Fluid phase behavior of systems involving high molecular weight compounds and supercritical fluids / Pedro F. Arce and Martín Aznar.

Format:

Book

Author/Creator:

Arce, Pedro F.

Contributor:

Aznar, Martín.

Series:

Chemical engineering methods and technology.

Chemical engineering methods and technology

Language:

English

Subjects (All):

Phase rule and equilibrium.

Supercritical fluids.

Molecular weights.

High pressure (Technology).

Fluid dynamics.

Physical Description:

1 online resource (139 p.)

Edition:

1st ed.

Place of Publication:

New York : Nova Science Publishers, c2010.

Language Note:

English

Summary:

Although supercritical fluids (SCF) and their unique solvent characteristics have been a matter of continuing scientific interest since the past century, their potential benefit to chemical processing have not been fully realised; it is only in the past a few years that SCF solvents have been the focus of active research and development programs.

Contents:

Intro

FLUID PHASE BEHAVIOR OF SYSTEMS INVOLVING HIGH MOLECULAR WEIGHT COMPOUNDS AND SUPERCRITICAL FLUIDS

CONTENTS

PREFACE

Chapter 1 ABSTRACT

Chapter 2 INTRODUCTION

Chapter 3 THERMODYNAMIC MODELS

3.1. PERTURBED CHAIN - STATISTICAL ASSOCIATING FLUID THEORY, PC-SAFT

3.2. SANCHEZ-LACOMBE, SL.

3.3. PENG-ROBINSON, PR

Chapter 4 PHASE EQUILIBRIUM AT HIGH-PRESSURES

Chapter 5 RESULTS AND DISCUSSIONS

5.1. EOS PURE-COMPONENT PARAMETERS

5.1.1. Low Molecular Weight Pure-Component Parameters

5.1.2. High Molecular Weight Pure-Component Parameters

5.2. PS + SUPERCRITICAL FLUID SYSTEMS

5.2.1. Pure-Component Parameters

5.2.2. Binary Interaction Parameters.

5.2.3. Modeling Solubility Pressures of Binary Systems

5.2.3.1. PS + Supercritical Fluid Systems

5.2.3.2. PS + Chlorofluorocarbon Fluid Systems

5.2.3.3. PS + Hydrochlorofluorocarbon and PS + Hydrofluorocarbon Fluid Systems

5.3. MOLTEN POLYMER + CO2 SYSTEMS

5.3.1. Evaluation of EoS Pure-Component Parameters

5.3.2. Correlation of GLE Data

5.3.3. HDPE + CO2 and LDPE + CO2 Systems

5.3.4. i-PP + CO2 Systems

5.3.5. P(Vac) + CO2 Systems

5.3.6. PS + CO2 Systems

5.3.7. p(MMA) + CO2 Systems

5.3.8. p(BMA) + CO2 Systems

5.3.9. p(DMS) + CO2 Systems

5.3.10. PC + CO2 Systems

5.4. MODELING OF BINARY AND TERNARY SYSTEMS INVOLVING A BIODEGRADABLE POLYMER, ACOPOLYMER AND A SUPERCRITICAL FLUID

5.4.1. Polymer + Fluid and Copolymer + Fluid Equilibrium

5.4.1.1. PLA + DME System

5.4.1.2. PLA + CO2 System

5.4.1.3. PLA + CDFM System

5.4.1.4. PLA + DFM System

5.4.1.5. PLA + TFM System

5.4.1.6. PLA + TFE System

5.4.1.7. PBS + CO2 System

5.4.1.8. PBSA + CO2 System.

5.4.2. Polymer + Fluid 1 + Fluid 2 Equilibrium

5.4.2.1. PLA + CO2 + DME System

5.5. BIODEGRADABLE COPOLYMER + SUPERCRITICAL FLUID SYSTEMS

5.5.1. PLAG + DME System

5.5.2. PLAG + CO2 System.

5.5.3. PLAG + CDFM System

5.5.4. PLAG + TFM System

5.6. BLOCK COPOLYMER + SUPERCRITICAL CO2 SYSTEMS

5.6.1. p(EO-b-BO) + CO2 System

5.6.2. p(EO-b-PO) + CO2 System

5.6.3. P(Vac-B-AHO) + CO2 System

5.7. POLYMER BLENDS AND POLYMER BLEND + CO2 SYSTEMS

5.7.1. Cloud Points Temperature of Blends

5.7.1.1. PBD/PS Blends

5.7.1.2. PVME/PS Blends

5.7.1.3. PPG/PEGE Blends

5.7.1.4. PEO/PES Blends

5.7.2. Fluid Phase Behavior of PS/PVME Blend + CO2 Systems

Chapter 6 CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

INDEX

Blank Page.

Notes:

Description based upon print version of record.

Includes bibliographical references (p. [113]-121) and index.

Description based on print version record and CIP data provided by publisher.

ISBN:

1-61324-617-X

OCLC:

742350335