《机电传动控制》第四周作业

一、题目要求：

结合本周学习的交流电机原理及启动、调速、制动特性，用Modelica设计和仿真一个用三相交流异步电机带动起重机起升机构运行。具体要求如下：

1）实现如下机械运动周期：

控制电机带重物上升，从静止加速到800r/min

保持800r/min匀速运动0.5s，

减速到静止，保持静止状态0.5s，

带重物下降，从静止达到600r/min

保持600r/min匀速运动0.6s，

减速到静止。
(为了便于仿真，匀速和静止持续时间较短)

2) 升降机构和重物折算到到电机转子轴上的等效负载惯量为1Kg.m^2，折算到到电机转子轴上的等效负载转矩是15N.m。

3）使用统一的电机模型,如果控制策略中用到转子串电阻，允许将该电机的转子改为绕线式转子（参数不变）。

4）参照教材中给出的交流电机启动、调速和制动方法，设计控制策略，用Modelica实现控制策略并与电机模型实现联合仿真。

5）可以采用定子串电阻、转子串电阻、定子调压、定子调频等手段，但必须具备工程上的可实施性。

6）评价指标：快速启动、制动，冲击转矩和冲击电流小，能耗小，兼顾实施的经济性。

二、仿真分析：

由于转速n与fs存在正比例的关系，所以采用改变fs来控制n的方法。在老师所给程序案例中，fs为50Hz时对应电机转速n为1500r/min，所以认为n=30fs。以下程序编写，均以控制不同时间段的fs为基础，来完成相应的转速要求，具体内容参考郑君政同学的参数设置。

三、仿真代码及结果：

model SACIM "A Simple AC Induction Motor Model"

type Voltage=Real(unit="V");

type Current=Real(unit="A");

type Resistance=Real(unit="Ohm");

type Inductance=Real(unit="H");

type Speed=Real(unit="r/min");

type Torque=Real(unit="N.m");

type Inertia=Real(unit="kg.m^2");

type Frequency=Real(unit="Hz");

type Flux=Real(unit="Wb");

type Angle=Real(unit="rad");

type AngularVelocity=Real(unit="rad/s");

 

constant Real Pi = 3.1415926;

 

Current i_A"A Phase Current of Stator";

Current i_B"B Phase Current of Stator";

Current i_C"C Phase Current of Stator";

Voltage u_A"A Phase Voltage of Stator";

Voltage u_B"B Phase Voltage of Stator";

Voltage u_C"C Phase Voltage of Stator";

Current i_a"A Phase Current of Rotor";

Current i_b"B Phase Current of Rotor";

Current i_c"C Phase Current of Rotor";

Frequency f_s"Frequency of Stator";

Torque Tm"Torque of the Motor";

Speed n"Speed of the Motor";

 

Flux Psi_A"A Phase Flux-Linkage of Stator";

Flux Psi_B"B Phase Flux-Linkage of Stator";

Flux Psi_C"C Phase Flux-Linkage of Stator";

Flux Psi_a"a Phase Flux-Linkage of Rotor";

Flux Psi_b"b Phase Flux-Linkage of Rotor";

Flux Psi_c"c Phase Flux-Linkage of Rotor";

 

Angle phi"Electrical Angle of Rotor";

Angle phi_m"Mechnical Angle of Rotor";

AngularVelocity w"Angular Velocity of Rotor";

 

Torque Tl"Load Torque";

 

parameter Resistance Rs = 0.531+0.5 "Stator Resistance";

parameter Resistance Rr = 0.408+0.5 "Rotor Resistance";

parameter Inductance Ls = 0.00252"Stator Leakage Inductance";

parameter Inductance Lr = 0.00252"Rotor Leakage Inductance";

parameter Inductance Lm = 0.00847"Mutual Inductance";

parameter Frequency f_N = 50"Rated Frequency of Stator";

parameter Voltage u_N = 220"Rated Phase Voltage of Stator";

parameter Real p =2"number of pole pairs";

parameter Inertia Jm = 0.1"Motor Inertia";

parameter Inertia Jl = 1"Load Inertia";

parameter Frequency f1 = 27;

parameter Frequency f2 = 15;

parameter Frequency f3 = 0.2;

parameter Frequency f4 = 19.8;

parameter Frequency f5 = 19.8;

parameter Real t1 = 100+500+671; //加速 800r/min恒速

parameter Real t2 = t1+50; //减速

parameter Real t3 = t2+600; //静止0.5s

parameter Real t4 = t3+200; //反向加速

parameter Real t5 = t4+300+600; //600r/min恒速

 

 

Real time1(start=0);

Real time2(start=0);

Real time3(start=0);

 

initial equation

 

Psi_A = 0;

Psi_B = 0;

Psi_C = 0;

Psi_a = 0;

Psi_b = 0;

Psi_c = 0;

phi = 0;

w = 0;

 

equation

 

u_A = Rs * i_A + 1000 * der(Psi_A);

u_B = Rs * i_B + 1000 * der(Psi_B);

u_C = Rs * i_C + 1000 * der(Psi_C);

 

0 = Rr * i_a + 1000 * der(Psi_a);

0 = Rr * i_b + 1000 * der(Psi_b);

0 = Rr * i_c + 1000 * der(Psi_c);

 

Psi_A = (Lm+Ls)*i_A + (-0.5*Lm)*i_B + (-0.5*Lm)*i_C + (Lm*cos(phi))*i_a + (Lm*cos(phi+2*Pi/3))*i_b + (Lm*cos(phi-2*Pi/3))*i_c;

Psi_B = (-0.5*Lm)*i_A + (Lm+Ls)*i_B + (-0.5*Lm)*i_C + (Lm*cos(phi-2*Pi/3))*i_a + (Lm*cos(phi))*i_b + (Lm*cos(phi+2*Pi/3))*i_c;

Psi_C = (-0.5*Lm)*i_A + (-0.5*Lm)*i_B + (Lm+Ls)*i_C + (Lm*cos(phi+2*Pi/3))*i_a + (Lm*cos(phi-2*Pi/3))*i_b + (Lm*cos(phi))*i_c;

 

Psi_a = (Lm*cos(phi))*i_A + (Lm*cos(phi-2*Pi/3))*i_B + (Lm*cos(phi+2*Pi/3))*i_C + (Lm+Lr)*i_a + (-0.5*Lm)*i_b + (-0.5*Lm)*i_c;

Psi_b = (Lm*cos(phi+2*Pi/3))*i_A + (Lm*cos(phi))*i_B + (Lm*cos(phi-2*Pi/3))*i_C + (-0.5*Lm)*i_a + (Lm+Lr)*i_b + (-0.5*Lm)*i_c;

Psi_c = (Lm*cos(phi-2*Pi/3))*i_A + (Lm*cos(phi+2*Pi/3))*i_B + (Lm*cos(phi))*i_C + (-0.5*Lm)*i_a + (-0.5*Lm)*i_b + (Lm+Lr)*i_c;

 

Tm =-p*Lm*((i_A*i_a+i_B*i_b+i_C*i_c)*sin(phi)+(i_A*i_b+i_B*i_c+i_C*i_a)*sin(phi+2*Pi/3)+(i_A*i_c+i_B*i_a+i_C*i_b)*sin(phi-2*Pi/3));

 

w = 1000 * der(phi_m);

 

phi_m = phi/p;

n= w*60/(2*Pi);

 

Tm-Tl = (Jm+Jl) * 1000 * der(w);

 

if time <= 100 then

u_A = 0;

u_B = 0;

u_C = 0;

Tl = 0;

elseif time <= t4 then

u_A = u_N * 1.414 * sin(2*Pi*f_s*time/1000);

u_B = u_N * 1.414 * sin(2*Pi*f_s*time/1000-2*Pi/3);

u_C = u_N * 1.414 * sin(2*Pi*f_s*time/1000-4*Pi/3);

Tl = 15;

else

u_A = u_N * 1.414 * sin(2*Pi*f_s*time/1000);

u_B = u_N * 1.414 * sin(2*Pi*f_s*time/1000+2*Pi/3);

u_C = u_N * 1.414 * sin(2*Pi*f_s*time/1000+4*Pi/3);

Tl = 15;

end if;

 

 

algorithm

 

if time <= 100 then

f_s := 0;

elseif time <= t1 then

f_s := f1;

elseif time <= t2 then

f_s := f2;

 

elseif time <= t3 then

f_s := f3;

elseif time <= t4 then

 

f_s := (time-t3)/(t4-t3)*(f4-f3)+f3;

 

elseif time <= t5 then

f_s := f5;

else

f_s := 0;

end if;

 

if n > 800*0.98 and n < 800*0.99 then

time1 := time;

end if;

if n < 0.1 then

time2 := time;

end if;

if n > -600*0.98 and n < -600*0.99 then

time3 := time;

end if;

end SACIM;

四、总结

基本按照要求完成任务，曲线整体较为平滑。