05541nam 2200673Ia 450 991083009040332120221206101719.01-281-75864-797866117586463-527-61539-33-527-61538-5(CKB)1000000000376227(EBL)481352(SSID)ssj0000142069(PQKBManifestationID)11158141(PQKBTitleCode)TC0000142069(PQKBWorkID)10091431(PQKB)11428116(MiAaPQ)EBC481352(OCoLC)212132991(EXLCZ)99100000000037622719950210d1995 uy 0engur|n|---|||||txtccrDynamics of environmental bioprocesses[electronic resource] modelling and simulation /Jonathan B. Snape ... [et al.]Weinheim ;New York VCHc19951 online resource (524 p.)Description based upon print version of record.3-527-28705-1 Includes bibliographical references and index.Dynamics of Environmental Bioprocesses; Preface; Organisation of the Book; ISIM Simulation Software; Acknowledgements; Table of Contents; Nomenclature for Chapters 1 and 2; 1 Modelling Principles; 1.1 The Role of Modelling in Environmental Technology; 1.2 General Aspects of the Modelling Approach; 1.3 Model Classification; 1.3.1 Deterministic Models; 1.3.2 Stochastic Models; 1.3.3 Steady-State Models; 1.3.4 Dynamic Models; 1.4 General Modelling Procedure; 1.5 Simulation Tools; 1.6 ISIM; 1.7 Introductory ISIM Example: WASTE; 1.8 Formulation of Dynamic Balance Equations1.8.1 Mass Balance Procedures1.8.1.1 Case A . Continuous Stirred-Tank Reactor; 1.8.1.2 Case B . Tubular Reactor; 1.8.1.3 Case C . River with Eddy Current; 1.8.1.4 Rate of Accumulation Term; 1.8.1.5 Convective Flow Terms; 1.8.1.6 Production Rate; 1.8.1.7 Diffusion of Components; 1.8.1.8 Interphase Transport; 1.8.1.9 Case A . Waste Holding Tank: Total and Component Mass Balance Example; 1.8.1.10 Case B . The Plug-Flow Tubular Reactor; 1.8.1.11 Case C . Biological Hazard Room; 1.8.1.12 Case D . Lake Pollution Problem; 1.8.2 Energy Balancing1.8.2.1 Case A . Determining Heat Transfer Area or Cooling Water Temperature1.8.2.2 Case B . Heating of a Filling Tank; 1.9 Chemical and Biological Reaction Systems; 1.9.1 Modes of Reactor Operation; 1.9.1.1 Batch Reactors; 1.9.1.2 Semi-Continuous or Fed-Batch Operation; 1.9.1.3 Continuous Operation; 1.9.2 Reaction Kinetics; 1.9.2.1 Chemical Kinetics; 1.9.2.2 Biological Reaction Kinetics; 1.9.2.3 Simple Microbial Growth Kinetics; 1.9.2.4 Substrate Uptake Kinetics; 1.9.2.5 Substrate Inhibition of Growth; 1.9.2.6 Additional Forms of Inhibition; 1.9.2.7 Other Expressions for Specific Growth Rate1.9.2.8 Multiple-Substrate Kinetics1.9.2.9 Structured Kinetic Models; 1.9.2.10 Interacting Micro-Organisms; 1.10 Modelling of Bioreactor Systems; 1.10.1 Stirred Tank Reactors; 1.10.2 Modelling Tubular Plug-Flow Reactor Behaviour; 1.10.2.1 Steady-State Balancing; 1.10.2.2 Unsteady-State Balancing; 1.11 Mass Transfer Theory; 1.11.1 Phase Equilibria; 1.11.2 Interphase Mass Transfer; 1.11.2.1 Case A . Steady-State Tubular and Column Modelling; 1.11.3 Case Studies; 1.11.3.1 Case A . Aeration of a Tank of Water; 1.11.3.2 Case B . Biological Oxidation in an Aerated Tank1.11.3.3 Case C . Determination of Biological Oxygen Uptake Rates by a Dynamic Method1.11.4 Gas-Liquid Phase Transfer Across a Free Surface; 1.12 Diffusion and Biological Reaction in Solid Phase Biosystems; 1.12.1 External Mass Transfer; 1.12.2 Finite Difference Model for Internal Transfer; 1.12.3 Case Studies for Diffusion with Biological Reaction; 1.12.3.1 Case A . Estimation of Oxygen Diffusion Effects in a Biofilm; 1.12.3.2 Case B . Biofilm Nitrification; 1.13 Process Control; 1.14 Optimisation. Parameter Estimation and Sensitivity Analysis1.14.1 Case A . Estimation of Bioreaction Kinetic Parameters for Batch Degradation Using ESL and SIMUSOLVDynamic environmental processes are complex; the easiest and most effective way to understanding them lies through the disciplines of dynamic modelling and computer simulation.The prerequisite modelling fundamentals are presented in the first chapter in a manner comprehensible to students as well as to practising scientists and engineers. The second chapter describes the many environmental processes that lend themselves to modelling, for example pollution and wastewater treatment. The third part of the book provides 65 simulation examples both on the page and on an accompanying diskettBioremediationMathematical modelsWaterPollutionMathematical modelsBioremediationComputer simulationWaterPollutionComputer simulationBioremediationMathematical models.WaterPollutionMathematical models.BioremediationComputer simulation.WaterPollutionComputer simulation.628.168015118628.5/01/5118628.5015118Snape Jonathan B888200MiAaPQMiAaPQMiAaPQBOOK9910830090403321Dynamics of environmental bioprocesses1984066UNINA