Laplace transforms:DC Motor circuit: Difference between revisions

Problem

Find the steady state current i(t) through a DC motor represented by a series R-L-Motor circuit. The resistance (R) is from the armature winding. The inductance (L) is the equivalent inductance of the wire coil (which turns by current flowing through the coil in a permanent magnetic field). The motor has input current i(t) and output angular velocity ω(t).

Solution

The torque is proportional to the armature current.

${\displaystyle T(t)=ki(t)}$

Similarly, relating mechanical (T(t)ω(t)) and electrical (v_m(t)i(t)) power, the conservation of energy requires the same proportionality between the voltage across the motor (v_m(t)) and the angular velocity (ω(t)).

${\displaystyle v_{m}(t)=k\omega (t)}$

We want to find the Laplace transfer function of the motor, and we define it as follows.

${\displaystyle \Omega (s)={\mathcal {L}}[\omega (t)]/v_{s}(s)}$

Summing the voltages around the series circuit gives us our differential equation.

${\displaystyle v_{s}(t)=Ri(t)+L{\frac {di(t)}{dt}}+k\omega (t)}$

Take the Laplace transform.

${\displaystyle V_{s}(s)=RI(s)+Ls(I(s)-i(0))+k\Omega (s)}$

At this point we can use the initial value theorem to find i(0).

${\displaystyle i(0)=\lim _{s\rightarrow \infty }s\int _{0}^{\infty }i(t)e^{-st}u(t)dt={\frac {\infty }{e^{\infty }}}=0}$

Substituting i(0) into the transformed differential equation gives us Eq *1*.

${\displaystyle V_{s}(s)=RI(s)+LsI(s)+k\Omega (s)*1*}$

Repeat the process with the analogous mechanical differential equation. Here J_m is the moment of inertia of the combined armature, shaft, and load. B is the coefficient of friction. Again the initial value theorem will yield ω(0) = 0.

${\displaystyle T(t)=J_{m}{\frac {d\omega (t)}{dt}}+B\omega (t)}$

Transforming yields the following.

${\displaystyle T(s)=(J_{m}s+B)\Omega (s)}$