Energy from Waste Production and Storage
The conversion of waste into value-added products - such as energy - transforms a potential environmental problem into a sustainable solution. Energy from Waste: Production and Storage focuses on the conversion of waste from various sources into materials for use in energy production and storage app...
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| Main Authors | , |
|---|---|
| Format | eBook Book |
| Language | English |
| Published |
Boca Raton, FL
CRC Press
2022
Taylor & Francis Group |
| Edition | 1 |
| Subjects | |
| Online Access | Get full text |
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| Abstract | The conversion of waste into value-added products - such as energy - transforms a potential environmental problem into a sustainable solution. Energy from Waste: Production and Storage focuses on the conversion of waste from various sources into materials for use in energy production and storage applications. It provides the state of the art in developing advanced materials and chemicals for energy applications using wastes and discusses the various treatment processes and technologies.
Key Features
Covers the synthesis of usable materials from various types of waste and their applications in energy production and storage.
Presents an overview and applications of wastes for green energy production and storage.
Describes the fundamentals of electrochemical behavior and understanding of energy devices such as fuel cells, batteries, supercapacitors, and solar cells.
Elaborates on advanced technologies used to convert waste into green biochemical energy.
This work offers a new direction to scientists, researchers, and students of materials and chemical engineering and related subjects seeking sustainable solutions to energy production and waste management. |
|---|---|
| AbstractList | The conversion of waste into value-added products - such as energy - transforms a potential environmental problem into a sustainable solution. Energy from Waste: Production and Storage focuses on the conversion of waste from various sources into materials for use in energy production and storage applications. It provides the state of the art in developing advanced materials and chemicals for energy applications using wastes and discusses the various treatment processes and technologies.
Key Features
Covers the synthesis of usable materials from various types of waste and their applications in energy production and storage.
Presents an overview and applications of wastes for green energy production and storage.
Describes the fundamentals of electrochemical behavior and understanding of energy devices such as fuel cells, batteries, supercapacitors, and solar cells.
Elaborates on advanced technologies used to convert waste into green biochemical energy.
This work offers a new direction to scientists, researchers, and students of materials and chemical engineering and related subjects seeking sustainable solutions to energy production and waste management. Conversion of waste into value-added products such as energy transforms a potential environmental problem into a sustainable solution. Energy from Waste: Production and Storage focuses on the conversion of waste from various sources for use in energy production and storage applications. It provides the state-of-the-art in developing advanced materials and chemicals for energy applications using wastes and discusses the various treatment processes and technologies. Covers synthesis of usable materials from various types of waste and their application in energy production and storage Presents an overview and applications of wastes for green energy production and storage Provides fundamentals of electrochemical behavior and understanding of energy devices such as fuel cells, batteries, supercapacitors, and solar cells Elaborates on advanced technologies used to convert waste into green biochemical energy This work provides new direction to scientists, researchers, and students in materials and chemical engineering and related subjects seeking to sustainable solutions to energy production and waste management. PART 1 Introduction Chapter 1 Biowastes for Energy: An Introduction Alfred Nkhama, Muhammad Rizwan Sulaiman, Jonghyun Choi, and Ram K. Gupta PART 2 Municipal Waste for Energy Chapter 2 Operational Tools and Techniques for Municipal Solid Waste Management Zobaidul Kabir, Mahfuz Kabir, M. Ashiqur Rahman, and Mofijur Rahman Chapter 3 Municipal Waste for Energy Production Mahfuz Kabir and Zobaidul Kabir Chapter 4 A Brief History of Energy Recovery from Municipal Solid Waste Debra R. Reinhart, Aditi Podder, and Stephanie C. Bolyard Chapter 5 Materials and Energy from Waste Plastics: A Catalytic Approach Shadab Shahsavari, Gita Bagheri, Zahra Shokri, and Shahin Shahsavari Chapter 6 Elucidating Sustainable Waste Management Approaches along with Waste-to-Energy Pathways: A Critical Review Asmita Mishra, Hammad Siddiqi, and B.C. Meikap Chapter 7 Biomass Downdraft Gasifier: State of the Art of Reactor Design Nathada Ngamsidhiphongsa, Phuet Prasertcharoensuk, Yaneeporn Patcharavorachot, and Amornchai Arpornwichanop Chapter 8 Food-Based Waste for Energy Shadab Shahsavari, Zahra Shokri, and Gita Bagheri PART 3 Waste for Biochemicals and Bioenergy Chapter 9 Biowastes for Ethanol Production Jeffin James Abraham, Christian Randell A. Arro, Ali A. El-Samak, Alaa H. Hawari, and Deepalekshmi Ponnamma Chapter 10 Waste Feedstocks for Biodiesel Production Umer Rashid, Rose Fadzilah Abdullah, Balkis Hazmi, and Wan Nur Aini Wan Mokhtar Chapter 11 Biowaste-Based Microbial Fuel Cells for Bioelectricity Generation Bhim Sen Thapa and T. S Chandra Chapter 12 Biowaste-Based Microbial Fuel Cells Nidhi Chauhan, Utkarsh Jain, and Kirti Saxena Chapter 13 Recent Development in Microbial Fuel Cells Using Biowaste Abhinay Thakur, Shveta Sharma, and Ashish Kumar Chapter 14 Waste-Derived Carbon Materials for Hydrogen Storage Mohamed Aboughaly and Hossam A. Gabbar Chapter 15 Organic Waste for Hydrogen Production Yassine Slimani and Essia Hannachi Chapter 16 Recycling E-Waste for Hydrogen Energy Production and Replacement as Building Construction Materials Ramji Kalidoss, Radhakrishnan Kothalam, and Ganesh Vattikondala PART 4 Waste for Advanced Energy Devices Chapter 17 Biowaste-Derived Carbon for Solar Cells Fahmeeda Kausar, Jazib Ali, Ghulam Abbas Ashraf, and Muhammad Bilal Chapter 18 Biowastes for Metal-Ion Batteries C. Nithya Chapter 19 NaFePO4 Regenerated from Failed Commercial Li-Ion Batteries for Na-Ion Battery Applications Dona Susan Baji, Anjali V. Nair, Shantikumar Nair, and Dhamodaran Santhanagopalan Chapter 20 Polymeric Wastes for Metal-Ion Batteries Ranjusha Rajagopalan and Haiyan Wang Chapter 21 Biowaste-Derived Components for Zn–Air Battery Yiyang Liu, Tasnim Munshi, Jennifer Hack, Ian Scowen, Paul R. Shearing, Guanjie He, and Dan J. L. Brett Chapter 22 Recycling of Wastes Generated in Automobile Metal–Air Batteries Weng Cheong Tan, Lip Huat Saw, Ming Chian Yew, and Ming Kun Yew Chapter 23 Biowastes for Metal–Sulfur Batteries Chaofeng Zhang, Quanwei Ma, Longhai Zhang, Rui Wang, Hao Li, Tengfei Zhou, and Changzhou Yuan Chapter 24 High-Performance Supercapacitors Based on Biowastes for Sustainable Future Kwadwo Mensah-Darkwa, Stefania Akromah, Benjamin Agyei-Tuffour, David Dodoo-Arhin, Anuj Kumar, and Ram K. Gupta Chapter 25 Hybrid Biowaste Materials for Supercapacitors Prashant Dubey, Ashwinder Kaur, Vishal Shrivastav, Isha Mudahar, Sunita Mishra, and Shashank Sundriyal Chapter 26 Polymeric Wastes for Supercapacitors Fabeena Jahan, Deepthi Panoth, Sindhu Thalappan Manikkoth, Kunnambeth M. Thulasi, Anjali Paravannoor, and Baiju Kizhakkekilikoodayil Vijayan Chapter 27 Carbon Nanostructures Derived from Polymeric Wastes for Supercapacitors Vanessa Hafemann Fragal, Elisangela Pacheco da Silva, Elizangela Hafemann Fragal, Michelly Cristina Galdioli Pella, Thiago Sequinel, Rafael Silva, Cristian Tessmer Radmann, Vanessa Bongalhardo Mortola, and Luiz Fernando Gorup Chapter 28 Supercapacitors Based on Waste Generated in Automobiles Souhardya Bera and Subhasis Roy Chapter 29 Halogenated Polymeric Wastes for Green Functional Carbon Materials Yingna Chang, Zongge Li, and Guoxin Zhang Chapter 30 Waste Mechanical Energy Harvesting from Vehicles by Smart Materials Omer Faruk Unsal and Ayşe Celik Bedeloğlu Index Ram K. Gupta is Associate Professor at Pittsburg State University. Dr. Gupta’s research focuses on green energy production and storage using conducting polymers and composites, electrocatalysts for fuel cells, nanomaterials, optoelectronics and photovoltaics devices, organic-inorganic hetero-junctions for sensors, nanomagnetism, bio-based polymers, bio-compatible nanofibers for tissue regeneration, scaffold and antibacterial applications, and biodegradable metallic implants. Dr. Gupta has published over 200 peer-reviewed articles, made over 275 national/international/ regional presentations, chaired many sessions at national/international meetings, wrote several book chapters, and received over $2.5 million for research and educational activities from external agencies. He serves as associate editor, guest editor, and editorial board member for various journals. Tuan Anh Nguyen earned his BSc in Physics from Hanoi University in 1992, and his Ph.D. in Chemistry from Paris Diderot University (France) in 2003. He was a Visiting Scientist at Seoul National University (South Korea, 2004) and the University of Wollongong (Australia, 2005). He then worked as a Postdoctoral Research Associate & Research Scientist at Montana State University (USA), 2006-2009. In 2012, he was appointed as Head of Microanalysis Department at the Institute for Tropical Technology (Vietnam Academy of Science and Technology). He has managed 4 Ph.D. theses as thesis director and 3 are in progress; He is Editor-In-Chief of "Kenkyu Journal of Nanotechnology & Nanoscience" and Founding Co-Editor-In-Chief of "Current Nanotoxicity & Prevention". He is the author of 4 Vietnamese books and Editor of 32 Elsevier books in the Micro & Nano Technologies Series. This book focuses on the conversion of waste from various sources for use in energy production and storage applications. It provides the state-of-the-art in developing advanced materials and chemicals for energy applications using wastes and discusses the various treatment processes and technologies. Conversion of waste into value-added products such as energy transforms a potential environmental problem into a sustainable solution. Energy from Waste: Production and Storage focuses on the conversion of waste from various sources for use in energy production and storage applications. It provides the state-of-the-art in developing advanced materials and chemicals for energy applications using wastes and discusses the various treatment processes and technologies. Covers synthesis of usable materials from various types of waste and their application in energy production and storage Presents an overview and applications of wastes for green energy production and storage Provides fundamentals of electrochemical behavior and understanding of energy devices such as fuel cells, batteries, supercapacitors, and solar cells Elaborates on advanced technologies used to convert waste into green biochemical energy This work provides new direction to scientists, researchers, and students in materials and chemical engineering and related subjects seeking to sustainable solutions to energy production and waste management. |
| Author | Tuan Anh Nguyen Ram K. Gupta |
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| Copyright | 2022 Taylor & Francis Group, LLC |
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| Edition | 1 First edition. |
| Editor | Gupta, Ram K. Nguyen, Tuan Anh |
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| Keywords | Hydrogen Production Energy Density Mesoporous Carbon valorization Ad Single Chamber MFC Supercapacitors automobile waste MECs ethanol MFCs Porous Carbon Energy Recovery Lithium Ion Batteries MSW Management zero waste fuel cells Heteroatom Doping Air Cathodes Metal Air Batteries Energy Sources AC Electrode Materials metal-sulfur batteries metal-ion batteries Electric Vehicles biodiesel hydrogen production metal-air batteries Polymer Waste American Chemical Society HTC Electrochemical Performance Carbon Materials HPC Moisture Content |
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| Language | English |
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| Notes | Summary: "Conversion of waste into value-added products such as energy transforms a potential environmental problem into a sustainable solution. This book focuses on the conversion of waste from various sources for use in energy production and storage applications. It provides state-of-the-art methods for developing advanced materials and chemicals for energy applications using waste, and discusses the various treatment processes and technologies. This work provides new direction to scientists, researchers, and students in materials and chemical engineering and related subjects seeking sustainable solutions to energy production and waste management"- Provided by publisher Includes bibliographical references and index |
| OCLC | 1306060543 |
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| PublicationCentury | 2000 |
| PublicationDate | 2022 20220328 2022-03-28 |
| PublicationDateYYYYMMDD | 2022-01-01 2022-03-28 |
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| PublicationDecade | 2020 |
| PublicationPlace | Boca Raton, FL |
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| PublicationYear | 2022 |
| Publisher | CRC Press Taylor & Francis Group |
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| Snippet | The conversion of waste into value-added products - such as energy - transforms a potential environmental problem into a sustainable solution. Energy from... Conversion of waste into value-added products such as energy transforms a potential environmental problem into a sustainable solution. Energy from Waste:... This book focuses on the conversion of waste from various sources for use in energy production and storage applications. It provides the state-of-the-art in... |
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| SubjectTerms | automobile waste biodiesel hydrogen production Biomass energy Catalysis Chemical Processing & Design CHEMICALENGINEERINGnetBASE CHEMLIBnetBASE Clean Technologies Energy & Fuels ENERGYANDCLEANTECHnetBASE ENVIROnetBASE ENVIRONMENTALENGINEERINGnetBASE ethanol metal-air batteries metal-ion batteries metal-sulfur batteries Refuse as fuel Renewable Energy SCI-TECHnetBASE STMnetBASE Supercapacitors Traditional Industries - Clean & Green Advancements valorization Waste & Recycling Waste products as fuel zero waste fuel cells |
| Subtitle | Production and Storage |
| TableOfContents | 10.5.4 Cetane Number -- 10.6 Engine Performance and Emissions -- 10.6.1 Engine Performance -- 10.6.2 Exhaust Emissions -- 10.7 Conclusions -- References -- Chapter 11 Biowaste-Based Microbial Fuel Cells for Bioelectricity Generation -- 11.1 Introduction -- 11.2 Principle of MFC -- 11.3 Factors Affecting the Recovery of Energy from Wastewater in MFC -- 11.3.1 Microbial Inoculum -- 11.3.2 Cathode Reaction -- 11.3.3 Separator and Ion Exchange Membrane -- 11.3.4 Design and Configuration of the System -- 11.3.5 Hydraulic Retention Time -- 11.4 Treatment of Hazardous Pollutants in MFC -- 11.4.1 Reduction and Recovery of Heavy Metals -- 11.4.2 Dyes Reduction -- 11.5 Use of Modified Electrodes for Performance Improvement. -- 11.6 Large-Scale Implications of MFC in Wastewater Treatment and Electricity Production -- 11.7 Future Prospective and Conclusions -- References -- Chapter 12 Biowaste-Based Microbial Fuel Cells -- 12.1 Introduction -- 12.2 Different Types of Biowaste Exploited as Substrate -- 12.2.1 Food or Kitchen Waste -- 12.2.2 Paper Industry Waste -- 12.2.3 Lignocellulosic Biomaterials -- 12.2.4 Animal Waste -- 12.2.5 Municipal Solid Waste -- 12.3 Biowaste to Bioenergy Conversion -- 12.4 Biowaste-Based MFC -- 12.5 Applications -- 12.5.1 Bioelectricity Production -- 12.5.2 Wastewater Treatment -- 12.5.3 Removal/Recovery of Heavy Metals -- 12.5.4 Biohydrogen Production -- 12.5.5 Biosensor Fabrication -- 12.5.6 Bioremediation -- 12.6 Challenges and Future Perspectives -- References -- Chapter 13 Recent Development in Microbial Fuel Cells Using Biowaste -- 13.1 Introduction -- 13.2 Microbial Fuel Cells -- 13.2.1 Structural Configurations -- 13.3 Types of MFCs on the Basis of Commercialization -- 13.3.1 Low-Cost MFCs -- 13.3.2 Compost-Based MFCs -- 13.4 Fundamental Bioelectricity Generation in MFCs Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- Preface -- Editors -- List of Contributors -- PART 1 Introduction -- Chapter 1 Biowastes for Energy: An Introduction -- 1.1 Introduction -- 1.2 Source and Significance of Biowastes -- 1.2.1 Biowastes from Forest and Wood Processing Industries -- 1.2.2 Biowaste from Food Processing -- 1.2.3 Biowaste from the Paper Industry -- 1.2.4 Biowaste from Municipal Solid -- 1.2.5 Animal Waste -- 1.3 Pretreatment of Biowaste -- 1.3.1 Pretreatment of Animal Fat Waste -- 1.3.2 Lignocellulosic Waste Pretreatment -- 1.3.3 Pretreatment of Waste Cooking Oil -- 1.3.4 Removal of Inhibitory Compounds and Salts -- 1.4 Biowaste to Bioenergy -- 1.4.1 Biodiesel from Biowaste -- 1.4.2 Biogas from Biowaste -- 1.4.3 Bioelectricity from Biowaste -- 1.4.4 Bioalcohol from Biowaste -- 1.4.5 Electrochemical Energy from Biowastes -- 1.5 Conclusions -- References -- PART 2 Municipal Waste for Energy -- Chapter 2 Operational Tools and Techniques for Municipal Solid Waste Management -- 2.1 Introduction -- 2.2 An Overview of Available Tools and Techniques for MSW Management -- 2.2.1 Source Reduction -- 2.2.2 Reuse and Recycling -- 2.2.3 Landfilling -- 2.2.4 Composting -- 2.2.5 Gasification -- 2.2.6 Incineration -- 2.2.7 Pyrolysis -- 2.2.8 Anaerobic Digestion -- 2.3 Experiences from Selected Innovative Approaches -- 2.3.1 Australia's Waste and Resource Recovery Infrastructure -- 2.3.2 Waste-to-Energy Facility in Singapore -- 2.4 Conclusions -- References -- Chapter 3 Municipal Waste for Energy Production -- 3.1 Introduction -- 3.2 Techniques of Generating Energy from MSW -- 3.3 Improved and Emerging Technologies of MSW-to-Energy -- 3.4 Good Practices and Potential of MSW-to-Energy -- 3.5 Conclusions -- References -- Chapter 4 A Brief History of Energy Recovery from Municipal Solid Waste -- 4.1 Introduction 8.2.4 Bioelectrochemical Systems -- 8.3 Useful Products from Food Waste -- 8.3.1 Gaseous-State Products -- 8.3.1.1 Biogas (Biomethane) -- 8.3.1.2 Synthetic Gas (Syngas) -- 8.3.1.3 Biohydrogen -- 8.3.2 Liquid-state Products -- 8.3.2.1 Biodiesel -- 8.3.2.2 Bioethanol -- 8.3.2.3 Pyrolysis Oil (Bio-Oil) -- 8.3.3 Solid-State Products -- 8.3.3.1 Biochar (Hydrochar) -- 8.3.3.2 Compost -- 8.4 Conclusions -- References -- PART 3 Waste for Biochemicals and Bioenergy -- Chapter 9 Biowastes for Ethanol Production -- 9.1 Introduction -- 9.1.1 What Are Biofuels and Biomass? -- 9.1.2 What Are Biowastes? -- 9.1.3 Why Bioethanol? -- 9.1.4 Global Production of Biofuels and Bioethanol -- 9.2 The Sources of Bioethanol -- 9.3 Mechanism of Bioethanol Production -- 9.3.1 Hydrolysis Process -- 9.3.1.1 First-Generation Hydrolysis -- 9.3.1.2 Second-Generation Hydrolysis -- 9.3.2 Detoxification Process -- 9.3.3 Fermentation Process -- 9.4 Bioethanol Production Systems -- 9.4.1 Production Systems Based on First-Generation Feedstocks -- 9.4.1.1 Sugar-Based Feedstocks -- 9.4.1.2 Starch-Based Feedstock -- 9.4.2 P roduction Systems Based on Second-Generation Feedstock -- 9.4.2.1 Physical Pretreatment -- 9.4.2.2 Chemical Pretreatment -- 9.4.2.3 Physiochemical Pretreatment -- 9.4.2.4 Biological Pretreatment -- 9.5 Brief Evaluation on the Market of Bioethanol Production from Biowastes -- 9.6 Conclusions -- References -- Chapter 10 Waste Feedstocks for Biodiesel Production -- 10.1 Introduction -- 10.2 Waste Oils -- 10.2.1 WCO -- 10.2.2 FOG -- 10.2.3 PFAD -- 10.2.4 POME -- 10.3 Physical and Chemical Properties of Waste Oil -- 10.3.1 Moisture Content -- 10.3.2 Acid Number -- 10.3.3 Saponification Value (SV) -- 10.4 Production of Biodiesel from Waste Oil -- 10.5 Biodiesel Properties -- 10.5.1 Density and Kinematic Viscosity -- 10.5.2 Flash Point -- 10.5.3 Cloud Point and Pour Point 13.5 Progress in the Development of Cost-Effective Electrode Materials for MFCs 4.2 History of MSW Disposal -- 4.3 Thermal and Biological Energy Conversion Processes -- 4.4 Waste-to-Energy - Landfilling -- 4.4.1 Landfill Gas Production -- 4.4.2 Energy Recovery and Utilization -- 4.4.3 Limitations and Challenges -- 4.5 Anaerobic Digestion -- 4.5.1 Limitations and Challenges -- 4.6 Incineration -- 4.6.1 Incineration Process Basics -- 4.6.2 Process Design and Operation Optimization over Time -- 4.6.3 Limitations and Challenges -- 4.7 Gasification and Pyrolysis -- 4.7.1 Processes Overview -- 4.7.2 Limitations and Challenges -- 4.8 Energy Analysis -- 4.9 Country Economies and MSW Energy Potential -- 4.10 Future of Energy Recovery from Waste -- References -- Chapter 5 Materials and Energy from Waste Plastics: A Catalytic Approach -- 5.1 Pyrolysis-Catalysis of Waste Plastics -- 5.1.1 Hydrogen Gas Production from Wastage Plastics -- 5.1.1.1 Reactor Design for Hydrogen-Rich Gas Production from Wastage of Plastics -- 5.1.1.2 The Effect of Operational Parameters on the Level of Hydrogen Production from Plastic Wastages -- 5.1.1.3 The Effect of Catalyst Type on the Level of Hydrogen Production from Waste Plastics -- 5.1.1.4 The Effect of Catalyst Temperature on Hydrogen Production from Waste Plastics -- 5.1.2 Carbon Nanotubes Production from Waste Plastics -- 5.1.2.1 The Effect of Operational Parameters on the Production of Carbon Nanotubes from Waste Plastics -- 5.2 Nanocatalysts in Water Treatment -- 5.2.1 Zero-valent Iron Nanoparticles as Catalysts -- 5.2.2 Titanium Dioxide as Catalysts -- 5.2.3 Nanostructured Iron Oxide as Catalysts -- 5.2.4 Magnetic Nanoparticles as Catalysts -- 5.2.5 Other Nanomaterials as Catalysts -- 5.3 Biocatalysts for Converting Keratin Waste -- 5.4 Catalysts for Biofuels Production from Waste Biomass -- References Chapter 6 Elucidating Sustainable Waste Management Approaches along with Waste-to-Energy Pathways: A Critical Review -- 6.1 Introduction -- 6.2 Wastes and Their Types -- 6.2.1 Agricultural Waste -- 6.2.2 Domestic Waste -- 6.2.3 Industrial Waste -- 6.2.4 Biomedical Waste -- 6.2.4.1 The Risks Associated with Biomedical Waste -- 6.2.5 E-Waste -- 6.2.6 Nuclear Waste -- 6.3 Sustainable Waste Management Approaches -- 6.4 Waste-to-Energy Technology -- 6.4.1 Conventional Methods -- 6.4.2 Future Trends and Developing Technology -- 6.5 Conclusions -- References -- Chapter 7 Biomass Downdraft Gasifier: State of the Art of Reactor Design -- 7.1 Introduction -- 7.2 Downdraft Biomass Gasification Process -- 7.3 Preliminary Calculation for Designing Downdraft Gasifiers -- 7.4 Design of Downdraft Gasifier -- 7.4.1 Imbert-Type Downdraft Gasifier -- 7.4.2 Stratified Downdraft Gasifier -- 7.4.3 Modified Downdraft Gasifier Designs -- 7.4.3.1 Internal Recycling of Pyrolysis Gas -- 7.4.3.2 Separating Gasifier into Two Stages -- 7.4.3.3 Supplying More Air Stages -- 7.4.3.4 Adjusting Throat Diameter -- 7.4.3.5 Extending Reduction Zone Length -- 7.5 Status of Downdraft Gasifier Designs -- 7.5.1 Multi-stage downdraft gasifier by Tarpo -- 7.5.2 Moving Injection Horizontal Gasification (MIHG) Technology by Wildfire Energy -- 7.5.3 GP750 Gasifier Design -- 7.6 Conclusions -- Acknowledgments -- References -- Chapter 8 Food-Based Waste for Energy -- 8.1 Introduction -- 8.2 Current Conversion Technologies for Waste to Energy -- 8.2.1 Biological Technology -- 8.2.1.1 Composting -- 8.2.1.2 Anaerobic Digestion -- 8.2.1.3 Fermentation -- 8.2.2 Thermal and Thermochemical Technology -- 8.2.2.1 Incineration -- 8.2.2.2 Pyrolysis -- 8.2.2.3 Gasification -- 8.2.2.4 Plasma Treatment -- 8.2.2.5 Hydrothermal Carbonization -- 8.2.3 Transesterification (Esterification |
| Title | Energy from Waste |
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