2.2-kW induction motor

This example simulates observer-based V/Hz control of a 2.2-kW induction motor.

from math import pi

import motulator.drive.control.im as control
from motulator.drive import model, utils

Compute base values based on the nominal values.

nom = utils.NominalValues(U=400, I=5, f=50, P=2.2e3, tau=14.6)
base = utils.BaseValues.from_nominal(nom, n_p=2)

Configure the system model.

par = model.InductionMachineInvGammaPars(
    n_p=2, R_s=3.7, R_R=2.1, L_sgm=0.021, L_M=0.224
)
machine = model.InductionMachine(par)
mechanics = model.MechanicalSystem(J=0.015)
converter = model.VoltageSourceConverter(u_dc=540)
mdl = model.Drive(machine, mechanics, converter)

Configure the control system.

est_par = control.InductionMachineInvGammaPars(
    n_p=2, R_s=3.7, R_R=2.1, L_sgm=0.021, L_M=0.224
)
cfg = control.ObserverBasedVHzControllerCfg(psi_s_nom=base.psi, i_s_max=1.5 * base.i)
vhz_ctrl = control.ObserverBasedVHzController(est_par, cfg)
ctrl = control.VHzControlSystem(vhz_ctrl, slew_rate=2 * pi * 120)

Set the speed reference and the external load torque.

ctrl.set_speed_ref(lambda t: (t > 0.2) * base.w_M)
mdl.mechanics.set_external_load_torque(lambda t: (t > 0.8) * nom.tau)

Create the simulation object, simulate, and plot the results in per-unit values.

sim = model.Simulation(mdl, ctrl)
res = sim.simulate(t_stop=1.6)
utils.plot(res, base)