Answer:
The room temperature will be [tex]90.3^{0}[/tex]
Explanation:
We know from First law of thermodynamics that the amount of heat flow (Q) through a system is given by
[tex]Q = m C_{V}\Delta T[/tex]
where, 'm' is the mass of the system, [tex]C_{V}[/tex] is the specific heat and [tex]\Delta T[/tex] is the temperature difference. Also we know, [tex]C_{V}[/tex] = 0.718 KJ [tex]Kg^{-1}[/tex].
According to the problem, the heat flow can also be written as
[tex]Q = P \times t = 100 W \times 8 hr = 0.1 kW \times 8 \times 3600 sec = 2880 KJ[/tex]
So,
[tex]&& mC_{V}\Delta T = 280000\\&or,& \Delta T = \frac{280000}{m \times C_{V}}[/tex]
Again, if 'm' be the mass of the gas and 'R' be the Universal gas constant = [tex]0.287 KPam^{3}Kg^{-1K^{1}}[/tex]then from Ideal gas equation we can write,
[tex]&& PV = mRT\\\\&or,& m = \frac{PV}{RT} = \frac{100kPa \times (3 \times 4 \times 4)}{0.287 KPam^{3}Kg^{-1}K^{-1} \times 293} = \frac{100 \times 48}{0.287 \times 293} = 57.08 Kg[/tex]
So,
[tex]&& \Delta T = \frac{2880}{57.08 \times 0.718}\\\\&or,& T_{2} - T_{1} = 70.3\\\\&or,& T_{2} = T_{1} + 70.3 = 293 + 70.3 K = 363.3 K\\\\&or,& T_{2} = 363.3 - 273 = 90.3^{0} C[/tex]
