05256nam 22006014a 450 991100477980332120200520144314.01-281-51422-597866115142280-08-050229-60-585-47095-2(CKB)111087026778682(EBL)349315(OCoLC)476165576(SSID)ssj0000127591(PQKBManifestationID)12002686(PQKBTitleCode)TC0000127591(PQKBWorkID)10074195(PQKB)10079302(MiAaPQ)EBC349315(EXLCZ)9911108702677868220010420d2002 uy 0engur|n|---|||||txtccrComputational flow modeling for chemical reactor engineering /Vivek V. RanadeSan Diego Academic Pressc20021 online resource (475 p.)Process systems engineering series ;v. 5Description based upon print version of record.0-12-576960-1 Includes bibliographical references and indexes.Cover; TOCContents; PART I: INTRODUCTION; CHChapter 1. Reactor Engineering and Flow Modeling; 1.1. Chemical Reactor Engineering (CRE); 1.2. Computational Flow Modeling (CFM); 1.3. CFM for CRE; References; PART II: COMPUTATIONAL FLOW MODELING; CHChapter 2. Mathematical Modeling of Flow Processes; 2.1. Basic Governing Equations; 2.2. Auxiliary Equations; 2.3. Boundary Conditions; 2.4. Discussion; 2.5. Summary; References; CHChapter 3. Turbulent Flow Processes; 3.1. Introduction; 3.2. Turbulence: Physical Picture; 3.3. Modeling Approaches; 3.4. Turbulence Models Basedon RANS; 3.5. SummaryReferencesCHChapter 4. Multiphase Flow Processes; 4.1. Introduction; 4.2. Modeling Dispersed Multiphase Flows; 4.3. Other Types of Multiphase Flows; 4.4. Summary; References; Appendix 4.1. Time Scales for Dispersed Multiphase Flows; Appendix 4.2. Correlations for Drag Coefficient; Appendix 4.3. Interphase Heat and Mass Transfer Correlations; CHChapter 5. Reactive Flow Processes; 5.1. Introduction; 5.2. Turbulent Reactive Mixing; 5.3. Modeling Approaches; 5.4. RANS-based Models of Reactive Flow Processes; 5.5. Multiphase Reactive Flow Processes; 5.6. Summary; ReferencesCHChapter 6. Numerical Solution of Model Equations6.1. Introduction; 6.2. Finite Volume Method; 6.3. Finite Volume Method for Calculationof Flow Field; 6.4. Finite Volume Method for Unsteady Flows; 6.5. Application of Finite Volume Method; 6.6. Summary; References; CHChapter 7. Numerical Solution of Complex Flow Models; 7.1. Simulation of Turbulent Flows; 7.2. Simulation of Multiphase Flows; 7.3. Simulation of Reactive Flows; 7.4. Special Topics; 7.5. Summary; References; CHChapter 8. Computational Tools for Simulating Flow Processes; 8.1. Mapping a Computational Flow Model on a Computer8.2. Pre-processors8.3. Solvers; 8.4. Post-processors; 8.5. Summary; References; PART III: CFM FOR CRE; CHChapter 9. Flow Modeling for Reactor Engineering; 9.1. Reactor Engineering Methodology; 9.2. Example 1: Suspension Polymerization Reactor; 9.3. Example 2: OXY Reactor for EDC; 9.4. Example 3: Bubble Column Reactor; 9.5. Example 4: FCC Regenerator; 9.6. Summary; References; PART IV: APPLICATIONS; CHChapter 10. Stirred Reactors; 10.1. Engineering of Stirred Reactors; 10.2. CFD-based Modeling of Stirred Reactors; 10.3. Computational Snapshot Approach10.4. Application to Reactor Engineering10.5. Summary; References; CHChapter 11. Bubble Column Reactors; 11.1. Engineering of Bubble Column Reactors; 11.2. CFD-based Modeling of Bubble Column Reactors; 11.3. Application to Reactor Engineering; 11.4. Summary; References; Appendix 11.1. Multigroup Model to Simulate Bubble Size Distribution; CHChapter 12. Fluidized Bed Reactors; 12.1. Engineering Fluidized Bed Reactors; 12.2. CFD Modeling of Gas-Solid Reactors; 12.3. Applications to Reactor Engineering; 12.4. Summary; References; CHChapter 13. Fixed Bed and Other Types of Reactors13.1. Fixed Bed ReactorsThis book describes how modeling fluid flow in chemical reactors may offer solutions that improve design, operation, and performance of reactors. Chemical reactors are any vessels, tubes, pipes, or tanks in which chemical reactions take place. Computational Flow Modeling for Chemical Reactor Engineering will show the reactor engineer how to define the specific roles of computational flow modeling, select appropriate tools, and apply these tools to link reactor hardware to reactor performance. Overall methodology is illustrated with numerous case studies.Industry has invested subProcess systems engineering ;v. 5.Chemical reactorsFluid dynamicsMathematical modelsChemical reactorsFluid dynamicsMathematical models.660/.2832Ranade Vivek V43998MiAaPQMiAaPQMiAaPQBOOK9911004779803321Computational Flow Modeling for Chemical Reactor Engineering357446UNINA02000nam0 22004693i 450 PUV093953320251003044316.0030642903920090121d1988 ||||0itac50 baengusz01i xxxe z01nMicrocomputers and laboratory instrumentationDavid J. Malcolme-Lawes2. edNew York [etc.]Plenum pressc1988XI, 272 p.ill.26 cmBibliografia: P. 261-263.FisicaStrumenti per misureElaborazione dei datiFIRNAPC235490IMicroelaboratoriFIRUFIC002643EStrumenti scientificiFIRCFIC011141I530FISICA14530.70285416FISICA. STRUMENTAZIONE. Applicazione di microeleboratori22MisuratoriApparecchi di misuraApparecchi di misurazioneStrumenti di misurazioneStrumenti di misuraMicroelaboratori elettroniciPersonal computerPC <Personal computer>Strumenti per misureMisuratoriStrumenti per misureApparecchi di misuraStrumenti per misureApparecchi di misurazioneStrumenti per misureStrumenti di misurazioneStrumenti per misureStrumenti di misuraMicroelaboratoriMicroelaboratori elettroniciMicroelaboratoriPersonal computerMicroelaboratoriPC <Personal computer>Malcolme-Lawes, David J.PUVV00811407014777ITIT-00000020090121IT-BN0095 NAP 01SALA DING $PUV0939533Biblioteca Centralizzata di Ateneo1 v.1 v. 01SALA DING 530 MAL.mi 0102 0000022195 VMA A4 1 v.Y 1996021519960215 01Microcomputers and laboratory instrumentation119229UNISANNIO