JP2012065479A - Motor drive device and vehicle equipped with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a loss in a motor drive device including a plurality of electric power converters without using complicated control logic.SOLUTION: A motor drive device 20 includes a converter 12 and inverters 14, 22, which are electric power converters, and an ECU 30, and drives motor generators MG1, MG2 by using an electric power from an electric power storage device 28. The ECU 30 calculates a loss of each electric power converter at a system voltage VH applied to the inverters 14, 22 and sets a voltage command value for the system voltage VH so that a loss generated in an electric power converter, where obtained loss becomes maximum, becomes minimum in a range where a drive command value of the electric power converter is attainable.

Description

  The present invention relates to a motor drive device and a vehicle on which the motor drive device is mounted, and more particularly to control for reducing the loss of the motor drive device.

  2. Description of the Related Art In recent years, attention has been paid to a vehicle that is mounted with a power storage device (for example, a secondary battery or a capacitor) and travels using driving force generated from electric power stored in the power storage device as an environment-friendly vehicle. Such vehicles include, for example, electric vehicles, hybrid vehicles, fuel cell vehicles, and the like.

  In these vehicles, when starting or accelerating, a rotating electric machine (which receives electric power from the power storage device to generate a driving force for traveling and generates electric power by regenerative braking during braking to store electric energy in the power storage device ( In some cases, a motor driving device including a motor generator is mounted. And in order to control the motor generator according to such a driving | running | working state, an inverter is mounted in a vehicle.

  In such a vehicle, the electric power required by the inverter varies depending on the vehicle state. In some cases, a converter is provided between the power storage device and the inverter in order to stably supply power required by the inverter. This converter boosts the inverter input voltage higher than the output voltage of the power storage device to increase the output of the motor and reduce the motor current at the same output, thereby reducing the size and cost of the inverter and motor. Can be achieved.

  In such a motor drive device, it is desired to improve efficiency by reducing the loss of the device from the viewpoint of energy saving. However, as there are many power conversion devices such as inverters and converters included in a motor drive device, and the system configuration becomes more complicated, the technique for reducing the loss of the entire device can also become more complicated.

  Japanese Patent Laying-Open No. 2010-035386 (Patent Document 1) is a system operation control device for operating a system including a plurality of components, and obtains a slope of loss in each component and is obtained for each component. A configuration is disclosed in which the system voltage supplied to the system is set by feedback control so that the total value of the loss slope becomes zero, thereby reducing the total loss for a plurality of components.

JP 2010-035386 A

  In the configuration disclosed in Japanese Patent Laid-Open No. 2010-035386 (Patent Document 1), it is possible to set a system voltage for minimizing the loss of the entire system, but the total value of the slope of the loss is zero. Therefore, it is necessary to perform the feedback control so that the control logic becomes complicated and the calculation load may be increased.

  Further, in order to perform feedback control, it is necessary to design and adjust the feedback gain.

  The present invention has been made to solve such a problem, and an object of the present invention is to reduce loss in a motor drive device including a plurality of power conversion devices without using complicated control logic. It is.

  According to the motor drive device of the present invention, the first motor, the first and second power conversion devices, and the control device are provided, and the motor is driven using the power from the DC power supply. A 1st power converter device is an inverter for driving a 1st motor using the electric power from DC power supply. The second power conversion device is connected to a terminal on the DC side in the first power conversion device. The control device controls the first and second power conversion devices. And a control apparatus calculates the loss of the 1st and 2nd power converter device with respect to the supply voltage to a 1st power converter device, and based on the loss which arises in the power converter device with which the obtained loss becomes the largest The voltage command value of the supply voltage supplied to the first power converter is set.

  Preferably, the control device sets the voltage command value so that the loss that occurs in the power conversion device having the maximum loss is minimized within a range where the drive command value for the power conversion device can be achieved.

  Preferably, the motor drive device further includes a second motor. The second power conversion device is an inverter for driving the second motor.

  Preferably, the motor drive device further includes a third power conversion device. The third power conversion device is a converter for converting the voltage of the DC power supply and supplying it to the first and second power conversion devices. The control device further calculates the loss of the third power conversion device with respect to the supply voltage to the first power conversion device, and performs power conversion that maximizes the loss among the first to third power conversion devices. The voltage command value is set so that the loss that occurs in the device is minimized within a range where the drive command value for the power conversion device can be achieved.

  Preferably, the drive command value includes a motor torque command value and a rotational speed command value. Then, when the torque command value for the first motor exceeds a predetermined threshold value, the control device causes the first motor to rotate with the torque command value and the rotation regardless of the magnitude of the loss of each power converter. The voltage command value is set so that the loss that occurs in the first power converter is minimized within a range in which the speed command value can be achieved.

  Preferably, the second power conversion device is a converter for converting the voltage of the DC power supply and supplying the converted voltage to the first power conversion device.

  Preferably, the control device includes, for each power conversion device, a map in which a voltage command value that minimizes a loss generated in the power conversion device at a given drive command value is determined in advance. Then, the control device sets the voltage command value using the map.

  The vehicle according to the present invention includes drive wheels, a first motor, first and second power conversion devices, and a control device, and travels using electric power from a DC power source. The vehicle is driven by rotating the first motor drive wheel. A 1st power converter device is an inverter for driving a 1st motor using the electric power from DC power supply. The second power conversion device is connected to a terminal on the DC side in the first power conversion device. The control device controls the first and second power conversion devices. And a control apparatus calculates the loss of the 1st and 2nd power converter device with respect to the supply voltage to a 1st power converter device, and based on the loss which arises in the power converter device with which the obtained loss becomes the largest The voltage command value of the supply voltage supplied to the first power converter is set.

  Preferably, the control device sets the voltage command value so that the loss that occurs in the power conversion device with the maximum loss is minimized within a range where the drive command value for the power conversion device can be achieved.

  Preferably, the vehicle further includes an engine that is used together with the driving force from the first motor and configured to rotate the driving wheels.

  Preferably, the vehicle further includes a second motor. And the 2nd power converter was generated by the 2nd motor using the function which converts the direct-current power from direct-current power supply into the alternating current power for driving the 2nd motor, and the driving force from an engine It is an inverter configured to have a function of converting AC power into DC power for charging a DC power supply.

  Preferably, the vehicle further includes a third power conversion device. The third power conversion device is a converter for converting the voltage of the DC power supply and supplying it to the first and second power conversion devices. The control device further calculates the loss of the third power conversion device with respect to the supply voltage to the first power conversion device, and performs power conversion that maximizes the loss among the first to third power conversion devices. The voltage command value is set so that the loss that occurs in the device is minimized within a range where the drive command value for the power conversion device can be achieved.

  Preferably, the second power conversion device is a converter for converting the voltage of the DC power supply and supplying the converted voltage to the first power conversion device.

  According to the present invention, in a motor drive device including a plurality of power conversion devices, loss can be reduced without using complicated control logic.

1 is an overall block diagram of a vehicle equipped with a motor control device according to a first embodiment. FIG. 3 is a diagram illustrating an example of loss of each power conversion device with respect to a system voltage in the first embodiment. It is a figure for demonstrating an example of the map which defines the minimum system voltage corresponding to a drive command value in an inverter. In Embodiment 1, it is a functional block diagram for demonstrating the system voltage setting control performed by ECU. 5 is a flowchart for illustrating details of a system voltage setting control process executed by an ECU in the first embodiment. FIG. 10 is a diagram for describing an overview of system voltage setting control in a modification of the first embodiment. In the modification of Embodiment 1, it is the 1st example of the flowchart for demonstrating the detail of the system voltage setting control process performed by ECU. In the modification of Embodiment 1, it is the 2nd example of the flowchart for demonstrating the detail of the system voltage setting control process performed by ECU. FIG. 6 is an overall block diagram of a vehicle equipped with a motor control device according to a second embodiment. FIG. 6 is an overall block diagram of a vehicle equipped with a motor control device according to a third embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

[Embodiment 1]
FIG. 1 is an overall block diagram of a hybrid vehicle 100 equipped with a motor control device according to the first embodiment. In the present embodiment, a hybrid vehicle equipped with an engine and a motor generator will be described as an example of vehicle 100. However, the configuration of vehicle 100 is not limited to this, and the vehicle can travel with electric power from the power storage device. If so, it is applicable. The vehicle 100 includes, for example, an electric vehicle and a fuel cell vehicle in addition to the hybrid vehicle.

  Referring to FIG. 1, vehicle 100 includes power storage device 28, system relays SR1 and SR2, smoothing capacitors C1 and C2, converter 12, inverter 23, and a control device (hereinafter referred to as an ECU "Electronic Control Unit"). 30), an engine 40, a power split mechanism 41, drive wheels 42, and motor generators MG1 and MG2.

  The power storage device 28 typically includes a secondary battery such as a nickel metal hydride battery or a lithium ion battery, or a power storage device such as an electric double layer capacitor. In addition, DC voltage (hereinafter also referred to as “battery voltage”) VB output from DC power storage device 28 and input / output DC current IB are detected by voltage sensor 10 and current sensor 11, respectively. Voltage sensor 10 and current sensor 11 output detected values of detected DC voltage VB and DC current IB to ECU 30. The output voltage of power storage device 28 is, for example, about 200V.

  System relay SR1 is connected to the positive terminal of power storage device 28 and power line PL1. System relay SR2 is connected to the negative terminal of power storage device 28 and ground line NL. System relays SR <b> 1 and SR <b> 2 are controlled by a signal SE from ECU 30, and switch between supply and interruption of power from power storage device 28 to converter 12.

  Converter 12 includes a reactor L1, switching elements Q1, Q2, and diodes D1, D2.

  Switching elements Q1 and Q2 are connected in series between power line PL2 and ground line NL. Switching elements Q1 and Q2 are controlled by a switching control signal PWC from ECU 30. In the present embodiment, IGBTs (Insulated Gate Bipolar Transistors), power MOS (Metal Oxide Semiconductor) transistors, or power bipolar transistors are used as switching elements Q1 and Q2 and switching elements Q3 to Q8 described later. it can. Anti-parallel diodes D1 and D2 are arranged for switching elements Q1 and Q2.

  Reactor L1 has one end connected to a connection node of switching elements Q1 and Q2, and the other end connected to power line PL1. That is, reactor L1, switching elements Q1, Q2 and diodes D1, D2 constitute a chopper circuit.

  Smoothing capacitor C1 is connected between power line PL1 and ground line NL, and reduces voltage fluctuation between power line PL1 and ground line NL.

  Converter 12 is basically controlled such that switching elements Q1 and Q2 are turned on and off in a complementary manner in each switching period. During the boosting operation, converter 12 boosts DC voltage VL across smoothing capacitor C1 to DC voltage VH (this DC voltage corresponding to the input voltage to inverter 14 is hereinafter also referred to as “system voltage”). This boosting operation is performed by supplying the electromagnetic energy accumulated in reactor L1 during the ON period of switching element Q2 to power line PL2 via switching element Q1 and antiparallel diode D1.

  Converter 12 steps down DC voltage VH to DC voltage VL during the step-down operation. This step-down operation is performed by supplying the electromagnetic energy stored in reactor L1 during the ON period of switching element Q1 to ground line NL via switching element Q2 and antiparallel diode D2.

  The voltage conversion ratio (the ratio of VH and VL) in these step-up and step-down operations is controlled by the on-period ratio (duty) of the switching elements Q1 and Q2 in the switching period. If switching elements Q1 and Q2 are fixed to ON and OFF, respectively, VH = VL (voltage conversion ratio = 1.0) can be obtained.

  Smoothing capacitor C2 is connected between power line PL2 and ground line NL. Smoothing capacitor C <b> 2 smoothes the DC voltage from converter 12 and supplies the smoothed DC voltage to inverter 23. The voltage sensor 13 detects the voltage across the smoothing capacitor C2, that is, the system voltage VH, and outputs the detected value to the ECU 30.

  Inverter 23 includes an inverter 14 for driving motor generator MG1 and an inverter 22 for driving motor generator MG2. It is not essential to provide two sets of inverters and motor generators as shown in FIG. 1. For example, as will be described later with reference to FIG. 9, only one set of inverters and motor generators may be provided.

  Motor generators MG1 and MG2 receive AC power supplied from inverter 23 and generate a rotational driving force for traveling the vehicle. Motor generators MG1 and MG2 receive rotational force from the outside, generate AC power according to a regenerative torque command from ECU 30, and generate regenerative braking force in vehicle 100.

  Motor generators MG1 and MG2 are also coupled to engine 40 via power split mechanism 41. Then, the driving force generated by engine 40 and the driving force generated by motor generators MG1, MG2 are controlled to have an optimal ratio. Alternatively, either one of motor generators MG1 and MG2 may function exclusively as an electric motor, and the other motor generator may function exclusively as a generator. In the first embodiment, description will be made assuming that motor generator MG1 functions exclusively as a generator driven by engine 40, and motor generator MG2 functions exclusively as an electric motor that drives drive wheels 42.

  In power split mechanism 41, a planetary gear mechanism (planetary gear) is used to distribute the power of engine 40 to both drive wheel 42 and motor generator MG1.

  Inverter 14 receives the boosted voltage from converter 12, and drives motor generator MG1 to start engine 40, for example. Inverter 14 also outputs regenerative power generated by motor generator MG <b> 1 by mechanical power transmitted from engine 40 to converter 12. At this time, converter 12 is controlled by ECU 30 to operate as a step-down circuit.

  Inverter 14 includes a U-phase arm 15, a V-phase arm 16, and a W-phase arm 17 provided in parallel between power line PL2 and ground line NL. Each phase arm includes a switching element connected in series between power line PL2 and ground line NL. For example, U-phase arm 15 includes switching elements Q3 and Q4, V-phase arm 16 includes switching elements Q5 and Q6, and W-phase arm 17 includes switching elements Q7 and Q8. Antiparallel diodes D3 to D8 are connected to switching elements Q3 to Q8, respectively. Switching elements Q3 to Q8 are controlled by a switching control signal PWI1 from ECU 30.

  Typically, motor generator MG1 includes a three-phase permanent magnet type synchronous motor, and one end of three coils of U, V, and W phases is commonly connected to a neutral point. Furthermore, the other end of each phase coil is connected to the connection node of the switching element in each phase arm 15-17.

Inverter 22 is connected to converter 12 in parallel with inverter 14.
Inverter 22 converts the DC voltage output from converter 12 into a three-phase AC voltage and outputs it to motor generator MG2 for driving drive wheels. Inverter 22 also outputs regenerative power generated by motor generator MG2 to converter 12 along with regenerative braking. At this time, converter 12 is controlled by ECU 30 to operate as a step-down circuit. Although the internal configuration of inverter 22 is not shown, it is the same as inverter 14 and will not be described in detail.

  When the torque command value of motor generator MG1 is positive (TR1> 0), inverter 14 has switching elements Q3 to Q8 responding to switching control signal PWI1 from ECU 30 when a DC voltage is supplied from smoothing capacitor C2. By the switching operation, motor generator MG1 is driven so as to convert a DC voltage into an AC voltage and output a positive torque. Further, when the torque command value of motor generator MG1 is zero (TR1 = 0), inverter 14 converts the DC voltage into the AC voltage and the torque becomes zero by the switching operation in response to switching control signal PWI1. In this manner, motor generator MG1 is driven. Thus, motor generator MG1 is driven to generate zero or positive torque designated by torque command value TR1.

  Further, during regenerative braking of vehicle 100, torque command value TR1 of motor generator MG1 is set negative (TR1 <0). In this case, inverter 14 converts the AC voltage generated by motor generator MG1 into a DC voltage by a switching operation in response to switching control signal PWI1, and converts the converted DC voltage (system voltage) to smoothing capacitor C2. To the converter 12. The regenerative braking here refers to braking with regenerative power generation when the driver operating the electric vehicle performs a footbrake operation, or regenerative braking by turning off the accelerator pedal while driving, although the footbrake is not operated. This includes decelerating (or stopping acceleration) the vehicle while generating electricity.

  Similarly, inverter 22 receives switching control signal PWI2 from ECU 30 corresponding to the torque command value of motor generator MG2, receives a switching control signal PWI2, and converts the DC voltage into an AC voltage to a predetermined torque by a switching operation. The motor generator MG2 is driven so that

  Current sensors 24 and 25 detect motor currents MCRT1 and MCRT2 flowing through motor generators MG1 and MG2, and output the detected motor currents to ECU 30. Since the sum of the instantaneous values of the currents of the U-phase, V-phase, and W-phase is zero, the current sensors 24 and 25 are arranged to detect the motor current for two phases as shown in FIG. All you need is enough.

  Rotation angle sensors (resolvers) 26 and 27 detect rotation angles θ1 and θ2 of motor generators MG1 and MG2, and output the detected rotation angles θ1 and θ2 to ECU 30. ECU 30 can calculate rotational speeds MN1 and MN2 and angular speeds ω1 and ω2 (rad / s) of motor generators MG1 and MG2 based on rotational angles θ1 and θ2. Note that the rotation angle sensors 26 and 27 may not be arranged by directly calculating the rotation angles θ1 and θ2 from the motor voltage and current in the ECU 30.

  Although not shown, ECU 30 includes a CPU (Central Processing Unit), a storage device, and an input / output buffer, and controls each device of vehicle 100. Note that these controls are not limited to processing by software, and can be processed by dedicated hardware (electronic circuit).

  As representative functions, the ECU 30 includes the input torque command values TR1 and TR2, the DC voltage VL detected by the voltage sensor 19, the DC current IB detected by the current sensor 11, and the system voltage detected by the voltage sensor 13. Based on VH, motor currents MCRT1, MCRT2 from current sensors 24, 25, rotation angles θ1, θ2 from rotation angle sensors 26, 27, etc., motor generators MG1, MG2 generate torques according to torque command values TR1, TR2. The operations of the converter 12 and the inverter 23 are controlled so as to output. That is, switching control signals PWC, PWI1, and PWI2 for controlling converter 12 and inverter 23 as described above are generated and output to converter 12 and inverter 23, respectively.

  During the boosting operation of converter 12, ECU 30 feedback-controls system voltage VH to generate switching control signal PWC so that system voltage VH matches the voltage target value.

  Further, when vehicle 100 enters the regenerative braking mode, ECU 30 generates switching control signals PWI1 and PWI2 so as to convert the AC voltage generated by motor generators MG1 and MG2 into a DC voltage, and outputs it to inverter 23. Thus, inverter 23 converts the AC voltage generated by motor generators MG1 and MG2 into a DC voltage and supplies it to converter 12.

  Further, when vehicle 100 enters the regenerative braking mode, ECU 30 generates a switching control signal PWC so as to step down the DC voltage supplied from inverter 23 and outputs it to converter 12. Thus, the AC voltage generated by motor generators MG1 and MG2 is converted into a DC voltage, and is further stepped down and supplied to power storage device 28.

  In the configuration of FIG. 1, the motor drive device 20 is configured by portions other than the motor generators MG <b> 1 and MG <b> 2, the engine 40, the power split mechanism 41, and the drive wheels 42.

  In the vehicle system as shown in FIG. 1, it is important to improve the efficiency of the entire motor drive device. In order to achieve this efficiency improvement, it is important to reduce the loss of each power conversion device in a motor drive device including a plurality of power conversion devices such as converter 12 and inverters 14 and 22 as shown in FIG. However, even in the case of the same traveling state, the loss varies depending on the driving state of each power converter. And this loss changes with the common system voltage VH supplied or output to these power converter devices.

  This system voltage VH is controlled by converter 12, but is basically set higher than the induced voltage generated by the rotation of motor generators MG1, MG2. This is because if the induced voltage by motor generators MG1 and MG2 becomes higher than system voltage VH, motor generators MG1 and MG2 may become uncontrollable. On the contrary, in order to control the induced voltage of motor generators MG1 and MG2 so as not to exceed system voltage VH, it is necessary to perform “field weakening control”, but this field weakening control generally increases loss. Will be invited.

  FIG. 2 is a diagram illustrating an example of the loss of each power conversion device with respect to the system voltage VH when the vehicle is in a specific traveling state.

  In the case of the example in FIG. 2, the traveling state is required to have a relatively high speed and high output, and the loss of the inverter 14 (hereinafter also referred to as “INV2”) that drives the motor generator MG2 becomes the largest. Yes. However, the output of INV2 may be equal to or lower than the loss of inverter 22 that drives motor generator MG1 (hereinafter also referred to as “INV1”) depending on the traveling state.

  Further, as shown in FIG. 2, in each power conversion device, the loss caused by the setting of the system voltage VH is different even in the same driving state. And about each power converter device, the specific system voltage VH from which a loss becomes the minimum may exist. The system voltage VH at which this loss is minimized differs depending on the power conversion device. For example, as shown in FIG. 2, the loss of a specific power conversion device (INV2 in FIG. 2) over a settable system voltage VH range. Is larger than the loss of other power converters and becomes dominant in the overall system loss of the motor drive device, the system will minimize the loss that occurs for the power converter that maximizes this loss. By setting the voltage VH, it can be expected that the loss of the entire motor driving apparatus is minimized.

  Therefore, in the first embodiment, in a certain traveling state, the loss for each driving state is obtained for a plurality of power conversion devices, and the system voltage VH is set so that the loss is minimized for the power conversion device that maximizes the obtained loss. System voltage setting control is performed.

  Next, the outline of the system voltage setting control will be described with reference to FIG. FIG. 3 is a diagram for explaining a map for determining the minimum system voltage corresponding to the drive command value in the inverter.

  Referring to FIG. 3, the upper part of FIG. 3 shows the above map, and the lower part of FIG. 3 for each operating point of the inverter drive command (that is, torque command value TR and rotation speed command value MN). As described above, the system voltage VHmin is set to be the minimum within the range where the drive command value can be achieved. And in each power converter, with respect to the power converter which calculates the loss which can generate | occur | produce from the present system voltage VH and a drive command (TR, NM), and produces the largest loss among the obtained losses, The set value of the system voltage is determined using the map shown in FIG.

  By setting the system voltage VH by such a method, the loss of the entire system is reduced by relatively easy calculation without using a complicated control logic such as feedback control for setting value calculation. It becomes possible.

  In the above description, the example of the map in the case of the inverter has been described. However, in the case of the converter 12, the loss is almost proportional to the boost ratio determined from the battery voltage VB of the power storage device 28 and the system voltage VH. To do.

  FIG. 4 is a functional block diagram for explaining the system voltage setting control executed by the ECU 30 in the first embodiment. Each functional block described in the functional block diagram illustrated in FIG. 4 is realized by hardware or software processing by the ECU 30.

  Referring to FIGS. 1 and 4, ECU 30 includes a loss calculation unit 31, a determination unit 32, a VH setting unit 33, and a storage unit 34.

  Loss calculation unit 31 sets torque command values TR1 and TR2 (hereinafter also collectively referred to as TR) and rotation speeds of motor generators MG1 and MG2 set based on the depression amount of an accelerator pedal (not shown). Values MN1 and MN2 (hereinafter collectively referred to as NM) are received from a host ECU (not shown). Loss calculating unit 31 receives the detected values of current battery voltage VB and system voltage VH from voltage sensors 10 and 13, respectively. Then, the loss calculation unit 31 uses the map as shown in FIG. 2 stored in the storage unit 34 based on such information, for example, to cause loss of INV1 and INV2 that can occur at the current system voltage VH. LOS1 and LOS2 and the loss LOSC of the converter 12 are calculated. The loss calculation unit 31 outputs the calculated losses LOS1, LOS2, and LOSC to the determination unit 32. Note that the loss of each power converter may be set using a predetermined arithmetic expression.

  The determination unit 32 receives the losses LOS1, LOS2, and LOSC from the loss calculation unit 31. Then, the determination unit 32 compares the obtained loss to determine which power conversion device has the largest loss. Then, the determination result SEL indicating the power conversion device having the maximum loss is output to the VH setting unit 33.

  The VH setting unit 33 receives the determination result SEL from the determination unit 32. VH setting unit 33 receives drive command (TR, NM) and battery voltage VB. The VH setting unit 33 uses the map as shown in FIG. 3 stored in the storage unit 34 for the power conversion device selected by the determination result SEL, based on the drive command or the battery voltage VB. The voltage command value VHR is determined. VH setting unit 33 outputs determined voltage command value VHR to another ECU or another functional part (none of which is shown) in ECU 30, and drives converter 12 based on voltage command value VHR there. A control signal PWC is generated.

  FIG. 5 is a flowchart for illustrating the details of the system voltage setting control process executed by ECU 30 in the first embodiment. Each step in the flowcharts shown in FIG. 5 and FIGS. 7 and 8 to be described later is realized by executing a program stored in advance in the ECU 30 at a predetermined cycle. Alternatively, for some steps, processing can be realized by dedicated hardware (electronic circuit).

  Referring to FIGS. 1 and 5, ECU 30 obtains torque command value TR and rotation speed command NM of motor generators MG <b> 1 and MG <b> 2 at step (hereinafter, step is abbreviated as S) 100. In S100, the ECU 30 also acquires the current system voltage VH and battery voltage VB.

  Based on these pieces of information, the ECU 30 calculates the losses LOS1, LOS2, and LOSC that can occur in each power converter by calculation.

  In step S120, the ECU 30 determines whether or not the loss LOS1 of the INV1 is the maximum.

  If loss LOS1 is maximum (YES in S120), the process proceeds to S130, and ECU 30 selects a map as shown in FIG. 3 for INV1. In step S140, the ECU 30 determines a voltage command value VHR for the system voltage that minimizes the loss, using the selected map and the drive command.

  On the other hand, if loss LOS1 is not the maximum (NO in S120), the process proceeds to S150, and ECU 30 next determines whether loss LOS2 of INV2 is the maximum.

  If loss LOS2 is the maximum (YES in S150), the process proceeds to S160, and ECU 30 selects a map for INV2 and uses it to determine voltage command value VHR (S140).

  When loss LOS2 is not maximum (NO in S150), ECU 30 determines that loss LOSC of converter 12 is maximum. ECU 300 then selects a map for converter 12 (S170), and uses it to determine voltage command value VHR (S140).

  By performing control according to such processing, in a motor drive device including a plurality of power conversion devices, loss of the motor drive device can be reduced with relatively simple control logic without using complicated control logic. It becomes possible.

[Modification of Embodiment 1]
In the above-described example, the configuration in which the loss of the inverter and the converter is always calculated and compared to determine the voltage command value VHR of the system voltage has been described.

  Incidentally, in the motor drive device as shown in FIG. 1, the capacity of the motor generator MG2 for running the vehicle is often designed to be larger than the capacity of the motor generator MG1. When motor generator MG2 is set to a high output, the motor generator MG2 is used for both the electric power generated by motor generator MG1 and the electric power from power storage device 28 (that is, the electric power supplied from converter 12). Generator MG2 may be driven. Therefore, in such a case, the capacity of inverter 22 for driving motor generator MG2 is generally designed to be larger than the capacity of other power converters.

  Then, in the case of a high output in which torque command value TR2 of motor generator MG2 is larger than a predetermined value, the loss due to INV2 can be more dominant than the loss of other power converters. In such a situation, when the control as shown in the first embodiment is applied, the system voltage VH can always be set based on INV2.

  Therefore, in the modification of the first embodiment, when torque command value TR2 to motor generator MG2 is larger than a predetermined threshold value, it is considered that there is a high possibility that the loss in INV2 is the maximum. The voltage command value VHR of the system voltage is set so that the loss of the INV2 is minimized without comparing the loss between the power changing devices.

  By doing so, loss comparison between the power change devices is not required under the above-described conditions, so that a simpler control logic can be obtained, and as a result, the calculation load of the ECU is further reduced. It becomes possible.

  FIG. 6 is a diagram for describing an overview of system voltage setting control in a modification of the first embodiment. Referring to FIG. 6, as described above, in region RG1 where torque command value TR2 of motor generator MG2 is larger than a predetermined threshold value TRth, as shown in the upper part of FIG. Can be significantly larger than the loss of other power converters. Therefore, when torque command value TR2 of motor generator MG2 falls within the range of region RG1, voltage command value VHR is determined using a map for INV2 without performing calculation / comparison of loss in each power converter. .

  On the other hand, in the region RG2 where the torque command value TR2 of the motor generator MG2 is equal to or less than the threshold value TRth, the loss of INV2 becomes small, and the state shown in the lower part of FIG. Therefore, in this case, voltage command value VHR is determined based on the comparison of the losses of each power converter as in the first embodiment. Alternatively, as is done in the prior art, the maximum voltage setting value of the system voltage determined using a map or the like is set as the voltage command value VHR from the drive command for each power converter. You may do it.

  FIG. 7 is a first example of a flowchart for explaining details of a system voltage setting control process executed by ECU 30 in the modification of the first embodiment. FIG. 7 is obtained by adding steps S105 and S106 to the flowchart of FIG. 5 of the first embodiment. In FIG. 7, the description of the same steps as those in FIG. 5 will not be repeated.

  Referring to FIGS. 1 and 7, when ECU 30 obtains a drive command or the like in S100, ECU 30 next determines in S105 whether torque command value TR2 of motor generator MG2 is greater than threshold value TRth. .

  If torque command value TR2 is greater than threshold value TRth (YES in S105), the process proceeds to S106, and ECU 30 selects a map for INV2, and uses it to determine voltage command value VHR. (S140).

  On the other hand, when torque command value TR2 is equal to or smaller than threshold value TRth (NO in S105), the process proceeds to S110, and the loss of each power converter is calculated in the same manner as the process of FIG. 6 of the first embodiment. At the same time, the voltage command value VHR is determined based on the obtained loss comparison.

  FIG. 8 is a second example of a flowchart for explaining details of a system voltage setting control process executed by ECU 30 in the modification of the first embodiment.

  Referring to FIGS. 1 and 8, when ECU 30 obtains a drive command or the like of motor generators MG1 and MG2 in S200, torque command value TR2 of motor generator MG2 is set to threshold value TRth in S210. It is determined whether or not it is larger.

  If torque command value TR2 is larger than threshold value TRth (YES in S210), the process proceeds to S220, and ECU 30 determines voltage command value VHR using a map for INV2.

  On the other hand, when torque command value TR2 is equal to or smaller than threshold value TRth (NO in S210), the process proceeds to S230, and for each of INV1 and INV2, voltage setting value VHmg1 of the system voltage determined based on the drive command , VHmg2 is calculated.

  In S240, ECU 30 determines whether or not voltage setting value VHmg2 for motor generator MG2 is larger than voltage setting value VHmg1 for motor generator MG2 (VHmg2 <VHmg1).

  If voltage setting value VHmg2 is greater than voltage setting value VHmg1 (YES in S240), ECU 30 sets voltage setting value VHmg2 as VHR in S250.

  On the other hand, when voltage setting value VHmg2 is equal to or lower than voltage setting value VHmg1 (NO in S240), ECU 30 sets voltage setting value VHmg1 as VHR in S260.

  By performing control according to such processing, it is possible to reduce the loss of the motor drive device while further reducing the calculation load as compared with the first embodiment.

[Embodiment 2]
In the first embodiment and its modification, a hybrid vehicle including two motor generators has been described. However, a hybrid vehicle including an engine and a motor generator includes the motor generator used for power generation in the first embodiment. It may not be possible.

  FIG. 9 is an overall block diagram of a vehicle 100A equipped with a motor control device 20A according to the second embodiment. In FIG. 9, the motor generator and the inverter are one set, and the device related to the motor generator MG2 in FIG. 1 is deleted.

  In FIG. 9, the same reference numerals for the motor generator and the inverter as those of the motor generator MG1 and the inverter 14 in the first embodiment are used for easy comparison with FIG. In the configuration in which the motor generator and the inverter are one set as in FIG. 9, the motor generator includes a function capable of driving the drive wheels, that is, the function of the motor generator MG2 described in the first embodiment. Please be careful.

  Even in such a configuration, when two power conversion devices are provided, such as an inverter for driving the motor generator and a converter for boosting the output voltage of the power storage device, the first embodiment and its System voltage setting control similar to that of the modification can be applied.

[Embodiment 3]
Further, vehicle 100B in the third embodiment shown in FIG. 10 has a configuration in which engine 40 and power split mechanism 41 are deleted from the configuration in the second embodiment. That is, vehicle 100B corresponds to the case of an electric vehicle.

  In the third embodiment, vehicle 100B travels using the driving force from motor generator MG1.

  Even in such an electric vehicle, when there are a plurality of power conversion devices, it is possible to apply the system voltage setting control similar to that in the first embodiment and the modification thereof as in the second embodiment. .

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  10, 13, 19 Voltage sensor, 11, 24, 25 Current sensor, 12 Converter, 14, 22, 23 Inverter, 15 U-phase arm, 16 V-phase arm, 17 W-phase arm, 20, 20A, 20B Motor drive device , 26, 27 Rotational angle sensor, 28 Power storage device, 30 ECU, 31 Loss calculation unit, 32 Determination unit, 33 Setting unit, 34 Storage unit, 40 Engine, 41 Power split mechanism, 42 Drive wheel, 100, 100A, 100B Vehicle , C1, C2 smoothing capacitor, D1-D8 diode, L1 reactor, MG1, MG2 motor generator, NL ground line, PL1, PL2 power line, Q1-Q8 switching element, SR1, SR2 system relay.

Claims (13)

A motor driving device for driving a motor using electric power from a DC power source,
A first motor;
A first power conversion device that is an inverter for driving the first motor using power from the DC power supply;
A second power converter connected to a terminal on the direct current side of the first power converter;
A control device for controlling the first power conversion device and the second power conversion device;
The control device calculates a loss of the first and second power conversion devices with respect to a supply voltage to the first power conversion device, and based on a loss generated in the power conversion device in which the obtained loss is maximized. A motor drive device that sets a voltage command value of the supply voltage supplied to the first power converter.   The control device sets the voltage command value such that a loss that occurs in the power conversion device that maximizes the loss is minimized within a range in which a drive command value for the power conversion device can be achieved. Item 2. The motor drive device according to Item 1. A second motor;
The motor drive device according to claim 2, wherein the second power conversion device is an inverter for driving the second motor. A third power converter,
The third power conversion device is a converter for converting the voltage of the DC power supply and supplying the converted voltage to the first and second power conversion devices,
The control device further calculates the loss of the third power conversion device with respect to the supply voltage to the first power conversion device, and the loss is maximized among the first to third power conversion devices. The motor drive device according to claim 3, wherein the voltage command value is set so that a loss generated in the power conversion device is minimized within a range where the drive command value for the power conversion device can be achieved. The drive command value includes a torque command value and a rotation speed command value of the motor,
When the torque command value for the first motor exceeds a predetermined threshold value, the control device causes the first motor to move regardless of the loss of each power converter. 5. The motor according to claim 3, wherein the voltage command value is set so that a loss occurring in the first power converter is minimized within a range in which the torque command value and the rotation speed command value can be achieved. Drive device.   The motor drive device according to claim 2, wherein the second power conversion device is a converter for converting a voltage of the DC power supply and supplying the converted voltage to the first power conversion device. The control device includes, for each power conversion device, a map in which the voltage command value that minimizes a loss generated in the power conversion device at a given drive command value is predetermined,
The motor drive device according to claim 2, wherein the control device sets the voltage command value using the map. A vehicle capable of traveling using electric power from a DC power source,
Drive wheels,
A first motor for driving the vehicle by rotating the drive wheel;
A first power conversion device that is an inverter for driving the first motor using power from the DC power supply;
A second power converter connected to a terminal on the direct current side of the first power converter;
A control device for controlling the first power conversion device and the second power conversion device;
The control device calculates a loss of the first and second power conversion devices with respect to a supply voltage to the first power conversion device, and based on a loss generated in the power conversion device in which the obtained loss is maximized. And setting a voltage command value of the supply voltage supplied to the first power converter.   The control device sets the voltage command value such that a loss that occurs in a power conversion device that maximizes the loss is minimized within a range in which a drive command value for the power conversion device can be achieved. 8. The vehicle according to 8.   The vehicle according to claim 9, further comprising an engine that is used together with a driving force from the first motor and configured to rotate the driving wheel. A second motor;
The second power conversion device uses the function of converting DC power from the DC power source into AC power for driving the second motor, and the second motor using the driving force from the engine. The vehicle according to claim 10, wherein the vehicle is an inverter configured to have a function of converting AC power generated by the DC power into DC power for charging the DC power supply. A third power converter,
The third power conversion device is a converter for converting the voltage of the DC power supply and supplying the converted voltage to the first and second power conversion devices,
The control device further calculates the loss of the third power conversion device with respect to the supply voltage to the first power conversion device, and the loss is maximized among the first to third power conversion devices. The vehicle according to claim 11, wherein the voltage command value is set such that a loss occurring in the power conversion device is minimized within a range where the drive command value for the power conversion device can be achieved.   The vehicle according to claim 9 or 10, wherein the second power conversion device is a converter for converting a voltage of the DC power supply and supplying the converted voltage to the first power conversion device.

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