- Page 1:
INAUGURAL-DISSERTATION zur Erlangun
- Page 5:
Dreams can never become a reality w
- Page 8 and 9:
II ial direction). Earlier studies
- Page 10 and 11:
IV DQMOM wird die Tropfengrößen-
- Page 13 and 14:
Contents Abstract . . . . . . . . .
- Page 15 and 16:
List of Tables 4.1 Initial weights
- Page 17 and 18:
List of Figures 1.1 A schematic dia
- Page 19 and 20:
List of Figures XIII 4.27 Effect of
- Page 21 and 22:
1. Introduction Drying has found ap
- Page 23 and 24:
3 Fig. 1.2: Chemical structure of p
- Page 25 and 26:
5 via inhalation aerosols. Dry powd
- Page 27 and 28:
7 equations are written in terms of
- Page 29 and 30:
9 for through appropriate sub-model
- Page 31 and 32:
2. Mathematical Modeling Spray cons
- Page 33 and 34:
2.1. State of the Art 13 the govern
- Page 35 and 36:
2.1. State of the Art 15 and if the
- Page 37 and 38:
2.2. Euler - Lagrangian Approach 17
- Page 39 and 40:
2.2. Euler - Lagrangian Approach 19
- Page 41 and 42:
2.3. Euler - Euler Approach 21 quan
- Page 43 and 44:
2.3. Euler - Euler Approach 23 Will
- Page 45 and 46:
2.3. Euler - Euler Approach 25 of t
- Page 47 and 48:
2.3. Euler - Euler Approach 27 With
- Page 49 and 50:
2.4. Single Droplet Modeling 29 col
- Page 51 and 52:
2.4. Single Droplet Modeling 31 the
- Page 53 and 54:
2.4. Single Droplet Modeling 33 pol
- Page 55 and 56:
2.4. Single Droplet Modeling 35 gra
- Page 57 and 58:
2.4. Single Droplet Modeling 37 thr
- Page 59 and 60:
2.4. Single Droplet Modeling 39 whe
- Page 61 and 62:
2.4. Single Droplet Modeling 41 (a)
- Page 63 and 64:
2.4. Single Droplet Modeling 43 not
- Page 65 and 66:
3. Numerical Methods In the numeric
- Page 67 and 68:
3.2. Spray Modeling 47 and solid la
- Page 69 and 70:
3.2. Spray Modeling 49 ⎛ ⎞ ⎛
- Page 71 and 72: 3.2. Spray Modeling 51 application
- Page 73 and 74: 3.3. Numerical Performance 53 where
- Page 75 and 76: 4. Results and Discussion Results p
- Page 77 and 78: 4.1. One-dimensional Evaporating Wa
- Page 79 and 80: 4.1. One-dimensional Evaporating Wa
- Page 81 and 82: 4.1. One-dimensional Evaporating Wa
- Page 83 and 84: 4.1. One-dimensional Evaporating Wa
- Page 85 and 86: 4.1. One-dimensional Evaporating Wa
- Page 87 and 88: 4.2. Two-dimensional Evaporating Wa
- Page 89 and 90: 4.2. Two-dimensional Evaporating Wa
- Page 91 and 92: 4.2. Two-dimensional Evaporating Wa
- Page 93 and 94: 4.2. Two-dimensional Evaporating Wa
- Page 95 and 96: 4.2. Two-dimensional Evaporating Wa
- Page 97 and 98: 4.3. Single Bi-component Droplet Ev
- Page 99 and 100: 4.3. Single Bi-component Droplet Ev
- Page 101 and 102: 4.3. Single Bi-component Droplet Ev
- Page 103 and 104: 4.3. Single Bi-component Droplet Ev
- Page 105 and 106: 4.3. Single Bi-component Droplet Ev
- Page 107 and 108: 4.3. Single Bi-component Droplet Ev
- Page 109 and 110: 4.3. Single Bi-component Droplet Ev
- Page 111 and 112: 4.3. Single Bi-component Droplet Ev
- Page 113 and 114: 4.4. Two-dimensional Evaporating PV
- Page 115 and 116: 4.4. Two-dimensional Evaporating PV
- Page 117 and 118: 4.4. Two-dimensional Evaporating PV
- Page 119 and 120: 5. Conclusions and Future Work The
- Page 121: 101 proved UNIFAC-vdW-FV method for
- Page 126 and 127: 106 A. Nomenclature Symbol Unit Des
- Page 128 and 129: 108 A. Nomenclature S n S g S l Vec
- Page 130 and 131: 110 A. Nomenclature List of Abbrevi
- Page 132 and 133: Bibliography [1] K. Masters: Spray
- Page 134 and 135: BIBLIOGRAPHY iii [24] K. D. Squires
- Page 136 and 137: BIBLIOGRAPHY v [49] D. L. Marchisio
- Page 138 and 139: BIBLIOGRAPHY vii [72] G. M. Faeth:
- Page 140 and 141: BIBLIOGRAPHY ix [95] C. Cercignani,
- Page 142 and 143: BIBLIOGRAPHY xi [119] R. O. Fox: Hi
- Page 144 and 145: BIBLIOGRAPHY xiii [142] R. Clift, J
- Page 146 and 147: BIBLIOGRAPHY xv [170] G. Brenn, L.
- Page 148 and 149: BIBLIOGRAPHY xvii [197] M. Stieß:
- Page 150: BIBLIOGRAPHY xix [222] I. S. Grigor