Experimental comparison of measurement techniques for drop size distributions in liquid/liquid dispersions S Maaß, S Wollny, A Voigt, M Kraume Experiments in Fluids 50, 259-269, 2011 | 182 | 2011 |
Determination of breakage rates using single drop experiments S Maaß, M Kraume Chemical Engineering Science 70, 146-164, 2012 | 170 | 2012 |
Automated drop detection using image analysis for online particle size monitoring in multiphase systems S Maaß, J Rojahn, R Hänsch, M Kraume Computers & Chemical Engineering 45, 27-37, 2012 | 146 | 2012 |
Experimental investigations and modelling of breakage phenomena in stirred liquid/liquid systems S Maaß, A Gäbler, A Zaccone, AR Paschedag, M Kraume Chemical Engineering Research and Design 85 (5), 703-709, 2007 | 85 | 2007 |
Definition of the single drop breakup event J Solsvik, S Maaß, HA Jakobsen Industrial & Engineering Chemistry Research 55 (10), 2872-2882, 2016 | 80 | 2016 |
Influence of the dispersed phase fraction on experimental and predicted drop size distributions in breakage dominated stirred systems S Maaß, N Paul, M Kraume Chemical engineering science 76, 140-153, 2012 | 77 | 2012 |
Prediction of drop sizes for liquid–liquid systems in stirred slim reactors—Part I: Single stage impellers S Maaß, F Metz, T Rehm, M Kraume Chemical Engineering Journal 162 (2), 792-801, 2010 | 76 | 2010 |
Drop breakage in liquid–liquid stirred dispersions: modelling of single drop breakage A Zaccone, A Gäbler, S Maaß, D Marchisio, M Kraume Chemical Engineering Science 62 (22), 6297-6307, 2007 | 76 | 2007 |
On droplets size distribution in a pulsed column. Part I: In-situ measurements and corresponding CFD–PBE simulations A Amokrane, S Maaß, F Lamadie, F Puel, S Charton Chemical Engineering Journal 296, 366-376, 2016 | 66 | 2016 |
Application of inline imaging for monitoring crystallization process in a continuous oscillatory baffled crystallizer R Kacker, S Maaß, J Emmerich, H Kramer AIChE Journal 64 (7), 2450-2461, 2018 | 47 | 2018 |
Optical inline analysis and monitoring of particle size and shape distributions for multiple applications: Scientific and industrial relevance J Emmerich, Q Tang, Y Wang, P Neubauer, S Junne, S Maaß Chinese Journal of Chemical Engineering 27 (2), 257-277, 2019 | 43 | 2019 |
Photo-optical in-situ measurement of drop size distributions: Applications in research and industry RP Panckow, L Reinecke, MC Cuellar, S Maaß Oil & Gas Science and Technology–Revue d’IFP Energies nouvelles 72 (3), 14, 2017 | 41 | 2017 |
Effective and intrinsic kinetics of liquid-phase isobutane/2-butene alkylation catalyzed by chloroaluminate ionic liquids L Schilder, S Maaß, A Jess Industrial & Engineering Chemistry Research 52 (5), 1877-1885, 2013 | 40 | 2013 |
Prediction of drop sizes for liquid–liquid systems in stirred slim reactors—part II: multi stage impellers S Maaß, T Rehm, M Kraume Chemical engineering journal 168 (2), 827-838, 2011 | 35 | 2011 |
Determination of particle size distributions in multiphase systems containing nonspherical fluid particles RP Panckow, G Comandè, S Maaß, M Kraume Chemical Engineering & Technology 38 (11), 2011-2016, 2015 | 34 | 2015 |
Numerical and experimental analysis of particle strain and breakage in turbulent dispersions S Maaß, S Wollny, R Sperling, M Kraume Chemical Engineering Research and Design 87 (4), 565-572, 2009 | 33 | 2009 |
Particle technology as a uniform discipline? Towards a holistic approach to particles, their creation, characterisation, handling and processing! M Morgeneyer, A Ramírez-Gómez, M Poletto, S Ward-Smith, RJ Tweedie, ... Chemical Engineering Research and Design 146, 162-165, 2019 | 32 | 2019 |
Analysis of particle strain in stirred bioreactors by drop breakage investigations S Maaß, S Buscher, S Hermann, M Kraume Biotechnology Journal 6 (8), 979-992, 2011 | 32 | 2011 |
Experimental analysis, modeling and simulation of drop breakage in agitated turbulent liquid/liquid-dispersions S Maaß | 18 | 2011 |
Measurement techniques for drop size distributions in stirred liquid-liquid systems S Maass, J Grunig, M Kraume Chemical and Process Engineering 30 (4), 635-651, 2009 | 18 | 2009 |