Liquid Biofuels
eBook - ePub

Liquid Biofuels

Fundamentals, Characterization, and Applications

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eBook - ePub

Liquid Biofuels

Fundamentals, Characterization, and Applications

About this book

Compiled by a well-known expert in the field, Liquid Biofuels provides a profound knowledge to researchers about biofuel technologies, selection of raw materials, conversion of various biomass to biofuel pathways, selection of suitable methods of conversion, design of equipment, selection of operating parameters, determination of chemical kinetics, reaction mechanism, preparation of bio-catalyst: its application in bio-fuel industry and characterization techniques, use of nanotechnology in the production of biofuels from the root level to its application and many other exclusive topics for conducting research in this area.

Written with the objective of offering both theoretical concepts and practical applications of those concepts, Liquid Biofuels can be both a first-time learning experience for the student facing these issues in a classroom and a valuable reference work for the veteran engineer or scientist. The description of the detailed characterization methodologies along with the precautions required during analysis are extremely important, as are the detailed description about the ultrasound assisted biodiesel production techniques, aviation biofuels and its characterization techniques, advance in algal biofuel techniques, pre-treatment of biomass for biofuel production, preparation and characterization of bio-catalyst, and various methods of optimization.

The book offers a comparative study between the various liquid biofuels obtained from different methods of production and its engine performance and emission analysis so that one can get the utmost idea to find the better biofuel as an alternative fuel. Since the book covers almost all the field of liquid biofuel production techniques, it will provide advanced knowledge to the researcher for practical applications across the energy sector.

A valuable reference for engineers, scientists, chemists, and students, this volume is applicable to many different fields, across many different industries, at all levels.  It is a must-have for any library.

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Information

Publisher
Wiley-Scrivener
Year
2021
Print ISBN
9781119791980
eBook ISBN
9781119793014
Edition
1
Topic
Physical Sciences
Subtopic
Energy

1
Introduction to Biomass to Biofuels Technologies

Ezgi Rojda Taymaz, Mehmet Emin Uslu and Irem Deniz*
Bioengineering Department, Faculty of Engineering, Manisa Celal Bayar University, Muradiye-Manisa, Turkey
Abstract
Biofuels are renewable, environmentally friendly, alternative fuels suitable for use as heat, power and alternative engine fuel, important for the socioeconomic development of countries, resource diversity and supply security. Applications of liquid-solid-gas biofuels obtained from biomass in energy sources are increasing rapidly. The bioenergy sector has a rather complex structure due to the diversity of potential raw materials and technical ways to convert biomass into energy. Sixty percent of the biomass is derived from agricultural waste, and various conversion techniques are applied to these organic wastes for bioenergy production. The most important alternative biofuels based on biomass can be classified as bioethanol, biodiesel, biogas, bio-methanol, bio-methyl ether and bio-oil. The most common biofuels are bioethanol and biodiesel. Biofuels have been found to increase its usability due to being based on renewable biological resources and non-toxic, having a good biodegradability, causing very low emissions when burned and being environmentally friendly. This chapter investigates biomass resources and biofuel technologies in a bio-refinery concept.
Keywords: Biomass, biofuel, bio-refinery, conversion techniques, energy, liquid biofuels

1.1 Introduction

Non-fossil biomass can be used for bioenergy production. This bioenergy is called biomass energy and is defined as the conversion of energy from the sun by plants. Its principle is to use the energy stored in the plant in its transformed form when needed. Biomass energy is examined in two groups as classical and modern. Classical biomass energy consists of firewood, plant and animal residues obtained from conventional forests. The main character of the use of classical biomass energy is that the energy from the biomass material is obtained through various combustion tools and direct combustion techniques from primitive to developed ones. Modern biomass resources are listed as energy forestry products, forest and wood industry wastes, energy agriculture, vegetable and animal wastes in the agricultural sector, urban wastes, and agriculture-based industrial wastes [1].
Biomass materials are transformed into biofuels after pre-preparation and conversion. Biofuels can be used for heat and electricity production. Biofuel use ranges from large central power station to vehicles. Modern biomass energy techniques are based on transforming the material so that the physical condition remains constant and/or changed. Biomass is divided into low biomass techniques and high biomass techniques. Low biomass techniques are direct combustion, anaerobic decomposition, fermentation-distillation processes. High biomass techniques consist of pyrolysis, hydrogasification, acid hydrolysis, and biological hydrogen production processes. Modern biomass energy is a sustainable energy source, in full compliance with the environment. Biofuels are the general names of gas, liquid and solid products obtained by passing agricultural products, wood, animal, plant and urban waste through various biochemical and/or thermochemical conversion processes. Gas biofuels; bio-hydrogen, biogas, synthetic gases, solid biofuels; wood coal, bio-char, bio-pellet, bio-bricket, liquid biofuels; bioethanol, biodiesel, bio-methanol, bio-methyletheter and vegetable oils [1, 2].
It is possible to produce both energy and new chemicals using different methods from biomass. Biogas and ethanol can be produced by fermentation in anaerobic environment [3]. Gas fuel and activated carbon are produced by pyrolysis from wastes with a high percentage of solid with thermal decomposition. Synthetic fuel (syngas) production can be made by hydrogasification and hydrogenation. Heat energy and electricity are produced by burning garbage and solid wastes directly with air. Organic fertilizer is produced as a result of composting of garbage and animal feces [1].

1.2 Lignocellulosic Biomass and Its Composition

Various agricultural by-products and vegetal wastes that are released to the environment as solid wastes can be considered as biomass sources. Such substances show similarities with wood in terms of their general properties and chemical structures and are called lignocellulosic biomass. Lignocellulosic biomass has a rather complex polymeric structure. The plant cell (from outside to inside) consists of pectin, cellulose, ligninhemicellulose, and soluble stoplasmic compounds. Intracellular components are mainly sugars, starch, proteins, pectin and lipids. Lignocellulosic materials are an important source of raw materials because these components can be separated by hydrolysis and extraction [4, 5].
The lignocellulosic materials that make up 50% of the total biomass in the world are not suitable for consumption as direct food and are made up of plant sources. Basically, there are three basic polymers: hemicellulose (C5H8O4)n, cellulose (C6H10O5)n and lignin [C9H10O3) (OCH3)0.9-1.7]n [4]. Typically, biomass contains 40-60% cellulose, 20-40% hemicellulose and 10–25% lignin. Extracts and minerals in lignocellulose are up to 10% of the weight of dry biomass. Other substances in the lignocellulose (extractives) are organic solutions or water-soluble substances, which make up a very small part (1-5%) of the lignocellulosic substance [6].
The cell walls of plants contain lignocellulose. If the lignin is removed, the polysaccharide derivative remains. Polysaccharides in the plant cell are also called halocellulose. Halocelluloses consist of celluloses and hemicelluloses. If halocellulose is hydrolyzed, C6 and C5 sugars, uronic acids and acetyl groups are obtained. C6 sugars are glucose, mannose and galactose. C5 sugars are mainly xylose and arabinose. The ratio of each compound varies depending on the plant source [7].
The main components of lignocellulosic natural sources are cellulose, hemicelluloses, lignin, extractives and inorganics [8]. Cellulose in nature is polysaccharides such as various starch, pectin, and hemicellulose. Hemicelluloses are galactose, mannose, xylose, arabinose and other sugars; they contain polymers and heteropolymers of uronic acids. In addition cellulose in nature exists as a mixture of cellulose-lignin [9, 10].

1.2.1 Cellulose

In the biosphere, which we call the world of living things, approximately 27x1010 tons of carbon is attached to living organisms and more than 99% of it is found in vegetable material. Approximately 40% of the carbon in plants comes from cellulose. In this regard, cellulose is the most abundant natural polymer on earth, and it has a wide spread from primitive plants (algae, moss, etc.) to highly organized plants (woods) and some bacteria [11, 12]. Cellulose is one of the most important structural polysaccharides that are found in the plant world and have the simplest structure and also located in the cell wall structure [13].
Cellulose is the most common polymer on earth which is a linear syndiotactic (alternative spatial arrangement) of the glucose polymer bonded by Β-(1 → 4)-glycosidic bonds. The size (degree of polymerization) of the cellulose molecule varies depending on...

Table of contents

  1. Cover
  2. Table of Contents
  3. Title Page
  4. Copyright
  5. Preface
  6. 1 Introduction to Biomass to Biofuels Technologies
  7. 2 Advancements of Cavitation Technology in Biodiesel Production – from Fundamental Concept to Commercial Scale-Up
  8. 3 Heterogeneous Catalyst for Pyrolysis and Biodiesel Production
  9. 4 Algal Biofuel: Emergent Applications in Next-Generation Biofuel Technology
  10. 5 Co-Liquefaction of Biomass to Biofuels
  11. 6 Biomass to Bio Jet Fuels: A Take Off to the Aviation Industry
  12. 7 Advance in Bioethanol Technology: Production and Characterization
  13. 8 Effect of Process Parameters on the Production of Pyrolytic Products from Biomass Through Pyrolysis
  14. 9 Thermo-Catalytic Conversion of Non-Edible Seeds (Extractive-Rich Biomass) to Fuel Oil
  15. 10 Suitability of Oil Seed Residues as a Potential Source of Bio-Fuels and Bioenergy
  16. 11 Co-Conversion of Algal Biomass to Biofuel
  17. 12 Pyrolysis of Caryota Urens Seeds: Fuel Properties and Compositional Analysis
  18. 13 Bio-Butanol as Biofuels: The Present and Future Scope
  19. 14 Application of Nanotechnology in the Production of Biofuel
  20. 15 Experimental Investigation of Long Run Viability of Engine Oil Properties in DI Diesel Engine Fuelled with Diesel, Bioethanol and Biodiesel Blend
  21. 16 Studies on the Diesel Blends Oxidative Stability in Mixture with TBHQ Antioxidant and Soft Computation Approach Using ANN and RSM at Varying Blend Ratio
  22. 17 Effect of Nanoparticles in Bio-Oil on the Performance, Combustion and Emission Characteristics of a Diesel Engine
  23. 18 Use of Optimization Techniques to Study the Engine Performance and Emission Analysis of Diesel Engine
  24. 19 Engine Performance and Emission Analysis of Biodiesel-Diesel and Biomass Pyrolytic Oil-Diesel Blended Oil: A Comparative Study
  25. 20 Agro-Waste for Second-Generation Biofuels
  26. Index
  27. Also of Interest
  28. End User License Agreement

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Yes, you can access Liquid Biofuels by Krushna Prasad Shadangi in PDF and/or ePUB format, as well as other popular books in Physical Sciences & Energy. We have over 1.5 million books available in our catalogue for you to explore.