Verfügbarkeit: Membrane contactor technology

Membrane contactor technology: water treatment, food processing, gas separation, and carbon capture

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Bibliographische Detailangaben
Weitere Verfasser:	Younas, Mohammad (HerausgeberIn), Rezakazemi, Mashallah (HerausgeberIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Weinheim, Germany Wiley-VCH [2022]
Schlagworte:	Lebensmitteltechnologie Membrankontaktor Carbon dioxide capture and storage Stoffübertragung Gastrennung Membranverfahren Abwasserreinigung CG10: Prozesssteuerung CH30: Technische u. Industrielle Chemie Chemical Engineering Chemie Chemische Verfahrenstechnik Chemistry FO20: Herstellung u. Verarbeitung von Lebensmitteln Food Processing, Production & Manufacture Food Science & Technology Herstellung u. Verarbeitung von Lebensmitteln Industrial Chemistry Lebensmittelforschung u. -technologie Process Engineering Prozesssteuerung Technische u. Industrielle Chemie Aufsatzsammlung
Online-Zugang:	http://www.wiley-vch.de/publish/dt/books/ISBN978-3-527-34861-9/ Inhaltsverzeichnis
Beschreibung:	xviii, 350 Seiten Illustrationen, Diagramme 24.4 cm x 17 cm
ISBN:	3527348611 9783527348619

Internformat

MARC


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653			\|a Chemical Engineering
653			\|a Chemie
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653			\|a FO20: Herstellung u. Verarbeitung von Lebensmitteln
653			\|a Food Processing, Production & Manufacture
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653			\|a Industrial Chemistry
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999			\|a oai:aleph.bib-bvb.de:BVB01-032810127

Datensatz im Suchindex

_version_	1804182675318112256
adam_text	VII CONTENTS PREFACE XV ABOUT THE AUTHORS XVII 1 INTRODUCTION TO MEMBRANE TECHNOLOGY 1 MOHAMMAD YOUNAS AND MASHALLAH REZAKAZEMI 1.1 OVERVIEW OF MEMBRANE TECHNOLOGY 1 1.2 CONVENTIONAL MEMBRANE SEPARATION PROCESSES 2 1.2.1 MICROFILTRATION (MF) 2 1.2.2 ULTRAFILTRATION (UF) 2 1.2.3 NANOFILTRATION (NF) 3 1.2.4 REVERSE OSMOSIS (RO) 3 1.2.5 ELECTRODIALYSIS (ED) 4 1.2.6 PERVAPORATION (PV) 5 1.3 MOLECULAR WEIGHT CUTOFF (MWCO) 8 1.4 CONCENTRATION POLARIZATION 9 1.5 MEMBRANE FOULING 10 1.6 DIAFILTRATION 11 1.7 HISTORICAL PERSPECTIVE 11 1.8 CONCLUDING REMARKS AND FUTURE CHALLENGES 12 REFERENCES 14 2 INTRODUCTION TO MEMBRANE CONTACTOR TECHNOLOGY 17 MOHAMMAD YOUNAS AND MASHALLAH REZAKAZEMI 2.1 MEMBRANE CONTACTOR SEPARATION PROCESSES 17 2.1.1 MEMBRANE CONTACTORS 17 2.1.2 HISTORY AND BACKGROUND OF MEMBRANE CONTACTORS 20 2.1.3 TYPES OF MEMBRANE CONTACTOR SYSTEMS 21 2.1.3.1 SOLID POROUS MEMBRANE AS MEDIUM OF CONTACT IN MEMBRANE CONTACTORS 21 2.1.3.2 LIQUID MEMBRANE CONTACTORS 30 2.1.4 MEMBRANE CONTACTOR INTEGRATED SYSTEMS 34 2.1.5 POTENTIAL OF MEMBRANE CONTACTOR IN CONCENTRATION, TEMPERATURE POLARIZATION, WETTING, AND FOULING OF MEMBRANES 35 VIII CONTENTS 2.2 CONCLUSION AND FUTURE TRENDS OF MEMBRANE CONTACTORS 37 REFERENCES 38 3 TRANSPORT THEORY IN MEMBRANE CONTACTOR: OPERATIONAL PRINCIPLE 45 MOHAMMAD YOUNAS, WAHEED UR REHMAN, AND MASHALLAH REZAKAZEMI 3.1 DIFFUSIONAL MASS AND HEAT TRANSFER MODELING 45 3.2 MEMBRANE CHARACTERIZATION MODELS 46 3.2.1 CONTACT ANGLE AND LIQUID ENTRY PRESSURE 46 3.2.2 LIQUID ENTRY PRESSURE (LEP) 49 3.2.3 PERMPOROMETRY (PORE SIZE DISTRIBUTION) 52 3.2.4 ELECTRON MICROSCOPY 52 3.3 TRANSPORT MODELS IN LIQUID-LIQUID CONTACTOR 52 3.3.1 RESISTANCE IN SERIES MODEL 55 3.3.1.1 MODEL APPROACH 56 3.3.1.2 TWO FILM THEORY 56 3.3.1.3 PHASE EQUILIBRIUM IN LIQUID-LIQUID SYSTEM 58 3.3.1 A OVERALL MASS TRANSFER COEFFICIENT 59 3.4 TRANSPORT MODEL IN GAS-LIQUID SYSTEMS 60 3.4.1 PHASE EQUILIBRIUM FOR GAS-LIQUID SYSTEM 61 3.4.2 RESISTANCE IN SERIES MODEL 61 3.5 REACTIVE DIFFUSION IN LIQUID-SIDE BOUNDARY LAYER 62 3.6 MASS TRANSFER RESISTANCE ANALYSIS 63 3.7 CORRELATIONS FOR MASS TRANSFER COEFFICIENTS 65 3.7.1 CORRELATION FOR FLOW IN SHELL SIDE 66 3.7.2 CORRELATION FOR FLOW IN TUBE SIDE 66 3.7.3 CORRELATION FOR MASS TRANSFER IN MEMBRANE PORES 68 3.8 CORRELATIONS FOR HEAT TRANSFER COEFFICIENTS 69 3.9 INTERFACIAL TRANSFER AREA 70 3.10 AXIAL PRESSURE DROP IN MEMBRANE CONTACTOR MODULE 71 3.11 DYNAMIC MODELING 71 3.12 TRANSFER UNITS AND MODULE DESIGN LENGTH 72 3.13 NUMERICAL MODELING OF MASS TRANSPORT IN MEMBRANE CONTACTOR MODULES 73 3.13.1 MASS TRANSFER IN SHELL SIDE 75 3.13.2 MASS TRANSFER INSIDE FIBERS 77 3.13.3 MASS TRANSFER IN MEMBRANE PORES 78 3.13.4 NUMERICAL MODELING TERM IN THE CASE OF MEMBRANE WETTING 79 3.14 NUMERICAL MODELING OF HEAT TRANSPORT IN MEMBRANE CONTACTOR MODULES 81 3.14.1 GOVERNING EQUATION IN COLD AND HOT CHANNELS 82 3.14.2 GOVERNING EQUATION INSIDE MEMBRANE 82 3.15 MODEL SOLUTION ALGORITHM 83 3.16 CONCLUSIONS AND PERSPECTIVES 84 CONTENTS IX 3.A MEMBRANE TRANSPORT THEORY: OPERATIONAL PRINCIPLE 84 3.A.1 STEADY-STATE RESISTANCE-IN-SERIES MODEL ACROSS LIQUID-LIQUID CONTACTOR 84 3.A.1.1 HYDROPHOBIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 84 3.A.1.2 HYDROPHOBIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 85 3.A.1.3 HYDROPHOBIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 85 3.A.1.4 HYDROPHOBIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 85 3.A.1.5 HYDROPHILIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 86 3.A.1.6 HYDROPHILIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 86 3.A.1.7 HYDROPHILIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 86 3.A.1.8 HYDROPHILIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 87 3.A.1.9 COMPOSITE MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 87 3.A.1.10 COMPOSITE MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 87 3.A.1.11 COMPOSITE MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 87 3.A.1.12 COMPOSITE MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 88 3.A.2 STEADY-STATE RESISTANCE-IN-SERIES MODEL ACROSS GAS-LIQUID CONTACTOR 88 3.A.2.1 HYDROPHOBIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 88 3.A.2.2 HYDROPHOBIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 88 3.A.2.3 HYDROPHOBIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 89 3.A.2.4 HYDROPHOBIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 89 3.A.2.5 HYDROPHILIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 89 3.A.2.6 HYDROPHILIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 90 3.A.2.7 HYDROPHILIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 90 3.A.2.8 HYDROPHILIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 91 CONTENTS 3.A.2.9 COMPOSITE MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 91 3.A.2.10 COMPOSITE MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 91 3.A.2.11 COMPOSITE MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 91 3.A.2.12 COMPOSITE MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 92 3.A.3 DYNAMIC MODELING ACROSS THE STORAGE TANK 92 REFERENCES 93 4 MODULE DESIGN AND MEMBRANE MATERIALS 99 NABILAH FAZIL, SIDRA SAQIB, AHMAD MUKHTAR, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 4.1 4.2 4.2.1 4.2.2 4.2.3 4.2.4 4.3 4.4 4.5 4.5.1 4.5.2 4.6 INTRODUCTION 99 MEMBRANE MODULE DESIGN CONFIGURATION 100 PLATE-AND-FRAME MODULES 100 SPIRAL WOUND MODULES 103 TUBULAR MODULES 104 HOLLOW FIBER MODULES 106 MEMBRANE CONTACTOR MODULE HOUSING 111 MEMBRANE MODULE FLOW CONFIGURATION 116 MEMBRANE MATERIALS 116 POLYMER MATERIALS 118 INORGANIC FILLERS 125 MEMBRANE AND MEMBRANE MODULE FOR MEMBRANE DISTILLATION (MD) AND OSMOTIC MEMBRANE DISTILLATION (OMD) 126 4.7 4.8 4.9 4.10 SOLVENTS USED IN MEMBRANE SYNTHESIS 128 MEMBRANE SYNTHESIS TECHNIQUES 128 CONCLUSIONS 130 FUTURE PERSPECTIVE 131 REFERENCES 131 5 MODE OF OPERATION IN MEMBRANE CONTACTORS 143 WAHEED UR REHMAN, ZARRAR SALAHUDDIN, SARAH FARRUKH, MUHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 5.1 5.1.1 5.1.2 5.1.3 5.1.4 5.1.4.1 5.1.4.2 5.1.4.3 5.1.5 MEMBRANE DISTILLATION (MD) 143 BASIC PRINCIPLES OF MD PROCESS 143 MD CONFIGURATIONS 144 OVERALL DRIVING FORCE 145 OVERALL MASS TRANSFER COEFFICIENT, K 147 FEED-SIDE MASS TRANSFER 148 MEMBRANE MASS TRANSFER 150 STRIP-SIDE MASS TRANSFER 151 VAPOR PRESSURE POLARIZATION COEFFICIENT, 0 V 152 CONTENTS XI 5.1.5.1 5.1.5.2 5.1.5.3 5.1.6 5.1.6.1 5.1.7 5.1.8 5.1.9 5.1.10 5.2 5.2.1 5.2.2 5.2.2.1 5.2.2.2 5.2.23 5.2.2.4 5.2.2.5 5.2.3 5.2.4 5.2.5 5.3 5.3.1 5.3.2 5.3.3 5.3.4 5.3.5 5.3.6 5.4 5.4.1 5.4.2 5.4.3 5.5 DCMD 152 FEED-SIDE AND STRIP-SIDE HEAT TRANSFER 153 MEMBRANE HEAT TRANSFER 153 AGMD 154 SGMD 156 VMD 157 MEMBRANES FOR MD PROCESS 157 PROS AND CONS OF MD PROCESS 158 FUTURE PROSPECTS OF MD PROCESS 161 OSMOTIC MEMBRANE DISTILLATION (OMD) 161 BASIC PRINCIPLES OF OMD PROCESS 161 OVERALL MASS TRANSFER 163 MASS TRANSFER ACROSS FEED BOUNDARY LAYER 163 MASS TRANSFER ACROSS STRIPPER BOUNDARY LAYER 163 MASS TRANSFER ACROSS MEMBRANE 164 MASS TRANSFER COEFFICIENT FOR FEED AND STRIPPER SIDE 164 MASS TRANSFER COEFFICIENT ACROSS MEMBRANE 164 STRIPPING SOLUTIONS FOR OMD 165 MEMBRANES FOR OMD PROCESS 166 PROS AND CONS OF OMD PROCESS 166 FORWARD OSMOSIS 167 BASIC PRINCIPLES OF FO PROCESS 167 CALCULATION OF THE OSMOTIC PRESSURES 167 REVERSE SOLUTE FLUX IN FO 170 MEMBRANES FOR FO PROCESS 170 DRAW SOLUTES FOR FO PROCESS 171 PROS AND CONS OF FO PROCESS 172 PRESSURE-RETARDED OSMOSIS 172 BASIC PRINCIPLES OF PRO PROCESS 172 MEMBRANES FOR PRO PROCESS 175 PROS AND CONS OF PRO PROCESS 176 CONCLUSIONS 176 REFERENCES 176 6 APPLICATIONS OF MEMBRANE CONTACTOR TECHNOLOGY IN WASTEWATER TREATMENT 185 AYESHA REHMAN, XIANHUI LI, SARAH FARRUKH, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 6.1 6.2 6.2.1 6.2.2 6.2.3 6.2.4 6.2.5 INTRODUCTION 185 COMMON TOXIC SUBSTANCES IN WASTEWATER 187 PHENOLS 187 HEAVY METALS 188 AMMONIA 188 HYDROGEN SULFIDE 188 CARBON DIOXIDE 188 XII CONTENTS 6.2.6 PETROLEUM HYDROCARBONS 188 6.2.7 POLYCYCLIC AROMATIC HYDROCARBONS 189 6.2.8 NITROBENZENE 189 6.3 ENVIRONMENTAL RISKS OF WASTEWATER 189 6.4 MEMBRANE TECHNOLOGY FOR WASTEWATER TREATMENT 190 6.5 MEMBRANE CONTACTOR TECHNOLOGY FOR REMOVAL OF ORGANIC CONTAMINANTS FROM WASTEWATER 193 6.6 REMOVAL OF INORGANIC CONTAMINANTS FROM WASTEWATER 200 6.7 POLYMER-BASED ADSORPTION MEMBRANES 202 6.8 ION-EXCHANGE NANOPOROUS MEMBRANE 204 6.9 MICELLAR-ENHANCED ULTRAFILTRATION MEMBRANE 204 6.10 MEMBRANE MATERIALS FOR WATER TREATMENT 205 6.11 MEMBRANE MATERIALS FOR MICROFILTRATION (MF) AND ULTRAFILTRATION (UF) 206 6.12 MEMBRANE MATERIALS FOR NANOFILTRATION (NF) 206 6.13 MEMBRANE MATERIALS FOR REVERSE OSMOSIS (RO) 207 6.14 MEMBRANE MATERIALS FOR FORWARD OSMOSIS (FO) 207 6.15 CHALLENGES IN MEMBRANE MATERIALS TO PREVENT FOULING 208 6.16 CONCLUSIONS AND PERSPECTIVES 209 REFERENCES 210 7 APPLICATIONS OF MEMBRANE CONTACTORS IN FOOD INDUSTRY 219 WAHEED UR REHMAN, BAZLA SARWAR, SIDRA SAQIB, AHMAD MUKHTAR, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 7.1 INTRODUCTION 219 7.2 MEMBRANE DISTILLATION (MD) APPLICATIONS IN FOOD INDUSTRY 219 7.2.1 MD IN THE CONCENTRATION OF APPLE JUICE 221 7.2.2 MD IN THE CONCENTRATION OF ORANGE JUICE 222 7.2.3 MD IN THE CONCENTRATION OF MILK 222 7.2.4 MD IN THE TREATMENT OF SALINE DAIRY WASTE WATER 223 7.2.5 MD IN THE CONCENTRATION OF MUSCADINE GRAPE POMACE 224 7.2.6 MD IN THE RECOVERY OF PHENOLS FROM OLIVE MILL WASTEWATER 225 7.2.7 MD IN THE CONCENTRATION OF SUCROSE SOLUTION 225 7.2.8 EFFECT OF OPERATING PARAMETERS ON MD FLUX 225 7.3 APPLICATION OF OSMOTIC MEMBRANE DISTILLATION (OMD) IN FOOD INDUSTRY 227 7.3.1 EFFECT OF OPERATING CONDITIONS ON OMD WATER FLUX 228 7.3.2 OMD IN THE CONCENTRATION OF APPLE JUICE 231 7.3.3 OMD IN THE CONCENTRATION OF GRAPE JUICE 232 7.3.4 OMD IN THE CONCENTRATION OF POMEGRANATE JUICE 233 7.3.5 OMD IN THE CONCENTRATION OF ORANGE JUICE 235 7.3.6 OMD IN THE CONCENTRATION OF CRANBERRY AND NONI JUICES 235 7.3.7 OMD IN THE CONCENTRATION OF KIWI AND PINEAPPLE JUICES 236 7.3.8 OMD IN THE CONCENTRATION OF TEA EXTRACTS 236 7.3.9 DEALCOHOLIZATION OF BEER AND WINE 237 CONTENTS XIII 7.4 COUPLED OPERATION OF OSMOTIC DISTILLATION AND MEMBRANE DISTILLATION 238 7.5 CONCLUSIONS 239 7.6 FUTURE PERSPECTIVES 239 REFERENCES 240 8 APPLICATIONS OF MEMBRANE CONTACTOR TECHNOLOGY FOR PRE-COMBUSTION CARBON DIOXIDE (CO 2 ) CAPTURE 247 ZARRAR SALAHUDDIN, SARAH FARRUKH, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 8.1 INTRODUCTION 247 8.2 WHY PRE-COMBUSTION CARBON CAPTURE? 250 8.3 MEMBRANES FOR PRE-COMBUSTION CARBON CAPTURE 250 8.3.1 HYDROGEN (H 2 )-SELECTIVE MEMBRANES 250 8.3.2 CO 2 -SELECTIVE MEMBRANES 255 8.4 ADVANTAGES AND LIMITATIONS OF PRE-COMBUSTION CARBON CAPTURE USING MEMBRANE TECHNOLOGY 262 8.5 APPLICATIONS OF PRE-COMBUSTION CARBON CAPTURE 263 8.6 CURRENT TRENDS AND FUTURE PROSPECTS 263 8.7 CONCLUDING AND FUTURE DIRECTIONS 269 REFERENCES 269 9 APPLICATION OF MEMBRANE CONTACTOR TECHNOLOGY FOR POST-COMBUSTION CARBON DIOXIDE (C0 2 ) CAPTURE 281 MUHAMMAD B. WAZIR, MUHAMMAD DAUD, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 9.1 INTRODUCTION 281 9.2 MEMBRANES FOR POST-COMBUSTION CO 2 CAPTURE 282 9.2.1 MEMBRANE TYPES 282 9.2.2 MEMBRANE MODULES 285 9.3 EXPERIMENTAL MEMBRANE MATERIALS FOR POST-COMBUSTION CO 2 SEQUESTRATION 285 9.4 COMMERCIAL MEMBRANES FOR POST-COMBUSTION CO 2 SEPARATION 288 9.5 COST OF POST-COMBUSTION CO 2 CAPTURE IN MEMBRANE CONTACTORS 289 9.6 ABSORBENTS FOR POST-COMBUSTION CO 2 SEPARATION 291 9.6.1 AMINE-BASED ABSORBENTS 291 9.6.2 AMMONIA 293 9.6.3 SALT SOLUTIONS 294 9.6.4 IONIC LIQUIDS 295 9.7 CONCLUSION AND FUTURE PERSPECTIVE 295 REFERENCES 296 10 MARKET PROSPECTS OF MEMBRANE CONTACTORS 305 ZAHRA PEZESHKI, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 10.1 MEMBRANE CONTACTOR MARKET DYNAMICS 305 XIV CONTENTS INDEX 342 10.2 10.3 10.3.1 10.3.2 10.3.3 10.3.4 10.4 10.5 10.6 10.6.1 10.6.2 10.6.3 10.6.4 10.6.5 10.6.6 10.6.7 10.6.8 10.6.9 10.6.10 10.6.11 10.6.12 10.6.13 10.6.14 10.7 10.8 MARKET OVERVIEW 306 MEMBRANE CONTACTOR MARKET BY APPLICATION 313 WATER AND WASTEWATER TREATMENT MARKET 313 FOOD PROCESSING MARKET 315 GAS SEPARATION MARKET 318 CARBON CAPTURE MARKET 321 MEMBRANE CONTACTOR MARKET, BY MEMBRANE 321 MEMBRANE CONTACTOR MARKET, BY REGION 325 RECENT DEVELOPMENTS OF MEMBRANE CONTACTOR COMPANIES 328 3M COMPANY 328 COBETTER FILTRATION EQUIPMENT PVT. LTD. 329 EUROWATER 329 JU.CLA.SSRL 329 VEOLIA ENVIRONNEMENT SA 329 PTI PACIFIC PTY. LTD. 330 KVAERNER ASA 330 LENNTECH B.V. 330 PURE WATER GROUP 330 TNO COMPANY 330 EUWA H. H. EUMANN GMBH (EUWA) 330 HYDRO-ELEKTRIK GMBH 331 KH TEC GMBH 331 ROMFIL GMBH 331 FUTURE DIRECTIONS 331 CONCLUSION 332 REFERENCES 332 11 CONCLUSIONS AND PERSPECTIVE 337 MOHAMMAD YOUNAS AND MASHALLAH REZAKAZEMI 11.1 FUTURE DIRECTIONS 340
adam_txt	VII CONTENTS PREFACE XV ABOUT THE AUTHORS XVII 1 INTRODUCTION TO MEMBRANE TECHNOLOGY 1 MOHAMMAD YOUNAS AND MASHALLAH REZAKAZEMI 1.1 OVERVIEW OF MEMBRANE TECHNOLOGY 1 1.2 CONVENTIONAL MEMBRANE SEPARATION PROCESSES 2 1.2.1 MICROFILTRATION (MF) 2 1.2.2 ULTRAFILTRATION (UF) 2 1.2.3 NANOFILTRATION (NF) 3 1.2.4 REVERSE OSMOSIS (RO) 3 1.2.5 ELECTRODIALYSIS (ED) 4 1.2.6 PERVAPORATION (PV) 5 1.3 MOLECULAR WEIGHT CUTOFF (MWCO) 8 1.4 CONCENTRATION POLARIZATION 9 1.5 MEMBRANE FOULING 10 1.6 DIAFILTRATION 11 1.7 HISTORICAL PERSPECTIVE 11 1.8 CONCLUDING REMARKS AND FUTURE CHALLENGES 12 REFERENCES 14 2 INTRODUCTION TO MEMBRANE CONTACTOR TECHNOLOGY 17 MOHAMMAD YOUNAS AND MASHALLAH REZAKAZEMI 2.1 MEMBRANE CONTACTOR SEPARATION PROCESSES 17 2.1.1 MEMBRANE CONTACTORS 17 2.1.2 HISTORY AND BACKGROUND OF MEMBRANE CONTACTORS 20 2.1.3 TYPES OF MEMBRANE CONTACTOR SYSTEMS 21 2.1.3.1 SOLID POROUS MEMBRANE AS MEDIUM OF CONTACT IN MEMBRANE CONTACTORS 21 2.1.3.2 LIQUID MEMBRANE CONTACTORS 30 2.1.4 MEMBRANE CONTACTOR INTEGRATED SYSTEMS 34 2.1.5 POTENTIAL OF MEMBRANE CONTACTOR IN CONCENTRATION, TEMPERATURE POLARIZATION, WETTING, AND FOULING OF MEMBRANES 35 VIII CONTENTS 2.2 CONCLUSION AND FUTURE TRENDS OF MEMBRANE CONTACTORS 37 REFERENCES 38 3 TRANSPORT THEORY IN MEMBRANE CONTACTOR: OPERATIONAL PRINCIPLE 45 MOHAMMAD YOUNAS, WAHEED UR REHMAN, AND MASHALLAH REZAKAZEMI 3.1 DIFFUSIONAL MASS AND HEAT TRANSFER MODELING 45 3.2 MEMBRANE CHARACTERIZATION MODELS 46 3.2.1 CONTACT ANGLE AND LIQUID ENTRY PRESSURE 46 3.2.2 LIQUID ENTRY PRESSURE (LEP) 49 3.2.3 PERMPOROMETRY (PORE SIZE DISTRIBUTION) 52 3.2.4 ELECTRON MICROSCOPY 52 3.3 TRANSPORT MODELS IN LIQUID-LIQUID CONTACTOR 52 3.3.1 RESISTANCE IN SERIES MODEL 55 3.3.1.1 MODEL APPROACH 56 3.3.1.2 TWO FILM THEORY 56 3.3.1.3 PHASE EQUILIBRIUM IN LIQUID-LIQUID SYSTEM 58 3.3.1 A OVERALL MASS TRANSFER COEFFICIENT 59 3.4 TRANSPORT MODEL IN GAS-LIQUID SYSTEMS 60 3.4.1 PHASE EQUILIBRIUM FOR GAS-LIQUID SYSTEM 61 3.4.2 RESISTANCE IN SERIES MODEL 61 3.5 REACTIVE DIFFUSION IN LIQUID-SIDE BOUNDARY LAYER 62 3.6 ' MASS TRANSFER RESISTANCE ANALYSIS 63 3.7 CORRELATIONS FOR MASS TRANSFER COEFFICIENTS 65 3.7.1 CORRELATION FOR FLOW IN SHELL SIDE 66 3.7.2 CORRELATION FOR FLOW IN TUBE SIDE 66 3.7.3 CORRELATION FOR MASS TRANSFER IN MEMBRANE PORES 68 3.8 CORRELATIONS FOR HEAT TRANSFER COEFFICIENTS 69 3.9 INTERFACIAL TRANSFER AREA 70 3.10 AXIAL PRESSURE DROP IN MEMBRANE CONTACTOR MODULE 71 3.11 DYNAMIC MODELING 71 3.12 TRANSFER UNITS AND MODULE DESIGN LENGTH 72 3.13 NUMERICAL MODELING OF MASS TRANSPORT IN MEMBRANE CONTACTOR MODULES 73 3.13.1 MASS TRANSFER IN SHELL SIDE 75 3.13.2 MASS TRANSFER INSIDE FIBERS 77 3.13.3 MASS TRANSFER IN MEMBRANE PORES 78 3.13.4 NUMERICAL MODELING TERM IN THE CASE OF MEMBRANE WETTING 79 3.14 NUMERICAL MODELING OF HEAT TRANSPORT IN MEMBRANE CONTACTOR MODULES 81 3.14.1 GOVERNING EQUATION IN COLD AND HOT CHANNELS 82 3.14.2 GOVERNING EQUATION INSIDE MEMBRANE 82 3.15 MODEL SOLUTION ALGORITHM 83 3.16 CONCLUSIONS AND PERSPECTIVES 84 CONTENTS IX 3.A MEMBRANE TRANSPORT THEORY: OPERATIONAL PRINCIPLE 84 3.A.1 STEADY-STATE RESISTANCE-IN-SERIES MODEL ACROSS LIQUID-LIQUID CONTACTOR 84 3.A.1.1 HYDROPHOBIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 84 3.A.1.2 HYDROPHOBIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 85 3.A.1.3 HYDROPHOBIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 85 3.A.1.4 HYDROPHOBIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 85 3.A.1.5 HYDROPHILIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 86 3.A.1.6 HYDROPHILIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 86 3.A.1.7 HYDROPHILIC MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 86 3.A.1.8 HYDROPHILIC MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 87 3.A.1.9 COMPOSITE MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 87 3.A.1.10 COMPOSITE MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM AQUEOUS PHASE TO ORGANIC PHASE) 87 3.A.1.11 COMPOSITE MEMBRANE BASED ON ORGANIC-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 87 3.A.1.12 COMPOSITE MEMBRANE BASED ON AQUEOUS-PHASE SIDE (SPECIES TRANSFERS FROM ORGANIC PHASE TO AQUEOUS PHASE) 88 3.A.2 STEADY-STATE RESISTANCE-IN-SERIES MODEL ACROSS GAS-LIQUID CONTACTOR 88 3.A.2.1 HYDROPHOBIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 88 3.A.2.2 HYDROPHOBIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 88 3.A.2.3 HYDROPHOBIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 89 3.A.2.4 HYDROPHOBIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 89 3.A.2.5 HYDROPHILIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 89 3.A.2.6 HYDROPHILIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 90 3.A.2.7 HYDROPHILIC MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 90 3.A.2.8 HYDROPHILIC MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 91 CONTENTS 3.A.2.9 COMPOSITE MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 91 3.A.2.10 COMPOSITE MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 91 3.A.2.11 COMPOSITE MEMBRANE BASED ON LIQUID-PHASE SIDE (SPECIES TRANSFERS FROM GAS PHASE TO LIQUID PHASE) 91 3.A.2.12 COMPOSITE MEMBRANE BASED ON GAS-PHASE SIDE (SPECIES TRANSFERS FROM LIQUID PHASE TO GAS PHASE) 92 3.A.3 DYNAMIC MODELING ACROSS THE STORAGE TANK 92 REFERENCES 93 4 MODULE DESIGN AND MEMBRANE MATERIALS 99 NABILAH FAZIL, SIDRA SAQIB, AHMAD MUKHTAR, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 4.1 4.2 4.2.1 4.2.2 4.2.3 4.2.4 4.3 4.4 4.5 4.5.1 4.5.2 4.6 INTRODUCTION 99 MEMBRANE MODULE DESIGN CONFIGURATION 100 PLATE-AND-FRAME MODULES 100 SPIRAL WOUND MODULES 103 TUBULAR MODULES 104 HOLLOW FIBER MODULES 106 MEMBRANE CONTACTOR MODULE HOUSING 111 MEMBRANE MODULE FLOW CONFIGURATION 116 MEMBRANE MATERIALS 116 POLYMER MATERIALS 118 INORGANIC FILLERS 125 MEMBRANE AND MEMBRANE MODULE FOR MEMBRANE DISTILLATION (MD) AND OSMOTIC MEMBRANE DISTILLATION (OMD) 126 4.7 4.8 4.9 4.10 SOLVENTS USED IN MEMBRANE SYNTHESIS 128 MEMBRANE SYNTHESIS TECHNIQUES 128 CONCLUSIONS 130 FUTURE PERSPECTIVE 131 REFERENCES 131 5 MODE OF OPERATION IN MEMBRANE CONTACTORS 143 WAHEED UR REHMAN, ZARRAR SALAHUDDIN, SARAH FARRUKH, MUHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 5.1 5.1.1 5.1.2 5.1.3 5.1.4 5.1.4.1 5.1.4.2 5.1.4.3 5.1.5 MEMBRANE DISTILLATION (MD) 143 BASIC PRINCIPLES OF MD PROCESS 143 MD CONFIGURATIONS 144 OVERALL DRIVING FORCE 145 OVERALL MASS TRANSFER COEFFICIENT, K 147 FEED-SIDE MASS TRANSFER 148 MEMBRANE MASS TRANSFER 150 STRIP-SIDE MASS TRANSFER 151 VAPOR PRESSURE POLARIZATION COEFFICIENT, 0 V 152 CONTENTS XI 5.1.5.1 5.1.5.2 5.1.5.3 5.1.6 5.1.6.1 5.1.7 5.1.8 5.1.9 5.1.10 5.2 5.2.1 5.2.2 5.2.2.1 5.2.2.2 5.2.23 5.2.2.4 5.2.2.5 5.2.3 5.2.4 5.2.5 5.3 5.3.1 5.3.2 5.3.3 5.3.4 5.3.5 5.3.6 5.4 5.4.1 5.4.2 5.4.3 5.5 DCMD 152 FEED-SIDE AND STRIP-SIDE HEAT TRANSFER 153 MEMBRANE HEAT TRANSFER 153 AGMD 154 SGMD 156 VMD 157 MEMBRANES FOR MD PROCESS 157 PROS AND CONS OF MD PROCESS 158 FUTURE PROSPECTS OF MD PROCESS 161 OSMOTIC MEMBRANE DISTILLATION (OMD) 161 BASIC PRINCIPLES OF OMD PROCESS 161 OVERALL MASS TRANSFER 163 MASS TRANSFER ACROSS FEED BOUNDARY LAYER 163 MASS TRANSFER ACROSS STRIPPER BOUNDARY LAYER 163 MASS TRANSFER ACROSS MEMBRANE 164 MASS TRANSFER COEFFICIENT FOR FEED AND STRIPPER SIDE 164 MASS TRANSFER COEFFICIENT ACROSS MEMBRANE 164 STRIPPING SOLUTIONS FOR OMD 165 MEMBRANES FOR OMD PROCESS 166 PROS AND CONS OF OMD PROCESS 166 FORWARD OSMOSIS 167 BASIC PRINCIPLES OF FO PROCESS 167 CALCULATION OF THE OSMOTIC PRESSURES 167 REVERSE SOLUTE FLUX IN FO 170 MEMBRANES FOR FO PROCESS 170 DRAW SOLUTES FOR FO PROCESS 171 PROS AND CONS OF FO PROCESS 172 PRESSURE-RETARDED OSMOSIS 172 BASIC PRINCIPLES OF PRO PROCESS 172 MEMBRANES FOR PRO PROCESS 175 PROS AND CONS OF PRO PROCESS 176 CONCLUSIONS 176 REFERENCES 176 6 APPLICATIONS OF MEMBRANE CONTACTOR TECHNOLOGY IN WASTEWATER TREATMENT 185 AYESHA REHMAN, XIANHUI LI, SARAH FARRUKH, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 6.1 6.2 6.2.1 6.2.2 6.2.3 6.2.4 6.2.5 INTRODUCTION 185 COMMON TOXIC SUBSTANCES IN WASTEWATER 187 PHENOLS 187 HEAVY METALS 188 AMMONIA 188 HYDROGEN SULFIDE 188 CARBON DIOXIDE 188 XII CONTENTS 6.2.6 PETROLEUM HYDROCARBONS 188 6.2.7 POLYCYCLIC AROMATIC HYDROCARBONS 189 6.2.8 NITROBENZENE 189 6.3 ENVIRONMENTAL RISKS OF WASTEWATER 189 6.4 MEMBRANE TECHNOLOGY FOR WASTEWATER TREATMENT 190 6.5 MEMBRANE CONTACTOR TECHNOLOGY FOR REMOVAL OF ORGANIC CONTAMINANTS FROM WASTEWATER 193 6.6 REMOVAL OF INORGANIC CONTAMINANTS FROM WASTEWATER 200 6.7 POLYMER-BASED ADSORPTION MEMBRANES 202 6.8 ION-EXCHANGE NANOPOROUS MEMBRANE 204 6.9 MICELLAR-ENHANCED ULTRAFILTRATION MEMBRANE 204 6.10 MEMBRANE MATERIALS FOR WATER TREATMENT 205 6.11 MEMBRANE MATERIALS FOR MICROFILTRATION (MF) AND ULTRAFILTRATION (UF) 206 6.12 MEMBRANE MATERIALS FOR NANOFILTRATION (NF) 206 6.13 MEMBRANE MATERIALS FOR REVERSE OSMOSIS (RO) 207 6.14 MEMBRANE MATERIALS FOR FORWARD OSMOSIS (FO) 207 6.15 CHALLENGES IN MEMBRANE MATERIALS TO PREVENT FOULING 208 6.16 CONCLUSIONS AND PERSPECTIVES 209 REFERENCES 210 7 APPLICATIONS OF MEMBRANE CONTACTORS IN FOOD INDUSTRY 219 WAHEED UR REHMAN, BAZLA SARWAR, SIDRA SAQIB, AHMAD MUKHTAR, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 7.1 INTRODUCTION 219 7.2 MEMBRANE DISTILLATION (MD) APPLICATIONS IN FOOD INDUSTRY 219 7.2.1 MD IN THE CONCENTRATION OF APPLE JUICE 221 7.2.2 MD IN THE CONCENTRATION OF ORANGE JUICE 222 7.2.3 MD IN THE CONCENTRATION OF MILK 222 7.2.4 MD IN THE TREATMENT OF SALINE DAIRY WASTE WATER 223 7.2.5 MD IN THE CONCENTRATION OF MUSCADINE GRAPE POMACE 224 7.2.6 MD IN THE RECOVERY OF PHENOLS FROM OLIVE MILL WASTEWATER 225 7.2.7 MD IN THE CONCENTRATION OF SUCROSE SOLUTION 225 7.2.8 EFFECT OF OPERATING PARAMETERS ON MD FLUX 225 7.3 APPLICATION OF OSMOTIC MEMBRANE DISTILLATION (OMD) IN FOOD INDUSTRY 227 7.3.1 EFFECT OF OPERATING CONDITIONS ON OMD WATER FLUX 228 7.3.2 OMD IN THE CONCENTRATION OF APPLE JUICE 231 7.3.3 OMD IN THE CONCENTRATION OF GRAPE JUICE 232 7.3.4 OMD IN THE CONCENTRATION OF POMEGRANATE JUICE 233 7.3.5 OMD IN THE CONCENTRATION OF ORANGE JUICE 235 7.3.6 OMD IN THE CONCENTRATION OF CRANBERRY AND NONI JUICES 235 7.3.7 OMD IN THE CONCENTRATION OF KIWI AND PINEAPPLE JUICES 236 7.3.8 OMD IN THE CONCENTRATION OF TEA EXTRACTS 236 7.3.9 DEALCOHOLIZATION OF BEER AND WINE 237 CONTENTS XIII 7.4 COUPLED OPERATION OF OSMOTIC DISTILLATION AND MEMBRANE DISTILLATION 238 7.5 CONCLUSIONS 239 7.6 FUTURE PERSPECTIVES 239 REFERENCES 240 8 APPLICATIONS OF MEMBRANE CONTACTOR TECHNOLOGY FOR PRE-COMBUSTION CARBON DIOXIDE (CO 2 ) CAPTURE 247 ZARRAR SALAHUDDIN, SARAH FARRUKH, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 8.1 INTRODUCTION 247 8.2 WHY PRE-COMBUSTION CARBON CAPTURE? 250 8.3 MEMBRANES FOR PRE-COMBUSTION CARBON CAPTURE 250 8.3.1 HYDROGEN (H 2 )-SELECTIVE MEMBRANES 250 8.3.2 CO 2 -SELECTIVE MEMBRANES 255 8.4 ADVANTAGES AND LIMITATIONS OF PRE-COMBUSTION CARBON CAPTURE USING MEMBRANE TECHNOLOGY 262 8.5 APPLICATIONS OF PRE-COMBUSTION CARBON CAPTURE 263 8.6 CURRENT TRENDS AND FUTURE PROSPECTS 263 8.7 CONCLUDING AND FUTURE DIRECTIONS 269 REFERENCES 269 9 APPLICATION OF MEMBRANE CONTACTOR TECHNOLOGY FOR POST-COMBUSTION CARBON DIOXIDE (C0 2 ) CAPTURE 281 MUHAMMAD B. WAZIR, MUHAMMAD DAUD, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 9.1 INTRODUCTION 281 9.2 MEMBRANES FOR POST-COMBUSTION CO 2 CAPTURE 282 9.2.1 MEMBRANE TYPES 282 9.2.2 MEMBRANE MODULES 285 9.3 EXPERIMENTAL MEMBRANE MATERIALS FOR POST-COMBUSTION CO 2 SEQUESTRATION 285 9.4 COMMERCIAL MEMBRANES FOR POST-COMBUSTION CO 2 SEPARATION 288 9.5 COST OF POST-COMBUSTION CO 2 CAPTURE IN MEMBRANE CONTACTORS 289 9.6 ABSORBENTS FOR POST-COMBUSTION CO 2 SEPARATION 291 9.6.1 AMINE-BASED ABSORBENTS 291 9.6.2 AMMONIA 293 9.6.3 SALT SOLUTIONS 294 9.6.4 IONIC LIQUIDS 295 9.7 CONCLUSION AND FUTURE PERSPECTIVE 295 REFERENCES 296 10 MARKET PROSPECTS OF MEMBRANE CONTACTORS 305 ZAHRA PEZESHKI, MOHAMMAD YOUNAS, AND MASHALLAH REZAKAZEMI 10.1 MEMBRANE CONTACTOR MARKET DYNAMICS 305 XIV CONTENTS INDEX 342 10.2 10.3 10.3.1 10.3.2 10.3.3 10.3.4 10.4 10.5 10.6 10.6.1 10.6.2 10.6.3 10.6.4 10.6.5 10.6.6 10.6.7 10.6.8 10.6.9 10.6.10 10.6.11 10.6.12 10.6.13 10.6.14 10.7 10.8 MARKET OVERVIEW 306 MEMBRANE CONTACTOR MARKET BY APPLICATION 313 WATER AND WASTEWATER TREATMENT MARKET 313 FOOD PROCESSING MARKET 315 GAS SEPARATION MARKET 318 CARBON CAPTURE MARKET 321 MEMBRANE CONTACTOR MARKET, BY MEMBRANE 321 MEMBRANE CONTACTOR MARKET, BY REGION 325 RECENT DEVELOPMENTS OF MEMBRANE CONTACTOR COMPANIES 328 3M COMPANY 328 COBETTER FILTRATION EQUIPMENT PVT. LTD. 329 EUROWATER 329 JU.CLA.SSRL 329 VEOLIA ENVIRONNEMENT SA 329 PTI PACIFIC PTY. LTD. 330 KVAERNER ASA 330 LENNTECH B.V. 330 PURE WATER GROUP 330 TNO COMPANY 330 EUWA H. H. EUMANN GMBH (EUWA) 330 HYDRO-ELEKTRIK GMBH 331 KH TEC GMBH 331 ROMFIL GMBH 331 FUTURE DIRECTIONS 331 CONCLUSION 332 REFERENCES 332 11 CONCLUSIONS AND PERSPECTIVE 337 MOHAMMAD YOUNAS AND MASHALLAH REZAKAZEMI 11.1 FUTURE DIRECTIONS 340
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genre	(DE-588)4143413-4 Aufsatzsammlung gnd-content
genre_facet	Aufsatzsammlung
id	DE-604.BV047409206
illustrated	Illustrated
index_date	2024-07-03T17:54:59Z
indexdate	2024-07-10T09:11:19Z
institution	BVB
institution_GND	(DE-588)16179388-5
isbn	3527348611 9783527348619
language	English
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-032810127
oclc_num	1294780364
open_access_boolean
owner	DE-29T
owner_facet	DE-29T
physical	xviii, 350 Seiten Illustrationen, Diagramme 24.4 cm x 17 cm
publishDate	2022
publishDateSearch	2022
publishDateSort	2022
publisher	Wiley-VCH
record_format	marc
spelling	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture edited by Mohammad Younas and Mashallah Rezakazemi Weinheim, Germany Wiley-VCH [2022] xviii, 350 Seiten Illustrationen, Diagramme 24.4 cm x 17 cm txt rdacontent n rdamedia nc rdacarrier Lebensmitteltechnologie (DE-588)4034901-9 gnd rswk-swf Membrankontaktor (DE-588)1256724696 gnd rswk-swf Carbon dioxide capture and storage (DE-588)7628985-0 gnd rswk-swf Stoffübertragung (DE-588)4057696-6 gnd rswk-swf Gastrennung (DE-588)4156082-6 gnd rswk-swf Membranverfahren (DE-588)4231727-7 gnd rswk-swf Abwasserreinigung (DE-588)4000313-9 gnd rswk-swf CG10: Prozesssteuerung CH30: Technische u. Industrielle Chemie Chemical Engineering Chemie Chemische Verfahrenstechnik Chemistry FO20: Herstellung u. Verarbeitung von Lebensmitteln Food Processing, Production & Manufacture Food Science & Technology Herstellung u. Verarbeitung von Lebensmitteln Industrial Chemistry Lebensmittelforschung u. -technologie Process Engineering Prozesssteuerung Technische u. Industrielle Chemie (DE-588)4143413-4 Aufsatzsammlung gnd-content Membrankontaktor (DE-588)1256724696 s Membranverfahren (DE-588)4231727-7 s Stoffübertragung (DE-588)4057696-6 s Abwasserreinigung (DE-588)4000313-9 s Lebensmitteltechnologie (DE-588)4034901-9 s Gastrennung (DE-588)4156082-6 s Carbon dioxide capture and storage (DE-588)7628985-0 s DE-604 Younas, Mohammad edt Rezakazemi, Mashallah (DE-588)1238923925 edt Wiley-VCH (DE-588)16179388-5 pbl Erscheint auch als Online-Ausgabe, PDF 978-3-527-83102-9 Erscheint auch als Online-Ausgabe, EPUB 978-3-527-83104-3 Erscheint auch als Online-Ausgabe, oBook 978-3-527-83103-6 X:MVB http://www.wiley-vch.de/publish/dt/books/ISBN978-3-527-34861-9/ DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=032810127&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture Lebensmitteltechnologie (DE-588)4034901-9 gnd Membrankontaktor (DE-588)1256724696 gnd Carbon dioxide capture and storage (DE-588)7628985-0 gnd Stoffübertragung (DE-588)4057696-6 gnd Gastrennung (DE-588)4156082-6 gnd Membranverfahren (DE-588)4231727-7 gnd Abwasserreinigung (DE-588)4000313-9 gnd
subject_GND	(DE-588)4034901-9 (DE-588)1256724696 (DE-588)7628985-0 (DE-588)4057696-6 (DE-588)4156082-6 (DE-588)4231727-7 (DE-588)4000313-9 (DE-588)4143413-4
title	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture
title_auth	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture
title_exact_search	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture
title_exact_search_txtP	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture
title_full	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture edited by Mohammad Younas and Mashallah Rezakazemi
title_fullStr	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture edited by Mohammad Younas and Mashallah Rezakazemi
title_full_unstemmed	Membrane contactor technology water treatment, food processing, gas separation, and carbon capture edited by Mohammad Younas and Mashallah Rezakazemi
title_short	Membrane contactor technology
title_sort	membrane contactor technology water treatment food processing gas separation and carbon capture
title_sub	water treatment, food processing, gas separation, and carbon capture
topic	Lebensmitteltechnologie (DE-588)4034901-9 gnd Membrankontaktor (DE-588)1256724696 gnd Carbon dioxide capture and storage (DE-588)7628985-0 gnd Stoffübertragung (DE-588)4057696-6 gnd Gastrennung (DE-588)4156082-6 gnd Membranverfahren (DE-588)4231727-7 gnd Abwasserreinigung (DE-588)4000313-9 gnd
topic_facet	Lebensmitteltechnologie Membrankontaktor Carbon dioxide capture and storage Stoffübertragung Gastrennung Membranverfahren Abwasserreinigung Aufsatzsammlung
url	http://www.wiley-vch.de/publish/dt/books/ISBN978-3-527-34861-9/ http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=032810127&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
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