JP6536460B2 - Inverter controller - Google Patents

Description

  The present invention relates to an inverter control device that controls an inverter by PWM control.

Conventionally, in an inverter control device that controls an inverter by PWM control, there is known a technique for reducing carrier noise and reducing noise due to electromagnetic noise. For example, the control device of the PWM inverter disclosed in Patent Literatures 1 and 2 adds the diffusion frequency (ΔFc × k1) obtained by multiplying the basic carrier frequency Fc0 by the maximum variation ΔFc and the coefficient k1 according to the following equation. The carrier frequency Fc is calculated.
Fc = Fc0 + ΔFc × k1
Here, the basic carrier frequency Fc0 is calculated according to the voltage command. The maximum variation ΔFc is a preset constant. The coefficient k1 is defined as table data that changes randomly in the range from “−1” to “+1”, and the average value of all the data is about zero.

Patent No. 4974457 gazette Patent No. 5121895 gazette

In the prior art of Patent Documents 1 and 2, when the basic carrier frequency Fc0 is constant, the fluctuation of the diffusion frequency becomes the fluctuation of the carrier frequency Fc as it is. Further, the change of the coefficient k1 is set at random, and if the coefficient k1 changes at once from the lower limit "-1" to the upper limit "+1", the carrier frequency Fc is a difference of twice the maximum fluctuation .DELTA.Fc. It changes rapidly.
Therefore, if the maximum variation ΔFc is set relatively large in order to sufficiently spread the carrier frequency Fc, the output voltage of the inverter may change suddenly depending on the amount of change of the coefficient k1, and the control may become unstable. On the other hand, if the maximum variation ΔFc is set relatively small, the carrier frequency Fc is not sufficiently diffused, and noise due to electromagnetic noise can not be reduced.

  The present invention was created in view of such a point, and an object thereof is to provide an inverter control device which improves control stability and reduces noise due to electromagnetic noise.

The inverter control device according to the present invention is a device that controls an inverter (30) that converts direct current power input from a power supply (11) into alternating current power by operation of a plurality of switching elements (31 to 36). The inverter control device includes a voltage command calculation unit (580), a PWM signal generation unit (66), and a carrier wave frequency setting unit (67).
The voltage command calculation unit calculates a voltage vector to be commanded to the inverter.
The PWM signal generation unit generates a PWM signal by comparing the phase voltage with the carrier wave as a method of specifying the voltage waveform output from the inverter. The carrier frequency setting unit sets the frequency (Fc) of the carrier used by the PWM signal generation unit.

The carrier frequency setting unit has a basic frequency adjustment unit (68) and a spread frequency adjustment unit (69).
The fundamental frequency adjustment unit periodically and continuously changes the fundamental frequency on which the carrier frequency is based within a predetermined variation range (Tb).
The diffusion frequency adjustment unit adds the diffusion frequencies distributed within the range of the maximum fluctuation (± ΔF) to the fundamental frequency to the fundamental frequency at intervals shorter than the fluctuation period (Tb) of the fundamental frequency.

  Here, the term "continuous" specifying the change of the fundamental frequency is interpreted on the basis of the fluctuation range of the fundamental frequency. For example, the frequency difference from the lower limit frequency to the upper limit frequency is eliminated as a “discontinuous” change that changes in one step. On the other hand, a relatively small step change relative to the fluctuation range is regarded as a "continuous change", and is interpreted as satisfying the constituent requirements of the present invention.

In the present invention, the carrier frequency is set by the periodically changing base frequency and the spreading frequency added to the base frequency at intervals shorter than the fluctuation period of the base frequency. The periodically and continuously changing fundamental frequency leads the frequency spread, and the spread frequency further has an auxiliary spreading function.
Therefore, according to the present invention, since it is not necessary to set the maximum fluctuation of the diffusion frequency to a particularly large value in order to reduce the noise due to the electromagnetic noise, it is possible to prevent the sudden change of the carrier frequency due to the fluctuation of the diffusion frequency. Therefore, the inverter control device of the present invention can appropriately achieve both improvement of control stability and reduction of noise due to electromagnetic noise.

Preferably, the diffusion range in which the diffusion frequency is distributed is set smaller than the fluctuation range of the fundamental frequency. Thereby, sudden change of the carrier wave frequency due to the diffusion component can be prevented, and control stability can be improved.
Preferably, the base frequency adjusting unit monotonously increases the base frequency from the lower limit frequency (Fm) of the variation range to the upper limit frequency (FM), and monotonously decreases the upper limit frequency to the lower limit frequency. As a result, sudden changes in the carrier frequency can be further prevented, and control stability can be further improved.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic block diagram of MG drive system to which the inverter control apparatus of each embodiment is applied. The control block diagram of the inverter control apparatus of each embodiment. The control block diagram of the modulator of each embodiment. The figure explaining the switch of the voltage waveform specific system according to a modulation factor. (A) The figure which shows the period fluctuation | variation of a fundamental frequency by 1st Embodiment, (b) frequency distribution map of spreading frequency, (c) carrier frequency-frequency characteristic view. The figure which shows setting of the fluctuation | variation period of the fundamental frequency by 2nd Embodiment. (A) Time-frequency characteristic diagram when the fluctuation range of the three-phase fundamental frequency is dispersed according to the third embodiment, (b) carrier frequency-frequency characteristic diagram. The figure which shows the period fluctuation | variation of the fundamental frequency by other embodiment. The frequency distribution table of the spreading | diffusion frequency by other embodiment. Distribution of carrier frequency according to the prior art.

Hereinafter, a plurality of embodiments of an inverter control device are described based on a drawing. The following first to third embodiments are collectively referred to as "the present embodiment".
The inverter control device of the present embodiment is a device that controls an inverter that supplies three-phase AC power to an MG in a system that drives a motor generator (hereinafter, "MG") that is a power source of a hybrid vehicle or an electric vehicle.

[System configuration]
First, the overall configuration of an MG drive system to which the inverter control device of each embodiment is applied will be described with reference to FIG. FIG. 1 illustrates a system comprising one MG.
The MG drive system 90 is a system that converts the DC power of the battery 11 as a “power source”, which is a chargeable / dischargeable secondary battery, into three-phase AC power by the inverter 30 and supplies it to the MG 80. In MG drive system 90, MG controller 10 mainly includes an inverter 30 and an inverter controller 50.
MG control device 10 may be applied to an MG drive system including a converter that boosts the voltage of battery 11 and outputs the boosted voltage to inverter 30. In addition, the MG control device 10 is similarly applicable to an MG drive system provided with two or more MGs.

  The MG 80 is, for example, a permanent magnet synchronous three-phase AC motor. In the present embodiment, the MG 80 has a function as an electric motor that generates a torque for driving the drive wheels of the hybrid vehicle, and a function as a generator that recovers the energy transmitted from the engine and the drive wheels by power generation.

The current path connected to the two-phase winding among the three-phase windings 81, 82 and 83 of MG 80 is provided with a current sensor for detecting a phase current. In the example of FIG. 1, current sensors 87, 88 for detecting the phase currents Iv, Iw are provided in the current paths connected to the V-phase winding 82 and the W-phase winding 83, respectively. Iu is estimated based on Kirchhoff's law. In other embodiments, any two phase current may be detected, and three phase current may be detected. Alternatively, another two-phase current estimation technique may be employed based on one-phase current detection value.
The electrical angle θe of the MG 80 is detected by, for example, a rotation angle sensor 85 such as a resolver.

  In the inverter 30, six switching elements 31 to 36 of upper and lower arms are bridge-connected. Specifically, switching elements 31, 32, and 33 are switching elements of upper arms of U phase, V phase, and W phase, respectively, and switching elements 34, 35, and 36 are below U phase, V phase, and W phase, respectively. It is a switching element of an arm. The switching elements 31 to 36 are, for example, IGBTs, and parallel connection is made of reflux diodes that allow current from the low potential side to the high potential side.

The inverter 30 converts DC power into three-phase AC power as the switching elements 31 to 36 operate according to the gate signals UU, UL, VU, VL, WU, and WL from the inverter control device 50. Then, phase voltages Vu, Vv, Vw according to the voltage command calculated by inverter control device 50 are applied to each phase winding 81, 82, 83 of MG 80. The smoothing capacitor 25 smoothes the system voltage Vsys input to the inverter 30.
The voltage sensor 37 detects a system voltage Vsys.

  The inverter control device 50 is configured by a microcomputer or the like, and internally includes a CPU, a ROM, an I / O (not shown), and a bus line connecting these components. The microcomputer executes software processing by executing a program stored in advance by the CPU and control by hardware processing by a dedicated electronic circuit.

  The inverter control device 50 acquires the system voltage Vsys detected by each sensor, the two-phase phase currents Iv and Iw, and the electrical angle θe. Further, the inverter control device 50 acquires the electrical angular velocity ω [deg / s] obtained by time-differentiating the electrical angle θe by the differentiator 86. Since the electrical angular velocity ω is converted to the number of revolutions N [rpm] by multiplying the proportional constant, “the number of revolutions obtained by converting the electrical angular velocity ω” is omitted and referred to as “the number of revolutions ω” in this specification. The differentiator 86 may be provided inside the inverter control device 50.

Further, inverter control device 50 receives torque command Trq ^* from the upper control circuit, and calculates gate signals UU, UL, VU, VL, WU, and WL for operating inverter 30 based on the information. Inverter 30 operates in response to gate signals UU, UL, VU, VL, WU and WL to operate switching elements 31-36 to convert DC power input from battery 11 into AC power and supplies it to MG80.

[Configuration and operation of inverter control device]
The configuration of inverter control device 50 will be described with reference to FIGS. 2 to 4.
FIG. 2 shows a configuration of an inverter control device 50 including a torque feedback control unit 540 and a current feedback control unit 580 as a “voltage command calculation unit” that calculates a voltage vector for instructing the inverter 30. In the figure, the "feedback control unit" is referred to as "FB control unit".

The characteristic effects and effects of the present embodiment are manifested on the premise that the voltage waveform to be output to the inverter 30 is specified by the PWM signal generated by comparing the phase voltage and the carrier wave.
As a configuration actually applied to MG drive system 90 of the hybrid vehicle, a configuration including both of torque feedback control unit 540 and current feedback control unit 580 is general, so the configuration is representative here. Will be described as a typical embodiment.

  In this configuration, the feedback method for calculating the voltage vector is switched according to the modulation factor calculated from the calculated amplitude of the voltage vector and the system voltage Vsys. That is, there are a case where torque feedback control unit 540 and current feedback control unit 580 cooperate to calculate a voltage vector, and a case where current feedback control unit 580 independently calculates a voltage vector.

  As shown in FIG. 2, the inverter control device 50 includes a dq conversion unit 51, a torque estimation unit 52, a torque subtractor 53, a controller 54, a current command calculation unit 55, a current subtractor 56, a controller 57, and a controller 58. , A voltage amplitude / phase operation unit 59, a modulator 60, a gate signal generation unit 79, and the like. Among these, the controller 57, the controller 58, and the voltage amplitude / phase calculator 59 are selectively provided according to the configuration of the above-mentioned feedback controller.

First, a configuration common to both feedback schemes will be described.
The dq conversion unit 51 converts the phase current obtained from the current sensors 87 and 88 into the dq axis current Id and Iq based on the electrical angle θe, and feeds it back to the current subtractor 56.
The current command calculation unit 55 calculates the dq-axis current commands Id ^* and Iq ^* using a map or a mathematical expression based on the torque command Trq ^{* so} that, for example, the maximum torque per current can be obtained.
The current subtractor 56 of the current feedback control unit 580 calculates current deviations ΔId and ΔIq between the dq-axis current commands Id ^* and Iq ^* and the dq-axis current Id fed back from the dq conversion unit 51.

Subsequently, a configuration in which the torque feedback control unit 540 and the current feedback control unit 580 cooperate to calculate a voltage vector will be described.
The torque estimation unit 52 calculates a torque estimated value Trq_est using the equation (1) based on the dq-axis current Id, Iq, and the motor constant of the MG 80. In a system provided with a torque sensor in the MG 80, the torque estimation unit 52 may not be provided, and a torque detection value may be acquired.
Trq_est = p × {Iq × ψ + (Ld−Lq) × Id × Iq} (1)
However,
p: MG logarithm of pole ψ: Back electromotive force constant Ld, Lq: d-axis inductance, q-axis inductance

Torque subtractor 53 of torque feedback control unit 540 calculates torque deviation ΔTrq between torque command Trq ^* and estimated torque value Trq_est. The controller 54 calculates the voltage phase φ by PI calculation so that the torque deviation ΔTrq converges to 0, and outputs the voltage phase φ to the modulator 60.
Further, the controller 57 of the current feedback control unit 580 calculates the voltage amplitude Vr by PI calculation so as to cause the current deviations ΔId and ΔIq to converge to 0, and outputs the voltage amplitude Vr to the modulator 60.

Next, a configuration in the case where the current feedback control unit 580 alone calculates a voltage vector will be described.
The controller 58 of the current feedback control unit 580 calculates dq axis voltage commands Vd ^* and Vq ^* by PI calculation so that the current deviations ΔId and ΔIq converge to zero. Voltage amplitude / phase operation unit 59 converts dq axis voltage commands Vd ^* and Vq ^* into voltage amplitude Vr and voltage phase φ, and outputs the result to modulator 601. Although FIG. 2 shows the voltage phase φ on the d axis basis, the voltage phase may be defined on the q axis basis.

Thus, the modulator 60 receives the voltage amplitude Vr and the voltage phase φ calculated by any feedback method. The modulator 60 also receives information such as the system voltage Vsys, the electrical angle θe, and the rotational speed ω.
The modulator 60 outputs at least a PWM signal as an output waveform of a pulse voltage for operating the inverter 30 based on the information. Here, the modulator 60 will be described as capable of outputting a pulse pattern or a PWM signal.

As shown in FIG. 3, the modulator 60 includes a modulation factor calculation unit 61, a method switching unit 62, and a voltage waveform identification unit 63. The voltage waveform specifying unit 63 includes a pulse pattern setting unit 64, a storage unit 65, a PWM signal generation unit 66, and a carrier frequency setting unit 67.
The modulation factor calculation unit 61 calculates the modulation factor m by Equation (2) based on the voltage amplitude Vr output from the current feedback control unit 580 and the system voltage Vsys.
m = 2 = 2 (2/3) × (Vr / Vsys) (2)

The method switching unit 62 switches the method of specifying the voltage waveform by the voltage waveform specifying unit 63 based on the modulation factor m or the like. For example, as shown in FIG. 4, the method switching unit 62 adopts the PWM method by carrier comparison when the modulation factor m is less than the predetermined value α, and adopts the pulse pattern method when the modulation factor m is the predetermined value α or more. Do.
The voltage waveform identification unit 63 identifies the voltage waveform output by the inverter 30. Specifically, a pulse pattern or a PWM signal is generated as a signal for driving the inverter 30, and is output to the gate signal generation unit 79. Gate signal generation unit 79 generates gate signals UU, UL, VU, VL, WU, and WL based on the pulse pattern or PWM signal output from modulator 60, and outputs the gate signals to switching elements 31 to 36 of inverter 30. .

Subsequently, the detailed configuration of the voltage waveform specifying unit 63 will be described.
The pulse pattern setting unit 64 selects any pulse pattern from a plurality of voltage waveforms stored in advance in the storage unit 65 as a method of specifying the voltage waveform output from the inverter 30. The pulse pattern is selected according to the modulation factor m, the rotation speed ω, and the like.
In the present specification, the pulse pattern includes a pattern that outputs a square wave of one pulse in one cycle of electricity. Typically, when the modulation factor is 1.27, a rectangular wave pulse pattern is selected. The pulse pattern other than the rectangular wave selected when the modulation factor is less than 1.27 is defined by the number of pulses per electrical cycle and the position and width of each pulse according to the modulation factor m, the number of rotations ω, etc. .

The PWM signal generation unit 66 generates a PWM signal by comparing the phase voltage calculated based on the output of the current feedback control unit 580 with the carrier wave as a method of specifying the voltage waveform output by the inverter 30. The voltage waveform which inverter 30 outputs is specified.
Specifically, the PWM signal is generated by comparing the duty converted to the phase voltage with a carrier wave such as a triangular wave. For example, sine wave PWM is used in the modulation rate range of 0 to 1.15, and overmodulation PWM is used in the modulation rate range of 1.15 to 1.27.

The carrier frequency setting unit 67 sets the frequency of the carrier used by the PWM signal generation unit 66 (hereinafter, “carrier frequency Fc”).
The carrier frequency Fc is reflected on the frequency component included in the voltage waveform of the PWM signal. Then, the switching elements 31 to 36 of the inverter 30 operate at that frequency to generate electromagnetic noise. When this frequency is included in the human audio frequency band, if the sound of the same frequency continues for a certain period of time, the user in the vicinity of the device may hear noise as noise. In particular, in the inverter control device 50 applied to the MG drive system 90 of the hybrid vehicle, there is a possibility of affecting the marketability of the vehicle.

  Therefore, the carrier wave frequency setting unit 67 of the present embodiment "spreads" the carrier wave frequency Fc in order to prevent continuous generation of the electromagnetic noise of the same frequency by the switching operation of the inverter 30. As a configuration for that, the carrier frequency setting unit 67 includes a basic frequency adjustment unit 68 and a spread frequency adjustment unit 69.

The fundamental frequency adjustment unit 68 periodically and continuously changes the fundamental frequency which is the basis of the carrier frequency Fc and a predetermined fluctuation range. In addition, about the interpretation of "continuous", it supplements in the place of "other embodiment."
The diffusion frequency adjustment unit 69 adds the diffusion frequency distributed within the range of the maximum fluctuation with respect to the fundamental frequency to the fundamental frequency at an interval shorter than the fluctuation period of the fundamental frequency.
Specific settings of the fundamental frequency and the spread frequency will be described later.

  As described above, the characteristic effects and advantages of the present embodiment appear on the premise that the voltage waveform output to the inverter 30 is specified by the PWM signal. The feature is that the carrier frequency Fc is variably adjusted by the carrier frequency setting unit 67 and the basic frequency adjustment unit 68 instead of fixing the carrier frequency Fc used for generating the PWM signal.

In short, in the modulator 60 shown in FIG. 3, when the method switching unit 62 selects the PWM method according to the modulation factor m, a characteristic effect is exhibited. In other words, the inverter control device 50 according to the present embodiment does not always need to perform control by carrier comparison, and may adjust the carrier frequency Fc variably only when performing control using a carrier under specific conditions.
The significance of having described the configuration of the inverter control device 50 including the pulse pattern setting unit 64 and the storage unit 65 that are not directly related to the characteristic effects and advantages as the representative embodiment is that this point is clearly indicated. .

Hereinafter, the detailed function and effect of the carrier wave frequency setting unit 67 will be described for each embodiment.
First Embodiment
The operation and effect of the first embodiment will be described with reference to FIG. In the first embodiment, attention is focused on the frequency Fc of a carrier wave used for generating a one-phase PWM signal.

  Here, for example, it is considered that the lower limit frequency Fm and the upper limit frequency FM of the basic frequency are fixed with respect to the change of the rotation speed ω of the MG 80. In another embodiment, the lower limit frequency Fm and the upper limit frequency FM of the basic frequency may be variable according to the rotation speed ω or the like of the MG 80. However, while the change in the rotational speed ω occurs on a relatively long time axis of several hundreds of ms to s or more, the fluctuation period Tb of the fundamental frequency is set, for example, on the order of several tens of μs to several ms. Are supposed to be Therefore, when considering the periodic fluctuation of the fundamental frequency, it may be considered that the rotational speed ω is substantially constant.

  As shown in FIG. 5A, the fundamental frequency monotonously increases with a constant positive gradient from the lower limit frequency Fm to the upper limit frequency FM. Then, when the upper limit frequency FM is reached, it is folded back and monotonously decreases to the lower limit frequency Fm with a constant negative slope obtained by inverting the slope at the time of increase. Thus, the fundamental frequency repeatedly increases and decreases periodically and continuously at the fluctuation period Tb in the fluctuation range Rb from the lower limit frequency Fm to the upper limit frequency FM.

Further, a part of FIG. 5A shows a state in which the diffusion frequency is added to the base frequency to be diffused. Although the spreading frequency is randomly added in the illustrated example, the spreading frequency may be added so as to repeat a predetermined pattern in a short cycle or a long cycle.
Thus, the spreading frequency is added to the base frequency at an interval shorter than the fluctuation period Tb of the base frequency. The PWM signal generation unit 66 generates a PWM signal by comparing the carrier wave of the frequency Fc thus obtained with the phase voltage, and specifies the output voltage waveform of the inverter 30.

As shown in FIG. 5 (b), for example, the diffusion frequency is distributed in a positive and negative symmetrical mountain shape in a diffusion range Rsp within the maximum fluctuation ± ΔF with respect to the fundamental frequency Fb. That is, the frequency of the fundamental frequency Fb is the highest, and the frequency decreases as the fluctuation from the fundamental frequency Fb increases. The frequency at the frequency having the upper limit fluctuation + ΔF and the lower limit fluctuation −ΔF converges to zero.
The variation Δf from the base frequency Fb at an arbitrary frequency within the diffusion range Rsp is expressed by equation (3) using a coefficient k (-1 ≦ k ≦ 1).
Δf = k × ΔF (3)
Further, as in equation (4), the width of the diffusion range Rsp is twice the one-sided maximum fluctuation amount ΔF.
Rsp = 2ΔF (4)

Here, as shown in FIG. 5A, the diffusion range Rsp is set smaller than the fluctuation range Rb of the fundamental frequency. That is, with respect to the fluctuation of the carrier frequency Fc, the periodic fluctuation of the fundamental frequency mainly contributes, and the diffusion by the spreading frequency additionally contributes.
By adding the spreading frequency around the periodically changing base frequency, the carrier frequency Fc fluctuates in the range of the lower limit Fm and the upper limit FM of the base frequency plus the maximum variation ± ΔF of the spreading frequency. Thus, the carrier frequency Fc fluctuates in the range of (Fm−ΔF) to (FM + ΔF).

Therefore, as shown in FIG. 5C, the frequency distribution of the carrier frequency Fc is constant in the range from the lower limit Fm to the upper limit FM of the fundamental frequency, and further, in the range from the lower limit Fm to the upper limit FM, The distribution with the maximum fluctuation ± ΔF of the diffusion frequency is added.
The frequency distribution of the carrier frequency Fc is a distribution of frequency components included in the voltage waveform of the PWM signal. As a result, for example, it is reflected in the frequency characteristic of the spectrum amplitude obtained by subjecting the inverter bus current to fast Fourier transform. In addition, the frequency distribution of the carrier frequency Fc affects the generation of the electromagnetic noise due to the operation of the inverter 30.

(effect)
(1) The effects of the present embodiment will be described in comparison with the prior art.
The prior art disclosed in Patent Documents 1 and 2 (Japanese Patent No. 4974457, Japanese Patent No. 5121895) is shown in FIG. In the prior art, the carrier frequency Fc is calculated by adding the diffusion frequency (ΔFc × k1) obtained by multiplying the basic carrier frequency Fc0 by the maximum variation ΔFc and the coefficient k1 by the equation (5).
Fc = Fc0 + ΔFc × k1 (5)

  In the prior art of Patent Documents 1 and 2, when the basic carrier frequency Fc0 is constant, the fluctuation of the diffusion frequency becomes the fluctuation of the carrier frequency Fc as it is. Further, the change of the coefficient k1 is set at random, and if the coefficient k1 changes at once from the lower limit "-1" to the upper limit "+1", the carrier frequency Fc is a difference of twice the maximum fluctuation .DELTA.Fc. It changes rapidly.

Therefore, as shown in FIG. 10A, if the maximum variation ΔFc is set relatively large to sufficiently spread the carrier frequency Fc, the output voltage of the inverter suddenly changes depending on the variation of the coefficient k1, May become unstable.
On the other hand, as shown in FIG. 10 (b), when the maximum fluctuation ΔFc is set relatively small, the carrier frequency Fc is not sufficiently diffused, and noise due to electromagnetic noise can not be reduced.

On the other hand, in the present embodiment, the carrier frequency Fc is set by the periodically changing base frequency and the spreading frequency added to the base frequency at an interval shorter than the fluctuation period Tb of the base frequency. The periodically and continuously changing fundamental frequency leads the frequency spread, and the spread frequency further has an auxiliary spreading function.
Therefore, in the present embodiment, since it is not necessary to set the maximum fluctuation of the diffusion frequency to a particularly large value in order to reduce noise due to electromagnetic noise, sudden change of the carrier frequency Fc due to the fluctuation of the diffusion frequency can be prevented. . Therefore, the inverter control device 50 can appropriately achieve both improvement of control stability and reduction of noise due to electromagnetic noise.

(2) In the present embodiment, the diffusion range Rsp in which the diffusion frequency is distributed is set smaller than the fluctuation range Rb of the fundamental frequency. As a result, sudden changes in the carrier frequency Fc due to the diffusion component can be prevented, and control stability can be improved.
(3) In the present embodiment, the fundamental frequency adjustment unit 68 monotonously increases or monotonically decreases the fundamental frequency in the fluctuation range Rb of the fundamental frequency. As a result, sudden changes in the carrier frequency Fc can be further prevented, and control stability can be further improved.
Furthermore, the fundamental frequency adjustment unit 68 may limit the time change rate of monotonous increase or monotonous decrease of the fundamental frequency.

Second Embodiment
The second embodiment will be described with reference to FIG. In the second embodiment, it is assumed that the inverter 30 is a three-phase inverter, and the basic frequency adjustment unit 68 reduces the fluctuation period Tb of the basic frequency by 1 / n of one electrical cycle of the inverter output voltage (n is a natural number) It is set to).

  FIG. 6 shows an example in which n = 3, that is, the fluctuation period Tb of the base frequency is set to one ninth of one electric period. The horizontal axis in FIG. 6 represents an electrical angle based on a phase at which the amplitude of the U-phase voltage Vu crosses zero from positive to positive. That is, the amplitudes of the U-phase voltage Vu, the V-phase pressure Vv, and the W-phase pressure Vw zero-cross from negative to positive at electrical angles 0, 120, and 240 [deg E], respectively. In addition, the voltage amplitudes of the respective phases zero-cross from positive to negative at electrical angles 180, 300 and 420 [deg E], respectively.

Here, by setting the fluctuation period Tb at an interval of 40 [deg E] equivalent to one-ninth of one electric period, in each phase where the voltage amplitude of each phase crosses from negative to positive, the base frequency is lower limit in all cases. The fundamental frequency becomes the upper limit frequency FM in any phase where the frequency Fm becomes a frequency and each phase voltage amplitude crosses from positive to negative zero. Therefore, the symmetry between the three phases can be secured for the periodic fluctuation of the fundamental frequency. As a result, the current offset can be suppressed and control stability can be improved.
In general, for an M-phase inverter of three or more phases, the basic frequency adjustment unit 68 sets the fluctuation period Tb of the basic frequency to "one (M × n) (n is a natural number)" of the electrical cycle of the inverter output voltage Is preferred.

Third Embodiment
The third embodiment will be described with reference to FIG. In the third embodiment, it is assumed that the inverter 30 is a multiphase inverter of three or more phases, and the basic frequency adjustment unit 68 is set so as to avoid overlapping of the fluctuation ranges Rb of the basic frequency of each phase. . In other words, the fundamental frequency adjustment unit 68 adjusts independently to disperse the variation range Rb of the fundamental frequency of each phase.

As shown in FIG. 7A, for example, with respect to the fluctuation range Rbv of the base frequency for identifying the V-phase voltage waveform, the fluctuation ranges Rbu and Rbw of the base frequency for identifying the voltage waveform of the U phase and the W phase are respectively low. The frequency side and the high frequency side are dispersedly set so as not to overlap each other.
FIG. 7 (b) is based on the frequency distribution of the carrier frequency Fc when the variation range Rb of the base frequency for specifying the voltage waveform of three phases is the same or a voltage waveform generated using the carrier frequency Fc. The amplitude of the inverter current spectrum is shown in broken lines. In this case, since the amplitude of the inverter current spectrum is concentrated in a specific frequency range, the sound pressure of the electromagnetic sound becomes large.

On the other hand, in the third embodiment, the amplitude of the inverter current spectrum based on the voltage waveform generated by using the carrier frequency obtained by spreading the fundamental frequency by dispersing the variation range Rb of the fundamental frequency of each phase is dispersed. It can be reduced.
Thereby, the sound pressure of the electromagnetic sound of the inverter 30 can be reduced.

(Other embodiments)
(A) The periodic function defining the periodic fluctuation of the fundamental frequency is not limited to the one having a triangular wave shape linearly increasing or decreasing with respect to the time axis as shown in FIGS. 5 (a) and 7 (a). In addition, for example, as shown in FIGS. 8A and 8B, a sine wave, a semi-elliptic, or a cycloid may be used. In these examples, the fundamental frequencies are both periodically and continuously changing. In addition, it monotonously increases from the lower limit frequency Fm to the upper limit frequency FM, and monotonously decreases from the upper limit frequency FM to the lower limit frequency Fm. Further, in another embodiment, not only the monotonous increase or the monotonous decrease, but a single change cycle Tb may be repeated a plurality of times of increase and decrease in the change range Rb. By finely adjusting the shape of the periodic function in this manner, it may be possible to make the electromagnetic sound more difficult to hear.

Further, FIG. 8C shows a periodic function that increases and decreases stepwise. Here, the periodic function of the triangular wave shape illustrated by straight lines in FIG. 5A and FIG. 7A also increases and decreases stepwise in the minimum control unit according to the resolution of the device.
However, the example shown in FIG. 8C does not mean the step at the minimum control unit level, but is in the order larger than the minimum control unit and at the step smaller in size than the fluctuation range Rb of the fundamental frequency. is there.

A step change of this size is then interpreted as being included in the "continuously changing" specified for the fundamental frequency in the claims. That is, the configuration using the fundamental frequency defined by the periodic function in FIG. 8C corresponds to “a mode for carrying out the invention described in the claims”.
In short, the term "continuous" specifying the change of the fundamental frequency in the claims is interpreted on the basis of the fluctuation range Rb of the fundamental frequency in view of the problem to be solved by the present invention of "improving control stability". Is appropriate.

For example, it is assumed that the sawtooth wave changes in the range from the lower limit frequency Fm of the fluctuation range Rb to the upper limit frequency FM. When the sawtooth wave rises, the frequency increases linearly, and at the same time reaching the upper limit frequency FM, the frequency immediately drops to the lower limit frequency Fm. Thus, the step change which changes the frequency difference from the lower limit frequency Fm of the fluctuation range Rb to the upper limit frequency FM in one step is a "discontinuous" change. In the configuration in which the fundamental frequency fluctuates in a sawtooth shape, that is, periodically and discontinuously, the problem of “improving control stability” can not be achieved, and thus is excluded from the present invention.
In contrast, in the configuration in which the base frequency changes stepwise at a small level with respect to the fluctuation range Rb, the effect of improving control stability is not affected. Thus, the present invention considers such relatively small step changes as "continuous" changes, including changes at the minimum control unit level.

  (B) The diffusion frequency may be discretely specified for the diffusion frequency coefficient k by a distribution table as shown in FIG. 9 in place of the distribution curve shown in FIG. 5 (b). In this table, the frequency corresponding to the coefficient k is defined so that the sum becomes 100% symmetrically between the positive region and the negative region, with the frequency when the coefficient k is 0 as the maximum value. For example, the frequency at k = 1.0 is 2%, and the frequency at k = (− 0.4) is 10%.

  By the way, it is considered that the distribution curve shown in FIG. 5 (b) is strictly equivalent to defining a discrete table at the minimum interval according to the resolution of the apparatus. However, the example shown in FIG. 9 is intended to discretely define the frequency corresponding to the coefficient k at an interval sufficiently larger than the minimum interval according to the resolution. As a result, it is possible to reduce the operation load associated with the generation of the diffusion frequency.

(C) In the above embodiment, the diffusion range Rsp of the diffusion frequency is set smaller than the fluctuation range Rb of the base frequency to prevent the sudden change of the carrier frequency Fc due to the diffusion component. However, it is also possible to set the diffusion range Rsp larger than the fluctuation range Rb, for example, by limiting the amount of one change of the diffusion frequency.
(D) The frequency distribution of the diffusion frequency is not limited to the example in which the distribution is symmetrical in the positive and negative directions with respect to the fundamental frequency Fb as shown in FIG. 5B, but may be asymmetric with respect to the fundamental frequency Fb. The same applies to FIG.

(E) The inverter control device of the present invention may be any device that generates an inverter output voltage by PWM control that compares a phase voltage with a carrier wave, regardless of the type of load of the inverter. Therefore, the inverter control device of the present invention is not limited to the MG drive system of a hybrid vehicle or an electric vehicle, and may be applied to a motor for general machinery and a system for driving a load other than the motor.
As mentioned above, the present invention is not limited to the above-mentioned embodiment at all, and can be implemented in various forms in the range which does not deviate from the meaning of an invention.

11 ... battery (power supply),
30 · · · inverter, 31-36 · · · switching element,
50 ・ ・ ・ Inverter control device,
580 ... current feedback control unit (voltage command calculation unit),
66: PWM signal generator,
67 ··· Carrier frequency setting unit,
68 · · · Basic frequency adjustment section,
69 ··· Diffusion frequency adjustment unit,
80 ... MG (AC motor).

Claims (6)

An inverter control device for controlling an inverter (30) that converts direct current power input from a power supply (11) into alternating current power by operation of a plurality of switching elements (31 to 36).
A voltage command calculation unit (580) for calculating a voltage vector to be commanded to the inverter;
A PWM signal generation unit (66) which compares a phase voltage with a carrier wave and generates a PWM signal as a method of specifying a voltage waveform output from the inverter;
A carrier frequency setting unit (67) for setting a carrier frequency (Fc) used by the PWM signal generation unit;
Equipped with
The carrier frequency setting unit
A base frequency adjusting section (68) for periodically and continuously changing a base frequency which is a base of the carrier frequency in a predetermined fluctuation range (Tb);
And a spread frequency adjustment unit (69) for adding spread frequencies distributed within a range of maximum fluctuation (± ΔF) with respect to the base frequency to the base frequency at intervals shorter than a change period (Tb) of the base frequency ,
An inverter controller characterized by having.   The inverter control device according to claim 1, wherein a diffusion range (Rsp) in which the diffusion frequency is distributed is set smaller than a fluctuation range of the base frequency. The basic frequency adjustment unit
The inverter control device according to claim 1 or 2, wherein the base frequency is monotonously increased from the lower limit frequency (Fm) to the upper limit frequency (FM) of the variation range, and monotonously decreased from the upper limit frequency to the lower limit frequency. The basic frequency adjustment unit
The variation period (Tb) of the basic frequency is set to one (M × n) (N is a natural number) one electrical cycle of the output voltage of the inverter for M-phase inverters of three or more phases. The inverter control apparatus as described in any one of 3. The basic frequency adjustment unit
The multi-phase inverter of three or more phases is set so as to avoid overlapping of the fluctuation ranges (Rbu, Rbv, Rbw) of the basic frequency used for specifying each phase voltage waveform. The inverter control device according to one aspect. A pulse pattern setting unit (64) for selecting one of a plurality of pulse patterns stored in advance as a method of specifying a voltage waveform output from the inverter;
A method switching unit (62) for switching a method of specifying a voltage waveform by the PWM signal generation unit or the pulse pattern setting unit;
The inverter control device according to any one of claims 1 to 5, further comprising:

Images