Time taken by a 836; W heater to heat 1; litre of water from 10^{circ} C to 40^{circ} C is

Q: Time taken by a $836\; W$ heater to heat $1\; litre$ of water from $10^{\circ} C$ to $40^{\circ} C$ is

b $W = JH$ $ \Rightarrow $ $P \times t = J \times m\,s\,\Delta \theta $ $ \Rightarrow $ $t = \frac{{J \times m \times s\Delta \theta }}{P}$ (For water $1\, litre$ = $1\,kg$) $ \Rightarrow $ $t = \frac{{4.2 \times 1 \times 1000 \times (40 - 10)}}{{836}} = 150\,sec$ Short Trick : use formula $t = \frac{{4200 \times m \times \Delta \theta }}{P}$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

Time taken by a $836\; W$ heater to heat $1\; litre$ of water from $10^{\circ} C$ to $40^{\circ} C$ is

A$200$
B$150$
C$836$
D$418$

AIEEE 2004, Medium

STD 11 Science
NEET
STD 12 - 3. current electricity
Physics

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