LEADER 05743nam  2200793 a 450 
001 9910827488203321
005 20240313140247.0
010   $a9781118498521
010   $a1118498526
010   $a9781299188570
010   $a1299188575
010   $a9781118498545
010   $a1118498542
010   $a9781118498538
010   $a1118498534
035   $a(CKB)2670000000325795
035   $a(EBL)1120631
035   $a(OCoLC)827207685
035   $a(SSID)ssj0000854605
035   $a(PQKBManifestationID)11464390
035   $a(PQKBTitleCode)TC0000854605
035   $a(PQKBWorkID)10911472
035   $a(PQKB)10922586
035   $a(MiAaPQ)EBC1120631
035   $a(Au-PeEL)EBL1120631
035   $a(CaPaEBR)ebr10657942
035   $a(CaONFJC)MIL450107
035   $a(PPN)224138804
035   $a(OCoLC)812249658
035   $a(FINmELB)ELB178496
035   $a(Perlego)1003378
035   $a(EXLCZ)992670000000325795
100   $a20121203d2013      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aProcess intensification for green chemistry $eengineering solutions for sustainable chemical processing /$fedited by Kamelia Boodhoo and Adam Harvey
205   $a1st ed.
210   $aChichester, West Sussex, U.K. $cWiley$d2013
215   $a1 online resource (431 p.)
300   $aDescription based upon print version of record.
311 08$a9780470972670 
311 08$a047097267X 
320   $aIncludes bibliographical references and index.
327   $aProcess Intensification For Green Chemistry: Engineering Solutions for Sustainable Chemical Processing; Contents; List of Contributors; Preface; 1 Process Intensification: An Overview of Principles and Practice; 1.1 Introduction; 1.2 Process Intensification: Definition and Concept; 1.3 Fundamentals of Chemical Engineering Operations; 1.3.1 Reaction Engineering; 1.3.2 Mixing Principles; 1.3.3 Transport Processes; 1.4 Intensification Techniques; 1.4.1 Enhanced Transport Processes; 1.4.2 Integrating Process Steps; 1.4.3 Moving from Batch to Continuous Processing; 1.5 Merits of PI Technologies
327   $a1.5.1 Business1.5.2 Process; 1.5.3 Environment; 1.6 Challenges to Implementation of PI; 1.7 Conclusion; Nomenclature; Greek Letters; References; 2 Green Chemistry Principles; 2.1 Introduction; 2.1.1 Sustainable Development and Green Chemistry; 2.2 The Twelve Principles of Green Chemistry; 2.2.1 Ideals of Green Chemistry; 2.3 Metrics for Chemistry; 2.3.1 Effective Mass Yield; 2.3.2 Carbon Efficiency; 2.3.3 Atom Economy; 2.3.4 Reaction Mass Efficiency; 2.3.5 Environmental (E) Factor; 2.3.6 Comparison of Metrics; 2.4 Catalysis and Green Chemistry
327   $a2.4.1 Case Study: Silica as a Catalyst for Amide Formation2.4.2 Case Study: Mesoporous Carbonaceous Material as a Catalyst Support; 2.5 Renewable Feedstocks and Biocatalysis; 2.5.1 Case Study: Wheat Straw Biorefinery; 2.6 An Overview of Green Chemical Processing Technologies; 2.6.1 Alternative Reaction Solvents for Green Processing; 2.6.2 Alternative Energy Reactors for Green Chemistry; 2.7 Conclusion; References; 3 Spinning Disc Reactor for Green Processing and Synthesis; 3.1 Introduction; 3.2 Design and Operating Features of SDRs; 3.2.1 Hydrodynamics; 3.2.2 SDR Scale-up Strategies
327   $a3.3 Characteristics of SDRs3.3.1 Thin-film Flow and Surface Waves; 3.3.2 Heat and Mass Transfer; 3.3.3 Mixing Characteristics; 3.3.4 Residence Time and Residence Time Distribution; 3.3.5 SDR Applications; 3.4 Case Studies: SDR Application for Green Chemical Processing and Synthesis; 3.4.1 Cationic Polymerization using Heterogeneous Lewis Acid Catalysts; 3.4.2 Solvent-free Photopolymerization Processing; 3.4.3 Heterogeneous Catalytic Organic Reaction in the SDR: An Example of Application to the Pharmaceutical/Fine Chemicals Industry; 3.4.4 Green Synthesis of Nanoparticles
327   $a3.5 Hurdles to Industry Implementation3.5.1 Control, Monitoring and Modelling of SDR Processes; 3.5.2 Limited Process Throughputs; 3.5.3 Cost and Availability of Equipment; 3.5.4 Lack of Awareness of SDR Technology; 3.6 Conclusion; Nomenclature; Greek Letters; Subscripts; References; 4 Micro Process Technology and Novel Process Windows - Three Intensification Fields; 4.1 Introduction; 4.2 Transport Intensification; 4.2.1 Fundamentals; 4.2.2 Mixing Principles; 4.2.3 Micromixers; 4.2.4 Micro Heat Exchangers; 4.2.5 Exothermic Reactions as Major Application Examples; 4.3 Chemical Intensification
327   $a4.3.1 Fundamentals
330   $aThe successful implementation of greener chemical processes relies not only on the development of more efficient catalysts for synthetic chemistry but also, and as importantly, on the development of reactor and separation technologies which can deliver enhanced processing performance in a safe, cost-effective and energy efficient manner. Process intensification has emerged as a promising field which can effectively tackle the challenges of significant process enhancement, whilst also offering the potential to diminish the environmental impact presented by the chemical industry.  Follow
606   $aGreen chemistry
606   $aChemical processes
606   $aSustainable engineering
615  0$aGreen chemistry.
615  0$aChemical processes.
615  0$aSustainable engineering.
676   $a628
701   $aBoodhoo$b Kamelia V. K$01719490
701   $aHarvey$b Adam$g(Adam P.)$01711043
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910827488203321
996   $aProcess intensification for green chemistry$94117375
997   $aUNINA