JP5334524B2 - Permanent magnet synchronous motor control device and control method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To drive and control a motor with high accuracy by identifying an induction voltage coefficient of a permanent magnet synchronous motor accurately regardless of the size of a load torque. <P>SOLUTION: A control device includes a current detector 4 which detects a current value to an inverter 2, a power estimator 9 which estimates a power value to be supplied to the motor 1 by using the current value detected by the current detector 4, a current estimator 11 which estimates a d-shaft current value and a q-shaft current value of the motor 1 by using the current value detected by the current detector 4, a Ke identification calculator 12b which identifies the induction voltage coefficient of the motor 1 by assigning the power value estimated by the power estimator 9 and the d-shaft current value and the q-shaft current value estimated by the current estimator 11 to a predetermined equation when each of a plurality of speed commands showing different speeds is output each, and an output voltage command calculator 15 which calculates the voltage of each phase to be added from the inverter 2 to the motor 1 by using the induction voltage coefficient identified by the Ke identification calculator 12b. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a technique for driving a permanent magnet synchronous motor by supplying electric power from an inverter to the permanent magnet synchronous motor.

  Conventionally, as a method for driving and controlling a permanent magnet synchronous motor without providing a position sensor or a torque sensor, there is a method disclosed in Patent Document 1 below.

  In this method, first, the current flowing from the inverter to the permanent magnet synchronous motor is detected, the d-axis current and q-axis current of the motor are identified from this current value, and the identification is performed under the assumption that the load torque of the motor is small. The induced voltage coefficient is identified using the d-axis current and the q-axis current. Then, using the identification values of the d-axis current, the q-axis current, and the induced voltage coefficient, the voltage of each phase applied from the inverter to the motor is determined, and the motor is driven and controlled.

  However, in the technique described in Patent Document 1, since the induced voltage coefficient is identified under the assumption that the motor load torque is small so that the motor load torque can be substantially ignored, the load torque is large. In this case, there is a problem that the identification accuracy of the induced voltage coefficient is lowered, and the motor cannot be controlled with high accuracy.

  The present invention pays attention to such problems of the prior art, and accurately identifies the induced voltage coefficient of the motor without providing a sensor such as a position sensor in the motor, thereby controlling the motor with high accuracy. Objective.

In order to solve the above problems, in the present invention,
Of the motor constants representing the characteristics of the permanent magnet synchronous motor, at least using the induced voltage coefficient,
In a control device for a permanent magnet synchronous motor comprising output voltage command means for obtaining a voltage applied to the permanent magnet synchronous motor from an inverter and transmitting a command value of the voltage to the inverter,
Current detection means for detecting a current value supplied to the permanent magnet synchronous motor;
Using a current value detected by the current detection means, a power estimation means for estimating a power value supplied to the permanent magnet synchronous motor;
Current estimation means for estimating the d-axis current value and the q-axis current value of the permanent magnet synchronous motor using the current value detected by the current detection means;
When each of the output voltage command means receives a plurality of speed commands indicating different speeds, the power value estimated by the power estimation means, the d-axis current value and the q-axis current estimated by the current estimation means Substituting a value into a predetermined formula, coefficient identifying means for identifying an induced voltage coefficient of the permanent magnet synchronous motor;
With
The output voltage command means uses the induced voltage coefficient identified by the coefficient identification means when obtaining the voltage to be applied to the permanent magnet synchronous motor from the inverter.
It is characterized by that.

  According to the present invention, the induced voltage coefficient is identified by using the power supplied to the motor having a correlation with the load torque of the permanent magnet synchronous motor, so that the induced voltage can be accurately induced regardless of the magnitude of the load torque to the motor. The voltage coefficient can be identified. Thus, in the present invention, since the induced voltage coefficient is accurately identified, the output voltage command determined using this value is also accurate, and the motor can be controlled with high accuracy.

  Hereinafter, various embodiments of a drive control apparatus for a permanent magnet synchronous motor according to the present invention will be described with reference to the drawings.

"First embodiment"
A first embodiment of a drive control apparatus for a permanent magnet synchronous motor according to the present invention will be described with reference to FIGS.

  As shown in FIG. 4, the drive control apparatus 100 according to the present embodiment converts the AC power from the AC power supply 111 into DC power, and stabilizes the DC voltage of the DC power supply circuit 3. Capacitor 18, DC power from DC power supply circuit 3 is converted into three-phase AC power, inverter 2 that is supplied to permanent magnet synchronous motor 1, current detector 4 that detects the current flowing through inverter 2, and inverter 2 Includes a control unit 17 that outputs a signal indicating a voltage value of each phase applied to the permanent magnet synchronous motor 1, and a substrate 19 on which these are mounted.

  As shown in FIG. 3, the current detector 4 has a shunt resistor provided in a DC power current path from the DC power supply circuit 3 to the inverter 2. The inverter 2 and the permanent magnet synchronous motor 1 are connected by a wiring 101 through which AC power of each phase passes.

  This permanent magnet synchronous motor (hereinafter simply referred to as a motor) 1 outputs a motor torque obtained by combining a torque component due to the magnetic flux of the permanent magnet and a torque component due to the inductance of the armature winding. A fan 102 is attached to the rotating shaft of the motor 1, and the fan 102 is driven to blow air from the fan 102 to the heat radiating fins 103. In the present embodiment, the above-described drive control device 100, the motor 1, the fan 102, and the heat radiation fin 103 are included to constitute a heat exchanger. Here, the motor 1 and the drive control device 100 are components of a heat exchanger, but the present invention is not limited to this, and may be components of other devices or the like. Needless to say.

  The control unit 17 is a microcomputer, which is a microcomputer that executes various operations, a ROM that stores various programs and fixed data in advance, a RAM that serves as a work area of the CPU, and an external input of signals. And an interface for performing output.

  The control unit 17 functionally outputs an operation mode generator 5 that outputs commands for various operation modes in accordance with instructions from the input device 112, and outputs a speed command in accordance with the operation mode commands from the operation mode generator 5. A speed command generator 6 for generating the voltage command and a voltage command generator 7 for generating a voltage command value for each phase of the inverter 2. Each of these functional units 5, 6 and 7 functions when the CPU executes a program stored in the ROM. Here, the control unit 15 is constituted by one microcomputer, but may be constituted by a plurality of microcomputers.

  Next, a detailed functional configuration of the control unit 17 will be described with reference to FIG.

The operation mode generator 5 of the control unit 17 outputs an operation mode command of either “normal operation mode” or “trial operation mode” in accordance with the instruction from the input device 112 (FIG. 3). The speed command generation unit 6 generates a speed command ωr *, which is a command for the speed of the motor 1, in response to the operation mode command from the operation mode generation unit 5. “*” Indicates a command value in this state when attached to a parameter relating to the state such as speed or current, and indicates an invariant value when attached to an invariable value such as resistance. Indicates the setting value. The voltage command generator 7 estimates the rotational speed ω of the motor 1 based on the direct current I _DC detected by the current detector 4 and the voltage of each phase of the motor 1 so as to follow the speed command ωr *. Outputs a PWM signal for controlling.

The voltage command generation unit 7 includes an operation mode generation unit 8 that outputs various types of operation according to the operation mode, a PDC estimation unit 9 that estimates DC power P _DC supplied to the inverter 2, and DC power P _DC. Idc-DC / Iqc-DC estimation section (second current estimation means) 10 for estimating the d-axis current I _d and the q-axis current I _q based on the above, and the reactive current Ir of the DC current I _DC supplied to the inverter 2 Idc-ar / Iqc-ar estimating unit (first current estimating means) 11 for estimating the d-axis current I _d and the q-axis current I _q based on the components of the effective current Ia and the resistance value of the permanent magnet synchronous motor 1 An identification calculation unit 12 for identifying R and an induced voltage coefficient Ke, an Id * calculation unit 13 for determining a d-axis current command I _d *, an Iq * calculation unit 14 for calculating a q-axis current command I _q *, and an inverter 2 of each phase of the output voltage command value V _u *, V _v *, and the output voltage command calculation unit 15 that calculates the V _w *, the output voltage command value V _u *, V _v *, based on V _w * And a PWM signal generator 16 for generating PWM signals (Pu, Pv, Pw).

PDC estimating portion 9, a filter 9a averaging the direct current I _DC supplied to the inverter 2, PDC operation for obtaining a DC power P _DC based on the average DC current I _DC-LF is output from the filter 9a Part 9b.

Idc-DC / Iqc-DC estimator (second current estimating means) 10, based on operating configuration of the operation mode generator 8, the switching unit 10c to switch the output destination of the DC power P _DC from the PDC estimator 9 when using a DC power P _DC of the normal operation will be described later, and Iqc-DC calculation unit 10a for obtaining the second q-axis current I _qc-DC, the DC power P _DC at a DC positioning operation described later And an Idc-DC calculation unit 10b for obtaining a second d-axis current I _dc-DC .

Idc-ar / Iqc-ar estimating unit 11 (first current estimation means), Ia seeking active current Ia and reactive current Ir using a direct current I _DC supplied to the inverter 2, and Ir computing unit 11a, obtains An Idc-ar / Iqc-ar calculation unit 11b for obtaining a first d-axis current I _dc-ar and a first q-axis current I _qc-ar using the effective current Ia and the reactive current Ir. ing.

The identification calculation unit 12 uses the second d-axis current I _dc-DC to identify the resistance value R of the motor 1, the R identification calculation unit 12a, the DC power P _DC, and the first d-axis current I _dc- A Ke identification calculation unit 12b that identifies the induced voltage coefficient Ke of the motor 1 using _ar and the first q-axis current I _qc-ar is provided.

As shown in FIG. 2, the output voltage command calculation unit 15 includes a dq axis voltage command calculation unit 15a for obtaining voltage command values V _d * and V _q * of each axis of the motor 1, an actual d axis and a control axis ( An axis error calculation unit 15b for obtaining a magnetic pole phase error Δθc that is a phase difference from the set d axis), and a speed correction amount calculation unit 15c for obtaining a speed correction amount Δω that is a speed difference between the actual d-axis speed and the control axis. A speed estimator (adder) 15d for estimating the speed ω1 of the control axis, a phase estimator (integrator) 15e for determining the phase θdc of the control axis, and voltage command values V _d *, V _q * for each axis Is converted to voltage command values V _u *, V _v *, V _w * for each phase of the motor 1 using the phase θd.

  The phase θdc of the control axis (set d axis) is based on the α axis that does not rotate and move even when the motor 1 is driven, as shown in FIG. The magnetic pole phase error Δθc is the phase difference between the actual d-axis and the control axis (set d-axis) as described above.

  Next, the operation of each part of the control unit 15 will be described.

  As described above, the operation mode generator 5 outputs either an operation mode command indicating the “trial operation mode” or an operation mode command indicating the “normal operation mode”.

When an operation mode command indicating “trial operation mode” is output, the speed command generator 6 sequentially outputs speed commands ω _r * indicating at least two different speed values in order to identify the induced voltage coefficient Ke. For example, the speed command ω _r * 1 and the speed command ω _r * 2 are sequentially output.

  Here, the change in the speed command ωr * with respect to the elapsed time in the “trial operation mode” will be described with reference to FIG.

For example, the speed command ω _r ^* is the speed command value ω _r * 1 at time t10, increases from time t11, and changes to the speed command value ω _r * 2 at time t12. Thus, in the “trial operation mode”, at least one acceleration or deceleration is performed, and two or more different speed commands are output.

  The operation will be described again with reference to FIG.

When the operation mode command indicating the “normal operation mode” is output from the operation mode generation unit 5, the speed command generation unit 6 outputs a desired speed command ω _r * required for actual operation. When the speed command generator 6 outputs a desired speed command ω _r * during the “normal operation mode”, the operation mode generator 8 will be described below as an operation mode according to the speed command ω _r *. , DC positioning operation, synchronous operation, normal operation (sensorless control operation) is selected.
DC positioning operation When the ω _r ^* = 0 is stopped, the d-axis current Id is supplied to the motor 1 to attract the magnetic pole position of the motor 1 to the control axis.
Synchronous operation The speed command value ω _r ^* is increased from ω _r ^* = 0, the rotation of the motor 1 is accelerated, a predetermined d-axis current Id is passed (q-axis current is 0), and a transition to the synchronous operation state is made (low speed region) Driving).
Normal operation (sensorless control operation)
From the synchronous operation, the speed command value ω _r ^* is further increased, and at the same time, the d-axis current Id is brought close to zero, and the q-axis current Iq is made to flow instead to shift to the normal operation (high-speed region operation).

The PDC estimator 9, the operation mode, regardless of the operation mode in each operating mode, the direct current I _DC supplied to the inverter 2, to estimate the DC power P _DC supplied to the inverter 2.

In the filter 9a of the PDC estimation unit 9, the direct current _IDC is averaged using the equation shown in the following (Equation 1) to obtain the average direct current _IDC-LF .

Where T _dF : Filter time constant
The PDC calculating unit 9b of the PDC estimator 9, the formula shown below (Equation 2), by substituting the average DC current I _DC-LF and DC voltage V _DC, obtains the DC power P _DC.

Here, the PDC calculation unit 9b stores in advance the DC voltage _VDC of the DC power supplied from the DC power supply circuit 3 to the inverter 2. However, a separate voltmeter may be provided in the DC power supply circuit 3 separately, and the output value from this voltmeter may be used as the DC voltage _VDC .

The Idc-DC / Iqc-DC estimation unit 10 estimates the second q-axis current I _qc-DC or the second d-axis current I _dc-DC according to the operation mode.

Switching unit of Idc-DC / Iqc-DC estimator 10 10c, when the operating mode generating unit 8 selects the "DC positioning operation", Idc-DC calculation unit DC power P _DC estimated by the PDC estimator 9 Send to 10b. The Idc-DC calculation unit 10b calculates the DC power P _DC sent from the switching unit 10c and the dq axis voltage command calculation unit 15a of the output voltage command calculation unit 15 by the following (Equation 3). A second d-axis current I _dc-DC is obtained using the shaft voltage command value V _d *.

Further, the switching unit 10c is configured so that the DC power estimated by the PDC estimation unit 9 is selected when the operation mode generation unit 8 selects “normal operation mode” and “normal operation”, and further selects “trial operation mode”. Send P _DC to Iqc-DC calculation unit 10a. The Iqc-DC calculation unit 10a calculates the DC power P _DC sent from the switching unit 10c and the q determined by the dq-axis voltage command calculation unit 15a of the output voltage command calculation unit 15 by the following (Equation 4). A second q-axis current I _qc-DC is obtained using the voltage command value V _q * of the axis.

  Note that (Equation 3) and (Equation 4) shown above will be described in detail later.

Idc-ar / Iqc-ar estimating part 11, the active current Ia, estimates the reactive current Ir using a direct current I _DC to unfiltered 9a. Ia of Idc-ar / Iqc-ar estimating unit 11, Ir computing unit 11a, the direct current I _DC to unfiltered 9a, obtaining the active current Ia and reactive current Ir in a known manner. The Idc-ar / Iqc-ar computing unit 11b uses the effective current Ia and the reactive current Ir obtained by the Ia and Ir computing unit 11a to perform the first d-axis current I _dc-ar and the first Q-axis current I _qc-ar is obtained. The first d-axis current I _dc-ar and the first q-axis current I _qc-ar are used to identify the induced voltage coefficient Ke in the test operation mode, as will be described later. The -ar / Iqc-ar estimation unit 11 only needs to operate in the test operation mode.

  The identification calculation unit 12 identifies the resistance value R of the motor 1 during the “DC positioning operation” in the “normal operation mode”, and identifies the induced voltage coefficient Ke of the motor 1 during the “trial operation mode”.

The R identification calculation unit 12a of the identification calculation unit 12 calculates the first d-axis obtained by the Idc-DC calculation unit 10b during the “DC positioning operation” in the “normal operation mode” according to the following (Equation 5). Using the current I _dc-DC , the resistance set value R * stored in advance by itself, and the d-axis current command I _d * determined by the Id * calculation unit 13, the identification value of the resistance of the motor 1 Find R ^. “^” Indicates an identification value. The R identification calculation unit 12a stores and updates the identification value R ^ as a new resistance identification value. The identification value R ^ stored by the R identification calculation unit 12a is used when the output voltage command calculation unit 15 calculates the output voltage command value, and the resistance set value R when the resistor identification value is next calculated by itself. Also used as *.

Further, the Ke identification calculation unit 12b of the identification calculation unit 12 uses the following (Equation 6) to determine the DC power P in the speed commands ω1 * and ω2 * estimated by the PDC estimation unit 9 in the “trial operation mode”. _DC1, a _{P DC2, Idc-ar / Iqc} -ar estimation unit 11 estimated by the speed command .omega.1 *, the second d-axis current I _dc1 in ω2 *, I _dc2 and second q axis current I _qc1, I _{Using qc2} and the resistance value or resistance identification value R obtained in advance, the identification value Ke ^ of the induced voltage coefficient is obtained.

  Note that (Equation 5) and (Equation 6) shown above will be described in detail later.

The I _d * calculation unit 13 determines the d-axis current command I _d * according to the operation mode and the operation mode.
(1) In “normal operation mode”, “DC positioning operation” or “synchronous operation” In order to attract the magnetic pole position of the motor 1 to the control axis, the I _d * operation unit 13 outputs the d-axis current command I _d *. Set to a positive value.
(2) “Normal operation mode” and “Normal operation (sensorless control operation)”
The I _d * calculation unit 13 changes the d-axis current command I _d * from a positive predetermined value to 0.
(3) In case of “trial operation mode”
The I _d * calculation unit 13 sets the d-axis current command I _d * to 0.

The Iq * calculation unit 14 determines a q-axis current command I _q * corresponding to the operation mode using the first q-axis current I _qc-DC .
(1) In “Normal operation mode”, “DC positioning operation” or “Synchronous operation”
The Iq * calculation unit 14 sets the q-axis current command I _q * to 0. That is, it is set to the command value shown in the following (Equation 7).

(2) In "Normal operation mode", "Normal operation (sensorless control operation)" or "Test operation mode"
The Iq * calculation unit 14 uses the filter time constant T _d for creating the q-axis current command and the second q-axis current I _qc-DC stored in advance by the following ( _Equation 8): Determine the q-axis current command I _q *.

The output voltage command calculation unit 15 obtains the output voltage commands V _u *, V _v *, V _w * as described above.

First, the dq-axis voltage command calculation unit 15a of the output voltage command calculation unit 15 uses the resistance set value R * identified by the R identification calculation unit 12a and the Ke identification calculation unit 12b according to (Equation 9) shown below. The set value Ke * of the identified induced voltage coefficient, the d-axis current command I _d * determined by the Id * calculation unit 13, the q-axis current command I _q * determined by the Iq * calculation unit 14, and the speed Using the speed command ωr * from the command generator 6 and the d-axis inductance setting value L _d * and the q-axis inductance setting value L _q * that are held in advance, Obtain the voltage commands V _d * and V _q *.

The axis error calculation unit 15b of the output voltage command calculation unit 15 calculates the resistance set value R * identified by the R identification calculation unit 12a and the induction identified by the Ke identification calculation unit 12b by the following (Equation 10). The voltage coefficient set value Ke *, the d-axis current command I _d * determined by the Id * calculation unit 13, the q-axis current command I _q * determined by the Iq * calculation unit 14, and Idc-DC / Iqc The second q-axis current I _qc-DC estimated by the _-DC estimation unit 10, the control axis speed ω1 estimated by the speed estimation unit 15d described later, and the d-axis inductance previously held by itself. Using the value L _d * and the set value L _q * of the q-axis inductance and the voltage commands V _d * and V _q * determined by the voltage command calculation unit 15a, the actual d axis and the control axis (set d axis) The magnetic pole phase error Δθc, which is the phase difference from

The speed correction amount calculation unit 15c uses the magnetic pole phase error Δθc obtained by the axis error calculation unit 15b and the PLL gain K _PLL held in advance by the following (Equation 11), A speed correction amount Δω, which is a speed difference between the d-axis speed and the control axis, is obtained.

  The speed estimation unit (addition unit) 15d adds the speed correction amount (−Δω) to the speed command ωr * from the speed command generation unit 6 as shown in the following (Equation 12) to estimate the control axis. Find the speed ω1.

The phase estimation unit (integration unit) 15e obtains the estimated phase θ _dc of the control axis according to the following (Equation 13) using the estimated speed ω1 of the d axis.

First, the coordinate conversion unit 15f uses the estimated phase θ _dc of the control axis obtained by the phase estimation unit 15e to obtain the voltage commands V _d * and V _q * obtained by the dq axis voltage command calculation unit 15a as motors. 1 is converted into voltage commands V _α * and V _β * based on the α and β axes that do not rotate or move even when driven. Subsequently, the voltage commands V _α *, V _β * are coordinate-transformed into voltage commands V _u *, V _v *, V _w * for each phase according to the following (Equation 14).

The PWM signal generation unit 16 generates PWM signals (Pu, Pv, Pw) based on the output voltage commands V _u *, V _v *, V _w * from the output voltage command calculation unit 15 and outputs the PWM signals. Send to inverter 2.

  The inverter 2 converts the DC power from the DC power supply circuit 3 into three-phase AC power in accordance with the PWM signal (Pu, Pv, Pw) from the control unit 15 described above, and supplies it to the permanent magnet synchronous motor 1.

  Next, the identification principle of the resistance value R of the motor 1 and the identification principle of the induced voltage coefficient Ke in this embodiment will be described.

  First, the identification principle of the resistance value R will be described.

  Regarding the response to the load torque of the motor 1, when the resistance setting value R * of the motor 1 does not include an error and when the error is included (when the resistance setting value R * is half of the actual resistance value R) As shown in FIG. In FIG. 7, load torque is applied to the motor 1 driven according to the speed command ωr * at time t20. As a result, the rotational speed ω of the motor generates vibration (region A in FIG. 7). At this time, if the resistance set value R * does not include an error, the vibration of the rotational speed ω is reduced with time and time, and the motor 1 is driven again according to the speed command ωr * (region B in FIG. 7). However, when a resistance error is included, the vibration at the rotational speed ω is amplified, and the motor 1 steps out (region C in FIG. 7). Thus, it is known that when the actual resistance value R is different from the set value R *, the control performance is deteriorated. Therefore, in order to drive the motor with high accuracy, it is necessary to identify the resistance value R.

  The resistance identification proposed in the present embodiment is performed when the operation mode generation unit 5 outputs the “normal operation mode” and the operation mode generation unit 8 outputs “DC positioning operation”.

Here, changes in the d-axis current I _d and the d-axis current command I _d * in the “DC positioning operation” will be described with reference to FIG. In the figure, the d-axis current command I _d * is zero in the time interval T0, increases in the time interval T1, and converges to a constant value in the time intervals T2 to T5. At this time, the d-axis current I _d begins to flow through the motor 1 as the d-axis current command I _d * increases in the time interval T1. Then, after time t1 when the d-axis current I _d flows, the magnetic pole position of the motor 1 is attracted to the control shaft, and DC positioning is performed. Note that the method of increasing the d-axis current command I _d * in the time interval T1 does not necessarily have to be proportional to time as shown in FIG. starts to flow d-axis current Id by an increase in d-axis current command Id *, as long attracted the magnetic pole position of the motor 1 to the control shaft, since the DC positioning is performed, the d-axis current command I _d *, for example, quadratic It may be increased.

Now, in the time section T1 shown in the figure, the d-axis current I _d increases so as to follow the d-axis current command I _d *. However, when the resistance setting value R * is not equal to the actual resistance value R, the d-axis current I _d converges to a value different from the d-axis current command I _d * (time intervals T2, T3). In the time intervals T2 and T3 in the figure, the d-axis current I _d is smaller than the d-axis current command I _d *, but the resistance set value R * and the true resistance value R are larger or smaller. Depending on the relationship, the reverse is also possible. However, in any case, this embodiment is applicable. Hereinafter, a method of calculating the resistance identification value in the time interval T3 in which the d-axis current I _d is in a steady state and converging the d-axis current I _d to the d-axis current command I _d * will be described.

When the operation mode is “DC positioning operation”, the DC power P _DC estimated by the PDC estimation unit 9 by the switching unit 10c of the Idc-DC / Iqc-DC estimation unit 10 is sent to the Idc-DC calculation unit 10b. Here, as described above, the d-axis current I _dc-DC is estimated by (Equation 3). This (Equation 3) is derived from the following idea.

  In a permanent magnet synchronous motor, it is known that (Equation 15) is satisfied regarding DC power.

Here, V _d : d-axis voltage, V _q : q-axis voltage In the “DC positioning operation”, if the torque load on the motor 1 is zero as described above, the equation shown in (Expression 16) is It holds.

  Furthermore, since the magnetic pole phase difference becomes zero by direct current positioning, (Equation 17) also holds.

  By substituting and organizing the above (Equation 16) and (Equation 17) into (Equation 15), the aforementioned (Equation 3) is obtained.

The Idc-DC computing unit 10b estimates the second d-axis current I _dc-DC using this (Equation 3) as described above. As described above, the R identification calculation unit 12a calculates the identification value R ^ of R by substituting the second d-axis current I _dc-DC etc. into (Equation 5). This (Equation 5) is derived from the following idea.

  In the model of the permanent magnet synchronous motor in the steady state, the following (Equation 18) holds.

Here, L _d : d-axis inductance, L _q : q-axis inductance Then, (Equation 16) is substituted into (Equation 18), and (Equation 7) is substituted into (Equation 9). Focusing on the d-axis voltage V _d and the d-axis voltage command V _d *, the following (Equation 19) is obtained.

  Substituting this (Equation 19) into the aforementioned (Equation 17), the following (Equation 20) is obtained.

  In this (Equation 20), when the second d-axis current Idc-DC shown in (Equation 3) is used instead of the d-axis current Id, (Equation 5) is derived.

Using this (Equation 5), the R identification calculation unit 12a calculates the resistance identification value R ^ in the time interval T3 in FIG. 8, and updates the resistance setting value R * at time t4. Then, in the time interval T4, the d-axis current I _d follows the d-axis current command I _d *, and both become equal after time t5 (time interval T5).

That is, in the present embodiment, the d-axis current I _dc-DC is estimated by (Equation 3) using a specific state during the “DC positioning operation”. Then, using this d-axis current I _dc-DC , the resistance value R of the motor 1 is identified by (Equation 5) using a specific state during the “DC positioning operation”.

  Here, the resistance identification value R ^ is calculated at different times within the time interval T3, and the resistance identification value R * is updated using the average value of the resistance identification values R ^, thereby improving the resistance identification accuracy. It is also possible. Alternatively, a method may be employed in which the resistance identification value R ^ is continuously calculated in the time interval T3 and an average value is obtained from the integral value, or a method used in combination with a filter.

  In the above, the case where the resistance identification is performed in the time interval T3 where the d-axis current Id is steady has been described. However, when the reduction of the driving time is more important than the accuracy of the resistance identification, the time interval T3 Alternatively, resistance identification can be performed in the time interval T1 or T2.

  It goes without saying that this resistance identification does not necessarily have to be executed every time in the DC positioning, and may be omitted as appropriate by storing the identification value.

In this embodiment, the Idc-ar / Iqc-ar estimation unit 11 also estimates the d-axis current. However, the estimation method in the Idc-ar / Iqc-ar estimation unit 11 is based on the modulation rate of the motor 1. Since the estimated value is affected, when executing resistance identification, the d-axis current I _dc-DC estimated by the Idc-DC calculation unit 10b, which is not affected by the modulation rate of the motor 1, can be rephrased. And the d-axis current estimated during the “DC positioning operation”.

  Next, the identification principle of the induced voltage coefficient Ke will be described.

  As with the resistance value R, the induced voltage coefficient Ke is known to deteriorate in control performance when the set value Ke * is different. Therefore, in order to drive the permanent magnet synchronous motor with high accuracy, it is necessary to identify the induced voltage coefficient Ke.

The identification of the induced voltage coefficient Ke proposed in the present embodiment is executed in the “trial operation mode”.
In this “trial operation mode”, the DC power P _DC estimated by the PDC estimation unit 9 is sent to the Iqc-DC calculation unit 10a by the switching unit 10c of the Idc-DC / Iqc-DC estimation unit 10, where As described above, the q-axis current I _qc-DC is estimated by ( _Equation 4). The voltage command generator 7 performs vector control based on the q-axis current I _qc-DC .

  In the “trial operation mode”, as described above with reference to FIG. 3, the speed command ωr * 1 is given in the time section T10, and the speed command ωr * 2 is given in the time sections T12 to T14. At this time, by the vector control, the rotational speed ω of the motor 1 becomes equal to the speed command ωr * 1 in the time interval T10, increases with the speed command in the time interval T11, and converges to the speed command ωr * 2 in the time interval T12. In the time interval T13, it is equal to the speed command ω * 2.

  In this “trial operation mode”, the induced voltage coefficient Ke is identified by the following method.

The Ke identification calculation unit 12b stores the DC power P _DC , the second d-axis current Idc-ar, and the second q-axis current Iqc-ar in the time sections T10 and T13 that are in a steady state. As the information to be stored, when importance is placed on the accuracy of identification, an average value obtained by dividing the integration of the current value in each of the time intervals T10 and T13 by time is preferable, but if importance is attached to the simplicity of the identification method, at a certain time. The instantaneous value of

  As described above, the Ke identification calculation unit 12b identifies the induced voltage coefficient Ke using the stored information and (Equation 6). This (Equation 6) is derived from the following idea.

  In the steady state in the time section T10 in the “trial operation mode”, the following (Expression 21) is established.

  Similarly, in the steady state in the time interval T13, the following (Equation 22) holds.

  Here, the following (Equation 23) is obtained by substituting the above (Equation 18) into (Equation 15).

  Further, by substituting (Equation 21) and (Equation 22) into (Equation 23), (Equation 24) is obtained.

  By arranging (Equation 24), the following (Equation 25) is obtained.

  By extracting the first row of (Equation 25), the above (Equation 6) is obtained.

  In the present invention, at least two types of speed commands ωr * (ωr * 1, ωr * 2,...) Are given, and a steady state corresponding to each speed command (ωr * 1, ωr * 2,...) Is obtained. If it reaches, it is possible to identify the induced voltage coefficient Ke, and there is no restriction on acceleration / deceleration of the speed command ωr *. When three or more types of speed commands ωr * are given, it is possible to improve the accuracy of identification by repeatedly using the identification calculation according to (Equation 6). In addition, as with resistance identification, identification can be omitted by storing identification values.

As described above, in the present embodiment, the d-axis current I _dc-DC of the inverter is estimated based on the average direct current I _DC-LF using the filter 9a, so that the modulation factor of the motor 1 is estimated. The value is not affected. In addition, in the present embodiment, the resistance value R of the motor 1 is identified using this d-axis current I _dc-DC using a specific state during the “DC positioning operation”. The value R can be identified accurately.

  Further, in the present embodiment, the induced voltage coefficient Ke is identified using the power supplied to the motor 1 having a correlation with the load torque of the motor 1, so that it is accurate regardless of the magnitude of the load torque to the motor 1. The induced voltage coefficient Ke can be identified.

  Thus, in this embodiment, since the resistance value R and the induced voltage coefficient Ke of the motor 1 are accurately identified, the output voltage command determined using these values is also accurate, and the motor 1 Drive control can be performed with high accuracy.

"Second Embodiment"
A second embodiment of the drive control device for a permanent magnet synchronous motor according to the present invention will be described with reference to FIGS. 9 and 10.

  As shown in FIG. 9, the drive control apparatus of this embodiment is different from the first embodiment in a PDC estimation unit 9 ′, and other configurations are the same as those in the first embodiment.

The PDC estimation unit 9 ′ of the present embodiment is based on a filter 9′a that averages the direct current I _DC supplied to the inverter 2 and an average direct current I _DC-LF that is an output from the filter 9′a. and PDC operation unit 9b for determining the DC power P _DC Te, depending on the selected operating mode in the operating configuration generator 8, comprises a constant change unit 9c for changing the constant T _dF filter time 9'a, the Yes. That is, the PDC estimation unit 9 ′ of this embodiment is obtained by adding a constant changing unit 9c to the PDC estimation unit 9 of the present embodiment of the first embodiment.

This constant changing unit 9c increases the filter time constant T _dF when the operation mode selected by the operation mode generation unit 8 is “DC positioning operation” and the motor speed is in the low speed range, and “normal operation (sensorless Control) ”, when the motor speed is in the high speed range, the filter time constant T _dF is decreased. With this processing, in this embodiment, the accuracy of estimation of the resistance value of the motor 1 can be improved because the estimation accuracy of the d-axis current I _d by (Equation 3) during DC positioning operation can be improved according to the principle shown below. In addition, it is possible to prevent deterioration of control performance during normal operation.

First, it will be described that the estimation accuracy of the d-axis current I _d according to ( _Equation 3) can be improved by increasing the filter time constant T _dF during DC positioning operation.

As shown in (Equation 2) and (Equation 3), in order to accurately estimate the d-axis current I _d , it is necessary to accurately estimate the DC power P _DC , which includes the average DC current I _DC-LF . The average value I _DC-LF0 needs to be detected correctly.

FIG. 10 shows the behavior of the average DC current I _DC-LF . I _DC-LOW (dotted line) and I _DC-HIGH (solid line) indicate the average DC when the filter time constant T _dF is large and small, respectively. Current is shown. As shown in the figure, the average direct current I _DC-LOW has less vibration than the average direct current I _{DC- HIGH} . This is because the latter, the filter 9'a, because the direct current I _DC is removed larger vibration component had originally. Further, the average values of the average direct currents I _DC-LOW and I _DC-HIGH do not depend on the filter time constant Td-F, and _therefore both are represented by I _DC-LF0 . In _order to detect I _DC-LF0 , the average DC current I _DC-LOW or I _DC-HIGH may be sampled at a predetermined time t20 determined by switching of the inverter. However, in reality, the sampling time and the predetermined time t20 do not necessarily coincide with each _other, and a difference occurs between the detected value by sampling and the average value _IDC-LF0 . At this time, it is clear that the difference becomes larger as the waveform to be sampled is more oscillatory. Conversely, it can be seen that sampling the average DC current I _DC-LOW with less vibration compared to the average DC current I _DC-HIGH makes it easier to obtain the accurate detection value I _DC-LF0. . Therefore, if the filter time constant T _dF is increased, the average value I _DC-LF0 of the average DC current I _DC-LF can be detected more accurately. As a result, the estimation accuracy of the d-axis current I _d according to ( _Equation 3) is improves.

When the filter time constant T _dF increasing the delay of the average DC current I _DC-LF for direct current I _DC increases. However, the operation mode when the current estimation by (Equation 3) is performed is DC positioning, and the permanent magnet synchronous motor 1 is in a steady state. Therefore, there is no demerit due to the delay of the average direct current I _DC-LF caused by the increase of the filter time constant T _dF .

  Next, it will be described that the control performance can be prevented from deteriorating during normal operation by reducing the filter time constant during normal operation (sensorless control).

(Equation 1) (Equation 2) As shown in equation (4), if the filter time constant T _dF is large, the average DC current I _DC-LF delay for direct current I _DC increases, as a result, the second The q-axis current I _qc-DC also has a large delay from the actual q-axis current I _q . Due to this, in a high speed range where normal operation is performed, the control performance is deteriorated particularly in a transient state in which the speed command or the load torque varies. Therefore, in sensorless control, the filter time constant T _dF can be reduced, and the delay of the second q-axis current I _qc-DC with respect to the q-axis current I _q can be reduced to prevent deterioration in control performance. It becomes effective.

In this embodiment, the constant changing unit 9c changes the magnitude of the filter time constant T _dF according to the operation mode selected by the operation mode generating unit 8, but the speed command from the speed command generating unit 6 is changed. The magnitude of the filter time constant T _dF may be changed according to the above. In this case, the constant changing unit 9c increases the filter time constant _TdF when the motor speed is in the low speed range as in the DC positioning operation, and the motor speed is in the high speed range as in the normal operation (sensorless control). In this case, the filter time constant T _dF is decreased.

It is a block diagram of the control apparatus of the permanent magnet synchronous motor in 1st embodiment which concerns on this invention. It is a block diagram which shows the detailed structure of the output voltage command calculating part 15 in FIG. It is a block diagram of the drive control apparatus of the permanent magnet synchronous motor in 1st embodiment which concerns on this invention. 1 is a perspective view of a permanent magnet synchronous motor and a drive control device thereof in a first embodiment according to the present invention. It is explanatory drawing which shows the mutual relationship of the various axes used for the various calculations in 1st embodiment which concerns on this invention. In 1st embodiment which concerns on this invention, it is a graph which shows the speed command pattern given in trial run mode, and the actual speed at that time. It is a graph which shows the behavior of rotational speed (omega) at the time of applying load torque to a permanent magnet synchronous motor. In 1st embodiment which concerns on this invention, it is a graph which shows the d-axis current command Id * pattern given by direct-current positioning operation, and the actual d-axis current value at that time. It is a block diagram of the control apparatus of the permanent magnet synchronous motor in 2nd embodiment which concerns on this invention. It is a graph which shows an example of the behavior of average direct current.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Permanent magnet synchronous motor, 2 ... Inverter, 3 ... DC power supply, 4 ... DC detector, 5 ... Operation mode generation part, 6 ... Speed command generation part, 7 ... Voltage command generation part, 8 ... Operation form generation part, 9, 9 '... PDC estimation unit, 9a, 9'a ... filter, 9b ... PDC calculation unit, 9c ... constant change unit, 10 ... Idc-DC / Iqc-DC estimation unit, 10a ... Iqc-DC calculation unit, 10b ... Idc-DC calculation unit, 11 ... Idc-ar / Iqc-ar estimation unit, 12 ... Identification calculation unit, 12a ... R identification calculation unit, 12b ... Ke identification calculation unit, 13 ... Id * calculation unit, 14 ... Iq * Calculation unit, 15 ... Output voltage command calculation unit, 17 ... Control unit, 100 ... Drive control device, 102 ... Fan, 103 ... Radiation fin, 111 ... AC power supply, 112 ... Input device

Claims (7)

An output voltage command for obtaining a voltage applied to the permanent magnet synchronous motor from an inverter using at least an induced voltage coefficient among motor constants representing characteristics of the permanent magnet synchronous motor, and transmitting a command value of the voltage to the inverter In a control device for a permanent magnet synchronous motor comprising means,
Current detection means for detecting a current value flowing through the permanent magnet synchronous motor;
Using a current value detected by the current detection means, a power estimation means for estimating a power value supplied to the permanent magnet synchronous motor;
Current estimation means for estimating the d-axis current value and the q-axis current value of the permanent magnet synchronous motor using the current value detected by the current detection means;
A plurality of power values estimated by the power estimation means in response to a plurality of speed commands at which the output voltage command means exhibits different speeds; a d-axis current value and a q-axis current value estimated by the current estimation means; Substituting into a predetermined formula, coefficient identifying means for identifying the induced voltage coefficient of the permanent magnet synchronous motor,
With
The output voltage command means uses the induced voltage coefficient identified by the coefficient identification means when obtaining the voltage applied to the permanent magnet synchronous motor from the inverter ,
The power estimation means includes
A low-pass filter that averages the current value detected by the current detection means;
A multiplier for determining the power value by multiplying a value of a DC voltage applied to the inverter by an average current value output from the low-pass filter;
A control device for a permanent magnet synchronous motor. In the control device of the permanent magnet synchronous motor according to claim 1 ,
When receiving at least two speed commands ω _r * 1 and ω _r * 2 as a plurality of speed commands indicating different speeds,
The estimated power value by the power estimating means and P _DC1, P _DC2,
The d-axis current values estimated by the current estimation means are I _dc1 and I _dc ,
The q-axis current values estimated by the current estimation means are I _qc1 and I _qc2 ,
When the resistance value of the permanent magnet synchronous motor or the resistance identification value R, which is determined in advance,
The predetermined formula is the following (Equation 1).

A control device for a permanent magnet synchronous motor. In the control device of the permanent magnet synchronous motor according to claim 1 or 2 ,
The d-axis current estimated by the current estimation means as the first current estimation means or the d-axis current estimated by the second current estimation means provided separately is substituted into a predetermined formula, and the permanent A resistance identifying means for identifying the resistance value of the magnet synchronous motor;
The output voltage command means further uses the resistance value identified by the resistance identification means to obtain a voltage to be applied to the permanent magnet synchronous motor from the inverter.
A control device for a permanent magnet synchronous motor. In the control device of the permanent magnet synchronous motor according to claim 3 ,
As the d-axis current I _dc estimated by the first current estimation means or the second current estimation means,
The d-axis current command value is I _d *,
Assuming that the resistance value of the permanent magnet synchronous motor determined in advance is R *,
The predetermined formula used when identifying the resistance value is the following (Equation 2).

A control device for a permanent magnet synchronous motor. In the control apparatus for the permanent magnet synchronous motor according to any one of claims 3 and 4 ,
Comprising the second current estimating means;
The second current estimating means estimates the d-axis current value by using the power value estimated by the power estimating means when the output voltage command means receives a speed command of a speed for DC positioning,
The resistance identification unit identifies the resistance value using the d-axis current value estimated by the second current estimation unit.
A control device for a permanent magnet synchronous motor. In the control device of the permanent magnet synchronous motor according to claim 1 or 2 ,
Mode generating means for outputting an instruction of a test operation mode or a normal operation mode according to an instruction from outside;
Upon receiving an instruction from the mode generating means indicating the trial operation mode, the output voltage command output means outputs the plurality of speed commands indicating different speeds at different times to identify the induced voltage coefficient. When receiving an instruction from the mode generating means that the operation mode is normal, a speed command generating means for outputting a speed command indicating a speed required in the normal operation mode to the output voltage command means;
A control device for a permanent magnet synchronous motor, comprising: In the control device of the permanent magnet synchronous motor according to claim 5 ,
Mode generating means for outputting an instruction of a test operation mode or a normal operation mode according to an instruction from outside;
Upon receiving an instruction from the mode generating means indicating the trial operation mode, the output voltage command output means outputs the plurality of speed commands indicating different speeds at different times to identify the induced voltage coefficient. When receiving an instruction from the mode generating means that the operation mode is normal, a speed command generating means for outputting a speed command indicating a speed required in the normal operation mode to the output voltage command means;
With
The speed command generation means outputs a speed command for the DC positioning speed as one of speeds required in the normal operation mode.
A control device for a permanent magnet synchronous motor.

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