JP2004350459A - Control unit of induction motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a controller for an induction motor capable of detecting, with high accuracy and sufficient rapidity, the rotational frequency and rotational direction of the induction motor under a free running condition by shortening required detection time. <P>SOLUTION: A current control loop is constituted on two fixed coordinates orthogonal to each other. When the induction motor 1 is under a running condition, a current command value for frequency detection is given, and a pulse signal superimposed with a current feedback value on the fixed coordinates is extracted. The pulse signal is converted on a rotating coordinates with a predetermined coordinate rotating frequency and the frequency of the pulse signal on the rotating coordinates is detected, thus determining the free-running rotational frequency and rotational direction. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

上記式（３２）（３３）、および図１１、図１２で示すように、αβ軸上で捉えた電流帰還値ｉα、ｉβは、座標回転周波数ｗ＿ａｘの正弦波となる主成分が支配的であるが、実際のｉα、ｉβには、フリーラン周波数と一定の比例関係にある周波数ｗ＿ｍで脈動する微小な脈動成分が重畳する。これは、誘導電動機１が回転周波数でピークをもつインピーダンス特性を有しているため、電流指令値をステップ状に与えるショックが電流制御ループに印加されることによって電流および電圧指令値に脈動信号が誘起されるためである。
【００３９】
この脈動成分が、上記式（２０）（２１）によって周波数ｗ＿ａｘ（この場合−３０［Ｈｚ］）で回転する回転座標系へ変換される結果、回転座標上の電流帰還値ｉγ、ｉδは、図１１、図１２に示すように、電流指令値ｉγ＿ｒｅｆ、ｉδ＿ｒｅｆに、周波数が（ｗ＿ｍ−ｗ＿ａｘ）、この場合、正転時３５［Ｈｚ］，逆転時２５［Ｈｚ］の脈動成分が重畳した波形となる。すなわち、電流制御誤差ｅｒｒ＿ｉγ、ｅｒｒ＿ｉδが電力状態量脈動信号Ｘγ、Ｘδとなり、図に示す波形となる。
なお、この脈動信号Ｘγ、Ｘδの収束性は、電流ＰＩ制御手段１０１の比例ゲインＫｐおよび積分ゲインＫｉにて操作することが可能である。
【００４０】
このようにして発生する、回転座標上の脈動成分Ｘγ、Ｘδ、すなわち電流制御誤差ｅｒｒ＿ｉγ、ｅｒｒ＿ｉδのいずれか一方、あるいは双方をフリーラン回転周波数検出手段３ｂに出力する。
このような回転座標上の脈動信号Ｘγ、Ｘδのいずれか一方あるいは双方を脈動周波数検出手段２１に入力し、符号が反転する回数をカウントすることで、脈動信号Ｘγ、Ｘδの周波数ｗ＿γδを算出する。具体的には、脈動計測期間をＴ［ｓｅｃ］、この期間中の符号反転の回数Ｎを脈動周波数検出手段２１にて計測し、上記実施の形態と同様の以下の式により算出する。
ｗ＿γδ＝（Ｎ−１）／（２・Ｔ）［Ｈｚ］ …（１０）
この後、脈動信号Ｘγ、Ｘδの周波数ｗ＿γδに対し、加減算手段２２にて、以下の式により、固定子座標上の２軸であるαβ軸上の脈動信号Ｘα、Ｘβの周波数ｗ＿ｍを算出する。
ｗ＿ｍ＝ｗ＿γδ＋ｗ＿ａｘ［Ｈｚ］ …（１１）
【００４１】
この実施の形態では、回転座標軸上で電流制御ループを構成して、回転座標上の脈動信号Ｘγ、Ｘδの周波数ｗ＿γδを計測する。脈動信号Ｘγ、Ｘδの周波数ｗ＿γδは、上記実施の形態１と同様に、フリーラン周波数と一定の比例関係にある固定子αβ軸上の脈動信号Ｘα、Ｘβの周波数ｗ＿ｍに対して、座標回転周波数ｗ＿ａｘが加算された値となっている。このため、誘導電動機が低速域であっても高い周波数領域に変換して脈動周波数が計測可能となり、検出精度を低下することなく周波数検出が大幅に高速化できる。また、脈動信号の位相差を検出する必要がなく、加減算手段２２にて上記の式（１１）の演算処理のみによって回転方向判別が可能となるため、容易にフリーラン状態の誘導電動機の回転方向の判別が行える。また、低速域においても、計測時間を短縮しつつ信頼性良く回転方向判別が行える。
さらに、フィードフォワード電圧演算手段１０２を備えて、座標回転周波数の誘起電圧により発生する信号成分をキャンセルするようにしたため、フリーラン周波数に関係して脈動する信号のみを信頼性良く抽出して周波数を検出できるため、フリーラン周波数の検出が信頼性良く高精度に行える。
【００４２】
実施の形態６．
次に、この発明の実施の形態６による誘導電動機の制御装置について説明する。図１３は、この発明の実施の形態６による誘導電動機の制御装置の構成を示すブロック図である。
この実施の形態６では、上記図９で示した実施の形態５の構成に対し、電力変換手段２ｆ内の電力状態量制御手段１２ｆの内部に、回転座標上の脈動信号Ｘγ、Ｘδを生成するためのフィルタ手段３４を設ける。
上記実施の形態５では、回転座標上の脈動成分Ｘγ、Ｘδとして電流制御誤差ｅｒｒ＿ｉγ、ｅｒｒ＿ｉδのいずれか一方、あるいは双方をフリーラン回転周波数検出手段３ｂに出力したが、この実施の形態では、電圧指令値と電流帰還値の少なくともどちらか一方の情報に基づいてフィルタ手段３４によりフィルタ処理を行う。これによりフリーラン回転周波数検出手段３ｂの処理に対して外乱となる情報を除去した脈動信号Ｘγ、Ｘδを生成することができる。
【００４３】
フィルタ手段３４の一例として、バンドパス処理と増幅処理を挙げる。フィルタ手段３４では、以下の式（３４）（３５）どちらかの演算を行い、回転座標上の脈動成分Ｘγ、Ｘδとして、どちらか一方をフリーラン回転周波数検出手段３ｂに出力する。
Ｘγ＝Ｋｂｐｆ・（ｓ／（ｓ＋ｗａ））・（ｗｂ／（ｓ＋ｗｂ））・ｉγ …（３４）
Ｘδ＝Ｋｂｐｆ・（ｓ／（ｓ＋ｗａ））・（ｗｂ／（ｓ＋ｗｂ））・ｉδ …（３５）
（ラプラス変換表記）
ただし、Ｋｂｐｆは脈動増幅ゲイン、ｗａは低域遮断周波数、ｗｂは高域遮断周波数であり、脈動を増幅させたい周波数帯域と増幅利得に応じて設定する。
【００４４】
このように得られる脈動成分Ｘγ、Ｘδをフリーラン回転周波数検出手段３ｂに出力することで、上記実施の形態５と同様の効果を得ることができる。即ち、この実施の形態においても、誘導電動機が低速域であっても高い周波数領域に変換して脈動周波数が計測可能となり、検出精度を低下することなく周波数検出が大幅に高速化できる。また、脈動信号の位相差を検出する必要がなく、加減算手段２２での演算処理のみによって回転方向判別が可能となるため、容易にフリーラン状態の誘導電動機の回転方向の判別が行える。また、低速域においても、計測時間を短縮しつつ信頼性良く回転方向判別が行える。
また、上記式（３４）（３５）で算出される脈動成分Ｘγ、Ｘδは、回転座標上の電流帰還値ｉγ、ｉδに対して直流オフセット、高周波ノイズが除去された脈動波形となっているため、脈動周波数検出手段２１における０クロス検知の精度が向上し周波数の検出が高精度に行える。
なお、所望のバンドパス・増幅処理を行えるのであれば、如何なるフィルタ処理を用いても良く、例えばさらに遮断特性が良好な高次数のバンドパスフィルタを用いるなどしても良い。
【００４５】
実施の形態７．
次に、この発明の実施の形態７による誘導電動機の制御装置について説明する。図１４は、この発明の実施の形態７による誘導電動機の制御装置の構成を示すブロック図である。
この実施の形態７では、上記図９で示した実施の形態５の構成に対し、電力変換手段２ｇ内の電力状態量制御手段１２ｇの内部に、電流脈動発振のために自励発振用の電圧発生手段３５ｂ、および加算手段３６を設ける。
電流指令値生成手段３１ｂからフリーラン周波数検出用に、電流制御ループに対してインパルス状の電流指令値を印加したときに、上記実施の形態５で説明したように、電流制御ループの制御信号に脈動信号が重畳するが、その脈動信号を電圧発生手段３５ｂによって発振、増幅させる。この発振、増幅された電流脈動を得て電力状態量脈動信号Ｘγ、Ｘδとし、これらをフリーラン回転周波数検出手段３ｂへ出力する。
【００４６】
この実施の形態においても、上記実施の形態５と同様の効果を得ることができる。すなわち、誘導電動機が低速域であっても高い周波数領域に変換して脈動周波数が計測可能となり、検出精度を低下することなく周波数検出が大幅に高速化できる。また、脈動信号の位相差を検出する必要がなく、加減算手段２２での演算処理のみによって回転方向判別が可能となるため、容易にフリーラン状態の誘導電動機の回転方向の判別が行える。また、低速域においても、計測時間を短縮しつつ信頼性良く回転方向判別が行える。
また、電圧発生手段３５ｂによって脈動信号の減衰が抑制されて、脈動を持続させる効果が得られているため、脈動周波数検出手段２１において回転座標上の脈動信号Ｘγ、Ｘδの周波数を計測する際に、０クロス検知の精度が向上する効果が得られる。
【００４７】
【発明の効果】
以上のように、この発明に係る誘導電動機の制御装置は、誘導電動機に交流電力を供給する電力変換器と、該電力変換器の出力電流を検出する検出器と、該検出器にて検出された３相の電流を固定子座標上の直交した２軸上に座標変換した電流帰還値が該２軸上で与えられた電流指令値に一致するように電圧指令値を生成して上記電力変換器を制御する電力状態量制御手段とを備えて、上記誘導電動機を電流制御する。そして、上記電流指令値として上記誘導電動機の周波数を検出するための所定の指令値を与えたときに、上記電力状態量制御手段の上記２軸上の制御信号に発生する脈動成分を抽出し第１の電力状態量脈動信号を生成する電力状態量脈動信号検出手段と、上記第１の電力状態量脈動信号を所定の回転周波数を有する回転座標上の第２の電力状態量脈動信号に変換する回転座標変換手段と、上記第２の電力状態量脈動信号の周波数を検出する周波数検出手段とを備え、上記検出周波数と上記回転周波数とに基づいて、フリーラン状態にある上記誘導電動機の周波数及び回転方向を求めるものである。このため、誘導電動機が低速域であっても高い周波数領域に変換して脈動周波数の計測が可能となり、検出精度を低下することなく周波数検出が大幅に高速化できる。また、脈動信号の位相差を検出する必要がなく、容易で信頼性良くフリーラン状態の誘導電動機の回転方向の判別が行える。
【図面の簡単な説明】
【図１】この発明の実施の形態１による誘導電動機の制御装置の構成を示すブロック図である。
【図２】この発明の実施の形態１による誘導電動機の制御装置の動作を説明する制御信号波形である。
【図３】この発明の実施の形態１による誘導電動機の制御装置の動作を説明する制御信号波形である。
【図４】この発明の実施の形態２による誘導電動機の制御装置の構成を示すブロック図である。
【図５】この発明の実施の形態３による誘導電動機の制御装置の構成を示すブロック図である。
【図６】この発明の実施の形態４による誘導電動機の制御装置の構成を示すブロック図である。
【図７】この発明の実施の形態４による誘導電動機の制御装置の動作を説明する制御信号波形である。
【図８】この発明の実施の形態４による誘導電動機の制御装置の動作を説明する制御信号波形である。
【図９】この発明の実施の形態５による誘導電動機の制御装置の構成を示すブロック図である。
【図１０】この発明の実施の形態５による誘導電動機の制御装置の部分構成を示すブロック図である。
【図１１】この発明の実施の形態５による誘導電動機の制御装置の動作を説明する制御信号波形である。
【図１２】この発明の実施の形態５による誘導電動機の制御装置の動作を説明する制御信号波形である。
【図１３】この発明の実施の形態６による誘導電動機の制御装置の構成を示すブロック図である。
【図１４】この発明の実施の形態７による誘導電動機の制御装置の構成を示すブロック図である。
【符号の説明】
１ 誘導電動機、３ａ，３ｂ フリーラン回転周波数検出手段、
１０ 電力変換器、１１ 電流検出手段、
１２ａ〜１２ｇ 電力状態量制御手段、１３ 電圧座標変換手段、
１４ 電流座標変換手段、２１ 脈動周波数検出手段、２３ 座標変換手段、
３１ａ，３１ｂ 電流指令値生成手段、３２ａ，３２ｂ 電流制御手段、
３３ 脈動検出手段、３４ 脈動信号検出手段としてのフィルタ手段、
３５ａ，３５ｂ 電圧発生手段、３６ 加算手段、αβ 固定子座標上の２軸、
γδ 回転座標上の２軸、Ｘα，Ｘβ 固定座標系脈動信号、
Ｘγ，Ｘδ 回転座標系脈動信号。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a control device for controlling an induction motor without using a speed sensor, and more particularly to a frequency detection of an induction motor in a free-run state.
[0002]
[Prior art]
If the inverter device is stopped due to a momentary power failure and then restarted due to power recovery, or if the inverter device is stopped and starts from a state in which the induction motor is rotating freely due to external force, the induction in the free-run state It is necessary to make the rotation frequency (free-run frequency) of the electric motor substantially equal to the output frequency of the inverter device and accelerate again.
A conventional method for detecting a free-run state of an induction motor detects a three-phase output current outside the inverter, converts the current into a two-phase coordinate axis system that is orthogonal, and converts the output current of the inverter unit to match the two-phase current command. A control signal system for controlling is provided, and when the induction motor is in a free-run state, a constant command signal is output from the current command unit to extract a ripple component generated in the control signal system. The free-run frequency of the induction motor is proportional to the ripple frequency of the ripple component, and the free-run frequency is obtained by obtaining the ripple frequency. Further, the rotation direction of the induction motor is determined by detecting the phase difference between the two-phase ripple components (for example, see Patent Document 1). In addition, in the conventional induction motor control device, a voltage generator for self-excited oscillation is provided, the primary current of the induction motor is self-excited, and the frequency of the self-oscillated primary current is detected. To calculate the rotation speed information of the induction motor (for example, see Patent Document 2).
[0003]
[Patent Document 1]
JP-A-3-3694 (pages 1-8)
[Patent Document 2]
JP-A-11-346500 (pages 2, 6-9, FIG. 1)
[0004]
[Problems to be solved by the invention]
In the free-run state detection by the conventional induction motor control device, a pulsation signal of a voltage command value or a current value is extracted, and then the frequency of the pulsation signal is detected to calculate a free-run frequency. The detection of the frequency of the pulsation signal is performed by counting the timing at which the sign of the pulsation signal is inverted. However, when the frequency of the pulsation signal is low, there is a problem that the time to reach the predetermined count becomes long.
For example, when the frequency is 5 [Hz], the time required for detecting the sign reversal of seven points (for three cycles) is 0.6 [sec]. Immediately after the application of the current command value, a count standby time is provided for the purpose of avoiding erroneous counting due to transient vibration, so that the required time is further increased. If the predetermined count is reduced, the time can be shortened. However, the frequency detection accuracy is reduced, and the number of times of detecting the phase difference between the two-phase pulsation components for determining the rotation direction is also reduced. In addition, the accuracy of discriminating the rotation direction also decreases.
[0005]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and it is possible to quickly and accurately detect the rotation frequency and rotation direction of an induction motor in a free-run state by shortening a time required for detection. The purpose is to detect.
[0006]
[Means for Solving the Problems]
A control device for an induction motor according to the present invention includes a power converter for supplying AC power to the induction motor, a detector for detecting an output current of the power converter, and a three-phase current detected by the detector. Is used to control the power converter by generating a voltage command value such that a current feedback value obtained by converting the coordinate on two orthogonal axes on the stator coordinates matches a current command value given on the two axes And a current control means for controlling the current of the induction motor. Then, when a predetermined command value for detecting the frequency of the induction motor is given as the current command value, a pulsation component generated in the control signal on the two axes of the power state quantity control means is extracted and Power state quantity pulsation signal detecting means for generating one power state quantity pulsation signal, and converting the first power state quantity pulsation signal into a second power state quantity pulsation signal on a rotating coordinate having a predetermined rotation frequency. Rotating coordinate conversion means, frequency detecting means for detecting the frequency of the second power state quantity pulsation signal, based on the detected frequency and the rotation frequency, the frequency of the induction motor in a free-run state and The direction of rotation is determined.
[0007]
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiment 1 FIG.
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 1 of the present invention. As shown in the figure, the control device of the induction motor 1 includes a power conversion unit 2a and a free-run rotation frequency detection unit 3a.
The power conversion unit 2a includes a power converter 10, a current detection unit 11, and a power state quantity control unit 12a, which are main circuits. Further, the power state quantity control unit 12a includes a current command value generation unit 31a and a current control unit 32a. The free-running rotational frequency detecting means 3a includes a pulsating frequency detecting means 21, an adding / subtracting means 22, and a coordinate converting means 23 as a rotating coordinate converting means.
[0008]
Next, the operation will be described.
First, the operation of the power conversion means 2a, particularly, the control operation by the current control loop will be described. The power conversion unit 2a forms a current control loop with the current control unit 32a, the power converter 10, the current detection unit 11, and the induction motor 1, and the primary current value of the induction motor 1, which is a current feedback value, corresponds to the current command. The current control unit 32a controls the power converter 10 by outputting a voltage command value so as to match the current command value output from the value generation unit 31a.
Here, the current command value, the voltage command value, and the current feedback value are given on two orthogonal axes (αβ axes) on the stator coordinates.
The current detecting means 11 calculates a current feedback value on the αβ axis by the following formulas (1) and (2) with respect to three-phase current values iu, iv, and iw obtained by detecting an actual current with a current detector such as a current sensor. The coordinates are converted into iα and iβ and output to the power state quantity control means 12a.
iα = (2/3) ^-1 -(Iu- (1/2) -iv- (1/2) -iw) ... (1)
iβ = (1/2) ^-(1/2) ・ Iw- (1/2) ^-(1/2) ・ Iv… (2)
[0009]
In the power state quantity control unit 12a, the current control unit 32a receives the current command values iα_ref and iβ_ref on the αβ axis and the current feedback values iα and iβ output from the current command value generation unit 31a as inputs, and uses the following equation (3). ) The voltage command values vα_ref and vβ_ref on the αβ axis are calculated by (4). Here, Kp and Ki are a proportional gain constant and an integral gain constant that determine the response of current control, and s is a Laplace operator.
vα_ref = (Kp + (Ki / s)) · (iα_ref−iα) (3)
vβ_ref = (Kp + (Ki / s)) · (iβ_ref−iβ) (4)
The voltage command values vα_ref and vβ_ref on the αβ axis are output to power converter 10. The power converter 10 outputs an actual voltage vector based on the input voltage command values vα_ref and vβ_ref on the αβ axis to the induction motor 1. For example, when a voltage-type inverter is used for the power converter 10, the voltage command values vα_ref and vβ_ref on the αβ axis are converted into three-phase waveforms, and then the arithmetic processing is performed to generate a switching pattern of the three-phase inverter. By inputting the switching pattern to the control input of the inverter, the pulse width modulated three-phase voltage is supplied to the induction motor 1.
In this way, the current control loop controls the current feedback values iα and iβ on the αβ axis to follow the αβ axis current command values iα_ref and iβ_ref output by the current command value generating means 31a.
[0010]
Next, current control for detecting the rotation frequency of the induction motor 1 when the power is not supplied from the power conversion means 2a to the induction motor 1 due to the occurrence of an instantaneous power failure, that is, when the induction motor 1 is in the free-run state. The operation of the loop will be described.
FIGS. 2 and 3 show signal waveforms on the αβ axis and the rotating coordinates (γδ axis) when detecting the rotation frequency of the induction motor 1 in the free-run state in forward rotation and reverse rotation, respectively. Here, in a situation where the free-run frequency of the induction motor 1 is rotating forward or backward at 5 [Hz], the DC current command value is stepwise changed from the current command value generation means 31a for free-run frequency detection. The signal waveform at the time of output is shown, which is given as α-axis current command value iα_ref = I0 (DC value) and given as β-axis current command value iβ_ref = 0.
As shown in FIGS. 2 and 3, by the function of the current control loop described above, the average value of the current feedback values iα and iβ on the αβ axis is changed to the average value on the αβ axis output from the current command value generation means 32a. Control is performed so as to follow the current command values iα_ref = I0 and iβ_ref = 0, but a pulsation signal having a frequency proportional to the free-run frequency appears in a signal waveform of the current feedback values iα and iβ. This is because the induction motor 1 has an impedance characteristic having a peak in the rotation frequency, and the shock that gives the current command value in a step-like manner is applied to the current control loop to change the current and voltage command values. Vibration is induced. The continuity of the vibration is related to the circuit constant of the induction motor, but can be operated by the value of the gain of the current control means 32a. For convenience, in FIGS. 2 and 3, the frequency of the pulsation signal on the αβ axis superimposed on the current feedback values iα and iβ is 5 [Hz], which is the same as the free-run frequency.
[0011]
The pulsation signals on the αβ axis superimposed on the current feedback values iα and iβ, which are control signals on the αβ axis of the power state quantity control means 12a, are referred to as first power state quantity pulsation signals Xα and Xβ. The operation of detecting the free-run frequency of the induction motor 1 based on the pulsation signals Xα and Xβ will be described.
As shown in FIG. 1, current control errors in the power state quantity control means 12a are extracted as pulsation signals Xα and Xβ, and output to the free-run rotation frequency detection means 3a. The pulsation signals Xα and Xβ are generated by the following equations (5) and (6).
Xα = iα_ref−ia (5)
Xβ = iβ_ref−iβ (6)
[0012]
The free-run rotation frequency detection means 3a rotates the pulsation signals Xα and Xβ on the stator αβ axis input from the power conversion means 2a at a predetermined coordinate rotation frequency w_ax [rad / sec] by the coordinate conversion means 23. Coordinate conversion is performed on the orthogonal two-axis γδ-axis coordinates, which are rotation coordinates, and pulsation signals Xγ and Xδ are generated as second power state quantity pulsation signals. Then, the frequencies of the pulsation signals Xγ and Xδ are measured by the pulsation frequency detection means 21. The method of measuring the frequency of the pulsation signal itself is the same as the conventional one, and the frequency is calculated by counting the number of zero crossings of the pulsation waveform within a certain period.
The addition and subtraction means 22 adds the coordinate rotation frequency w_ax of the rotation coordinate system to the frequency of the pulsation signals Xγ and Xδ of the power state quantity on the rotation coordinate obtained in this way, so that the two axes on the stator coordinate are obtained. The frequencies of the pulsation signals Xα and Xβ on the αβ axis are calculated.
As described above, since the frequencies of the pulsation signals Xα and Xβ and the free-run frequency of the induction motor 1 are in a constant proportional relationship, the free-run frequency of the induction motor 1 is obtained from the detected frequencies of the pulsation signals Xα and Xβ. Can be
[0013]
The operation of the free-run rotation frequency detecting means 3a will be described in detail.
In the coordinate conversion unit 23, in addition to the pulsation signals Xα and Xβ on the stator αβ axis output from the current control unit 32a, a coordinate rotation frequency w_ax is input as a command value. Then, the pulsation signals Xγ and Xδ of the power state amount captured on the orthogonal biaxial γδ axis, which is the rotating coordinate rotating at w_ax [rad / sec], are calculated as follows.
θγδ = (1 / s) · w_ax (7)
Xγ = cos θγδ · Xα + sin θγδ · Xβ (8)
Xδ = −sin θγδ · Xα + cos θγδ · Xβ (9)
In the situation where the induction motor 1 in the free-run state is rotating forward at 5 [Hz] or reversely rotating at -5 [Hz], the current command value generating means 31a outputs the α-axis current command value iα_ref for free-run frequency detection. = I0 (DC value), β-axis current command value iβ_ref = 0, and when the coordinate rotation frequency w_ax is given by −30 [Hz] (−188 [rad / sec]), the power state quantity on this rotation coordinate The pulsation signals Xγ and Xδ have signal waveforms as shown in FIGS.
[0014]
That is, as shown in FIGS. 2 and 3, pulsations having a frequency w_m proportional to the free-run frequency appear in the current feedback values iα and iβ on the αβ axes, which are two axes on the stator coordinates. In this case, the pulsation frequency w_m is 5 [Hz]. On the other hand, the frequency w_γδ of the pulsation signals Xγ and Xδ captured on the orthogonal two-axis γδ axis, which is a rotating coordinate rotating at w_ax [Hz], is observed as approximately (w_m−w_ax) [Hz]. In the case of FIG. 2 where the induction motor 1 is rotating forward, 5-(− 30) = 35 [Hz], and in the case of FIG. 3 where the induction motor 1 is rotating reversely, −5 − (− 30) = 25 [Hz].
Either or both of the pulsation signals Xγ and Xδ on the rotating coordinates are input to the pulsation frequency detection means 21 and the frequency w_γδ of the pulsation signals Xγ and Xδ is calculated by counting the number of times the sign is inverted. . Specifically, the pulsation measurement period is T [sec], and the number N of sign inversions during this period is measured by the pulsation frequency detecting means 21 and calculated by the following equation.
w_γδ = (N−1) / (2 · T) [Hz] (10)
Thereafter, the frequency w_m of the pulsation signals Xα, Xβ on the αβ axis, which is the two axes on the stator coordinates, is calculated by the following equation using the following equation with respect to the frequency w_γδ of the pulsation signals Xγ, Xδ.
w_m = w_γδ + w_ax [Hz] (11)
[0015]
In the case where the induction motor 1 is rotating forward and the frequency w_m of the pulsation signals Xα and Xβ on the αβ axis is +5 [Hz] in FIG. 2, this is represented by the rotational coordinates where the coordinate rotation frequency w_ax is −30 [Hz]. When the measurement is performed, a pulsation of 35 [Hz] is measured. From the measured frequency and the known coordinate rotation frequency w_ax, 5 [Hz], which is the frequency w_m of the pulsation signals Xα and Xβ, is calculated by Expression (11).
Further, in the case of FIG. 3 in which the frequency w_m of the pulsation signals Xα and Xβ on the αβ axis is −5 [Hz] when the induction motor is in reverse rotation, this is converted to the rotation coordinates where the coordinate rotation frequency w_ax is −30 [Hz]. , A pulsation of 25 [Hz] is measured. Based on the measured frequency and the known coordinate rotation frequency w_ax, −5 [Hz], which is the frequency w_m of the pulsation signals Xα and Xβ, is calculated by Expression (11). In this case, on the stator coordinates, a pulsation waveform in which the phase sequence of the αβ axis is reversed with respect to the case of FIG. 2 appears, but the frequency w_γδ of the pulsation signals Xγ and Xδ on the rotating coordinates is measured. When the frequency w_m of the pulsation signals Xα and Xβ is calculated from the frequency and the coordinate rotation frequency w_ax, the calculated frequency w_m becomes a numerical value including the rotation direction information (−5 in this case). For this reason, it is not necessary to detect the phase difference of the pulsation signal, and the rotation direction can be determined only by the arithmetic processing of the above equation (11) by the addition / subtraction means 22, so that the rotation of the induction motor in the free-run state can be easily performed. The direction can be determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
[0016]
As described above, the frequency w_γδ of the pulsation signals Xγ and Xδ for which the frequency measurement is actually performed is a frequency obtained by adding (−w_ax) to the frequency w_m of the pulsation signals Xα and Xβ on the αβ axis, and thus the coordinate rotation frequency w_ax Depending on the setting, measurement can be performed in a high frequency range, and frequency detection can be significantly speeded up without reducing detection accuracy.
In this case, assuming that the frequency w_m of the pulsation signals Xα and Xβ on the αβ axis is 5 [Hz], the time required for detection for three cycles is 0.6 [sec], but the coordinate rotation frequency w_ax is set to −30. [Hz] (−188 [rad / sec]), the frequency of the pulsation signals Xγ and Xδ on the rotating coordinates is 35 [Hz], and the time required for measurement for three cycles is:
1 / {5-(-30)} × 3 = 85.7 [msec].
[0017]
In addition, since the pulsation itself does not occur near the rotation speed of the induction motor 1 of 0 [Hz], the calculation result of Expression (11) becomes w_m = w_ax, which is inappropriate. Therefore, when the calculation result is w_m <w_ax + α (α: a small positive number), w_m = 0 [Hz] is reset as exceptional processing.
[0018]
Further, the free-run frequency detection according to the present embodiment is premised on use in a region where the sign of the pulsation frequency w_m-w_ax in the rotating coordinate system is positive. That is, the frequency range in which the direction can be determined is restricted by the following equation (12). However, if w_ax is set according to the use condition of the induction motor 1, no problem occurs.
w_ax <(frequency domain in which direction can be determined) (12)
For example, the frequency range where free-run frequency detection is
− | W_MIN | <w_m <+ | w_MAX |
If w_ax <− | w_MIN | is set, the rotation direction can be determined.
[0019]
Furthermore, in order to obtain the effect of speeding up the frequency detection in both the forward rotation and the reverse rotation, the frequency w_γδ of the pulsation signals Xγ and Xδ is changed by using the pulsation signals Xα and Xβ on the αβ axis in both the normal rotation and the reverse rotation. Must be higher for the absolute value of frequency w_m. For this purpose, the absolute value of the coordinate rotation frequency w_ax is set to at least twice the absolute value of w_MIN, that is, w_ax <−2 · | w_MIN |.
Here, the absolute value of w_MIN does not necessarily have to be the maximum operating frequency of the induction motor 1. For example, when driving a load with a large inertia based on a fixed rotation direction command, such as a railway application or a large-capacity blower application, the reversal of the rotation direction during free-run is performed in a low frequency range. Limited to That is, | w_MIN | is set as the absolute value upper limit of the assumed reversal frequency, and w_ax is set to be extremely lower than the maximum operating frequency and w_ax is set to satisfy w_ax <−2 · | w_MIN |. High-speed free-run frequency detection and rotation direction discrimination can be performed while taking into consideration the entire operation region to be performed.
[0020]
Embodiment 2 FIG.
Next, a control device for an induction motor according to a second embodiment of the present invention will be described. FIG. 4 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 2 of the present invention.
In the second embodiment, a pulsation extraction unit 33 is provided inside the power state quantity control unit 12b in the power conversion unit 2b in addition to the configuration of the first embodiment shown in FIG.
In the first embodiment, the current control errors represented by the equations (5) and (6) are used as the first power state quantity pulsation signals Xα and Xβ, but in the second embodiment, A value obtained by subtracting the voltage drop due to the resistance from the voltage command value is calculated by the pulsation extraction means 33 as shown in equations (13) and (14), and is output to the free-run frequency detection means 3a as Xα and Xβ.
Xα = vα_ref−Rs_n · I0 (13)
Xβ = vβ_ref (14)
Here, I0 is the step width of the step command value applied to the α-axis current command value, and Rs_n is the set value of the primary resistance value.
[0021]
Also in this embodiment, similarly to the first embodiment, the pulsation signals Xα and Xβ obtained on the stator αβ axis are subjected to coordinate conversion to rotational coordinates having a predetermined coordinate rotational frequency. By measuring the frequency of the pulsation signals Xγ and Xδ on the rotating coordinates, the pulsation frequency can be measured in a high frequency range even in a low-speed range of the induction motor, and the frequency detection can be performed without lowering the detection accuracy. Speed up. Further, it is not necessary to detect the phase difference of the pulsation signal, and the addition / subtraction means 22 can determine the rotation direction only by the arithmetic processing of the above equation (11). Can be determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
[0022]
Embodiment 3 FIG.
Next, a control device for an induction motor according to Embodiment 3 of the present invention will be described. FIG. 5 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 3 of the present invention.
In the third embodiment, the pulsation signals Xα and Xβ on the stator αβ axis are provided inside the power state quantity control unit 12c in the power conversion unit 2c, in contrast to the configuration of the first embodiment shown in FIG. Is provided.
In the first and second embodiments, the pulsation signals Xα and Xβ are extracted from the current feedback values iα and iβ or the voltage command values vα_ref and v_β_ref. In the third embodiment, at least one of the voltage command value and the current feedback value is used. Filter processing is performed by the filter means 34 based on one of the pieces of information. This makes it possible to generate pulsation signals Xα and Xβ from which information that disturbs the processing of the free-run rotation frequency detecting means 3a has been removed.
[0023]
As an example of the filter means 34, a method of calculating primary magnetic flux estimated values Φα, Φβ on the stator αβ axis and extracting pulsation signals of the estimated magnetic flux as first power state quantity pulsation signals Xα, Xβ will be described. .
The filter means 34 calculates the following equations (15) to (18) to calculate estimated magnetic flux values Φα and Φβ, and then calculates pulsation signals Xα and Xβ. Rs_n is a primary resistance set value.
Φα = (1 / s) · (vα_ref−Rs_n · iα) (15)
Φβ = (1 / s) · (vβ_ref−Rs_n · iβ) (16)
Xα = (s / (s + w_a)) · Φα (17)
Xβ = (s / (s + w_a)) · Φβ (18)
[0024]
As described above, when the current command value generating means 31a gives the step current command value as the current command value iα_ref = I0 (DC value) on the α-axis and the current command value iβ_ref = 0 on the β-axis, as described above, A pulsation signal having a frequency w_m having a fixed proportional relationship with the free-run frequency is superimposed on the current command value and the current feedback value. Further, as can be seen from the equations (15) and (16), the pulsation signal having the same frequency w_m is also superimposed on the magnetic flux estimation values Φα and Φβ. A pulsation signal superimposed on the magnetic flux estimation values Φα and Φβ is extracted according to equations (17) and (18), which are high-pass filter arithmetic expressions of a cutoff frequency w_a [rad / sec], and is extracted as a first power state quantity pulsation signal. Xα and Xβ are output to the free-run rotation frequency detecting means 3a.
[0025]
Also in this embodiment, similarly to the first embodiment, the pulsation signals Xα and Xβ obtained on the stator αβ axis are subjected to coordinate conversion to rotational coordinates having a predetermined coordinate rotational frequency. By measuring the frequency of the pulsation signals Xγ and Xδ on the rotating coordinates, the pulsation frequency can be measured in a high frequency range even in a low-speed range of the induction motor, and the frequency detection can be performed without lowering the detection accuracy. Speed up. Further, it is not necessary to detect the phase difference of the pulsation signal, and the addition / subtraction means 22 can determine the rotation direction only by the arithmetic processing of the above equation (11). Therefore, the rotation direction of the induction motor in the free-run state can be easily determined. Can be determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
The pulsation signals Xα and Xβ on the stator αβ axis calculated by the equations (15) to (18) are converted into iα and iβ or vα_ref and vβ_ref by the effect of the integration operation of the equations (15) and (16). This is equivalent to performing a low-pass process. For this reason, the pulsation waveform from which the high-frequency noise has been removed is input to the free-running rotation frequency detection means 3a. Thereafter, when the pulsation frequency detection means 21 measures the frequencies of the pulsation signals Xγ and Xδ on the rotational coordinates. In addition, the effect of improving the accuracy of 0 cross detection is obtained. As described above, the filter unit 34 has an effect of removing a signal that becomes a disturbance in the frequency measurement of the pulsation signal, so that the detection accuracy of the free-run frequency is improved.
[0026]
The calculation processing of the pulsation signals Xα and Xβ on the stator αβ axis used by the filter means 34 is not limited to the above equations (15) to (18), but may be performed by the voltage command values vα_ref, v_β_ref or the current feedback value. Any filter processing may be used as long as the phase difference information of the pulsation signal superimposed on iα and iβ is stored. For example, the filter means 34 is provided with band-pass filter processing and amplification gain for both the signals on the α-axis and the β-axis to amplify the pulsation component in a specific frequency region and detect the free-run rotation frequency in the subsequent stage. The pulsation frequency detection means 21 in the means 3a may improve the accuracy of zero cross detection.
[0027]
Embodiment 4 FIG.
Next, a control device for an induction motor according to Embodiment 4 of the present invention will be described. FIG. 6 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 4 of the present invention.
In the fourth embodiment, in contrast to the configuration of the first embodiment shown in FIG. 1, the voltage for self-excited oscillation for current pulsation oscillation is provided inside the power state quantity control means 12d in the power conversion means 2d. A generator 35a and an adder 36 are provided.
When an impulse-like current command value is applied to the current control loop for free-run frequency detection from the current command value generation means 31a, a pulsation signal superimposed on the current feedback value of the current loop and the voltage command value is generated. The pulsation signal is oscillated and amplified by the voltage generating means 35a. This oscillation and amplified current pulsation, in this case, current feedback values iα and iβ are obtained and used as first power state quantity pulsation signals Xα and Xβ on the αβ axis, which are output to the free-run rotation frequency detecting means 3a. I do. Since only the pulsation signal is amplified by the voltage generating means 35a, the current feedback values iα and iβ can be used as they are as the pulsation signals Xα and Xβ. In order to further improve the extraction accuracy of the pulsation signals Xα and Xβ, pulsation extraction means for performing a high-pass filter process for removing a DC offset or the like may be provided.
[0028]
FIGS. 7 and 8 show signal waveforms on the αβ axis and the rotation coordinates (γδ axis) when detecting the rotation frequency of the induction motor 1 in the free-run state in forward rotation and reverse rotation, respectively. Here, in the situation where the free-run frequency of the induction motor 1 is rotating forward or backward at 5 [Hz], the current command value generating means 31a outputs the current command value iα_ref on the α-axis for free-run frequency detection. When the impulse command value is given the current command value iβ_ref = 0 on the β axis and the pulsation signal is oscillated and amplified by the voltage generating means 35a, the current feedback values iα and iβ on the αβ axis 7 shows waveforms of pulsation signals Xγ and Xδ. For convenience, in FIGS. 7 and 8, the frequency of the pulsation signal on the αβ axis indicated by the current feedback values iα and iβ is 5 [Hz], which is the same as the free-run frequency.
As shown in FIGS. 7 and 8, it can be seen that the waveform of each pulsation signal does not attenuate and continues even after several hundred [msec] after the impulse-shaped current command value is applied. As described above, since the attenuation is suppressed by the voltage generation unit 35a and the effect of maintaining the pulsation is obtained, when the pulsation frequency detection unit 21 measures the frequency of the pulsation signals Xγ and Xδ on the rotational coordinates, The effect of improving the accuracy of 0 cross detection is obtained.
[0029]
Also in this embodiment, similarly to the first embodiment, the pulsation signals Xα and Xβ obtained on the stator αβ axis are subjected to coordinate transformation into rotational coordinates having a predetermined coordinate rotational frequency. With the configuration, since the frequency of the pulsation signals Xγ and Xδ on the rotating coordinates is measured, the pulsation frequency can be measured by converting the induction motor into a high frequency region even in a low speed range, and the frequency can be measured without lowering the detection accuracy. Detection can be greatly accelerated. Further, it is not necessary to detect the phase difference of the pulsation signal, and the addition / subtraction means 22 can determine the rotation direction only by the arithmetic processing of the above equation (11). Can be determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
[0030]
Embodiment 5 FIG.
Next, a control device for an induction motor according to a fifth embodiment of the present invention will be described. FIG. 9 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 5 of the present invention.
As shown in the figure, the control device of the induction motor 1 includes a power conversion unit 2e and a free-run rotation frequency detection unit 3b.
The power conversion unit 2e includes a power converter 10, a current detection unit 11, a power state quantity control unit 12e, a voltage coordinate conversion unit 13, and a current coordinate conversion unit 14, which are main circuits. Further, the power state quantity control unit 12e includes a current command value generation unit 31b and a current control unit 32b. The free-run rotation frequency detecting means 3b includes a pulsating frequency detecting means 21 and an adding / subtracting means 22. As shown in FIG. 10, the current control unit 32b includes a current PI control unit 101, a feedforward voltage calculation unit 102, a current control error calculation unit 103, and an addition unit 104.
[0031]
Next, the operation will be described.
First, the operation of the power conversion means 2e, particularly the control operation by the current control loop, will be described. The power conversion unit 2e forms a current control loop with the current control unit 32b, the voltage coordinate conversion unit 13, the current coordinate conversion unit 14, the power converter 10, the current detection unit 11, and the induction motor 1. The current control means 32b outputs the voltage command value and controls the power converter 10 so that the current feedback value obtained from the primary current value matches the current command value output from the current command value generation means 31b. .
Here, the current command value, the voltage command value, and the current feedback value are given on orthogonal two-axis γδ-axis coordinates, which are rotation coordinates rotating at a predetermined coordinate rotation frequency w_ax [rad / sec]. Control is performed so that the current feedback value matches the current command value on the coordinates.
[0032]
In the current detecting means 11, the same arithmetic expression (1) (2) shown in the first embodiment described above is applied to the three-phase current values iu, iv, and iw whose actual currents are detected by a current detector such as a current sensor. ), The coordinates are converted into current feedback values iα and iβ on the αβ axis and output to the current coordinate conversion means 14.
iα = (2/3) ^-1 -(Iu- (1/2) -iv- (1/2) -iw) ... (1)
iβ = (1/2) ^-(1/2) ・ Iw- (1/2) ^-(1/2) ・ Iv… (2)
The current coordinate conversion means 14 receives the coordinate rotation frequency w_ax in addition to the current feedback values iα and iβ on the αβ axis. Then, current control control is performed by converting the current feedback values iγ and iδ on the orthogonal two-axis γδ axes, which are rotating coordinates rotating at w_ax [rad / sec], by the following equations (19), (20), and (21). Output to the means 32b.
θγδ = (1 / s) · w_ax (19)
iγ = cos θγδ · iα + sin θγδ · iβ (20)
iδ = −sin θγδ · iα + cos θγδ · iβ (21)
[0033]
The current control means 32b inputs the current feedback values iγ, iδ on the rotational coordinates and the current command values iγ_ref, iδ_ref to the current control error calculating means 103, and obtains the rotational coordinates as in the following equations (22) and (23). The above current control errors err_iγ and err_iδ are calculated and output to the current PI control means 101.
err_iγ = iγ_ref−iγ (22)
err_iδ = iδ_ref−iδ (23)
The current PI control means 101 calculates the control voltages vγ_PI and vδ_PI by the following proportional-integral calculation, and outputs the control voltages to the adding means 104. Here, Kp and Ki are a proportional gain constant and an integral gain constant that determine the response of the current control.
vγ_PI = (Kp + (Ki / s)) · err_iγ (24)
vδ_PI = (Kp + (Ki / s)) · err_iδ (25)
[0034]
Further, the feedforward voltage calculating means 102 performs an induced voltage calculation necessary for performing current control on the rotating coordinates. The necessity of this means will be described below.
When a DC current command value is given on a rotating coordinate rotating at a coordinate rotation frequency w_ax [Hz], for example, a current command value iγ_ref on the γ-axis = I0 (DC value), a δ-axis current command value iδ_ref = 0 An induced voltage having a frequency w_ax is generated on the stator αβ axis due to leakage inductance. As a result, the current control loop includes a signal component generated by the induced voltage at the frequency w_ax, in addition to the signal pulsating in relation to the free-run frequency. In order to detect the free-run frequency, the purpose is to detect only the frequency of the pulsation signal on the αβ axis that pulsates in relation to the free-run frequency. Therefore, it is necessary to cancel the pulsation component of the frequency w_ax.
[0035]
Specifically, based on the current command values iγ_ref and iδ_ref on the rotating coordinates output from the current command value generating means 31b and the coordinate rotation frequency w_ax, the induction motor 1 is calculated by the following equations (26) and (27). The induced voltages vγ_FF and vδ_FF due to the leakage inductance are calculated. Note that on the γδ axis rotating at the coordinate rotation frequency w_ax, the induced voltage can be calculated as a DC amount. At this time, if the offset component of the voltage drop due to the primary resistance is also calculated, the pulsation signal of w_m [Hz] on the αβ axis can be extracted with higher accuracy.
vγ_FF = Rs_n · iγ_ref−w_ax · σLs_n · iδ_ref (26)
vδ_FF = w_ax · σLs_n · iγ_ref + Rs_n · iδ_ref (27)
Here, Rs_n is a set value of the primary resistance value, and σLs_n is a set value of the leakage inductance.
The adding means 104 performs the following addition, calculates voltage command values vγ_ref, vδ_ref, and outputs the calculated voltage command values to the voltage command coordinate conversion means 13.
vγ_ref = vγ_PI + vγ_FF (28)
vδ_ref = vδ_PI + vδ_FF (29)
The pulsation components of two frequencies w_m and w_ax to be superimposed on the current control loop can be separated by the arithmetic processing by the above equations (26) to (29). Specifically, in equations (28) and (29), vγ_PI and vδ_PI are components required for free-run frequency detection, and vγ_FF and vδ_FF are induced voltage components due to leakage inductance.
[0036]
The voltage coordinate conversion means 13 calculates the voltage by using the reference phase angle θγδ of the rotating coordinates calculated by the equation (19) using the voltage command values vγ_ref and vδ_ref on the rotating coordinates as inputs, and the following equations (30) and (31). The command values vγ_ref and vδ_ref are subjected to coordinate conversion on the αβ axis of the stator coordinates.
vα_ref = cos θγδ · vγ_ref−sin θγδ · vδ_ref (30)
vβ_ref = sin θγδ · vγ_ref + cos θγδ · vδ_ref (31)
The voltage command values vα_ref and vβ_ref on the αβ axis calculated in this way are output to power converter 10. The power converter 10 outputs an actual voltage vector based on the input voltage command values vα_ref and vβ_ref on the αβ axis to the induction motor 1. For example, when a voltage-type inverter is used for the power converter 10, the voltage command values vα_ref and vβ_ref on the αβ axis are converted into three-phase waveforms, and then the arithmetic processing is performed to generate a switching pattern of the three-phase inverter. By inputting the switching pattern to the control input of the inverter, the pulse width modulated three-phase voltage is supplied to the induction motor 1.
In this way, by the current control loop configured on the rotating coordinates, the current feedback values iγ and iδ on the rotating coordinates are controlled so as to follow the current command values iγ_ref and iδ_ref.
[0037]
Next, current control for detecting the rotation frequency of the induction motor 1 when the power is not supplied from the power conversion means 2e to the induction motor 1 due to the occurrence of an instantaneous power failure, that is, when the induction motor 1 is in the free-run state. The operation of the loop will be described.
FIGS. 11 and 12 show signal waveforms on the rotating coordinates (γδ axis) and αβ axis when detecting the rotation frequency of the induction motor 1 in the free-run state by the forward rotation and the reverse rotation, respectively. Here, in a situation where the free-run frequency of the induction motor 1 is rotating forward or backward at 5 [Hz], the current command value generating means 31b steps the DC current command value for detecting the free-run frequency. The signal waveform at the time of output is shown, which is given as a specified γ-axis current value iγ_ref = I0 (DC value) and given as a specified δ-axis current value iδ_ref = 0.
As shown in FIGS. 11 and 12, by the function of the current control loop described above, the average value of the current feedback values iγ and iδ on the rotating coordinates is calculated on the rotating coordinates output by the current command value generating means 32b. Control is performed so as to follow the current command value iγ_ref = I0, iδ_ref = 0.
[0038]
Thus, the main components of the current feedback values iα and iβ captured on the stator αβ axis can be expressed by the following expressions (32) and (33) from the inverse conversion relationship with respect to the above expressions (20) and (21).

As shown in the above equations (32) and (33), and FIGS. 11 and 12, the main components of the current feedback values iα and iβ captured on the αβ axis are sine waves of the coordinate rotation frequency w_ax. However, a minute pulsating component pulsating at a frequency w_m having a fixed proportional relationship with the free-run frequency is superimposed on the actual iα and iβ. This is because the induction motor 1 has an impedance characteristic having a peak at the rotation frequency, so that a pulsating signal is applied to the current and voltage command values by applying a stepwise shock to the current command value to the current control loop. This is because it is induced.
[0039]
As a result of converting the pulsation component into a rotating coordinate system rotating at a frequency w_ax (in this case, −30 [Hz]) by the above equations (20) and (21), the current feedback values iγ and iδ on the rotating coordinates are as shown in FIG. 11, as shown in FIG. 12, the current command values iγ_ref and iδ_ref have a frequency (w_m−w_ax). Become. That is, the current control errors err_iγ and err_iδ become the power state quantity pulsation signals Xγ and Xδ, and have the waveforms shown in FIG.
The convergence of the pulsation signals Xγ and Xδ can be controlled by the proportional gain Kp and the integral gain Ki of the current PI control means 101.
[0040]
The pulsation components Xγ and Xδ on the rotational coordinates generated in this manner, that is, one or both of the current control errors err_iγ and err_iδ are output to the free-run rotation frequency detection means 3b.
Either or both of the pulsation signals Xγ and Xδ on the rotating coordinates are input to the pulsation frequency detection means 21 and the frequency w_γδ of the pulsation signals Xγ and Xδ is calculated by counting the number of times the sign is inverted. . Specifically, the pulsation measurement period is T [sec], and the number N of sign inversions during this period is measured by the pulsation frequency detection means 21 and is calculated by the following equation similar to the above embodiment.
w_γδ = (N−1) / (2 · T) [Hz] (10)
Thereafter, the frequency w_m of the pulsation signals Xα, Xβ on the αβ axis, which is the two axes on the stator coordinates, is calculated by the following equation using the following equation with respect to the frequency w_γδ of the pulsation signals Xγ, Xδ.
w_m = w_γδ + w_ax [Hz] (11)
[0041]
In this embodiment, a current control loop is formed on the rotating coordinate axis, and the frequency w_γδ of the pulsation signals Xγ and Xδ on the rotating coordinate is measured. The frequency w_γδ of the pulsation signals Xγ and Xδ is, as in the first embodiment, the coordinate rotation frequency with respect to the frequency w_m of the pulsation signals Xα and Xβ on the stator αβ axis, which has a fixed proportional relationship with the free-run frequency. w_ax is a value obtained by adding. For this reason, even if the induction motor is in a low speed range, it can be converted into a high frequency range to measure the pulsation frequency, and the frequency detection can be significantly speeded up without lowering the detection accuracy. Further, it is not necessary to detect the phase difference of the pulsation signal, and the addition / subtraction means 22 can determine the rotation direction only by the arithmetic processing of the above equation (11). Can be determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
Furthermore, since the signal component generated by the induced voltage of the coordinate rotation frequency is canceled by providing the feedforward voltage calculation means 102, only the pulsating signal related to the free-run frequency is extracted with high reliability and the frequency is extracted. Since it can be detected, the free-run frequency can be detected with high reliability and high accuracy.
[0042]
Embodiment 6 FIG.
Next, a control device for an induction motor according to Embodiment 6 of the present invention will be described. FIG. 13 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 6 of the present invention.
In the sixth embodiment, in contrast to the configuration of the fifth embodiment shown in FIG. 9, the pulsation signals Xγ and Xδ on the rotating coordinates are generated inside the power state quantity control means 12f in the power conversion means 2f. Filter means 34 is provided.
In the fifth embodiment, one or both of the current control errors err_iγ and err_iδ are output to the free-run rotation frequency detection unit 3b as the pulsation components Xγ and Xδ on the rotation coordinates. Filter processing is performed by the filter means 34 based on at least one of the command value and the current feedback value. This makes it possible to generate pulsation signals Xγ and Xδ from which information that disturbs the processing of the free-run rotation frequency detecting means 3b has been removed.
[0043]
As an example of the filter means 34, a band pass process and an amplification process will be described. The filter means 34 performs one of the following equations (34) and (35), and outputs one of the pulsation components Xγ and Xδ on the rotational coordinates to the free-running rotational frequency detecting means 3b.
Xγ = Kbpf · (s / (s + wa)) · (wb / (s + wb)) · iγ (34)
Xδ = Kbpf · (s / (s + wa)) · (wb / (s + wb)) · iδ (35)
(Laplace conversion notation)
Here, Kbpf is a pulsation amplification gain, wa is a low-frequency cutoff frequency, wb is a high-frequency cutoff frequency, and is set according to the frequency band in which pulsation is to be amplified and the amplification gain.
[0044]
By outputting the pulsation components Xγ and Xδ obtained in this way to the free-run rotation frequency detecting means 3b, the same effect as in the fifth embodiment can be obtained. That is, also in this embodiment, even if the induction motor is in a low speed range, it can be converted into a high frequency range and the pulsation frequency can be measured, and the frequency detection can be significantly speeded up without lowering the detection accuracy. In addition, since it is not necessary to detect the phase difference of the pulsation signal and the rotation direction can be determined only by the arithmetic processing in the addition / subtraction means 22, the rotation direction of the induction motor in the free-run state can be easily determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
Further, the pulsation components Xγ and Xδ calculated by the above equations (34) and (35) have a pulsation waveform in which the DC offset and the high-frequency noise have been removed from the current feedback values iγ and iδ on the rotating coordinates. In addition, the accuracy of the zero-cross detection in the pulsation frequency detection means 21 is improved, and the frequency can be detected with high accuracy.
Note that any filter processing may be used as long as a desired band-pass / amplification processing can be performed. For example, a high-order band-pass filter having a better cutoff characteristic may be used.
[0045]
Embodiment 7 FIG.
Next, a control device for an induction motor according to Embodiment 7 of the present invention will be described. FIG. 14 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 7 of the present invention.
In the seventh embodiment, in contrast to the configuration of the fifth embodiment shown in FIG. 9, a voltage for self-excited oscillation for current pulsation oscillation is provided inside power state quantity control means 12g in power conversion means 2g. A generator 35b and an adder 36 are provided.
When the impulse-like current command value is applied to the current control loop for the purpose of detecting the free-run frequency from the current command value generation means 31b, the control signal of the current control loop is applied as described in the fifth embodiment. Although the pulsation signal is superimposed, the pulsation signal is oscillated and amplified by the voltage generation means 35b. This oscillated and amplified current pulsation is obtained to generate power state quantity pulsation signals Xγ and Xδ, which are output to the free-run rotation frequency detecting means 3b.
[0046]
In this embodiment, the same effect as in the fifth embodiment can be obtained. In other words, even if the induction motor is in a low-speed range, the pulsation frequency can be measured by converting it into a high frequency range, and the frequency detection can be significantly speeded up without lowering the detection accuracy. In addition, since it is not necessary to detect the phase difference of the pulsation signal and the rotation direction can be determined only by the arithmetic processing in the addition / subtraction means 22, the rotation direction of the induction motor in the free-run state can be easily determined. Further, even in a low speed range, the rotation direction can be determined with high reliability while reducing the measurement time.
Further, since the pulsation signal attenuation is suppressed by the voltage generation unit 35b and the effect of maintaining the pulsation is obtained, the pulsation frequency detection unit 21 measures the frequency of the pulsation signals Xγ and Xδ on the rotating coordinates. , 0 cross detection accuracy is improved.
[0047]
【The invention's effect】
As described above, the control device for an induction motor according to the present invention includes a power converter that supplies AC power to the induction motor, a detector that detects an output current of the power converter, and a detector that is detected by the detector. A voltage command value is generated such that a current feedback value obtained by coordinate-converting the three-phase current on two axes orthogonal to each other on a stator coordinate coincides with a current command value given on the two axes. And a power state control means for controlling the induction motor to control the current of the induction motor. Then, when a predetermined command value for detecting the frequency of the induction motor is given as the current command value, a pulsation component generated in the control signal on the two axes of the power state quantity control means is extracted and Power state quantity pulsation signal detecting means for generating one power state quantity pulsation signal, and converting the first power state quantity pulsation signal into a second power state quantity pulsation signal on a rotating coordinate having a predetermined rotation frequency. Rotating coordinate conversion means, frequency detecting means for detecting the frequency of the second power state quantity pulsation signal, based on the detected frequency and the rotation frequency, the frequency of the induction motor in a free-run state and The direction of rotation is determined. For this reason, even if the induction motor is in a low speed range, it can be converted into a high frequency range and the pulsation frequency can be measured, and the frequency detection can be significantly speeded up without lowering the detection accuracy. Further, it is not necessary to detect the phase difference of the pulsation signal, and the rotation direction of the induction motor in the free-run state can be easily and reliably determined.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 1 of the present invention.
FIG. 2 is a control signal waveform illustrating an operation of the control device for the induction motor according to the first embodiment of the present invention.
FIG. 3 is a control signal waveform for explaining an operation of the control device for the induction motor according to the first embodiment of the present invention;
FIG. 4 is a block diagram showing a configuration of a control device for an induction motor according to a second embodiment of the present invention.
FIG. 5 is a block diagram showing a configuration of a control device for an induction motor according to Embodiment 3 of the present invention.
FIG. 6 is a block diagram showing a configuration of a control device for an induction motor according to a fourth embodiment of the present invention.
FIG. 7 is a control signal waveform illustrating an operation of the control device for the induction motor according to the fourth embodiment of the present invention.
FIG. 8 is a control signal waveform illustrating an operation of the control device for the induction motor according to the fourth embodiment of the present invention.
FIG. 9 is a block diagram showing a configuration of a control device for an induction motor according to a fifth embodiment of the present invention.
FIG. 10 is a block diagram showing a partial configuration of a control device for an induction motor according to a fifth embodiment of the present invention.
FIG. 11 is a control signal waveform illustrating an operation of the control device for the induction motor according to the fifth embodiment of the present invention.
FIG. 12 is a control signal waveform illustrating an operation of the control device for the induction motor according to the fifth embodiment of the present invention.
FIG. 13 is a block diagram showing a configuration of a control device for an induction motor according to a sixth embodiment of the present invention.
FIG. 14 is a block diagram showing a configuration of a control device for an induction motor according to a seventh embodiment of the present invention.
[Explanation of symbols]
1 induction motor, 3a, 3b free-run rotation frequency detecting means,
10 power converter, 11 current detecting means,
12a to 12g power state quantity control means, 13 voltage coordinate conversion means,
14 current coordinate conversion means, 21 pulsation frequency detection means, 23 coordinate conversion means,
31a, 31b current command value generation means, 32a, 32b current control means,
33 pulsation detection means, 34 filter means as pulsation signal detection means,
35a, 35b voltage generating means, 36 adding means, two axes on αβ stator coordinates,
γδ Two axes on rotating coordinates, Xα, Xβ fixed coordinate system pulsation signal,
Xγ, Xδ Rotational coordinate system pulsation signal.

Claims (6)

A power converter for supplying AC power to the induction motor, a detector for detecting an output current of the power converter, and a three-phase current detected by the detector on two orthogonal axes on stator coordinates Power state quantity control means for controlling the power converter by generating a voltage command value so that the current feedback value obtained by the coordinate conversion becomes equal to the current command value given on the two axes. In a control device for an induction motor for controlling a current of an electric motor, when a predetermined command value for detecting a frequency of the induction motor is given as the current command value, the power state quantity control means is provided on the two axes. A power state quantity pulsation signal detecting means for extracting a pulsation component generated in the control signal to generate a first power state quantity pulsation signal; and detecting the first power state quantity pulsation signal on a rotational coordinate having a predetermined rotation frequency. The second power state quantity pulsation signal And a frequency detecting means for detecting a frequency of the second power state quantity pulsation signal. Based on the detected frequency and the rotational frequency, the induction motor in a free-run state is provided. A control device for an induction motor, wherein a frequency and a rotation direction are obtained. A power converter for supplying AC power to the induction motor, a detector for detecting an output current of the power converter, and a voltage command value generated such that a current feedback value obtained from the detected current matches the current command value. A power state variable control means for controlling the power converter, and controlling the current of the induction motor, wherein the power state variable control means includes a rotating coordinate having a predetermined rotation frequency. In the above, control is performed so that the current feedback value matches the current feedback value.When a predetermined command value for detecting the frequency of the induction motor is given as the current command value, the power state quantity control is performed. A power state quantity pulsation signal detecting means for extracting a pulsation component generated in the control signal on the rotational coordinate of the means and generating a power state quantity pulsation signal; and a circuit for detecting a frequency of the power state quantity pulsation signal. A number detection means, the detection frequency and on the basis of the above rotational frequency, the control device for an induction motor and obtains the frequency and direction of rotation of the induction motor in the free run state. Current coordinates for converting the detected currents of the three phases detected by the detector into two orthogonal axes on the stator coordinates and then converting the coordinates on the rotational coordinates to generate the current feedback value Conversion means, and voltage coordinate conversion means for performing coordinate conversion of the voltage command value on the rotating coordinates generated by the power state quantity control means on two orthogonal axes on the stator coordinates. The control device for an induction motor according to claim 2. 4. The control of an induction motor according to claim 2, wherein the power state quantity control means includes means for canceling a signal component generated by an induced voltage of a rotation frequency of the rotation coordinate from the voltage command value. apparatus. 5. The power state variable control means includes a voltage generating means for self-excited oscillation, and adds the generated voltage to the voltage command value to oscillate and amplify the generated pulsating component. The control device for an induction motor according to any one of the above. The rotation frequency of the rotation coordinates is set so that an absolute value thereof is larger than an upper limit of an absolute value of a reverse rotation frequency assumed during the operation of the induction motor. Induction motor control device.

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