Production of Biofuels and Chemicals from Sustainable Recycling of Organic Solid Waste

The book explores sustainable recycling processes for multiple organic solid wastes, offering methods to convert them into valuable products like fuels and commodity chemicals. It aims to improve awareness of effective conversion protocols and develop innovative biomass conversion processes. It features contributions from renowned experts and professionals, covering recent advances and promising new methods.

Format: Paperback / softback
Length: 506 pages
Publication date: 20 May 2023
Publisher: Springer Verlag, Singapore

Sustainable Recycling Processes for Multiple Organic Solid Wastes: A Comprehensive Guide to Materials Recovery and Value-Added Product Creation
Sustainable recycling processes for multiple organic solid wastes are essential for promoting manufacturing processes and reducing environmental impact. This book provides a comprehensive overview of physical, biological, chemical, and thermo-chemical recycling methods, as well as methods for material recycle of wastes into value-added products, including fuels and commodity chemicals. The text aims to improve awareness of effective conversion protocols and develop innovative biomass conversion processes. It covers recent advances, assesses promising new methods, and highlights direct conversion of organic solid wastes to process feeds. Highly-recognized authorities, experts, and professionals have contributed individual chapters in selected areas to cover the overall topic in a comprehensive manner.
Physical Recycling Processes: Physical recycling processes involve the physical separation of materials from organic solid wastes. This can be done through sorting, shredding, grinding, and other mechanical methods. Physical recycling processes can be used to recover valuable materials such as metals, plastics, and paper, which can be reused in manufacturing processes. However, physical recycling processes can be energy-intensive and may not be suitable for all types of organic solid wastes.
Biological Recycling Processes: Biological recycling processes involve the use of microorganisms to break down organic materials into their basic components. This can be done through composting, anaerobic digestion, and fermentation. Biological recycling processes can be more efficient than physical recycling processes and can produce valuable products such as organic fertilizers, biogas, and biofuels. However, biological recycling processes can be limited by the availability of suitable microorganisms and the environmental conditions.
Chemical Recycling Processes: Chemical recycling processes involve the use of chemicals to break down organic materials into their basic components. This can be done through pyrolysis, gasification, and hydrolysis. Chemical recycling processes can be more efficient than physical and biological recycling processes and can produce valuable products such as synthetic fuels, chemicals, and plastics. However, chemical recycling processes can be hazardous and may require specialized equipment and facilities.
Thermo-Chemical Recycling Processes: Thermo-chemical recycling processes involve the use of heat to break down organic materials into their basic components. This can be done through incineration, combustion, and pyrolysis. Thermo-chemical recycling processes can be more efficient than physical and biological recycling processes and can produce valuable products such as energy, carbon, and metals. However, thermo-chemical recycling processes can be hazardous and may require specialized equipment and facilities.
Material Recycle of Wastes into Value-Added Products: Material recycle of wastes into value-added products is a critical aspect of sustainable recycling processes. This can be done through the use of various technologies, such as pyrolysis, gasification, and hydrolysis. Pyrolysis involves the heating of organic materials to produce a gas, which can be used as a fuel or as a raw material for other products. Gasification involves the heating of organic materials to produce a gas, which can be used as a fuel or as a raw material for other products. Hydrolysis involves the heating of organic materials to produce a liquid, which can be used as a fuel or as a raw material for other products.
In addition to the material recycle of wastes into value-added products, sustainable recycling processes can also help to reduce the amount of waste that is sent to landfills. Landfills are a major source of greenhouse gas emissions, and by reducing the amount of waste that is sent to landfills, sustainable recycling processes can help to mitigate climate change.
Recent Advances in Sustainable Recycling Processes: Recent advances in sustainable recycling processes have led to the development of new technologies and methods that are more efficient and cost-effective. For example, the use of anaerobic digestion has become more popular in recent years, as it can produce organic fertilizers and biogas from organic wastes. The use of pyrolysis has also become more popular, as it can produce synthetic fuels and chemicals from organic wastes.
Assessing and Highlighting Promising New Methods or New Technological Strategies: Assessing and highlighting promising new methods or new technological strategies is essential for the development of sustainable recycling processes. This can be done through research and development, as well as through collaboration with other organizations and industries. Research and development can help to identify new technologies and methods that are more efficient and cost-effective, while collaboration with other organizations and industries can help to promote the adoption of sustainable recycling processes.
Direct Conversion of Organic Solid Wastes to Process Feeds: Direct conversion of organic solid wastes to process feeds is a promising new method that has the potential to reduce the amount of waste that is sent to landfills. This can be done through the use of anaerobic digestion, pyrolysis, and gasification. Anaerobic digestion involves the breakdown of organic materials into their basic components, while pyrolysis involves the heating of organic materials to produce a gas, which can be used as a fuel or as a raw material for other products. Gasification involves the heating of organic materials to produce a gas, which can be used as a fuel or as a raw material for other products.
In conclusion, sustainable recycling processes for multiple organic solid wastes are essential for promoting manufacturing processes and reducing environmental impact. This book provides a comprehensive overview of physical, biological, chemical, and thermo-chemical recycling methods, as well as methods for material recycle of wastes into value-added products. By improving awareness of effective conversion protocols and developing innovative biomass conversion processes, sustainable recycling processes can help to create a more sustainable future for our planet.

Dimension: 235 x 155 (mm)
ISBN-13: 9789811661648
Edition number: 1st ed. 2022