Determine the final specific volume (m3/kg) for a gas undergoing a process from state 1 (T1...

Determine the molecular weight of a gas if its specific heats at constant pressure and volume...

Determine the molecular weight of a gas if its specific heats at constant pressure and volume are Cp=2.286 kj/kg K and Cv=1.768 kj/kg K.   Ans=16.05 kg/k mol

Ideal gas ethylene undergoes a reversible adiabatic compression by which its temperature increases from T1 =...

Ideal gas ethylene undergoes a reversible adiabatic compression by which its temperature increases from T1 = 300 K to T2 = 450 K. The molar entropy in the initial state is given as s1 = 100 J K–1 mol–1, and here, for ethylene, cp = ?T + c0 with ? = 0.1 J K–2 mol–1 and c0 = 13.1 J K–1 mol–1. Determine the change of the molar entropy s2 – s1 and the change of the chemical potential ?2...

In a cylinder/piston arrangement, air is compressed in a reversible polytropic process to a final state...

In a cylinder/piston arrangement, air is compressed in a reversible polytropic process to a final state of 800 kPa, 500 K. Initially air is at 110 kPa and 25oC. During the compression process heat transfer takes place with the ambient maintained at 25oC. Assume air as an ideal gas (R =0.287 kJ/kg) and has constant specific heats of Cp = 1.004 kJ/kgK and Cv = 0.717 kJ/kgK. If the mass of air in the cylinder is 0.1286 kg, determine a)...

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...

Steam at 120 bars and 400°C is a real gas. Determine the specific volume, in m3/kg,...

Steam at 120 bars and 400°C is a real gas. Determine the specific volume, in m3/kg, by means of (a) the ideal-gas equation, (b) van der Waals' equation, (c) the Redlich-Kwong (RK) equation, (d) the two-parameter Z chart, and (e) the superheat table.

An ideal monatomic gas is contained in a vessel of constant volume 0.400 m3. The initial...

An ideal monatomic gas is contained in a vessel of constant volume 0.400 m3. The initial temperature and pressure of the gas are 300 K and 5.00 atm, respectively. The goal of this problem is to find the temperature and pressure of the gas after 18.0 kJ of thermal energy is supplied to the gas. (a) Use the ideal gas law and initial conditions to calculate the number of moles of gas in the vessel. 80.99 Correct: Your answer is...

An ideal monatomic gas is contained in a vessel of constant volume 0.330 m3. The initial...

An ideal monatomic gas is contained in a vessel of constant volume 0.330 m3. The initial temperature and pressure of the gas are 300 K and 5.00 atm, respectively. The goal of this problem is to find the temperature and pressure of the gas after 24.0 kJ of thermal energy is supplied to the gas. (a) Use the ideal gas law and initial conditions to calculate the number of moles of gas in the vessel. Your response differs from the...

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...