Verfügbarkeit: A novel method for predicting product properties in fluidized bed spray granulation

A novel method for predicting product properties in fluidized bed spray granulation:

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Bibliographische Detailangaben
1. Verfasser:	Kieckhefen, Paul 1992- (VerfasserIn)
Format:	Abschlussarbeit Buch
Sprache:	English
Veröffentlicht:	Göttingen Cuvillier Verlag 2021
Ausgabe:	1. Auflage
Schriftenreihe:	SPE-Schriftenreihe 19
Schlagworte:	Wirbelschicht Teilchengröße Numerische Strömungssimulation Diskrete-Elemente-Methode Granulieren Wärmeübergangsmodellierung Solution granulation CFD-DEM method Hochschulschrift
Online-Zugang:	Inhaltsverzeichnis Inhaltsverzeichnis
Beschreibung:	xvi, 185 Seiten Diagramme 24 cm
ISBN:	9783736975569 3736975562

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Datensatz im Suchindex

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adam_text	CONTENTS 1. INTRODUCTION 1 1.1. AIM OF THIS WORK ....................................................................................... 3 1.2. STRUCTURE OF THIS WORK ................................................................................. 4 2. NUMERICAL SIMULATION OF PARTICULATE FLOWS USING CFD-DEM 5 2.1. GOVERNING EQUATIONS OF THE DISCRETE ELEMENT METHOD ............................. 5 2.2. GOVERNING EQUATIONS IN COMPUTATIONAL FLUID DYNAMICS ....................... 8 2.2.1. TURBULENCE MODELING ..................................................................... 10 2.3. EULERIAN-LAGRANGIAN PHASE COUPLING ....................................................... 10 2.3.1. A NOVEL, SIMPLE COUPLING ALGORITHM FOR MASSIVELY PARALLEL SIMULATIONS .................................................................................... 11 2.3.2. EULER-LAGRANGE MAPPING ............................................................... 14 2.3.3. MOMENTUM COUPLING FOR DENSE PARTICULATE FLOWS ....................... 15 2.4. COARSE-GRAINING TECHNIQUES FOR DENSE PARTICULATE FLOWS ....................... 18 2.4.1. PARTICLE COARSENING ........................................................................ 18 2.4.2. FLUID COARSENING ........................................................................... 18 3. DEVELOPMENT OF A SEGREGATED CALIBRATION APPROACH FOR HANDLING WETTED MATERIALS IN THE DISCRETE ELEMENT METHOD 21 3.1. MICROMECHANICS OF WETTED GRANULAR MATTER ........................................... 21 3.1.1. CAPILLARY FORCE ................................................................................. 22 3.1.2. VISCOUS FORCE ................................................................................. 26 3.1.3. LIQUID BRIDGE RUPTURE AND LIQUID DISTRIBUTION ............................. 27 3.1.4. LIQUID BRIDGE VOLUME ..................................................................... 28 3.1.5. PARTICLE SOFTENING CORRECTION AND COARSE GRAINING APPROACHES . . 33 3.2. LIQUID BRIDGE MODEL COMPOSITION AND IMPLEMENTATION .......................... 34 3.3. EXPERIMENTAL CHARACTERIZATION .................................................................. 37 3.3.1. BASIC MATERIAL PROPERTIES ............................................................... 37 3.3.2. SHEAR TESTING ................................................................................... 38 3.3.3. STATIC ANGLE OF REPOSE ..................................................................... 39 3.3.4. DYNAMIC ANGLE OF REPOSE ............................................................... 40 3.4. SENSITIVITY ANALYSIS OF THE NUMERICAL MODEL ........................................... 42 3.4.1. RESTITUTION ANALYSIS ........................................................................ 42 3.4.2. SENSITIVITY OF THE STATIC ANGLE OF REPOSE ........................................ 44 IX 3.4.3. SENSITIVITY OF THE SHEAR TEST ............................................................. 48 3.4.4. SENSITIVITY OF THE DYNAMIC ANGLE OF REPOSE ................................... 50 3.5. CALIBRATION WORKFLOW FOR LIQUID BRIDGE MODELLING IN THE DISCRETE ELEMENT METHOD ................................................................................. 54 4. CALIBRATION OF A DISCRETE ELEMENT METHOD CONTACT LAW FOR DESCRIBING A WETTED GRANULAR SYSTEM 59 4.1. EXPERIMENTAL CHARACTERIZATION .................................................................. 59 4.1.1. BASIC PHYSICAL PROPERTIES ................................................................ 59 4.1.2. STATIC ANGLE OF REPOSE ..................................................................... 60 4.1.3. SHEAR TESTING .................................................................................... 60 4.1.4. DYNAMIC ANGLE OF REPOSE ................................................................ 63 4.2. DETERMINATION OF MODEL MATERIAL PARAMETERS ........................................... 66 4.3. CALIBRATION OF FRICTIONAL CONTACT MODEL COEFFICIENTS ................................ 67 4.4. CALIBRATION OF LIQUID BRIDGE MODEL COEFFICIENTS ...................................... 71 4.5. SUMMARY ..................................................................................................... 73 5. IMPLEMENTATION AND VALIDATION OF A FULL-PHYSICS CFD-DEM SOLVER FOR THE SIMULATION OF FLUIDIZED BED SPRAY GRANULATION 75 5.1. GOVERNING EQUATIONS FOR HEAT AND MASS TRANSFER MODELING .................... 76 5.1.1. GOVERNING EQUATIONS FOR THE DROPLET PHASE AND THE PARTICLE PHASE 76 5.2. CLOSURES FOR HEAT AND MASS TRANSFER .......................................................... 78 5.2.1. HEAT TRANSFER ................................................................................. 78 5.2.2. MASS TRANSFER ................................................................................. 79 5.3. SURFACE COVERAGE MODELING ........................................................................ 80 5.3.1. ANALYTICAL SURFACE COVERAGE MODELS .............................................. 81 5.3.2. SURFACE COVERAGE MODELING USING A DISCRETIZED SURFACE AREA ... 82 5.3.3. COMPARISON OF SURFACE COVERAGE MODELS ...................................... 82 5.4. DROPLET DEPOSITION MODELING ..................................................................... 84 5.5. GOVERNING EQUATIONS IN THE EULERIAN FRAME OF REFERENCE ....................... 87 5.5.1. VAPOR TRANSPORT .............................................................................. 87 5.5.2. EVAPORATION MODELING ..................................................................... 88 5.5.3. HEAT TRANSFER AND TRANSPORT .......................................................... 88 5.6. SOLVER VALIDATION AGAINST DRYING EXPERIMENTS ......................................... 90 5.6.1. CASE ANALYSIS ................................................................................. 92 5.6.2. VALIDATION AGAINST STEADY-STATE EXPERIMENTS ................................ 93 5.6.3. VALIDATION OF MEAN TEMPERATURE RESPONSE AGAINST TRANSIENT EXPERIMENTS .................................................................................... 96 5.7. SUMMARY ..................................................................................................... 97 X 6. DEVELOPMENT OF A NOVEL APPROACH FOR PREDICTION OF PARTICLE PROPERTIES IN FLUIDIZED BED SPRAY GRANULATION 99 6.1. THEORETICAL CONSIDERATIONS ........................................................................ 99 6.1.1. MACROSCOPIC EXPERIMENTAL STUDIES ................................................. 99 6.1.2. MICRO-SCALE PROCESSES IN LAYERING GRANULATION ................................ 101 6.2. PROPOSED APPROACH ....................................................................................... 103 6.2.1. REQUIREMENTS .................................................................................... 103 6.2.2. TRACKED QUANTITIES ........................................................................... 104 6.2.3. EVALUATION OF THE SIMULATIONS .......................................................... 105 6.2.4. WORKFLOW ............................................................................................ 105 6.2.5. LIMITATIONS AND ASSUMPTIONS .......................................................... 107 6.3. DERIVATION OF A MAPPING BETWEEN TRACKED QUANTITIES AND PRODUCT PROPERTIESL07 6.3.1. FITTING OF A LINEAR REGRESSION MODEL ................................................. 107 6.4. DEMONSTRATION CASE ACCORDING TO HOFFMANN (2016) ................................... 110 6.4.1. CASE SETUP .......................................................................................... ILL 6.4.2. DRYING BEHAVIOR AND TRACKED QUANTITIES ......................................... 112 6.5. SUMMARY ........................................................................................................ 113 7. MICRO-SCALE PRODUCT-PROPERTY PREDICTORS IN FLUIDIZED BED SPRAY GRANULATION OF A SUSPENSION 117 7.1. EXPERIMENTAL PROCEDURE .............................................................................. 117 7.2. SIMULATION SETUP .......................................................................................... 118 7.3. RELATIONSHIP BETWEEN SHELL POROSITY AND PROCESS CONDITIONS .................... 120 7.4. CORRELATING SHELL POROSITY AND TRACKED QUANTITIES ...................................... 124 7.5. SUMMARY ........................................................................................................ 124 8. MICRO-SCALE PRODUCT-PROPERTY PREDICTORS IN FLUIDIZED BED SPRAY GRANULATION OF A LIQUID SOLUTION 127 8.1. EXPERIMENTAL PROCEDURE .............................................................................. 127 8.2. PRODUCT ROUGHNESS QUANTIFICATION USING LASER-SCANNING CONFOCAL MICROSCOPY ..................................................................................................... 130 8.2.1. POST-PROCESSING OF ROUGHNESS MEASUREMENTS ................................... 130 8.2.2. ROUGHNESS QUANTIFICATION ................................................................ 132 8.3. SIMULATION SETUP ......................................................................................... 137 8.4. RELATIONSHIP BETWEEN GLOBAL PROCESS CONDITIONS AND TRACKED QUANTITIES 141 8.5. PRINCIPAL COMPONENT ANALYSIS OF INFLUENCE OF GLOBAL PROCESS CONDITIONS AND TRACKED QUANTITIES ON PRODUCT PROPERTIES ........................................... 142 8.6. DERIVATION OF A MAPPING BETWEEN GLOBAL PROCESS CONDITIONS AND PARTICLE PROPERTIES ..................................................................................................... 145 8.7. DERIVATION OF A MAPPING BETWEEN TRACKED QUANTITIES AND PARTICLE PROPERTIES 147 8.8. SUMMARY ........................................................................................................ 149 XI 9. APPLICATION OF THE PRODUCT PROPERTY PREDICTION-APPROACH TO SCALE-UP 151 9.1. EXPERIMENTAL DESIGN AND SIMULATION SETUP ................................................. 151 9.2. ANALYSIS OF HYDRODYNAMICS, THERMODYNAMICS AND TRACKED QUANTITIES IN SCALE-UP ........................................................................................................ 154 9.3. SUMMARY ........................................................................................................ 161 10. CONCLUSION 163 BIBLIOGRAPHY 167 A. CFD-DEM MODELLING: VERIFICATION 175 A.L. TEST CASE SETUP ............................................................................................. 175 A. 1.1. MASS TRANSPORT AND CONSERVATION .................................................... 175 A.L. 2. ENERGY CONSERVATION ........................................................................ 177 B. SOLUTION GRANULATION CASE: SUPPLEMENTARY DATA 181 C. CALCULATION OF THERMOPHYSICAL PROPERTIES IN OPENFOAM 185 C.L. CALCULATION OF THE DENSITY ........................................................................... 185 C.2. CALCULATION OF THE HEAT CAPACITY ................................................................... 185 C.3. CALCULATION OF THE VISCOSITY ........................................................................... 186 CURRICULUM VITAE 187 XII
adam_txt	CONTENTS 1. INTRODUCTION 1 1.1. AIM OF THIS WORK . 3 1.2. STRUCTURE OF THIS WORK . 4 2. NUMERICAL SIMULATION OF PARTICULATE FLOWS USING CFD-DEM 5 2.1. GOVERNING EQUATIONS OF THE DISCRETE ELEMENT METHOD . 5 2.2. GOVERNING EQUATIONS IN COMPUTATIONAL FLUID DYNAMICS . 8 2.2.1. TURBULENCE MODELING . 10 2.3. EULERIAN-LAGRANGIAN PHASE COUPLING . 10 2.3.1. A NOVEL, SIMPLE COUPLING ALGORITHM FOR MASSIVELY PARALLEL SIMULATIONS . 11 2.3.2. EULER-LAGRANGE MAPPING . 14 2.3.3. MOMENTUM COUPLING FOR DENSE PARTICULATE FLOWS . 15 2.4. COARSE-GRAINING TECHNIQUES FOR DENSE PARTICULATE FLOWS . 18 2.4.1. PARTICLE COARSENING . 18 2.4.2. FLUID COARSENING . 18 3. DEVELOPMENT OF A SEGREGATED CALIBRATION APPROACH FOR HANDLING WETTED MATERIALS IN THE DISCRETE ELEMENT METHOD 21 3.1. MICROMECHANICS OF WETTED GRANULAR MATTER . 21 3.1.1. CAPILLARY FORCE . 22 3.1.2. VISCOUS FORCE . 26 3.1.3. LIQUID BRIDGE RUPTURE AND LIQUID DISTRIBUTION . 27 3.1.4. LIQUID BRIDGE VOLUME . 28 3.1.5. PARTICLE SOFTENING CORRECTION AND COARSE GRAINING APPROACHES . . 33 3.2. LIQUID BRIDGE MODEL COMPOSITION AND IMPLEMENTATION . 34 3.3. EXPERIMENTAL CHARACTERIZATION . 37 3.3.1. BASIC MATERIAL PROPERTIES . 37 3.3.2. SHEAR TESTING . 38 3.3.3. STATIC ANGLE OF REPOSE . 39 3.3.4. DYNAMIC ANGLE OF REPOSE . 40 3.4. SENSITIVITY ANALYSIS OF THE NUMERICAL MODEL . 42 3.4.1. RESTITUTION ANALYSIS . 42 3.4.2. SENSITIVITY OF THE STATIC ANGLE OF REPOSE . 44 IX 3.4.3. SENSITIVITY OF THE SHEAR TEST . 48 3.4.4. SENSITIVITY OF THE DYNAMIC ANGLE OF REPOSE . 50 3.5. CALIBRATION WORKFLOW FOR LIQUID BRIDGE MODELLING IN THE DISCRETE ELEMENT METHOD . 54 4. CALIBRATION OF A DISCRETE ELEMENT METHOD CONTACT LAW FOR DESCRIBING A WETTED GRANULAR SYSTEM 59 4.1. EXPERIMENTAL CHARACTERIZATION . 59 4.1.1. BASIC PHYSICAL PROPERTIES . 59 4.1.2. STATIC ANGLE OF REPOSE . 60 4.1.3. SHEAR TESTING . 60 4.1.4. DYNAMIC ANGLE OF REPOSE . 63 4.2. DETERMINATION OF MODEL MATERIAL PARAMETERS . 66 4.3. CALIBRATION OF FRICTIONAL CONTACT MODEL COEFFICIENTS . 67 4.4. CALIBRATION OF LIQUID BRIDGE MODEL COEFFICIENTS . 71 4.5. SUMMARY . 73 5. IMPLEMENTATION AND VALIDATION OF A FULL-PHYSICS CFD-DEM SOLVER FOR THE SIMULATION OF FLUIDIZED BED SPRAY GRANULATION 75 5.1. GOVERNING EQUATIONS FOR HEAT AND MASS TRANSFER MODELING . 76 5.1.1. GOVERNING EQUATIONS FOR THE DROPLET PHASE AND THE PARTICLE PHASE 76 5.2. CLOSURES FOR HEAT AND MASS TRANSFER . 78 5.2.1. HEAT TRANSFER . 78 5.2.2. MASS TRANSFER . 79 5.3. SURFACE COVERAGE MODELING . 80 5.3.1. ANALYTICAL SURFACE COVERAGE MODELS . 81 5.3.2. SURFACE COVERAGE MODELING USING A DISCRETIZED SURFACE AREA . 82 5.3.3. COMPARISON OF SURFACE COVERAGE MODELS . 82 5.4. DROPLET DEPOSITION MODELING . 84 5.5. GOVERNING EQUATIONS IN THE EULERIAN FRAME OF REFERENCE . 87 5.5.1. VAPOR TRANSPORT . 87 5.5.2. EVAPORATION MODELING . 88 5.5.3. HEAT TRANSFER AND TRANSPORT . 88 5.6. SOLVER VALIDATION AGAINST DRYING EXPERIMENTS . 90 5.6.1. CASE ANALYSIS . 92 5.6.2. VALIDATION AGAINST STEADY-STATE EXPERIMENTS . 93 5.6.3. VALIDATION OF MEAN TEMPERATURE RESPONSE AGAINST TRANSIENT EXPERIMENTS . 96 5.7. SUMMARY . 97 X 6. DEVELOPMENT OF A NOVEL APPROACH FOR PREDICTION OF PARTICLE PROPERTIES IN FLUIDIZED BED SPRAY GRANULATION 99 6.1. THEORETICAL CONSIDERATIONS . 99 6.1.1. MACROSCOPIC EXPERIMENTAL STUDIES . 99 6.1.2. MICRO-SCALE PROCESSES IN LAYERING GRANULATION . 101 6.2. PROPOSED APPROACH . 103 6.2.1. REQUIREMENTS . 103 6.2.2. TRACKED QUANTITIES . 104 6.2.3. EVALUATION OF THE SIMULATIONS . 105 6.2.4. WORKFLOW . 105 6.2.5. LIMITATIONS AND ASSUMPTIONS . 107 6.3. DERIVATION OF A MAPPING BETWEEN TRACKED QUANTITIES AND PRODUCT PROPERTIESL07 6.3.1. FITTING OF A LINEAR REGRESSION MODEL . 107 6.4. DEMONSTRATION CASE ACCORDING TO HOFFMANN (2016) . 110 6.4.1. CASE SETUP . ILL 6.4.2. DRYING BEHAVIOR AND TRACKED QUANTITIES . 112 6.5. SUMMARY . 113 7. MICRO-SCALE PRODUCT-PROPERTY PREDICTORS IN FLUIDIZED BED SPRAY GRANULATION OF A SUSPENSION 117 7.1. EXPERIMENTAL PROCEDURE . 117 7.2. SIMULATION SETUP . 118 7.3. RELATIONSHIP BETWEEN SHELL POROSITY AND PROCESS CONDITIONS . 120 7.4. CORRELATING SHELL POROSITY AND TRACKED QUANTITIES . 124 7.5. SUMMARY . 124 8. MICRO-SCALE PRODUCT-PROPERTY PREDICTORS IN FLUIDIZED BED SPRAY GRANULATION OF A LIQUID SOLUTION 127 8.1. EXPERIMENTAL PROCEDURE . 127 8.2. PRODUCT ROUGHNESS QUANTIFICATION USING LASER-SCANNING CONFOCAL MICROSCOPY . 130 8.2.1. POST-PROCESSING OF ROUGHNESS MEASUREMENTS . 130 8.2.2. ROUGHNESS QUANTIFICATION . 132 8.3. SIMULATION SETUP . 137 8.4. RELATIONSHIP BETWEEN GLOBAL PROCESS CONDITIONS AND TRACKED QUANTITIES 141 8.5. PRINCIPAL COMPONENT ANALYSIS OF INFLUENCE OF GLOBAL PROCESS CONDITIONS AND TRACKED QUANTITIES ON PRODUCT PROPERTIES . 142 8.6. DERIVATION OF A MAPPING BETWEEN GLOBAL PROCESS CONDITIONS AND PARTICLE PROPERTIES . 145 8.7. DERIVATION OF A MAPPING BETWEEN TRACKED QUANTITIES AND PARTICLE PROPERTIES 147 8.8. SUMMARY . 149 XI 9. APPLICATION OF THE PRODUCT PROPERTY PREDICTION-APPROACH TO SCALE-UP 151 9.1. EXPERIMENTAL DESIGN AND SIMULATION SETUP . 151 9.2. ANALYSIS OF HYDRODYNAMICS, THERMODYNAMICS AND TRACKED QUANTITIES IN SCALE-UP . 154 9.3. SUMMARY . 161 10. CONCLUSION 163 BIBLIOGRAPHY 167 A. CFD-DEM MODELLING: VERIFICATION 175 A.L. TEST CASE SETUP . 175 A. 1.1. MASS TRANSPORT AND CONSERVATION . 175 A.L. 2. ENERGY CONSERVATION . 177 B. SOLUTION GRANULATION CASE: SUPPLEMENTARY DATA 181 C. CALCULATION OF THERMOPHYSICAL PROPERTIES IN OPENFOAM 185 C.L. CALCULATION OF THE DENSITY . 185 C.2. CALCULATION OF THE HEAT CAPACITY . 185 C.3. CALCULATION OF THE VISCOSITY . 186 CURRICULUM VITAE 187 XII
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author	Kieckhefen, Paul 1992-
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genre	(DE-588)4113937-9 Hochschulschrift gnd-content
genre_facet	Hochschulschrift
id	DE-604.BV047895521
illustrated	Not Illustrated
index_date	2024-07-03T19:27:24Z
indexdate	2024-07-10T09:24:29Z
institution	BVB
institution_GND	(DE-588)1067137041
isbn	9783736975569 3736975562
language	English
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-033277533
oclc_num	1313913124
open_access_boolean
owner	DE-83
owner_facet	DE-83
physical	xvi, 185 Seiten Diagramme 24 cm
publishDate	2021
publishDateSearch	2021
publishDateSort	2021
publisher	Cuvillier Verlag
record_format	marc
series	SPE-Schriftenreihe
series2	SPE-Schriftenreihe
spelling	Kieckhefen, Paul 1992- Verfasser (DE-588)1218475668 aut A novel method for predicting product properties in fluidized bed spray granulation von Paul Kieckhefen 1. Auflage Göttingen Cuvillier Verlag 2021 xvi, 185 Seiten Diagramme 24 cm txt rdacontent n rdamedia nc rdacarrier SPE-Schriftenreihe 19 Dissertation Technische Universität Hamburg 2021 Wirbelschicht (DE-588)4066372-3 gnd rswk-swf Teilchengröße (DE-588)4509483-4 gnd rswk-swf Numerische Strömungssimulation (DE-588)4690080-9 gnd rswk-swf Diskrete-Elemente-Methode (DE-588)4577038-4 gnd rswk-swf Granulieren (DE-588)4158043-6 gnd rswk-swf Wärmeübergangsmodellierung Solution granulation CFD-DEM method (DE-588)4113937-9 Hochschulschrift gnd-content Teilchengröße (DE-588)4509483-4 s Wirbelschicht (DE-588)4066372-3 s Granulieren (DE-588)4158043-6 s Numerische Strömungssimulation (DE-588)4690080-9 s Diskrete-Elemente-Methode (DE-588)4577038-4 s DE-604 Eric Cuvillier (Firma) (DE-588)1067137041 pbl SPE-Schriftenreihe 19 (DE-604)BV042137745 19 B:DE-101 application/pdf https://d-nb.info/1248886178/04 Inhaltsverzeichnis DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=033277533&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p vlb 20220106 DE-101 https://d-nb.info/provenance/plan#vlb
spellingShingle	Kieckhefen, Paul 1992- A novel method for predicting product properties in fluidized bed spray granulation SPE-Schriftenreihe Wirbelschicht (DE-588)4066372-3 gnd Teilchengröße (DE-588)4509483-4 gnd Numerische Strömungssimulation (DE-588)4690080-9 gnd Diskrete-Elemente-Methode (DE-588)4577038-4 gnd Granulieren (DE-588)4158043-6 gnd
subject_GND	(DE-588)4066372-3 (DE-588)4509483-4 (DE-588)4690080-9 (DE-588)4577038-4 (DE-588)4158043-6 (DE-588)4113937-9
title	A novel method for predicting product properties in fluidized bed spray granulation
title_auth	A novel method for predicting product properties in fluidized bed spray granulation
title_exact_search	A novel method for predicting product properties in fluidized bed spray granulation
title_exact_search_txtP	A novel method for predicting product properties in fluidized bed spray granulation
title_full	A novel method for predicting product properties in fluidized bed spray granulation von Paul Kieckhefen
title_fullStr	A novel method for predicting product properties in fluidized bed spray granulation von Paul Kieckhefen
title_full_unstemmed	A novel method for predicting product properties in fluidized bed spray granulation von Paul Kieckhefen
title_short	A novel method for predicting product properties in fluidized bed spray granulation
title_sort	a novel method for predicting product properties in fluidized bed spray granulation
topic	Wirbelschicht (DE-588)4066372-3 gnd Teilchengröße (DE-588)4509483-4 gnd Numerische Strömungssimulation (DE-588)4690080-9 gnd Diskrete-Elemente-Methode (DE-588)4577038-4 gnd Granulieren (DE-588)4158043-6 gnd
topic_facet	Wirbelschicht Teilchengröße Numerische Strömungssimulation Diskrete-Elemente-Methode Granulieren Hochschulschrift
url	https://d-nb.info/1248886178/04 http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=033277533&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
volume_link	(DE-604)BV042137745
work_keys_str_mv	AT kieckhefenpaul anovelmethodforpredictingproductpropertiesinfluidizedbedspraygranulation AT ericcuvillierfirma anovelmethodforpredictingproductpropertiesinfluidizedbedspraygranulation

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