1. The problem statement, all variables and given/known data
5. A large cylinder with a diameter of 3.00 m and a height of 3.50 m is closed at the upper end and open at the lower end. It is lowered from air into sea water with the air initially at 20.0°C and then to a depth of 75.0 m. At this depth the water temperature is 4.0°C, and the cylinder is in thermal equilibrium with the water.
(a) How high does sea water rise in the cylinder?
(b) To what minimum pressure must the air in the cylinder be raised to expel the water that entered? (ie. If you were to pump enough air into the cylinder to displace all the water out the bottom, what would the pressure be in the cylinder?)
2. Relevant equations
[tex]\frac{P_1 V_1}{T_1} = \frac{P_2 V_2}{T_2}[/tex]
[tex]P = \rho g h[/tex]
3. The attempt at a solution
In my attempt I used the following for each variable:
[tex]P_1 = 101.3Kpa \\ V_1 = \frac{\pi}{4}d^2 \cdot h \\ T_1 = 20 C \\ P_2 = \rho g (75m) \\ T_2 = 4 C \\ V_2 = ?[/tex]
My reasoning for using the pressure at a depth of 75 meters for P2 is that in order for there to be any space in the container the pressure exerted by the air and the pressure exerted by the water have to be equal (in equilibrium). For part b) I found the height of the column of water, rho g h'd it and added the pressure at 75m to get the total pressure needed. Does that all make sense?
Thanks.
5. A large cylinder with a diameter of 3.00 m and a height of 3.50 m is closed at the upper end and open at the lower end. It is lowered from air into sea water with the air initially at 20.0°C and then to a depth of 75.0 m. At this depth the water temperature is 4.0°C, and the cylinder is in thermal equilibrium with the water.
(a) How high does sea water rise in the cylinder?
(b) To what minimum pressure must the air in the cylinder be raised to expel the water that entered? (ie. If you were to pump enough air into the cylinder to displace all the water out the bottom, what would the pressure be in the cylinder?)
2. Relevant equations
[tex]\frac{P_1 V_1}{T_1} = \frac{P_2 V_2}{T_2}[/tex]
[tex]P = \rho g h[/tex]
3. The attempt at a solution
In my attempt I used the following for each variable:
[tex]P_1 = 101.3Kpa \\ V_1 = \frac{\pi}{4}d^2 \cdot h \\ T_1 = 20 C \\ P_2 = \rho g (75m) \\ T_2 = 4 C \\ V_2 = ?[/tex]
My reasoning for using the pressure at a depth of 75 meters for P2 is that in order for there to be any space in the container the pressure exerted by the air and the pressure exerted by the water have to be equal (in equilibrium). For part b) I found the height of the column of water, rho g h'd it and added the pressure at 75m to get the total pressure needed. Does that all make sense?
Thanks.
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