Offshore Processing of CO2-Rich Natural Gas with Supersonic Separator, 1st ed. 2019 Multiphase Sound Speed, CO2 Freeze-Out and HYSYS Implementation

This book introduces a new and powerful approach based on rigorous process simulations conducted with professional simulators like HYSYS to predict the performance of supersonic separators (SS). The book addresses the utilization of SSs for the offshore processing of CO2-rich natural gas as an alternative to Joule-Thomson expansion, glycol absorption, membrane permeation and chemical absorption. It describes and analyzes the conventional offshore processing of CO2-rich natural gas, discussing the advantages of SS in terms of cost and power consumption. The book offers a comprehensive framework for modeling SS units, describing the physical principles of SS in detail. The thermodynamic multiphase sound speed is also discussed at the light shed by a classical analysis based on the Landau Model of phase transitions. A complete framework is presented for modelling and simulating SS units within HYSYS environment. A special chapter is dedicated to the performance of SSs for removing CO2 from CO2-rich natural gas, taking into account the limitations of CO2 freeze-out in various scenarios of gas feed in terms of CO2 content, pressure and temperature.

Introduction.- Conventional Offshore Processing of Co2 Rich Natural Gas.- Introducing Natural Gas Processing with Supersonic Separator.- Thermodynamic Modeling of Co2-Rich Natural Gas Systems.- Thermodynamic Speed of Sound for Multiphase Multi-Reactive Equilibrium Systems.- Hysys Modeling of Supersonic Separators and Membrane Permeation Units for Processing of Co2-Rich Natural Gas.- Modeling of Co2 Freeze-Out in the Processing of Co2-Rich Natural Gas.- Offshore Processing of Co2 Rich Natural Gas with Supersonic Separators Versus Conventional Routes.- Thermodynamic Hydrate Inhibitors in Offshore Processing of Natural Gas: Recovery of Methanol, Ethanol and Monoethylene Glycol Via Gas Processing with Supersonic Separators.

- Prof. Dr. Ofélia de Queiroz Fernandes Araújo: She holds a PhD (1987) and MSc (1984) degrees in Chemical Engineering from the University of Illinois at Urbana-Champaign (USA), and BSc in Chemical Engineering from the Federal University of Rio de Janeiro (1981), Brazil. Worked at NATRON SA (1987-198) and OXITENO SA (1989-1993) in process simulation and control engineering. Joined the Federal University of Rio de Janeiro, in 1993, in the Chemical Engineering Department, where she is currently Associate Professor. Her research interests are process and environmental engineering, with special focus in natural gas processing, and CO2 separation and utilization, and green engineering. She was head of two graduate programs - Technology of Chemical and Biochemical Processes (2007-2010) and Environmental Engineering (2014-2015).

 

- Prof. Dr. José Luiz de Medeiros: He graduated in Chemical Engineering at Federal University of Rio de Janeiro (1980), Brazil. He earned MSc (1982) and DSc (1990) Chemical Engineering degrees from the same institution. He is currently an Assistant Professor in the Department of Chemical Engineering at Federal University of Rio de Janeiro since 1990. He has experience in several sectors of chemical engineering with emphasis in Petroleum, Natural Gas and Petrochemistry, with several published works in the following research lines: Applied Thermodynamics, Separation Processes, Process Identification & Optimization, Statistical & Mathematical Methods. His fields of study concentrate on Compositional Modeling, Hydro-treatment & Hydrocracking of Oil Fractions, Compressible & Incompressible Flows and Associate Separation Technologies, Flow Assurance in Natural Gas Systems, Pipeline Network Modeling for Natural Gas & Oil Transportation, Leak Detection in Compressible & Incompressible Pipeline Networks, Chemical Sequestration of CO2 , Capture of CO2 & H2S from Natural Gas via Membrane Permeation and Technologies of Contact with Aqueous

Presents the conceptual aspects of offshore processing of raw natural gas with supersonic separators in comparison to processing with conventional technologies Discusses in detail the concept and theory of generalized multiphase and multi-reactive speed of sound as a thermodynamic property and how to calculate it in HYSYS process simulators Provides a complete theoretical framework for modeling supersonic separators for the removal of condensable species such as water and heavy hydrocarbons from natural gas Describes process flowsheets for the removal of water and heavy hydrocarbons from natural gas using supersonic separators, comparing the economic and energy performance with conventional approaches Details how CO2 freeze-out introduces issues and limitations affecting the performance of supersonic separators