Verfügbarkeit: Waste sites as biological reactors

Waste sites as biological reactors: characterization and modeling

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Bibliographische Detailangaben
1. Verfasser:	Miller, Percival A. (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Boca Raton [u.a.] Lewis 2003
Schlagworte:	Mathematisches Modell Umwelt Bioreactors Refuse and refuse disposal > Biodegradation Waste disposal sites > Environmental aspects Waste disposal sites > Mathematical models Biologischer Abbau Bioreaktor Abfallbeseitigung
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Includes bibliographical references (p. 355-366) and index
Beschreibung:	383 p. ill. : 25 cm
ISBN:	1566705509

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Datensatz im Suchindex

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adam_text	Titel: Waste sites as biological reactors Autor: Miller, Percival A. Jahr: 2003 Table of Contents Chapter 1 Introduction................................................ 1 The Nature and Control of Waste Disposal Sites .............................. 1 The Bioreactor Concept...................................................... 3 Reactor Configurations of Relevance to Practical Description of a Waste Site .. 4 The Waste Site as a Biological Reactor....................................... 8 Chapter 2 Physical Characteristics of Waste Sites........................ 13 Waste Site Biological Reactor Concepts ...................................... 13 Basic Physical Characteristics of Solid Media............................. 13 Determination of Mean Particle S ize ..................................... 14 Particle Size Distribution Approaches to Finding Mean Size of Porous Media................................................... 14 Grain Size Statistics vs. Age of Wastes.................................... 20 Packed Bed Porosity, Hydraulic Conductivity and Permeability............. 20 Porosity of a Waste Site...................................................... 21 An Approach to Determining Porosity of A Packed Bed of Mixed Particle Types................................................. 23 Density and Other Properties of Mixed Soil and Waste Materials.............. 25 Applicability of Conductivity and Permeability Relations for Packed Beds..... 25 Permeability k of a Mixed Porous Media...................................... 30 Permeability (k) Correction for Packed Bed Flow............................. 32 Correction of Packed Column Pressure Drop for Wall Effects.................. 35 Corrections for Pressure Drop Relations for Fluid Flow through a Waste Site .. 38 Waste Site Particle Properties: Size and Shape................................ 38 Characterization of Surface Area and Related Physical Properties of Wastes.................................................... 44 Specific Surface Areas of Solid Materials From Liquid or Gas Sorption Isotherms............................................... 44 Equivalence Between BET and GAB Water Adsorption Models............ 50 Areas from Nitrogen, Vapor Adsorption vs. Moisture Sorption............. 50 Relationship between Water Activity and Other Moisture Characteristic Terms........................................... 51 Range of Adsorption in Solid Materials and Water Availability to Organisms............................................... 51 Determination of Solid Structure Characteristics from Adsorption Data..... 54 Example............................................................... 56 The Relation between Specific Surface Area and Sphericity of Waste Particles....................................................... 57 Example............................................................... 65 Particle Shape Considerations............................................. 66 Application to Mixtures of Granular Materials............................. 70 Application of Particle-based Properties to the Kinetic Modeling of Reactors................................................... 71 Chapter 3 Characterization of Disposed Wastes: Physical and Chemical Properties and Biodegradation Factors........___ 73 Determination of Physical and Chemical Characteristics of Wastes ............ 73 MSW Composition vs. Landfill Layer Depth or Age: Data for Initialization___ 74 Individual Wastes and Characteristics......................................... 75 Characteristics of Paper Wastes............................................... 75 Characteristics of Food Wastes............................................... 77 Characteristics of Yard Wastes................................................ 78 Characteristics of Plastics Wastes............................................. 79 Plastics Deterioration in Waste Sites.......................................... 83 Chemical Deterioration of Plastics......................................... 85 Biological Deterioration of Plastics........................................ 85 Effect of Physical Structure of Plastic on Degradability..................... 86 Organisms Involved in Plastics Biodegradation............................. 86 Variation of Degradation with Plastic Type................................ 87 Effect of Plastics Biodegradability Test Method on Published Results.................................................... 88 Effect of Air or Oxygen Content on Plastics Degradation................... 90 Plastics Deterioration Rates ............................................... 91 Landfill Leachate and Landfill Gas Characteristics............................ 91 Landfill Leachate......................................................... 94 Leachate Organics........................................................ 95 Leachate BOD/COD Ratio as an Indicator of Biological Treatability................................................ 96 Hazardous or Toxic Compounds in Waste Site Leachates................... 97 Chapter 4 Waste Site Ecology.......................................... 101 Influence of the Waste Site Environment on Types of Organisms Present....... 102 Species Competition for Food at a Waste Site................................. 103 The Range of Organisms at Waste Sites....................................... 104 Organisms Found in Compost Piles........................................... 104 Trophic Relations and Environmental Factors Determining Organisms at Waste Sites...................................................106 Influence of Site Environmental Factors on Organism Types................... 113 The Waste Site as an Environment for Organisms............................. 114 Definition of Impact of Organisms at Disposed Waste Site..................... 117 Organisms Reported at Landfills, Dumps and Other Waste Sites: Considerations................................................118 Waste Site Scavengers ....................................................... 119 Bears..................................................................... 122 Other Large Animals at Waste Sites....................................... 123 Small Animals............................................................ 123 Waste Removal Impact of Animals at Disposal Sites.......................... 124 Birds..................................................................... 127 Waste Removal by Insects and Soil Mesofauna................................ 130 Impact of Worms and Nematodes.......................................... 131 Springtails (Collembola).................................................. 134 Waste Site Microorganisms: Fungi, Yeast and Bacteria..................... 137 Soil Fungi ................................................................ 137 Landfill Bacteria.......................................................... 141 Summary.................................................................... 141 Chapter 5 Moisture and Heat Flows..................................... 143 Moisture as a Control of Processes in the Waste Site.......................... 143 Water Film Thickness on Solid Materials under Sorption Regime.............. 145 Method I for Liquid Film Thickness Determination ........................... 147 Correction of Errors in Calculation of t by Method 1........................ 148 Method II for Moisture Film Thickness....................................... 149 Water Potential vs. Water Activity of Soils and Solid Porous Materials.................................................149 The Issue of Mixed Water Saturation or Varied Water Potential in Wastes...... 153 Maximum Moisture Sorption by a Material................................... 154 Effect of Waste Moisture Content on Soil Organisms.......................... 156 Water Availability to Organisms.............................................. 160 Hydraulic Conductivity...................................................... 161 Capillary Effects in Waste Sites .............................................. 163 Theory ................................................................... 164 Waste Site Moisture Retention Characteristics ................................ 166 Full Range Moisture Capillarity.............................................. 167 Middle Moisture Content Range.............................................. 168 Moist to Saturation or Wet Moisture Content Section of Curve ................ 169 Moisture Retention Curve in the Dry Range for Landfilled Waste.............. 169 Boundary Conditions ........................................................ 170 Estimation of Constants Full-Range (Wet to Dry) Moisture Capillarity Relations.......................................................170 Reliability of Estimated Values............................................... 173 Relevance of the Lower Curve Junction to Bioreactor Simulation.............. 173 Development of Moisture Capillarity-Hydraulic Conductivity Relationships ... 175 Dry Range Logarithmic Curve Section, for 9j 6 0 ................... 175 Medium Moisture Range, Power Law Curve, for #,- 0 6j............... 176 Saturated-to-Mid Range (Parabolic) Curve, #,- 9 6j.................... 177 Summary of Extended Range Conductivity Relationships..................... 178 Moisture Inflow and Moisture Balance........................................ 179 Locations Used for Landfill Cover Moisture Impact Simulations............... 179 Microorganism Rate vs. Water Content and Water Activity.................... 180 Limitations of Applying Water Potential Concepts............................ 182 Models of Water Content vs. Water Potential................................. 182 Limitations of Models of Water Retention vs. Humidity.................... 183 Discussion................................................................... 186 Chapter 6 Heat Generation and Transport............................... 189 Introduction ................................................................. 189 The Heat Model ............................................................. 191 Viscous Energy Dissipation............................................... 191 Definition of Waste Site System Heat Capacity................................ 192 Heat Content of System: Landfill Gas or Air as Saturating Fluid............... 194 The Volumetric Heat Generation Term q .................................... 195 Heat Impact of Moisture Uptake and Flows................................... 195 Heat Effect of Moisture Evaporation....................................... 197 Evaporation Enhancement Due to Thermal Gradient in Pore Structure......... 198 Temperature vs. Water Vapor Diffusion, Latent Heat and Density Variation___200 Water Vapor Diffusion....................................................200 Latent Heat of Vaporization............................................... 201 Water Vapor Density Variation............................................201 Other Data for Evaluating DA, f and dpv/dT VS. Temperature (T)........202 Definitions of Waste Site System Tortuosity................................... 203 Tortuosity as a Function of Particle Flatness...............................204 Tortuosity as a Function of Particle Surface Properties..................... 208 Energy Balance at Atmospheric Boundary of Bioreactor...................... 209 Net Solar Radiation....................................................... 210 Effect of Surface Albedo..................................................... 212 Incoming Longwave Radiation............................................... 212 Outgoing Longwave Radiation............................................... 214 Latent Heat Flow of a Bioreactor System..................................... 214 Temperature Variation with Depth............................................ 215 Sensible Heat Flow from the Bioreactor System............................... 215 Development of the Heat Generation Model .................................. 215 Solution to the Heat Equation ................................................216 Heat Equation ............................................................ 216 Temperature at the Waste Site Surface........................................ 218 Variables of the Heat Generation Model ......................................223 Landfill Thermal Conductivity Km............................................ 223 Thermal Conductivity and Diffusivity Values................................. 224 Estimating the Mean Thermal Conductivity of Mixed Waste Materials.........224 Chapter 7 The Kinetics of Decomposition of Wastes......................229 Introduction ................................................................. 229 Anaerobic and Aerobic Decomposition Patterns ..............................229 Anaerobic Decomposition ...................................................230 The Anaerobic Decomposition Process....................................231 Waste Hydrolysis by Soil Organisms....................................231 Determination of the Hydrolysis Rates of Organic Solid Materials.......232 Practical Forms of the Hydrolysis Relationship..........................233 Anaerobic and Aerobic Regimes and Lag Time .........................234 Hydrolysis Products in Anaerobic Decomposition.......................... 235 Hydrolysis Products Use for Acidogenic Biomass Growth and Acid Generation....................................................237 Acid Production in Anaerobic Operation...................................238 Acetic Acid Generation................................................... 238 Methane Generation ...................................................... 239 Carbon Dioxide (CO2) Generation.........................................239 Total GAS Output ........................................................240 Gas in Management Scenarios.............................................241 Decomposition PROCESS Sensitivity to pH...............................242 Improvement of Reactor Liquid Phase pH............................... 242 Approaches to Incorporating the Effect of pH on Decomposition Kinetics .......................................... 244 Ion Concentration Inhibition......................................... 244 Mechanistic Models of pH Effect.................................... 245 Models for Effect of Product Inhibition and Incorporating pH Effect.. 246 Assumptions for Mass Balance Model for Anaerobic Decomposition.......248 Leachate or Gas Recycle as Anaerobic Bioreactor Options .................249 The Kinetics of Aerobic Decomposition at a Waste Site.......................249 Aerobic Hydrolysis....................................................... 250 The Change from Anaerobic to Aerobic Regimes..........................251 Lag Time for Aerobic Reactor Decomposition............................. 251 Aerobic Hydrolysis Product Generation, Incorporation and Use ...............253 Use of Hydrolysis Products for Growth of Acidogenic Biomass and Acid Formation.....................................................253 Basic Relations for Oxygen-Limited Growth...............................253 Oxygen as a Limiting Substrate in Aerobic Kinetics..................... 254 Oxygen Solubility in Water or Liquid...................................... 257 Oxygen Transport Considerations ......................................... 259 The Oxygen Consumption Term R(O).....................................259 Change of Oxygen Concentration with Waste Site Depth...................260 Oxygen Transport and Consumption in a Column Waste Site Reactor....... 260 Diffusivity Coefficients for Liquid and Gas Solutes ...........................264 Practical Waste Site Parameters for Diffusion.............................. 264 A Stoichiometric Approach to Decomposition................................ 266 The Stoichiometry of Decomposition of Wastes............................267 Development of a General Stoichiometric Relationship.....................268 The Dependence of the Stoichiometric Relationship on fs and Yield Factor Yx/s .............................................269 Reactor Considerations for /j ............................................. 270 Definition of Residence Time ts ........................................... 272 The Fraction of Substrate Energy Stored in the Biomass....................274 Accuracy of the Value of %............................................... 274 The Energy Expression.................................................... 276 Other Discussions of the Yield Term Yave,e for the Energy Expression......277 Cell Mass Yield Factor YX/s from Chemical Oxygen Demand (cod)........ 278 Yield Estimation from Oxygen Consumption..............................279 The Value of YX/o........................................................279 Use of fs Values to Estimate Water Production from Aerobic Decomposition.................................................281 CO2 Produced, O2 Required and Heat Produced During Aerobic Decomposition.................................................282 The Stoichiometry of Anaerobic Decomposition of Solid Wastes........... 283 Water Consumption During Anaerobic Decomposition Process..........284 Carbon Dioxide, Methane and Hydrogen Sulfide from Anaerobic Decomposition............................................ 284 Methane Production from Stoichiometric Anaerobic Decomposition..... 284 Hydrogen Sulfide Production........................................... 284 Stoichiometric Heat Production During the Anaerobic Decomposition Reaction............................................. 285 Values of Decomposition Kinetic Constants...................................286 Chapter 8 Decomposition Issues........................................291 Introduction ................................................................. 291 Waste Site Models Of Previous Waste Site Studies............................ 291 Landfill Soil Sampling Studies ............................................... 297 Organics vs. Landfill Depth ............................................... 297 Landfill Soil Microorganism Studies.......................................... 298 Mass Transfer Considerations................................................ 304 Sherwood Number........................................................ 305 Application of Transport Model to Gas Flux.................................. 308 Gas-Liquid Transfers........................................................ 308 Mass Flux................................................................... 309 Removal of Chemical in Liquid Film......................................... 310 Application of Transport Model to Gas Chemicals Flux....................... 311 Biodegradation Rates for Waste Site Organic Chemicals.......................312 Partitioning Between Gas and Liquid......................................... 312 Waste Site Settlement........................................................ 313 Chapter 9 Sensitivity Analysis and Conclusions.........................321 Introduction ................................................................. 321 Information in Database for MSW Fractions as Substrate...................... 322 Range of Anaerobic and Hydrolysis Rates.................................... 323 Chemical Characterization of Waste Fractions................................323 Moisture Sorption Factors for Municipal Waste Materials..................... 324 Moisture Response of Materials to the Environment........................... 325 Testing Approach............................................................327 Other Properties Estimated for the Database..................................328 Constants for Aerobic and Anaerobic Decomposition.........................328 Soil Moisture Content........................................................329 Moisture Inflow Effect of Cover............................................329 Temperature as a Decomposition Factor......................................329 Biofiltration Effect.......................................................330 Settlement Effect ............................................................ 330 Discussion...............................................................330 Moisture Input............................................................331 Conclusions ................................................................. 331 Recommendations........................................................ 332 Appendix 1 Waste Properties..........................................333 Appendix 2 Landfill Gas Properties....................................347 References...............................................................355 Index........................................................................367
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spelling	Miller, Percival A. Verfasser aut Waste sites as biological reactors characterization and modeling Percival A. Miller with Nicholas L. Clesceri Boca Raton [u.a.] Lewis 2003 383 p. ill. : 25 cm txt rdacontent n rdamedia nc rdacarrier Includes bibliographical references (p. 355-366) and index Mathematisches Modell Umwelt Bioreactors Refuse and refuse disposal Biodegradation Waste disposal sites Environmental aspects Waste disposal sites Mathematical models Biologischer Abbau (DE-588)4145625-7 gnd rswk-swf Bioreaktor (DE-588)4006780-4 gnd rswk-swf Abfallbeseitigung (DE-588)4000100-3 gnd rswk-swf Bioreaktor (DE-588)4006780-4 s Abfallbeseitigung (DE-588)4000100-3 s Biologischer Abbau (DE-588)4145625-7 s DE-604 Clesceri, Nicholas L. Sonstige oth HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=010149115&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Miller, Percival A. Waste sites as biological reactors characterization and modeling Mathematisches Modell Umwelt Bioreactors Refuse and refuse disposal Biodegradation Waste disposal sites Environmental aspects Waste disposal sites Mathematical models Biologischer Abbau (DE-588)4145625-7 gnd Bioreaktor (DE-588)4006780-4 gnd Abfallbeseitigung (DE-588)4000100-3 gnd
subject_GND	(DE-588)4145625-7 (DE-588)4006780-4 (DE-588)4000100-3
title	Waste sites as biological reactors characterization and modeling
title_auth	Waste sites as biological reactors characterization and modeling
title_exact_search	Waste sites as biological reactors characterization and modeling
title_full	Waste sites as biological reactors characterization and modeling Percival A. Miller with Nicholas L. Clesceri
title_fullStr	Waste sites as biological reactors characterization and modeling Percival A. Miller with Nicholas L. Clesceri
title_full_unstemmed	Waste sites as biological reactors characterization and modeling Percival A. Miller with Nicholas L. Clesceri
title_short	Waste sites as biological reactors
title_sort	waste sites as biological reactors characterization and modeling
title_sub	characterization and modeling
topic	Mathematisches Modell Umwelt Bioreactors Refuse and refuse disposal Biodegradation Waste disposal sites Environmental aspects Waste disposal sites Mathematical models Biologischer Abbau (DE-588)4145625-7 gnd Bioreaktor (DE-588)4006780-4 gnd Abfallbeseitigung (DE-588)4000100-3 gnd
topic_facet	Mathematisches Modell Umwelt Bioreactors Refuse and refuse disposal Biodegradation Waste disposal sites Environmental aspects Waste disposal sites Mathematical models Biologischer Abbau Bioreaktor Abfallbeseitigung
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