and the entire system including wiring and the like can be downsized. it can.

1 is a schematic configuration diagram showing an accessory drive system according to a first embodiment of the present invention. It is explanatory drawing explaining the 1st one-side drive operation by 1st Embodiment of this invention. It is explanatory drawing explaining the on-off state of a switching element and drive voltage in the 1st single side drive operation | movement of 1st Embodiment of this invention. It is explanatory drawing explaining the 2nd single side drive operation | movement by 1st Embodiment of this invention. It is explanatory drawing explaining the on-off state and drive voltage of a switching element in the 2nd single side drive operation | movement of 1st Embodiment of this invention. It is explanatory drawing explaining the inversion drive operation | movement by 1st Embodiment of this invention. It is explanatory drawing explaining the on-off state of a switching element and drive voltage in the inversion drive operation of 1st Embodiment of this invention. It is explanatory drawing explaining the on-off state of a switching element and drive voltage in the inversion drive operation of 1st Embodiment of this invention. It is explanatory drawing explaining the common mode drive operation | movement by 1st Embodiment of this invention. It is explanatory drawing explaining the on-off state and driving voltage of a switching element in the common mode drive operation | movement of 1st Embodiment of this invention. It is explanatory drawing explaining the electric power feeding operation | movement by 1st Embodiment of this invention. It is explanatory drawing explaining the on-off state of the switching element in the electric power feeding operation | movement of 1st Embodiment of this invention. It is a schematic block diagram which shows the auxiliary machinery drive system by 2nd Embodiment of this invention.

Hereinafter, a drive device according to the present invention will be described with reference to the drawings. Hereinafter, in a plurality of embodiments, the same numerals are given to the substantially same composition, and explanation is omitted.
(First embodiment)
The drive device by 1st Embodiment of this invention is demonstrated based on FIGS.
As shown in FIG. 1, the drive device 1 of this embodiment is applied to an auxiliary machine drive system 5 mounted on a vehicle (not shown). The auxiliary machine drive system 5 includes a drive device 1, a first power supply 41, a second power supply 42, a load 51 as a first load, and the like.

The drive device 1 includes a motor generator 10 as a rotating electrical machine, a first inverter 20, a second inverter 30, a first control unit 61, a second control unit 62, and the like.
The motor generator 10 is a three-phase AC rotating machine. The motor generator 10 of the present embodiment is connected to the engine 8 and is driven by the electric power of the first power supply 41 and the second power supply 42 to function as a starter that starts the engine 8 and kinetic energy transmitted from the engine 8. It is an ISG (Integrated Starter Generator) that also has a function as an alternator that is driven by the generator to generate electric power.

  Motor generator 10 has a U-phase coil 11, a V-phase coil 12, and a W-phase coil 13. U-phase coil 11, V-phase coil 12 and W-phase coil 13 correspond to “windings”. Hereinafter, the U-phase coil 11, the V-phase coil 12, and the W-phase coil 13 are referred to as "coils 11 to 13" as appropriate. Further, the current supplied to the U-phase coil 11 is referred to as U-phase current Iu, the current supplied to the V-phase coil 12 is referred to as V-phase current Iv, and the current supplied to the W-phase coil 13 is referred to as W-phase current Iw.

The first inverter 20 is a three-phase inverter, and switches the first upper arm elements 21 to 23 arranged on the high potential side and the first lower arm arranged on the low potential side in order to switch energization to the coils 11 to 13. Elements 24 to 26 are connected.
The first inverter 20 is connected to one ends 111, 121, 131 of the coils 11-13. Specifically, a connection point 27 between the U-phase first upper arm element 21 and the first lower arm element 24 is connected to one end 111 of the U-phase coil 11. A connection point 28 between the V-phase first upper arm element 22 and the first lower arm element 25 is connected to one end 121 of the V-phase coil 12. A connection point 29 between the W-phase first upper arm element 23 and the first lower arm element 26 is connected to one end 131 of the W-phase coil 13.
The first inverter 20 is connected to the first power supply 41 and the load 51.

The second inverter 30 is a three-phase inverter, and the second upper arm elements 31 to 33 disposed on the high potential side and the second lower arm disposed on the low potential side in order to switch energization to the coils 11 to 13. Elements 34 to 36 are connected.
The second inverter 30 is connected to the other ends 112, 122, 132 of the coils 11-13. Specifically, a connection point 37 between the U-phase second upper arm element 31 and the second lower arm element 34 is connected to the other end 112 of the U-phase coil 11. A connection point 38 between the V-phase second upper arm element 32 and the second lower arm element 35 is connected to the other end 122 of the V-phase coil 12. A connection point 39 between the W-phase second upper arm element 33 and the second lower arm element 36 is connected to the other end 132 of the W-phase coil 13.
The second inverter 30 is connected to the second power source 42.

Thus, in this embodiment, the 1st inverter 20 and the 2nd inverter 30 are connected to the both ends of the coils 11-13.
Hereinafter, the first upper arm elements 21 to 23, the first lower arm elements 24 to 26, the second upper arm elements 31 to 33, and the second lower arm elements 34 to 36 are appropriately connected to the switching elements 21 to 26, 31 to 31, respectively. 36. In addition, a corresponding phase and an inverter are written together, such as “U1 upper arm element 21”.
Although the switching elements 21 to 26 and 31 to 36 of the present embodiment are IGBTs (Insulated Gate Bipolar Transistors), for example, MOS (Metal Oxide Semiconductor) transistors, bipolar transistors, or the like may be used.

The first power source 41 is a chargeable / dischargeable DC power source, is connected to the first inverter 20, and is provided so as to be able to exchange power with the motor generator 10 via the first inverter 20. The 1st power supply 41 of this embodiment is a 12 [V] lead acid battery.
The second power source 42 is a chargeable / dischargeable DC power source, is connected to the second inverter 30, and is provided so as to be able to exchange power with the motor generator 10 via the second inverter 30. The second power source 42 of the present embodiment is a 48 [V] lithium storage battery.
In the present embodiment, the voltage of the first power supply 41 is the first power supply voltage V1, and the voltage of the second power supply 42 is the second power supply voltage V2. In the present embodiment, the first power supply 41 has a higher capacity than the second power supply 42, and the second power supply 42 has a higher output than the first power supply 41.

The first capacitor 43 is a smoothing capacitor that smoothes the current from the first power supply 41 to the first inverter 20 side or the current from the first inverter 20 to the first power supply 41 side.
The second capacitor 44 is a smoothing capacitor that smoothes the current from the second power source 42 to the second inverter 30 side or the current from the second inverter 30 side to the second power source 42 side.

  The load 51 is a constant voltage load to which power from the first power supply 41 is supplied. The load 51 includes, for example, auxiliary equipment and electrical components to which the power of the first power supply 41 is supplied via an accessory power supply (not shown). At least some of the negative terminals of the load 51 are grounded by being connected to a vehicle body (not shown). In the present embodiment, the load 51 corresponds to the “first load”.

The 1st control part 61 and the 2nd control part 62 are comprised as a normal computer, and are provided with CPU, ROM, RAM, I / O, the bus line which connects these, etc. inside.
The first control unit 61 controls the driving of the first inverter 20 based on the driving request of the motor generator 10, the charging states of the first power supply 41 and the second power supply 42, and the power request which is a power supply request of the load 51. . Specifically, the first control unit 61 generates a first control signal for controlling the on / off operation of the switching elements 21 to 26 of the first inverter 20 so that the driving operation according to the power request is performed, and the switching element 21. Output to ~ 26 gates.

  The second control unit 62 controls the driving of the second inverter 30 based on the driving request of the motor generator 10, the charging states of the first power supply 41 and the second power supply 42, and the power request that is the power supply request of the load 51. . Specifically, the second control unit 62 generates a second control signal that controls the on / off operation of the switching elements 31 to 36 of the second inverter 30 so that the driving operation according to the power request is performed, and the switching element 31. Output to ~ 36 gates.

In the present embodiment, the first inverter 20, the first power supply 41, the first capacitor 43, the load 51, and the first control unit 61 are the first system 101, and the second inverter 30, the second power supply 42, the second capacitor 44 and the second control unit 62 are the second system 102.
If both the first system 101 and the second system 102 are grounded by body ground, current flows between the first system 101 and the second system 102 via the vehicle body, and the motor generator 10 cannot be driven. . In the present embodiment, since the first system 101 side is grounded by grounding at least a part of the load 51, the second system 102 side is not grounded.

Here, operation | movement of the drive device 1 is demonstrated based on FIGS. In FIG. 2 and the like, switching elements that are turned on are indicated by solid lines, and switching elements that are turned off are indicated by broken lines. 2 and the like, the description of the engine 8, the first control unit 61, and the second control unit 62 is omitted.
First, the driving operation of the first inverter 20 and the second inverter 30 will be described in the case where the motor generator 10 is driven using the power of at least one of the first power supply 41 and the second power supply 42.

(1) First one-side drive operation When the motor generator 10 is driven by the electric power of the first power supply 41, the first inverter 20 and the second inverter 30 are set to the first one-side drive operation. In the first one-side drive operation, as shown in FIG. 2, the second phase can be obtained by turning on all the phases of the second upper arm elements 31 to 33 or turning off one of the second lower arm elements 34 to 36 and turning off the other. The inverter 30 is neutralized. In order to reduce the bias of heat loss, the state in which the second upper arm elements 31 to 33 are turned on and the state in which the second lower arm elements 34 to 36 are turned on may be appropriately switched.
Further, the first inverter 20 is controlled according to the power demand.

In the example shown in FIG. 2, the U1 upper arm element 21, the V1 lower arm element 25, the W1 lower arm element 26, and the second upper arm elements 31 to 33 are turned on. At this time, a current in a path indicated by an arrow Y11 flows in FIG.
Further, as indicated by an arrow YL1, power is supplied to the load 51 from the first power supply 41. The same applies to the second one-side driving operation and the inversion driving operation described later.

FIG. 3 shows an example of U-phase control, where (a) is the fundamental wave related to the U-phase current Iu, (b) is the on / off state of the U1 upper arm element 21, and (c) is the U1 lower arm element 24. (D) shows the on / off state of the U2 upper arm element 31, (e) shows the on / off state of the U2 lower arm element 34, and (f) shows the drive voltage applied to the motor generator 10. The same applies to FIG. 5, FIG. 7, FIG. 8, and FIG.
As shown in FIG. 3, the first inverter 20 is switched by PWM control or the like by comparing the first fundamental wave F1 and the carrier wave according to the power demand, and the second inverter 30 is neutralized, so that the motor The generator 10 is applied with a driving voltage whose pulse height is the first power supply voltage V1.

(2) Second one-side drive operation When the motor generator 10 is driven by the electric power of the second power source 42, the first inverter 20 and the second inverter 30 are set to the second one-side drive operation. In the second one-side drive operation, as shown in FIG. 4, by turning on one of all phases of the first upper arm elements 21 to 23 or all phases of the first lower arm elements 24 to 26 and turning off the other. The first inverter 20 is neutralized. In order to reduce the bias of heat loss, the state in which the first upper arm elements 21 to 23 are turned on and the state in which the first lower arm elements 24 to 26 are turned on may be appropriately switched.
Further, the second inverter 30 is controlled according to the power demand.

In the example shown in FIG. 4, the first upper arm elements 21 to 23, the U2 upper arm element 31, the V2 lower arm element 35, and the W2 lower arm element 36 are turned on. At this time, a current in a path indicated by an arrow Y12 in FIG. 4 flows.
As shown in FIG. 5, the first inverter 20 is neutralized, and the second inverter 30 is switched by PWM control or the like based on comparison between the second fundamental wave F2 and the carrier wave according to the power demand. 10, a drive voltage having a pulse height of the second power supply voltage V2 is applied.

(3) Inversion Drive Operation When the motor generator 10 is driven by the power of the first power supply 41 and the second power supply 42, the first inverter 20 and the second inverter 30 are set to the inversion drive operation. In the inversion driving operation, the driving of the first inverter 20 is controlled based on the first fundamental wave F1 corresponding to the power request, and the driving of the second inverter 30 is controlled based on the second fundamental wave F2 corresponding to the power request. .

  In the present embodiment, the first control unit 61 generates a first control signal by comparing the first fundamental wave F1 according to the voltage command of the first inverter 20 and the carrier wave, and the second control unit 62 performs the second inverter. It is assumed that the second control signal is generated by comparing the second fundamental wave F2 and the carrier wave according to 30 voltage commands. In the inversion driving operation, the phases of the first fundamental wave F1 and the second fundamental wave F2 are inverted. In other words, the first fundamental wave F1 and the second fundamental wave F2 are out of phase by approximately 180 [°]. The phase difference between the first fundamental wave F1 and the second fundamental wave F2 is 180 [°], but a voltage corresponding to the sum of the first power supply voltage V1 and the second power supply voltage V2 is supplied to the motor generator 10. Deviations that can be applied are allowed.

When the amplitude of the first fundamental wave F1 and the amplitude of the second fundamental wave F2 are equal, the first inverter 20 and the second inverter 30 are turned upside down in the elements that are turned on in each phase. In the example shown in FIG. 6, the U1 upper arm element 21, the V1 lower arm element 25, the W1 lower arm element 26, the V2 upper arm element 32, the W2 upper arm element 33, and the U2 lower arm element 34 are turned on. In FIG. 6, a current of a path indicated by an arrow Y13 flows.
The first fundamental wave F1 and the second fundamental wave F2 may have the same or different amplitudes. Further, the first fundamental wave F1 and the second fundamental wave F2 may have the same waveform as in the case where both are sine waves. For example, one of the first inverter 20 and the second inverter 30 may be a sine wave. The waveforms may be different as in the case of PWM control and overmodulation PWM control of the other. The same applies to the common-phase driving operation described later.
Note that, when the amplitude and the waveform are different in the inversion driving operation, the elements that are turned on in each phase are not necessarily upside down in the first inverter 20 and the second inverter 30.

  FIG. 7 shows an example of the phase inversion control. A voltage corresponding to the sum of the first power supply voltage V1 and the second power supply voltage V2 (that is, V1 + V2) is applied to the motor generator 10 as a drive voltage. Is done.

  In the inversion driving operation, as shown in FIG. 8, in the second inverter 30, instead of the PWM control based on the comparison between the second fundamental wave and the carrier wave, the switching elements 31 to 36 are switched every half cycle of the second fundamental wave. It is good also as the rectangular wave control which switches on-off. Thereby, switching loss can be reduced.

  In the present embodiment, the motor generator 10 is an ISG and functions as a starter of the engine 8. For this reason, when a high output operation such as return from idle stop or cold start is necessary, the first inverter 20 and the second inverter 30 are driven in an inverted manner, and the electric power from the first power supply 41 and the second power supply 42 is obtained. Is supplied to the motor generator 10, the output of the motor generator 10 can be increased.

(4) In-phase driving operation In the in-phase driving operation, the first fundamental wave F1 and the second fundamental wave F2 have the same phase and the phase difference is 0 [°], but the first power supply voltage V1 and the second power supply voltage A deviation that allows a voltage corresponding to the difference from V2 to be applied to the motor generator 10 is allowed.
When the amplitude of the first fundamental wave F1 and the amplitude of the second fundamental wave F2 are equal, the elements that are turned on in each phase are the same up and down in the first inverter 20 and the second inverter 30. In the example shown in FIG. 9, the U1 upper arm element 21, the V1 lower arm element 25, the W1 lower arm element 26, the U2 upper arm element 31, the V2 lower arm element 35, and the W2 lower arm element 36 are turned on. , A current in a path indicated by an arrow Y14 flows.

At this time, a voltage corresponding to the difference between the first power supply voltage V1 and the second power supply voltage V2 is applied to the motor generator 10 as a drive voltage, and the power supply with the lower voltage is charged with the power of the power supply with the higher power supply. The FIG. 10 shows an example of the in-phase driving operation. Since the second power supply voltage V2 is larger than the first power supply voltage V1, a voltage corresponding to the pulse height (V2−V1) is applied to the motor generator 10 as the driving voltage. And the first power supply 41 is charged by the power of the second power supply 42.
Further, as indicated by an arrow YL2 in FIG. 9, power is supplied to the load 51 from the second power source 42.
Since the in-phase driving operation involves charging of the first power supply 41, the SOC of the first power supply 41 is close to the upper limit value and is not executed when the first power supply 41 cannot be charged.

When driving the motor generator 10, the lower the drive voltage, the smaller the loss. For this reason, it is desirable to select a drive operation having the smallest drive voltage among drive operations capable of realizing the required rotation speed and torque.
When the first power supply voltage V1 and the second power supply voltage V2 are equal, the drive voltage applied to the motor generator 10 in the first one-side drive operation and the motor generator 10 applied in the second one-side drive operation. It is equal to the drive voltage. In this case, for example, the first one-side driving operation and the second one-side driving operation may be appropriately switched according to the heat loss of the switching elements 21 to 26 and 31 to 36, for example.

Next, operations of the first inverter 20 and the second inverter 30 when the motor generator 10 is driven by the engine 8 to generate power will be described.
First inverter 20 and second inverter 30 are set to the first one-side drive operation, second inverter 30 is neutralized, and first inverter 20 is regenerated based on the power generated by motor generator 10. As a result, a current in the direction opposite to the arrow Y11 in FIG. 2 flows, the first power supply 41 is charged by the power generated by the motor generator 10, and the power generated by the motor generator 10 is supplied to the load 51.

  Further, the first inverter 20 and the second inverter 30 are set to the second one-side drive operation, the first inverter 20 is neutralized, and the second inverter 30 is regenerated based on the generated power of the motor generator 10. Thereby, a current in the direction opposite to the arrow Y12 in FIG. 4 flows, and the second power source 42 is charged.

(5) Power Supply Operation Next, a power supply operation for supplying power from the second power source 42 to the first power source 41 and the load 51 side with the motor generator 10 stopped will be described with reference to FIGS. 12, (a) is the U-phase current Iu, (b) is the on / off state of the U1 upper arm element 21, (c) is the on / off state of the V1 lower arm element 25, and (d) is the on / off state of the U2 upper arm element 31. The state (e) shows the on / off state of the V2 lower arm element 35.

  In the power feeding operation, in the first inverter 20, the upper arm element of the first phase and the lower arm element of the second phase are always turned on in order to pass a direct current to a specific phase. In the second inverter 30, one of the upper arm element of the first phase and the lower arm element of the second phase is always turned on, and the other is switched on and off with a predetermined duty. The “predetermined duty” related to the on / off switching is set according to the amount of power supplied to the load 51 and the amount of charge charged to the first power supply 41.

  For example, as shown in FIGS. 11 and 12, when the first phase is the U phase and the second phase is the V phase, the U1 upper arm element 21 and the V1 lower arm element 25 of the first inverter 20 are turned on, and the second inverter One of the 30 U2 upper arm elements 31 and the V2 lower arm element 35 is turned on, and the other is switched on and off with a predetermined duty. In the present embodiment, the U2 upper arm element 31 is turned on and the V2 lower arm element 35 is turned on and off with a predetermined duty. FIG. 11 shows a state where the V2 lower arm element 35 is turned on.

  Further, the coils 11 to 13 and the capacitors 43 and 44 of the motor generator 10 can be regarded as an LC circuit, and the current supplied during the power feeding operation is a direct current rectified by the LC circuit. In the example of FIG. 11, as indicated by an arrow Y <b> 15, a direct current flows from the second inverter 30 side to the first inverter 20 side in the U-phase coil 11, and in the V-phase coil 12 from the first inverter 20 side to the second inverter. A direct current flows to the 30 side.

  In the present embodiment, the switching elements 21 to 26 of the first inverter 20 have a free-wheeling diode that allows a current to flow from the low voltage side to the high voltage side. The upper arm element of the first phase and the lower arm element of the second phase may not be turned on.

By the power feeding operation, the power of the second power source 42 is fed to the first power source 41 and the load 51. In the power feeding operation, since a direct current is supplied to a specific phase, the rotor of the motor generator 10 is slightly rotated to the lock position corresponding to the current when the direct current starts to flow. However, this is not a problem when viewed as a whole system. is there. In addition, it is desirable to select a phase through which a direct current is applied so that the amount of movement of the rotor is reduced according to the rotor position.
That is, in the example of FIG. 11 and FIG. 12, the first phase is the U phase and the second phase is the V phase, but the first phase may be any of the U phase, the V phase, or the W phase. The two phases may be any of the two phases other than the first phase.

As described above in detail, the drive device 1 includes the motor generator 10, the first inverter 20, the second inverter 30, the first control unit 61, and the second control unit 62.
The motor generator 10 has coils 11 to 13.
The first inverter 20 includes first upper arm elements 21 to 23 disposed on the high potential side and first lower arm elements 24 to 26 disposed on the low potential side, and one ends 111 and 121 of the coils 11 to 13. 131, the first power supply 41, and the load 51.
The second inverter 30 includes second upper arm elements 31 to 33 disposed on the high potential side and second lower arm elements 34 to 36 disposed on the low potential side, and the other ends 112 of the coils 11 to 13, 122, 132 and the second power source 42.
The first control unit 61 controls driving of the first inverter 20.
The second control unit 62 controls driving of the second inverter 30.

  The first power supply 41 of the present embodiment performs power transfer with the motor generator 10 via the first inverter 20 and supplies power to the load 51 that is a constant voltage load. The motor generator 10 can be supplied with power from the first power supply 41 and the second power supply 42. That is, in this embodiment, it can be said that the power supply to the load 51 and the driving of the motor generator 10 at a relatively high output are realized by one driving device 1.

  In addition, a first inverter 20 and a first power supply 41 are provided on one end side of the motor generator 10, and a second inverter 30 and a second power supply 42 are provided on the other end side to perform an inversion driving operation. A voltage corresponding to the sum of the first power supply voltage V1 and the second power supply voltage can be applied to the motor generator 10. As a result, compared with the case where the motor generator 10 is driven by a single power source, the motor generator 10 can have a higher output without causing a significant increase in current, and the entire system including wiring and the like can be downsized. be able to.

The first power supply voltage V1 is equal to or lower than the second power supply voltage V2, the load 51 is grounded, and the second power supply 42 and the second control unit 62 are not grounded.
Thereby, motor generator 10 can be driven appropriately.
The first power supply 41 has a higher capacity than the second power supply 42, and the second power supply 42 has a higher output than the first power supply 41. As a result, power can be stably supplied from the first power supply 41 to the load 51. Further, when it is desired to increase the output of the motor generator 10, it is possible to increase the output of the motor generator 10 by supplying power from the second power supply 42 side.

The first control unit 61 and the second control unit 62 respond to a power request that is at least one of a drive request for the motor generator 10, a charge state of the first power supply 41 and the second power supply 42, and a power supply request for the load 51. The driving operation of the first inverter 20 and the second inverter 30 is switched.
By switching the driving operation of the first inverter 20 and the second inverter 30, the driving of the motor generator 10, the charging of the first power source 41 and the second power source 42, and the power feeding to the load 51 can be appropriately controlled. .

The driving operation includes a first one-side driving operation, a second one-side driving operation, and an inversion driving operation.
In the first one-side drive operation, the second inverter 30 is neutralized and the first inverter 20 is controlled based on the power demand.

In the second one-side drive operation, the first inverter 20 is neutralized and the second inverter 30 is controlled based on the power demand.
The inversion operation is an operation of driving the first inverter 20 based on the first fundamental wave F1 corresponding to the power request and driving the second inverter 30 based on the second fundamental wave F2 corresponding to the power request, The phase of the first fundamental wave F1 and the phase of the second fundamental wave F2 are inverted.

  The first power supply voltage V1 in the first one-side drive operation, the second power supply voltage V2 in the second one-side drive operation, and the voltage corresponding to the sum of the first power supply voltage V1 and the second power supply voltage V2 in the inversion drive operation (that is, V1 + V2). Is applied to the motor generator 10. By switching the driving operation according to the power demand and applying the optimum voltage to the motor generator 10, the loss in the driving device 1 can be reduced.

In the inversion driving operation, the first inverter 20 is subjected to pulse width modulation (PWM) control based on the carrier wave and the first fundamental wave F1, and the second inverter 30 has a pulse width based on the carrier wave and the second fundamental wave F2. Modulated (PWM) controlled.
Thereby, the 1st inverter 20 and the 2nd inverter 30 can be appropriately inverting driven.

Further, the inversion driving operation may be performed as follows. That is, the first inverter 20 is subjected to pulse width modulation (PWM) control based on the carrier wave and the first fundamental wave F1, and the second inverter 30 is controlled by the switching elements 31 to 36 every half cycle of the second fundamental wave F2. A rectangular wave that switches on and off is controlled.
Further, the second inverter 30 is subjected to pulse width modulation control based on the carrier wave and the second fundamental wave F2, and the first inverter 20 is a rectangular wave that switches on and off the switching elements 21 to 26 every half cycle of the first fundamental wave F1. It is good also as control.
In the first inverter 20 or the second inverter 30 that is controlled by the rectangular wave, the number of times of switching can be reduced, so that the switching loss can be reduced. Since the switching loss increases as the voltage increases, rectangular wave control of the inverter on the side to which the high voltage is applied has a greater effect of reducing the switching loss.

When the first power supply voltage V1 and the second power supply voltage V2 are different, the drive operation includes an in-phase drive operation.
The in-phase driving operation is an operation of driving the first inverter 20 based on the first fundamental wave F1 and driving the second inverter 30 based on the second fundamental wave F2, and the phase of the first fundamental wave F1 and the first The two fundamental waves F2 have the same phase.
Thus, for example, when the second power supply voltage V2 is higher than the first power supply voltage V1, the first power supply 41 can be charged while driving the motor generator 10 by the power of the second power supply 42.

When the first power supply voltage V1 and the second power supply voltage V2 are different, the driving operation includes a power feeding operation.
In the power feeding operation, the upper arm element of the first phase and the lower arm element of the second phase of the first inverter 20 or the second inverter 30 connected to the power source having the lower voltage are turned on. Also, one of the upper arm element of the first phase and the lower arm element of the second phase connected to the power source having the higher voltage is turned on, and the other is turned on / off with a predetermined duty.
As a result, a direct current flows in the first phase and the second phase, so that power can be supplied from the high voltage side to the low voltage side without driving the motor generator 10.

The motor generator 10 is connected to the engine 8 and has a starter function that is driven by the power of at least one of the first power supply 41 and the second power supply 42 to start the engine 8, and an alternator function that is driven by the engine 8 to generate power. Have.
Since the starter function, the alternator function, and the power supply to the load 51 are realized by one drive device 1, the system can be simplified. Further, when the motor generator 10 is used as a starter, such as when returning from an idle stop, the motor generator 10 can be operated at a high voltage by performing an inversion driving operation, so that an increase in current can be suppressed. Thereby, the accessory drive system 5 can be reduced in size.

(Second Embodiment)
A drive system according to a second embodiment of the present invention is shown in FIG.
As shown in FIG. 13, the auxiliary machine drive system 6 is provided with a load 52 that is a constant voltage load to which the power of the second power source 42 is supplied. Since the second power source 42 is a 48 [V] power source, the load 52 is preferably a power source that requires a relatively large amount of power, such as a pump or a motor.
In the present embodiment, the second inverter 30, the second power source 42, the second capacitor 44, the load 52, and the second control unit 62 constitute the second system 103, and the load 52 corresponds to the “second load”. .

As described in the above embodiment, when both the first system 101 and the second system 103 are connected to the vehicle body, a current flows through the vehicle body, so that the motor generator 10 cannot be driven. In general, the load 51 connected to the first power supply 41 which is a 12 [V] power supply is often grounded to the vehicle body. Therefore, the load 52 connected to the second power source 42 is insulated, and the second system 103 is not grounded.
The driving operation of this embodiment is the same as that of the above embodiment.

In the present embodiment, the second inverter 30 is connected to the load 52. The load 52 is not grounded.
For example, when the first power supply voltage V1 and the second power supply voltage V2 are different, it is possible to supply power of an appropriate voltage to the loads 51 and 52.
In addition, the same effects as those of the above embodiment can be obtained.

(Other embodiments)
In the above embodiment, the first power source is a 12 [V] power source, and the second power source is a 48 [V] power source. In another embodiment, the voltage of the first power source and the second power source is not limited to 12 [V] and 48 [V], and may be any number. In the above embodiment, the second power supply voltage is higher than the first power supply voltage. In other embodiments, the first power supply voltage may be greater than or equal to the second power supply voltage.

  In the above embodiment, the first power source is a lead storage battery, and the second power source is a lithium storage battery. In other embodiments, the first power source and the second power source may use any chargeable / dischargeable power storage device such as an electric double layer capacitor. Further, the first power source and the second power source may be the same or different types of power storage devices.

In the above embodiment, in the inversion driving operation, the example in which both the first inverter and the second inverter are PWM-controlled, and the example in which the first inverter is PWM-controlled and the second inverter is rectangular-wave controlled have been described. In another embodiment, the first inverter may be subjected to rectangular wave control, and the second inverter may be subjected to PWM control.
Further, the first inverter and the second inverter may be controlled by a control method other than PWM control.

In the above embodiment, the rotating electrical machine is an ISG. In another embodiment, the rotating electrical machine may be a device other than ISG. Moreover, in the said embodiment, a drive device is applied to the auxiliary machinery drive system of a vehicle. In another embodiment, the drive device may be applied to a system other than the accessory drive system. In addition, when applying a drive device other than a vehicle, you may earth | ground by methods other than body earth.
As mentioned above, this invention is not limited to the said embodiment at all, In the range which does not deviate from the meaning of invention, it can implement with a various form.

DESCRIPTION OF SYMBOLS 1 ... Drive device 10 ... Motor generator (rotary electric machine)
DESCRIPTION OF SYMBOLS 20 ... 1st inverter 30 ... 2nd inverter 41 ... 1st power supply 42 ... 2nd power supply 51 ... Load (1st load)
52 ... Load (second load)
61 ... 1st control part 62 ... 2nd control part

Claims (11)

A rotating electrical machine (10) having windings (11, 12, 13);
The first upper arm elements (21 to 23) disposed on the high potential side and the first lower arm elements (24 to 26) disposed on the low potential side, and one end (111, 121, 131) of the winding. ), A first power source (41), and a first inverter (20) connected to the first load (51);
A second upper arm element (31 to 33) disposed on the high potential side and a second lower arm element (34 to 36) disposed on the low potential side, and the other end (112, 122, 132) and a second inverter (30) connected to the second power source (41);
A first control unit (61) for controlling driving of the first inverter;
A second control unit (62) for controlling the driving of the second inverter;
Equipped with a,
The voltage of the first power source is equal to or lower than the voltage of the second power source,
The first load is grounded;
The drive device (1), wherein the second power source and the second control unit are ungrounded . The second inverter is connected to a second load (52),
The drive device according to claim 1, wherein the second load is ungrounded. A rotating electrical machine (10) having windings (11, 12, 13);
The first upper arm elements (21 to 23) disposed on the high potential side and the first lower arm elements (24 to 26) disposed on the low potential side, and one end (111, 121, 131) of the winding. ), A first power source (41), and a first inverter (20) connected to the first load (51);
A second upper arm element (31 to 33) disposed on the high potential side and a second lower arm element (34 to 36) disposed on the low potential side, and the other end (112, 122, 132) and a second inverter (30) connected to the second power source (41);
A first control unit (61) for controlling driving of the first inverter;
A second control unit (62) for controlling the driving of the second inverter;
Equipped with a,
The second inverter is connected to a second load (52),
The drive device (1) , wherein the second load is ungrounded . The first power source has a higher capacity than the second power source;
Said second power source, a driving apparatus according to any one of claims 1-3, characterized in that said a high output from the first power supply. The first control unit and the second control unit are at least one of a drive request for the rotating electrical machine, a charge state of the first power source and the second power source, and a power supply request for the first load. in response, the driving device according to any one of claims 1 to 4, characterized in that switches the driving operation of the first inverter and the second inverter. A rotating electrical machine (10) having windings (11, 12, 13);
The first upper arm elements (21 to 23) disposed on the high potential side and the first lower arm elements (24 to 26) disposed on the low potential side, and one end (111, 121, 131) of the winding. ), A first power source (41), and a first inverter (20) connected to the first load (51);
A second upper arm element (31 to 33) disposed on the high potential side and a second lower arm element (34 to 36) disposed on the low potential side, and the other end (112, 122, 132) and a second inverter (30) connected to the second power source (41);
A first control unit (61) for controlling driving of the first inverter;
A second control unit (62) for controlling the driving of the second inverter;
Equipped with a,
The first control unit and the second control unit are at least one of a drive request for the rotating electrical machine, a charge state of the first power source and the second power source, and a power supply request for the first load. In response to this, the drive operation of the first inverter and the second inverter is switched,
When the voltage of the first power source is different from the voltage of the second power source,
In the driving operation,
Turning on the upper arm element of the first phase and the lower arm element of the second phase of the first inverter or the second inverter connected to the power source having the lower voltage;
One of the upper arm element of the first phase or the lower arm element of the second phase of the first inverter or the second inverter connected to the power source having the higher voltage is turned on, and the other is turned on / off with a predetermined duty. A driving device (1) including a power feeding operation for switching . In the driving operation,
A first one-side drive operation for neutralizing the second inverter and controlling the first inverter based on the power demand;
A second one-side drive operation for neutralizing the first inverter and controlling the second inverter based on the power demand;
And an operation of driving the first inverter based on a first fundamental wave corresponding to the power demand and driving the second inverter based on a second fundamental wave corresponding to the power demand, wherein 7. The driving apparatus according to claim 5, further comprising an inversion driving operation in which a phase of one fundamental wave and a phase of the second fundamental wave are inverted. In the inversion driving operation,
The first inverter is subjected to pulse width modulation control based on a carrier wave and the first fundamental wave,
The drive device according to claim 7 , wherein the second inverter is subjected to pulse width modulation control based on the carrier wave and the second fundamental wave. In the inversion driving operation,
One of the first inverter or the second inverter is subjected to pulse width modulation control based on the carrier wave and the corresponding first fundamental wave or the second fundamental wave,
Said first inverter or the other of said second inverter, claim characterized in that it is controlled square wave to switch on and off of the switching element for each half cycle of said corresponding first fundamental wave or the second fundamental wave 7 The drive device described in 1. When the voltage of the first power source is different from the voltage of the second power source,
In the driving operation,
An operation of driving the first inverter based on the first fundamental wave and driving the second inverter based on the second fundamental wave, wherein the phase of the first fundamental wave and the second fundamental wave The drive device according to any one of claims 7 to 9 , wherein a common-phase drive operation in which the phase is the same phase is included.   The rotating electrical machine is connected to an engine (5) and is driven by power of at least one of the first power source and the second power source to start the engine, and an alternator that is driven by the engine to generate electric power It has a function, The drive device as described in any one of Claims 1-10 characterized by the above-mentioned.

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