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Idea circa aerem vitalem nec-non de fluido igneo : quam Deo duce & auspice dei-par^a, in Augustissimo Ludoviceo Medico Monspeliensi, publicis subjiciebat disputationibus, pro trimestri mensis Aprilis anni 1787 /Gaultiere, Philippe de. January 1787 (has links)
Thesis (doctoral)--Paris, 1787. / "Ad primum appollinaris laureum consequendum." Head-pieces. Includes bibliographical references.
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Viscosity of slags / Viskosität von SchlackenBronsch, Arne 06 October 2017 (has links) (PDF)
Slags plays a significant role at high temperature processes. The estimation of the slag viscosity is vital for the safe run of e.g. entrained flow gasifiers. One opportunity of determination is rotational viscometry. This technique is disadvantageous in view of elevated temperatures, applied materials and the necessary time. Additionally, the viscosity can be predicted by the help of viscosity models, where viscosity is a function of slag composition and temperature. Due to changing slag properties within the technical processes, the calculated viscosities can hugely differ from measured ones.
In this work, the viscosities of 42 slags where measured up to 100 Pa s and temperatures up to 1700 °C. Oxidizing and reducing conditions were applied. Additionally, selected slag samples were quenched at defined temperatures to qualitatively and quantitatively determine the formed minerals by X-ray diffraction (XRD). Differential temperature analysis (DTA) was applied to find the onset of crystallization for the complementation of investigations.
The Einstein-Roscoe equation was chosen to improve the classic viscosity models. Reducing atmosphere decreased viscosity and the number of formed minerals was increased. Slags show a shear-thinning behavior above ca. 10 vol.-% of solid mineral matter. Also, Newtonian behavior was observed up to 60 vol.-%. To overcome problems with the kinetic cooling behavior of the slags, a viscosity approximation method was applied afterwards. This can result in optimized viscosity predictions when several preconditions are fulfilled.
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Viscosity of slagsBronsch, Arne 13 July 2017 (has links)
Slags plays a significant role at high temperature processes. The estimation of the slag viscosity is vital for the safe run of e.g. entrained flow gasifiers. One opportunity of determination is rotational viscometry. This technique is disadvantageous in view of elevated temperatures, applied materials and the necessary time. Additionally, the viscosity can be predicted by the help of viscosity models, where viscosity is a function of slag composition and temperature. Due to changing slag properties within the technical processes, the calculated viscosities can hugely differ from measured ones.
In this work, the viscosities of 42 slags where measured up to 100 Pa s and temperatures up to 1700 °C. Oxidizing and reducing conditions were applied. Additionally, selected slag samples were quenched at defined temperatures to qualitatively and quantitatively determine the formed minerals by X-ray diffraction (XRD). Differential temperature analysis (DTA) was applied to find the onset of crystallization for the complementation of investigations.
The Einstein-Roscoe equation was chosen to improve the classic viscosity models. Reducing atmosphere decreased viscosity and the number of formed minerals was increased. Slags show a shear-thinning behavior above ca. 10 vol.-% of solid mineral matter. Also, Newtonian behavior was observed up to 60 vol.-%. To overcome problems with the kinetic cooling behavior of the slags, a viscosity approximation method was applied afterwards. This can result in optimized viscosity predictions when several preconditions are fulfilled.:List of Tables ............................................................................................................ vi
List of Figures ........................................................................................................ viii
Symbols and Abbreviations .................................................................................. xviii
1. Introduction and Aim ....................................................................................... 1
2. General Overview of Slag ............................................................................... 2
2.1 Viscosity ...................................................................................................... 2
2.1.1 Viscosity Introduction ........................................................................... 2
2.1.2 Flow behavior of fluids ......................................................................... 3
2.2 Slag Definition and Phase Diagrams ........................................................... 4
2.3 Solid Slag Structure .................................................................................... 5
2.4 Liquid Slag Structure ................................................................................. 10
2.5 Basicity and B/A-ratio ................................................................................ 11
2.6 Slag Components...................................................................................... 13
2.6.1 Silicon dioxide .................................................................................... 13
2.6.2 Aluminum oxide ................................................................................. 13
2.6.3 Calcium oxide .................................................................................... 15
2.6.4 Iron oxide ........................................................................................... 16
2.6.5 Magnesium Oxide .............................................................................. 18
2.6.6 Potassium Oxide ................................................................................ 19
2.6.7 Sodium Oxide .................................................................................... 20
2.6.8 Titanium Oxide ................................................................................... 21
2.6.9 Phosphorous ...................................................................................... 22
2.6.10 Sulfur .............................................................................................. 22
2.7 Summary of Last Chapters ........................................................................ 23
3. Slag Viscosity Toolbox .................................................................................. 25
3.1 Slag Viscosity Predictor............................................................................. 25
3.2 Slag Viscosity Database............................................................................ 26
3.3 Prediction Quality of Viscosity Models ....................................................... 27
4. Classic Slag Viscosity Modelling ................................................................... 30
4.1 Selected Classic Viscosity Models ............................................................ 31
4.1.1 S2 ....................................................................................................... 32
4.1.2 Watt-Fereday ..................................................................................... 32
4.1.3 Bomkamp ........................................................................................... 32
4.1.4 Shaw .................................................................................................. 32
4.1.5 Lakatos .............................................................................................. 33
4.1.6 Urbain ................................................................................................ 33
4.1.7 Riboud ............................................................................................... 33
4.1.8 Streeter .............................................................................................. 34
4.1.9 Kalmanovitch-Frank ........................................................................... 34
4.1.10 BBHLW .......................................................................................... 34
4.1.11 Duchesne ....................................................................................... 34
4.1.12 ANNliq ............................................................................................ 35
4.2 Need of Improvement in Viscosity Literature ............................................. 35
4.3 Summary of Last Chapters ........................................................................ 36
5. Advanced Slag Viscosity Modelling .............................................................. 37
5.1 Crystallization ............................................................................................ 37
5.1.1 Nucleation .......................................................................................... 38
5.1.2 Crystallization Rate ............................................................................ 39
5.1.3 Crystallization Measurement Methods ............................................... 39
5.2 Slag Properties Changes During Crystallization ........................................ 40
5.2.1 Slag Density ....................................................................................... 40
5.2.2 Solid Volume Fraction ........................................................................ 46
5.2.3 Estimation of Slag Composition During Cooling ................................. 46
5.3 Viscosity Depending on Particles and Shear Rate..................................... 47
5.3.1 Einstein-Roscoe Equation .................................................................. 48
5.3.2 Improved Modelling Approach by Modified Einstein-Roscoe .............. 49
5.4 Summary of Last Chapters ........................................................................ 50
6. Experimental Procedures ............................................................................. 52
6.1 Viscosity Measurements ........................................................................... 52
6.1.1 Estimating Parameter Ranges of Viscosity Measurements ................ 53
6.1.2 Viscosity Measurement Procedure ..................................................... 54
6.2 Thermal Analysis of Slags ......................................................................... 55
6.2.1 Experimental Conditions of DTA ........................................................ 55
6.3 Phase Determination ................................................................................. 55
6.3.1 Quench Experiment Processing ......................................................... 56
6.3.2 Phase Determination on XRD Results ............................................... 56
6.4 Summary of Last Chapters ........................................................................ 57
7. Results and Discussion ................................................................................ 58
7.1 Selected Slag Samples ............................................................................. 58
7.1.1 Slag Sample Composition Before Viscosity Measurements ............... 58
7.1.2 Slag Sample Composition After Viscosity Measurements .................. 59
7.2 General Results of Viscosity Measurements ............................................. 60
7.2.1 Viscosity under Air Atmosphere ......................................................... 63
7.2.2 Viscosity under Reducing Atmospheres ............................................. 65
7.2.3 Viscosity under Constant Partial Oxygen Pressure ............................ 66
7.2.4 Summary of Last Chapter .................................................................. 68
7.3 Mineral Formation ..................................................................................... 69
7.3.1 General Results on Primarily Mineral Formation ................................ 69
7.3.2 Influences on Primarily Mineral Formation ......................................... 70
7.3.3 Mineral Formation over Wide Temperature Ranges ........................... 71
7.3.4 Summary of Last Chapter .................................................................. 77
7.4 Results Obtained by DTA .......................................................................... 78
7.4.1 Comparing Results obtained by DTA and Quenching ........................ 80
7.4.2 Summary of Last Chapter .................................................................. 82
7.5 Shear Rate Influence on Slag Viscosity ..................................................... 82
7.5.1 Shear Rate Influence under Oxidizing Atmospheres .......................... 83
7.5.2 Shear Rate Influence under Reducing Atmospheres .......................... 87
7.5.3 Shear Rate Influence under Constant Atmospheres .......................... 91
7.5.4 Summary of chapter ........................................................................... 92
7.6 Atmospheric Influence on Viscosity ........................................................... 93
7.6.1 Summary of Last Chapter .................................................................. 95
7.7 Cooling Rate Influence on Slag Viscosity .................................................. 95
7.7.1 Summary of Last Chapter .................................................................. 97
8. Advanced Viscosity Modelling Approach ...................................................... 99
8.1 Prediction Quality of Classical Viscosity Models ........................................ 99
8.1.1 Selecting the Best Viscosity Model for Newtonian Flow ..................... 99
8.1.2 Summary of Last Chapter ................................................................ 103
8.2 Predicting Liquidus Temperature ............................................................. 103
8.2.1 Comparing Liquidus Calculations and Quenching Experiments ....... 103
8.2.2 Comparing DTA Results and Liquidus Calculations ......................... 105
8.2.3 Summary of Last Chapter ................................................................ 107
8.3 Predicting Liquid Slag Composition ......................................................... 108
8.3.1 Results of Slag Composition Calculations at Oxidizing Conditions ... 108
8.3.2 Results of Slag Composition Calculations at Reducing Conditions ... 110
8.3.3 Summary of Last Chapter ................................................................ 111
8.4 Modelling Approach ................................................................................ 112
8.4.1 Development of Datasets for Advanced Viscosity Modeling ............. 113
8.4.2 Summary of Last Chapter ................................................................ 116
8.5 Results of Advanced Slag Viscosity Modelling Approach ........................ 116
8.5.1 Summary of Last Chapter ................................................................ 121
9. Summary .................................................................................................... 123
10. Appendix: Information on Classic Viscosity Modelling ................................. 126
10.1 Backgrounds of Applied Viscosity Models............................................ 126
10.2 Viscosity Model of the BCURA (S2) ..................................................... 129
10.3 Watt-Fereday ....................................................................................... 130
10.4 Bomkamp ............................................................................................ 130
10.5 Shaw ................................................................................................... 131
10.6 Lakatos Model ..................................................................................... 132
10.7 Urbain Model ....................................................................................... 133
10.8 Riboud Model ...................................................................................... 134
10.9 Streeter Model ..................................................................................... 136
10.10 Kalmanovitch-Frank Model .................................................................. 137
10.11 BBHLW Model ..................................................................................... 137
10.12 Duchesne Model .................................................................................. 139
10.13 ANNliq Model ...................................................................................... 141
11. Appendix: Settings of Equilibrium Calculations ........................................... 143
12. Appendix: Parameters of Einstein-Roscoe Equation ................................... 153
13. Appendix: Ash and Slag Sample Preparation ............................................. 155
14. Appendix: Experimental Procedures: Viscometer ....................................... 159
14.1 General Viscometer Description .......................................................... 159
14.2 Temperature Calibration ...................................................................... 160
14.3 Viscometer Calibration ......................................................................... 160
14.4 Accuracy and Reproducibility of HT-Viscosity Measurements .............. 161
14.5 Influence of Inductive Heating .............................................................. 163
14.6 Influence of Measurement System Materials ....................................... 164
15. Appendix: Experimental Procedures: Quenching Furnace .......................... 167
16. Appendix: Slag Sample Parameters and Composition ................................ 168
17. Appendix: Slag Viscosity Measurements Results ....................................... 175
18. Appendix: Viscosities at Different Cooling Rates ........................................ 182
19. Appendix: Slag Viscosity Modelling: AALE Calculations ............................. 187
20. Appendix: Advanced Viscosity Modelling: a-factors .................................... 193
21. Appendix: Slag Mineral Phase Investigations and Modelling ...................... 197
22. Appendix: Results of DTA Measurements on Slags .................................... 207
23. Appendix: Advanced Slag Viscosity Modelling Approach ............................ 211
References ........................................................................................................... 228
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