JP2006217762A - Ac motor driving device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To highly efficiently operate a synchronous motor with a magnetic field including a permanent magnet synchronous motor. <P>SOLUTION: An active power target value Pn in the case that the motor is operated with a minimum loss or in a state equivalent to it is prepared as a table 21 that receives inputs of the amplitude V and the frequency f of a voltage impressed to the motor. It is made possible to achieve highly efficient operation that minimizes the loss generated in the motor, by calculating active power P by multiplying the low-frequency component of an inverter input DC current Idc by an inverter DC voltage Edc, by integrating the deviation of Pn and P with an integrator 23, and by subtracting its output from a voltage command value obtained via an f/V conversion portion 1. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an AC motor drive device that operates a motor with high efficiency by appropriately adjusting the amplitude of a voltage applied to the motor in V / f (voltage / frequency) control of an AC motor, particularly a synchronous motor.

  This type of control method includes controlling the voltage and current of the synchronous motor based on position information obtained from a position detector attached to the rotating shaft of the motor, and estimating the rotor position from the voltage and current of the motor. There are those that do not require a position detector (sensorless vector control), and those that control the voltage and frequency applied to the motor approximately in proportion (constant V / f control). V / f control is disclosed in Patent Document 1, for example, and has a feature that a position detector is unnecessary and control is simple.

FIG. 5 is a block diagram showing an example of V / f constant control described in Patent Document 1. In FIG.
In the figure, 11 is a three-phase inverter, 12 is a permanent magnet type synchronous motor with a field, 13 is a frequency commander, 14 is a frequency / voltage (f / V) converter, 15 is a pulse width modulator, Reference numeral 17 is an AC current detector, 18 is a vector calculator, 19 is a high-pass filter that passes high frequency components, 20 is a proportional calculator, 21 is an adder / subtractor, and 22 is an integrator.

The frequency command device 13 is set with the synchronous speed (frequency command f *) of the synchronous motor 12, and the f / v converter 14 outputs a voltage command v * corresponding to the frequency command f *. The integrator 22 integrates the frequency command f * and calculates the phase θ of the voltage applied to the stator winding of the synchronous motor 12. The pulse width modulator 15 generates a drive pulse by performing pulse width modulation (PWM) based on the voltage command v * and the phase θ, and controls the switching element of the three-phase inverter 11 on and off.
The three-phase inverter 11 outputs a three-phase AC voltage whose pulse width is controlled, and this voltage is applied to the windings of the synchronous motor 12 to generate a rotating magnetic field.

Two phases out of the three-phase current supplied to the synchronous motor 12, for example, iu and iw are detected by the AC current detectors 16 and 17, and converted into an orthogonal coordinate system by the vector calculator 18, thereby being effective. The current iδ is obtained from the relationship of the following equation (1).
iδ = [(− 1 / √3) sin θ + cos θ] iu + [(− 2 / √3) sin θ] iw
... (1)

By the way, the effective current iδ becomes a direct current amount in the steady state, but if the synchronization speed deviates from the steady state, a transient change occurs in iδ and the system becomes unstable. This has been confirmed by analysis and experiment as in Non-Patent Document 1, for example.
Therefore, the variation Δiδ of iδ is obtained by removing the DC component from iδ by the high-pass filter 19, and is obtained as a frequency correction amount Δf * by multiplying Δiδ by a predetermined gain by the proportional computing unit 20, and the previous frequency command f * Negative feedback is made. As a result, the fluctuation of iδ can be reduced, the system state can be brought close to the steady state, and the control system can be stabilized.

In the above example, it is necessary to detect the phase current of the electric motor. On the other hand, by detecting the effective current of the motor based on only the low frequency component of the DC input current of the inverter that drives the motor without detecting the phase current, and using this as the above-described effective current iδ, For example, Non-Patent Document 2 discloses a method for simply realizing stabilization control of a synchronous motor. In this method, instead of obtaining the active current from the phase current, the inverter input power is almost equal to the motor active power (although the latter is reduced by the inverter loss, this is small, so it is ignored or corrected) The effective current of the motor is obtained from the detected value of the input DC current of the inverter using the fact that each phase effective current of the motor is expressed by the following equation (2).
Effective current (effective value) of motor = active power / (number of phases x effective value of each phase voltage) (2)

A specific example for realizing the above is shown in FIG.
In FIG. 6, the input DC current of the inverter is detected by the current detector 24, and the effective current i δ is obtained from the low frequency component and the output voltage (command value v ^* ) of the inverter by the active current calculator 26. The other parts are the same as in FIG. As described above, FIG. 6 has a feature that it is inexpensive and simple because a necessary effective current can be derived without detecting a phase current.

By the way, when a synchronous motor with a field is driven by applying a voltage, its frequency is determined by a desired motor rotation speed, while its amplitude has a certain degree of freedom. In general, the amplitude of the current flowing through the motor varies depending on the amplitude of the applied voltage, and the copper loss in the motor increases as the current amplitude increases. Therefore, in order to suppress the generated loss in the electric motor and realize the energy saving operation, it is necessary to appropriately adjust the amplitude of the electric motor voltage.
As the adjustment method, the reactive power of the motor is obtained from the applied voltage and current, and the applied voltage is automatically adjusted so that this becomes a desired value, thereby minimizing the motor current and realizing high power factor operation. It is disclosed in the previous Non-Patent Document 1.

  However, as shown in Non-Patent Document 2, when the control is performed based on the DC input current of the inverter, it is not necessary to detect the phase current, and therefore usually the phase current detector is not provided. There is a problem that it cannot be asked. There is also a method for obtaining the phase current from the DC input current of the inverter, which is disclosed in Patent Document 2, for example.

JP 2000-236694 (page 3-4, FIG. 1) Japanese Patent No. 2563226 IEEJ Transactions D, Vol.122, No.3, 2002, pp. 253-259 "Performance improvement of V / f control of permanent magnet synchronous motor" 2004 Proceedings of National Congress of the Institute of Electrical Engineers of Japan, pp. I-335 to 336 “PMSM stabilization V / f control method by detecting inverter DC current”

According to the method of Patent Document 2, reactive power can be calculated based on the derived phase current. However, in this method, it is necessary to detect the DC input current at high speed in synchronization with the PWM voltage waveform output from the inverter. That is, it can be said that it is impossible to derive the phase current in the configuration in which only the DC input current component is detected using the low-pass filter as shown in Non-Patent Document 2.
Accordingly, an object of the present invention is to adjust the amplitude of the applied voltage of the motor so as to minimize the loss generated in the motor when the motor control is performed using only the low frequency component of the DC input current of the inverter. .

In order to solve such a problem, in the invention of claim 1, in an AC motor driving device that drives a synchronous motor with a field by adjusting an applied voltage,
The active power consumed or generated by the motor is measured or estimated, and the active power is applied to the motor so that it matches the target target for active power when the motor operates with a minimum loss or conformity thereto. The voltage amplitude is adjusted.
In the first aspect of the present invention, the active power target value when the motor is operating in a state where the loss is minimum or in accordance with the table is a table, function or approximation with the amplitude and frequency of the voltage applied to the motor as inputs. As a function, the amplitude of the voltage can be adjusted so that the measured or estimated active power matches an active power target value determined based on the table, function, or approximate function (claim). Item 2).

In the invention of claim 1 or 2, when the frequency command value of the voltage applied to the electric motor is changed over time, the adjustment of the amplitude of the voltage applied to the electric motor can be stopped. Invention).
Moreover, in any one of Claims 1-3, it has the 1st voltage command value which defined the amplitude of the voltage applied to the said motor as a function of the frequency command value of the voltage, The said active power target Subtracting, from the first voltage command value, a power deviation processing value obtained by performing at least one of time integration, amplification, or low-pass processing on a deviation between the value and the measured or estimated active power Thus, the amplitude of the voltage can be adjusted (invention of claim 4).

In the fourth aspect of the invention, when the frequency command value of the voltage applied to the electric motor is temporally changed, the subtraction of the power deviation processing value from the first voltage command can be stopped. (Invention of Claim 5). The AC motor drive device according to claim 4, wherein:
In any one of the first to fifth aspects of the invention, the adjustment of the amplitude of the voltage applied to the electric motor can be performed within a predetermined upper and lower limit value corresponding to the frequency of the voltage. 6 invention).

  According to the present invention, since the applied voltage of the motor is adjusted so as to minimize the generation loss of the motor, there is an advantage that the motor can be driven with high efficiency.

Before describing embodiments of the invention, the principle will be described.
Generally, the active power P at the terminal of the motor in the steady state is expressed by the following equation (3).
Effective power P = machine power Pm + electromagnetic loss PL (3)
The active power P is positive when power is input to the motor from a power source (such as an inverter) that drives the motor, and is negative when the power is reversed. Further, the mechanical power Pm is positive when the electric motor is operating as a motor, and is negative when the electric motor is operating as a generator. The electromagnetic loss PL is always positive.

  In the above equation (3), the mechanical power Pm is the sum of the shaft output of the generator and the mechanical loss. Here, the shaft output of the generator is the product of the rotational angular velocity and the shaft torque, and the shaft torque is determined by the load of the motor. On the other hand, the mechanical loss is substantially determined only by the rotational angular velocity. Therefore, if the rotational speed is constant, only the load changes the machine power Pm, and does not change the power by operating the electric power of the motor.

  In order to operate the motor with high efficiency, the electromagnetic loss PL (mainly the sum of the copper loss and the core loss) represented by the above equation (3) should be as small as possible. Here, as described above, the mechanical power Pm cannot be electrically changed when the rotational speed is constant, and therefore should be considered as a precondition (also referred to as a load condition). From the above, minimization of the electromagnetic loss PL at a certain rotational speed and load condition is nothing but minimization of the active power P.

Now, in general, the characteristic equation of the multiphase synchronous motor is expressed as the following equation (4) expressed by the following equation (1).

Each amount shown in Equation (4) as Equation 1 is as follows.
vx: x-axis component of armature voltage, ix: x-axis component of armature current, Ra: phase resistance, Lx: x-axis inductance, ω: electrical angular velocity, Ψa: magnetic flux linkage by field, p: differential operation Child, x; d or q, d axis is the magnetic pole axis of the rotor, q axis is the axis advanced by 90 ° from the d axis in the positive rotation direction (ω> 0) Here, a steady state is assumed, Is zero for the term having the differential operator p shown in the equation (4) of Equation 1 and constant for the term having ω.

Further, the terminal voltage amplitude V of the electric motor has a relationship of vd and vq with the following equation (5).
V = √2 × √ (vd ² + vq ² ) (5)
Furthermore, the motor current amplitude I is in the relationship of id and iq with the following equation (6).
I = √2 × √ (id ² + iq ² ) (6)

Here, consider a case where the electric motor is a non-salient pole machine, that is, Ld = Lq.
In this case, the torque generated by the electric motor is only the magnet torque, which is proportional to the q-axis current iq. Therefore, iq is also determined when the shaft torque is determined by the load as described above. As a result, since the variable on the right side of the equation (4) is only the d-axis current id in the steady state, it can be seen that id changes depending on the value of the terminal voltage V. In general, the smaller the current I is, the smaller the copper loss is. Therefore, when iq is determined according to the load condition, the current I is minimum, that is, the copper loss is minimum under the condition of id = 0. In summary, when the rotational speed and the shaft torque are given, the current amplitude changes depending on the terminal voltage, and the copper loss is minimized at the terminal voltage amplitude V where id = 0.

  If the motor has a copper loss several times larger than the core loss, it can be considered that the electromagnetic loss PL is substantially minimized at the terminal voltage amplitude V where id = 0. Further, it can be understood that there is a terminal voltage V that minimizes the electromagnetic loss PL for the following reason even when the copper loss and the core loss are approximately the same or the core loss is larger. That is, the core loss depends on the density of the magnetic flux density in the electric motor, the density of the magnetic flux density depends on the current amplitude and phase, and as can be understood from the above equations (4) to (6), the current amplitude Since the phase depends on the terminal voltage amplitude V, the core loss is a function of the terminal voltage amplitude V. This function is usually a downwardly convex function that is minimized at a certain voltage V. Therefore, similarly, the electromagnetic loss PL, which is the sum of the copper loss having a downward convex characteristic with respect to V, can also be said to have a terminal voltage V that minimizes PL by having the downward convex characteristic. .

  On the other hand, when the electric motor is a salient pole machine, that is, when Ld ≠ Lq, since not only the magnet torque but also the reluctance torque exists, the d-axis current also contributes to the generation of torque. However, when the rotational speed and the shaft torque are given, the values of the d-axis current and the q-axis current with respect to a certain terminal voltage V are unambiguous so that the torque required by the load is output and the equation (4) is satisfied. Is determined. The relationship between the current amplitude and the copper loss, and the relationship between the density of the magnetic flux density and the core loss are the same as in the case of the non-salient pole machine, and the current amplitude and the density of the magnetic flux density depend on the terminal voltage V. It can be understood that there is a terminal voltage V that minimizes the electromagnetic loss PL even in the case of the salient pole machine, as in the case of the non-salient pole machine.

The above is illustrated in FIG.
FIG. 1 is a graph showing the armature terminal voltage amplitude V on the horizontal axis and the power or power on the vertical axis, and shows general trends of P, Pm and PL shown in the above equation (3). The rotational speed and load torque are constant. Since the mechanical power Pm does not depend on V, it is a straight line parallel to the horizontal axis, and the electromagnetic loss PL has a downward convex characteristic. The active power P is the sum of Pm and PL. Since Pm is constant, the values Va of V at which P and PL are constant are equal. If the terminal voltage amplitude V is too low, equation (4) is not satisfied, and the motor steps out and cannot be operated.

As described above, minimization of electromagnetic loss is nothing but minimization of motor active power, and there is a terminal voltage amplitude V that minimizes electromagnetic loss. The principle of the present invention is that a method of measuring or estimating the effective power of the motor and adjusting the terminal voltage V so that the effective power is minimized is effective.
The active power of the motor can be obtained by using the method described in Patent Document 1, and the terminal voltage amplitude of the motor is nothing but the output voltage of a power source such as an inverter that drives the motor, and this is known. Can be treated as

By the way, when trying to execute the above method as it is, the active power is minimized even if the operating condition (speed, load torque) changes while observing the measured value or estimated value of the active power in the steady state. Since the terminal voltage V is continuously changed, there is a concern that the terminal voltage V is not stable. A method for solving this will be described with reference to FIG.
FIG. 2 is an example in which the terminal voltage is plotted on the horizontal axis, the active power is plotted on the vertical axis, and the characteristics of the terminal voltage at which the electromagnetic loss is minimized with respect to the load torque are plotted with the rotational speed as a parameter. In other words, the value of the active power P at the terminal voltage that minimizes the electromagnetic loss as shown in FIG. 1 is obtained for each load torque and rotation speed. The speed, terminal voltage, and load torque in FIG. 2 are shown as percentages relative to a certain reference value.

  In practice, the characteristics shown in FIG. 2 are stored and held in the control device for the motor drive inverter as a table, function or approximate function (collectively referred to as a function) having the terminal voltage amplitude and the rotation speed as variables. deep. When the electric motor is operated at a predetermined rotational speed, the frequency of the terminal voltage is determined by the rotational speed, but the amplitude has a degree of freedom. Therefore, the electric motor is rotated with the provisional terminal voltage amplitude. Then, since the active power is calculated from the terminal voltage amplitude and the rotational speed using the table or function stored as described above, this is used as the active power target value.

  That is, since the active power target value is the active power when the loss is minimum at a certain rotation speed and terminal voltage, the actual active power (active power measured value or estimated value) is used as the target value. What is necessary is just to adjust a terminal voltage so that it may correspond. When the measured value or estimated value of the active power matches the active power target value, operation is performed with the terminal voltage adjusted appropriately and the loss being minimal (including cases where there is a slight deviation due to various errors). Will be done. By doing so, it is not necessary to constantly vary the terminal voltage amplitude V, and thus the operation can be stabilized.

The adjustment of the voltage amplitude as described above is performed assuming a steady state, and there is a possibility that the operation becomes unstable when the rotation speed is changing, such as during acceleration / deceleration. Further, since acceleration torque is generally required during acceleration, it is desirable to obtain a required acceleration torque by applying a higher terminal voltage than that in a steady state.
For this reason, terminal voltage adjustment for high-efficiency operation is stopped when operating conditions are changing, such as during acceleration / deceleration, and is executed only when the speed is constant, thereby stabilizing the operation. It becomes possible to make it.

Specifically, the high-efficiency operation described above can be realized by, for example, the control system shown in FIG. In the normal V / f drive method, the terminal voltage amplitude V is uniquely determined according to the input of the speed command f. However, in FIG. 3, a voltage adjustment unit 2 is further provided based on the f / V conversion unit 1. ing.
In the voltage adjustment unit 2, the active power target value Pn is obtained from the speed command f and the terminal voltage command V by the storage unit 21 in which the characteristics shown in FIG. On the other hand, the multiplier 24 multiplies the DC voltage value Edc of the inverter and the low frequency component of the DC input current Idc (output of the Idc low pass filter (LPF)) to calculate the active power P. The adder / subtractor 22a obtains a deviation between Pn and P, which is input to the integrator 23, and its output is subtracted from the voltage command value by the adder / subtractor 22b.

That is, the provisional terminal voltage amplitude corresponding to the speed command value f is determined by the f / V conversion unit 1,
The adjustment of the terminal voltage for higher efficiency is performed by changing the output of the integrator 23 until the deviation of the actual active power from the active power target value becomes zero, and changing the terminal voltage amplitude. Note that the product of Edc and the low frequency component of Idc is the input power of the inverter, and in order to determine the effective power of the generator from this, the efficiency of the inverter must be considered. This can be achieved by calculating and correcting the inverter efficiency for each of Edc and Idc, and further for each inverter operating condition. Further, the efficiency of the inverter is generally as high as 90% or more, and may be ignored. It should be noted that the terminal voltage can be adjusted by using a P regulator, PI regulator, or a device provided with a first-order lag filter after the P regulator instead of the integrator. In short, any means may be used as long as the terminal voltage can be adjusted so that the deviation of the active power becomes small.

  In the control system shown in FIG. 3, the voltage V from the f / V converter 1 is set to the maximum value that should be given to the electric motor at the speed f, that is, the voltage amplitude at which the maximum torque is obtained, for high efficiency operation. It is preferable in terms of mounting that the terminal voltage adjustment is a method of subtracting an appropriate value from this maximum value. This is because, by adopting such a method, voltage adjustment is not performed during acceleration / deceleration, that is, by setting the terminal voltage at which maximum torque can be obtained immediately by stopping the subtraction of the integrator output from the f / V converter output. This is because it becomes possible.

  When the motor changes from the steady state to the acceleration / deceleration state, the command value of the inverter output voltage frequency is changed. Therefore, if the subtraction of the power deviation integral value from the output voltage amplitude is stopped before or simultaneously with the start of the motor, Good. Furthermore, if the subtraction is suddenly stopped, the voltage applied to the electric motor changes suddenly, which may cause disturbance and make the operation unstable. In order to avoid this, for example, the subtraction is preferably stopped through a process of reducing the power deviation integrated value with a certain rate of time change.

FIG. 4 shows an example of the speed-terminal voltage amplitude characteristic of the motor in a steady state.
The two characteristic curves indicated by the dotted line and the solid line respectively show the terminal voltage characteristics when the current is zero and when the current at which the maximum torque can be obtained flows, both of which can be derived from the equation (4) in the above equation (1). . It is sufficient that the terminal voltage adjustment described so far is performed between a value at which the maximum torque is obtained and the case where the current is zero. As an example, the terminal voltage adjustment range in the case of speed A is indicated by an arrow.

  Therefore, two characteristic curves as shown in FIG. 4 for the electric motor to be driven may be obtained in advance, and the values of both characteristic curves at each speed may be determined as upper and lower limit values for terminal voltage adjustment. In other words, for example, the terminal voltage adjustment value must be limited due to the effect of temperature changes in the resistance value of the motor in the active power of the motor, or due to approximation errors or other errors in the active power target value (eg, neglect of inverter efficiency). In this case, an excessive voltage or an excessive voltage is applied to the electric motor, causing an overcurrent or a step-out. If the limit values as described above are provided, there is no such danger, and a highly reliable system can be realized.

Principle explanatory diagram of the present invention Characteristic diagram showing the characteristics of terminal voltage with minimum electromagnetic loss against load torque The principal part block diagram which shows embodiment of this invention The characteristic figure which shows the speed-terminal voltage amplitude characteristic in the steady state of the motor Block diagram showing an example of V / f constant control disclosed in Patent Document 1 Block diagram showing the stabilization control method of the asynchronous motor disclosed in Non-Patent Document 2

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... f / V (frequency / voltage) converter, 2 ... Voltage adjustment part, 21 ... Memory | storage part, 22a, 22b ... Adder / subtractor, 23 ... Integrator, 24 ... Multiplier, 25 ... Low pass filter (LPF).

Claims (6)

In an AC motor drive device that drives a synchronous motor with a field by adjusting a voltage to be applied,
The active power consumed or generated by the motor is measured or estimated, and the active power is applied to the motor so that it matches the target target for active power when the motor operates with a minimum loss or conformity thereto. An AC motor driving device characterized by adjusting a voltage amplitude.   The active power target value when the motor is operating in a state with minimum loss or in accordance with this is stored as a table, function or approximate function with the amplitude and frequency of the voltage applied to the motor as inputs, and the measurement 2. The AC motor drive according to claim 1, wherein the amplitude of the voltage is adjusted so that the estimated active power matches an active power target value determined based on the table, the function, or the approximate function. apparatus.   3. The AC motor drive device according to claim 1, wherein when the frequency command value of the voltage applied to the electric motor is changed with time, the adjustment of the amplitude of the voltage applied to the electric motor is stopped. .   A first voltage command value defining an amplitude of a voltage applied to the motor as a function of a frequency command value of the voltage, and a deviation between the active power target value and the measured or estimated active power as time. The amplitude adjustment of the voltage is performed by subtracting a power deviation processing value obtained by at least one of integration, amplification or low-pass processing from the first voltage command value. The AC motor drive device according to any one of claims 1 to 3.   5. The AC according to claim 4, wherein the subtraction of the power deviation processing value from the first voltage command is stopped when the frequency command value of the voltage applied to the electric motor is temporally changed. Electric motor drive device. 6. The AC motor driving device according to claim 1, wherein the adjustment of the amplitude of the voltage applied to the electric motor is performed within a predetermined upper and lower limit value corresponding to the frequency of the voltage. .

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