Determination of Amine Volatility for CO 2 Capture Thu Nguyen January 10, 2008 The University of Texas at Austin Professor Gary Rochelle.

Slides:

Advertisements

Similar presentations

Vapor Pressure William Henry Francois Marie Raoult.

Advertisements

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

A Selection of Physical Chemistry Problems Solved using Mathematica Housam BINOUS National Institute of Applied Sciences and Technology

Solubility of K 2 SO 4 in CO 2 Loaded MEA/PZ Solution Jan 10th, 2008 Qing Xu Rochelle group Department of Chemical Engineering University of Texas at Austin.

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

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

Physical Properties of Solutions.  Homogeneous mixtures: ◦ Solutions – ions or molecules (small particles) ◦ Colloids – larger particles but still uniform.

Chapter 11 1 Ch 11 Page 467. STATES OF MATTER CH CH CH 5The internet? Phase Change- The transformation from one phase to another upon the.

CHEN 4470 – Process Design Practice Dr. Mario Richard Eden Department of Chemical Engineering Auburn University Lecture No. 3 – Overview of Mass Exchange.

Part 2: External Control of Solubility Temperature and Pressure Predictions: Will solubility increase or decrease with increasing temperature? Will solubility.

Gas-Solution Processes Gas Solubility Raoult’s Law Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.

Solution Thermodynamics: Applications

Liquid Phase Properties from VLE Data SVNA 12.1

Solution Thermodynamic:

VAPOR PRESSURE OF WATER Experiment #2. What are we doing in this experiment? 1.Determine the vapor pressure of water at different temperatures. 2. Determine.

Phase Changes Chapter 11. Vaporization An endothermic process in which the intermolecular attractions of a liquid are broken releasing molecules as a.

CHEMISTRY 2000 Topic #3: Thermochemistry and Electrochemistry – What Makes Reactions Go? Spring 2008 Dr. Susan Lait.

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.

Chapter 11 Properties of solutions. Solutions A solution is a homogenous mixture. The solvent does the dissolving. The solute is dissolved by the solvent.

Gases Physical Characteristics of Gases: The Kinetic Theory (a model for gases): 1. Gases consist of a large number of tiny particles with insignificant.

Dr Saad Al-ShahraniChE 334: Separation Processes  Nonideal Liquid Solutions  If a molecule contains a hydrogen atom attached to a donor atom (O, N, F,

Vapor-Liquid Equilibrium (VLE) at Low Pressures

Updates Midterms are Feb. 08 and Mar. 15 at 7pm… anyone with a night class or other midterm will write it at 6 pm (notify me at least 1 week prior if you.

COLLIGATIVE PROPERTIES STRUCTURE MEETS FUNCTION: WHAT PROPERTIES DO SOLUTIONS HAVE AND WHY?

Amine Thermal Degradation By: Jason Davis. Overview Carbamate Polymerization of MEA Background Chemistry Model PZ and MEA/PZ Blends Amine Screening.

CHEMISTRY 2000 Topic #3: Thermochemistry and Electrochemistry – What Makes Reactions Go? Spring 2012 Dr. Susan Lait.

OTHER CONCENTRATION UNITS Yves Alarie, Ph.D Professor Emeritus U niversity of Pittsburgh,USA.

1 Research Review Meeting, Austin, 10-11/I-2008 Thermal measurements: Heat of absorption of CO 2 and Vapour-Liquid Equilibria in alkanolamine-water solutions.

Distillation ... A Separation Method.

University of Auckland New Zealand Geothermal Group Department of Engineering Science Computer Modelling of Gas and Liquid Tracers in Geothermal Reservoirs.

Physical and chemical equilibrium of CO2-Water-Mineral system using Aspen Plus process simulator Technical University of Delft Ali Akbar Eftekhari Hans.

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

Stephanie Freeman January 10 th, 2007 Rochelle Group University of Texas at Austin – Dept. of Chemical Engineering.

Solutions Homogeneous Mixture of 2 or more Substances.

Kinetics of CO2 Absorption into MEA-AMP Blended Solution

Practical Applications of Raman Spectroscopy for Process Analysis

ERT 108/3 PHYSICAL CHEMISTRY FIRST LAW OF THERMODYNAMICS Prepared by: Pn. Hairul Nazirah Abdul Halim.

Solution thermodynamics theory—Part I

January 10-11, 2008 UT Meeting, Texas, USA

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Chemistry FIFTH EDITION Chapter 11 Properties of Solutions

Solutions AP Chemistry.

Solutions. Occur in all phases u The solvent does the dissolving. u The solute is dissolved. u There are examples of all types of solvents dissolving.

Solutions. Occur in all phases u The solvent does the dissolving. u The solute is dissolved. u There are examples of all types of solvents dissolving.

David Van Wagener The University of Texas at Austin Research Review Meeting January 11, 2008.

Dalton’s Law of Partial Pressure

VLE Modeling of Aqueous Solutions of Unloaded and Loaded Hydroxides of Lithium, Sodium and Potassium Shahla Gondal, Muhammad Usman, Juliana G.M.S. Monteiro,

Unit 7.3: Gas Law Calculations. IV) (7.3) Gas Law Calculations a) Introduction: i) You can use the ideal gas law to solve a variety of problems 1) One.

Vapor Pressure. Pressure of the vapor present when equilibrium is achieved between the rate of vaporization and the rate of condensation. At the boiling.

Multicomponent systems

Jet Fuel Vaporization and Condensation: Modeling and Validation Robert Ochs and C.E. Polymeropoulos Rutgers, The State University of New Jersey International.

Atmospheric Chemistry Chemical effects on cloud activation with special emphasis on carbonaceous aerosol from biomass burning M. C. Facchini, S. Decesari,

Kinetic and Thermodynamic Data for MEA and MEA/PZ By: Ross Dugas January 11, 2008.

APPLICATIONS Applications of Raoult’s law

Introduction to phase equilibrium

Ideal and Dilute Solutions 2/21/2016. Master Thermodynamics Equations.

By Marcus Hilliard Gary T. Rochelle The University of Texas at Austin

Aspen RateSep Absorber Model for CO 2 Capture CASTOR Pilot Plant IFP – Lyon, France by: Ross Dugas January 11, 2008

Noorulnajwa Diyana Yaacob PPK Bioproses Universiti Malaysia Perlis MULTIPHASE SYSTEM.

WCB/McGraw-Hill © The McGraw-Hill Companies, Inc.,1998 Thermodynamics Çengel Boles Third Edition 15 CHAPTER Chemical and Phase Equilibrium.

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Chapter 17 Honors Chemistry Thermochemistry.

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

Hydrogen via Thermochemical cycles

Solution of Thermodynamics: Theory and applications

Greenhouse Effect Presented By: Janet Fang Sam Atwood EESC W4400.

Vapor Pressure William Henry Francois Marie Raoult.

5. EXPERIMENT Material: Instrument Experiment condition:

Schedule Today (3/27): Continue Chapter 17

Schedule Today (3/29): Continue Chapter 17

Presentation transcript:

Determination of Amine Volatility for CO 2 Capture Thu Nguyen January 10, 2008 The University of Texas at Austin Professor Gary Rochelle

Outline Scope of Present Work – determine MDEA and PZ volatility Experimental Apparatus – introduce FTIR setup & operation Theory – use Raoult’s Law to measure volatility: partial pressure & activity coefficient) Results – explore volatility in terms of loading, temperature, & amine concentration Future Work -- outline of activities planned

Scope of Present Work Determine PZ and MDEA volatility in blends of varying amine concentrations 1)Explore volatility in terms of Partial Pressure and Activity Coefficient 2)Ask how do these parameters behave with i. CO 2 loading ii. Temperature iii. Varying amine concentration 3) Run experiments at 40ºC and 60ºC

Experimental Apparatus – Stirred Reactor Coupled with FTIR Analysis

-apparatus allows simultaneous measurements of CO 2 solubility and amine volatility -sample line & FTIR are both kept at elevated operating temperature (180ºC) to eliminate condensation / adsorption of vapor amine to surface -FTIR is capable of performing multi-component analysis -gas is returned back to reactor at ~55ºC higher than reactor temp. to avoid rapid condensation / loss of amine species

Theory -activity coefficient is calculated using modified Raoult’s law y i P =γ i * x i * P o y i : vapor phase mole fraction of species i (FTIR) P : total pressure at equilibrium (reactor pressure) γ i : activity coefficient of species i (to be determined) x i : liquid phase mole fraction of species i (Amine Titration) P o : vapor pressure of species i (DIPPR database)

Vapor Pressure Equation (DIPPR Thermodynamic Database) P vap (Pa) = exp [A + B/T + C(ln T) + DT E ] where T is in Kelvin P vap = exp [ /T – 6.65(ln T) e-18(T) 6 for PZ P vap = exp [ /T – 34(ln T) e-5(T) 2 for MDEA model confirmed to provide good consistent estimates of vapor pressures within 283K – 785K range (includes experimental temperatures)

Figure 1. PZ Volatility

Figure 2. Apparent PZ Activity Coefficient

Figure 3. MDEA Volatility

Figure 4. MDEA Activity Coefficient

Conclusions PZ Partial Pressure ~ ppm (40ºC) ppm (60ºC) MDEA Partial Pressure ~ ppm (40ºC) ppm (60ºC)

-Continue amine volatility measurements for: -other blends of varying amine concentrations -focus on volatility in absorber lean & wash water stream -focus on volatility at stripper unit -ROC16 solution -Modeling experimental results to obtain activity coefficient prediction models -NMR Analysis -Heat Capacity Measurements Future Work