Two kg of refrigerant 134a undergoes an isothermal process in a pistoncylinder assembly from p1 =...

A mass of one kg of water within a piston–cylinder assembly undergoes a constant-pressure process from...

A mass of one kg of water within a piston–cylinder assembly undergoes a constant-pressure process from saturated vapor at 500 kPa to a temperature of 260°C. Kinetic and potential energy effects are negligible. For the water: a) Evaluate the work, in kJ, b) If the work is 30 kJ, evaluate the heat transfer, in kJ, c) If the heat transfer is negligible, evaluate the entropy production in kJ/K d) Determine if the process is reversible, irreversible, or impossible.

Water undergoes a constant‐volume process within a piston–cylinder assembly from saturated liquid at 4 bar to...

Water undergoes a constant‐volume process within a piston–cylinder assembly from saturated liquid at 4 bar to a final pressure of 50 bar. Kinetic and potential energy effects are negligible. Determine the work and the heat transfer, each in kJ per kg of water. [7 points]

A 5 kg mass of R134a refrigerant is compressed polytropically from the state initial: p1 =...

A 5 kg mass of R134a refrigerant is compressed polytropically from the state initial: p1 = 1 bar, T1 = 27 ° C until the final state: p2 = 15 bar, T2 = 227 ° C. Specific heat R134a medium at constant volume, Cv = 0.72 kJ / kg K. Calculate: a) exponent of polytropy; b) final volume; c) final volume using the virial state equation d) work done on the gas for compression; e) amount of heat given up...

A piston-cylinder assembly containing 3 kg of an ideal gas undergoes a constant pressure process from...

A piston-cylinder assembly containing 3 kg of an ideal gas undergoes a constant pressure process from an initial volume of 48 m3 to a final volume of 30 m3 . During the process, the piston supplies 1.2 MJ of work to the gas. The gas has a constant specific heat at constant volume of 1.80 kJ/(kg∙K) and a specific gas constant of 1.48 kJ/(kg∙K). Neglect potential and kinetic energy changes. a. Determine the initial specific volume of the gas in...

Carbon dioxide (CO2) is compressed in a piston–cylinder assembly from p1 = 0.7 bar, T1 =...

Carbon dioxide (CO2) is compressed in a piston–cylinder assembly from p1 = 0.7 bar, T1 = 280 K to p2 = 14 bar. The initial volume is 0.2 m3. The process is described by pV1.25 = constant. Assuming ideal gas behavior and neglecting kinetic and potential energy effects, determine the work and heat transfer for the process, each in kJ, using constant specific heats evaluated at 300 K, and data from Table A-23.

A system consisting of 2 kg of water initially at 130°C, 10 bar undergoes an internally...

A system consisting of 2 kg of water initially at 130°C, 10 bar undergoes an internally reversible, isothermal expansion during which there is energy transfer by heat into the system of 700 kJ. Determine the final pressure, in bar, and the work by the system, in kJ.

a tube-within-a-tube heat exchanger operating at steady state is composed of one pipe containing Refrigerant 134a...

a tube-within-a-tube heat exchanger operating at steady state is composed of one pipe containing Refrigerant 134a and another pipe containing an ideal gas with constant specific heat at constant pressure of 1.2 kJ/(kg∙K). The refrigerant 134a enters the heat exchanger in a saturated liquid state and exits the heat exchanger in a saturated vapor state. The temperature and mass flow rate of the refrigerant 134a are -20° C and 3 kgs/s, respectively, at both its inlet and outlet. The ideal...

A gas initially at 2.8 bar and 60ºC is compressed to a final pressure of 14...

A gas initially at 2.8 bar and 60ºC is compressed to a final pressure of 14 bar in an isothermal internally reversible process. Determine the work and heat transfer, each in kJ per kg of gas, if the gas is (a) Refrigerant 134a, (b) air as an ideal gas. Sketch the process on p–v and T–s coordinates

A closed system containing R-134a initially at 280 kPa and 30 °C undergoes a reversible isothermal...

A closed system containing R-134a initially at 280 kPa and 30 °C undergoes a reversible isothermal process, after which its quality is 0.40. (a) What is the specific heat and work transfer, q and w, experienced by the system? (b) Sketch the process on a T-s diagram, labeling the states and the isobars.

Steam undergoes an isentropic compression in an insulated piston–cylinder assembly from an initial state where T1...

Steam undergoes an isentropic compression in an insulated piston–cylinder assembly from an initial state where T1 = 120°C, p1 = 1 bar to a final state where the pressure p2 = 20 bar. Determine the final temperature, in °C, and the work, in kJ per kg of steam. The final temperature equals 513.87°C.