Sustainable resource management : technologies for recovery and reuse of energy and waste materials / edited by Wenshan Guo [and three others].

Format:

Book

Contributor:

Guo, Wenshan, editor.

Language:

English

Subjects (All):

Recycling (Waste, etc.)--Technological innovations.

Recycling (Waste, etc.).

Physical Description:

1 online resource (821 pages)

Edition:

1st ed.

Place of Publication:

Weinheim, Germany : Wiley-VCH, [2021]

Summary:

Sustainable Resource Management Learn how current technologies can be used to recover and reuse waste products to reduce environmental damage and pollution In this two-volume set, Sustainable Resource Management: Technologies for Recovery and Reuse of Energy and Waste Materials delivers a compelling argument for the importance of the widespread.

Contents:

Cover

Title Page

Copyright

Contents

Preface

Chapter 1 Resource Recovery and Reuse for Sustainable Future Introduction and Overview

1.1 Introduction

1.2 Background

1.2.1 Hierarchy of Resource Use

1.2.2 Analyzing the Needs for Resource and Energy Recovery and Reuse

1.2.2.1 Population Growth

1.2.2.2 Resource Scarcity

1.2.2.3 Environmental Impacts

1.2.2.4 Economical Aspect

1.3 Current Status of Resource Recovery and Reuse

1.3.1 Wastewater

1.3.1.1 Nutrient Recovery

1.3.1.2 Organic Carbon Recovery

1.3.1.3 Heat Recovery

1.3.2 Waste

1.4 Research Needs

1.4.1 Development of Novel Technologies

1.4.2 Social and Economic Feasibility of Resource Recovery and Reuse

1.4.3 Development of Internationally Coordinated Framework and Strategy

1.5 Book Overview

References

Chapter 2 Hydrothermal Liquefaction of Food Waste: A Potential Resource Recovery Strategy

2.1 Introduction

2.1.1 Global Food Waste Production

2.1.2 Conventional Food Waste Management Practices

2.1.2.1 Land Filling

2.1.2.2 Fertilizer/Animal Feed

2.1.2.3 Incineration

2.1.2.4 Composting

2.1.3 Advanced Food Waste Management Methods

2.1.3.1 Acidogenesis

2.1.3.2 Solventogenesis

2.1.3.3 Biodiesel

2.1.3.4 Bioplastics

2.2 Significance of Hydrothermal Liquefaction of Food Waste

2.2.1 HTL Reactor Operation

2.2.2 Isothermal HTL and Fast HTL

2.2.3 HTL Products

2.2.4 Greenhouse Gas Emissions

2.3 Factors Influencing HTL During FW Treatment

2.3.1 Temperature

2.3.2 Reaction Time

2.3.3 Solid‐to‐Solvent Ratio

2.3.4 Composition of Food Waste

2.3.5 Catalyst Concentration

2.4 HTL of Food Waste: Case Studies

2.5 Conclusions and Future Scope

Acknowledgement

Chapter 3 Coping with Change: (Re) Evolution of Waste Management in Local Authorities in England.

3.1 Introduction

3.2 Sustainability Transitions Literature

3.3 Waste Management in England

3.4 Research Design and Methods

3.4.1 Research Design

3.4.2 Methods

3.4.3 Selection of Interviewees

3.4.4 Secondary Data

3.5 Results and Discussion

3.5.1 English Waste in the Context of the EU

3.5.2 Influences in the UK Context for LAs

3.5.3 Implementation of the 2000 Waste Strategy

3.5.3.1 LA Implementation of Waste Policy

3.5.3.2 Targets

3.5.3.3 Financial Instruments

3.5.3.4 Regional Governance

3.5.4 Local Authorities and the Public

3.5.5 Legacy of the Strategy

3.6 Conclusions

Acknowledgements

Chapter 4 Hydrothermal Liquefaction of Lignocellulosic Biomass for Bioenergy Production

4.1 Introduction

4.2 Composition of Lignocellulosic Biomass and their Degradation in HTL Processes

4.2.1 Composition of Lignocellulosic Biomass

4.2.2 Brief Review on the Development of HTL Technology

4.2.3 Main Components Degradation of the Lignocellulosic Biomass During HTL

4.2.3.1 Cellulose and its Degradation in HTL Processes

4.2.3.2 Hemicellulose and its Degradation in HTC Process

4.2.3.3 Lignin and its Degradation in HTC Processes

4.3 Research Status in HTL of Lignocellulosic Biomass

4.3.1 Products Description

4.3.1.1 Bio‐oil

4.3.1.2 Solid Residue

4.3.1.3 Other By‐products

4.3.2 Operating Parameters for Bio‐oil Production by HTL

4.3.2.1 Bio‐oil

4.3.2.2 Temperature

4.3.2.3 Heating Rate

4.3.2.4 Residence Time

4.3.2.5 Pressure

4.3.2.6 Catalysts

4.3.2.7 Liquid‐to‐Solid Ratio

4.4 Limitations and Prospects for Bioenergy Production from Lignocellulosic Biomass by HTL

4.4.1 Poor Quality of Crude Bio‐oil

4.4.2 Aqueous By‐products Utilization

4.4.3 Prospects

4.5 Conclusion and Future Work

References.

Chapter 5 Resource Recovery‐Oriented Sanitation and Sustainable Human Excreta Management

5.1 Introduction

5.2 Present Scenario

5.2.1 Ecological Sanitation

5.2.1.1 Rottebehaelter and Centrifugal Separation Sanitation

5.2.1.2 Biofilters, Vermicomposting Units, Bag Toilets

5.2.2 Failure, Success, and Lessons

5.3 Resource Recovery Options in Rural Areas

5.3.1 Nutrient Recovery from Urine

5.3.2 Anaerobic Digestion or Composting?

5.3.3 Community‐Scale or Household Models?

5.4 Resource Recovery Sanitation in Urban Context

5.4.1 Energy Matters

5.4.2 Johkasou Systems

5.4.3 Possibilities of Industrial‐Scale Units

5.5 Life Cycle Assessment of Sanitation Systems

5.6 Human Excreta and Sustainable Future

5.6.1 Economics of Resource Recovery Sanitation

5.6.2 Sanitation Access and Resource Recovery

5.7 Conclusion and Recommendations

Chapter 6 Resource Recovery and Recycling from Livestock Manure: Current Statue, Challenges, and Future Prospects for Sustainable Management

6.1 Introduction

6.2 Present Scenario and Global Perspective of Manure Generation and Recycling

6.2.1 Sanitization and Hygiene in Manure Management

6.2.1.1 Aerobic Composting

6.2.2 Importance and Significance of Resource Recovery

6.2.2.1 Nitrogen and Phosphorus Recovery from Livestock Manure

6.2.2.2 Heavy Metal Recovery from Livestock Manure

6.3 Resource Recovery Technologies and Logistics for Handling, Transport, and Distribution of Manures

6.3.1 Nutrient Recovery from Manure

6.3.2 Bioenergy Production by Anaerobic Digestion/Co‐digestion

6.3.3 Composting/Co‐composting

6.3.4 Centralized and De‐centralized Models?

6.4 Energy Matters and Economic Feasibility

6.4.1 Energy Production

6.4.2 Mineral Reutilization

6.4.2.1 Ammonia Stripping

6.4.2.2 Struvite Crystallization.

6.4.2.3 Mineral Concentrates

6.5 Resource Recovery Sanitation in Developed and Developing Countries

6.5.1 Operational Guidelines for Septage Treatment and Disposal

6.5.1.1 Storage

6.5.1.2 Pasteurization

6.5.1.3 Chemical Treatments

6.5.1.4 Anaerobic Treatments

6.5.1.5 Composting

6.5.2 Testing the Possibilities of Commercial‐Scale Resource Recovery

6.6 Life Cycle Assessment of Sustainable Manure Management Systems

6.7 Innovation in Sustainable Manure Management Systems and Recycling

6.7.1 Economics of Resource Recovery from Manure and Sanitation

6.7.2 Business Models for a Circular Economy

6.7.3 Enabling Environment Sanitation and Financing for Resource Recovery

6.8 Challenges and Limitation

6.9 Conclusion and Future Prospects

Chapter 7 Utilization of Microalgae and Thraustochytrids for the Production of Biofuel and Nutraceutical Products

7.1 Introduction

7.1.1 Microalgae

7.1.2 Thraustochytrids

7.1.3 Biodiesel and Biobased Jet Fuel

7.1.4 Docosahexaenoic Acid (DHA) and Eicosapentaenoic Acid (EPA)

7.2 Microalgae for Biodiesel and Jet Fuel Production

7.2.1 Selection of Microalgae

7.2.2 Processes of Microalgae to Biofuel

7.2.2.1 Microalgae Cultivation

7.2.2.2 Microalgae Harvesting

7.2.2.3 Extraction of Oil from Microalgae

7.2.2.4 Biodiesel Production from Microalgal Oil

7.2.2.5 Jet Fuel Production from Microalgal Oil

7.3 Thraustochytrids for Biodiesel Production

7.4 Challenges of Microalgae and Thraustochytrids to Biofuel

7.5 Microalgae and Thraustochytrids for DHA and EPA Productions

7.6 Future Perspectives

7.6.1 Integrated Microalgae/Thraustochytrids Cultivation and Harvesting System

7.6.2 Genetically Modified Microalgae/Thraustochytrids for High Oil and Easy Extraction of Lipids.

7.6.3 Integrated Microalgae/Thraustochytrids System for Biofuel and DHA/EPA Production

Chapter 8 Pertinent Issues of Algal Energy and Bio‐Product Development A Biorefinery Perspective

8.1 Introduction

8.2 Current Status of Algal Energy and Bio‐product Formation

8.3 Analysis of Conversion Methods

8.3.1 Dynamics of Algal Biomass Composition

8.3.2 Conversion Routes

8.3.3 Product Yield and Market Value

8.4 Competent Applications of Algae

8.5 Biorefinery and Integrated Approaches

8.6 Technological Issues: Pros and Cons

8.7 Life Cycle Assessment

8.8 Techno‐Economic Analysis (TEA)

8.9 Futuristic Options

Chapter 9 Resource Utilization of Sludge and Its Potential Environmental Applications for Wastewater

9.1 Introduction

9.2 Types of Sludge in Wastewater Treatment Process

9.2.1 Activated Sludge

9.2.2 Granular Sludge

9.2.2.1 Anaerobic Granular Sludge

9.2.2.2 Aerobic Granular Sludge

9.3 Sludge‐Based Activated Carbon for Wastewater Treatment

9.3.1 Production Method

9.3.1.1 ZnCl2

9.3.1.2 H3PO4

9.3.2 Treatment of Dye Wastewater

9.3.2.1 MG Sorption onto Sludge‐Based ACs

9.3.2.2 Mineral Acid Modification of AGS‐Derived AC for MG Sorption

9.3.3 Treatment of Heavy Metal‐Contained Wastewater

9.3.3.1 Heavy Metal Sorption onto Sludge‐Based AC

9.3.3.2 Cu(II) Sorption onto AGS‐AC in the Presence of HA and FA

9.4 Granular Sludge Biosorbent Applied for Wastewater Treatment

9.4.1 Treatment of Dye Wastewater

9.4.1.1 Role of EPS in Aerobic Granular Sludge for MB Sorption

9.4.1.2 Biosorption of Dye Wastewater and Photocatalytic Regeneration of AGS

9.4.2 Treatment of Heavy Metal‐Contained Wastewater

9.4.2.1 Zn(II) Sorption onto AGS

9.4.2.2 Cu(II) Sorption onto AGS

9.4.2.3 Ni(II) Sorption onto AGS/AnGS.

9.4.2.4 Magnetic Modification of AnGS for Pb(II) and Cu(II) Removal.

Notes:

Description based on print version record.

Description based on publisher supplied metadata and other sources.

ISBN:

3-527-82537-1

3-527-82539-8

OCLC:

1246580459