Example: Unrestrained Expansion A rigid tank is partitioned into two equal parts as shown. One side of the tank contains 1 kg water at 100 kPa and at room.

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Example: Unrestrained Expansion A rigid tank is partitioned into two equal parts as shown. One side of the tank contains 1 kg water at 100 kPa and at room temperature of 20°C and the other side is totally evacuated. The partitioned is then removed to allow the water expands into the entire tank. (a) What is the volume of the tank? (b) What will be the final temperature long time after the expansion if the tank is exchanging heat with its surroundings? (c) What is the final pressure of the tank? (d) What is the total amount of heat transfer between the tank and its surroundings? (e) Draw the transition process on T-v and P-v diagrams. T v P v

At a pressure of 100 kPa, the saturation temperature is 99.63°C, therefore, the liquid exists as a compressed (or subcooled) liquid. A liquid is incompressible and its properties are relatively independent of its pressure. We can approximate the compressed liquid as a saturated liquid at the given temperature.