JP2019134630A - Control method and control apparatus of motor - Google Patents

Abstract

To suppress reduction in efficiency of a motor while reducing vibrations caused by operation of the motor.SOLUTION: A control device (10) for controlling operation of a motor (5) on the basis of d-axis and q-axis current command values relating to electric power supplied to the motor (5), calculates both the d-axis and the q-axis current command values so that efficient operation for efficiently controlling the motor (5) is performed. The control device (10) determines whether a switching condition for switching from efficient operation to another operation state is satisfied. When the switching condition is satisfied, one current command value is increased, and the other current command value is decreased.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a control method and a control device for controlling operation of an electric motor based on a current command value of the electric motor.

  In Patent Document 1, in order to suppress the vibration caused by the rotational operation of the motor, a compensation signal for canceling the torque ripple of the motor output is obtained based on the current command value of the motor and the rotor rotation angle, and the compensation signal is used as the current command value. An additional control device is disclosed.

JP 2007-267466 A

  In the control device as described above, generally, the current command value is calculated so as to efficiently control the operation of the motor. For this reason, by adding a compensation signal to the current command value, vibration caused by the motor, which is an electric motor, can be suppressed, but the current command value is shifted from the original value, so there is a concern that the efficiency of the electric motor may be reduced. Is done.

  An object of the present invention is to provide a control method and a control apparatus that suppress a reduction in the efficiency of the motor while reducing vibrations caused by the operation of the motor.

  The motor control method according to one aspect of the present invention controls the operation of the motor based on d-axis and q-axis current command values relating to power supplied to the motor. The control method includes a calculation step of calculating current command values for both the d-axis and the q-axis so that an efficient operation for efficiently controlling the electric motor is performed. Further, the motor control method includes a determination step for determining whether or not a switching condition for switching from the efficient operation to another operating state is satisfied, and one of the current command values when the switching condition is satisfied. And a change step of decreasing the other current command value.

  According to this aspect, it is possible to suppress the reduction in the efficiency of the motor while reducing the vibration caused by the operation of the motor.

FIG. 1 is a block diagram illustrating a configuration example of a motor control device according to an embodiment of the present invention. FIG. 2A is a diagram showing contour lines of electromagnetic excitation force in the dq-axis current coordinate system of the electric motor. FIG. 2B is a diagram showing efficiency and torque contour lines in the dq-axis current coordinate system of the electric motor. FIG. 3 is a flowchart showing an example of a processing procedure relating to the motor control method according to the present embodiment. FIG. 4 is a conceptual diagram illustrating an example of a condition for switching to the vibration suppression operation range. FIG. 5 is a diagram for explaining a threshold value setting method for the torque command value. FIG. 6 is a diagram for explaining a method for changing the dq-axis current when switching to the vibration suppression operation in a state where the torque of the electric motor is kept constant.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 is a block diagram illustrating a configuration example of a control device 100 that controls the operation of the electric motor according to the present embodiment.

  The control device 100 is composed of one or a plurality of controllers, and stores a control program determined in advance to execute current vector control. The control apparatus 100 supplies alternating current power to an electric motor using the electric power of the battery 41 by running a control program.

  The control device 100 of the present embodiment generates a current command vector of power to be supplied to the electric motor 5 constituting the electric motor, and controls the rotation operation of the electric motor 5 based on the current command vector. The current command vector is specified by d-axis and q-axis current command values indicating the d-axis component and the q-axis component of the current supplied to the electric motor 5, respectively. The d-axis and the q-axis here are coordinate axes that are electrically orthogonal to each other.

  For example, the control device 100 is mounted on a vehicle that is a casing that houses the electric motor 5, and the electric motor 5 is used as a part or all of a drive source that drives the vehicle. Vehicles include not only electric vehicles but also hybrid vehicles and fuel cell vehicles.

  The control device 100 includes a current command generator 1, arithmetic units 21 and 22, a current vector controller 3, an inverter unit 4, an electric motor 5, current detectors 61 and 62, a rotor detector 7, and the like. A coordinate converter 8, a rotation speed calculator 9, and a compensation processing unit 10.

Based on the torque command value T ^* for the electric motor 5, the current command generation unit 1 performs the d-axis and q-axis current command values i _d1 so that the efficient operation for efficiently controlling the electric motor 5 is performed. ^{* And} i _q1 ^* are generated. For example, the current command generator 1 corrects the d-axis and q-axis current command values i _d1 ^* and i _q1 ^* according to the rotation speed detection value N of the electric motor 5.

When the current command generation unit 1 of the present embodiment acquires each parameter of the torque command value T ^* and the rotation speed detection value N, the current command generation unit 1 refers to a predetermined current table. Then, the current command generation unit 1 specifies an operating point determined by each parameter, and calculates d-axis and q-axis current command values i _d1 ^* and i _q1 ^* associated with the operating point.

In the current table, a set of d-axis current command value i _d1 ^* and q-axis current command value i _q1 ^* is associated with each operating point specified by the torque command value T ^* and the rotation speed detection value N. It has been. In each column of the d-axis current command value i _d ^* and the q-axis current command value i _q ^* , a plurality of sets of d-axis and q-axis current values in which the generated torque of the electric motor 5 is equal to the torque command value T ^* are shown. Among them, a set of d-axis and q-axis current values that maximize the efficiency of the electric motor 5 is stored. The stored current value is obtained in advance based on experimental data and simulation results.

The current command generator 1 outputs the calculated d-axis current command value i _d1 ^* and q-axis current command value i _q1 ^* to the calculators 21 and 22, respectively.

The arithmetic units 21 and 22 calculate the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 ^* for suppressing the vibration generated in the vehicle housing the electric motor 5 and the vibration generated in the electric motor 5 itself. Add to the command values i _d1 ^* and i _q1 ^* .

The computing unit 21 outputs an addition value of the d-axis current command value i _d1 ^* and the d-axis compensation amount i _d2 ^* to the current vector controller 3 as a new d-axis current command value i _d ^* . The computing unit 22 outputs the addition value of the q-axis current command value i _q1 ^* and the q-axis compensation amount i _q2 ^* to the current vector controller 3 as a new q-axis current command value i _q ^* .

Current vector controller 3 on the basis of the d-axis and the current command value of q-axis _i ^{d *} and _i ^{q *,} the d-axis and q-axis current command value _i ^{d *} and _i ^{q *} are the electric motor 5, respectively Current vector control is executed so as to converge to the d-axis and q-axis current detection values i _d and i _q of the supplied AC power.

That is, the current vector controller 3 performs feedback control that feeds back the d-axis and q-axis current detection values i _d and i _q to the d-axis and q-axis current command values i _d ^* and i _q ^* , respectively. Run.

  The current vector controller 3 outputs d-axis and q-axis voltage command values by executing feedback control. The current vector controller 3 converts the d-axis and q-axis voltage command values into three-phase voltage command values based on the electrical angle detection value θ of the electric motor 5 and outputs the converted voltage command values to the inverter unit 4.

  The inverter unit 4 is connected to a battery 41, and the battery 41 is provided with a sensor 42 that detects an SOC (State Of Charge) indicating the remaining capacity of the battery 41. The sensor 42 may detect the voltage of the battery 41.

  The inverter unit 4 converts the DC voltage of the battery 41 into a three-phase AC voltage based on the three-phase voltage command value output from the current vector controller 3 and supplies it to each phase of the electric motor 5.

  For example, the inverter unit 4 includes a plurality of power elements, converts a three-phase voltage command value into a drive signal for driving the plurality of power elements based on a voltage detection value of the battery 41, and converts the converted plurality of power elements. A drive signal is supplied to the control terminal of each power element.

The inverter unit 4 converts the DC voltage of the battery 41 into a three-phase AC voltage in accordance with a drive signal supplied to the control terminal of each power element, and converts the converted three-phase AC voltage to the electric motor 5. Supply to each phase. As a result, the electric motor 5 is supplied with three-phase alternating currents i _u , i _v and i _w .

The electric motor 5 is rotationally driven by three-phase alternating currents i _u , _iv and i _w supplied from the battery 41 via the inverter unit 4. That is, the electric motor 5 is an electric motor that converts AC power supplied by the inverter unit 4 into rotational energy.

  The electric motor 5 according to the present embodiment is a rotating electric machine including three-phase windings of U, V, and W, and can be used as a drive source for a vehicle or the like. For example, the electric motor 5 is realized by an IPM (Interior Permanent Magnet) type three-phase synchronous motor.

The current detectors 61 and 62 detect at least two-phase AC currents among the three-phase AC currents i _u , _iv and i _w supplied from the inverter unit 4 to the electric motor 5. Current detector 61 and 62 of the present embodiment outputs to the coordinate converter 8 detects the alternating current i _u and i _v of U and V phases.

  The rotor detector 7 detects the electrical angle of the rotor constituting the electric motor 5. The rotor detector 7 outputs the detected electrical angle value θ indicating the detected electrical angle value to the rotation speed calculator 9 and outputs the detected electrical angle value θ to the coordinate converter 8.

The coordinate converter 8 converts the U-phase and V-phase alternating currents i _u and _iv into d-axis and q-axis current detection values i _d and i _q based on the detected electrical angle θ of the electric motor 5. Output to the current vector controller 3

  The rotational speed calculator 9 calculates the rotational speed of the electric motor 5 from the amount of change per hour in the electrical angle detection value θ. The rotation speed calculator 9 outputs a rotation speed detection value N indicating the calculated rotation speed value to the current command generation unit 1 and outputs the rotation speed detection value N to the compensation processing unit 10.

The compensation processing unit 10 determines whether or not a switching condition for switching the drive state of the electric motor 5 from the efficient operation to another operation state is satisfied, and when it is determined that the switching condition is satisfied, the d-axis and the q-axis are determined. The current command values i _d ^* and i _q ^* are changed in different directions. That is, the compensation processing unit 10 constitutes a switching unit that changes both the current command values i _d ^* and i _q ^* in different directions when switching from the efficient operation to another operation state.

For example, the compensation processing unit 10 determines whether or not the switching condition is satisfied according to the driving state of the electric motor 5. When the switching condition is satisfied, the compensation processing unit 10 performs the d-axis and q-axis current command values i _d ^* and the d-axis and the q-axis so that the vibration suppression operation for suppressing the vibration generated in at least one of the electric motor 5 and the vehicle is performed. Change i _q ^* . On the other hand, when the switching condition is not satisfied, the compensation processing unit 10 suppresses changes in the d-axis and q-axis current command values i _d ^* and i _q ^* .

In the present embodiment, the compensation processing unit 10 acquires the detection value of the sensor 42, the travel information Data from the car navigation system, the torque command value T ^* indicating the driving state of the electric motor 5, the rotation speed detection value N, and the like. To do. Then, the compensation processing unit 10 determines whether or not a switching condition from the efficient operation to the vibration suppression operation is satisfied based on at least one of these parameters.

Specifically, the compensation processing unit 10 determines whether or not the torque command value T ^* is lower than a predetermined threshold regarding the execution of the efficient operation as the switching condition. The predetermined threshold here is determined in advance so that the maximum torque of the electric motor 5 defined by the implementation of the efficient operation does not decrease when the current supplied from the inverter unit 4 to the electric motor 5 reaches the upper limit value. It is done.

When the torque command value T ^* is equal to or greater than a predetermined threshold value, the compensation processing unit 10 controls the vibration damping to avoid a decrease in the torque generated by the electric motor 5 due to the execution of the vibration damping control. It is determined that the condition for switching to operation is not satisfied.

On the other hand, when the torque command value T ^* falls below a predetermined threshold, the maximum torque of the electric motor 5 cannot be reduced, and the d-axis and q-axis current command values i _d ^* and i _q ^* can be changed. Therefore, the compensation processing unit 10 determines that the condition for switching to the vibration suppression operation is satisfied.

  Further, the compensation processing unit 10 determines whether or not the rotation speed detection value N is within a predetermined rotation speed range related to the execution of the vibration damping operation as the switching condition. The predetermined rotational speed range mentioned here indicates a rotational speed range in which vibration generated by the operation of the electric motor 5 sharply increases during the efficient operation of the electric motor 5, and is determined in advance by experimental data and simulation results.

  When the rotational speed detection value N is within a predetermined rotational speed range, the compensation processing unit 10 proceeds to a vibration suppression operation in order to suppress an increase in the level of sound vibration generated in the electric motor 5 or the vehicle. It is determined that the switching condition is satisfied.

  On the other hand, when the rotation speed detection value N is outside the predetermined range, the compensation processing unit 10 causes the sound vibration level of the electric motor 5 or the vehicle to be lower than the allowable value. Is determined to have been established.

Next, when the compensation processing unit 10 determines that the condition for switching to the vibration suppression operation is satisfied, one of the current command values i _d ^* and i _q ^* of the d-axis and the q-axis is commanded. And the other current command value is decreased. Thereby, the increase in the vibration which arises in the electric motor 5 or a vehicle can be suppressed.

In this embodiment, the compensation processing unit 10 generates vibrations that cause the d-axis and q-axis current command values i _d ^* and i _q ^* in the electric motor 5 or the vehicle when the condition for switching to the vibration suppression operation is satisfied. It approaches the vibration control operation point to suppress.

Specifically, the compensation processing unit 10 refers to a predetermined current compensation table, and calculates d-axis and q-axis compensation amounts i _d2 ^* and i _q2 ^* . In the current compensation table, a set of d-axis compensation amount i _d2 ^* and q-axis compensation amount i _q2 ^* is associated with each operating point specified by the torque command value T ^* and the rotation speed detection value N. .

For example, the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 are _{calculated based} on the d-axis and q-axis current command values i _d1 ^* and i while the operating point of the electric motor 5 follows the torque command value T ^*. It is determined so as to approach the above-mentioned vibration suppression operation point from the efficiency operation point specified by _q1 ^* .

On the other hand, when determining that the condition for switching to the vibration suppression operation is not satisfied, the compensation processing unit 10 sets the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 to “0”. Thereby, an efficient driving | operation is implemented or continued.

Then, the compensation processing unit 10 outputs the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 ^* to the calculators 21 and 22, respectively. Accordingly, the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 are reflected on the d-axis and q-axis current command values i _d ^* and i _q ^{* in} accordance with whether or not the switching condition is satisfied. That is, the driving state of the electric motor 5 is switched from the efficient operation to the vibration suppression operation or from the vibration suppression operation to the efficiency operation.

  Next, the relationship between the d-axis current and the q-axis current in the vibration damping operation and the efficient operation of the electric motor 5 will be briefly described with reference to FIGS. 2A and 2B.

  FIG. 2A is a diagram illustrating an example of contour lines of electromagnetic excitation force generated in the electric motor 5 at a specific rotation speed of the electric motor 5. FIG. 2B is a diagram illustrating the contour lines of the efficiency of the electric motor 5 superimposed on the contour lines of the generated torque of the electric motor 5 indicated by broken lines.

2A and 2B show the d-axis and q-axis current coordinate systems, the horizontal axis is the q-axis current i _q indicating the q-axis component of the current supplied to the electric motor 5, and the vertical axis is it is a d-axis current _{i d} indicating the d-axis component. The dotted line indicates the vibration suppression operation line Lsv, and the solid line indicates the efficiency operation Le line.

As shown in FIG. 2A, for damping operating line Lsv, so that the electromagnetic excitation force generated in the electric motor 5 is minimized, d-axis current i _d and the q-axis optimization operating point specified by the current i _q Has been. This optimized operating point is also referred to as a vibration suppression operating point.

  As the electromagnetic excitation force of the electric motor 5 increases, the torque ripple generated in the electric motor 5 increases, and the electric motor 5 vibrates due to this. As the vibration of the electric motor 5 increases, sound generated in the electric motor 5, that is, sound vibration increases. Furthermore, depending on the rotational speed of the electric motor 5, sound vibration increases even when part of the vehicle that fixes the electric motor 5 resonates due to vibration of the electric motor 5.

  As shown in FIG. 2B, the operating point of the efficient operation line Le is optimized so that the efficiency of the electric motor 5 is maximized for each torque generated by the electric motor 5. This optimized operating point is also referred to as an efficient operating point.

As described above, the operating points of the efficient operation line Le and the vibration suppression operation line Lsv are set at different positions for each generated torque of the electric motor 5. For this reason, in a situation where the generated torque of the electric motor 5 is kept constant, the d-axis current i is increased while the q-axis current i _q is increased compared to the efficiency operation point when the vibration damping operation is performed. _d must be reduced.

Therefore, when the driving state of the electric motor 5 is switched from the efficient operation to the vibration suppression operation, the compensation processing unit 10 of the present embodiment differs in the d-axis and q-axis current command values i _d ^* and i _q ^* from each other. Change direction. Thereby, the operating point of the electric motor 5 can be brought closer to the vibration suppression operating point from the efficient operating point.

  Next, the operation of the compensation processing unit 10 in the present embodiment will be described in detail with reference to FIG.

  FIG. 3 is a flowchart showing an example of a processing procedure for the method of controlling the electric motor 5 in the present embodiment. This processing procedure is repeatedly performed at a predetermined cycle of, for example, several hundred milliseconds.

  In step S <b> 1, the compensation processing unit 10 determines whether or not to prioritize efficient driving based on the traveling state of the vehicle in order to avoid a situation where the power of the battery 41 is insufficient.

  In the present embodiment, the compensation processing unit 10 determines whether or not the SOC of the battery 41 is lower than the battery threshold value in order to avoid a situation in which the vehicle 41 is running and the battery 41 runs out of power and the vehicle stops. to decide.

  The SOC of the battery 41 is detected by the sensor 42 shown in FIG. The battery threshold value may be obtained from experimental data or simulation results, and may be set based on, for example, the power consumption of the battery 41 predicted from the travel history of the vehicle.

  Further, the compensation processing unit 10 determines whether or not the travel distance from the current position of the vehicle to the nearest charging spot exceeds the spot threshold so that the vehicle equipped with the battery 41 can reach the nearest charging spot. To do. The travel distance to the nearest charging spot is acquired from a car navigation system mounted on the vehicle. The spot threshold value may be a predetermined value or a value that changes according to the remaining capacity of the battery 41.

  When the SOC of the battery 41 is lower than the battery threshold, or when the travel distance from the current position of the vehicle to the nearest charging spot is higher than the spot threshold, the compensation processing unit 10 gives priority to the implementation of the efficient operation. Determination is made, and the process proceeds to step S7.

  On the other hand, when the SOC of the battery 41 is equal to or greater than the battery threshold value and the travel distance from the current position of the vehicle to the nearest charging spot is equal to or less than the spot threshold value, it is determined that priority is not given to performing efficient driving.

  Thus, the compensation processing unit 10 determines whether or not to prioritize the implementation of the efficient operation based on the parameter for predicting the power shortage of the battery 41.

  In step S <b> 2, the compensation processing unit 10 determines whether or not the efficient operation is selected as the operation mode of the electric motor 5 when it is determined that priority is not given to the execution of the efficient operation.

  For example, a push button is provided in the driver's seat of the vehicle, and the driver pushes the push button to select efficient driving as the operation mode. Thereby, the compensation processing unit 10 acquires the operation signal indicating the efficient operation, and determines that the efficient operation is selected as the operation mode based on the operation signal. When it is determined that the efficient operation is selected, the compensation processing unit 10 proceeds to the process of step S7.

In step S3, the compensation processing unit 10 acquires the torque command value T ^* and the rotation speed detection value N of the electric motor 5 when determining that the efficient driving is not selected by the driver.

In step S4, the compensation processing unit 10 avoids a situation where the maximum torque of the electric motor 5 defined by the implementation of the efficient operation is reduced, so that the torque command value T ^* is a predetermined threshold value T ₁ relating to the implementation of the efficient operation. It is determined whether or not: The method of setting the thresholds T ₁ with respect to the torque command value T ^*, to be described later with reference to FIG.

And if the torque command value T ^* exceeds the thresholds T ₁ takes place can not reach torque of the electric motor 5 until the torque command value T ^* by a reduction of the maximum torque of the electric motor 5 due to the implementation of the damping operation obtain. Compensation processing section 10 as a countermeasure, if the torque command value T ^* exceeds the thresholds T _1, the process proceeds to the processing of step S7, to implement efficient operation.

On the other hand, when the torque command value T ^* is thresholds T ₁ or less, since the reduction of the maximum torque of the electric motor 5 can not occur, compensation processing unit 10, an operation state of the electric motor 5 from the efficiency operation control It is determined that the operation can be switched to the vibration operation, and the process proceeds to step S5.

Compensation processing unit in step S5 10, in order to suppress the sound of the electric motor 5 or the vehicle with the implementation of efficient operation vibration from becoming excessively large, the rotational speed detection value N, the upper limit N ₂ from a predetermined lower limit value N ₁ It is determined whether or not the rotation speed is within the range. Predetermined rotational speed range referred to herein is the range on the implementation of the damping operation, the method of setting the lower limit value N ₁ and the upper limit N ₂ will be described later with reference to FIG.

The rotational speed detection value N, if is outside the rotational speed range from the lower limit value N ₁ to the upper limit N ₂ has a low level of vibration sound generated by the electric motor 5 even if conducted efficient operation, compensation The process part 10 progresses to the process of step S7, and implements an efficient driving | operation.

On the other hand, the rotational speed detection value N, when there within the rotational speed range from the lower limit value N ₁ to the upper limit N ₂ is Otofu level becomes excessive when carrying out the efficient operation. For this reason, the compensation processing unit 10 proceeds to the process of step S6 in order to perform the vibration damping operation.

In step S6, the compensation processing unit 10 refers to the current compensation table based on the torque command value T ^* and the rotation speed detection value N. Then, the compensation processing unit 10 _{calculates the} d-axis compensation amount i _d2 ^* (N, T ^* ) and the q-axis compensation amount i _q2 ^* (N, T ^* ) associated with the current compensation table, and calculates the calculated values. _Is set to the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 ^* .

As a result, the compensation amounts i _d2 ^* and i _q2 ^* are respectively obtained for the d-axis and q-axis current command values i _d1 ^* and i _q1 ^* calculated by the current command generation unit 1 in order to perform efficient operation. Is added.

As described above, when the driving state of the electric motor 5 is switched from the efficient operation to the vibration suppression operation, the compensation processing unit 10 reduces the d-axis current command value i _d ^* as shown in FIG. 2B. , Q-axis current command value i _q ^* is increased. Therefore, since the operating point of the electric motor 5 is shifted from the efficient operating point toward the vibration suppression operating point, sound vibration generated by the electric motor 5 can be suppressed.

  Further, when the switching condition from the efficient operation to the vibration suppression operation is not satisfied in step S4 or S5, or when the operation is forcibly switched to the efficient operation according to the traveling state of the vehicle in step S1 or S2, the compensation process The unit 10 proceeds to the process of step S7.

In step S7, the compensation processing unit 10 sets “0” in each of the d-axis and q-axis compensation amounts i _d2 ^* and i _q2 ^* in order to perform the efficient operation. Thus, each of the d-axis and the current command value of q-axis _{i d1} ^* and _{i q1} ^* is directly because it is set to the current command value _i ^{d *} and _i ^{q *,} implementing efficiency operation to the electric motor 5 can do.

  When the process of step S6 or S7 ends, the compensation processing unit 10 ends a series of processing procedures for the control method of the electric motor 5.

  In addition, although the control method of this embodiment demonstrated the example which performs each process of step S1, S2, S4, and S5 as switching conditions to vibration suppression control, it is not restricted to this. For example, at least one of the processes of steps S1, S2, S4, and S5 may be executed. Even in this case, it is possible to prevent the efficiency of the electric motor 5 from decreasing while suppressing the vibration generated by the operation of the electric motor 5.

  Next, a method for setting a vibration suppression operation range for performing the vibration suppression operation of the electric motor 5 will be briefly described with reference to FIGS. 4 and 5.

  FIG. 4 is a conceptual diagram showing an example of a vibration suppression operation range of the electric motor 5 in the present embodiment.

  In FIG. 4, the horizontal axis is the rotational speed N of the electric motor 5, the vertical axis is the generated torque T of the electric motor 5, the drive range of the electric motor 5 is indicated by a dotted line, and the vibration suppression operation range is indicated by a solid line. It is shown.

  Of the drive range of the electric motor 5, the vibration suppression operation of the electric motor 5 is performed within the vibration suppression operation range, and the efficient operation of the electric motor 5 is performed outside the vibration suppression operation range.

As shown in FIG. 4, a threshold value T <b> ₁ is set for the torque generated by the electric motor 5 as a switching condition from the efficient operation to the vibration suppression operation. The thresholds T _1, the value of the maximum torque when the electric motor 5 was carried damping operation is preset. The method of setting the threshold value T _1, will be described later with reference to FIG.

Further, as a switching condition from efficiency operation to the damping operation, the lower limit value defining the three rotational speed range N ₁ and the upper limit value N ₂ is set. The lower limit value N ₁ and the upper limit value N ₂ are derived from the inherent resonance frequency f ₀ in the electric motor 5 obtained from experimental data and simulation results.

In a general distributed winding motor, the sound vibration of the sixth harmonic f _6n that is a frequency of the sixth multiple tends to increase. The sixth-order harmonic f _6n can be calculated using the resonance frequency f ₀ , the number of poles P, and the natural number m as shown in Expression (1).

Therefore, the lower limit value N ₁ and the upper limit value N ₂ is set so as to cover the rotation speed range of the electric motor 5 that sound vibration level becomes excessive in the vicinity of the sixth harmonics f _6n.

  In this way, by finely defining the vibration suppression operation range, the implementation area of the efficient operation is expanded, so that the efficiency of the electric motor 5 can be reduced while reducing the excessive vibration caused by the rotation operation of the electric motor 5. It can suppress that it falls entirely.

  In the example of FIG. 4, three rotation speed ranges are set, but one or two rotation speed ranges may be set so that the three rotation speed ranges are included. Thereby, since the opportunity to switch from an efficient driving | operation to a vibration suppression driving | operation reduces, the torque fluctuation of the electric motor 5 which may arise by switching can be suppressed.

Figure 5 is a diagram illustrating a method of setting the thresholds T ₁ shown in FIG.

FIG 5, a vertical axis and d-axis current i _d abscissa at a current coordinate system with the q-axis current i _q, a plurality of equal current lines are indicated by dashed lines, a plurality of equal torque line is indicated by a solid line ing.

  The equicurrent line indicated by the solid line is usually drawn by the upper limit value of the current that can be supplied from the inverter unit 4 to the electric motor 5. The further away from the efficiency operating point P0 on the equicurrent line, the lower the efficiency of the electric motor 5, and the smaller the generated torque of the electric motor 5.

As shown in FIG. 5, to identify the damping operation point P1 which a an equal current line damping operating line Lsv intersect, is set torque value of the electric motor 5 at the damping operation point P1 as thresholds T ₁ The Thus, in the electric motor 5 to implement the damping operation, the generated torque value when the current supplied from the inverter unit 4 has reached the upper limit or the vicinity thereof is set as the threshold value T _1.

By setting the thresholds T ₁ with respect to the torque command value T ^* as the switching conditions between the damping operation and efficient operation, the switching to the damping operation when the torque command value T ^* exceeds the thresholds T ₁ It becomes possible to ban. Therefore, a situation where the maximum torque of the electric motor 5 is reduced can be avoided. On the other hand, that it allows the switching to the damping operation when the torque command value T ^* below the threshold T _1, it is possible to reduce the noise and vibration level of the electric motor 5 or the vehicle.

  Therefore, it is possible to suppress a decrease in the maximum torque of the electric motor 5 while reducing the excessive vibration caused by the operation of the electric motor 5.

Next, FIG. 7 shows a method for changing the d-axis and q-axis current command values i _d ^* and i _q ^* when the operation state of the electric motor 5 is switched between the vibration suppression operation and the efficiency operation. The description will be given with reference.

Figure 6 is a diagram for describing change method of the d-axis current i _d and the q-axis current i _q in a scene in which torque generated by the electric motor 5 is kept constant.

Figure 6 is a vertical axis and d-axis current i _d abscissa at a current coordinate system with the q-axis current i _q, multiple equal torque lines are indicated by dashed lines.

  The efficient operation point Pc1 on the same equal torque line is an operation point that intersects the efficiency operation line Le, and the vibration suppression operation point Pc2 is an operation point that intersects the vibration suppression operation line Lsv.

  When the operating state of the electric motor 5 is switched, a specific response delay occurs when the d-axis and q-axis components of the current supplied to the electric motor 5 are changed. For this reason, if the compensation processing unit 10 changes the compensation amount so as to move between the efficient operation point Pc1 and the vibration suppression operation point Pc2 by a single current control, torque fluctuation may occur in the electric motor 5. .

As a countermeasure, in a scene where the generated torque of the electric motor 5 is maintained constant, the compensation processing unit 10 generates a predetermined change amount of the generated torque on an equal torque line between the efficient operation point Pc1 and the vibration suppression operation point Pc2. The compensation amounts i _d2 ^* and i _q2 ^* of the d-axis and the q-axis are calculated step by step so as to move at the same time.

  The predetermined change amount is determined in advance based on the period obtained by obtaining a period during which the torque fluctuation of the electric motor 5 is suppressed when the operating state of the electric motor 5 is switched through experimental data and simulation results. For example, the predetermined change amount is obtained on the basis of a period shorter than the time from when the operating state is switched to when the torque fluctuation of the electric motor 5 occurs due to a response delay of the supply current to the electric motor 5. .

As described above, when the switching condition is established, the compensation processing unit 10 determines that the d-axis and q-axis current command values i _d ^* and the d-axis and q-axis current command values i _d ^* and so that the generated torque of the electric motor 5 follows the torque command value T ^*. i _q ^* is changed step by step. Thereby, when the driving | running state of the electric motor 5 is switched, the torque fluctuation which arises in the electric motor 5 can be suppressed.

In the above-described embodiment, the example in which the current command generation unit 1 calculates the current command values i _d1 ^* and i _q1 ^* of the d axis and the q axis based on the torque command value T ^* has been described. However, the current command generator 1 is not limited to this, and for example, a constant d-axis current command value i _d1 ^* and a q-axis current command value i _q1 ^* for rotating the electric motor 5 with a constant torque ^. May be output. Even in this case, the effects of the present embodiment can be obtained.

  In the present embodiment, as shown in FIGS. 2A and 2B, the vibration suppression operation line Lsv of the electric motor 5 is shifted to the lower right than the efficiency operation line Le. Is not limited to this.

For example, the control device 100 may control the electric motor 5 in which the vibration suppression operation line Lsv is shifted to the upper left than the efficiency operation line Le. In this case, the compensation processing unit 10 increases the d-axis current command value i _d ^* and decreases the q-axis current command value i _q ^* so as to reduce vibration caused by the operation of the electric motor 5. That is, if the compensation processing unit 10 determines that the condition for switching to the vibration suppression control is satisfied, both the current command values i _d ^* and i _q
Are changed in different directions.

  Next, functions and effects of the embodiment of the present invention will be described.

According to the present embodiment, the control device 100 that executes the method for controlling the electric motor 5 that constitutes the electric motor includes the d-axis and q-axis current command values i _d ^* and i _q ^* related to the power supplied to the electric motor 5 ^. Based on the above, the operation of the electric motor 5 is controlled. The current command generation unit 1 of the control device 100 calculates current command values i _d1 ^* and i _q1 ^* of both the d axis and the q axis so that an efficient operation for efficiently controlling the electric motor 5 is performed. The calculation step to be executed is executed.

  Then, as shown in FIG. 3, the compensation processing unit 10 of the control device 100 determines whether or not the switching condition for switching from the efficient operation to another operation state is satisfied, and the switching condition. A change step S6 for increasing one current command value and decreasing the other current command value when the above is established.

In this way, by switching the electric motor 5 from the efficient operation to another operation state in which both current command values i _d ^* and i _q ^* are changed in different directions, for example, the operating point of the electric motor 5 is changed to As shown in FIG. 2A, it is possible to approach the vibration suppression operation line Lsv.

  Thus, since the vibration generated by the electric motor 5 is suppressed as the operating point of the electric motor 5 approaches the vibration suppression operation line Lsv, the efficiency of the electric motor 5 decreases while reducing the vibration generated by the electric motor 5. Can be suppressed. That is, it is possible to achieve both sound vibration performance and efficiency in the electric motor 5.

Further, according to the present embodiment, when the compensation processing unit 10 that executes the process of the change step S6 determines that the switching condition from the efficient operation to the vibration suppression operation is satisfied, it is based on the torque command value T ^* . Both current command values i _d ^* and i _q ^* are brought close to a predetermined vibration suppression operation point. The predetermined vibration suppression operation point here is an operation point optimized to suppress vibration of the vehicle that constitutes the electric motor 5 or the housing that houses the electric motor 5, for example, as shown in FIG. 2B. This is an operating point on the vibration suppression operation line Lsv.

Thus, by bringing both current command values i _d ^* and i _q ^* closer to a predetermined vibration damping operation point, the level of sound vibration generated by the operation of the electric motor 5 is reduced as shown in FIG. 2A. be able to.

Further, according to this embodiment, as in the processing in step S4 in FIG. 3, the compensation processing unit 10, when the torque command value T ^* below the thresholds T ₁ on the implementation of efficient operation, both the current command The values i _d ^* and i _q ^* are changed in different directions. Thereby, the vibration which arises by operation | movement of the electric motor 5 can be suppressed, avoiding the situation where the maximum torque of the electric motor 5 restrict | limited by the upper limit electric current of the inverter part 4 falls.

Further, according to the present embodiment, another operation state that is switched from the efficient operation includes a vibration suppression operation that suppresses vibrations of the electric motor or a housing that houses the electric motor. When the rotational speed detection value N of the electric motor 5 is within a predetermined rotational speed range related to the execution of the vibration damping operation, as in the process of step S5, the compensation processing unit 10 determines both current command values i _d. ^{* And} i _q ^* are changed in different directions.

Lower limit N ₁ and the upper limit value N ₂ of the rotational speed range of the above, as described in FIG. 4, is defined to include peak in the frequency characteristic of the electric motor 5. Thereby, the torque ripple which arises in the rotational speed range of the electric motor 5, ie, an excessive sound vibration, can be suppressed.

  Furthermore, by defining the rotational speed range in consideration of the frequency characteristics of the electric motor 5, the area of efficient operation can be expanded. Therefore, it is possible to improve the efficiency of the electric motor 5 as a whole while suppressing the vibration generated by the electric motor 5 from becoming excessive.

In addition, according to the present embodiment, the compensation processing unit 10 allows both current commands so that the torque generated in the electric motor 5 follows the torque command value T ^* when the condition for switching to the damping operation is satisfied. The values i _d ^* and i _q ^* are changed stepwise. Thereby, as described in FIG. 7, torque fluctuations associated with switching of the operating state of the electric motor 5 can be suppressed in a situation where the generated torque of the electric motor 5 is kept constant.

  Further, according to the present embodiment, the electric motor 5 drives the vehicle, and the control device 100 that controls the electric motor 5 can select an operation mode in which the driver of the vehicle gives priority to efficient driving. Is possible.

In this case, the compensation processing unit 10 generates a current command when an efficient operation is selected by the driver even when the condition for switching to the vibration suppression control is satisfied as in the process of step S2 of FIG. The calculation value of the unit 1 is set to the d-axis and q-axis current command values i _d ^* and i _q ^* , respectively.

  As described above, the cruising distance of the vehicle can be extended by forcibly performing the efficient driving when the operation mode giving priority to the efficient driving is selected.

Moreover, according to this embodiment, the electric motor 5 drives a vehicle using the electric power of the battery 41 mounted in the vehicle. Then, the compensation processing unit 10 generates a current command when the remaining capacity of the battery 41 is less than a predetermined threshold even when the condition for switching to vibration suppression control is satisfied as in the process of step S1. The calculation value of the unit 1 is set to the d-axis and q-axis current command values i _d ^* and i _q ^* , respectively.

Further, even when the condition for switching to vibration suppression control is satisfied, the compensation processing unit 10 generates a current command when the travel distance between the charging spot capable of charging the battery 41 and the vehicle is longer than a specific threshold. The calculation value of the unit 1 is set to the current command values i _d ^* and i _q ^* of the d axis and the q axis.

  As a result, the efficient driving is forcibly performed according to the driving state of the vehicle such as the charging state of the battery 41 and the driving distance to the nearest charging spot, so that the running vehicle stops due to insufficient power of the battery 41. Can be avoided.

The embodiment of the present invention has been described above. However, the above embodiment only shows a part of application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. Absent. For example, in calculating the d-axis and q-axis current command values i _d ^* and i _q ^* for the control device 100, a general non-interference control function may be added.

1 Current command generator (calculation means, calculation step)
10 Compensation processing unit (switching means)
100 Control device S1, 2, 4, 5 Judgment step S6 Change step

Claims (8)

A control method for controlling the operation of the electric motor based on d-axis and q-axis current command values relating to electric power supplied to the electric motor,
A calculation step of calculating current command values of both the d-axis and the q-axis so that an efficient operation for efficiently controlling the electric motor is performed;
A determination step of determining whether or not a switching condition for switching from the efficient operation to another operation state is satisfied;
When the switching condition is satisfied, a change step of increasing one of the current command values and decreasing the other current command value;
An electric motor control method comprising: The method for controlling an electric motor according to claim 1,
In the changing step, when the switching condition is satisfied, the operating point specified by the both current command values is determined based on the torque command value for the motor, and the motor or the casing that houses the motor is used. Move closer to the specified operating point to suppress vibration,
Electric motor control method. A method for controlling an electric motor according to claim 1 or 2,
In the change step, when the torque command value for the electric motor is lower than a threshold value related to the implementation of the efficient operation, both the current command values are changed in different directions.
Electric motor control method. A method for controlling an electric motor according to any one of claims 1 to 3,
The other operation state includes a vibration suppression operation that suppresses vibration of the electric motor or a housing that houses the electric motor,
In the changing step, when the rotational speed of the electric motor is within a predetermined range related to the execution of the vibration damping operation, the current command values of both are changed in different directions.
Electric motor control method. A method for controlling an electric motor according to any one of claims 1 to 4, comprising:
In the change step, when the switching condition is satisfied, both the current command values are changed stepwise so that the torque generated in the electric motor follows the torque command value.
Electric motor control method. A method for controlling an electric motor according to any one of claims 1 to 5,
The electric motor drives a vehicle,
In the changing step, even when the switching condition is satisfied, when the efficient operation is selected, both values calculated in the calculating step are set as current command values for the d-axis and the q-axis, respectively. To
Electric motor control method. A method for controlling an electric motor according to any one of claims 1 to 6,
The electric motor drives the vehicle using electric power of a battery mounted on the vehicle,
In the changing step, even when the switching condition is satisfied, when the remaining capacity of the battery is less than a predetermined threshold, or the distance between the charging spot where the battery can be charged and the vehicle is specified. When far from the threshold value, both values calculated in the calculation step are set as current command values for the d-axis and q-axis, respectively.
Electric motor control method. A control device for controlling the operation of the electric motor based on d-axis and q-axis current command values relating to electric power supplied to the electric motor,
Arithmetic means for calculating current command values for both the d-axis and the q-axis so that efficient operation for efficiently controlling the electric motor is performed;
When switching from the efficient operation to another operating state, switching means for changing both current command values in different directions;
An electric motor control device.

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