Figure 7.21 shows a series LCR circuit connected to a variable frequency 230 V source. L = 5.0 H, C = 80μF, R = 40Ω.

(a) Determine the source frequency which drives the circuit in resonance.

(b) Obtain the impedance of the circuit and the amplitude of current at the resonating frequency.

(c) Determine the rms potential drops across the three elements of the circuit. Show that the potential drop across the LC combination is zero at the resonating frequency.

Question

Philoid · Accepted Answer

(a) Given: L = 5.0 H

C = 80 Μf = 80 × 10^-6F

R = 40Ω

_{Voltage source V = 230 V}

_{The diagram is given as:}

_{Resonance angular frequency can be calculated as follows}

_ω_R = 1/√LC

_ω_R = 1/ √(5H × 80 × 10^-6F)

_{On calculating, we get}

_ω_R = 50 rad/s

Therefore, source frequency which drives the circuit in resonance frequency ω_R = 50 rad/s.

(b) Impedance can be calculated by using the formula:

At resonance condition i.e. when

Z = R = 40 Ω

_{At resonating frequency, the amplitude of the current can be calculated using the formula:}

_{Where V}₀ is the peak voltage

_{Z is the impedance}

_V₀ = √2V_rms

_I₀ = (√2 × 230V)/40Ω

_⇒ _I₀ = 8.13 A

The impedance of the circuit is 40 Ω and the amplitude of current at the resonating frequency is 8.13 A.

_{(c) The root mean square potential drop across the inductor is given by the following formula:}

_(V_L) _rms = I × 1/ω_R L

_{Where I = I}₀/√ 2

_{I = √ 2V/√2Z}

_{Substituting values, we get}

_{I = 230V/40Ω = 230/40 A}

_Now,

_(V_L) _rms = I × 1/ω_R L

(V_L)_r.m.s.

(V_L)_r.m.s = 1437.5 V

Potential drop across capacitor can be calculated as follows:

_(V_C) _rms = I × 1/ω _R C

(V_C)_r.m.s.

(V_C)_r.m.s = 1437.5 V

Potential drop across resistor can be calculated as follows:

_(V_R) _rms = I × R

_(V_R) _{r. m. s}

_(V_R) _rms = 230 V

Potential drop across LC combination can be calculated as follows:

_V_LC

At resonance condition i.e. when ωL = 1/ωC

Therefore, _V_LC = 0