A cylindrical container has insulating wall and an insulating piston which can freely move up and down without any friction. It contains a mixture of ideal gases. Originally the gas is at atmospheric pressure `P_(0)` and temperature `(T_(0))`. A tap positioned above the container is opened and it supplies water at a constant rate of `(dm)/(dt)= 0.25 kg//s`. The water collects above the piston in the container and the gas compresses. The tap is kept open till the temperature of the gas is doubled. During the process the T vs `(1)/(V)` graph for the gas was recorded and found to be a parabola with its vertex at origin as shown in the graph. Area of piston `A = 1.515 xx 10^(-3) m^(2)` and atmospheric pressure `= 10^(5) N//m^(2)` (a) Find the ratio of `V_(rms)` and speed of sound in the gaseous mixture. (b) For how much time the tap was kept open?

A cylindrical container has insulating wall and an insulating piston w

1.	A cylindrical container has insulating wall and an insulating piston which can freely move up and down without any friction. It contains a mixture of ideal gases. Originally the gas is at atmospheric pressure `P_(0)` and temperature `(T_(0))`. A tap positioned above the container is opened and it supplies water at a constant rate of `(dm)/(dt)= 0.25 kg//s`. The water collects above the piston in the container and the gas compresses. The tap is kept open till the temperature of the gas is doubled. During the process the T vs `(1)/(V)` graph for the gas was recorded and found to be a parabola with its vertex at origin as shown in the graph. Area of piston `A = 1.515 xx 10^(-3) m^(2)` and atmospheric pressure `= 10^(5) N//m^(2)` (a) Find the ratio of `V_(rms)` and speed of sound in the gaseous mixture. (b) For how much time the tap was kept open?
Answer» Correct Answer - (a) `sqrt(2)` (b) 290 second

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