JP4230443B2 - Synchronous motor drive device - Google Patents

Description

  The present invention relates to a drive device for driving a synchronous motor by inverter control, and more particularly to a drive device having a function of detecting step-out of a synchronous motor.

  In a drive device that drives a synchronous motor by inverter control, step-out detection is performed by various methods. For example, in Patent Document 1, in a motor drive system that drives a permanent magnet type synchronous motor without a speed / position sensor, the step-out detection is performed. Set a reference value for the physical quantity that appears only during timing, that is, the amount of correction to the rotational speed command that is performed to stabilize the motor control, or the calculated value of the axis error (axis deviation). Provide a function to determine step-out when the correction value or shaft error exceeds a preset reference value, or calculate the reactive power of the motor from the applied voltage and current detection value of the motor, and based on this calculation result An example in which a function for determining whether or not an electric motor has stepped out is provided is disclosed.

JP 2003-79200 A

  However, in the technique described in Patent Document 1, in order to perform reliable step-out detection, a correction amount or a shaft error (amount of shaft misalignment) for the rotational speed command performed for stabilizing the motor control is not achieved. A reference value is set for the calculated value, and when these correction values or axis errors exceed the preset reference value, a function is provided to determine step-out, and the motor is determined from the applied voltage and current detection value of the motor. It is necessary to provide a function of calculating the reactive power of the motor and determining whether or not the motor has stepped out based on the calculation result.

  Therefore, since two detection methods are required at the same time, the control becomes very complicated, and a very high-performance microprocessor or the like and a large-capacity memory are required for the realization. In addition, since the amount of shaft misalignment is used to stabilize the motor control, the output voltage is saturated, and the shaft misalignment cannot be estimated in a high output region where the target voltage does not match the output voltage. Furthermore, it is impossible to calculate reactive power. Therefore, there is a problem that it is impossible to detect step-out.

  On the other hand, synchronous motors are also used in ventilation fans and fans in refrigeration air conditioners, but in refrigeration air conditioners, if the step-out continues due to the failure of the fan motor, the capacity of the refrigeration air conditioner cannot be obtained. Since the compressor, the electric motor, the refrigerant piping, the inverter circuit, and the like are damaged, it is necessary for the motor driving device for the blower to detect the step-out with high accuracy so that the operation can be stopped and alarmed.

  On the other hand, ventilation fans and fans in refrigeration and air conditioners are installed in a state where they are exposed to the influence of outside wind, so even if the synchronous motor is normal, step-out may occur due to gusts. In this case, it can be said that it is not necessary to take an operation stop / alarm measure, so it is considered that the operation may be restarted without stopping even if a step-out is detected. It is also important to be able to provide a driving device for a blower motor having such a step-out detection function at low cost.

  The present invention has been made in view of the above, and an object of the present invention is to obtain a drive device for a synchronous motor having an out-of-step detection function capable of detecting out-of-step with high accuracy and without restriction with an inexpensive configuration.

  Another object of the present invention is to provide a synchronous motor drive device that can appropriately select and execute operation stop and restart when step-out is detected.

In order to achieve the above-mentioned object, the present invention is a drive in which the drive control of the synchronous motor is performed by inverter control using the dq coordinate current component obtained at the time of the drive control irrespective of the rotor position detecting means. In the device, a mechanism for extracting a q-axis current component that is a torque current component during operation by giving a change to a target operating frequency and detecting a step- out based on a response amplitude value of the q-axis current component corresponding to the change It is provided with.

  According to the present invention, in the non-saliency type synchronous motor, regardless of whether the inductances of the d-axis and the q-axis are equal or different, the q-axis current becomes a direct current when the target operating frequency is not changed. Therefore, separation from the fluctuation component is easy, and step-out can be detected with high accuracy and no restrictions. Moreover, the detection processing system does not become complicated.

  According to the present invention, there is an effect that it is possible to obtain a synchronous motor drive device having an out-of-step detection function capable of performing out-of-step detection with high accuracy and without restriction with an inexpensive configuration.

  Exemplary embodiments of a synchronous motor drive device according to the present invention will be explained below in detail with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of a synchronous motor drive device according to an embodiment of the present invention. In FIG. 1, an inverter device 1 that is a drive device drives and controls a synchronous motor 3 by inverter control based on a DC voltage output from a DC power supply unit 2.

  The synchronous motor 3 will be described by taking a permanent magnet type synchronous motor (PMSM) as an example here, but in addition, a brushless DC motor (BLDCM), a reluctance motor (RM), a synchronous reluctance motor (SyRM), a switch A reluctance motor (SRM) or the like can be similarly applied.

  The inverter device 1 includes an inverter main circuit unit 4, a current detection unit 5, and an inverter control unit 6. The inverter control unit 6 includes an electric motor control unit 7 and a step-out detection unit 8.

  The inverter main circuit unit 4 includes three sets of switching elements “10a, 10b”, “10c, 10d”, “10e, 10” connected in series between the positive and negative buses of the DC power supply unit 2, and each switching And a drive circuit (not shown) for controlling on / off of the element. In addition, the freewheeling diode 11 is connected to each switching element in parallel. In FIG. 1, the switching elements “10a, 10b” are for the U phase, the switching elements “10c, 10d” are for the V phase, and the switching elements “10e, 10f” are for the W phase.

The three sets of switching elements “10a, 10b”, “10c, 10d”, and “10e, 10” are connected to respective control electrodes from a drive circuit (not shown) by PWM (pulse width modulation) signals “UP, UN” from the motor control unit 7. , VP, VN, WP, WN "is applied to perform a switching operation. Note that the subscript “P” in the PWM signal indicates that it is for the upper arm switching element, and the subscript “N” indicates that it is for the lower arm switching element. The connection ends of the three sets of switching elements “10a, 10b”, “10c, 10d”, and “10e, 10” are connected to the output terminal of the inverter device 1. A power supply cable to the synchronous motor 3 is connected to this output terminal.

  The current detection unit 5 includes two current detectors 5 a and 5 b that respectively detect a two-phase drive current in a three-phase drive current that the inverter main circuit unit 4 gives to the synchronous motor 3 during operation of the synchronous motor 3. . In FIG. 1, the current detector 5a detects a U-phase drive current Iu, and the current detector 5b detects a V-phase drive current Iv. The two-phase drive currents “Iu, Iv” detected by the current detection unit 5 are given to the motor control unit 7.

The motor control unit 7 includes a phase current calculation unit 12, a coordinate conversion unit 13, a modulation frequency generation unit 14, a target operation frequency generation unit 15, a voltage command value calculation unit 16, an output voltage vector calculation unit 17, and a DC power supply unit 2 side. A DC voltage detector 18 and a PWM signal generator 19 are provided. The modulation frequency generation unit 14, the target operation frequency generation unit 15, and the voltage command value calculation unit 16 constitute a variation applying unit as a whole. In addition, the step -out detection unit 8 that is a step-out detection unit includes a frequency component extraction unit 21, a current comparison unit 22, and a number comparison unit 23.

  In the motor control unit 7, the three-phase drive current “Iu, Iv, Iw” is obtained from the two-phase drive current “Iu, Iv” detected by the current detection unit 5 in the phase current calculation unit 12. The coordinate conversion unit 13 converts the three-phase drive current “Iu, Iv, Iw” obtained by the phase current calculation unit 12 into an excitation current component Id and a torque current component Iq on dq coordinates, and a voltage command value This is given to the calculation unit 16 and the frequency component extraction unit 21 in the step-out detection unit 8. The phase current calculation unit 12 can be omitted.

  The modulation frequency F0 is input from the modulation frequency generation unit 14 to the target operation frequency generation unit 15 and the frequency component extraction unit 21. The modulation frequency F0 generated by the modulation frequency generator 14 can be specified from an operation panel (not shown). Further, the target operation frequency f0 and the output current command Id * are input to the voltage command value calculation unit 16 from the outside (for example, a host computer such as a main computer or a man-machine interface of a system in which the inverter device is incorporated). .

The voltage command value calculation unit 16 first operates the current operation frequency f so as to coincide with the target operation frequency f0 from the outside, and supplies it to the target operation frequency generation unit 15. The target operation frequency generation unit 15 modulates the current operation frequency f from the voltage command value calculation unit 16 by the modulation frequency F0 from the modulation frequency generation unit 14 , and changes the target operation frequency command (rotation speed command) at the modulation frequency F0. ) F * is generated and given to the voltage command value calculation unit 16.

  Then, the voltage command value calculation unit 16 includes a rotation speed command f * from the target operation frequency generation unit 15, an output current command Id * from the outside, and dq coordinate current components Id and Iq from the coordinate conversion unit 13. The output voltage command values Vd * and Vq * in the dq coordinates are obtained based on the above and given to the output voltage vector calculation unit 17.

  The output voltage vector calculation unit 17 is based on the bus voltage Vdc of the DC power supply unit 1 detected by the DC voltage detection unit 18 and the output voltage command values Vd * and Vq * in the dq coordinates from the voltage command value calculation unit 16. An output voltage vector Vx * is obtained and supplied to the PWM signal generator 19. A binary state signal Sy_err indicating the operating state of the synchronous motor 3 is input to the PWM signal generation unit 19 from the number comparison unit 23 in the step-out detection unit 8. The status signal Sy_err indicates, for example, a synchronization state when Sy_err = 0, and indicates a step-out state when Sy_err = 1.

  The PWM signal generation unit 19 monitors the state signal Sy_err from the number comparison unit 23 in the step-out detection unit 8, and when the state signal Sy_err is at "0" level, the output voltage vector from the output voltage vector calculation unit 17 The generation of PWM signals “UP, UN, VP, VN, WP, WN” for ON / OFF control of the switching elements 10a, 10b, 10c, 10d, 10e, 10f based on Vx * is repeated. The PWM signal generator 19 stops generating the PWM signals “UP, UN, VP, VN, WP, WN” as soon as the status signal Sy_err becomes “1” level.

In the step-out detection unit 8, the frequency component extraction unit 21 modulates the dq coordinate current components Id and Iq from the coordinate conversion unit 13 and the modulation frequency of the target operation frequency command f * from the modulation frequency generation unit 14. From F 0, the modulation frequency F 0 component Iqω 0 of the torque current component Iq is extracted and provided to the current comparison unit 22.

  The current comparison unit 22 compares the magnitude relationship between the reference current Ith given from the outside and the modulation frequency F0 component Iqω0 of the torque current component Iq from the frequency component extraction unit 21, and the comparison result signal Si is sent to the number comparison unit 23. give.

  The number comparison unit 23 checks the number of times that the modulation frequency F0 component Iqω0 of the torque current component Iq has increased or decreased the reference current Ith based on the comparison result signal Si from the current comparison unit 22, and the number of times reference value NG_Level given from the outside The magnitude relation is compared, and when the number of times the state signal Sy_err given to the PWM signal generator 19 is increased or decreased exceeds the reference number of times NG_Level, it is determined to be in a synchronized state and is set to “0” level. Judgment of step-out is made and set to “1” level.

  In the number comparison unit 23, when the synchronous motor 3 is a blower motor, when the state signal Sy_err is set to “1”, it is forcibly returned to the “0” level and the PWM signal generation unit 19 is restarted. Repeating this operation a plurality of times, and if it still fails to properly set Sy_err = 0, an abnormality is notified to the operation panel or the like. On the other hand, when the synchronous motor 3 is not a blower motor, the number comparison unit 23 immediately notifies the operation panel or the like of an abnormality when the state signal Sy_err is set to “1” level.

  Hereinafter, the step-out detection operation according to this embodiment will be described with reference to FIGS. FIG. 2 is an operation waveform diagram for explaining the operation of the main part relating to the step-out detection in the inverter control unit during the synchronous operation of the synchronous motor shown in FIG. FIG. 3 is an operation waveform diagram for explaining the operation of the main part related to the step-out detection in the inverter control unit at the time of step-out of the synchronous motor shown in FIG. FIG. 4 is a diagram for explaining the relationship between the rotor of the synchronous motor shown in FIG. 1 and the electrical angle phase and coordinates used in the inverter control unit. FIG. 5 is a flowchart for explaining a step-out detection function included in the synchronous motor driving inverter device shown in FIG. 1. 2 and 3 show an example in which the synchronous motor 3 has four rotor poles.

  2 and 3, the waveform (a) is a phase angle (electrical angle phase) used in the inverter control unit 6. A waveform (b) is a target operation frequency command f * generated by the target operation frequency generation unit 15. A waveform (c) is a q-axis current Iq obtained by the coordinate conversion unit 13. The waveform (d) is the reference signal Ith and the modulation frequency F0 component Iqω0 related to the comparison operation in the current comparison unit 22. The reference signal Ith has an upper limit value “+ Ith” and a lower limit value “−Ith”. A waveform (e) is a comparison result signal Si output from the current comparison unit 22.

  As shown in FIG. 2, when the synchronous motor is in synchronous operation, the rotor repeats acceleration / deceleration with a minute amplitude according to the fluctuation cycle of the target operation frequency command f *, and torque fluctuation occurs in the q axis. The amplitude of the q-axis current Iq varies. As a result, the modulation frequency F0 component Iqω0 periodically exceeds the upper and lower reference currents “± Ith”. Therefore, the comparison result signal Si, which is a result of comparison with the reference current “± Ith”, is a periodic pulse signal having a pulse width corresponding to the set value of the reference current “± Ith”.

  On the other hand, as shown in FIG. 3, if the synchronous motor is in a step-out state, the shaft torque does not vary according to the variation period of the target operating frequency command f *, and the amplitude of the q-axis current Iq does not vary. The amplitude is constant. As a result, the modulation frequency F0 component Iqω0 falls within and does not exceed the upper and lower reference currents “± Ith”. For this reason, the comparison result signal Si, which is the result of comparison with the reference current “± Ith”, does not change and becomes zero level.

  Thus, the number of times (fluctuation frequency) at which the q-axis current intersects the reference current Ith is different between the step-out time and the synchronization time. In particular, at the step-out time, the fluctuation frequency is unique depending on the motor regardless of the rotation speed. It is decided. Therefore, it is possible to detect step-out by detecting this difference. That is, it can be known from the state of the comparison result signal Si whether the synchronous motor is in a synchronized state or in a step-out state.

  Specifically, in this embodiment, as shown in FIG. 1, the number comparison unit 23 measures the number of crossings between the q-axis current Iq and the reference current Ith within a predetermined time Tm from the state of the comparison result signal Si. The step-out is determined only when the total number of intersections is equal to or less than the number of step-out detection times NG_Level.

  That is, in an electric motor that drives a load such as a blower with small fluctuation during one rotation, as shown in FIG. 2, the fluctuation component (AC component) generated in the q-axis current during synchronous operation is large, and the step-out shown in FIG. The fluctuation component (alternating current component) generated in the q-axis current at the time is smaller than that at the time of synchronization. Therefore, in the case of an electric motor that drives a load such as a blower with a small fluctuation during one rotation, the modulation frequency F0 component included in the q-axis current is detected, and is removed when the magnitude of the AC component exceeds a predetermined value. It is sufficient to judge that it has been adjusted.

  In addition, in an electric motor that drives a load having a large fluctuation during one rotation, a large fluctuation occurs in the q-axis current even during synchronous operation. In this case, the fluctuation cycle of the target operating frequency f * is selected by selecting a different cycle from the load fluctuation cycle, and a large S / N can be obtained by selectively extracting a signal component with a bandpass filter, FFT, etc. Even in the case of an electric motor that drives a large load, step-out can be detected with high accuracy by the same method.

  Next, with reference to FIG. 4, a phenomenon in which a difference appears in the q-axis current Iq between synchronization and step-out in accordance with a change in the target operation frequency command f * will be described. In FIG. 4, the N pole side on the rotor is generally d-axis, and the phase advanced 90 degrees in the rotation direction is generally q-axis. When the position sensor that detects the position of the rotor is not used for driving the synchronous motor, the inverter control unit 6 cannot accurately capture the dq axes of the rotor. Therefore, the inverter control unit 6 defines the γ-δ axis as the estimated dq axis. The γ-axis is a phase advanced by Δθ from the d-axis. Further, the phase angle of the inverter control unit 6 when the γ axis is viewed from the U phase of the three-phase fixed coordinates is defined as an electrical angle phase θe.

  Here, a non-salient pole type motor having the same d-axis and q-axis inductances, such as a surface magnet type synchronous motor (SPMSM), will be described. In the synchronous operation state, the rotor of the synchronous motor 3 and the output voltage phase of the inverter device 1 are synchronized. For this reason, the relationship between the rotor phase (dq axis) and the output voltage phase (γ−δ axis) of the inverter device 1 maintains a constant phase difference Δθ, that is, the output voltage phase (γ− of the inverter device 1). When the δ axis) is used as a reference, the inductance Lγ viewed from the γ axis is equal to the inductance Lδ viewed from the δ axis, and the d-axis current Id (Iγ) and the q-axis current Iq (Iδ) are substantially DC. Become.

  However, when the target operating frequency command f * is changed, minute rotation unevenness occurs according to the change. For this reason, since the output voltage phase (γ-δ axis) and the rotor phase (dq axis) of the inverter device 1 fluctuate during one rotation, the q-axis current Iq (Iδ), which is a non-control amount, fluctuates. Will occur.

  On the other hand, in the step-out state, since the rotor is stopped and no induced voltage is generated, the rotation unevenness corresponding to the variation of the target operation frequency command f * does not occur, and the q-axis current Iq (Iδ) that is the torque current is generated. No fluctuations according to uneven rotation occur.

  Therefore, even in a non-salient pole type motor having the same d-axis and q-axis inductances, as in a non-salient pole type motor in which the d-axis and q-axis inductances are not equal, such as an embedded magnet type synchronous motor (IPMSM), By changing the target operating frequency command f * in the dq coordinates during one rotation of the rotor and detecting the number of fluctuations in the q-axis current Iq, the operating state of the rotor can be grasped in principle. This makes it possible to detect the step-out of the synchronous motor. In particular, in a non-saliency type synchronous motor, when no modulation is applied, the q-axis current becomes a direct current, so that it is easy to separate from the modulation component. Therefore, this method can detect a step-out with high sensitivity particularly in a non-salient pole type synchronous motor.

  In short, since the estimation formula for the axis deviation can be realized only with a motor having a difference in each inductance of the d-axis and the q-axis, in principle, it is difficult to detect the step-out with a motor having a small difference in each inductance of the d-axis and the q-axis. However, with the out-of-step detection method of the present invention, it is possible to adopt an electric motor with little difference in each inductance of the d-axis and q-axis even for a fan that is likely to generate noise due to torque fluctuation during one rotation with a wing load. It becomes.

  Next, each processing operation in the step-out detection operation according to this embodiment will be described with reference to FIG. 1 along FIG. In addition, in FIG. 5, the application example to the drive device in case the synchronous motor 3 is a synchronous motor used for a ventilation blower or a refrigerating air-conditioner blower is shown.

  In FIG. 5, in step ST <b> 1, when the drive control of the synchronous motor 3 is started, the current detection unit 5 detects at least two-phase drive currents, for example, U-phase and V-phase drive currents “Iu, Iv”. . Thus, the phase current calculation unit 12 calculates the phase currents “Iu, Iv, Iw” for three phases from the phase current “Iu, Iv” (step ST2). Then, the coordinate conversion unit 13 converts the phase currents “Iu, Iv, Iw” for three phases into currents “Id, Iq” on the dq coordinates (step ST3). Note that the phase current calculation process (step ST2) can be omitted, and the process can proceed to the coordinate conversion process (step ST3) immediately after the current detection process (step ST1).

  Next, when the frequency component extraction unit 21 extracts the modulation frequency F0 component Iqω0 in the current “Id, Iq” on the dq coordinate (step ST4), the current comparison unit 22 generates the modulation frequency F0 component. The magnitude relationship between Iqω0 and reference current Ith is determined (step ST6). That is, in the current comparison unit 22, when the magnitude | IqF0 | of the modulation frequency F0 component Iqω0 is larger than the reference current Ith (step ST6: Yes), the comparison result signal Si is set to the “1” level (step ST7). When the magnitude | IqF0 | of the modulation frequency F0 component Iqω0 is smaller than the reference current Ith (step ST6: No), the comparison result signal Si is set to the “0” level (step ST8).

  In a ventilation blower or a refrigeration air conditioner blower, since the moment of inertia is large with respect to the output torque of the electric motor, a large torque fluctuation occurs in the q-axis even in a slight frequency fluctuation in the synchronized state. Therefore, the comparison result signal Si sufficient for detecting the synchronization state is obtained.

  Next, the number comparison unit 23 compares the number of changes in the comparison result signal Si per unit time with the step-out detection number NG_Level (step ST9). In the number comparison unit 23, when “the number of changes per unit time of the comparison result signal Si”> “the number of out-of-step detection times NG_Level” (step ST9: No), since it is in a synchronous state, the PWM signal generator 19 is supplied with Sy_err. = 0 is given, and the process returns to step ST1.

  On the other hand, when “the number of changes per unit time of the comparison result signal Si” ≦ “the step-out detection number NG_Level” (step ST9: Yes), the number comparison unit 23 is in a step-out state, and therefore the PWM signal generator 19 is given a state signal Sy_err of Sy_err = 1, and the PWM signal generator 19 is stopped from generating a PWM signal (step ST10).

  Then, the number comparison unit 23 determines whether or not the number of times that Sy_err = 1 is output to the PWM signal generator 19 exceeds a predetermined value (step ST11), and if not (step ST11: No), the number comparison unit 23 proceeds to step ST1. When the process proceeds and exceeds (step ST11: Yes), the process proceeds to step ST12.

  That is, in the refrigeration air conditioner, if the step-out continues due to the failure of the blower motor, the capacity of the refrigeration air conditioner cannot be obtained, and the compressor, the electric motor, the refrigerant piping, the inverter circuit, etc. are damaged. Further, in the ventilation blower, if the step-out continues due to the failure of the blower motor, the original ventilation function cannot be obtained until the restart takes place, and odor, hot air, moisture and the like cannot be discharged. On the other hand, ventilation fans and fans in refrigeration air conditioners are installed in a state where they are exposed to the influence of outside wind, and therefore, even when the synchronous motor is normal, step-out may occur due to gusts. The frequency of this occurrence is low.

  Therefore, when the state signal Sy_err is set to “1”, the number comparison unit 23 forcibly returns the level signal to “0” and restarts the PWM signal generation unit 19 (step ST11: No). In the case of transient step-out due to the above-mentioned gust of wind, it is often possible to return to normal operation with a small number of restarts such as once or twice. On the other hand, in the case of a step-out due to a bearing lock due to a rise in temperature due to a decrease in the lubrication performance of the motor bearing at the end of the product life or a foreign object on the fan blade, the step-out frequently occurs even after restarting, so the unit time The number of restarts is determined, and the restart is repeated a plurality of times (step ST11: No). Then, when the number of restarts exceeds a predetermined value (step ST11: Yes), the restart is immediately stopped and an abnormality is notified to the operation panel or the like (step ST12).

  Thus, if the step-out detection method according to this embodiment is applied to the driving device of the synchronous motor used for the blower of the refrigeration air-conditioning apparatus, the step-out of the synchronous motor can be accurately and appropriately detected. It is possible to suppress adverse effects on the refrigerating and air-conditioning apparatus. Thereby, the reliability of the refrigeration air conditioner can be improved.

  In addition, if the step-out detection method according to this embodiment is applied to the synchronous motor drive device used in the ventilation blower, restarting is performed before the odor, hot air, moisture, etc. cannot be discharged sensibly. Since it can be applied, the reliability of the ventilation fan can be improved.

  According to the step-out detection method according to this embodiment, in addition to being able to detect step-out accurately, when the step-out detection processing as shown in FIG. Since the processing load of the processor or the like is extremely light, a synchronous motor driving device having a highly accurate step-out detection function can be realized at low cost.

  Here, the step-out detection method according to this embodiment is a method that modulates the target operating frequency command, but the necessity to constantly modulate the target frequency is that the necessity to perform the operation of step-out detection constantly. Is not necessarily. When the response speed of step-out detection may be slow, a method of applying modulation intermittently may be used. According to this, it is possible to reduce the loss due to the motor current ripple caused by the modulation, that is, the out-of-step detection operation.

  This measure is a device that does not cause a problem as a system, such as a ventilator fan or a fan of a refrigerating and air-conditioning apparatus, that rarely undergoes load fluctuations that lead to step-out, and even if it occurs, restart within a few tens of seconds. This is particularly effective in the case of For example, if modulation for step-out detection is performed within a period of 100 ms and is performed once every 10 seconds, the influence of loss due to modulation can be reduced to 1/100. Specifically, for example, if the decrease in overall system efficiency is 10% when the step-out detection operation is always performed, the decrease in efficiency can be suppressed to 0.1%.

  In addition, since the step-out detection method according to this embodiment is a method that modulates the target operating frequency command, the presence or absence of noise and vibration is a problem in ventilation fans and refrigeration air conditioner fans that require quietness. become. On the other hand, in the ventilation fan and the refrigeration air conditioner fan, since the moment of inertia is large with respect to the modulation, the actual response to the output torque of the electric motor is slow, and the fluctuation of the actual load rotational speed is small. Therefore, even if a method of modulating the target operating frequency command is adopted, noise vibrations are not likely to occur, so that there is little problem.

  However, when the modulation frequency is an audible frequency, there is a possibility that annoying noise accompanying modulation is felt. In that case, as shown in FIG. 1, an instruction is given to the modulation frequency generator 14 from the operation panel or the like to generate a frequency having fluctuations or the like, or to generate an inaudible frequency. Thereby, the silence of the blower can be ensured.

  As an example of generating an inaudible frequency, specifically, for example, a 4-pole or 8-pole electric motor is used for a ventilation blower or a blower of a refrigeration air conditioner, and the minimum operation frequency is about 10 Hz. It is good to use the frequency of. Since the lowest human audible frequency is 20 Hz, if the modulation frequency is 10 Hz or less, audible noise due to modulation for step-out detection does not occur.

  On the other hand, the method for determining the presence or absence of step-out is not limited to a method in which the fluctuation of the modulation frequency component of the q-axis current is performed depending on the number of crossings with the reference current, and the amplitude of the modulation frequency component of the q-axis current is extracted. However, a method of determining the presence or absence of step-out using the difference in amplitude may be used. Extraction of the amplitude of the modulation frequency component of the q-axis current can be easily realized by using a highly sensitive bandpass filter, FFT, or the like. According to this determination method, even a slight q-axis torque fluctuation relative to the operating torque can be detected with high sensitivity, so that the modulation amplitude for step-out detection can be reduced, and an increase in loss and noise due to modulation can be suppressed. .

  Further, the relationship between the modulation frequency and the operating frequency can be determined as follows according to the type of the electric motor. That is, as the synchronous motor 3, in the embedded magnet type synchronous motor, the fluctuation of the q-axis current is large during normal operation. Therefore, if modulation is performed at a frequency different from the fluctuation frequency of the q-axis current during normal operation, S / N can be increased. Therefore, in general, fluctuations in the q-axis current during normal operation appear as higher-order components of the operating frequency, so the minimum value of the operating frequency is not included in the modulation frequency for step-out detection so as not to overlap the operating frequency. The following fixed frequencies can be used.

  Similarly, even in a synchronous motor that drives a reciprocating compressor or a single rotary compressor, a load torque ripple with a large fluctuation in q-axis current does not occur during normal operation, which is different from the fluctuation frequency of q-axis current during normal operation. When modulation is performed at a frequency, the S / N of the detection component can be increased. In general, therefore, fluctuations in the q-axis current during normal operation appear as the primary and high-order components of the operating frequency, and therefore, the operating frequency is not overlapped with the operating frequency in the modulation frequency for step-out detection. A fixed frequency below the minimum value of can be used.

  By the way, although the phase current of the electric motor is used in this embodiment to obtain the q-axis current for step-out detection, the q-axis current may be obtained by using the bus current of the inverter main circuit unit 4. . According to this, since the phase current detection unit 5 is not required, the step-out detection method according to the present invention can be applied to a bus current detection type driving device that is low in current detection cost.

  Further, as can be understood from the above description, the out-of-step detection method according to the present invention is not limited to the case where the primary magnetic flux constant control is used as the driving method of the synchronous motor, but the driving capable of giving a variation to the target operating frequency. Any method can be applied to any drive device that can detect a torque current that is synchronous and asynchronous and can detect the difference.

  As described above, the synchronous motor drive device according to the present invention is useful for detecting the step-out of the synchronous motor with an inexpensive configuration with high accuracy and without restriction, and is particularly noiseless and highly efficient. Therefore, it is suitable for improving the reliability by applying to a synchronous motor used for a ventilation fan or a fan of a refrigeration air conditioner.

It is a block diagram which shows the structure of the drive device of the synchronous motor by one Embodiment of this invention. FIG. 2 is an operation waveform diagram for explaining an operation of a main part related to step-out detection in an inverter control unit during synchronous operation of the synchronous motor shown in FIG. 1 (during synchronization). It is an operation | movement waveform diagram explaining the operation | movement of the principal part in connection with the step-out detection in an inverter control part at the time of a step-out of the synchronous motor shown in FIG. It is a figure explaining the relationship between the rotor of the synchronous motor shown in FIG. 1, and the electrical angle phase and coordinate used with an inverter control part. It is a flowchart explaining the step-out detection function with which the drive device of the synchronous motor shown in FIG.

Explanation of symbols

1 Inverter device (drive device)
2 DC power supply unit 3 Synchronous motor 4 Inverter main circuit unit 5 Current detection unit 5a, 5b Current detector 6 Inverter control unit 7 Motor drive unit 8 Step-out detection unit 10a, 10b, 10c, 10d, 10e, 10f Switching element 11 Reflux Diode 12 Phase current calculation unit 13 Coordinate conversion unit 14 Modulation frequency generation unit 15 Target operation frequency generation unit 16 Voltage command value calculation unit 17 Output voltage vector calculation 18 DC voltage detection unit 19 PWM signal generation unit 21 Frequency component extraction unit 22 Current comparison Part 23 Number comparison part

Claims (10)

In the drive device that performs the drive control of the synchronous motor by the inverter control using the dq coordinate current component obtained at the time of the drive control regardless of the rotor position detection unit,
A mechanism for extracting a q-axis current component that is a torque current component during operation by giving a change to the target operating frequency, and detecting a step- out based on a response amplitude value of the q-axis current component corresponding to the change;
A drive device for a synchronous motor, comprising: The mechanism for detecting the step-out is:
Fluctuation imparting means for varying the generated voltage vector of the output voltage vector computing means for generating a voltage vector for controlling the synchronous motor by modulating the target operating frequency;
Step-out detection means for detecting the presence or absence of step-out from the transient response of the q-axis current component obtained during drive control of the synchronous motor;
The drive device for a synchronous motor according to claim 1, comprising:   When the step-out detection means detects a step-out of the synchronous motor, it restarts after the synchronous motor stops driving, and when the predetermined number of restarts does not return to the synchronized state, the synchronous motor is stopped and an abnormality is notified. The apparatus for driving a synchronous motor according to claim 2, further comprising means for performing the operation.   4. The dq coordinate current component obtained during drive control of the synchronous motor is generated from at least two-phase detection drive currents supplied to the synchronous motor. The synchronous motor drive device.   The dq coordinate current component obtained during drive control of the synchronous motor is detected from a bus current of an inverter circuit that generates drive current to be supplied to the synchronous motor by inverter control. Item 4. The synchronous motor drive device according to Item 2 or 3. The step-out detection means includes
Means for extracting a fluctuation period component of the target operating frequency from the q-axis current component obtained during drive control of the synchronous motor;
Means for generating a crossing determination signal indicating the number of times that the fluctuation period component of the target operating frequency in the extracted q-axis current component crosses a reference value;
Means for outputting a step-out detection signal when the number of intersections indicated by the intersection determination signal does not exceed the number of synchronization determinations;
The synchronous motor drive device according to claim 2, wherein the synchronous motor drive device is provided. The step-out detection means includes
Means for extracting a fluctuation amplitude component of the target operating frequency from the q-axis current component obtained during drive control of the synchronous motor;
Means for outputting a step-out detection signal when the amplitude value of the fluctuation amplitude component of the target operating frequency in the extracted q-axis current component does not exceed the synchronization determination reference value;
The synchronous motor drive device according to claim 2, wherein the synchronous motor drive device is provided.   The synchronous motor drive device according to claim 2 or 3, wherein the modulation frequency used by the variation applying means is an inaudible frequency.   4. The synchronous motor drive device according to claim 2, wherein the modulation frequency used by the fluctuation applying unit is a fixed frequency equal to or lower than an operation frequency.   The synchronous motor drive device according to claim 2 or 3, wherein the fluctuation applying means intermittently performs an operation of modulating the target operating frequency.

Images