Answered step by step
Verified Expert Solution
Question
1 Approved Answer
3. The Joule-Thomson coefficient, JT, is expressed by the following equation; JT=(PT)H(Q3.1) where H is enthalpy. The van der Waals equation of state is given
3. The Joule-Thomson coefficient, JT, is expressed by the following equation; JT=(PT)H(Q3.1) where H is enthalpy. The van der Waals equation of state is given by the following expression; P=VbRTV2a where, the constant, a, accounts for the interaction strength between the gas molecules, and the constant, b, accounts for the finite size of the gas molecules. For a van der Waals gas, it can be shown that the Joule-Thomson coefficient is given by JT=CP[1(2/VRT)(1b/V)2](2a/RT)(1b/V)2b where, CP is the specific heat capacity and V is specific volume. 3-1. Using equation (Q3.2) and equation (Q3.4), derive an analytical expression to solve for the maximum inversion pressure, Pi,max. Using the equation derived, first calculate the Pi,max values and then plot the Joule-Thomson inversion curves for methane (CH4), carbon monoxide (CO) and nitrogen (N2) gases. Use at least 10 pressure points when plotting the curves; i.e. between 0 and Pi,max, for each gas. You may use the data given in Table Q3.1. 3-2. According to the principle of Corresponding States, all fluids, when compared at the same reduced temperature and reduced pressure, have approximately the same compressibility factor and all deviate from ideal gas behavior to about the same degree. By plotting the Joule-Thomson inversion curves you have computed in part b) in terms of reduced variables, check if the principle of corresponding states holds for the inversion temperature, Ti. You may use the data given in Table Q3.1. 3. The Joule-Thomson coefficient, JT, is expressed by the following equation; JT=(PT)H(Q3.1) where H is enthalpy. The van der Waals equation of state is given by the following expression; P=VbRTV2a where, the constant, a, accounts for the interaction strength between the gas molecules, and the constant, b, accounts for the finite size of the gas molecules. For a van der Waals gas, it can be shown that the Joule-Thomson coefficient is given by JT=CP[1(2/VRT)(1b/V)2](2a/RT)(1b/V)2b where, CP is the specific heat capacity and V is specific volume. 3-1. Using equation (Q3.2) and equation (Q3.4), derive an analytical expression to solve for the maximum inversion pressure, Pi,max. Using the equation derived, first calculate the Pi,max values and then plot the Joule-Thomson inversion curves for methane (CH4), carbon monoxide (CO) and nitrogen (N2) gases. Use at least 10 pressure points when plotting the curves; i.e. between 0 and Pi,max, for each gas. You may use the data given in Table Q3.1. 3-2. According to the principle of Corresponding States, all fluids, when compared at the same reduced temperature and reduced pressure, have approximately the same compressibility factor and all deviate from ideal gas behavior to about the same degree. By plotting the Joule-Thomson inversion curves you have computed in part b) in terms of reduced variables, check if the principle of corresponding states holds for the inversion temperature, Ti. You may use the data given in Table Q3.1
Step by Step Solution
There are 3 Steps involved in it
Step: 1
Get Instant Access to Expert-Tailored Solutions
See step-by-step solutions with expert insights and AI powered tools for academic success
Step: 2
Step: 3
Ace Your Homework with AI
Get the answers you need in no time with our AI-driven, step-by-step assistance
Get Started