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1、<p> 本科生畢業(yè)設(shè)計(外文翻譯)</p><p> 題 目: 步進電機的設(shè)計與仿真 </p><p> 姓 名: </p><p> 學(xué) 號: </p><p> 系 別:
2、 電氣工程 </p><p> 專 業(yè): 電氣工程及其自動化 </p><p> 年 級: </p><p> 指導(dǎo)教師: </p><p
3、> 步進電機的振蕩、不穩(wěn)定以及控制 </p><p> 摘要:本文介紹了一種分析永磁步進電機不穩(wěn)定性的新穎方法。結(jié)果表明,該種電機有兩種類型的不穩(wěn)定現(xiàn)象:中頻振蕩和高頻不穩(wěn)定性。非線性分叉理論是用來說明局部不穩(wěn)定和中頻振蕩運動之間的關(guān)系。一種新型的分析介紹了被確定為高頻不穩(wěn)定性的同步損耗現(xiàn)象。在相間分界線和吸引子的概念被用于導(dǎo)出數(shù)量來評估高頻不穩(wěn)定性。通過使用這個數(shù)量就可以很容易地估計高頻供應(yīng)
4、的穩(wěn)定性。此外,還介紹了穩(wěn)定性理論。廣義的方法給出了基于反饋理論的穩(wěn)定問題的分析。結(jié)果表明,中頻穩(wěn)定度和高頻穩(wěn)定度可以提高狀態(tài)反饋。 </p><p> 關(guān)鍵詞:步進電機,不穩(wěn)定,非線性,狀態(tài)反饋。 &
5、#160; </p><p><b> 1. 介紹 </b></p><p> 步進電機是將數(shù)字脈沖輸入轉(zhuǎn)換為模擬角度輸出的電磁增量運動裝置。其內(nèi)在的步進能力允許沒有反饋的精確位置控制。 也就是說,他們可以在開環(huán)模式下跟蹤任何步階位置,因此執(zhí)行位置控制是不需要任何反饋的。步進電機提供比直流電機每單位更高的峰值扭矩
6、;此外,它們是無電刷電機,因此需要較少的維護。所有這些特性使得步進電機在許多位置和速度控制系統(tǒng)的選擇中非常具有吸引力,例如如在計算機硬盤驅(qū)動器和打印機,代理表,機器人中的應(yīng)用等. </p><p> 盡管步進電機有許多突出的特性,他們?nèi)栽馐苷袷幓虿环€(wěn)定現(xiàn)象。這種現(xiàn)象嚴重地限制其開環(huán)的動態(tài)性能和需要高速運作的適用領(lǐng)域。 這種振蕩通常在步進率低于1000脈沖/秒的時候發(fā)生,并已被確認為中頻不穩(wěn)定
7、或局部不穩(wěn)定,或者動態(tài)不穩(wěn)定。此外,步進電機還有另一種不穩(wěn)定現(xiàn)象,也就是在步進率較高時,即使負荷扭矩小于其牽出扭矩,電動機也常常不同步。該文中將這種現(xiàn)象確定為高頻不穩(wěn)定性,因為它以比在中頻振蕩現(xiàn)象中發(fā)生的頻率更高的頻率出現(xiàn)。高頻不穩(wěn)定性不像中頻不穩(wěn)定性那樣被廣泛接受,而且還沒有一個方法來評估它。 </p><p> 中頻振蕩已經(jīng)被廣泛地認識了很長一段時間,但是,一個完整的了解還沒有牢固確立。這可以歸因
8、于支配振蕩現(xiàn)象的非線性是相當(dāng)困難處理的。大多數(shù)研究人員在線性模型基礎(chǔ)上分析它。盡管在許多情況下,這種處理方法是有效的或有益的,但為了更好地描述這一復(fù)雜的現(xiàn)象,在非線性理論基礎(chǔ)上的處理方法也是需要的。例如,基于線性模型只能看到電動機在某些供應(yīng)頻率下轉(zhuǎn)向局部不穩(wěn)定,并不能使被觀測的振蕩現(xiàn)象更多深入。事實上,除非有人利用非線性理論,否則振蕩不能評估。 </p><p> 因此,在非線性動力學(xué)上利用被發(fā)展的數(shù)
9、學(xué)理論處理振蕩或不穩(wěn)定是很重要的。值得指出的是,Taft和Gauthier,還有Taft和Harned使用的諸如在振蕩和不穩(wěn)定現(xiàn)象的分析中的極限環(huán)和分界線之類的數(shù)學(xué)概念,并取得了關(guān)于所謂非同步現(xiàn)象的一些非常有啟發(fā)性的見解。盡管如此,在這項研究中仍然缺乏一個全面的數(shù)學(xué)分析。本文一種新的數(shù)學(xué)分被開發(fā)了用于分析步進電機的振動和不穩(wěn)定性。 </p><p> 本文的第一部分討論了步進電機的穩(wěn)定性分析。結(jié)果表明
10、,中頻振蕩可定性為一種非線性系統(tǒng)的分叉現(xiàn)象(霍普夫分叉)。本文的貢獻之一是將中頻振蕩與霍普夫分叉聯(lián)系起來,從而霍普夫理論從理論上證明了振蕩的存在性。高頻不穩(wěn)定性也被詳細討論了,并介紹了一種新型的量來評估高頻穩(wěn)定。這個量是很容易計算的,而且可以作為一種標準來預(yù)測高頻不穩(wěn)定性的發(fā)生。在一個真實電動機上的實驗結(jié)果顯示了該分析工具的有效性。 </p><p> 本文的第二部分通過反饋討論了步進電機的穩(wěn)定性控制
11、。一些設(shè)計者已表明,通過調(diào)節(jié)供應(yīng)頻率,中頻不穩(wěn)定性可以得到改善。特別是Pickup和Russell都在頻率調(diào)制的方法上提出了詳細的分析。在他們的分析中,雅可比級數(shù)用于解決常微分方程和一組數(shù)值有待解決的非線性代數(shù)方程組。此外,他們的分析負責(zé)的是雙相電動機,因此,他們的結(jié)論不能直接適用于我們需要考慮三相電動機的情況。在這里,我們提供一個沒有必要處理任何復(fù)雜數(shù)學(xué)的更簡潔的穩(wěn)定步進電機的分析。在這種分析中,使用的是d-q模型的步進電機。由于雙相
12、電動機和三相電動機具有相同的d-q模型,因此,這種分析對雙相電動機和三相電動機都有效。迄今為止,人們僅僅認識到用調(diào)制方法來抑制中頻振蕩。本文結(jié)果表明,該方法不僅對改善中頻穩(wěn)定性有效,而且對改善高頻穩(wěn)定性也有效。 </p><p> 2. 動態(tài)模型的步進電機 </p><p> 本文件中所考慮的步進電機由一個雙相或三相繞組的跳動定子和永磁轉(zhuǎn)子組成
13、。一個極對三相電動機的簡化原理如圖1所示。步進電機通常是由被脈沖序列控制產(chǎn)生矩形波電壓的電壓源型逆變器供給的。這種電動機用本質(zhì)上和同步電動機相同的原則進行作業(yè)。步進電機主要作業(yè)方式之一是保持提供電壓的恒定以及脈沖頻率在非常廣泛的范圍上變化。在這樣的操作條件下,振動和不穩(wěn)定的問題通常會出現(xiàn)。</p><p> 圖1.三相電動機的圖解模型</p><p> 用q–d框架參考轉(zhuǎn)換建立了一個三
14、相步進電機的數(shù)學(xué)模型 。下面給出了三相繞組電壓方程</p><p> 其中R和L分別是相繞組的電阻和感應(yīng)線圈,并且M是相繞組之間的互感線圈。 </p><p> 是應(yīng)歸于永磁體 的相的磁通,且可以假定為轉(zhuǎn)子位置的</p><p><b> 正弦函數(shù)如下</b></p><p> 其中
15、N是轉(zhuǎn)子齒數(shù)。本文中強調(diào)的非線性由上述方程所代表,即磁通是轉(zhuǎn)子位置的非線性函數(shù)。 </p><p> 使用Q ,d轉(zhuǎn)換,將參考框架由固定相軸變換成隨轉(zhuǎn)子移動的軸(參見圖2)。矩陣從a,b,c框架轉(zhuǎn)換成q,d框架變換被給出了 </p><p> 例如,給出了q,d參考里的電壓</p><p> 在a,b,c參考中,只有兩個變量是獨立
16、的因此,上面提到的由三個變量轉(zhuǎn)化為兩個變量是允許的。在電壓方程(1)中應(yīng)用上述轉(zhuǎn)換,在q,d框架中獲得轉(zhuǎn)換后的電壓方程為</p><p> 圖2,a,b,c和d,q參考框架</p><p> 其中L1 = L + M,且ω是電動機的速度。 有證據(jù)表明,電動機的扭矩有以下公式</p><p> 如果Bf是粘性摩擦
17、系數(shù),和Tl代表負荷扭矩(在本文中假定為恒定)。 為了構(gòu)成完整的電動機的狀態(tài)方程,我們需要另一種代表轉(zhuǎn)子位置的狀態(tài)變量。為此,通常使用滿足下列方程的所謂的負荷角δ</p><p> 其中ω0是電動機的穩(wěn)態(tài)轉(zhuǎn)速。方程(5),(7),和(8)構(gòu)成電動機的狀態(tài)空間模型,其輸入變量是電壓vq和vd.如前所述,步進電機由逆變器供給,其輸出電壓不是正弦電波而是方波。然而,由于相比正弦情況下非正弦電壓不能很大程度地
18、改變振蕩特性和不穩(wěn)定性(如將在第3部分顯示的,振蕩是由于電動機的非線性),為了本文的目的我們可以假設(shè)供給電壓是正弦波。根據(jù)這一假設(shè),我們可以得到如下的vq和vd</p><p> 其中Vm是正弦波的最大值。上述方程,我們已經(jīng)將輸入電壓由時間函數(shù)轉(zhuǎn)變?yōu)闋顟B(tài)函數(shù),并且以這種方式我們可以用自控系統(tǒng)描繪出電動機的動態(tài),如下所示。這將有助于簡化數(shù)學(xué)分析。 </p><p> 根據(jù)方程(
19、5),(7),和(8),電動機的狀態(tài)空間模型可以如下寫成矩陣式 </p><p> 其中且ω1 = Nω0 是供應(yīng)頻率。輸入矩陣B被定義為</p><p> 矩陣A是F(.)的線性部分,如下</p><p> Fn(X)代表了F(.)的線性部分,如下</p><p> 輸入端u獨立于時間,因此,
20、方程(10)是獨立的。 </p><p> 在F(X,u)中有三個參數(shù),它們是供應(yīng)頻率ω1,電源電壓幅度Vm和負荷扭矩Tl。這些參數(shù)影響步進電機的運行情況。在實踐中,通常用這樣一種方式來驅(qū)動步進電機,即用因指令脈沖而變化的供應(yīng)頻率ω1來控制電動機的速度,而電源電壓保持不變。因此,我們應(yīng)研究參數(shù)ω1的影響。</p><p> 3.分叉和中頻振蕩 </p>
21、<p> 設(shè)ω=ω0,得出方程(10)的平衡</p><p><b> 且φ是它的相角,</b></p><p> 方程(12)和(13)顯示存在著多重均衡,這意味著這些平衡永遠不能全局穩(wěn)定。人們可以看到,如方程(12)和(13)所示有兩組平衡。第一組由方程(12)對應(yīng)電動機的實際運行情況來代表。第二組由方程(13)總是不穩(wěn)定且不涉及到實際運作情況來
22、代表。在下面,我們將集中精力在由方程(12)代表的平衡上。</p><p> Oscillation, Instability and Control of Stepper Motors</p><p> Abstract. A novel approach to analyz
23、ing instability in permanent-magnet stepper motors is presented. It is shown that there are two kinds of unstable phenomena i
24、n this kind ofmotor: mid-frequency oscillation and high-frequency instability. Nonlinear bifurcation theory is used to illustrate the r
25、elationship between local instability and midfrequency oscillatory motion. A novel analysis is presented to analyze the loss of sy
26、nchronism phenomenon, which is identified as high-frequency instability. T</p><p> Keywords: Stepper motors, instability, nonlinearity, state
27、 feedback.</p><p> 1. Introduction </p><p> Stepper motors are electromagnetic incremental-motion devices which convert digital puls
28、e inputs to analog angle outputs. Their inherent stepping ability allows for accurate position control without feedback. That is,&
29、#160;they can track any step position in open-loop mode, consequently no feedback is needed to implement position control. Stepper
30、 motors deliver higher peak torque per unit weight than DC motors; in addition, they are brushless machines and therefore
31、0;require less maintenance. All of th</p><p> Although stepper motors have many salient properties, they suffer from an oscill
32、ation or unstable phenomenon. This phenomenon severely restricts their open-loop dynamic performance and applicable area where high spe
33、ed operation is needed. The oscillation usually occurs at stepping rates lower than 1000 pulse/s, and has been recognized as&
34、#160;a mid-frequency instability or local instability , or a dynamic instability . In addition, there is another kind of unst
35、able phenomenon in stepper motors, that </p><p> Most researchers have analyzed it based on a linearized model [1]. Altho
36、ugh in many cases, this kind of treatments is valid or useful, a treatment based on nonlinear theory is needed in o
37、rder to give a better description on this complex phenomenon. For example, based on a linearized model one can only see&
38、#160;that the motors turn to be locally unstableatsomesupplyfrequencies, which does not give much insight into the observed oscillatory
39、 phenomenon. In fact, the oscillation cannot be assessed unless</p><p> Therefore, it is significant to use developed mathemat
40、ical theory on nonlinear dynamics to handle the oscillation or instability. It is worth noting that Taft and Gauthier ,
41、and Taft and Harned used mathematical concepts such as limit cycles and separatrices in the analysis of oscillatory and
42、;unstable phenomena, and obtained some very instructive insights into the socalled loss of synchronous phenomenon. Nevertheless, there
43、is still a lack of a comprehensive mathematical analysis in this kind o</p><p> The first part of this paper discuss
44、es the stability analysis of stepper motors. It is shown that the mid-frequency oscillation can be characterized as a bifurca
45、tion phenomenon (Hopf bifurcation) of nonlinear systems. One of contributions of this paper is to relate the midfrequency oscillat
46、ion to Hopf bifurcation, thereby, the existence of the oscillation is proved </p><p> theoretically by Hopf theory. High-frequ
47、ency instability is also discussed in detail, and a novel quantity is introduced to evaluate high-frequency stability. This quanti
48、ty is very easy </p><p> to calculate, and can be used as a criteria to predict the onset of the high-frequency
49、 instability. Experimental results on a real motor show the efficiency of this analytical tool. </p><p> The second part&
50、#160;of this paper discusses stabilizing control of stepper motors through feedback. Several authors have shown that by modulating
51、;the supply frequency [5], the midfrequency </p><p> instability can be improved. In particular, Pickup and Russell [6, 7]
52、0;have presented a detailed analysis on the frequency modulation method. In their analysis, Jacobi series was used to solve a
53、 ordinary differential equation, and a set of nonlinear algebraic equations had to be solved numerically. In addition, their
54、analysis is undertaken for a two-phase motor, and therefore, their conclusions cannot applied directly to our situation, where a
55、160;three-phase motor will be considered. Here, we give a</p><p> stabilizing stepper motors, where no complex mathematical manipul
56、ation is needed. In this analysis, a d–q model of stepper motors is used. Because two-phase motors and three-phase motors
57、0;have the same q–d model and therefore, the analysis is valid for both two-phase and three-phase motors. Up to date, it
58、 is only recognized that the modulation method is needed to suppress the midfrequency oscillation. In this paper, it is
59、shown that this method is not only valid to improve mid-frequency stability</p><p> The stepper motor considered in this
60、paper consists of a salient stator with two-phase or threephase windings, and a permanent-magnet rotor. A simplified schematic of&
61、#160;a three-phase motor with one pole-pair is shown in Figure 1. The stepper motor is usually fed by a voltage-source i
62、nverter, which is controlled by a sequence of pulses and produces square-wave voltages. This </p><p> motor operates essential
63、ly on the same principle as that of synchronous motors. One of major operating manner for stepper motors is that supplyi
64、ng voltage is kept constant and frequency </p><p> of pulses is changed at a very wide range. Under this operating
65、160;condition, oscillation and instability problems usually arise. </p><p> Figure 1. Schematic model of a three-phase stepper moto
66、r. </p><p> A mathematical model for a three-phase stepper motor is established using q–d framereference transformation. The&
67、#160;voltage equations for three-phase windings are given by </p><p> where R and L are the resistance and inductance of&
68、#160;the phase windings, and M is the mutual inductance between the phase windings. _pma, _pmb and _pmc are the flux-linkages
69、 of the </p><p> phases due to the permanent magnet, and can be assumed to be sinusoid functions of rotor posit
70、ion _ as follow</p><p> where N is number of rotor teeth. The nonlinearity emphasized in this paper is represented b
71、y the above equations, that is, the flux-linkages are nonlinear functions of the rotor position. </p><p> By using the
72、60;q; d transformation, the frame of reference is changed from the fixed phase axes to the axes moving with the rotor
73、60;(refer to Figure 2). Transformation matrix from the a; b; c frame to the q; d frame is given by [8]</p><p&
74、gt; For example, voltages in the q; d reference are given by </p><p> In the a; b; c reference, only two varia
75、bles are independent (ia C ib C ic D 0); therefore, the above transformation from three variables to two variables is
76、60;allowable. Applying the above </p><p> transformation to the voltage equations (1), the transferred voltage equation in the
77、;q; d frame can be obtained as </p><p> Figure 2. a, b, c and d, q reference frame. </p><p> where L1&
78、#160;D L CM, and ! is the speed of the rotor.It can be shown that the motor’s torque has the following form [2
79、]</p><p> The equation of motion of the rotor is written as </p><p> where Bf is the coefficient of viscous
80、;friction, and Tl represents load torque, which is assumed to be a constant in this paper. </p><p> In order to
81、;constitute the complete state equation of the motor, we need another state variable that represents the position of the roto
82、r. For this purpose the so called load angle _ [8] is usually used, which satisfies the following equation</p><p> w
83、here !0 is steady-state speed of the motor. Equations (5), (7), and (8) constitute the statespace model of the motor, fo
84、r which the input variables are the voltages vq and vd. As mentioned before, stepper motors are fed by an inverter,
85、;whose output voltages are not sinusoidal but instead are square waves. However, because the non-sinusoidal voltages do not change
86、 the oscillation feature and instability very much if compared to the sinusoidal case (as will be shown in Section 3,
87、60;the oscillation </p><p> where Vm is the maximum of the sine wave. With the above equation, we have changed the
88、160;input voltages from a function of time to a function of state, and in this way we can represent the dynamics of
89、 the motor by a autonomous system, as shown below. This will simplify the mathematical analysis. </p><p> From Equations&
90、#160;(5), (7), and (8), the state-space model of the motor can be written in a matrix form as follows</p><p> wherei
91、s defined as the input, and !1 D N!0 is the supply frequency. The input matrix B is defined by</p><p> The
92、;matrix A is the linear part of F._/, and is given by </p><p> Fn.X/ represents the nonlinear part of F._/, and
93、 is given by </p><p> The input term u is independent of time, and therefore Equation (10) is autonomous. There
94、;are three parameters in F.X;u/, they are the supply frequency !1, the supply voltage magnitude Vm and the load torque T
95、l . These parameters govern the behaviour of the stepper motor. In practice, stepper motors are usually driven in such a
96、 way that the supply frequency !1 is changed by the command pulse to control the motor’s speed, while the supply vo
97、ltage is kept constant. Therefore, we shall investigate </p><p> 3. Bifurcation and Mid-Frequency Oscillation </p><p> By
98、setting ! D !0, the equilibria of Equation (10) are given as </p><p> Equations (12) and (13) indicate that multiple
99、 equilibria exist, which means that these equilibria can never be globally stable. One can see that there are two groups
100、 of equilibria as shown in Equations (12) and (13). The first group represented by Equation (12) corresponds to the real
101、 operating conditions of the motor. The second group represented by Equation (13) is always unstable and does not relate
102、;to the real operating conditions. In the following, we will concentrate on the equilibria rep</p><p><b> 參考文獻 </b><
103、/p><p> [1] J.L. Hall, Science 202 (1978) 13. </p><p> [2] T. Rosenband et al., Science 319 (2008) 1808. </p>
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