Dominic C. Y. Foo – författare

Process Integration Approaches to Planning Carbon Management Networks provides a comprehensive treatment of carbon emissions pinch analysis (CEPA), covering the fundamentals as well as more advanced variants based on mathematical programming. A significant portion of the book is dedicated to case studies that provide a range of examples to demonstrate how CEPA can be applied to practical energy planning problems. Selected chapters also include electronic supplements (e.g., spreadsheet templates and software code) to aid the reader in applying these methods to new sets of data. This book is ideal for academic researchers and graduate students interested in carbon-constrained energy planning models and applications.This book Provides essential information on CEPA and mathematical programming Gives illustrative examples and case studies drawn from contemporary climatic issues Covers state-of-the-art methodological developments Discusses about applications in various countries Offers additional support through supplementary spreadsheet templates and software codeProfessor Dominic Foo is a professor of process design and integration at the University of Nottingham Malaysia. He is a fellow of the Institution of Chemical Engineers, a fellow of the Academy of Science Malaysia, a chartered engineer with the UK Engineering Council, and a professional engineer with the Board of Engineers Malaysia. He works on process integration for resource conservation and CO2 reduction, with more than 400 published works. Prof. Foo is the co-editor-in-chief for Process Integration and Optimization for Sustainability, subject editor for Process Safety & Environmental Protection, and an editorial board member for several other renowned journals. Raymond R. Tan is a professor of chemical engineering and university fellow at De La Salle University, Philippines. He is also a member of the National Academy of Science and Technology of the Philippines. His main areas of research are process systems engineering and process integration, where he has over 300 published works. Prof. Tan received his BS and MS degrees in chemical engineering and PhD in mechanical engineering from De La Salle University. He is also a co-editor-in-chief of Process Integration and Optimization for Sustainability, subject editor of Sustainable Production and Consumption, and an editorial board member of Clean Technologies and Environmental Policy.

Process Integration Approaches to Planning Carbon Management Networks provides a comprehensive treatment of carbon emissions pinch analysis (CEPA), covering the fundamentals as well as more advanced variants based on mathematical programming. A significant portion of the book is dedicated to case studies that provide a range of examples to demonstrate how CEPA can be applied to practical energy planning problems. Selected chapters also include electronic supplements (e.g., spreadsheet templates and software code) to aid the reader in applying these methods to new sets of data. This book is ideal for academic researchers and graduate students interested in carbon-constrained energy planning models and applications.This book Provides essential information on CEPA and mathematical programming Gives illustrative examples and case studies drawn from contemporary climatic issues Covers state-of-the-art methodological developments Discusses about applications in various countries Offers additional support through supplementary spreadsheet templates and software codeProfessor Dominic Foo is a professor of process design and integration at the University of Nottingham Malaysia. He is a fellow of the Institution of Chemical Engineers, a fellow of the Academy of Science Malaysia, a chartered engineer with the UK Engineering Council, and a professional engineer with the Board of Engineers Malaysia. He works on process integration for resource conservation and CO2 reduction, with more than 400 published works. Prof. Foo is the co-editor-in-chief for Process Integration and Optimization for Sustainability, subject editor for Process Safety & Environmental Protection, and an editorial board member for several other renowned journals. Raymond R. Tan is a professor of chemical engineering and university fellow at De La Salle University, Philippines. He is also a member of the National Academy of Science and Technology of the Philippines. His main areas of research are process systems engineering and process integration, where he has over 300 published works. Prof. Tan received his BS and MS degrees in chemical engineering and PhD in mechanical engineering from De La Salle University. He is also a co-editor-in-chief of Process Integration and Optimization for Sustainability, subject editor of Sustainable Production and Consumption, and an editorial board member of Clean Technologies and Environmental Policy.

This book covers recent developments in process systems engineering (PSE) for efficient resource use in biomass conversion systems. It provides an overview of process development in biomass conversion systems with focus on biorefineries involving the production and coproduction of fuels, heating, cooling, and chemicals. The scope includes grassroots and retrofitting applications. In order to reach high levels of processing efficiency, it also covers techniques and applications of natural-resource (mass and energy) conservation. Technical, economic, environmental, and social aspects of biorefineries are discussed and reconciled. The assessment scales vary from unit- to process- and life-cycle or supply chain levels.

The chapters are written by leading experts from around the world, and present an integrated set of contributions. Providing a comprehensive, multi-dimensional analysis of various aspects of bioenergy systems, the book is suitable for both academic researchers and energy professionals in industry.

This book covers recent developments in process systems engineering (PSE) for efficient resource use in biomass conversion systems. It provides an overview of process development in biomass conversion systems with focus on biorefineries involving the production and coproduction of fuels, heating, cooling, and chemicals. The scope includes grassroots and retrofitting applications. In order to reach high levels of processing efficiency, it also covers techniques and applications of natural-resource (mass and energy) conservation. Technical, economic, environmental, and social aspects of biorefineries are discussed and reconciled. The assessment scales vary from unit- to process- and life-cycle or supply chain levels.

The chapters are written by leading experts from around the world, and present an integrated set of contributions. Providing a comprehensive, multi-dimensional analysis of various aspects of bioenergy systems, the book is suitable for both academic researchers and energy professionals in industry.

This book covers recent developments in process systems engineering (PSE) for efficient resource use in biomass conversion systems. It provides an overview of process development in biomass conversion systems with focus on biorefineries involving the production and coproduction of fuels, heating, cooling, and chemicals. The scope includes grassroots and retrofitting applications. In order to reach high levels of processing efficiency, it also covers techniques and applications of natural-resource (mass and energy) conservation. Technical, economic, environmental, and social aspects of biorefineries are discussed and reconciled. The assessment scales vary from unit- to process- and life-cycle or supply chain levels. The chapters are written by leading experts from around the world, and present an integrated set of contributions. Providing a comprehensive, multi-dimensional analysis of various aspects of bioenergy systems, the book is suitable for both academic researchers and energy professionals in industry.

Process Integration Approaches to Planning Carbon Management Networks provides a comprehensive treatment of carbon emissions pinch analysis (CEPA), covering the fundamentals as well as more advanced variants based on mathematical programming. A significant portion of the book is dedicated to case studies that provide a range of examples to demonstrate how CEPA can be applied to practical energy planning problems. Selected chapters also include electronic supplements (e.g., spreadsheet templates and software code) to aid the reader in applying these methods to new sets of data. This book is ideal for academic researchers and graduate students interested in carbon-constrained energy planning models and applications.

This book

Provides essential information on CEPA and mathematical programming

Gives illustrative examples and case studies drawn from contemporary climatic issues

Covers state-of-the-art methodological developments

Discusses about applications in various countries

Offers additional support through supplementary spreadsheet templates and software code

Professor Dominic Foo is a professor of process design and integration at the University of Nottingham Malaysia. He is a fellow of the Institution of Chemical Engineers, a fellow of the Academy of Science Malaysia, a chartered engineer with the UK Engineering Council, and a professional engineer with the Board of Engineers Malaysia. He works on process integration for resource conservation and CO2 reduction, with more than 400 published works. Prof. Foo is the co-editor-in-chief for Process Integration and Optimization for Sustainability, subject editor for Process Safety & Environmental Protection, and an editorial board member for several other renowned journals.

Raymond R. Tan is a professor of chemical engineering and university fellow at De La Salle University, Philippines. He is also a member of the National Academy of Science and Technology of the Philippines. His main areas of research are process systems engineering and process integration, where he has over 300 published works. Prof. Tan received his BS and MS degrees in chemical engineering and PhD in mechanical engineering from De La Salle University. He is also a co-editor-in-chief of Process Integration and Optimization for Sustainability, subject editor of Sustainable Production and Consumption, and an editorial board member of Clean Technologies and Environmental Policy.

Process Integration Approaches to Planning Carbon Management Networks provides a comprehensive treatment of carbon emissions pinch analysis (CEPA), covering the fundamentals as well as more advanced variants based on mathematical programming. A significant portion of the book is dedicated to case studies that provide a range of examples to demonstrate how CEPA can be applied to practical energy planning problems. Selected chapters also include electronic supplements (e.g., spreadsheet templates and software code) to aid the reader in applying these methods to new sets of data. This book is ideal for academic researchers and graduate students interested in carbon-constrained energy planning models and applications.

This book

Provides essential information on CEPA and mathematical programming

Gives illustrative examples and case studies drawn from contemporary climatic issues

Covers state-of-the-art methodological developments

Discusses about applications in various countries

Offers additional support through supplementary spreadsheet templates and software code

Professor Dominic Foo is a professor of process design and integration at the University of Nottingham Malaysia. He is a fellow of the Institution of Chemical Engineers, a fellow of the Academy of Science Malaysia, a chartered engineer with the UK Engineering Council, and a professional engineer with the Board of Engineers Malaysia. He works on process integration for resource conservation and CO2 reduction, with more than 400 published works. Prof. Foo is the co-editor-in-chief for Process Integration and Optimization for Sustainability, subject editor for Process Safety & Environmental Protection, and an editorial board member for several other renowned journals.

Raymond R. Tan is a professor of chemical engineering and university fellow at De La Salle University, Philippines. He is also a member of the National Academy of Science and Technology of the Philippines. His main areas of research are process systems engineering and process integration, where he has over 300 published works. Prof. Tan received his BS and MS degrees in chemical engineering and PhD in mechanical engineering from De La Salle University. He is also a co-editor-in-chief of Process Integration and Optimization for Sustainability, subject editor of Sustainable Production and Consumption, and an editorial board member of Clean Technologies and Environmental Policy.

Presents comprehensive coverage of process intensification and integration for sustainable design, along with fundamental techniques and experiences from the industryDrawing from fundamental techniques and recent industrial experiences, this book discusses the many developments in process intensification and integration and focuses on increasing sustainability via several overarching topics such as Sustainable Manufacturing, Energy Saving Technologies, and Resource Conservation and Pollution Prevention Techniques.Process Intensification and Integration for Sustainable Design starts discussions on: shale gas as an option for the production of chemicals and challenges for process intensification; the design and techno-economic analysis of separation units to handle feedstock variability in shale gas treatment; RO-PRO desalination; and techno-economic and environmental assessment of ultrathin polysulfone membranes for oxygen-enriched combustion. Next, it looks at process intensification of membrane-based systems for water, energy, and environment applications; the design of internally heat-integrated distillation column (HIDiC); and graphical analysis and integration of heat exchanger networks with heat pumps. Decomposition and implementation of large-scale interplant heat integration is covered, as is the synthesis of combined heat and mass exchange networks (CHAMENs) with renewables. The book also covers optimization strategies for integrating and intensifying housing complexes; a sustainable biomass conversion process assessment; and more. Covers the many advances and changes in process intensification and integrationProvides side-by-side discussions of fundamental techniques and recent industrial experiences to guide practitioners in their own processesPresents comprehensive coverage of topics relevant, among others, to the process industry, biorefineries, and plant energy managementOffers insightful analysis and integration of reactor and heat exchanger networkLooks at optimization of integrated water and multi-regenerator membrane systems involving multi-contaminantsProcess Intensification and Integration for Sustainable Design is an ideal book for process engineers, chemical engineers, engineering scientists, engineering consultants, and chemists.

Presents comprehensive coverage of process intensification and integration for sustainable design, along with fundamental techniques and experiences from the industry

Drawing from fundamental techniques and recent industrial experiences, this book discusses the many developments in process intensification and integration and focuses on increasing sustainability via several overarching topics such as Sustainable Manufacturing, Energy Saving Technologies, and Resource Conservation and Pollution Prevention Techniques.

Process Intensification and Integration for Sustainable Design starts discussions on: shale gas as an option for the production of chemicals and challenges for process intensification; the design and techno-economic analysis of separation units to handle feedstock variability in shale gas treatment; RO-PRO desalination; and techno-economic and environmental assessment of ultrathin polysulfone membranes for oxygen-enriched combustion. Next, it looks at process intensification of membrane-based systems for water, energy, and environment applications; the design of internally heat-integrated distillation column (HIDiC); and graphical analysis and integration of heat exchanger networks with heat pumps. Decomposition and implementation of large-scale interplant heat integration is covered, as is the synthesis of combined heat and mass exchange networks (CHAMENs) with renewables. The book also covers optimization strategies for integrating and intensifying housing complexes; a sustainable biomass conversion process assessment; and more.

Covers the many advances and changes in process intensification and integration Provides side-by-side discussions of fundamental techniques and recent industrial experiences to guide practitioners in their own processes Presents comprehensive coverage of topics relevant, among others, to the process industry, biorefineries, and plant energy management Offers insightful analysis and integration of reactor and heat exchanger network Looks at optimization of integrated water and multi-regenerator membrane systems involving multi-contaminants

Process Intensification and Integration for Sustainable Design is an ideal book for process engineers, chemical engineers, engineering scientists, engineering consultants, and chemists.