Liquid Phase Properties from VLE Data SVNA 12.1

Slides:

Advertisements

Similar presentations

ITK-234 Termodinamika Teknik Kimia II

Advertisements

SELECTING THERMODYNAMIC PROPERTY METHODS

Gas Solubilities Henry’s Law: [A]equilibrium = SA · pA

Fugacity of Non-Ideal Mixtures (SVNA 11.6 and 11.7)

Thermodynamic Property Methods

Property Methods In Aspen Plus

CHEE 311Lecture 161 Correlation of Liquid Phase Data SVNA 12.1 Purpose of this lecture: To show how activity coefficients can be calculated by means of.

Advanced Thermodynamics Note 11 Solution Thermodynamics: Applications

Properties of Reservoir Fluids Fugacity and Equilibrium Fall 2010 Shahab Gerami 1.

Vapor and Liquid Equilibrium

Properties of Solutions. Concentration Terms Dilute - not a lot of solute. Concentrated - a large amount of solute. Concentration can be expressed quantitatively.

Chapter 12 Gas-Liquid Equilibrium

Chemistry Thermodynamics Lecture 12 : Kinetic coefficients and Linear response Lecture 13 : Non Ideal Solutions and Activity Lecture 14: Chemical.

5. Equations of State SVNA Chapter 3

Solid-vapor equilibrium (SVE) and Solid-liquid equilibrium (SLE)

Chemical Reaction Equilibria

Chapter 14-Part VII Applications of VLLE.

Chapter 14: Phase Equilibria Applications

Lecture 18Multicomponent Phase Equilibrium1 Theories of Solution The Gibbs energy of mixing is given by: And the chemical potential is: For ideal gases,

The Advanced Chemical Engineering Thermodynamics The retrospect of the science and the thermodynamics Q&A -1- 9/16/2005(1) Ji-Sheng Chang.

Distillation Underlying Principles of Distillation

The Advanced Chemical Engineering Thermodynamics The variables (thermodynamic properties) and the equations in thermodynamics Q&A -2- 9/22/2005(2) Ji-Sheng.

Solution thermodynamics theory—Part IV

Chemical Engineering Thermodynamics II

CHEE 311J.S. Parent1 7. Liquid Phase Properties from VLE Data (11.1) The fugacity of non-ideal liquid solutions is defined as: (10.42) from which we derive.

Pure Component VLE in Terms of Fugacity

Solution Thermodynamics: Applications

Now we introduce a new concept: fugacity

Excess Gibbs Energy Models

Solution Thermodynamic:

Vapor pressure and liquids Vapor : A gas that exists below its critical point Gas : gas that exists above its critical point ِNote : A gas can not condense.

Chemical Thermodynamics II Phase Equilibria

CHEE 311J.S. Parent1 1. Science of Thermodynamics Concerned with knowing the physical state of a system at equilibrium. A concise (mathematical) description.

Physical Chemistry content Physical Chemistry 1 (BSC) Thermodynamics Terms The thermodynamic system First law of thermodynamics Work, heat, internal energy,

Fugacity, Ideal Solutions, Activity, Activity Coefficient

(12) The expression of K in terms of fugacity coefficient is: The standard state for a gas is the ideal-gas state of the pure gas at the standard-state.

THERMODYNAMICS OF SEPARATION OPERATIONS

1. (1.3) (1.8) (1.11) (1.14) Fundamental equations for homogeneous closed system consisting of 1 mole:

The Simplest Phase Equilibrium Examples and Some Simple Estimating Rules Chapter 3.

ERT 108/3 PHYSICAL CHEMISTRY INTRODUCTION Prepared by: Pn. Hairul Nazirah Abdul Halim.

Solution thermodynamics theory—Part I

6. Coping with Non-Ideality SVNA 10.3

Lecture 6. NONELECTROLYTE SOLUTONS. NONELECTROLYTE SOLUTIONS SOLUTIONS – single phase homogeneous mixture of two or more components NONELECTROLYTES –

CHEE 311J.S. Parent1 4. Chemical Potential in Mixtures When we add dn moles of a component to n moles of itself, we will observe (?) a change in Gibbs.

Solution thermodynamics theory—Part IV

ACTIVITY AND ACTIVITY COEFFICIENT

APPLICATIONS Applications of Raoult’s law

PETE 310 Lecture # 26 Chapter 12 Gas-Liquid Equilibrium Non-ideal VLE.

42C.1 Non-Ideal Solutions This development is patterned after that found in Molecular Themodynamics by D. A. McQuarrie and John D. Simon. Consider a molecular.

Introduction to phase equilibrium

Solution thermodynamics theory

Chemical Engineering Thermodynamics II Dr. Perla B. Balbuena: JEB 240 Web site:

8. Solute (1) / Solvent (2) Systems 12.7 SVNA

1. Write down the vapor-liquid equilibrium (VLE) equations for a binary system assuming that the vapor phase is ideal and the liquid phase follows Raoult’s.

SOLUTION THERMODYNAMICS:

Chemical Engineering Thermodynamics II Dr. Perla B. Balbuena: JEB 240 Website:

Activities and Activity Coefficients. The Definition of the Activity For any real system, the chemical potential for the solute (or solvent) is given.

SAL COLLEGE OF ENGINEERING Department of Chemical Engineering ALA CHEMICAL ENGINEERING THERMODYNAMICS -II ( ) TOPIC : SIMPLE MODELS FOR VAPOUR/LIQUID.

Solution Thermodynamics: Applications Chapter 12-Part IV.

Chapter 14: Phase Equilibria Applications Part II.

G.H.PATEL COLLEGE OF ENGINEERING AND TECHNOLOGY Chemical Engineering Thermodynamics-2 Code – Topic:-Fugacity and Fugacity coefficient for pure.

Solution thermodynamics theory—Part III

CHEE 323J.S. Parent1 Reaction Kinetics and Thermodynamics We define a catalyst as a substance that increases the rate of approach to equilibrium of a reaction.

Partial Properties: Thought Experiment

Process Design Course Using the NIST, DIPPR and DDBSP databases for Finding Physical, Chemical and Thermodynamic Properties Process Design Course.

Solution of Thermodynamics: Theory and applications

} C = 1 F = 2 P = 1 Gibbs phase rule F = C – P + 2

Classical Thermodynamics of Multicomponent Systems

Don’t be in a such a hurry to condemn a person because he doesn’t do what you do, or think as you think. There was a time when you didn’t know what you.

Phase diagrams and phase transitions of unary systems

Presentation transcript:

Liquid Phase Properties from VLE Data SVNA 12.1 Purpose of this lecture: To illustrate how activity coefficients can be calculated from experimental VLE data obtained at low pressures Highlights For our calculations we take advantage of the fact that as P->0 the vapour phase molecular interactions in a mixture at VLE become very weak, hence the vapour behaves as an ideal gas. In thermodynamic terms this can be written as The modified form of Raoult’s law can then be used for the estimation of the activity coefficients from experimental low P VLE Reading assignment: Section 12.1 (pp. 430-432) CHEE 311 Lecture 15

7. Liquid Phase Properties from VLE Data SVNA 12.1 The mixture fugacity of a component in non-ideal liquid solution is defined by: (11.46) We also define the activity coefficient: (11.91) which is a measure of the departure of the component behaviour from an ideal solution. Using the activity coefficient, equation 11.46 becomes: How do we calculate/measure these properties? CHEE 311 Lecture 15

Liquid Phase Properties from VLE Data Suppose we conduct VLE experiments on our system of interest. At a given temperature, we vary the system pressure by changing the cell volume. Wait until equilibrium is established (usually hours) Measure the compositions of the liquid and vapour CHEE 311 Lecture 15

Liquid Solution Fugacity from VLE Data Our understanding of molecular dynamics does not permit us to predict non-ideal solution fugacities, fil . We must measure them by experiment, often by studies of vapour-liquid equilibria. Suppose we need liquid solution fugacity data for a binary mixture of A+B at P,T. At equilibrium, The vapour mixture fugacity for component i is given by, (11.52) If we conduct VLE experiments at low pressure, but at the required temperature, we can use by assuming that iv = 1. CHEE 311 Lecture 15

Liquid Solution Fugacity from Low P VLE Data Since our experimental measurements are taken at equilibrium, What we need is VLE data at various pressures (all relatively low) Table 12.1 CHEE 311 Lecture 15

Activity Coefficients from Low P VLE Data With a knowledge of the liquid solution fugacity, we can derive activity coefficients. Actual fugacity Ideal solution fugacity Our low pressure vapour fugacity simplifies fil to give: and if P is close to Pisat: leaving us with CHEE 311 Lecture 15

Activity Coefficients from Low P VLE Data Our low pressure VLE data can now be processed to yield experimental activity coefficient data: Table 12.2 CHEE 311 Lecture 15

Activity Coefficients from Low P VLE Data CHEE 311 Lecture 15