Foreword I
Page: i-i (1)
Author: Vijayanand Suryakant Moholkar
DOI: 10.2174/9789815049848123010001
PDF Price: $15
Foreword II
Page: ii-ii (1)
Author: Aniruddha B. Pandit
DOI: 10.2174/9789815049848123010002
PDF Price: $15
Acknowledgements
Page: v-v (i)
Author: Sankar Chakma
DOI: 10.2174/9789815049848123010004
PDF Price: $15
Basic Concepts of Ultrasound and its Effects on Fuel Processing
Page: 1-34 (34)
Author: Maneesh Kumar Poddar, Pritam Kumar Dikshit and Sankar Chakma*
DOI: 10.2174/9789815049848123010006
PDF Price: $15
Abstract
Ultrasound-assisted technique is well-known for process intensification via
chemical and physical changes under the influence of acoustic cavitation. Acoustic
cavitation is the phenomenon of nucleation, growth, and collapse of cavitation bubbles
into a liquid medium that augments the reaction kinetics and the final process yield.
This chapter provides a fundamental and detailed understanding of the acoustic
cavitation phenomenon. It includes the history and origin of the acoustic wave and its
formation, the concept of cavitation bubbles, bubble nucleation and growth mechanism,
cavitation effects, and its types. Numerous process parameters, such as applied
frequency, intensity, temperature, dissolved gas content, etc., also directly or indirectly
influence the cavitation threshold are also highlighted.
Further, the ultrasound's physical and chemical effects involving various chemical and
biochemical processes to enhance the process yield are also reviewed. The mode of
generation of ultrasound energy and its measurement technique are also briefly
discussed. Finally, an overview of modeling and simulation of radial motion of single
bubble growth, its oscillation in both ultrasound-assisted and conventional systems, and
bubble growth rate under rectified diffusion are also discussed in detail.
Sonochemical Production of Hydrogen: A Green and Sustainable Approach
Page: 35-59 (25)
Author: Aissa Dehane and Slimane Merouani*
DOI: 10.2174/9789815049848123010007
PDF Price: $15
Abstract
In the last two decades, the subject of hydrogen production by sonolysis
(sono-hydrogen) has been widely investigated experimentally and theoretically. This
chapter highlights the recent experimental and theoretical progress in the field of
sonochemical production of hydrogen. The chapter will be divided into two parts: (i)
literature review of the available experimental data (experimental conditions,
production yields, influencing factors) and (ii) a numerical analysis of the treated
subject, with emphasis on the impact of different energetic terms of the bubble energy
balance on the sonochemical yields of hydrogen, all with relation to operational
parameters (frequency, intensity of ultrasound, size of bubble population). The chapter
will be closed with some perspectives on innovation and sustainability of the process.
Physical, Chemical and Biological Pre-treatment of Lignocellulosic Biomass for Biorefinery Applications
Page: 60-97 (38)
Author: Amrita Ranjan* and Pamela J. Welz
DOI: 10.2174/9789815049848123010008
PDF Price: $15
Abstract
The generation of energy from fossil fuels contributes significantly to global
warming. This may be mitigated by the use of renewable (bio-based) feedstocks.
Second generation biofuels made in biorefineries that utilize agricultural residues and
other lignocellulosic wastes as feedstocks reduce the dependency on food crops such as
sugar cane (for bioethanol) and oil seeds (for biodiesel). Pre-treatment of
lignocellulosic feedstocks is key for ensuring process efficiency from the substrate to
the product. There are many pre-treatment methods, and method selection is incumbent
on the type of feedstock and the downstream processes required to generate the final
product(s). Product yields can be increased by integrating two or three pre-treatment
methods. For example, by combining physical and/or chemical pre-treatment with
ultrasonication. The content of this chapter is focused on describing various pre-treatment methods that are used to break down and/or hydrolyse lignocellulosic
biomass. The discussion extends to both conventional and novel ‘green’ methods and
includes the advantages and disadvantages of each method type. Possible solutions for
overcoming some of these disadvantages are included.
Ultrasound Based Integrated Technique for Production of Sustainable Bio-crude from Domestic Sewage Sludge for Biorefinery
Page: 98-129 (32)
Author: Anindita Das and Kaustubha Mohanty*
DOI: 10.2174/9789815049848123010009
PDF Price: $15
Abstract
Generation of a tremendous amount of domestic sewage sludge pushes
society to look for an alternate and viable option rather than its direct disposal. The
organic-rich constituents of sludge make it an asset rather than waste. Sludge to energy
conversion is a feasible option to combat the demand for renewable energy. Resource
recovery from waste leads to socio-economic development by reducing fossil
dependency with clean and green energy. This chapter mainly focuses on the potential
of ultrasound-based techniques for the pretreatment of DSS to enhance bio-crude
production. Thermochemical and biochemical treatment are two routes of sludge
valorization with their advantages and limitations. Pyrolysis, gasification, combustion,
and hydrothermal processing come under thermochemical treatment whereas,
anaerobic digestion, aerobic digestion, and fermentation form the basis of biochemical
treatment. Thermochemical routes demand energy, whereas biochemical routes are a
time-consuming process. Pretreatment of sludge is a viable option to overcome these
limitations. Ultrasound pretreatment increases COD solubilization, volatile suspended
solids reduction, biogas production during AD, increases the yield and HHV of biocrude during thermochemical treatment, and favors lipid extraction for biodiesel
production, and also promotes bioethanol production. Moreover, integrated ultrasound
pretreatment positively affects the overall process by reducing the overall cost and
increasing bio-crude production.
Application of Sonication in Lipid Extraction from Microbial Biomass for Third Generation of Biodiesel
Page: 130-143 (14)
Author: Ritesh S. Malani* and Sushobhan Pradhan
DOI: 10.2174/9789815049848123010010
PDF Price: $15
Abstract
Increasing demand in terms of fuel and energy with limited fossil fuels
forces researchers to develop renewable fuels in sustainable ways. Biodiesel, as an
alternative to mineral diesel, has emerged as one of the potential renewable fuels. With
an increasing demand for biodiesel, conventional and non-conventional sources of
triglycerides were investigated. In terms of future demand, edible and non-edible
sources are insufficient to fulfill the requirement and thus microbial oil will be one of
the crucial feedstock for biodiesel production. The extraction of lipids from various
biomass is one of the crucial steps in the synthesis of biodiesel, which controls the
overall production cost. Over the last few years, conventional lipid extraction
techniques such as solvent extraction, mechanical processes, and chemical treatments
have been explored, however, all these have their own limitations. Moreover, in order
to obtain high purity lipids in an economical way, the use of sonication has garnered
much attention in extracting the lipids from the microbial biomass because of the
shorter process time, the straightforwardness of the process, and the superior quality of
products. It may also lead to reducing the use of solvents in the extraction process. The
book chapter deals with the limitations of conventional extraction processes of lipids
from microbial biomass and the role of ultrasound in efficient and economic
operations. Moreover, to lower the production cost, the application of ultrasound in
simultaneous extraction and transesterification has been explored.
Application of Ultrasound in Microbial and Algal Biofuel Production
Page: 144-181 (38)
Author: Maneesh Kumar Poddar, Lopa Pattanaik and Pritam Kumar Dikshit*
DOI: 10.2174/9789815049848123010011
PDF Price: $15
Abstract
The application of ultrasound has received immense research attentions in
the past few years due to its application in various sectors including dye degradation,
pretreatment process, fuel production, bioprocessing, etc. Recently, ultrasonication has
been used as a novel bioprocessing tool for enhancing biofuel production from
microbial and algal biomass during the fermentation process. Additionally, this
technique is also used in many areas of downstream processing such as extraction of
lipids from biomass, filtration, and crystallization. The usage of ultrasonication during
the fermentation process can result in the enhancement of the transfer of oxygen for
aerobic culture, homogenization of biomass for the reduction in clump formation, and
faster substrate transfer to biomass which further results in enhanced microbial growth.
In view of this, the present chapter mainly focuses on the role of ultrasonication in
microbial and algal lipid production and its extraction process with an aim for liquid
biofuel production. Additionally, the influence of various operating parameters (power
intensity, frequency, duration, reactor design, and kinetics) over the growth, lipid
production, and extraction process are also described in detail.
Synergy of Microwave and Ultrasound for Intensification of Biodiesel Synthesis
Page: 182-201 (20)
Author: Vitthal L. Gole*, Jyoti Sharma and Rajesh K. Yadav
DOI: 10.2174/9789815049848123010012
PDF Price: $15
Abstract
Biodiesel synthesis from sustainable feedstock is gaining importance in
depleting crude oil feedstock and addressing greenhouse emission challenges. A
developing country like India has planned to reduce its 10% dependency on crude oil
by 2022. Synthesis of biodiesel from sustainable edible feedstock has been a concern
for energy vs. food issues. Non-edible feedstock such as Calophyllum innophyllum
Linn, Karanja, Jatropha, Waste Cooking oil, waste engine oil, etc., is gaining
importance. However, biodiesel synthesis from these feedstocks requires higher
processing due to higher initial free fatty content. Intensified techniques can overcome
the shortcoming of higher processing requirements. Spectacular effects associated with
ultrasound and microwave are beneficial for enhancing the rate of processing.
Individual results of microwave and ultrasound have certain limitations. The
intensification of biodiesel synthesis is dependent on the removal of heat/mass barriers
in the transesterification process. Microwave interaction with polar molecules present
in the system enhances the temperature of the reaction at a very intense rate. Microemulsification and the high speed of micro-streaming velocities produced from the
ultrasound during interaction with the aqueous phase are incredibly useful for reducing
the mass transfer barrier in heterogeneous phases. The synergy of microwave and
ultrasound may help enhance the processing rate on a multi-fold basis. The present
chapter has presented an overview of microwave and ultrasound energy effects for
biodiesel synthesis. Process economics has been discussed for future development in
biodiesel synthesis.
Intensification of Biodiesel Production Process using Acoustic and Hydrodynamic Cavitation
Page: 202-224 (23)
Author: Swapnil Sukhadeo Bargole and Virendra Kumar Saharan*
DOI: 10.2174/9789815049848123010013
PDF Price: $15
Abstract
Biodiesel is an alternative to conventional fossil fuels. It has several
advantages over conventional fuels. It is non-toxic, renewable, and biodegradable with
no sulfur content. Researchers have used different techniques to produce biodiesel from
various edible and non-edible oil sources in the last many years, but these technologies
have several disadvantages. They are highly energy-intensive, have high operating
costs, low volume throughput, and require high investment costs that make them
uneconomical for large-scale operations. In recent years, sonochemical reactors such as
ultrasonication or acoustic cavitation (AC) and hydrodynamic cavitation (HC) have
been considered promising, efficient, and environmentally acceptable techniques for
synthesizing biodiesel. These techniques work on the principle of generation, growth,
and collapse of cavities due to pressure variation within the solution. The cavity
collapse releases a tremendous amount of energy within a short period, typically within
a microsecond at multiple locations within the solution. The release of such immense
power generates local hot spots and highly disruptive pressure shock waves, which help
in increasing the mass transfer rate and thereby causing improved transesterification
reactions.
This book chapter reviews the primary mechanism of intensified approaches using
cavitation, fundamentals of acoustic and hydrodynamic cavitation reactors, basic
designs, and operational guidelines for obtaining the maximum biodiesel yields. This
chapter discusses the effect of various operating parameters of AC and HC on biodiesel
yield. In the case of HC, details of different cavitating devices and the impact of
geometrical and operating parameters that affect the cavitation conditions and biodiesel
yield are discussed.
Improved Enhanced Oil Recovery – Role of Sonication: An Overview
Page: 225-236 (12)
Author: Ritesh S. Malani* and Rahul Saha
DOI: 10.2174/9789815049848123010014
PDF Price: $15
Abstract
Crude oil is one of the prominent resources to fulfill the need of day-to-day
life. With few reservoirs, the proper utilization and maximization of oil recovery from
existing oil wells are one of the foremost objectives in today’s scenario.
Conventionally, the inbuilt pressure and artificial pumping followed by water flooding
could result in 30-50% of oil recovery. Thus, to produce the remaining residual crude
oil, various enhanced oil recovery methods are adopted, including gas flooding, fire
flooding, chemical EOR, etc. Still, oil recovery in large quantities persists to be a
challenging task for engineers throughout the world. The major limitation for
improving the oil recovery is the water enrichment of the reservoirs, which governs the
oil displacement efficiency from the reservoir to the production platform.
The application of sound waves in reservoir engineering is an established technology.
In seismic surveys, sound waves of various frequencies have been used to predict oil
and gas reserves. The advancement of the application of ultrasound irradiation on
multiple sectors, including the enhancement of oil recovery from wells, has also been
analyzed and tested. The idea behind applying cavitation technology is that the passage
of ultrasound waves releases the energy in terms of transient cavitation and allows the
formation of the fine emulsion of two immiscible phases. The emulsion enables the
improvement of oil movability toward the production well without changing the
porosity and permeability of rocks. Thus, the cavitation technique can be applied to
estimate oil-water saturation in reservoirs and can further improve the oil recovery
factor. This chapter emphasizes the fundamentals of enhanced oil recovery schemes,
their mechanisms, and the application of ultrasound irradiation toward improved oil
recovery.
Role of Sonication in the Upgradation of Heavy Crude Oil
Page: 237-252 (16)
Author: Ritesh S. Malani*
DOI: 10.2174/9789815049848123010015
PDF Price: $15
Abstract
The increase in energy consumption throughout the globe with declining
global light-oil reserves necessitates the utilization of heavy crude oil reservoirs to
meet the demand. The processing of heavy crude oil in refineries creates extensive
loads on thermal and catalytic processes to upgrade them as well as to meet market
legislations. Heavy crude oil is rich in excess sulfur and other metals along with high
molecular hydrocarbons such as resins, waxes, asphaltenes, heavy aromatics, etc. The
separation of lighter hydrocarbon fractions is difficult as well as the processing of
vacuum residue also needs attention. The thermal processes break the heavy
hydrocarbons into smaller ones which later can be reformed or cracked using catalytic
processes. The catalytic processes cannot be employed directly as the impurities will
poison catalysts. Thermal processes such as vis-breaking, thermal cracking and coking
are highly energy intensive processes and mainly progress through free radical
mechanism. The application of ultrasound in the upgradation of heavy crude oil will
help in the reduction of energy requirements and load on these thermal processes. The
present chapter overviews ultrasound-assisted cavitation as an innovative method to
intensify the cracking of asphaltenes and other heavy hydrocarbon molecules existing
in the vacuum or atmospheric distillate residual.
Sono-Bio-Desulphurization of Liquid Fuel using Free and Immobilized Cell
Page: 253-279 (27)
Author: Dharmendra Kumar Bal and Jaykumar B. Bhasarkar*
DOI: 10.2174/9789815049848123010016
PDF Price: $15
Abstract
In view of environmental concerns, the production of clean energy is one of
the most critical issues in modern years to accommodate the growing energy needs of
society (domestic usage), agriculture, and industry. Clean energy can be accomplished
in several ways. A possible solution to this issue is to use renewable energy sources
such as solar, wind, and nuclear power universally. The use of conventional techniques
to produce energy by the combustion of fossil fuels has adverse effects on the
environment due to the emission of greenhouse gas that contributes to global warming.
The conventional method adopted by petroleum refinery industries has not been
successful for profound desulphurization to achieve low sulphur contents. To overcome
this, several new alternative chemicals, and physical and biological techniques have
been developed to meet ultra-low sulphur fuel in the last two decades. Microbial
desulphurization is one of the emerging alternative techniques that can remove the
organo-sulphur compounds from fuels. The limitation of microbial desulphurization is
the slow kinetics and it can be overcome by combining it with other desulphurization
processes (hybrid system), such as the ultrasound-assisted processes. This chapter
presents a critical account of research in different facets of ultrasound-assisted
biodesulphurization. The microbial desulphurization process involves the use of free or
immobilized microorganisms over the PU foams and the application of enzymes for
desulphurization of DBT. The enzymes or proteins can act as catalysts to degrade
sulphur compounds present in fuels. The present chapter also deals with the
ultrasound-assisted microbial and enzymatic pathways. The concurrent analysis of
experimental results on enzymatic biodesulphurizarion along with simulation results of
cavitation bubble dynamics provides more insight into the actual mechanism of
ultrasound on microbial and enzymatic desulphurization process.
Physical Insight into Ultra-low Desulfurization of Liquid Fuels using Sono-hybrid Fenton Reaction
Page: 280-299 (20)
Author: Prachi Upadhyay and Sankar Chakma*
DOI: 10.2174/9789815049848123010017
PDF Price: $15
Abstract
The sulfur-containing hydrocarbons are the main source of SOx
and CO2
gas
emissions, which is a threat to the environment for sustainability development.
According to the US environment protection agency, the sulfur content should be
within the limit of 15 ppm and 30 ppm for diesel and gasoline, respectively. Also, a
couple of advanced techniques have been developed so far for the removal of sulfur
from fuels. Among these techniques, ultrasound-based advanced oxidation processes
have been found to be more efficient and effective for sulfur removal.
In this chapter, we have discussed the physical and chemical mechanism of ultrasound
based advanced oxidation processes including the influences of process parameters
such as pH, the concentration of sulfur, concentration of oxidant, presence of phase
transfer catalyst, oxalate ions, etc. Also, several hybrid techniques are discussed with
their advantages and disadvantages for obtaining ultra-low sulfur fuel.
Subject Index
Page: 300-305 (6)
Author: Sankar Chakma
DOI: 10.2174/9789815049848123010018
PDF Price: $15
Introduction
Ultrasound Technology for Fuel Processing is a comprehensive reference guide that explores the application of sonochemistry and ultrasound waves in the intensified processing of fuels. The book focuses on the cavitation phenomenon, which generates extreme conditions, such as high temperatures and pressures, within the cavitation bubbles, leading to significant enhancements in chemical reactions and overall process yields. Key features of the book include comprehensive coverage of ultrasound fuel processing, with the inclusion of information about several new processing techniques, detailed references, and a focus on sustainability enhancing petrochemical technologies. Key Topics: - The basics of ultrasound technology, including its history, acoustic wave origin, and process parameters influencing cavitation thresholds. - Green hydrogen production through sonolysis of water and the influence of various parameters on hydrogen yield. - Pre-treatment methods for biofuel production, exploring both conventional and novel green methods. - Ultrasound-based techniques to enhance alternative energy production (biocrude, biogas, and bioethanol). - Biodiesel synthesis using ultrasound-microwave synergy for enhanced processing rates. - Intensified approaches in sonochemistry, including the use of cavitation, fundamentals of sonochemical reactors, and operational guidelines for maximizing biodiesel yields. - Enhanced oil recovery and crude oil upgradation using ultrasound and cavitation techniques, focusing on cracking heavy hydrocarbon molecules. - Ultrasound-assisted chemical and bio-desulfurization processes. Ultrasound Technology for Fuel Processing provides an in-depth understanding of the principles and applications of ultrasound in fuel processing, offering valuable insights for researchers, faculty, and professionals in fuel processing technology and related areas in industrial, petroleum and chemical engineering.