WEEK 6. Multiphase systems

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WEEK 6 Multiphase systems

Multiphase systems P 237. Processes usually deal with material being transferred from one phase (gas, liquid, or solid) to another. 6.1a Phase diagrams F = force on piston Water vapor Water liquid a) At time=0, system is at 20 o C. Force is chosen so that P = 3 mm Hg b) This is point A in Fig 6.1-1 on page 241. Everything evaporates. It s all vapor c) Increase P to 760 mm Hg d) Keep pressure at 760 mm Hg and increase T to 130 o C e) Consider the state of water throughout the process (A->B->C->D->E) Note: 1) T and P on vapor-liquid equilibrium (points B and D); P= vapor pressure, T=boiling point temperature of water at P 2) The boiling point where P = 1 atm = normal boiling point of water 3) (T,P) on solid-liquid equilibrium curve: T is the melting point or freezing point at P 4) Solid-vapor equilibrium curve (T, P), P is the vapor pressure of solid at T; T is the sublimation point at P 5) (T, P) where solid, liquid, vapor phase coexist --- triple point of substance 6) Critical temperature and critical pressure: where vapor-liquid equilibrium stops. Above and to the right of the critical point, 2 separate phases never coexist

Multiphase systems Compressed liquid: liquid is not about to vaporize: water at 20 o C and 1 atm. Saturated liquid: liquid is about to vaporize: water at 100 o C and 1 atm. Superheated vapor: vapor not about to condense: water vapor (steam) > 100 o C at 1 atm. Saturated vapor: vapor is about to condense: water at 100 o C and 1 atm.

6.1b Estimation of vapor pressure P243. Volatility: How easy the substance can go from liquid (or solid) state to a vapor phase Vapor pressure: measures volatility. High vapor pressure at given T ----- High volatility Clapeyron equation: T : absolute temperature dp ΔHˆ v dt T( Vˆ ˆ g VL ) Vˆ and Vˆ : Specific molar volume (volume/mole) g ΔHˆ v : L = Latent heat of vaporization (energy required to vaporize one Mole of the liquid) Vˆ ˆ g >> V : And assume ideal gas RT V L ˆg = P d( ln P ) ΔHˆ = v We have the following equation: d( 1/ T) R Methods can be use to determine heat of vaporization

Estimation of vapor pressure If the heat of vaporization is known, Clausius- Clapeyron equation is used: ln P ΔHˆ v = + B after integration of Clapeyron equation RT Example 6.1-1 page 244 in class We also use Antoine equation for vapor pressure and temperature relations (Page 640) log 10 B P = A T + C ( )

6.2 Gibbs Phase Rule Intensive variable: independent of size of the process Extensive variable: dependent of size The Gibbs phase rule deals with system at equilibrium DF = 2+c-Π (no reaction) DF: The number of intensive variables that must be specified for a system at equilibrium before the remaining intensive variables can be calculated c: The number of components Π: The number of phases at equilibrium Intensive variables: T, P, concentration Ex1: pure liquid water: DF = 2-1-1 = 2 Ex2: A mixture of liquid, solid, and vapor: DF = 2+1-3 = 0 (page 241)

Fitting Polynomial and Correlation Equations to Vapor Pressure Data Often, it is necessary to fit a set of data to an equation (ex: y=ax+b). Given (x,y) data, the goal is to find the coefficients a and b such that the line goes through the points. Example in Matlab and Excel B 2 Variance: VarC i = A+ P 10 T i Ex: Clayperon Equation Data correlation by a polynomial: P calc = a 0 +a 1 TK+a 2 TK 2 +a 3 TK 3 +a 4 TK 4 +a 5 TK 5 Minimize a least-squares objective function: N i= 1 N + ( P P ) obs ( n 1) calc Confidence interval: uncertainty associated with a particular parameter Does the confidence interval include zero? Is the error randomly distributed with zero mean? 2 n: degree of polynomial N: number of data points RMSD = Root mean square deviation

Fitting Polynomial and Correlation Equations to Vapor Pressure Data Clapeyron Equation Data Correlation log ( ) B P = A+ T Degree of freedom = #Component 2 + #phase Empirical equation relating temperature and vapor pressure Confidence interval and variance are small Difficult to compare variance of this model vs polynomial because different forms of the parameters were used Example in Matlab and Excel

Fitting Polynomial and Correlation Equations to Vapor Pressure Data (Next) Riedel Equation Data Correlation log B P = A+ + C T + DT T ( ) log ( ) β Example in Matlab and Excel HMK: 6.3, 6.22

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