Thermodynamics // Homework #3 Closed System Energy Analysis 1
Transcription
Thermodynamics // Homework #3 Closed System Energy Analysis 1
Thermodynamics // Homework #3 mass of the steam, (b) the final temperature, and (c) the amount Closed System Energy Analysis 1. 3 A 0.5-m rigid tank contains refrigerant-134a initially at 160 kPa and 40 percent quality. Heat is now transferred to the refrigerant 2. refrigerant in the tank and (b) the amount of heat transferred. touching the piston but exerts no force on it. Heat is now slowly Also, show the process on a P-v diagram with respect to transferred to the steam, causing the pressure and the volume to saturation lines.{10.03 kg, 2707 kJ} rise 3 to 500 kPa and 0.6 m3, A 20-ft rigid tank initially contains saturated refrigerant- 134a respectively. Show the process on a vapor at 160 psia. As a result of heat transfer from the P-v diagram with respect to saturation refrigerant, the pressure drops to 50 psia. Show the process on a lines and determine (a) the final P-v diagram with respect to saturation lines, and determine (a) temperature, (b) the work done by the the final temperature, (b) the amount of refrigerant that has steam, condensed, and (c) the heat transfer {40.23ºF, 47.75 lbm, 4169 transferred. {1132ºC, 35 kJ, 808 kJ} 9. and (c) the total heat A piston–cylinder device initially contains 0.8 m3 of saturated A well-insulated rigid tank contains 5 kg of a saturated liquid– water vapor at 250 kPa. At this state, the piston is resting on a vapor mixture of water at l00 kPa. Initially, three-quarters of the set of stops, and the mass of the piston is such that a pressure of mass is in the liquid phase. An electric resistor placed in the tank 300 kPa is required to move it. Heat is now slowly transferred to is connected to a 110-V source, and a current of 8 A flows the steam until the volume doubles. Show the process on a P-v through the resistor when the switch is turned on. Determine diagram with respect to saturation lines and determine (a) the how long it will take to vaporize all the final temperature, (b) the work done during this process, and (c) liquid in the tank. Also, show the process the total heat transfer. {662ºC, 240 kJ, 1213 kJ} 10. Two tanks (Tank A and Tank B) are separated by a partition. saturation lines. {153.1 min} Initially Tank A contains 2-kg steam at 1 MPa and 300°C while An insulated tank is divided into two Tank B contains 3-kg saturated liquid–vapor mixture with a parts by a partition. One part of the tank contains 2.5 kg of vapor mass fraction of 50 percent. Now the partition is removed compressed liquid water at 60°C and 600 kPa while the other and the two sides are allowed to mix until the mechanical and part is evacuated. The partition is now removed, and the water thermal equilibrium are established. If the pressure at the final expands to fill the entire tank. Determine the final temperature state is 300 kPa, determine (a) the temperature and quality of the of the water and the volume of the tank for a final pressure of 10 steam (if mixture) at the final state and (b) the amount of heat 3 kPa. {45.81ºC, 0.972 m } 5. A piston–cylinder device initially contains steam at 200 kPa, 200°C, and 0.5 m3. At this state, a linear spring (F x) is on a T-v diagram with respect to 4. 8. until the pressure reaches 700 kPa. Determine (a) the mass of the Btu} 3. of heat transfer. {7.565 kg, 179.9 ºC, 4495 kJ} lost from the tanks. {133.5 ºC, 0.3641, 3959 kJ} A piston–cylinder device contains 5 kg of refrigerant- 134a at 800 kPa and 70°C. The refrigerant is now cooled at constant pressure until it exists as a liquid at 15°C. Determine the amount of heat loss and show the process on a T-v diagram with respect to saturation lines. {1173 kJ} 6. A piston–cylinder device contains 0.5 lbm of water initially at 120 psia and 2 ft3. Now 200 Btu of heat is transferred to the water while its pressure is held constant. Determine the final temperature of the water. Also, show the process on a T-v diagram with respect to saturation lines. {1161.4 ºF} 7. A piston–cylinder device contains steam initially at 1 MPa, 450°C, and 2.5 m3. Steam is allowed to cool at constant pressure until it first starts condensing. Show the process on a Tv diagram with respect to saturation lines and determine (a) the Closed System Energy Analysis (Ideal Gas) 11. A rigid tank contains 20 lbm of air at 50 psia and 80°F. The air is now heated until its pressure doubles. Determine (a) the volume of the tank and (b) the amount of heat transfer. { 80 ft3, 1898 Btu} 12. A 3-m3 rigid tank contains hydrogen at 250 kPa and 550 K. The gas is now cooled until its temperature drops to 350 K. Determine (a) the final pressure in the tank and (b) the amount of heat transfer. {159.1 kPa, 686.2 kJ} 13. A piston–cylinder device contains 25 ft3 of nitrogen at 40 psia and 700°F. Nitrogen is now allowed to cool at constant pressure until the temperature drops to 200°F. Using specific heats at the average temperature, determine the amount of heat loss. {284.2 Btu} 14. A piston–cylinder device contains 0.8 kg of nitrogen initially at 100 kPa and 27°C. The nitrogen is now compressed slowly in a polytropic process during which PV1.3=constant until the volume is reduced by one-half. Determine the work done and the heat transfer for this process. {54.8 kJ, 13.6 kJ} 15. A piston–cylinder device, whose piston is resting on a set of stops, initially contains 3 kg of air at 200 kPa and 27°C. The mass of the piston is such that a pressure of 400 kPa is required to move it. Heat is now transferred to the air until its volume doubles. Determine the work done by the air and the total heat transferred to the air during this process. Also show the process on a P-v diagram. {516 kJ, 2674 kJ}