Purely Inductive AC Circuit 🌀⚡

A coil (inductance L) is hooked to an AC source that delivers \(v = v_m \sin \omega t\). Kirchhoff’s loop rule says the applied voltage must balance the self-induced emf, so

\[ v – L\frac{di}{dt}=0 \] :contentReference[oaicite:0]{index=0}

Finding the current

Rewrite the loop rule as \[ \frac{di}{dt}= \frac{v_m}{L}\sin \omega t. \quad (1) \] Integrate (1):

\[ i = -\frac{v_m}{\omega L}\cos \omega t + C. \] The current swings symmetrically about zero, so the constant C is zero. Use the identity \(\cos\omega t = \sin\bigl(\omega t + \frac{\pi}{2}\bigr)\) to get

\[ \boxed{\;i = i_m \sin\!\Bigl(\omega t – \frac{\pi}{2}\Bigr)\;} \qquad\text{with}\qquad i_m = \frac{v_m}{\omega L}. \] :contentReference[oaicite:1]{index=1}

Key takeaway ⏰: the current lags the voltage by exactly \(\frac{\pi}{2}\) rad (one-quarter cycle). :contentReference[oaicite:2]{index=2}

Inductive Reactance

Define the opposition offered by a coil as its inductive reactance

\[ \boxed{\;X_L = \omega L\;} \] :contentReference[oaicite:3]{index=3}

  • Same unit as resistance: ohm (Ω).
  • Bigger L or higher frequency → larger \(X_L\), so smaller current.

Instantaneous and Average Power 🔌

Instantaneous power is \[ p = vi = v_m i_m \sin\omega t \, \sin\!\Bigl(\omega t – \tfrac{\pi}{2}\Bigr) = -\tfrac{1}{2}v_m i_m \sin 2\omega t. \]

The average of \(\sin 2\omega t\) over a full cycle is zero, so

\[ \boxed{\;P_{\text{avg}} = 0\;} \]

Thus, an ideal inductor stores energy in its magnetic field during part of the cycle and returns it later; it never consumes energy. :contentReference[oaicite:4]{index=4}

Worked Example 🎯

Given: \(L = 25.0\,\text{mH}\), \(V_{\text{rms}} = 220\,\text{V}\), \(f = 50\,\text{Hz}\).

  1. \(X_L = 2\pi f L = 7.85\,\Omega\).
  2. \(I_{\text{rms}} = \dfrac{V_{\text{rms}}}{X_L} = 28\,\text{A}\).

Even a modest inductance lets only \(\approx 28\,\text{A}\) flow at mains frequency—proof that reactance behaves like frequency-dependent “resistance.” :contentReference[oaicite:5]{index=5}

Visualising with Phasors 🧭

Picture two arrows spinning at angular speed \(\omega\): the voltage arrow leads, and the current arrow trails by \(90^{\circ}\). Their vertical shadows trace the sine curves of \(v\) and \(i\). This rotating-vector trick makes phase relationships crystal-clear. :contentReference[oaicite:6]{index=6}

Quick Recap 📌

  • Current lags voltage by \(\tfrac{\pi}{2}\).
  • Inductive reactance \(X_L = \omega L\) limits AC current.
  • \(I_{\text{rms}} = V_{\text{rms}}/X_L\).
  • Average power in an ideal inductor is zero.

High-Yield Ideas for NEET 🎓

  1. Phase difference: coil current lags supply voltage by \(90^{\circ}\).
  2. Inductive reactance formula \(X_L = \omega L\) and its frequency dependence.
  3. Expression for peak current \(i_m = v_m/(\omega L)\).
  4. Zero average power in a purely inductive circuit.