JP6136998B2 - AC motor control device - Google Patents

Description

  The present invention relates to a control apparatus for an AC motor that detects a phase current of one phase among multiple phases by a current sensor and controls energization of the AC motor.

  In recent years, electric vehicles and hybrid vehicles equipped with AC motors have attracted attention as a power source for vehicles due to social demands for low fuel consumption and low exhaust emissions. For example, in a hybrid vehicle, a DC power source composed of a secondary battery or the like and an AC motor are connected via a power converter composed of an inverter or the like, and the DC voltage of the DC power source is converted into an AC voltage by the inverter. There is one that drives an AC motor.

  In such a control device for an AC motor mounted in a hybrid vehicle or an electric vehicle, a current sensor for detecting a phase current is provided in one “sensor phase”, and the “sensor phase” estimated based on the current detection value of the sensor phase is provided. A technique for controlling energization of an AC motor by feeding back an estimated current value other than “estimated phase” is known (see, for example, Patent Document 1). By providing the current sensor only in one phase, the number of current sensors is reduced, and the size near the output terminal of the inverter is reduced and the cost of the control system is reduced.

  In the control apparatus for an AC motor disclosed in Patent Document 1, an α-β coordinate system in which an α axis is defined in a direction that coincides with a sensor phase and a β axis is defined in a direction orthogonal to the α axis is used. The α-axis current iα is calculated based on iw_sns, and the β-axis current iβ is calculated based on the differential value Δiα of the α-axis current iα. Then, the sensor phase reference current phase θx is calculated from the α-axis current iα and the β-axis current iβ, and the estimated phase current estimation value iu_est is calculated based on the sensor phase reference current phase θx and the sensor phase current detection value iw_sns. calculate.

Since this control device calculates the β-axis current iβ based on the differential value Δiα of the α-axis current iα without using the current command value, the energization of the AC motor is performed as in the rectangular wave control mode of the torque feedback control method. The present invention is also applicable to a control mode that does not use a current command value for control. The “rectangular wave” in the rectangular wave control mode refers to a waveform of one pulse in one cycle of current.
On the other hand, in the current feedback control method using the dq-axis current command value for the energization control of the AC motor, the β-axis current iβ can be calculated using the phase current command value obtained by performing inverse dq conversion on the dq-axis current command value. Even in this case, after calculating the β-axis current iβ, the sensor phase reference current phase θx is calculated from the α-axis current iα and the β-axis current iβ.

JP 2013-172594 A

In the control apparatus for an AC motor disclosed in Patent Literature 1, the sensor phase reference current phase θx is calculated by calculating the arc tangent of a value obtained by dividing the α-axis current iα by the β-axis current iβ. Since this calculation uses a map, a large amount of memory is required. In addition, since the number of comparisons imposes processing, including (iα / iβ) division and conditional branching based on the sign and angle reference, the amount of computation increases. Furthermore, a short cycle calculation is required to improve the estimation accuracy.
In recent years, a digital circuit using a gate circuit or the like is often used for short-cycle computation, but a large gate circuit is required when the storage amount and computation amount are large, and the cost increases.
The present invention has been made in view of the above-described problems, and an object of the present invention is to control an AC motor that detects a phase current of one phase among multiple phases by a current sensor and calculates an estimated current value of another phase. It is an object of the present invention to provide a control device for an AC motor that reduces the storage amount and calculation amount of the control means.

The present invention relates to an inverter that drives a multi-phase AC motor having three or more phases, a current sensor that detects a current flowing in one sensor phase among the multi-phases of the AC motor, and a plurality of switching elements that constitute the inverter. The present invention relates to an AC motor control device including control means for switching on / off to control energization of the AC motor.
Here, the “AC motor” includes an AC drive motor, a generator, and a motor generator. For example, a motor that is used as a main machine of a hybrid vehicle or an electric vehicle and generates torque for driving drive wheels. Applicable to generators. In addition, for example, an electric motor control device that drives a motor generator corresponds to an “AC electric motor control device”.

The control means of the present invention includes a “shift current calculation means” for calculating a shift current value shifted in phase with respect to a current detection value for the sensor phase, It is characterized by having “another-phase current estimating means” for calculating an estimated current value of at least one phase other than the sensor phase by adding values obtained by multiplying “invariant coefficients” to each other.
In the present invention, the estimated current value of the estimation phase is calculated based on the detected current value of the sensor phase and the shift current. Unlike the control device of Patent Document 1, the calculation process of the sensor phase reference current phase θx that involves division and calculation of the arc tangent is not performed, so no map is required and the storage amount is small. In addition, since there is no calculation including conditional branching, the calculation amount is reduced. By reducing the storage amount and the calculation amount in this way, short cycle calculation can be realized with a small gate circuit.

Specifically, the control means calculates a shift current value as an output of a “delay filter” that receives a current detection value of the sensor phase that is a function of the phase, and based on the gain and phase of the transfer function of the delay filter. Thus, a “time invariant coefficient” can be calculated.
In addition, the control means may provide an integral value of a detected current value of the sensor phase in a section from a phase that is a predetermined phase (0 ° <ξ <720 °, ξ ≠ 360 °) from the arbitrary reference phase to the reference phase. The shift current value and the “time-invariant coefficient” may be calculated based on “(integrated shift current Ishift)”.

  In particular, when a current value whose phase is shifted by 90 [°] or 270 [°] with respect to the current detection value of the sensor phase is set as the shift current value, that is, when the shift current value is orthogonal to the current detection value of the sensor phase Is not limited to the quadrature quadrature of the sine wave, but can simplify the calculation and reduce the processing load by using differentiation and integration focusing on the relationship between the sine wave and the cosine wave.

It is a figure which shows the structure of the electric motor drive system to which the control apparatus of the alternating current motor by 1st Embodiment of this invention is applied. 1 is an overall configuration diagram of an AC motor control device according to a first embodiment of the present invention. FIG. It is a block diagram which shows the structure of the control part of the control apparatus of the alternating current motor of FIG. It is (a) phase-axis waveform figure which shows the shift electric current which shifted | deviated 90 degrees with respect to sensor phase electric current, (b) It is a figure of a fixed coordinate system. It is (a) phase-axis waveform figure which shows the shift electric current which shifted | deviated 30 degrees with respect to sensor phase electric current, (b) It is a figure of a fixed coordinate system. It is a figure explaining the switch timing and intermediate | middle timing in a rectangular wave control mode. It is a flowchart of the electric current estimation process by 1st Embodiment of this invention. It is a schematic diagram explaining the filter process by 2nd Embodiment of this invention.

Hereinafter, an AC motor control apparatus for controlling driving of an AC motor according to the present invention will be described with reference to the drawings. In the following embodiments, substantially the same components are denoted by the same reference numerals and description thereof is omitted.
(First embodiment)
As shown in FIG. 1, an electric motor control device 10 as an “AC electric motor control device” according to a first embodiment of the present invention is applied to an electric motor drive system 1 that drives a hybrid vehicle. The motor drive system 1 includes an AC motor 2, a DC power source 8, a motor control device 10, and the like.
The AC motor 2 is an electric motor that generates torque for driving the drive wheels 6 of the electric vehicle, for example. The AC motor 2 of the present embodiment is a permanent magnet type synchronous three-phase AC motor.

  The electric vehicle includes a vehicle that drives the drive wheels 6 with electric energy, such as a hybrid vehicle, an electric vehicle, and a fuel cell vehicle. The electric vehicle of the present embodiment is a hybrid vehicle including the engine 3, and the AC electric motor 2 is transmitted from the engine 3 and the drive wheel 6 as a function of an electric motor that generates torque for driving the drive wheel 6. It is a so-called motor generator (denoted as “MG” in the drawing) having a function as a generator that can be driven by the kinetic energy of the vehicle to generate electric power.

The AC motor 2 is connected to the axle 5 via a gear 4 such as a transmission. Thereby, the driving force of the AC motor 2 drives the drive wheels 6 by rotating the axle 5 via the gear 4.
The DC power supply 8 is a chargeable / dischargeable power storage device such as a secondary battery such as nickel metal hydride or lithium ion or an electric double layer capacitor. The DC power supply 8 is connected to an inverter 12 (see FIG. 2) of the motor control device 10 and is configured to be able to exchange power with the AC motor 2 via the inverter 12.

  The vehicle control circuit 9 is configured by a microcomputer or the like, and includes a CPU, a ROM, an I / O, a bus line that connects these, and the like, all of which are not shown. The vehicle control circuit 9 controls the entire electric vehicle by software processing by executing a program stored in advance by the CPU or hardware processing by a dedicated electronic circuit.

The vehicle control circuit 9 obtains signals from various sensors and switches such as an accelerator signal from an accelerator sensor (not shown), a brake signal from a brake switch, a shift signal from a shift switch, and a vehicle speed signal related to the vehicle speed. It is configured to be possible. The vehicle control circuit 9 detects the driving state of the vehicle based on these acquired signals and outputs a torque command value trq ^* corresponding to the driving state to the motor control device 10. The vehicle control circuit 9 outputs a command signal to an engine control circuit (not shown) that controls the operation of the engine 3.

As shown in FIG. 2, the motor control device 10 includes an inverter 12, a current sensor 13, and a control unit 15 as “control means”.
A boost voltage of a DC power source by a boost converter (not shown) is input to the inverter 12 as a system voltage VH. The inverter 12 has six switching elements (not shown) that are bridge-connected. As the switching element, for example, an insulated gate bipolar transistor (IGBT), a metal oxide semiconductor (MOS) transistor, a bipolar transistor, or the like can be used. On / off of the switching element is controlled based on the PWM signals UU, UL, VU, VL, WU, WL output from the PWM signal generation unit 25 of the control unit 15, so that the three applied to the AC motor 2 are controlled. The driving of the AC motor 2 is controlled based on the phase AC voltages vu, vv, vw.

The current sensor 13 is provided in any one phase of the AC motor 2. In the present embodiment, the current sensor 13 is provided in the W phase. Hereinafter, the W phase in which the current sensor 13 is provided is referred to as a “sensor phase”. The current sensor 13 detects the W-phase current as the sensor-phase current detection value iw_sns and outputs the detected current to the control unit 15.
Hereinafter, the description of the present embodiment will be made on the assumption that the sensor phase is the W phase. However, in other embodiments, the U phase or the V phase may be the sensor phase.

The rotation angle sensor 14 is provided in the vicinity of a rotor (not shown) of the AC motor 2, detects the electrical angle θe, and outputs it to the control unit 15. Further, based on the electrical angle θe detected by the rotation angle sensor 14, the rotational speed N of the rotor of the AC motor 2 is calculated. Hereinafter, “the rotational speed N of the rotor of the AC motor 2” is simply referred to as “the rotational speed N of the AC motor 2”.
The rotation angle sensor 14 of the present embodiment is a resolver, but in other embodiments, other types of sensors such as a rotary encoder may be used.

  The control unit 15 is configured by a microcomputer or the like, and includes a CPU, a ROM, an I / O, a bus line that connects these configurations, and the like, all of which are not shown. The control unit 15 controls the operation of the AC motor 2 by software processing by executing a program stored in advance by the CPU or hardware processing by a dedicated electronic circuit.

The motor control device 10 sets the AC motor 2 as “motor” according to the rotational speed N of the AC motor 2 based on the electrical angle θe detected by the rotation angle sensor 14 and the torque command value trq ^* from the vehicle control circuit 9. The power is consumed by “power running operation” or generated by “regenerative operation as a generator”. Specifically, the operation is switched in the following four patterns depending on whether the rotation speed N and the torque command value trq ^* are positive or negative.
<1. Forward rotation power consumption> Power consumption when the rotational speed N is positive and the torque command value trq ^* is positive.
<2. Forward rotation regeneration> When the rotational speed N is positive and the torque command value trq ^* is negative, power is generated.
<3. Reverse running power> Power consumption when the rotational speed N is negative and the torque command value trq ^* is negative.
<4. Reverse regeneration> Electricity is generated when the rotational speed N is negative and the torque command value trq ^* is positive.

When the rotational speed N> 0 (forward rotation) and the torque command value trq ^* > 0, or when the rotational speed N <0 (reverse rotation) and the torque command value trq ^* <0, the inverter 12 With this switching operation, the AC motor 2 is driven so that the DC power supplied from the DC power supply 8 side is converted into AC power and torque is output (powering operation).
On the other hand, when the rotational speed N> 0 (forward rotation) and the torque command value trq ^* <0, or when the rotational speed N <0 (reverse rotation) and the torque command value trq ^* > 0, the inverter 12 By the switching operation of the switching element, the AC power generated by the AC motor 2 is converted into DC power and supplied to the DC power supply 8 side to perform a regenerative operation.

Next, the configuration of the control unit 15 mainly applied to the rectangular wave control mode of the torque feedback control method will be described with reference to FIGS.
As shown in FIG. 3, the control unit 15 includes a torque subtractor 52, a PI calculation unit 53, a rectangular wave generator 54, a signal generator 55, a current estimation unit 40, and a torque estimation unit 56.

The torque subtractor 52 calculates a torque deviation Δtrq that is a difference between the estimated torque value trq_est fed back from the torque estimation unit 56 and the torque command value trq ^* .
The PI calculation unit 53 performs PI calculation on the “voltage phase command value VΨ” that is the phase command value of the voltage vector so that the torque deviation Δtrq converges to 0 so that the estimated torque value trq_est follows the torque command value trq ^*. Calculated by

The rectangular wave generator 54 generates a rectangular wave based on the voltage phase command value VΨ and the electrical angle θe, and generates a U phase voltage command value vu ^* , a V phase voltage command value vv ^* , and a W phase voltage command value vw ^*. Is output.
Based on the U-phase voltage command value vu ^* , the V-phase voltage command value vv ^* , and the W-phase voltage command value vw ^* , the signal generator 55 is a voltage command signal UU related to switching on / off of the switching element of the inverter 12. , UL, VU, VL, WU, WL are generated and output to the inverter 12.
Three-phase AC voltages vu, vv, vw are generated by controlling on / off of the switching elements of the inverter 12 based on the voltage command signals UU, UL, VU, VL, WU, WL. The three-phase AC voltages vu, vv, vw are applied to the AC motor 2, and the drive of the AC motor 2 is controlled so that torque according to the torque command value trq ^* is output.

The current estimation unit 40 calculates the current estimation value iu_est of the estimation phase by a characteristic calculation described later based on the current detection value iw_sns of the sensor phase detected by the current sensor 13 and the electrical angle θe acquired from the rotation angle sensor 14. Further, based on the detected current value iw_sns of the sensor phase and the estimated current value iu_est of the estimated phase, the d-axis current estimated value id_est and the q-axis current estimated value iq_est are calculated.
Based on the d-axis current estimated value id_est and the q-axis current estimated value iq_est estimated by the current estimating unit 40, the torque estimating unit 56 calculates the torque estimated value trq_est using a map or a mathematical formula and feeds it back to the torque subtractor 52. .

Next, a detailed configuration of the current estimation unit 40 will be described.
The current estimation unit 40 includes a shift current calculation unit 42 as “shift current calculation unit”, another phase current estimation unit 44 as “other phase current estimation unit”, and a dq conversion unit 45. The sensor phase current detection value iw_sns is input to the shift current calculation unit 42, the other-phase current estimation unit 44, and the dq conversion unit 45 in a multiple manner, and calculation is executed step by step in each unit.
In addition, since the control unit 15 of the present embodiment is applied to the torque feedback control type rectangular wave control mode, basically, the d-axis current command value id ^* and the q-axis current command value iq ^* are not used. .

The shift current calculation unit 42 calculates a “shift current value” in which the phase is shifted with respect to the detected current value iw_sns of the sensor phase. Here, as shown in FIG. 4B, the current phase of the current vector (Ia∠θx) of the current amplitude Ia with respect to the W-phase axis is defined as “sensor phase reference current phase θx”. The sensor phase current detection value iw_sns is expressed by equation (1) using the sensor phase reference current phase θx and the current amplitude Ia.
iw_sns = Ia × sin (θx) (1)
Regarding the symbol of the sensor phase reference current phase, “xθ” described in Patent Document 1 (Japanese Patent Laid-Open No. 2013-172594) and “θx” used in this specification are synonymous.

In the following description, in the present embodiment, it is assumed that the W phase is a sensor phase, and the current detection value iw_sns of the sensor phase is a continuous value that changes with a phase change. For example, “phase current detection value iw_sns”, or “W-phase detection current iw_sns” when expressed as a continuous waveform with respect to the phase. W-phase detection current iw_sns exhibits a sine waveform shown in FIG.
When a shift current value shifted by “shift phase γ” with respect to the detected current value iw_sns of the sensor phase is expressed as “(W phase) shift current value iwshift” or a continuous waveform, “value” is added. First, it is referred to as “(W phase) shift current iwshift”.

The range of the shift phase γ is 0 <γ <360 ° and γ ≠ 180 °, and the W-phase shift current value iwshift is expressed by Expression (2). FIG. 4 shows an example of “γ = 90 °”.
iwshift = Ia × sin (θx−γ) (2)
Supplementally, the U-phase current estimation value iu_est is expressed by Expression (3) in which the phase is shifted by 120 [°] with respect to the W-phase current detection value iw_sns of Expression (1). That is, the U-phase current estimated value iu_est corresponds to an example of the W-phase shift current value iwshift. In the following, the angle unit is displayed as [°] in the text and without [] in the formula.
iu_est = Ia × sin (θx−120 °) (3)

The other-phase current estimation unit 44 adds the values obtained by multiplying the current detection value iw_sns of the sensor phase and the W-phase shift current value iwshift calculated by the shift current calculation unit 42 by a “time-invariant coefficient”, respectively. By doing so, the U-phase current estimated value iu_est is calculated. That is, when A and B are “time-invariant coefficients”, the U-phase current estimated value iu_est is calculated by a calculation formula represented by the formula (4).
iu_est = A × iw_sns + B × iwshift (4)

The dq conversion unit 45 performs dq conversion on the U-phase current estimation value iu_est and the sensor phase (W-phase) current detection value iw_sns using Equation (5), and calculates the d-axis current estimation value id_est and the q-axis current estimation value iq_est. To do.

That is, if the information on the W-phase shift current value iwshift in equation (2) and the coefficients A and B in equation (4) are obtained, division and arctangent with a large processing load as in the prior art of Patent Document 1 are obtained. The U-phase current estimated value iu_est can be calculated only by multiplication and addition according to Equation (4) without calculating the sensor phase reference current phase θx by calculation.
Hereinafter, a specific calculation method of the W-phase shift current value iwshift and the coefficients A and B will be mainly described. First, the case where the shift phase γ is 90 [°] or 270 [°] will be described, and then the case where the shift phase γ is an angle other than 90 [°] or 270 [°] will be described.

<When Shift Phase γ is 90 [°] or 270 [°]>
As shown in FIG. 4, consider a case where a “W-phase orthogonal current” having a phase shifted by 90 ° with respect to the W-phase detection current iw_sns is set as the W-phase shift current iwshift. When formula (3) is expanded and arranged in the form of the sum of the term including “Ia × sin (θx)” and the term including “Ia × sin (θx−90 °) = − Ia × cos (θx)”. Equation (6) is obtained. The same applies to the case where the shift phase γ is 270 [°], only the sign is reversed.

  The W-phase current detection value iw_sns in the first term of Expression (6) is acquired from the current sensor 13. For the second term, information on the amplitude ratio ((√3) / 2) to the current amplitude Ia and the shift phase (90 [°]) is obtained from the mathematical formula. Therefore, if the W-phase shift current value iwshift (= Ia × sin (θx−90 °) = − Ia × cos (θx)) is obtained, the other-phase current estimation unit 44 obtains the U-phase current from Equation (6). An estimated value iu_est can be calculated.

In this case, since the W-phase shift current iwshift is a W-phase orthogonal current, the current information orthogonal to the W-phase is obtained by differentiating the W-phase detection current iw_sns using an angular velocity ω as shown in, for example, Expression (7). It can be obtained by. Here, it is assumed that the current amplitude Ia hardly changes with time, that is, the time derivative of the current amplitude Ia is zero.

By the way, in the control device of Patent Document 1 (Japanese Patent Laid-Open No. 2013-172594), the α-axis current iα is differentiated in the α-β coordinate system to calculate the β-axis current iβ, and then the α-axis current iα is converted to the β-axis current. The sensor phase reference current phase θx is calculated from the arc tangent of the value divided by iβ.
Since this calculation uses a map, a large amount of memory is required. In addition, since the number of comparisons imposes processing, including (iα / iβ) division and conditional branching based on the sign and angle reference, the amount of computation increases. Furthermore, a short cycle calculation is required to improve the estimation accuracy.
In recent years, a digital circuit using a gate circuit or the like is often used for short-cycle computation. However, a large gate circuit is required if the storage amount and computation amount are large, and the cost increases.

On the other hand, in this embodiment, the information on the β-axis current iβ obtained by differentiation is directly used in the equation (6), so that the other-phase current can be estimated without calculating the sensor phase reference current phase θx. It is a feature that can be done.
The means for obtaining the W-phase orthogonal current information is not limited to differentiation, and for example, integration may be used. The method of using this integration will be described in the next item.

<When the shift phase γ is an angle other than 90 [°] or 270 [°]>
For example, as shown in FIG. 5, a case is considered in which a current whose phase is shifted by 30 [°] with respect to the W-phase detection current iw_sns is set as the W-phase shift current iwshift. When Expression (3) is expanded and rearranged in the form of the sum of the term including “Ia × sin (θx)” and the term including “Ia × sin (θx−30 °)”, Expression (8) is obtained. .

  The W-phase current detection value iw_sns of the first term of Expression (8) is acquired from the current sensor 13. For the second term, information on the amplitude ratio (√3) to the current amplitude Ia and the shift phase (30 [°]) is obtained from the mathematical formula. Therefore, if the value of the W-phase shift current value “iwshift = Ia × sin (θx−30 °)” is obtained, the other-phase current estimation unit 44 calculates the U-phase current estimation value iu_est from Equation (8). be able to.

Next, a method for calculating the W-phase shift current value iwshift using “integrated shift current Ishift” will be described.
The shift current calculation unit 42 calculates the integration of the W-phase current detection value iw_sns in the section from the phase that is a predetermined phase (0 ° <ξ <720 °, ξ ≠ 360 °) from the arbitrary reference phase to the reference phase. Integral shift current Ishift is calculated as “value”. Here, the “arbitrary reference phase” may be a current phase at the time of calculation or a phase before the time of calculation.
First, “current (Ia × sin φ) as a function of phase φ is a section from phase (θ−ξ) to phase θ (where ξ is a phase where 0 ° <ξ <720 ° and ξ ≠ 360 °) Is defined as “integrated shift current Ishift”. Assuming that the amplitude Ia is invariant with respect to the phase θ, the integral shift current Ishift is expressed by Expression (9), where “arbitrary reference phase” is θ. Equation (9) is not limited to the sensor phase reference current phase θx with respect to the W phase, but is an equation for a general phase θ.

When formula (9) is transformed, formula (10) is obtained. Ks defined by Equation (11) indicates an amplitude ratio.

According to the equation (10), it can be seen that the integral shift current Ishift has an amplitude Ks times that of the current (Ia × sin θ) and the phase is shifted by (ξ / 2).
Applying to the present embodiment in which the W phase is the sensor phase, and replacing “phase θ” in equation (9) with “sensor phase reference current phase θx”, the current (Ia × sin θ) in equations (9) and (10) Corresponds to “W-phase detection current = Ia × sin (θx)”. Further, in relation to the equation (2), “ξ = 2γ”.
The table below shows examples of the phase ξ, the shift phase γ, and the amplitude ratio Ks indicating the integration interval.

Next, when equation (9) is modified and “θ = θx”, equation (12) defining “Ia × cos (θx)” using integral shift current Ishift is obtained.

Further, with respect to the U-phase current command value iu_est, Expression (3) is expanded and divided into sin (θx) and cos (θx) terms, and the right side of Expression (12) is substituted into “Ia × cos (θx)”. Further, when the expression (1) is replaced with “Ia × sin (θx) = iw_sns”, the expression (13) is derived.

  Formula (13) is a general formula corresponding to Formula (4). Thus, for an arbitrary phase ξ (= 2γ), the U-phase current command value iu_est is set to “a value obtained by multiplying the W-phase current detection value iw_sns and the integral shift current Ishift by respective times invariable coefficients. "Can be calculated.

The above-mentioned “when the shift phase γ is 30 °” will be verified. Substituting “ξ = 60 °” in equation (9) leads to equation (14). Therefore, the shift current calculation unit 42 calculates the integral shift current Ishift at ξ = 60 ° by the equation (14), and the other phase current estimation unit 44 calculates the U-phase current command value iu_est by the equation (8). can do.

Thus, by using the equations (9) to (13), the W-phase shift current value iwshift can be easily calculated even when the shift phase γ is an angle other than 90 [°] or 270 [°].
Since the calculation of the integral shift current Ishift is performed by piecewise quadrature of a sine wave, the calculation amount is reduced and the calculation load can be reduced as the shift phase γ is set to be relatively small. On the other hand, as the shift phase γ is set relatively large, the influence of noise can be reduced and the calculation accuracy of the integral shift current Ishift can be improved.

Further, supplementary explanation will be given for the current detection timing in the rectangular wave control mode.
As shown in FIG. 6, the voltage waveform of each phase in the rectangular wave control mode is a current cycle in which 0 [V] in the off state and the system voltage VH in the on state are switched every 180 [°]. The waveform of one pulse. The phases of the three-phase voltage waveforms are shifted from each other by 120 [°], and a switching element (not shown) of any phase of the inverter 12 is turned on / off every electrical angle of 60 [°]. The waveform is switched on / off.

The on / off timing of the switching element is referred to as “switch timing”. The difference in electrical angle θe between successive switch timings is 60 [°]. The timing set between successive switch timings is called “intermediate timing”. The difference in electrical angle θe between the intermediate timings is also 60 [°].
In FIG. 6, the electrical angle difference between successive switch timings is divided into two equal parts, and the intermediate timing is set at an electrical angle θe that is shifted by 30 [°] from the switch timing. However, the present invention is not limited to this example, and the intermediate timing may be set to an electrical angle θe other than 30 [°] from the switch timing, or may be set twice or more between successive switch timings. .

The sensor phase current detection value iw_sns is detected at least one of the switch timing and the intermediate timing. Therefore, a current detection value with an electrical angle of 60 [°] is obtained.
When the integral shift current Ishift is used, the shift current calculation unit 42 calculates the integral shift current Ishift by an integral calculation with respect to the sensor phase current detection value iw_sns. This integration operation corresponds to the detection timing of the sensor phase current detection value iw_sns, and is preferably executed in at least one of the phase intervals between the switch timings or the phase interval between the intermediate timings.

Next, a current estimation processing routine executed by the current estimation unit 40 based on the logics of the above formulas (9) to (13) will be described with reference to the flowchart of FIG. In the following description of the flowchart, the symbol S indicates “step”.
This current estimation routine is repeatedly executed at a predetermined calculation period during the power-on period of the control unit 15. When this routine is started, in the first S10, the current detection value iw_sns of the sensor phase detected by the current sensor 13 is acquired, and the electrical angle θe of the AC motor 2 detected by the rotation angle sensor 14 is acquired.

In S30, the current detection value iw_sns (= Ia × sin (θx)) of the sensor phase is integrated with respect to a predetermined phase interval by the equation (9), and the integrated shift current Ishift is calculated.
In S50, the current detection value iw_sns of the sensor phase and the value obtained by multiplying the integral shift current Ishift by the “time-invariant coefficient” are added to each other to calculate the U-phase current estimation value iu_est according to the equation (13). To do.

In S60, the U-phase current estimation value iu_est and the sensor phase (W-phase) current detection value iw_sns are dq-transformed by the equation (15) to calculate the d-axis current estimation value id_est and the q-axis current estimation value iq_est. .
Above, the current estimation routine which the current estimation part 40 performs is complete | finished.

(effect)
(1) The electric motor control apparatus 10 of this embodiment detects the phase current of one phase among three phases by the current sensor 13, and estimates the other two-phase phase currents. By providing the current sensor 13 only in the sensor phase, the number of current sensors 13 can be reduced. Thereby, the three-phase output terminal vicinity of the inverter 12 can be reduced in size, and the cost of the motor control apparatus 10 can be reduced.
Further, by making the number of the current sensors 13 one, the influence of the gain error of the current sensor which can be generated in the conventional AC motor control system using a plurality of current sensors is eliminated. Thereby, in the AC motor 2, the output torque fluctuation caused by the gain error of the plurality of current sensors can be eliminated. For example, in the case of a vehicle, the vehicle vibration is eliminated, and an element for reducing the merchantability of the vehicle. Can be removed.

  (2) The current estimation unit 40 calculates a current estimation value iu_est of the estimation phase based on the current detection value iw_sns of the sensor phase and the shift current value iwshift. Unlike the control device of Patent Document 1, the calculation process of the sensor phase reference current phase θx that involves division and calculation of the arc tangent is not performed, so no map is required and the storage amount is small. Also, there is no operation including conditional branching. The amount of calculation is reduced. By reducing the storage amount and the calculation amount in this way, short cycle calculation can be realized with a small gate circuit.

  (3) When the shift phase γ is an angle other than 90 [°] or 270 [°], the integral shift current Ishift is calculated by the quadrature quadrature of the sine wave. The calculation amount increases. On the other hand, when the shift phase γ is 90 [°] or 270 [°], that is, when the shift current value iwshift is orthogonal to the current detection value iw_sns of the sensor phase, the sine wave and cos are not limited to piecewise quadrature. Calculations can be simplified and processing load can be reduced by using differentiation and integration focusing on the relationship with waves.

  (4) When the shift current value iwshift is calculated from the integrated shift current Ishift, the shift current calculation unit 42 detects the current value iw_sns of the sensor phase at least in one of the phase intervals between the switch timings or the phase interval between the intermediate timings. Is integrated to calculate the shift current Ishift.

  While the waveform of the current detection value detected at each switching timing is affected by the switching operation, the waveform is distorted, while the waveform of the current detection value detected at each intermediate timing is not affected by the switching operation. Is hardly distorted. Therefore, the current waveform consisting of both the current detection value at each switch timing and the current detection value at each intermediate timing does not increase or decrease regularly like a sine wave, but tends to increase or decrease irregularly.

On the other hand, both of the waveform of the current detection value detected at each switching timing and the waveform of the current detection value detected at each intermediate timing increase or decrease almost regularly in each waveform. Therefore, if the integral calculation of the shift current Ishift is executed in the phase interval between the switch timings or in the phase interval between the intermediate timings, the influence of the current detection value that irregularly increases and decreases between the switch timing and the intermediate timing is almost eliminated. Without being received, the integral shift current Ishift can be calculated with high accuracy. As a result, the calculation accuracy of the estimated current value iu_est of the estimated phase can be improved.
The same applies to the timing of the differential operation for calculating the shift current by differentiating the W-phase detection current iw_sns when the shift phase γ is 90 [°] or 270 [°].

(Second Embodiment)
The integration operation in the first embodiment is understood as a kind of filter processing in a broader concept. Therefore, a mode in which the shift current calculation unit 42 of the control unit 15 calculates the shift current by continuously executing the delayed filter processing will be described as a second embodiment. This delay filter includes a second-order or higher-order delay filter. Here, a first-order delay filter will be described as an example.
The second embodiment is common to FIGS. 1 to 6 of the first embodiment with respect to the overall configuration of the AC motor control device, the configuration of the control unit, the example of the sensor phase current detection value iw_sns and the shift current value iwshift, and the like. Can be referred to. Further, FIG. 7 is the same except for the term “integrated shift current Ishift” in S30 and S50.

The transfer function G (s) of the first-order lag filter used in the second embodiment is shown in Expression (15). κ is a constant.

When the filter process is executed for each predetermined angle, the response g (θ), the input f (θ), and the output h (θ) are expressed by equations (16), (17), and (18). The response g (θ) is a function obtained by inverse Laplace transform of the transfer function G (s). Further, the input f (θ) indicates the detected current, and the output h (θ) indicates the shift current. These relationships are schematically shown in FIG. In FIG. 8, L represents Laplace transform, and L- ¹ represents inverse Laplace transform.

For the sake of simplicity, the shift current h (θ) defined by the equation (18) is obtained by using the gain | G | (the equation (19.1)) and the phase ∠G (the equation (19.2)) of the transfer function. , And may be handled as in equation (20).

The above equations (16), (17), (18), and (20) are equations for a general phase θ. When applied to the present embodiment in which the W phase is the sensor phase and “phase θ” in equation (17) is read as “sensor phase reference current phase θx”, as shown in equation (21), input f (θx) (= Ia × sin (θx)) corresponds to the W-phase detection current iw_sns.

Then, assuming that the estimated phase is the V phase, the other-phase current estimating unit 44 calculates the V-phase current estimated value iv_est by the equation (22) derived by a process similar to the equation (13).

In the case where the filter process is executed every predetermined time instead of every predetermined angle, “θ” can be replaced with “ωt (angular velocity × time)”, and the same calculation formula as described above can be derived. At this time, if the constant κ included in the transfer function G (s) is changed according to the rotational speed (proportional to the angular velocity ω), the influence of the gain | G | and the phase ∠G from the angular velocity ω can be reduced.
In addition, the second embodiment has the same effects as the first embodiment.

(Other embodiments)
(A) The sensor phase for detecting the phase current by the current sensor is not limited to the W phase in the above embodiment, and may be the U phase or the V phase. Further, in the first embodiment, the U phase is exemplified as the estimated phase in the second embodiment, but in the case where the sensor phase is the U phase or the V phase, the W phase may be defined as the estimated phase.

(A) The AC motor control apparatus according to the present invention is not limited to the torque feedback control type rectangular wave control mode shown in the above embodiment, but is applied to the current feedback control type sine wave PWM control mode and overmodulation PWM control mode. May be.
For example, the control device disclosed in Japanese Patent Application Laid-Open No. 2013-172592 / 172593 is applied to a current feedback control method, and in an α-β coordinate system, two-phase current command values other than the sensor phase (for example, iu ^* and iv ^* ), Alternatively, the β-axis current iβ orthogonal to the α-axis current iα is calculated based on the current command value of one phase other than the sensor phase and the current detection value of the sensor phase (for example, iv ^* and iw_sns). By directly using the β-axis current iβ calculated in this way as the “shift current” in the equation (6) of the above embodiment, the other-phase current can be estimated without calculating the sensor phase reference current phase θx. The same effects as in the above embodiment are achieved.

  (C) The AC motor of the above embodiment is a permanent magnet type synchronous three-phase AC motor. However, in other embodiments, an induction motor or other synchronous motor may be used. In addition, the AC motor of the above embodiment is a so-called motor generator having both a function as a motor and a function as a generator. However, in other embodiments, the AC motor may not have a function as a generator. Furthermore, the present invention is not limited to a three-phase AC motor, and can be widely applied to a multi-phase AC motor having three or more phases.

  (D) The control device for an AC motor according to the present invention is not limited to a system in which only one set of an inverter and an AC motor is provided as in the above embodiment, but may be applied to a system in which two or more sets of inverters and AC motors are provided. Good. Further, the present invention may be applied to a system such as a train in which a plurality of AC motors are connected in parallel to one inverter.

(E) The control device for an AC motor according to the present invention is not limited to the AC motor of the hybrid vehicle having the configuration shown in FIG. 1, and may be applied to an AC motor of an electric vehicle having any configuration. Moreover, you may apply to AC motors other than an electric vehicle.
As mentioned above, this invention is not limited to the said embodiment at all, In the range which does not deviate from the meaning of invention, it can implement with a various form.

2 ... AC motor,
10: Electric motor control device (AC motor control device),
12 ... Inverter,
13 ... Current sensor,
15 ... control unit (control means),
42 ... shift current calculation unit (shift current calculation means),
44. Other phase current estimation unit (other phase current estimation means).

Claims (4)

An inverter (12) for driving a three-phase or more multi-phase AC motor (2);
A current sensor (13) for detecting a current flowing in a single sensor phase among the multiphases of the AC motor;
Control means (15) for switching energization of the AC motor by switching on / off of a plurality of switching elements constituting the inverter;
With
The control means includes
Shift current calculation means (42) for calculating a shift current value shifted in phase with respect to the current detection value of the sensor phase;
Other phase current estimation means for calculating a current estimation value of at least one phase other than the sensor phase by adding values obtained by multiplying the current detection value of the sensor phase and the shift current value by a time-invariant coefficient. (43)
A control device (10) for an AC motor, characterized by comprising: The control means includes
Calculating the shift current value as an output of a delay filter that receives a current detection value of the sensor phase that is a function of the phase;
2. The AC motor control apparatus according to claim 1, wherein the time-invariant coefficient is calculated based on a gain and a phase of a transfer function of the delay filter. The control means includes
Based on an integration value of a current detection value of the sensor phase in a section from a predetermined phase (0 ° <ξ <720 °, ξ ≠ 360 °) from a predetermined phase to the reference phase. The control apparatus for an AC motor according to claim 1, wherein a shift current value and the time-invariant coefficient are calculated.   The shift current value is a current value having a phase shifted by 90 [°] or 270 [°] with respect to a current detection value of the sensor phase. AC motor control device.

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