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  1. 1
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  7. 7
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  10. 10
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  11. 11
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  12. 12
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  14. 14
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  15. 15
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  16. 16
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  17. 17
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  18. 18
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  19. 19
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  20. 20
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  21. 21
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  22. 22
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  23. 23
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  24. 24
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  25. 25
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  26. 26
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  27. 27
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  28. 28
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  29. 29
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  30. 30
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  31. 31
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  32. 32
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  33. 33
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  34. 34
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  35. 35
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  36. 36
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  37. 37
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  38. You have free access to this content38
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  39. 39
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  40. 40
    H.J. Cheng, S.S. Hsiau, The study of granular agglomeration mechanism, Powder Technology, 2010, 199, 3, 272

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  41. 41
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  42. 42
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  43. 43
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  44. 44
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  45. 45
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  46. 46
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  47. 47
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  48. 48
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  49. 49
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  50. 50
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    CrossRef

  51. 51
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    CrossRef

  52. 52
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    CrossRef

  53. 53
    Gavin M. Walker, Granulation, 2007,

    CrossRef

  54. 54
    Thomas Abberger, Granulation, 2007,

    CrossRef

  55. 55
    K.P. Hapgood, S.M. lveson, J.D. Litster, L.X. Liu, Granulation, 2007,

    CrossRef

  56. 56
    Paul Mort, Granulation, 2007,

    CrossRef

  57. 57
    G.M. Walker, G. Andrews, D. Jones, Effect of process parameters on the melt granulation of pharmaceutical powders, Powder Technology, 2006, 165, 3, 161

    CrossRef

  58. 58
    F.Y. Wang, X.Y. Ge, N. Balliu, I.T. Cameron, Optimal control and operation of drum granulation processes, Chemical Engineering Science, 2006, 61, 1, 257

    CrossRef

  59. 59
    A.M. Nilpawar, G.K. Reynolds, A.D. Salman, M.J. Hounslow, Surface velocity measurement in a high shear mixer, Chemical Engineering Science, 2006, 61, 13, 4172

    CrossRef

  60. 60
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    CrossRef

  61. 61
    Simon M. Iveson, Neil W. Page, Dynamic strength of liquid-bound granular materials: The effect of particle size and shape, Powder Technology, 2005, 152, 1-3, 79

    CrossRef

  62. 62
    Justin A. Gantt, Edward P. Gatzke, High-shear granulation modeling using a discrete element simulation approach, Powder Technology, 2005, 156, 2-3, 195

    CrossRef

  63. 63
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    CrossRef

  64. 64
    Paul R Mort, Scale-up of binder agglomeration processes, Powder Technology, 2005, 150, 2, 86

    CrossRef

  65. 65
    A.M. Bouwman, M.J. Henstra, D. Westerman, J.T. Chung, Z. Zhang, A. Ingram, J.P.K. Seville, H.W. Frijlink, The effect of the amount of binder liquid on the granulation mechanisms and structure of microcrystalline cellulose granules prepared by high shear granulation, International Journal of Pharmaceutics, 2005, 290, 1-2, 129

    CrossRef

  66. 66
    Tadeusz Gluba, The energy of bed processing during drum granulation, Chemical Engineering and Processing: Process Intensification, 2005, 44, 2, 237

    CrossRef

  67. 67
    Simon M. Iveson, Neil W. Page, Brittle to Plastic Transition in the Dynamic Mechanical Behavior of Partially Saturated Granular Materials, Journal of Applied Mechanics, 2004, 71, 4, 470

    CrossRef

  68. 68
    Peter Knight, Challenges in granulation technology, Powder Technology, 2004, 140, 3, 156

    CrossRef

  69. 69
    M Bardin, P.C Knight, J.P.K Seville, On control of particle size distribution in granulation using high-shear mixers, Powder Technology, 2004, 140, 3, 169

    CrossRef

  70. 70
    Anneke M. Bouwman, Marinella R. Visser, Anko C. Eissens, Johannes A. Wesselingh, Henderik W. Frijlink, The effect of vessel material on granules produced in a high-shear mixer, European Journal of Pharmaceutical Sciences, 2004, 23, 2, 169

    CrossRef

  71. 71
    Philippe A. L. Wauters, Brian Scarlett, L. X. Liu, James D. Litster, Gabrie M. H. Meesters, A population balance model for high shear granulation, Chemical Engineering Communications, 2003, 190, 10, 1309

    CrossRef

  72. 72
    G.M. Walker, H.E.M.N. Moursy, C.R. Holland, M.N. Ahmad, Effect of process parameters on the crush strength of granular fertiliser, Powder Technology, 2003, 132, 1, 81

    CrossRef

  73. 73
    Kaspar van den Dries, Onno M. de Vegt, Vincent Girard, Herman Vromans, Granule breakage phenomena in a high shear mixer; influence of process and formulation variables and consequences on granule homogeneity, Powder Technology, 2003, 133, 1-3, 228

    CrossRef

  74. 74
    Karen P. Hapgood, James D. Litster, Rachel Smith, Nucleation regime map for liquid bound granules, AIChE Journal, 2003, 49, 2
  75. 75
    J.D. Litster, Scaleup of wet granulation processes: science not art, Powder Technology, 2003, 130, 1-3, 35

    CrossRef

  76. 76
    S.L Rough, D.I Wilson, A Bayly, D York, Tapping characterisation of high shear mixer agglomerates made with ultra-high viscosity binders, Powder Technology, 2003, 132, 2-3, 249

    CrossRef

  77. 77
    Simon M. Iveson, Neil W. Page, Jim D. Litster, The importance of wet-powder dynamic mechanical properties in understanding granulation, Powder Technology, 2003, 130, 1-3, 97

    CrossRef

  78. 78
    James N. Michaels, Toward rational design of powder processes, Powder Technology, 2003, 138, 1, 1

    CrossRef

  79. 79
    D Oulahna, F Cordier, L Galet, J.A Dodds, Wet granulation: the effect of shear on granule properties, Powder Technology, 2003, 130, 1-3, 238

    CrossRef

  80. 80
    E. Favre, L. Marchal-Heusler, M. Kind, Chemical Product Engineering: Research and Educational Challenges, Chemical Engineering Research and Design, 2002, 80, 1, 65

    CrossRef

  81. 81
    P.A.L Wauters, R van de Water, J.D Litster, G.M.H Meesters, B Scarlett, Growth and compaction behaviour of copper concentrate granules in a rotating drum, Powder Technology, 2002, 124, 3, 230

    CrossRef

  82. 82
    Simon M. Iveson, Limitations of one-dimensional population balance models of wet granulation processes, Powder Technology, 2002, 124, 3, 219

    CrossRef

  83. 83
    Philippe A.L Wauters, Rutger B Jakobsen, James D Litster, Gabrie M.H Meesters, Brian Scarlett, Liquid distribution as a means to describing the granule growth mechanism, Powder Technology, 2002, 123, 2-3, 166

    CrossRef

  84. 84
    Daan Verkoeijen, Gerard A. Pouw, Gabriël M. H. Meesters, Brian Scarlett, Population balances for particulate processes—a volume approach, Chemical Engineering Science, 2002, 57, 12, 2287

    CrossRef

  85. 85
    K van den Dries, H Vromans, Relationship between inhomogeneity phenomena and granule growth mechanisms in a high-shear mixer, International Journal of Pharmaceutics, 2002, 247, 1-2, 167

    CrossRef

  86. 86
    Fu Yang Wang, Ian T. Cameron, Review and future directions in the modelling and control of continuous drum granulation, Powder Technology, 2002, 124, 3, 238

    CrossRef

  87. 87
    Simon M. Iveson, Jai A. Beathe, Neil W. Page, The dynamic strength of partially saturated powder compacts: the effect of liquid properties, Powder Technology, 2002, 127, 2, 149

    CrossRef

  88. 88
    Simon M. Iveson, Philippe A.L. Wauters, Sarah Forrest, James D. Litster, Gabrie M.H. Meesters, Brian Scarlett, Growth regime map for liquid-bound granules: further development and experimental validation, Powder Technology, 2001, 117, 1-2, 83

    CrossRef

  89. 89
    Dafni G Bika, Michael Gentzler, James N Michaels, Mechanical properties of agglomerates, Powder Technology, 2001, 117, 1-2, 98

    CrossRef

  90. 90
    Simon M. Iveson, James D. Litster, Karen Hapgood, Bryan J. Ennis, Nucleation, growth and breakage phenomena in agitated wet granulation processes: a review, Powder Technology, 2001, 117, 1-2, 3

    CrossRef

  91. 91
    A. Faure, P. York, R.C. Rowe, Process control and scale-up of pharmaceutical wet granulation processes: a review, European Journal of Pharmaceutics and Biopharmaceutics, 2001, 52, 3, 269

    CrossRef

  92. 92
    S.M. Iveson, N.W. Page, Tensile bond strength development between liquid-bound pellets during compression, Powder Technology, 2001, 117, 1-2, 113

    CrossRef

  93. 93
    Alexandre Goldszal, Jacques Bousquet, Wet agglomeration of powders: from physics toward process optimization, Powder Technology, 2001, 117, 3, 221

    CrossRef

  94. 94
    L. X. Liu, J. D. Litster, S. M. Iveson, B. J. Ennis, Coalescence of deformable granules in wet granulation processes, AIChE Journal, 2000, 46, 3
  95. 95
    Michael B. Mackaplow, Lawrence A. Rosen, James N. Michaels, Effect of primary particle size on granule growth and endpoint determination in high-shear wet granulation, Powder Technology, 2000, 108, 1, 32

    CrossRef

  96. 96
    S.H Schaafsma, P Vonk, N.W.F Kossen, Fluid bed agglomeration with a narrow droplet size distribution, International Journal of Pharmaceutics, 2000, 193, 2, 175

    CrossRef

  97. 97
    P.J.T. Mills, J.P.K. Seville, P.C. Knight, M.J. Adams, The effect of binder viscosity on particle agglomeration in a low shear mixer/agglomerator, Powder Technology, 2000, 113, 1-2, 140

    CrossRef

  98. 98
    S.M. Iveson, J.D. Litster, Fundamental studies of granule consolidation part 2: Quantifying the effects of particle and binder properties, Powder Technology, 1998, 99, 3, 243

    CrossRef

  99. 99
    S.M. Iveson, J.D. Litster, Liquid-bound granule impact deformation and coefficient of restitution, Powder Technology, 1998, 99, 3, 234

    CrossRef

  100. 100
    Andreas Bück, Evangelos Tsotsas, Karl Sommer, Size Enlargement, Ullmann's Encyclopedia of Industrial Chemistry,
  101. 101
    Karen P. Hapgood, James D. Litster, Wet Granulation Processes,