Biodiesel technology and applications

BIODIESEL This outstanding new volume provides a comprehensive overview on biodiesel technologies, covering a broad range of topics and practical applications, edited by one of the most well-respected and prolific engineers in the world and his team. Energy technologies have attracted great attention due to the fast development of sustainable energy. Biodiesel technologies have been identified as the sustainable route through which overdependence on fossil fuels can be reduced. Biodiesel has played a key role in handling the growing challenge of a global climate change policy. Biodiesel is defined as the monoalkyl esters of vegetable oils or animal fats. Biodiesel is a cost-effective, renewable, and sustainable fuel that can be made from vegetable oils and animal fats. Compared to petroleum-based diesel, biodiesel would offer a non-toxicity, biodegradability, improved air quality and positive impact on the environment, energy security, safe-to-handle, store and transport and so on. Biodiesels have been used as a replacement of petroleum diesel in transport vehicles, heavy-duty trucks, locomotives, heat oils, hydrogen production, electricity generators, agriculture, mining, construction, and forestry equipment. This book describes a comprehensive overview, covering a broad range of topics on biodiesel technologies and allied applications. Chapters cover history, properties, resources, fabrication methods, parameters, formulations, reactors, catalysis, transformations, analysis, in situ spectroscopies, key issues and applications of biodiesel technology. It also includes biodiesel methods, extraction strategies, biowaste utilization, oleochemical resources, non-edible feedstocks, heterogeneous catalysts, patents, and case-studies. Progress, challenges, future directions, and state-of-the-art biodiesel commercial technologies are discussed in detail. This book is an invaluable resource guide for professionals, faculty, students, chemical engineers, biotechnologists, and environmentalists in these research and development areas. This outstanding new volume: Summarizes the recent developments in this rapidly-developing, multi-disciplinary field Provides the reader with a practical understanding of biodiesel technology toward the real-world applications Formulates concepts, case-studies, patents, and applications helpful in decision making and problem-solving, in a single resource Delivers state-of-the-art information on biodiesel technology Audience: Chemical and process engineers and other professionals, faculty, students, scientists, biotechnologists, and environmental engineers

Preface xvii 1 Biocatalytic Processes for Biodiesel Production 1 Ubaid Mehmood, Faizan Muneer, Muhammad Riaz, Saba Sarfraz and Habibullah Nadeem 1.1 Introduction and Background 2 1.2 Importance of Biodiesel Over Conventional Diesel Fuel 3 1.3 Substrates for Biodiesel Production 4 1.4 Methods in Biodiesel Production 6 1.5 Types of Catalysts Involved in Biodiesel Production 7 1.5.1 Chemical Homogenous Catalysts 7 1.5.2 Solid Heterogeneous Catalysts 8 1.5.3 Biocatalysts 8 1.6 Factors Affecting Enzymatic Transesterification Reaction 8 1.6.1 Effect of Water in Enzyme Catalyzed Transesterification 9 1.6.2 Effect of Bioreactor 10 1.6.3 Effect of Acyl Acceptor on Enzymatic Production of Biodiesel 10 1.6.4 Effect of Temperature on Enzymatic Biodiesel Production 14 1.6.5 Effect of Glycerol on Enzymatic Biodiesel Production 14 1.6.6 Effect of Solvent on Biodiesel Production 16 1.7 Lipases as Biocatalysts for Biodiesel Production 17 1.7.1 Mechanisms of Lipase Action 19 1.7.2 Efficient Lipase Sources for Biodiesel Producing Biocatalyst 19 1.8 Comparative Analysis of Intracellular and Extracellular Lipases for Biodiesel Production 21 1.9 Recombinant Lipases for Cost-Effective Biodiesel Production 26 1.10 Immobilization of Lipases for Better Biodiesel Production 28 1.11 Recent Strategies to Improve Biodiesel Production 31 1.11.1 Combination of Lipases 31 1.11.2 Microwave and Ultrasonic-Assisted Reaction 33 1.12 Lipase Catalyzed Reaction Modeling and Statistical Approaches for Reaction Optimization 35 1.13 Conclusion and Summary 38 References 38 2 Application of Low-Frequency Ultrasound for Intensified Biodiesel Production Process 59 Mohd Razealy Anuar, Mohamed Hussein Abdurahman, Nor Irwin Basir and Ahmad Zuhairi Abdullah 2.1 Current Fossil Fuel Scenario 60 2.2 Biodiesel 60 2.3 Transesterification 61 2.4 Challenges for Improved Biodiesel Production 62 2.5 Homogeneous Catalyst for Biodiesel Production 63 2.6 Heterogeneous Catalyst for Biodiesel Production 64 2.7 Immiscibility of the Reactants 65 2.8 Ultrasound-Assisted Biodiesel Production Process 66 2.8.1 Fundamental Aspects of the Process 66 2.8.2 Homogeneously Catalyzed Ultrasound-Assisted System 69 2.8.3 Heterogeneously Catalyzed Ultrasound-Assisted System 72 2.8.3.1 Heterogeneously Acid Catalyzed System 72 2.8.3.2 Heterogeneous Based Catalyzed Ultrasound-Assisted System 74 2.8.3.3 Influence of Reaction Parameters 78 2.9 Conclusions 79 Acknowledgement 80 References 80 3 Application of Catalysts in Biodiesel Production 85 Anilkumar R. Gupta and Virendra K. Rathod 3.1 Introduction 85 3.2 Homogeneous Catalysis for the Biodiesel Production 89 3.2.1 Homogeneous Acid Catalyst 89 3.2.2 Homogeneous-Base Catalyst 93 3.3 Heterogeneous Catalyst 96 3.3.1 Heterogeneous Acid Catalyst 97 3.3.2 Heterogeneous-Base Catalyst 106 3.4 Biocatalysts 115 3.5 Conclusion 119 References 124 4 Hydrogenolysis as a Means of Valorization of Biodiesel-Derived Glycerol: A Review 137 Manjoro T.T., Adeniyi A. and Mbaya R.K.K. 4.1 Introduction 138 4.2 Ways of Valorization of Biodiesel-Derived Glycerol 139 4.2.1 Catalytic Conversion of Glycerol Into Value-Added Commodities 140 4.2.1.1 Catalytic Oxidation of Glycerol 140 4.2.1.2 Catalytic Dehydration of Glycerol 143 4.2.1.3 Pyrolysis of Bioglycerol 144 4.2.1.4 Glycerol Transesterification 145 4.2.1.5 Glycerol Direct Carboxylation 146 4.3 Hydrogenolysis of Glycerol 147 4.3.1 Definition of Hydrogenolysis 147 4.3.2 Catalytic Hydrogenolysis of Glycerol 148 4.3.3 Product Spectrum from Hydrogenolysis of Glycerol 148 4.3.4 Hydrogenolysis of Glycerol to 1,2-PDO (Propylene Glycol): Reaction Systems Overview 149 4.3.5 Catalyst Selection 151 4.3.6 Reaction Conditions That Influence the Hydrogenolysis of Glycerol to 1,2-PDO 153 4.3.6.1 Effect of Reaction Temperature 153 4.3.6.2 Effect of H2 Pressure 154 4.3.6.3 Effect of Initial Water Concentration 155 4.3.6.4 Effect of Reaction Time 156 4.3.6.5 Effect of Catalyst Weight 156 4.3.6.6 Proposed Reaction Mechanisms for Glycerol Hydrogenolysis to Produce 1,2-PDO 157 4.4 Conclusion 159 References 159 5 Current Status, Synthesis, and Characterization of Biodiesel 167 Akshay Garg, Gaurav Dwivedi, Prashant Baredar and Siddharth Jain 5.1 Introduction 167 5.2 Status of Biodiesel in India 169 5.3 Biodiesel Production in India 169 5.3.1 Feedstocks Popular in India 169 5.3.1.1 Jatropha (Jatropha curcas) Oil 171 5.3.1.2 Pongamia Oil 171 5.3.1.3 Mahua Oil 171 5.3.1.4 Neem Oil 171 5.3.1.5 Linseed Oil 171 5.3.1.6 Rubber Seed Oil 172 5.3.1.7 Tobacco Oil 172 5.3.1.8 Castor 172 5.3.1.9 Waste Cooking Oil 172 5.3.1.10 Algae Oil 172 5.3.2 Advantages of Non-Edible Oils 173 5.3.3 Modification Techniques 173 5.3.3.1 Blending 173 5.3.3.2 Micro-Emulsification 173 5.3.3.3 Cracking 174 5.3.3.4 Transesterification 174 5.3.4 Biodiesel Production Methodology 174 5.3.4.1 Catalytic Transesterification 174 5.3.4.2 Non-Catalytic Transesterification 178 5.3.5 Optimization Methodology for Biodiesel 179 5.3.5.1 Central Composite Design Technique 179 5.3.5.2 Box Behnken Technique 179 5.4 Properties of Biodiesel 180 5.5 Analytical Methods 181 5.5.1 Titration 181 5.5.2 Chromatic Methods 181 5.5.2.1 Gas Chromatography 183 5.5.2.2 High-Performance Liquid Chromatography 184 5.5.3 Spectroscopic Methods 184 5.5.3.1 Nuclear Magnetic Resonance Spectroscopy 184 5.5.3.2 Infrared Spectroscopy 185 5.5.4 Rancimat Method 185 5.5.5 Viscometry 186 5.6 Conclusion 186 References 187 6 Commercial Technologies for Biodiesel Production 195 Chikati Roick, Leonard Okonye, Nkazi Diankanua and Gorimbo Joshua Abbreviation 196 6.1 Introduction 196 6.2 Biodiesel Production 197 6.3 Technologies Used for Biodiesel Production 198 6.3.1 Chemical Reaction (Transesterification) 199 6.3.2 Thermochemical Conversion 199 6.3.3 Biomechanical Conversion 201 6.3.4 Direct Combustion 201 6.4 Other Technologies in Use for Biodiesel Production 201 6.5 Feedstock Requirement 203 6.6 Some Problems Facing Commercialization of Biodiesel in Africa 203 6.7 Case Studies/Current Status and Future Potential 204 6.8 Conclusions 207 Acknowledgments 208 References 208 7 A Global Scenario of Sustainable Technologies and Progress in a Biodiesel Production 215 M. B. Kumbhar, P. E. Lokhande,, U. S. Chavan and V.G. Salunkhe 7.1 Introduction 216 7.2 Current Status of Feedstock for Biodiesel Production Technology 218 7.3 Scenario of Biodiesel in Combustion Engine 222 7.4 Biodiesel Production Technologies 223 7.4.1 Direct Blending 223 7.4.2 Pyrolysis 224 7.4.3 Microemulsification 225 7.4.4 Transesterification 226 7.5 Microwave-Mediated Transesterification 227 7.6 Ultrasound-Mediated Transesterification 229 7.7 Catalysis in Biodiesel Production 230 7.7.1 Homogeneous Catalysts 230 7.7.2 Heterogeneous Catalysts 231 7.7.3 Heterogeneous Nanocatalysts 232 7.7.4 Supercritical Fluids 232 7.7.5 Biocatalysts 232 7.8 The Concept of Biorefinery 234 7.9 Summary and Outlook 236 7.10 Conclusion 237 References 237 8 Biodiesel Production Technologies 241 Moina Athar and Sadaf Zaidi 8.1 Introduction 242 8.2 Biodiesel Feedstocks 242 8.2.1 Selection of Feedstocks 243 8.3 Biodiesel Production Technologies 248 8.3.1 Pyrolysis 248 8.3.2 Dilution 249 8.3.3 Micro-Emulsion 249 8.3.4 Transesterification 249 8.3.4.1 Homogeneously Catalyzed Transesterification Processes 250 8.3.4.2 Heterogeneously Catalyzed Transesterification Processes 252 8.3.4.3 Enzymatic Catalyzed Transesterification Processes 252 8.4 Intensification Techniques for Biodiesel Production 253 8.4.1 Supercritical Alcohol Method 253 8.4.2 Microwave Heating 253 8.4.3 Ultrasonic Irradiation 255 8.4.4 Co-Solvent Method 256 8.5 Other Techniques of Biodiesel Production 256 References 257 9 Methods for Biodiesel Production 267 M.Gul, M.A. Mujtaba, H.H. Masjuki, M.A. Kalam and N.W.M. Zulkifli 9.1 Selection of Feedstock for Biodiesel 267 9.1.1 First-Generation Feedstock 268 9.1.2 Second-Generation Feedstock 268 9.1.3 Third-Generation Feedstock 269 9.2 Methods for Biodiesel Production 269 9.2.1 Dilution With Hydrocarbons Blending 269 9.2.2 Micro-Emulsion 269 9.2.3 Pyrolysis (Thermal Cracking) 270 9.2.4 Transesterification (Alcoholysis) 271 9.2.4.1 In Situ Transesterification (Reactive Extraction) 271 9.2.4.2 Conventional Transesterification 272 9.2.4.3 Microwave/Ultrasound-Assisted Transesterification 278 9.2.4.4 Variables Affecting Transesterification Reaction 278 References 282 10 Non-Edible Feedstock for Biodiesel Production 285 Chikati Roick, Kabir Opeyemi Otun, Nkazi Diankanua and Gorimbo Joshua List of Abbreviations 286 10.1 Introduction 286 10.2 Reports Relevant to Global Warming and Renewable Energy 287 10.3 Biofuels as an Alternative Energy Source 288 10.3.1 First-Generation Biofuels 288 10.3.2 Second-Generation Biofuels 289 10.3.3 Third-Generation Biofuels 290 10.4 Benefits of Using Biodiesel 290 10.5 Technologies of Biodiesel Production From Non-Edible Feedstock 291 10.6 Biodiesel Production by Transesterification 292 10.7 Non-Edible Feedstocks for Biodiesel Production 295 10.7.1 Non-Edible Vegetable Oils 296 10.7.2 Waste Cooking Oil 297 10.7.3 Algal Oil 298 10.7.4 Waste Animal Fat/Oil 299 10.8 Fuel Properties of Biodiesel Obtained From Non-Edible Feedstock 299 10.9 Advantages of Non-Edible Feedstocks 302 10.10 Economic Importance of Biodiesel Production 302 10.11 Conclusions 303 Acknowledgments 303 References 304 11 Oleochemical Resources for Biodiesel Production 311 Gayathri R., Ranjitha J. and Vijayalakshmi Shankar 11.1 Introduction 311 11.2 Definition of Oleochemicals 312 11.3 Oleochemical Types 313 11.4 Production of Biodiesel 315 11.5 Types of Feedstocks 317 11.5.1 Non-Edible Feedstocks 317 11.5.2 Non-Edible Vegetable Oil 317 11.5.3 Tall Oil 318 11.5.4 Waste Cooking Oils 318 11.5.5 Animal Fats 318 11.5.6 Chicken Fat 319 11.5.7 Lard 319 11.5.8 Tallow 320 11.5.9 Leather Industry Solid Waste Fat 321 11.5.10 Fish Oil 322 11.6 Uses of Oleochemicals 322 11.6.1 Polymer Applications 322 11.6.2 Application of Plant Oil as a Substitute for Petro-Diesel 323 11.6.3 Used as Surfactants 323 11.6.4 Oleochemicals Used in Pesticide 324 11.6.5 Oleochemicals Used in Spray Adjuvants and Solvents 324 11.7 Methyl Ester or Biodiesel Production 324 11.7.1 Palm Oil 326 11.7.2 Sunflower Oil 326 11.7.3 ME From AFW 327 11.8 Parameters Affecting the Yield of Biodiesel 327 11.8.1 Reaction Conditions 327 11.8.2 Catalyst 327 11.8.2.1 Alkali Catalyst 327 11.8.2.2 Acid Catalyst 329 11.8.2.3 Biocatalyst 329 11.8.2.4 Heterogeneous Catalyst 329 11.8.2.5 ME Conversion by Supercritical Method 329 11.8.3 Properties of Feedstock 330 11.8.3.1 Composition of FA 330 11.8.3.2 FFA 330 11.8.3.3 Heat 330 11.8.3.4 Presence of Unwanted Materials 330 11.8.3.5 Titer 332 11.8.4 Characteristic of Feedstock 332 11.9 Optimization of Reactions Conditions for High Yield and Quality of Biodiesel 332 11.9.1 Pre-Treatment of Feedstock 332 11.9.1.1 Elimination of Water 332 11.9.1.2 Elimination of Insoluble Impurities 332 11.9.1.3 Elimination of Unsaponifiables 333 11.9.2 Characterization and Selection of Feedstocks 333 11.9.3 Selection of Reaction Conditions 333 11.10 Oil Recovery 333 11.10.1 Alkaline Flooding Method 333 11.10.2 Additives 334 11.11 Quality Improvement of Biodiesel 334 11.11.1 Additives for Improving Combustion Ability 334 11.11.2 Additives for Enhancing the Octane Number 334 11.11.3 Additives for Improving the Stability 334 11.11.4 Additives to Enhance Cold Flow Property 334 11.11.5 Additives to Enhance Lubricity 335 11.11.6 Additives to Enhance Cetane Number 335 11.12 Conclusion 335 Abbreviations 335 References 336 12 Overview on Different Reactors for Biodiesel Production 341 V. C. Akubude, K.F. Jaiyeoba, T.F Oyewusi, E.C. Abbah, J.A. Oyedokun and V.C. Okafor 12.1 Introduction 341 12.2 Biodiesel Production Reactors 342 12.2.1 Batch Reactor 343 12.2.2 Continuous Stirred Tank Reactor 344 12.2.3 Fixed Bed Reactor 346 12.2.4 Bubble Column Reactor 347 12.2.5 Reactive Distillation Column 349 12.2.6 Hybrid Catalytic Plasma Reactor 350 12.2.7 Microreactors Technology 350 12.2.8 Oscillatory Flow Reactors 353 12.2.9 Other Novel Reactors 353 12.3 Future Prospects 354 12.4 Conclusion 354 References 354 13 Patents on Biodiesel 361 Azira Abdul Razak, Mohamad Azuwa Mohamed and Darfizzi Derawi 13.1 Introduction 361 13.2 Generation of Biodiesel 362 13.3 Development of Catalyst 363 13.3.1 Homogeneous Catalyst 364 13.3.2 Heterogeneous Catalyst 364 13.4 Method Producing Biodiesel 365 13.4.1 Pre-Treatment Process 365 13.4.2 Direct Use and Blending of Oils 366 13.4.3 Esterification of FFA 366 13.4.4 Transesterification of TAG 367 13.4.5 Pyrolysis 368 13.5 Reactor's Technology for Biodiesel Production 369 13.5.1 Continuous Stirred Tank Reactor 370 13.5.2 Fixed Bed Reactor 370 13.5.3 Micro-Mixer Reactor 371 13.6 Conclusion 372 References 372 14 Reactions of Carboxylic Acids With an Alcohol Over Acid Materials 377 J.E. Castanheiro 14.1 Introduction 377 14.2 Zeolites 378 14.3 SO3H as Catalyst 379 14.4 Metal Oxides 380 14.5 Heteropolyacids 382 14.6 Other Materials 384 14.7 Conclusions 384 References 385 15 Biodiesel Production From Non-Edible and Waste Lipid Sources 389 Opeoluwa O. Fasanya, Aishat A. Osigbesan and Onoriode P. Avbenake 15.1 Introduction 390 15.2 Non-Edible Plant-Based Oils 394 15.2.1 Jatropha curcas 394 15.2.2 Calophyllum inophyllum 397 15.2.3 Mesua ferrea 397 15.2.4 Jojoba Oil 398 15.2.5 Azadirachta indica 398 15.2.6 Rubber Seed Oil 399 15.2.7 Ricinus communis as Feedstock (Castor Oil) 402 15.2.8 Other Non-Edible Oils 403 15.3 Waste Animal Fats 404 15.4 Expired and Waste Cooking Oils 405 15.5 Algae/Microalgae 406 15.6 Insects as Biodiesel Feedstock 411 15.7 Deacidification 414 15.8 Other Technologies 414 15.9 Conclusion 415 References 415 16 Microalgae for Biodiesel Production 429 Charles Oluwaseun Adetunji, Victoria Olaide Adenigba, Devarajan Thangadura and Mohd Imran Ahamed 16.1 Introduction 430 16.2 Physicochemical Properties of Biodiesel From Microalgae 431 16.3 Genetic Engineering/Techniques Enhancing Biodiesel Production 432 16.4 Nanotechnology in Microalgae Biodiesel Production 434 16.5 Specific Examples of Biodiesel Production From Microalgae 434 16.6 Methodology Involved in the Extraction of Algae 438 16.6.1 Chemical Solvents Extraction 439 16.6.2 Extraction by Supercritical Carbon Dioxide 439 16.6.3 Extraction Using Biochemical Techniques 439 16.6.4 Extraction Involving Direct Transesterification 440 16.6.5 Extraction Using Transesterification Techniques 440 16.7 Conclusion and Future Recommendation to Knowledge 440 References 441 17 Biodiesel Production Methods and Feedstocks 447 Setareh Heidari and David A. Wood 17.1 Introduction 448 17.2 Biofuel Classification in Terms of Origin and Technological Conversion of Raw Materials 449 17.3 Techniques Capable of Producing Biodiesel on Commercial Scales 451 17.3.1 Direct and Blending Methods With the Aim of Biodiesel Generation 452 17.3.2 Microemulsion Methods 452 17.3.3 Pyrolysis Methods 453 17.3.4 Transesterification Methods 453 17.4 Influential Parameters on Biodiesel Production 454 17.4.1 The Choice of Transesterification Catalysts 454 17.4.2 Effects of Catalyst Characteristics on Biodiesel Production Efficiency 454 17.5 Biodiesel Markets and Economic Considerations 455 17.6 Challenges Confronting Biodiesel Uptake 456 17.7 Corrosion and Quality Monitoring Issues for Biodiesel 457 17.8 Conclusions 457 References 458 18 Application of Nanoparticles for the Enhanced Production of Biodiesel 465 Muhammad Hilman Mustapha, Akhsan Kamil Azizi, Wan Nur Aini Wan Mokhtar and Mohamad Azuwa Mohamed 18.1 Introduction 465 18.2 Solid Nanoparticles 466 18.3 Nanobioparticles/Nanobiocatalyst 471 18.4 Magnetic Nanoparticles 473 18.5 How Nanoparticles Enhanced Biodiesel Production? 475 18.6 Conclusion 477 References 477 Index 481