This question was previously asked in

UPPCL AE EE Previous Paper 2 (Held On: 1 January 2019 Shift 2)

Option 1 : 1000 rpm

CT 1: Network Theory 1

11608

10 Questions
10 Marks
10 Mins

**Concept:**

Circuit diagram for DC shunt motor is given below.

V_{t} = terminal voltage DC

I_{L} = line current

I_{F} = field current

For DC shunt motor, speed equation is

\(N \propto \frac{{{E_b}}}{\varphi }\)

N is the speed of motor

E_{b} is back emf

ϕ is flux per pole

\(N \propto \frac{{{E_b}}}{\varphi } \propto \frac{{V - {I_a}{R_a}}}{\varphi }\)

**If losses are neglected, then R _{a} = 0 and, \(\varphi \propto {I_f} \propto \frac{V}{{{R_{Sh}}}}\)**

Therefore, the speed of the DC motor becomes proportional to

\(N \propto \frac{V}{{{I_f}}}\)

Now

\(\frac{{{N_2}}}{{{N_1}}} = \frac{{{V_2}}}{{{I_{f2}}}} \times \frac{{{I_{f1}}}}{{{V_1}}} = \frac{{{V_2}}}{{\frac{{{V_2}}}{{{R_{sh}}}}}} \times \frac{{\frac{{{V_1}}}{{{R_{sh}}}}}}{{{V_1}}}\)

**Calculation:**

Given that, V_{1} = 240 V, V_{2} = 180 V, N_{1} = 1000 rpm

\(\Rightarrow \frac{{{N_2}}}{{1000}} = \frac{{180}}{{\frac{{180}}{{{R_{sh}}}}}} \times \frac{{\frac{{240}}{{{R_{sh}}}}}}{{240}}\)

\(\Rightarrow \frac{{{N_2}}}{{1000}} = 1\)

⇒ N_{2} = 1000 rpm

**Alternative approach:**

- When voltage drop or armature resistance is neglected then back emf become equal to the supply voltage.
- If linear magnetization curve is assumed, then magnetic flux is directly proportional to field current.
- For a DC shunt motor, the field current is proportional to supply voltage.
- Hence for the given assumptions both back emf and magnetic flux undergo the same variations.
- Therefore, the speed at 180 V will be same as at 240 V, given 1000 rpm.