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Minimum Boiling Point Azeotrope

Minimum Boiling Point Azeotrope. Maximum Boiling Point Azeotrope. Single Equilibrium Stage – Ethanol-Water, P = 1 atm. V, y EtOH. Vapor. F, z EtOH. L, x EtOH. Liquid. F is the total moles of ethanol and water fed to the stage.

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Minimum Boiling Point Azeotrope

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  1. Minimum Boiling Point Azeotrope Lecture 4

  2. Maximum Boiling Point Azeotrope Lecture 4

  3. Single Equilibrium Stage – Ethanol-Water, P = 1 atm V, yEtOH Vapor F, zEtOH L, xEtOH Liquid F is the total moles of ethanol and water fed to the stage. V is the total moles in the vapor stream exiting the stage. L is the total moles in the liquid stream exiting the stage. zEtOH is the mole fraction of ethanol in the feed. yEtOH is the mole fraction of ethanol in the vapor stream. xEtOH is the mole fraction of ethanol in the liquid stream. Lecture 4

  4. Feed Mole-Fraction Relationships • Note that a feed mole-fraction, zF,can be a subcooled liquid, a saturated liquid, a two-phase mixture, a saturated vapor, or a superheated vapor. • The feed phase is dependent upon the temperature, pressure, and the composition (mole fraction). Lecture 4

  5. zF and x,y Relationships • Assuming that the equilibrium stage is at the same temperature and pressure of the feed: • If zF is a subcooled liquid, then zF is simply xF and there is no y. • If zF is a superheated vapor, zF is yF and there is no x. • If zF is a saturated liquid, zF is essentially xF with a single vapor bubble formed of new mole fraction y. • If zF is a saturated vapor, zF is essentially yF with a single liquid drop formed of new mole fraction x. • If zF is in the two-phase region, the system will separate into a liquid and vapor of new mole fractions x and y, respectively. zF is not equal to either x or y, but x and y be determined from the T vs. x,y data or plot. Lecture 4

  6. An Initial Way to Investigate this Equilibrium Behavior… • Another way to look at this behavior is to first look at a closed system at a particular pressure and initial temperature, and heat or cool the system at constant pressure and z mole fraction. • We can do this using the T vs. x,y plot… Lecture 4

  7. Mass Balance – Lever Rule • Assume a two-phase mixture of known mole fraction is allowed to separate at constant temperature and pressure. • After a suitable period of time, the system will reach equilibrium. • The two-phase mixture at point A separates into the liquid at point B and vapor at point C along the isotherm, Tsys, as illustrated by: Lecture 4

  8. Mass Balance – Lever Rule Lecture 4

  9. Mass Balance – Lever Rule V, yC Vapor F, zA L, xB Liquid Lecture 4

  10. Mass Balance – Lever Rule Lecture 4

  11. Mass Balance – Lever Rule Lecture 4

  12. Mass Balance – Lever Rule Lecture 4

  13. Mass Balance – Lever Rule Lecture 4

  14. Temperature-Composition Diagram for Ethanol-Water, P = 1 atm 100 95 Two Phase Superheated Vapor Phase 90 C) o T( 85 80 Subcooled Liquid Phase 75 zEtOH 0.0 0.2 0.4 0.6 0.8 1.0 x or y EtOH EtOH Lecture 4

  15. Temperature-Composition Diagram for Ethanol-Water, P = 1 atm 100 V 95 Two Phase Superheated Vapor Phase ≈V 90 L V C) o V T( L 85 ≈L 80 L Subcooled Liquid Phase 75 zEtOH 0.0 0.2 0.4 0.6 0.8 1.0 x or y EtOH EtOH Lecture 4

  16. Mass Balance – Further Relationships Lecture 4

  17. Note for a Two-Phase Mixture… • At vapor-liquid equilibrium, the temperatures of the vapor and liquid are equal. • When a two-phase mixture separates at vapor-liquid equilibrium conditions, the vapor phase will be at saturated vapor conditions and the liquid phase will be at saturated liquid conditions. • We will use this assumption when we do our multi-stage solutions – the vapor and liquid streams exiting a stage will be assumed to be at saturated conditions. • Thus, the liquid fed from one stage to another stage can be assumed to be a saturated liquid and the vapor feed to another stage can be assumed to be a saturated vapor. Lecture 4

  18. Enthalpy vs. Composition – Ponchon-Savarit Plot • Presents the temperature equilibrium relationship for enthalpy vs. x and y. • Pressure is constant (note the units). • One normally plots the more volatile component. • Enthalpy will be required in future problems utilizing energy balances. • Note the units of concentration! Lecture 4

  19. Enthalpy vs. Composition – Ponchon-Savarit Plot Lecture 4

  20. Tips For Reading Charts • Use a clear ruler. • Photocopy and enlarge the diagrams. • Draw lines on the diagram to find intersection points. • Measure the scale in mm and convert to chart units. • E.g., What is the enthalpy of a (two phase) feed stream at 1 kg/cm2 pressure, 82°C, 0.6 wt% ethanol? • Measure 21 mm/100 kcal/kg. Intersection at 8.5 mm above 200 kcal/kg. H = 200 kcal/kg+(8.5mm/21mm)×100 kcal/kg=240.5 kcal/kg Lecture 4

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