JP2021158855A - Motor drive device - Google Patents

Abstract

To reflect an iron loss of a motor during supplying a driving current to the driving circuit of the motor.SOLUTION: A motor drive device (10) comprising a power supply device (30) supplying a driving current to a motor (20), and a control part (110) controlling the power supply device (30), further provides a measurement part (100) measuring an iron loss corresponded to the iron loss of the motor (20) which is supplying the driving current, in which the control part (110) controls the power supply device (30) on the basis of the iron loss measured by the measurement part (100).SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a motor drive and a sample piece.

Generally, a motor is driven by a motor drive device including a power feeding unit that supplies a driving current to the motor and a control unit that controls the power feeding unit. Patent Document 1 discloses a technique of estimating a loss of a motor supplying a drive current based on temperature data and controlling a cooling device of the motor based on the loss.

JP-A-2017-112649

By the way, there is a desire to reflect the iron loss of the motor supplying the drive current in the drive current of the motor.

An object of the present disclosure is to reflect the iron loss of the motor supplying the drive current in the drive current of the motor.

The first aspect of the present disclosure is a motor drive device including a power supply unit (30) that supplies a drive current to the motor (20) and a control unit (110) that controls the power supply unit (30). A measuring unit (100) for measuring the iron loss corresponding to the iron loss of the motor (20) supplying the driving current is further provided, and the control unit (110) is measured by the measuring unit (100). It is characterized in that the power feeding unit (30) is controlled based on the iron loss.

In the first aspect, since the power feeding unit (30) is controlled based on the iron loss corresponding to the iron loss of the motor (20) supplying the drive current, the drive current of the motor (20) being supplied The iron loss can be reflected in the drive current of the motor (20).

A second aspect of the present disclosure comprises, in the first aspect, a sample piece (41-44) containing a soft magnetic material and an exciting portion (30,120,130) for exciting the sample piece (41-44). The exciting portion (30,120,130) simulates the time change of the magnetic flux density and the magnetic field strength at a predetermined portion including the soft magnetic material in the magnetic circuit of the motor (20) supplying the driving current. The iron loss measured by the measuring unit (100) after exciting (41 to 44) is characterized by the iron loss generated in the sample piece (41 to 44) excited by the exciting unit (30,120,130). And.

In the second aspect, the iron loss generated in the sample pieces (41 to 44) is directly obtained, and the feeding unit (30) is controlled based on the iron loss. Therefore, the iron loss of the motor (20) that is supplying the drive current can be accurately reflected in the drive current of the motor (20).

In the third aspect of the present disclosure, in the second aspect, the control unit (110) derives the iron loss of the motor (20) based on the iron loss measured by the measurement unit (100). It is characterized by including a derivation unit (111).

In the third aspect, the iron loss generated in the sample pieces (41 to 44) is directly obtained, and the iron loss of the motor (20) is derived based on the iron loss. Therefore, the iron loss of the motor (20) can be accurately obtained.

In the fourth aspect of the present disclosure, in the third aspect, the lead-out unit (111) includes the iron loss of the sample piece (41 to 44), the weight of the sample piece (41 to 44), and the above. It is characterized in that the iron loss of the motor (20) is derived based on the weight of a predetermined portion including the soft magnetic material in the magnetic circuit of the motor (20).

In the fourth aspect, the iron loss of the motor (20) can be obtained more accurately.

A fifth aspect of the present disclosure is that in any one of the second to fourth aspects, the predetermined portion in the magnetic circuit of the motor (20) is a stator (21) of the motor (20). ) Includes a back yoke portion (22a) and a teeth portion (22b).

In the fifth aspect, the iron loss of the back yoke portion (22a) and the teeth portion (22b) of the stator (21) of the motor (20) is accurately reduced based on the iron loss generated in the sample piece (41, 42). You can ask.

A sixth aspect of the present disclosure further comprises windings (51-53) wound around the sample pieces (41-43) in any one of the second to fifth aspects, the excitation The part (30) is characterized in that the sample pieces (41 to 43) are excited by passing an electric current through the windings (51 to 53) of the sample pieces (41 to 43).

In the sixth aspect, the sample pieces (41 to 43) are directly excited by the current flowing through the windings (51 to 53) of the sample pieces (41 to 43).

In the seventh aspect of the present disclosure, in the sixth aspect, the windings (51 to 53) of the sample pieces (41 to 43) are parallel to the windings (23) of the motor (20). It is connected, and the exciting portion (30) is the feeding portion (30).

In the eighth aspect of the present disclosure, in the sixth aspect, the windings (51 to 53) of the sample pieces (41 to 43) are in series with the windings (23) of the motor (20). It is connected, and the exciting portion (30) is the feeding portion (30).

In the ninth aspect of the present disclosure, in the sixth aspect, the winding (51) of the sample piece (43) is a power supply device for passing a current through the winding (51) of the sample piece (43). It is connected to (120), the exciting unit (120) is the power supply device (120), and the power supply device (120) is different from the power supply unit (30).

In the ninth aspect, the power supply (30) causes a current to flow through the winding (51) of the sample piece (43).

A tenth aspect of the present disclosure is that in any one of the seventh to ninth aspects, the exciting portion (30) is at least the winding (51 to 53) of the sample piece (41 to 44). It is characterized in that a voltage corresponding to the phase voltage of the motor (20) is applied to a part of the motor (20).

In the tenth aspect, the teeth portion (22b) of the stator (21) of the motor can be simulated with the sample pieces (41, 42).

In the eleventh aspect of the present disclosure, in any one of the seventh to tenth aspects, the exciting portion (30) is at least the winding (51 to 53) of the sample piece (41 to 44). It is characterized in that a voltage corresponding to the line voltage of the motor (20) is applied to a part of the motor (20).

In the eleventh aspect, the back yoke portion (22a) of the stator (21) of the motor can be simulated with the sample pieces (41, 42).

In the twelfth aspect of the present disclosure, in any one of the sixth to eleventh aspects, the measuring unit (100) consumes the sample piece (41 to 44) in the winding (51 to 53). It is characterized in that the iron loss of the sample piece (41 to 44) is measured based on the power consumption and the copper loss in the winding (51 to 53) of the sample piece (41 to 44).

In the twelfth aspect, the iron loss of the sample piece (41 to 44) can be measured based on the power consumption and the copper loss in the winding (51 to 53) of the sample piece (41 to 44).

In the thirteenth aspect of the present disclosure, in any one of the second to twelfth aspects, the exciting portion (30,120,130) is magnetically saturated at the predetermined portion in the magnetic circuit of the motor (20). When the condition presumed to occur is satisfied, the ratio of the voltage or current for exciting the sample pieces (41 to 44) to the driving current is increased as compared with the case where the condition is not satisfied. do.

In the thirteenth aspect, even when it is assumed that magnetic saturation occurs at a predetermined portion in the magnetic circuit of the motor (20), the predetermined portion can be simulated with high accuracy by the sample pieces (41 to 44). Therefore, even in such a case, the iron loss of the motor (20) can be accurately reflected in the drive current.

In the 14th aspect of the present disclosure, in any one of the 2nd to 13th aspects, the exciting unit (30,120,130) inputs the driving current for performing the weakening magnetic flux control to the motor (20). When the time change is simulated with the sample pieces (41 to 44), the ratio of the voltage or current for exciting the sample pieces (41 to 44) to the drive current is compared with other cases. It is characterized by making the size smaller.

In the fourteenth aspect, even when it is assumed that the weakening magnetic flux control is performed by the motor (20), a predetermined part in the magnetic circuit of the motor (20) can be simulated with a sample piece (41 to 44) with high accuracy. can. Therefore, even in such a case, the iron loss of the motor (20) can be accurately reflected in the drive current.

A fifteenth aspect of the present disclosure is, in any one of the first to fourth aspects, the envelope of the drive current, the envelope of the line voltage of the motor (20), and the motor (20). It is characterized in that at least one of the input power, the torque of the motor (20), and the rotational speed of the motor (20) pulsates periodically.

In a fifteenth aspect, the wrapping wire of the drive current (90), the wrapping wire of the line voltage of the motor (20), the input power of the motor (20), the torque of the motor (20), and the rotational speed of the motor (20). Even if at least one of the above pulsates periodically, the iron loss of the motor (20) can be accurately reflected in the drive current.

In the sixteenth aspect of the present disclosure, in any one of the second to fifth aspects, the magnetic field generator (80) excites the sample piece (44) by generating a magnetic field. It is characterized by being.

In the sixteenth aspect, the sample piece (44) is excited.

In the 17th aspect of the present disclosure, in any one of the 2nd to 16th aspects, the measuring unit (100) changes the magnetic flux density and the magnetic field strength in the sample pieces (41 to 44) with time. Based on this, the iron loss of the sample pieces (41 to 44) is measured.

In the seventeenth aspect, the iron loss of the sample pieces (41 to 44) can be measured by measuring the time change of the magnetic flux density and the magnetic field strength of the sample pieces (41 to 44).

In the eighteenth aspect of the present disclosure, in any one of the third to seventeenth aspects, the derivation unit (111) further derives the copper loss of the motor (20) that is supplying the drive current. The control unit (110) is characterized in that the power supply unit (30) is controlled based on the iron loss and the copper loss of the motor (20) derived by the lead-out unit (111).

In the eighteenth aspect, since the power feeding unit (30) is controlled based on the copper loss corresponding to the copper loss of the motor (20) supplying the drive current, the drive current of the motor (20) being supplied Copper loss can be reflected in the drive current of the motor (20).

The nineteenth aspect of the present disclosure is directed to a ring-shaped sample piece (41 to 43) used in any one of the above two to fifteenth aspects of the motor drive device.

In the nineteenth aspect, the iron loss of the motor (20) that is supplying the drive current using the ring-shaped sample pieces (41 to 43) can be reflected in the drive current of the motor (20).

FIG. 1 is a configuration diagram of a motor drive device according to the first embodiment. FIG. 2 is an enlarged plan view of a part of the motor. FIG. 3 is a graph showing an example of the waveform of the drive current. FIG. 4 is a flowchart of the parameter control operation of the first embodiment. FIG. 5 is a flowchart of a method for obtaining the iron loss of the motor of the first embodiment. FIG. 6 is a configuration diagram of the motor drive device of the first modification of the first embodiment. FIG. 7 is a configuration diagram of the motor drive device of the second modification of the first embodiment. FIG. 8 is a configuration diagram of the motor drive device of the second embodiment. FIG. 9 is a configuration diagram of the motor drive device of the third embodiment. FIG. 10 is a configuration diagram of the motor drive device of the fourth embodiment. FIG. 11 is a flowchart of a method for obtaining the iron loss of the motor of the fourth embodiment. FIG. 12 is a configuration diagram of the motor drive device of the fifth embodiment.

<< Embodiment 1 >>
The first embodiment will be described. The motor drive device (10) of the first embodiment is used to execute a method of determining the iron loss of the motor (20) using the sample pieces (41, 42). Specifically, the motor drive device (10) of the first embodiment is used to obtain the iron loss of the motor (20) by simulating a predetermined part of the motor (20) with a sample piece (41, 42). Be done.

<Structure of iron loss measurement system>
As shown in FIG. 1, the motor drive device (10) includes a power supply device (30) as a power feeding unit and an exciting unit, first and second sample pieces (41, 42), and first and second waveform measurement. It includes an apparatus (61,62), a measuring unit (100), and a control unit (110). The motor drive (10) is connected to the motor (20).

As shown in FIG. 2, the motor (20) includes a stator (21) and a rotor (24). The stator (21) has a stator core (22) made of a soft magnetic material (eg, electrical steel sheet or dust core). The stator core (22) has a back yoke portion (22a) and a teeth portion (22b). In this example, the winding (23) is wound around the teeth portion (22b) by a centralized winding method. The winding (23) may be wound around the teeth portion (22b) by a distributed winding method. The rotor (24) includes a rotor core (25) made of a soft magnetic material (for example, an electromagnetic steel plate or a dust core) and a plurality of permanent magnets (26) provided on the rotor core (25). Has. The motor (20) is, for example, an embedded magnet type synchronous motor. The back yoke portion (22a) and the teeth portion (22b) correspond to predetermined portions including the soft magnetic material in the magnetic circuit of the motor (20), respectively.

Here, the magnetic circuit of the motor (20) includes a back yoke portion (22a), a teeth portion (22b), an air gap, a rotor (24), an air gap, a teeth portion (22b), and a back yoke portion (22a). ) Is a closed circuit in which magnetic flux circulates and flows in the order described.

The motor (20) is housed in a casing of a rotary compressor (not shown). The rotor (24) of the motor (20) is connected to a compression mechanism (not shown) via a drive shaft (not shown). In particular, in a rotary compression mechanism, the load periodically pulsates according to the number of cylinders during one rotation of the machine angle, so that the output (torque or rotation speed) of the motor (20) also pulsates periodically. The load of the motor (20) is not limited to the rotary compression mechanism, and may be, for example, another rotary compression mechanism or a flywheel.

The power supply device (30) supplies a drive current (specifically, a current for rotationally driving the motor (20), which is obtained by actual measurement or analysis) to the motor (20). The input side of the power supply (30) is connected to an AC power supply or a DC power supply (not shown) that is a rectified commercial power supply. In this example, the DC link voltage of the DC power supply pulsates periodically at a frequency that is, for example, one-half or one-sixth the fundamental frequency of the AC power supply or commercial power supply, and thereby the drive current also pulsates periodically. .. Further, the load pulsates while the motor (20) makes one rotation at the mechanical angle, and the drive current also pulsates periodically. The output side of the power supply (30) is connected to the motor (20) via a U-phase cable (11), a V-phase cable (12), and a W-phase cable (13). The power supply unit (30) is, for example, an asynchronous or synchronous three-phase voltage PWM inverter.

Here, an example of the waveform of the drive current is shown in FIG. In the figure, the broken line indicates the U-phase current, the alternate long and short dash line indicates the V-phase current, and the alternate long and short dash line indicates the W-phase current. From the figure, it can be seen that the envelope (90) of the drive current shown by the solid line is pulsating periodically. Similarly, at least one of the envelope of the line voltage of the motor (20) and the input power of the motor (20) may pulsate periodically.

The first sample piece (41) is a ring-shaped sample piece made of a soft magnetic material (for example, an electromagnetic steel plate or a dust core). The first sample piece (41) is a sample piece in which a soft magnetic material is formed in a substantially annular shape. The first sample piece (41) is a sample piece in which a closed magnetic path is formed by a soft magnetic material. The magnetic path cross-sectional area of the first sample piece (41) is substantially constant over the entire circumference. The impedance of the first sample piece (41) is preferably 10 times or more, more preferably 100 times or more the impedance of the motor (20). The first sample piece (41) corresponds to the sample piece.

The soft magnetic material constituting the first sample piece (41) is preferably the same as the soft magnetic material constituting the stator core (22) of the motor (20). As a result, the iron loss of the motor (20) can be obtained more accurately. The soft magnetic material constituting the first sample piece (41) may be different from the soft magnetic material constituting the stator core (22) of the motor (20). In this case, it is preferable that the iron losses of both soft magnetic materials with respect to the fundamental frequency of the input power are equal to or substantially equal to each other.

The first primary winding (51) is wound around the first sample piece (41). The first primary winding (51) is connected in parallel with the winding (23) of the motor (20). One end of the first primary winding (51) is connected to the U phase of the motor (20) inside the motor (20). The other end of the first primary winding (51) is connected to the V phase of the motor (20) inside the motor (20). A voltage corresponding to the line voltage of the motor (20) (in this example, the U-V line voltage) is applied to the first primary winding (51). The number of turns of the first primary winding (51) is the amplitude of the magnetic flux density at the point A (described later) of the back yoke portion (22a) of the motor (20) to which the drive current is input, and the first sample piece (41). The amplitude of the magnetic flux density in the above is set to be substantially equal to each other. The first primary winding (51) corresponds to the winding of the sample piece. The first secondary winding (54) is also wound around the first sample piece (41). The first secondary winding (54) is connected to the second waveform measuring device (62).

Since the configuration of the second sample piece (42) is the same as that of the first sample piece (41), detailed description thereof will be omitted. The second sample piece (42) corresponds to the sample piece.

The soft magnetic material constituting the second sample piece (42) is preferably the same as the soft magnetic material constituting the stator core (22) of the motor (20). As a result, the iron loss of the motor (20) can be obtained more accurately. The soft magnetic material constituting the second sample piece (42) may be different from the soft magnetic material constituting the stator core (22) of the motor (20). In this case, it is preferable that the iron losses of both soft magnetic materials with respect to the fundamental frequency of the input power are equal to or substantially equal to each other.

A second primary winding (52) is wound around the second sample piece (42). The second primary winding (52) is connected in parallel with the winding (23) of the motor (20). One end of the second primary winding (52) is connected to the U phase of the motor (20) inside the motor (20). The other end of the second primary winding (52) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the second primary winding (52). The number of turns of the second primary winding (52) is the amplitude of the magnetic flux density at the point B (described later) of the teeth portion (22b) of the motor (20) to which the drive current is input, and the second sample piece (42). It is set so that the amplitude of the magnetic flux density is substantially equal to that of the magnetic flux density. The second primary winding (52) corresponds to the winding of the sample piece. A second secondary winding (55) is also wound around the second sample piece (42). The second secondary winding (55) is connected to the second waveform measuring device (62).

The first waveform measuring device (61) is provided on the primary side of the first and second sample pieces (41, 42). The first waveform measuring device (61) measures the time change of the currents (in other words, the primary currents) of the first and second primary windings (51,52). The first waveform measuring device (61) is, for example, an oscilloscope, a power meter, or a current detector.

The second waveform measuring device (62) is provided on the secondary side of the first and second sample pieces (41, 42). The second waveform measuring device (62) measures the time change of the voltage (in other words, the secondary voltage) of the first and second secondary windings (54,55). The second waveform measuring device (62) is, for example, an oscilloscope or a voltage detector.

The measuring unit (100) is measured by the time change of the currents of the first and second primary windings (51,52) measured by the first waveform measuring device (61) and by the second waveform measuring device (62). Based on the time change of the voltage of the first and second secondary windings (54,55), the time change of the magnetic flux density and the magnetic field strength in each of the first and second sample pieces (41, 42) is obtained. .. Then, the iron loss generated in the first and second sample pieces (41,42) is obtained based on the time change of the magnetic flux density and the magnetic field strength in the first and second sample pieces (41,42).

The control unit (110) controls the power supply device (30) based on the iron loss generated in the first and second sample pieces (41, 42) measured by the measurement unit (100). The control unit (110) includes a lead-out unit (111) for deriving the iron loss and the copper loss of the motor (20). The control unit (110) controls the power supply device (30) based on the iron loss and the copper loss of the motor (20) derived by the out-licensing unit (111).

The measuring unit (100) and the control unit (110) specify the optimum values of the parameters related to the control of the motor (20), and execute the parameter control operation for driving the motor (20) using the optimum values. By the parameter control operation, for example, parameters such as a DC link voltage input to the power supply device (30), a current phase of the motor (20), and a carrier frequency when PWM control of the power supply device (30) can be specified. The functions of the measuring unit (100) and the control unit (110) are realized by a common microcomputer for driving a motor.

<Parameter control operation>
The parameter control operation will be described with reference to the flowchart of FIG.

First, in S101, the control unit (110) sets the parameters to predetermined initial values and proceeds to the process of S102.

In S102, the control unit (110) causes the power supply device (30) to supply the drive current to the motor (20). In this state, the measuring unit (100) measures the iron loss of the first and second sample pieces (41, 42). Further, the control unit (110) derives the iron loss and the copper loss of the motor (20) based on the iron loss of the first and second sample pieces (41, 42) measured by the measuring unit (100). .. Then, the control unit (110) calculates the sum of the iron loss and the copper loss of these motors (20) as the total loss. Here, the control unit (110) calculates the average value for one cycle of the machine angle as the iron loss, the copper loss, and the total loss. In the first embodiment, the control unit (110) calculates the average value for one cycle of the mechanical angle as the iron loss, the copper loss, and the total loss, but the average value for one cycle of the electric angle or the time. The integrated value may be calculated. The detailed derivation method of the iron loss of the motor (20) will be described later. The copper loss of the motor (20) is derived based on the current and resistance of the motor (20). The current of the motor (20) is measured by a current measuring device (not shown).

In S103, the control unit (110) determines whether or not the loss calculation, that is, the processing of S102 is completed for all the values of the parameters. If it is not finished, the process proceeds to S104, and if it is finished, the process proceeds to S105.

In S104, the control unit (110) changes the value of the parameter.

In S105, the control unit (110) selects the value having the smallest total loss calculated in S102 among all the values of the parameter as the optimum value of the parameter. For example, a mountain climbing method is used to select the optimum value.

In S106, the control unit (110) sets parameters to the optimum values selected in S105 and drives the motor (20) under the control of the power supply device (30). In this way, the motor (20) can be driven by setting the parameter to the value at which the total loss is the smallest, so that the motor (20) can be driven efficiently.

<Method of finding iron loss and copper loss of motor>
The method in which the measuring unit (100) and the control unit (110) obtain the iron loss of the motor (20) using the first and second sample pieces (41, 42) in S102 of the above parameter control operation is shown in FIG. This will be described with reference to the flowchart of 5.

First, in the excitation step, the control unit (110) causes the power supply device (30) to supply the drive current to the motor (20). As a result, the power supply device (30) inputs a drive current to the motor (20) and drives the motor (20) to rotate. That is, the power supply device (30) causes the first sample piece (41) to be driven by the motor (20) by passing a current through the first primary winding (51) of the first sample piece (41). ) Is excited so as to simulate the time change of the magnetic flux density and the magnetic field strength in the back yoke portion (22a). On the other hand, the power supply device (30) transfers the second sample piece (42) to the teeth portion (20) of the motor (20) by passing a current through the second primary winding (52) of the second sample piece (42). Excitation is performed so as to simulate the time change of the magnetic flux density and the magnetic field strength in 22b).

Specifically, the first sample piece (41) is excited to simulate the temporal changes in magnetic flux density and magnetic field strength at point A (see FIG. 2) at the back yoke portion (22a) of the motor (20). .. The point A is a radial midpoint in the back yoke portion (22a) and a circumferential midpoint between adjacent tooth portions (22b). The point A is suitable for simulating the time change of the magnetic flux density in the back yoke portion (22a) as a point where the magnetic flux concentration or the rotating magnetic field is not generated in the cross section of the back yoke portion (22a). The point A is a back yoke portion (22a) as a center point of the yoke width in a cross section having the same magnetic path cross section as the magnetic path cross section corresponding to the point (in this example, point A) that simulates the time change of the magnetic flux density. ) Is suitable for simulating the time change of the magnetic field strength. The site simulated by the first sample piece (41) is not limited to the point A.

Further, the second sample piece (42) simulates the time change of the magnetic flux density and the magnetic field strength at the point B (see FIG. 2) of the teeth portion (22b) of the motor (20) supplying the drive current. Be excited. The point B is an intermediate point in the width direction (circumferential direction) and the longitudinal direction (diameter direction) in the teeth portion (22b). The point B is suitable for simulating the time change of the magnetic flux density in the teeth portion (22b) as a point where the magnetic flux concentration or the rotating magnetic field is not generated in the cross section of the teeth portion (22b). The point B is a tooth portion (22b) as a center point of the tooth width in a cross section having the same magnetic path cross section as the magnetic path cross section corresponding to the point simulating the time change of the magnetic flux density (point B in this example). It is suitable for simulating the time change of the magnetic field strength in. The portion simulated by the second sample piece (42) is not limited to the point B. Then proceed to the measurement step.

In the measurement step, the measuring unit (100) performs the first sample piece (41) and the second sample piece (41) based on the time change of the magnetic flux density and the magnetic field strength in each of the first sample piece (41) and the second sample piece (42). The iron loss generated in each of the second sample pieces (42) is measured. The iron loss generated in each of the first sample piece (41) and the second sample piece (42) is the iron loss corresponding to the iron loss of the motor (20).

Specifically, the measuring unit (100) is based on the respective voltages of the first secondary winding (54) and the second secondary winding (55) measured by the second waveform measuring device (62). From the relationship of B = ∫Vdt / nS (B: magnetic flux density, V: voltage, n: number of winding turns, S: magnetic path cross-sectional area of the sample piece), the first sample piece (41) and the second sample piece The time change of the magnetic flux density in each of (42) is obtained. Further, the measuring unit (100) has H = ni / based on the currents of the first primary winding (51) and the second primary winding (52) measured by the first waveform measuring device (61). From the relationship of 2πr (H: magnetic field strength, n: number of windings, i: current, 2πr: average magnetic path length of sample piece, r: average value of outer diameter and inner diameter of sample piece), the first sample piece The time change of the magnetic field strength in each of (41) and the second sample piece (42) is obtained. The time change of the magnetic field strength is based on the voltage measured by the H coil arranged in each of the first sample piece (41) and the second sample piece (42), and H = ∫Vdt / A (H:: It may be obtained from the relationship of magnetic field strength, V: voltage, A: area turn). Then, the measuring unit (100) obtains the iron loss generated in each of the first sample piece (41) and the second sample piece (42) based on the obtained time change of the magnetic flux density and the magnetic field strength. Here, the iron loss of each of the plurality of cycles (as an example, the three cycles P1 to P3 are shown in FIG. 3) is obtained, and the average value thereof is calculated to obtain the first sample piece (41) and the second sample. The iron loss generated in each of the pieces (42) may be obtained. Then proceed to the derivation step.

In the derivation step, the derivation unit (111) of the control unit (110) derives the iron loss of the motor (20) based on the iron loss of each of the first sample piece (41) and the second sample piece (42). do.

Specifically, the out-licensing unit (111) obtains the iron loss per unit weight of the first sample piece (41) based on the iron loss and the weight of the first sample piece (41). The iron loss in the back yoke portion (22a) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the back yoke portion (22a) of the motor (20). Similarly, the out-licensing unit (111) obtains the iron loss per unit weight of the second sample piece (42) based on the iron loss and the weight of the second sample piece (42). The iron loss in the teeth portion (22b) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the teeth portion (22b) of the motor (20). Then, the lead-out portion (111) is the sum of the iron loss of the back yoke portion (22a) of the motor (20) and the iron loss of the teeth portion (22b) of the motor (20), and the iron loss of the motor (20). Ask for.

-Effect of Embodiment 1-
The motor drive device (10) of the first embodiment includes a measurement unit (100) for measuring the iron loss corresponding to the iron loss of the motor (20) supplying a drive current, and the control unit (110) is a control unit (110). The power supply device (30) is controlled based on the iron loss measured by the measuring unit (100). As a result, the power supply device (30) is controlled based on the iron loss corresponding to the iron loss of the motor (20) supplying the drive current, so that the iron loss of the motor (20) supplying the drive current can be reduced. , Can be reflected in the drive current of the motor (20).

Further, the motor drive device (10) of the first embodiment includes a sample piece (41,42) containing a soft magnetic material and a power supply device (30) for exciting the sample piece (41, 42). When the power supply device (30) inputs a drive current to drive the motor (20), the time change of the magnetic flux density and the magnetic field strength at a predetermined portion including the soft magnetic material in the magnetic circuit of the motor (20). The sample piece (41,42) is excited so as to simulate, and the iron loss measured by the measuring unit (100) is the sample piece (41,42) excited by the power supply device (30). It is an iron loss caused by. .. Here, the motor drive device (10) directly obtains the iron loss generated in the sample piece (41, 42), and controls the power supply device (30) based on the iron loss. Therefore, the iron loss of the motor (20) that is supplying the drive current can be accurately reflected in the drive current of the motor (20).

Further, in the motor drive device (10) of the first embodiment, the control unit (110) derives the iron loss of the motor (20) based on the iron loss measured by the measurement unit (100). The unit (111) is provided. Here, the motor drive device (10) directly obtains the iron loss generated in the sample piece (41, 42), and derives the iron loss of the motor (20) based on the iron loss. Therefore, the iron loss of the motor (20) can be accurately obtained.

Further, in the motor drive device (10) of the first embodiment, the lead-out unit (111) includes the iron loss of the sample piece (41,42), the weight of the sample piece (41,42), and the above. The iron loss of the motor (20) is derived based on the weight of a predetermined portion including the soft magnetic material in the magnetic circuit of the motor (20). Here, by considering the ratio of the weight of the sample piece (41,42) to the weight of a predetermined part in the magnetic circuit of the motor (20), the motor is based on the iron loss of the sample piece (41,42). It is conceivable to find the iron loss of (20). As a result, the iron loss of the motor (20) can be obtained more accurately.

Further, in the motor drive device (10) of the first embodiment, the predetermined portion in the magnetic circuit of the motor (20) is the back yoke portion (22a) of the stator (21) of the motor (20) and the back yoke portion (22a). Includes teeth section (22b). In this method, iron loss occurs in the sample piece (41, 42) that simulates the time change of the magnetic flux density and the magnetic field strength in the back yoke portion (22a) and the teeth portion (22b) of the stator (21) of the motor (20). Directly ask. Then, based on the obtained iron loss of the sample piece (41, 42), the iron loss of the back yoke portion (22a) and the teeth portion (22b) of the stator (21) of the motor (20) is derived. Therefore, the iron loss of the back yoke portion (22a) and the teeth portion (22b) of the motor (20) stator (21) can be accurately obtained.

Further, in the motor drive device (10) of the first embodiment, the winding (51,52) wound around the sample piece (41,42) is further provided, and the power supply device (30) is the sample piece. The sample piece (41,42) is excited by passing an electric current through the winding (51,52) of (41,42). Here, the sample piece (41,42) is directly excited by the current flowing through the winding (51,52) of the sample piece (41,42).

Further, in the motor drive device (10) of the first embodiment, at least a part of the windings (51,52) of the sample piece (41,42) has a voltage corresponding to the phase voltage of the motor (20). It is applied. As a result, the teeth portion (22b) of the stator (21) of the motor (20) can be simulated with the sample pieces (41, 42).

Further, in the motor drive device (10) of the first embodiment, at least a part of the windings (51,52) of the sample piece (41,42) has a voltage corresponding to the line voltage of the motor (20). Is applied. Here, the back yoke portion (22a) of the stator (21) of the motor (20) can be simulated with the sample pieces (41, 42).

Further, in the motor drive device (10) of the first embodiment, the wrapping wire of the driving current (90), the wrapping wire of the line voltage of the motor (20), the input power of the motor (20), and the motor (20). At least one of the torque of 20) and the rotational speed of the motor (20) pulsates periodically. Here, at least one of the drive current wrapping wire (90), the line voltage wrapping wire of the motor (20), the input power of the motor (20), the torque of the motor (20), and the rotation speed of the motor (20). Even if one pulsates periodically, the iron loss of the motor (20) can be obtained accurately. It should be noted that it has been difficult to obtain the iron loss of the motor in consideration of such periodic pulsation by the conventionally known method.

Further, in the motor drive device (10) of the first embodiment, the measuring unit (100) uses the sample piece (41, 42) based on the time change of the magnetic flux density and the magnetic field strength of the sample piece (41, 42). 42) Measure the iron loss. Here, the iron loss of the sample piece (41,42) can be measured by measuring the time change of the magnetic flux density and the magnetic field strength of the sample piece (41,42).

Further, in the first embodiment, the power supply device (30) is configured by an inverter. Here, conventionally, it has been difficult to measure the iron loss of a motor (20) driven by using an inverter. On the other hand, in the first embodiment, when the motor (20) is driven by using the inverter, the iron loss of the motor (20) can be accurately obtained. In particular, in the first embodiment, when the motor (20) is driven by using an asynchronous inverter in which the number of switchings within one cycle of the electric angle changes according to the change in the driving frequency (in this case, iron is used in the conventional method). It was particularly difficult to obtain the loss accurately.) However, the iron loss of the motor (20) can be obtained accurately.

Further, in the motor drive device (10) of the first embodiment, the lead-out unit (111) further derives the copper loss of the motor (20) that is supplying the drive current, and the control unit (110) , The power supply device (30) is controlled based on the iron loss and the copper loss of the motor (20) derived by the lead-out unit (111). As a result, the power supply device (30) is controlled based on the copper loss corresponding to the copper loss of the motor (20) supplying the drive current, so that the copper loss of the motor (20) supplying the drive current can be reduced. , Can be reflected in the drive current of the motor (20).

− Modification 1 of Embodiment 1
A modification 1 of the first embodiment will be described. In the first modification, the configurations of the first primary winding (51) and the second primary winding (52) are different from those of the first embodiment. Hereinafter, the differences from the first embodiment will be mainly described.

As shown in FIG. 6, one end of the first primary winding (51) is connected to the U phase of the motor (20) outside the motor (20). The other end of the first primary winding (51) is connected to the V phase of the motor (20) outside the motor (20). A voltage corresponding to the line voltage of the motor (20) (in this example, the U-V line voltage) is applied to the first primary winding (51). One end of the second primary winding (52) is connected to the U phase of the motor (20) outside the motor (20). The other end of the second primary winding (52) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the second primary winding (52).

− Modification of Embodiment 1 2-
A modification 2 of the first embodiment will be described. In the second modification, the configurations of the first primary winding (51) and the second primary winding (52) are different from those of the first embodiment, and the third primary winding (53) is provided. Hereinafter, the differences from the first embodiment will be mainly described.

As shown in FIG. 7, the first primary winding (51), the second primary winding (52), and the third primary winding (53) are wound around one sample piece (41). One end of the first primary winding (51) is connected to the U phase of the motor (20) outside the motor (20). The other end of the primary primary winding (51) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the first primary winding (51). One end of the second primary winding (52) is connected to the V phase of the motor (20) outside the motor (20). The other end of the second primary winding (52) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (V-phase voltage in this example) of the motor (20) is applied to the second primary winding (52). One end of the third primary winding (53) is connected to the W phase of the motor (20) outside the motor (20). The other end of the third primary winding (53) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (W phase voltage in this example) of the motor (20) is applied to the third primary winding (53). The third primary winding (53) corresponds to the winding of the sample piece. A secondary winding (54) is also wound around the sample piece (41). The secondary winding (54) is connected to the second waveform measuring device (62).

− Modification of Embodiment 1 3-
A modification 3 of the first embodiment will be described. In the third modification, the configurations of the first primary winding (51) and the second primary winding (52) are different from those of the first embodiment. Hereinafter, the differences from the first embodiment will be mainly described.

Although not shown, both the primary winding (51) and the secondary primary winding (52) are wound around one sample piece (41). One end of the first primary winding (51) is connected to the U phase of the motor (20) inside the motor (20). The other end of the first primary winding (51) is connected to the V phase of the motor (20) outside the motor (20). A voltage corresponding to the line voltage of the motor (20) (in this example, the U-V line voltage) is applied to the first primary winding (51). One end of the second primary winding (52) is connected to the W phase of the motor (20) inside the motor (20). The other end of the second primary winding (52) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (W phase voltage in this example) of the motor (20) is applied to the second primary winding (52).

− Modification of Embodiment 1 4-
A modification 4 of the first embodiment will be described. The present modification 4 is different from the modification 2 of the first embodiment in that one end of each of the first to third primary windings (51 to 53) is connected inside the motor (20). Hereinafter, the points different from the modification 2 of the first embodiment will be mainly described.

Although not shown, one end of the primary winding (51) is connected to the U phase of the motor (20) inside the motor (20). The other end of the primary primary winding (51) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the first primary winding (51). One end of the second primary winding (52) is connected to the V phase of the motor (20) inside the motor (20). The other end of the second primary winding (52) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (V-phase voltage in this example) of the motor (20) is applied to the second primary winding (52). One end of the third primary winding (53) is connected to the W phase of the motor (20) inside the motor (20). The other end of the third primary winding (53) is connected to the neutral point of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (W phase voltage in this example) of the motor (20) is applied to the third primary winding (53).

<< Embodiment 2 >>
The second embodiment will be described. The second embodiment is different from the first embodiment in the configuration of the winding wound around the sample piece (41, 42) and the specific content of the measurement step. Hereinafter, the differences from the first embodiment will be mainly described.

<Structure of motor drive device>
As shown in FIG. 8, the motor driving device (10) of the second embodiment includes a power measuring device (70) instead of the first waveform measuring device (61). The power measuring device (70) is used to measure the power consumption and copper loss in the first to third primary windings (51 to 53) of the first and second sample pieces (41, 42). The first to third primary windings (51 to 53) are connected to the power measuring device (70). The power measuring device (70) is, for example, a power meter.

The first primary winding (51) is wound around the first sample piece (41). The first primary winding (51) is connected in series with the winding (23) of the motor (20). The first primary winding (51) is connected to the U phase of the motor (20) outside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the first primary winding (51). The number of turns of the first primary winding (51) is the amplitude of the magnetic flux density at the point B of the teeth portion (22b) of the motor (20) to which the drive current is input, and the magnetic flux density in the first sample piece (41). The amplitude is set to be substantially equal. The first primary winding (51) corresponds to the winding of the sample piece.

A second primary winding (52) and a third primary winding (53) are wound around the second sample piece (42). The second primary winding (52) and the third primary winding (53) are connected in series with the winding (23) of the motor (20). The second primary winding (52) is connected to the U phase of the motor (20) outside the motor (20). The third primary winding (53) is connected to the V phase of the motor (20) outside the motor (20). A voltage corresponding to the line voltage of the motor (20) (in this example, the UV line voltage) is applied between the second primary winding (52) and the third primary winding (53). NS. The number of turns of the second primary winding (52) and the third primary winding (53) is the amplitude of the magnetic flux density at the point A of the back yoke portion (22a) of the motor (20) to which the drive current is input, and the second. The amplitude of the magnetic flux density in the two sample pieces (42) is set to be substantially equal to each other. The second primary winding (52) and the third primary winding (53) correspond to the windings of the sample piece, respectively.

The impedance of each of the first sample piece (41) and the second sample piece (42) is preferably 1/10 or less, and more preferably 1/100 or less of the impedance of the motor (20).

<How to find the iron loss of a motor>
In the measurement step of the second embodiment, the measuring unit (100) consumes power in the first to third primary windings (51 to 53) and copper loss in the first to third primary windings (51 to 53). Based on the above, the iron loss generated in each of the first sample piece (41) and the second sample piece (42) is measured.

Specifically, the measuring unit (100) determines the current measured value of the power measuring device (70) and the primary winding from the power consumption of the first primary winding (51) measured by the power measuring device (70). By subtracting the copper loss of the first primary winding (51) obtained from the resistance value of (51), the iron loss generated in the first sample piece (41) is obtained. The measuring unit (100) uses the power consumption of the second primary winding (52) and the third primary winding (53) measured by the power measuring device (70) to obtain the current measured value of the power measuring device (70) and the current measurement value of the power measuring device (70). The second sample is obtained by subtracting the copper loss of the second primary winding (52) and the third primary winding (53) obtained from the resistance values of the second primary winding (52) and the third primary winding (53). Find the iron loss that occurs in the piece (42).

-Effect of Embodiment 2-
The same effect as that of the first embodiment can be obtained by the second embodiment as well.

− Modification 1 of Embodiment 2
A modification 1 of the second embodiment will be described. In the first modification, the configurations of the first to third primary windings (51 to 53) are different from those of the second embodiment. Hereinafter, the points different from the second embodiment will be mainly described.

Although not shown, the primary winding (51) is connected to the U phase of the motor (20) inside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the first primary winding (51). The second primary winding (52) is connected to the U phase of the motor (20) inside the motor (20). The third primary winding (53) is connected to the V phase of the motor (20) inside the motor (20). A voltage corresponding to the line voltage of the motor (20) (in this example, the UV line voltage) is applied between the second primary winding (52) and the third primary winding (53). NS.

− Modification of Embodiment 2 2-
A modification 2 of the second embodiment will be described. In the second modification, the configurations of the first to third primary windings (51 to 53) are different from those of the second embodiment. Hereinafter, the points different from the second embodiment will be mainly described.

Although not shown, all of the first to third primary windings (51 to 53) are wound around one sample piece (41). The first primary winding (51) is connected to the U phase of the motor (20) inside or outside the motor (20). A voltage corresponding to the phase voltage (U-phase voltage in this example) of the motor (20) is applied to the first primary winding (51). The second primary winding (52) is connected to the V phase of the motor (20) inside or outside the motor (20). A voltage corresponding to the phase voltage (V-phase voltage in this example) of the motor (20) is applied to the second primary winding (52). The third primary winding (53) is connected to the W phase of the motor (20) inside or outside the motor (20). A voltage corresponding to the phase voltage (W phase voltage in this example) of the motor (20) is applied to the third primary winding (53).

<< Embodiment 3 >>
The third embodiment will be described. The third embodiment is different from the first embodiment in that the iron loss of the motor (20) is obtained without directly using the motor (20). Hereinafter, the differences from the first embodiment will be mainly described.

<Structure of motor drive device>
As shown in FIG. 9, the motor drive device (10) of the third embodiment further includes a power supply device (120) as an exciting unit different from the power supply device (30), and includes a first sample piece and a second sample piece. A sample piece (43) is provided in place of (41, 42). A primary winding (51) and a secondary winding (54) are wound around the sample piece (43).

The power supply unit (120) supplies the sample piece (43) with an exciting current corresponding to the drive current (determined by actual measurement or analysis) of the motor (20). The input side of the power supply (120) is connected to a DC power supply (not shown). The output side of the power supply (120) is connected to the primary winding (51) wound around the sample piece (43).

The sample piece (43) is a ring-shaped sample piece made of a soft magnetic material (for example, an electromagnetic steel plate or a dust core). The sample piece (43) is a sample piece in which a soft magnetic material is formed in a substantially annular shape. The sample piece (43) is a sample piece in which a closed magnetic path is formed by a soft magnetic material. The magnetic path cross-sectional area of the sample piece (43) is substantially constant over the entire circumference. The soft magnetic material constituting the sample piece (43) is preferably the same as the soft magnetic material constituting the stator core (22) of the motor (20). As a result, the iron loss of the motor (20) can be obtained more accurately.

The first waveform measuring device (61) is provided on the primary side of the sample piece (43). The first waveform measuring device (61) measures the time change of the current (in other words, the primary current) of the primary winding (51). The first waveform measuring device (61) is, for example, an oscilloscope, a power meter, or a current detector.

The second waveform measuring device (62) is provided on the secondary side of the sample piece (43). The second waveform measuring device (62) measures the time change of the voltage (in other words, the secondary voltage) of the secondary winding (54). The second waveform measuring device (62) is, for example, an oscilloscope or a voltage detector.

<How to find the iron loss of a motor>
In S102 of the above parameter control operation, a method of obtaining the iron loss of the motor (20) using the sample piece (43) will be described with reference to the flowchart of FIG.

First, in the excitation step, the control unit (110) causes the power supply device (120) to supply the exciting current to the primary winding (51). As a result, the power supply device (120) creates an exciting current for simulating the back yoke portion (22a) of the motor (20) and an exciting current for simulating the teeth portion (22b) of the motor (20). Input separately to the primary winding (51) of the sample piece (43). At this time, a current flows through the primary winding (51) of the sample piece (43), and the sample piece (43) has the magnetic flux density and the magnetic field strength in the back yoke portion (22a) or the teeth portion (22b) of the motor (20). It is excited to simulate the time change of.

Specifically, the sample piece (43) first simulates the time change of the magnetic flux density and the magnetic field strength at the point A (see FIG. 2) of the back yoke portion (22a) of the motor (20) supplying the drive current. It is excited to do. Subsequently, the sample piece (43) is excited so as to simulate the time change of the magnetic flux density and the magnetic field strength at the point B (see FIG. 2) of the teeth portion (22b) of the motor (20) supplying the drive current. Will be done. The site simulated by the sample piece (43) is not limited to the points A and B. Further, the excitation for simulating the teeth portion (22b) may be performed before the excitation for simulating the back yoke portion (22a). Then proceed to the measurement step.

In the measurement step, the measuring unit (100) measures the iron loss generated in the sample piece (43) based on the time change of the magnetic flux density and the magnetic field strength in the sample piece (43).

Specifically, the measuring unit (100) has B = ∫Vdt / nS (B: magnetic flux density, V:) based on the voltage of the secondary winding (54) measured by the second waveform measuring device (62). From the relationship of voltage, n: number of windings, S: magnetic path cross-sectional area of the sample piece), the time change of the magnetic flux density in the sample piece (43) is obtained. Further, based on the current (excitation current) of the primary winding (51) measured by the first waveform measuring device (61), H = ni / 2πr (H: magnetic field strength, n: number of winding turns, i). : Current, 2πr: Average magnetic path length of the sample piece, r: Average value of the outer diameter and inner diameter of the sample piece), the time change of the magnetic field strength in the sample piece (43) is obtained. The time change of the magnetic field strength is H = ∫Vdt / A (H: magnetic field strength, V: voltage, A: area turn) based on the voltage measured by the H coil arranged on the sample piece (43). It may be obtained from the relationship of. Then, based on the obtained magnetic flux density and the time change of the magnetic field strength, the iron loss generated in the sample piece (43) is obtained. Here, the iron loss of each of the plurality of cycles (as an example, the three cycles of P1 to P3 are shown in FIG. 3) is obtained, and the average value thereof is calculated to obtain the iron loss generated in the sample piece (43). You may. Then proceed to the derivation step.

In the derivation step, the derivation unit (111) of the control unit (110) derives the iron loss of the motor (20) based on the iron loss of the sample piece (43) measured by the measurement unit (100).

Specifically, the lead-out unit (111) has iron loss of the sample piece (43) when an exciting current simulating the back yoke portion (22a) of the motor (20) is applied, and the weight of the sample piece (43). Based on the above, the iron loss per unit weight of the sample piece (43) is obtained. The iron loss in the back yoke portion (22a) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the back yoke portion (22a) of the motor (20). Similarly, the lead-out unit (111) determines the iron loss of the sample piece (43) when an exciting current that simulates the teeth portion (22b) of the motor (20) is applied and the weight of the sample piece (43). Based on this, the iron loss per unit weight of the sample piece (43) is calculated. The iron loss in the teeth portion (22b) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the teeth portion (22b) of the motor (20). Then, the lead-out portion (111) is the sum of the iron loss of the back yoke portion (22a) of the motor (20) and the iron loss of the teeth portion (22b) of the motor (20), and the iron loss of the motor (20). Ask for.

-Effect of Embodiment 3-
The same effect as that of the first embodiment can be obtained by the third embodiment.

Further, in the third embodiment, the primary winding (51) of the sample piece (43) is connected to a power supply device (120) for passing a current through the primary winding (51) of the sample piece (43). ing. Here, the power supply (120) causes a current to flow through the primary winding (51) of the sample piece (43). When the drive current of the motor (20) is obtained by analysis, it is possible to accurately obtain the iron loss of the motor (20) without making a prototype of the motor (20).

<< Embodiment 4 >>
The fourth embodiment will be described. The fourth embodiment is different from the first embodiment in that the iron loss of the motor (20) is obtained without directly using the motor (20). Hereinafter, the differences from the first embodiment will be mainly described.

<Structure of motor drive device>
As shown in FIG. 10, the motor drive device (10) of the fourth embodiment includes a magnetic field generator (80) as an exciting unit and a sample piece (44). The magnetic field generator (80) has a power supply device (130), a yoke body (81), and a primary winding (56) and a secondary winding (57).

The power supply unit (130) supplies the yoke body (81) with an exciting current corresponding to the drive current (determined by actual measurement or analysis) of the motor (20). The input side of the power supply (130) is connected to a DC power supply (not shown). The output side of the power supply (130) is connected to a primary winding (56) wound around a yoke body (81).

The yoke body (81) is a member made of a soft magnetic material. The yoke body (81) has a sufficiently large magnetic path cross-sectional area so that its iron loss is 1% or less of that of the sample piece (44), and is formed in a substantially C shape. It has an air gap (82). The yoke body (81) constitutes a closed magnetic path via the air gap (82). The yoke body (81) is composed of a member separate from the sample piece (44).

The sample piece (44) is a block-shaped (rectangular parallelepiped-shaped in this example) sample piece made of a soft magnetic material (for example, an electromagnetic steel plate or a dust core). The soft magnetic material constituting the sample piece (44) is preferably the same as the soft magnetic material constituting the stator core (22) of the motor (20). As a result, the iron loss of the motor (20) can be obtained more accurately. A secondary winding (57) is wound around the sample piece (44).

The first waveform measuring device (61) measures the time change of the current (in other words, the primary current) of the primary winding (56). The first waveform measuring device (61) is, for example, an oscilloscope, a power meter, or a current detector.

The second waveform measuring device (62) measures the time change of the voltage (in other words, the secondary voltage) of the secondary winding (57). The second waveform measuring device (62) is, for example, an oscilloscope or a voltage detector.

<How to find the iron loss of a motor>
In S102 of the above parameter control operation, a method of obtaining the iron loss of the motor (20) using the sample piece (44) will be described with reference to the flowchart of FIG.

First, in the placement step, the sample piece (44) is placed in the air gap (82) of the yoke body (81). Then proceed to the excitation step.

In the excitation step, the control unit (110) causes the power supply (130) to supply an exciting current to the primary winding (56). As a result, the power supply device (130) creates an exciting current for simulating the back yoke portion (22a) of the motor (20) and an exciting current for simulating the teeth portion (22b) of the motor (20). Separately flow through the primary winding (56) of the yoke body (81). At this time, a current flows through the primary winding (56) of the yoke body (81), and the sample piece (44) is the back yoke portion (22a) or the teeth portion (22b) of the motor (20) supplying the drive current. It is excited to simulate the time change of the magnetic flux density and the magnetic field strength in.

Specifically, the sample piece (44) is first excited to simulate the temporal changes in magnetic flux density and magnetic field strength at point A (see FIG. 2) at the back yoke portion (22a) of the motor (20). .. Subsequently, the sample piece (44) is excited to simulate the temporal changes in magnetic flux density and magnetic field strength at point B (see FIG. 2) at the teeth portion (22b) of the motor (20). That is, the power supply device (130) causes a current to flow in the primary winding (56) of the yoke body (81), whereby a magnetic flux flows through the yoke body (81). This magnetic flux flows through the air gap (82), which indirectly excites the sample piece (41) arranged in the air gap (82). The site simulated by the sample piece (44) is not limited to the points A and B. Further, the excitation for simulating the teeth portion (22b) may be performed before the excitation for simulating the back yoke portion (22a). Then proceed to the measurement step.

In the measurement step, the measuring unit (100) measures the iron loss generated in the sample piece (44) based on the time change of the magnetic flux density and the magnetic field strength in the sample piece (44).

Specifically, the measuring unit (100) has B = ∫Vdt / nS (B: magnetic flux density, V:) based on the voltage of the secondary winding (57) measured by the second waveform measuring device (62). From the relationship of voltage, n: number of windings, S: magnetic path cross-sectional area of the yoke body), the time change of the magnetic flux density in the yoke body (81) was obtained, and based on this, the magnetic flux density in the sample piece (44) was obtained. Find the time change of. Further, the measuring unit (100) has H = ni / L (H: magnetic field strength, n:) based on the current (exciting current) of the primary winding (56) measured by the first waveform measuring device (61). From the relationship of the number of winding turns, i: current, L: average magnetic path length of the yoke body), the time change of the magnetic field strength in the yoke body (81) was obtained, and based on this, the magnetic field strength in the sample piece (44) was obtained. Find the time change of. The time change of the magnetic field strength of the sample piece (44) is based on the voltage measured by the H coil arranged on the sample piece (44), and H = ∫Vdt / A (H: magnetic field strength, V: voltage, A: Area turn) may be obtained. Then, the measuring unit (100) obtains the iron loss generated in the sample piece (44) based on the time change of the obtained magnetic flux density and the magnetic field strength. Here, the iron loss of each of the plurality of cycles (as an example, the three cycles of P1 to P3 are shown in FIG. 3) is obtained, and the average value thereof is calculated to obtain the iron loss generated in the sample piece (44). You may. Then proceed to the derivation step.

In the derivation step, the derivation unit (111) of the control unit (110) derives the iron loss of the motor (20) based on the iron loss of the sample piece (44).

Specifically, the lead-out unit (111) has iron loss of the sample piece (44) when an exciting current simulating the back yoke portion (22a) of the motor (20) is applied, and the weight of the sample piece (44). Based on the above, the iron loss per unit weight of the sample piece (44) is calculated. The iron loss in the back yoke portion (22a) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the back yoke portion (22a) of the motor (20). Similarly, the lead-out unit (111) has the iron loss of the sample piece (44) when an exciting current simulating the teeth part (22b) of the motor (20) is applied and the weight of the sample piece (44). Based on this, the iron loss per unit weight of the sample piece (44) is calculated. The iron loss in the teeth portion (22b) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the teeth portion (22b) of the motor (20). Then, the iron loss of the motor (20) is calculated as the sum of the iron loss of the back yoke portion (22a) of the motor (20) and the iron loss of the teeth portion (22b) of the motor (20).

-Effect of Embodiment 4-
The same effect as that of the first embodiment can be obtained by the fourth embodiment.

Further, in the motor drive device (10) of the fourth embodiment, the magnetic field generator (80) excites the sample piece (44) by generating a magnetic field. As a result, the sample piece (44) is excited.

<< Embodiment 5 >>
The fifth embodiment will be described. In the fifth embodiment, the configuration of the magnetic field generator (80) is different from that of the fourth embodiment. Hereinafter, the differences from the fourth embodiment will be mainly described.

<Structure of motor drive device>
As shown in FIG. 12, in the fifth embodiment, the yoke body (81) has a columnar columnar portion (81a) and a columnar projecting portion projecting from both ends of the columnar portion in a common direction so as to face each other. With (81b), it is formed in a substantially U-shape. The primary winding (56) connected to the output side of the power supply device (130) is wound around the columnar portion (81a).

The sample piece (44) is formed in a plate shape, and is composed of, for example, a single plate of an electromagnetic steel plate. Both ends of the sample piece (44) face each other with one side facing the tip surface of the protruding part (81b) of the yoke body (81) at intervals. The primary winding (56) connected to the output side of the power supply device (130) may be wound around the sample piece (44) instead of the yoke body (81). A secondary winding (57) is wound around the sample piece (44).

<How to find the iron loss of a motor>
In S102 of the above parameter control operation, a method of obtaining the iron loss of the motor (20) using the sample piece (44) will be described with reference to the flowchart of FIG.

First, in the placement step, the sample piece (44) has one surface of both ends of the sample piece (44) facing the tip surface of the protruding portion (81b) of the yoke body (81) with a small gap. Is placed. Then proceed to the excitation step.

In the excitation step, the control unit (110) causes the power supply (130) to supply an exciting current to the primary winding (56). As a result, the power supply device (130) creates an exciting current for simulating the back yoke portion (22a) of the motor (20) and an exciting current for simulating the teeth portion (22b) of the motor (20). Input separately to the primary winding (56) of the yoke body (81). At this time, a current flows through the primary winding (56) of the yoke body (81), and the sample piece (44) is the back yoke portion (22a) or the teeth portion (22b) of the motor (20) supplying the drive current. It is excited to simulate the time change of the magnetic flux density and the magnetic field strength in.

Specifically, the sample piece (44) is first excited to simulate the temporal changes in magnetic flux density and magnetic field strength at point A (see FIG. 2) at the back yoke portion (22a) of the motor (20). .. Subsequently, the sample piece (44) is excited to simulate the temporal changes in magnetic flux density and magnetic field strength at point B (see FIG. 2) at the teeth portion (22b) of the motor (20). That is, the power supply (130) causes a current to flow through the primary winding (56) of the yoke body (81), which causes magnetic flux to flow through the yoke body (81), which indirectly excites the sample piece (44). NS. The site simulated by the sample piece (44) is not limited to the points A and B. Further, the excitation for simulating the teeth portion (22b) may be performed before the excitation for simulating the back yoke portion (22a). Then proceed to the measurement step.

In the measurement step, the measuring unit (100) measures the iron loss generated in the sample piece (44) based on the time change of the magnetic flux density and the magnetic field strength in the sample piece (44).

Specifically, the measuring unit (100) has B = ∫Vdt / nS based on the voltage of the secondary winding (57) wound around the sample piece (44) measured by the second waveform measuring device (62). From the relationship (B: magnetic flux density, V: voltage, n: number of windings, S: magnetic path cross-sectional area of the sample piece), the time change of the magnetic flux density in the sample piece (44) is obtained. Further, the measuring unit (100) has H = ni / L (H: magnetic field strength, n:) based on the current (exciting current) of the primary winding (56) measured by the first waveform measuring device (61). From the relationship of the number of winding turns, i: current, L: average magnetic path length of the sample piece), the time change of the magnetic field strength in the yoke body (81) was obtained, and based on this, the magnetic field strength in the sample piece (44) was obtained. Find the time change of. The time change of the magnetic field strength of the sample piece (44) is based on the voltage measured by the H coil arranged on the sample piece (44), and H = ∫Vdt / A (H: magnetic field strength, V: voltage, A: Area turn) may be obtained. Then, the measuring unit (100) obtains the iron loss generated in the sample piece (44) based on the time change of the obtained magnetic flux density and the magnetic field strength. Here, the iron loss of each of the plurality of cycles (as an example, the three cycles of P1 to P3 are shown in FIG. 3) is obtained, and the average value thereof is calculated to obtain the iron loss generated in the sample piece (44). You may. Then proceed to the derivation step.

In the derivation step, the derivation unit (111) of the control unit (110) derives the iron loss of the motor (20) based on the iron loss of the sample piece (44).

Specifically, the lead-out unit (111) has iron loss of the sample piece (44) when an exciting current simulating the back yoke portion (22a) of the motor (20) is applied, and the weight of the sample piece (44). Based on the above, the iron loss per unit weight of the sample piece (44) is calculated. The iron loss in the back yoke portion (22a) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the back yoke portion (22a) of the motor (20). Similarly, the sample piece (44) is based on the iron loss of the sample piece (44) when an exciting current that simulates the teeth portion (22b) of the motor (20) is applied and the weight of the sample piece (44). ) To find the iron loss per unit weight. The iron loss in the teeth portion (22b) of the motor (20) is calculated as the product of the iron loss per unit weight and the weight of the teeth portion (22b) of the motor (20). Then, the iron loss of the motor (20) is calculated as the sum of the iron loss of the back yoke portion (22a) of the motor (20) and the iron loss of the teeth portion (22b) of the motor (20).

-Effect of Embodiment 5-
The same effect as that of the fourth embodiment can be obtained by the fifth embodiment as well.

<< Other Embodiments >>
The above embodiment may have the following configuration.

For example, in the first to fifth embodiments and modifications thereof, magnetic saturation occurs at a predetermined portion (for example, the back yoke portion (22a) or the teeth portion (22b)) in the magnetic circuit of the motor (20) in the excitation step. When the condition presumed to be satisfied is satisfied, the ratio of the voltage or current for exciting the sample piece (41 to 44) to the driving current may be larger than that when the condition is not satisfied. Specifically, for example, a plurality of sample pieces (41 to 43) having different winding numbers of windings are prepared, and when the condition is satisfied, the winding number of windings to be wound is set. It is conceivable to use relatively large sample pieces (41 to 43). As another example, a plurality of sample pieces (41 to 44) having different magnetic path cross-sectional areas are prepared, and when the conditions are satisfied, sample pieces (41 to 44) having a relatively large magnetic path cross-sectional area are prepared. It is conceivable to use it. As yet another example, an amplification amplifier may be connected to the winding of the sample piece (41 to 43), and when the condition is satisfied, the voltage applied to the winding of the sample piece (41 to 43) may be boosted. Conceivable.

Further, for example, in the excitation step, when the time change of the magnetic flux density and the magnetic field strength when the drive current for performing the weakening magnetic flux control is input to the motor (20) is simulated by the sample piece (41 to 44), other than that. The ratio of the voltage or current for exciting the sample piece (41 to 44) to the drive current may be smaller than in the case of. Specifically, for example, a plurality of sample pieces (41 to 44) having different winding numbers of windings are prepared, and when the condition is satisfied, the winding number of windings to be wound is determined. It is conceivable to use relatively small sample pieces (41-44). As another example, a plurality of sample pieces (41 to 44) having different magnetic path cross-sectional areas are prepared, and when the conditions are satisfied, sample pieces (41 to 44) having a relatively small magnetic path cross-sectional area are prepared. It is conceivable to use it. As yet another example, an amplification amplifier may be connected to the winding of the sample piece (41 to 44), and when the condition is satisfied, the voltage applied to the winding of the sample piece (41 to 44) may be stepped down. Conceivable.

Further, for example, according to the motor driving device (10) of the present disclosure, it is possible to obtain the iron loss generated at an arbitrary portion (for example, the back yoke portion (22a) or the teeth portion (22b)) of the motor (20). As an example, if the first sample piece (41) in the first embodiment is used, the iron loss of only the back yoke portion (22a) of the motor (20) can be accurately obtained. It should be noted that it has been difficult to accurately determine the iron loss of an arbitrary portion in the magnetic circuit of the motor (20) by a conventionally known measuring method.

Further, for example, the winding (23) of the motor (20) is connected in a star shape, but the present invention is not limited to this, and the winding (23) may be connected in a delta shape.

Further, in the above-described first to fifth embodiments, the functions of the measuring unit (100) and the control unit (110) are realized by a common microcomputer for driving the motor, but the function for obtaining the iron loss and the copper loss of the motor is obtained. An analog arithmetic unit that realizes the above may be provided separately. As a result, the sampling frequency can be increased, and iron loss, copper loss, and total loss can be calculated more accurately.

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. Further, the above embodiments and modifications may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired.

As described above, the present disclosure is useful for motor drives and sample pieces.

10 Motor drive
20 motor
21 Stator
22 Stator core
22a Back yoke
22b Teeth section
23 windings
30 Power supply (power supply, excitation)
41 First sample piece (sample piece)
42 Second sample piece (sample piece)
43,44 Sample piece
51 Primary primary winding (winding)
52 Second primary winding (winding)
53 Third primary winding (winding)
56 Primary winding (winding)
80 Magnetic field generator (excited part)
81 York body
100 measuring unit
110 Control unit
111 Derivation part
120 Power supply (excitation part)

Claims (19)

A motor drive device including a power feeding unit (30) that supplies a drive current to the motor (20) and a control unit (110) that controls the power feeding unit (30).
Further equipped with a measuring unit (100) for measuring the iron loss corresponding to the iron loss of the motor (20) that is supplying the drive current.
The control unit (110) is a motor drive device characterized in that the power supply unit (30) is controlled based on the iron loss measured by the measurement unit (100). In the motor drive device according to claim 1,
Sample pieces (41-44) containing soft magnetic material and
It is equipped with an exciting part (30,120,130) that excites the above sample pieces (41 to 44).
The exciting portion (30,120,130) simulates the time change of the magnetic flux density and the magnetic field strength at a predetermined portion including the soft magnetic material in the magnetic circuit of the motor (20) supplying the driving current. Excite (41-44) and
A motor drive device characterized in that the iron loss measured by the measuring unit (100) is the iron loss generated in the sample pieces (41 to 44) excited by the exciting unit (30,120,130). In the motor drive device according to claim 2,
The control unit (110) is a motor drive device including a lead-out unit (111) that derives the iron loss of the motor (20) based on the iron loss measured by the measurement unit (100). In claim 3,
The derivation unit (111) is a predetermined portion including the iron loss of the sample piece (41 to 44), the weight of the sample piece (41 to 44), and the soft magnetic material in the magnetic circuit of the motor (20). A motor driving device characterized in that the iron loss of the motor (20) is derived based on the weight of the motor (20). In any one of claims 2 to 4,
The predetermined portion in the magnetic circuit of the motor (20) includes a back yoke portion (22a) and a teeth portion (22b) of the stator (21) of the motor (20). .. In any one of claims 2 to 5,
Further provided with windings (51-53) wound around the sample pieces (41-43),
The exciting unit (30) is a motor driving device characterized in that the sample pieces (41 to 43) are excited by passing an electric current through the windings (51 to 53) of the sample pieces (41 to 43). In claim 6,
The windings (51 to 53) of the sample pieces (41 to 43) are connected in parallel with the windings (23) of the motor (20).
The exciting unit (30) is a motor driving device characterized by being the feeding unit (30). In claim 6,
The windings (51 to 53) of the sample pieces (41 to 43) are connected in series with the windings (23) of the motor (20).
The exciting portion is a motor driving device characterized by being the feeding portion. In claim 6,
The winding (51) of the sample piece (43) is connected to a power supply device (120) for passing a current through the winding (51) of the sample piece (43).
The exciting unit (120) is the power supply device (120).
The power supply device (120) is a motor drive device characterized by being different from the power supply unit (30). In any one of claims 7 to 9,
The exciting portion (30) is characterized in that a voltage corresponding to the phase voltage of the motor (20) is applied to at least a part of the windings (51 to 53) of the sample pieces (41 to 44). Motor drive. In any one of claims 7 to 10,
The exciting portion (30) is characterized in that a voltage corresponding to the line voltage of the motor (20) is applied to at least a part of the windings (51 to 53) of the sample pieces (41 to 44). Motor drive device. In any one of claims 6 to 11,
The measuring unit (100) determines the power consumption of the windings (51 to 53) of the sample pieces (41 to 44) and the copper loss of the windings (51 to 53) of the sample pieces (41 to 44). A motor drive device characterized by measuring the iron loss of the sample pieces (41 to 44) based on the above. In any one of claims 2 to 12,
When the condition presumed that magnetic saturation occurs at the predetermined portion in the magnetic circuit of the motor (20) is satisfied, the exciting portion (30,120,130) has the driving current as compared with the case where the condition is not satisfied. A motor drive device characterized by increasing the ratio of voltage or current for exciting the sample pieces (41 to 44) to. In any one of claims 2 to 13,
When the exciting unit (30,120,130) simulates the time change when the driving current for controlling the weakening magnetic flux is input to the motor (20) with the sample pieces (41 to 44), in other cases. A motor driving device, characterized in that the ratio of a voltage or a current for exciting the sample pieces (41 to 44) to the driving current is reduced as compared with the above. In any one of claims 2 to 14,
At least one of the drive current envelope, the line voltage envelope of the motor (20), the input power of the motor (20), the torque of the motor (20), and the rotational speed of the motor (20). A motor drive that pulsates periodically. In any one of claims 2 to 5,
The exciting unit (80) is a motor driving device, which is a magnetic field generating device that excites the sample piece (44) by generating a magnetic field. In any one of claims 2 to 16,
The motor driving device (100) measures the iron loss of the sample pieces (41 to 44) based on the time change of the magnetic flux density and the magnetic field strength of the sample pieces (41 to 44). .. In the motor drive device according to any one of claims 3 to 17.
The derivation unit (111) further derives the copper loss of the motor (20) that is supplying the drive current, and further derives the copper loss.
The control unit (110) is a motor drive device characterized in that the power supply unit (30) is controlled based on the iron loss and the copper loss of the motor (20) derived by the lead-out unit (111). The ring-shaped sample piece used in the motor driving device according to any one of claims 2 to 15.

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