Chapter 1 Introduction��001
1��1 Fluidization and fluidized bed��001
1��2 Typical ��PB-Ug relationship��003
1��3 Geldart powder classification��006
1��4 Gas-solid fluidization regimes��007
1��5 Fluidization applications��010
1��6 Miniaturization of fluidized beds��013
1��7 Micro fluidized bed applications��017
1��8 Sources of information on micro fluidization��018
Abbreviation��019
Nomenclature��019
References��020

Chapter 2 Fundamentals of Gas-Solid Micro Fluidization��027
2��1 Bed pressure drops in micro fluidized beds��027
2��1��1 The bed pressure drop overshoot��028
2��1��2 The bed pressure drop offset��030
2��1��3 Deviation from the Ergun equation��033
2��2 Mechanistic analysis of the wall effects��036
2��2��1 The wall frictional force��038
2��2��2 Increase in bed voidage��043
2��2��3 Inhomogeneous flow��045
2��3 Discussions on the wall effects��050
2��4 Other influencing factors��053
2��4��1 Influence of particle diameter��053
2��4��2 Influence of gas properties��055
2��4��3 Influence of temperature��056
Abbreviation��057
Nomenclature��057
References��059

Chapter 3 Gas and Solid Mixing��062
3��1 Experimental and analytic techniques��062
3��1��1 Gas residence time distribution��063
3��1��2 Axial dispersion model��065
3��2 Gas mixing��069
3��2��1 Gas residence time distribution��069
3��2��2 Axial gas dispersion coefficient��071
3��2��3 Two-phase model analysis��072
3��2��4 The criteria for plug flow of gas in micro fluidized beds��077
3��3 Solid mixing��081
3��3��1 Solid mixing simulation��081
3��3��2 Particle feeding simulation��082
Abbreviation��086
Nomenclature��086
References��088

Chapter 4 Micro Fluidization Regimes��090
4��1 Experimental observations��090
4��2 Fixed bed��092
4��3 Minimum fluidization velocity��096
4��3��1 Factors influencing Umf��096
4��3��2 Prediction of minimum fluidization velocity��099
4��4 Particulate fluidization��102
4��5 Bubbling fluidized bed��104
4��5��1 The onset of bubbling fluidization��104
4��5��2 Prediction of minimum bubbling velocity��107
4��5��3 Bubble size��108
4��6 Slugging fluidized bed��109
4��6��1 The onset of slugging fluidization��109
4��6��2 Prediction of slugging velocity��111
4��7 Turbulent fluidized bed��113
4��7��1 The onset of turbulent fluidization��113
4��7��2 Prediction of transition velocity Uc��115
4��8 Distinction between micro and macro fluidized beds��116
4��9 Fluidization regime map for micro fluidized beds��119
Nomenclature��125
References��127

Chapter 5 Hydrodynamic Modeling of Micro Fluidized Beds��129
5��1 CFD modeling approaches��129
5��2 Two-fluid method��132
5��2��1 TFM formulation��132
5��2��2 TFM simulations and validations��136
5��2��3 TFM-predicted MFB hydrodynamics��140
5��3 The discrete element method��144
5��3��1 Model formulation��145
5��3��2 DEM simulations and validations��146
5��3��3 DEM-predicted MFB hydrodynamics��147
5��4 A brief discussion and future perspective��152
Abbreviation��153
Nomenclature��153
References��154

Chapter 6 Microreactors for Thermal Analysis of Gas-Solid Thermochemical Reactions��158
6��1 Thermal analysis approaches��158
6��1��1 Thermochemical reaction pathways��158
6��1��2 General requirements for thermal analysis approaches��159
6��2 Microreactors for thermal analysis��163
6��2��1 General approaches and requirements��163
6��2��2 Classification of microreactors��163
6��3 Furnace heating micro reactors��166
6��3��1 Micro fixed bed reactor��166
6��3��2 Gas pulsed microreactor��167
6��3��3 Thermogravimetric analyzer��168
6��3��4 The single and tandem ?-reactors��170
6��3��5 Drop-tube reactor��172
6��3��6 Catalyst cell fluidized bed reactor��173
6��4 Resistively heated micro reactors��174
6��4��1 Wire mesh reactor��174
6��4��2 Curie point reactor��176
6��4��3 Pulse-heated analysis of solid reaction reactor��177
6��4��4 Microprobe reactor��178
6��5 Particle bed heating micro reactors��178
6��5��1 Micro spouted bed reactor��178
6��5��2 Micro fluidized bed reactor��179
6��6 Other non-resistively heating micro reactors��180
6��6��1 Microwave microreactor��180
6��6��2 Laser ablation reactor��180
6��6��3 Thermal plasma reactor��181
6��7 Remarks��182
Abbreviation��184
References��184

Chapter 7 System of Micro Fluidized Bed Reaction Analysis��188
7��1 System configurations��189
7��1��1 System configurations of micro fluidized bed reaction analyzer��189
7��1��2 Micro fluidized bed reactor design��192
7��1��3 Solid sample feeding method��194
7��1��4 Liquid sample feeding method��195
7��1��5 Online gas sampling and analysis��196
7��1��6 Online particle sampling��197
7��1��7 Change of reaction atmosphere��198
7��2 Kinetic data analysis��200
7��2��1 Data acquisition��200
7��2��2 Data processing��201
7��2��3 Kinetic modeling��202
7��3 New developments in MFBRA��203
7��3��1 MFB thermogravimetric analyzer��203
7��3��2 Induction heating MFB��205
7��3��3 External force assistance��206
7��3��4 Micro spouted bed reaction analyzer��208
7��3��5 Membrane-assisted micro fluidized beds��208
7��3��6 Other developments��209
Abbreviation��209
Nomenclature��210
References��211

Chapter 8 Characteristics of Micro Fluidized Bed Reaction Analyzers��215
8��1 Approaching intrinsic kinetics��215
8��1��1 High heating and cooling rates��216
8��1��2 Effective suppression of diffusion��217
8��1��3 Close-to-plug flow of gas��220
8��1��4 Bed homogeneity��222
8��1��5 Applied kinetics��222
8��2 Understanding reaction mechanism��226
8��2��1 Revealing the true character of fast reactions��226
8��2��2 Detecting intermediary reactions��228
8��2��3 Decoding the reaction mechanism��229
8��2��4 Reactions with in/ex-situ solid particles��230
8��2��5 Non-isothermal differential applications��232
8��3 Reactions under water vapor atmosphere��233
8��3��1 High moisture content feedstocks��233
8��3��2 Reactions with steam as reactants��234
8��4 Sampling and characterization of solid particles during a reaction process��235
8��5 Multistage gas-solid reaction processes��236
8��6 Reaction kinetics under product gas inhibitory atmospheres��238
8��6��1 Isotope tagging method��238
8��6��2 Comparisons between the micro fluidized bed and thermogravimeter��239
Abbreviation��240
Nomenclature��241
References��241

Chapter 9 Applications of Micro Fluidized Beds��244
9��1 Drying��244
9��2 Adsorption��245
9��2��1 CO2 capture using capsulated liquid sorbents��246
9��2��2 CO2 capture using solid adsorbents��247
9��2��3 CO2 capture by gas-solid reactions��247
9��3 Catalytic reaction��249
9��3��1 Catalytic gas reaction��249
9��3��2 Catalytic gas-solid reaction��250
9��4 Thermal decomposition��255
9��4��1 Liquid decomposition��255
9��4��2 Solid decomposition��256
9��5 Pyrolysis��257
9��5��1 Biomass pyrolysis��258
9��5��2 Coal and oil shale pyrolysis��259
9��5��3 Blended material pyrolysis��259
9��6 Thermal cracking��262
9��7 Gasification��264
9��7��1 Biomass gasification��264
9��7��2 Coal gasification��265
9��7��3 In/ex-situ char gasification��265
9��8 Combustion��267
9��8��1 Decoupling combustion��267
9��8��2 Oxy-fuel combustion��268
9��8��3 Chemical looping combustion��269
9��8��4 In/ex-situ chart combustion��270
9��9 Reduction��272
9��9��1 Iron ore reduction��272
9��9��2 Nitrogen oxide reduction by tar��273
9��9��3 WO3 reduction-sulfurization��273
9��10 Other reactions��274
References��274

Chapter 10 Applications of MFBR in Industrial Process Development��281
10��1 Advanced combustion with low-NOx emissions��281
10��1��1 Low-NOx combustion technology��281
10��1��2 NOx reduction by pyrolysis products��283
10��1��3 Pilot experiments and commercial application��287
10��2 Reaction characteristics tested by MFBRA for biomass staged gasification��290
10��2��1 Staged gasification process analysis using MFBRA��290
10��2��2 Characteristics of gasification sub-processes by MFBRA��291
10��2��3 Design of an industrial FBTS gasification process��299
10��3 Light calcination of magnesite using transported bed��301
10��3��1 Existing technology and equipment��302
10��3��2 Kinetic analysis of magnesite calcination��302
10��3��3 Advanced transport bed calcination process��304
10��3��4 Engineering commissioning of a 400 kt/a industrial process��306
Abbreviation��307
Nomenclature��308
References��308

Chapter 11 Characterization of Liquid-Solid Micro Fluidized Beds��311
11��1 Introduction��311
11��2 Hydrodynamics properties��312
11��2��1 Manufacturing methods��312
11��2��2 Minimum fluidization velocity��313
11��2��3 Mixing��318
11��2��4 Mass transfer��319
11��3 Applications��322
11��3��1 Chemical conversions��322
11��3��2 Bioprocessing and bioproduction��322
11��3��3 Other applications��329
11��3��4 Challenges and prospects for MFB scaling-up��329
11��4 Conclusion��330
Abbreviation��330
Nomenclature��331
References��331

Chapter 12 Characterization of Gas-Liquid-Solid Micro Fluidized Beds��338
12��1 Hydrodynamics��338
12��1��1 Pressure drop and minimum fluidization velocity��338
12��1��2 Flow regimes�� expanded behavior�� solid holdup�� and multi-bubble behavior��349
12��2 Applications��366
12��2��1 Chemical reactions��366
12��2��2 Photocatalytic degradation of methylene blue (MB)��367
12��2��3 Catalytic oxidation of crotonaldehyde to crotonic acid��372
12��3 Summary��375
Nomenclature��375
References��377

Future Prospects��378