Dr.-Ing. Thomas Wucherpfennig

Boehringer Ingelheim Pharma GmbH & Co. KG
Bioprocess Development Biologicals

Binger Strasse 173

55216 Ingelheim am Rhein

Phone +49 7351 54-144806

Mail Dr. Thomas Wucherpfennig


Thomas pursued the study of Biotechnology at the Technical University of Braunschweig, Germany, and Chemical Engineering at the University of Waterloo, Canada. He earned his PhD in Bioprocess Engineering from the Technical University of Braunschweig. Prior to joining Boehringer Ingelheim as a postdoctoral fellow in 2014, Thomas acquired valuable experience in the industrial biotech sector at Roche and Clariant. Since 2015, he has held various roles in cell culture process development at Boehringer Ingelheim and currently serves as a Senior Principal Scientist, spearheading late-stage process development. In addition, Thomas is a lecturer at FH Oberösterreich in Wels and TUHH – Hamburg University of Technology, His research focus is on bioprocess scale-up, bioreactor characterization, Process Analytical Technology (PAT), and cell culture process modeling.

Research Interests

  • Scale-up of bioprocesses
  • Bioreactor characterization
  • Computational Fluid Dynamics (CFD)
  • Process Analytical Technology (PAT)
  • Cell culture process modelling

Publications

[185011]
Title: Hydrodynamic inhomogeneities in large scale stirred tanks – Influence on mixing time.
Written by: A. Rosseburg, J. Fitschen, J. Wutz, T. Wucherpfennig, M. Schlüter
in: <em>Chemical Engineering Science</em>. (2018).
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on pages: 208-220
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DOI: https://doi.org/10.1016/j.ces.2018.05.008
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Abstract: Aerated stirred tank reactors are widely used in chemical industry and bioprocess engineering. One major parameter to characterize the heat- and mass transfer performance of such aerated stirred tank reactors is the mixing time necessary to homogenize the reactor volume. Despite its importance, the prediction of the mixing time is still challenging due to the complex hydrodynamic inhomogeneities induced by the gaseous phase, which becomes strongly apparent in large scale systems. A precise measurement of the two phase flow on the other hand requires a volumetric insight and is thus difficult to realize. To overcome this problem a transparent stirred tank reactor on industrial scale has been erected at the Hamburg University of Technology in cooperation with Boehringer Ingelheim Pharma GmbH & Co.KG. With the decolouration method the temporal and spatial development of mixing can be taken into account. The results indicate the importance of the local inhomogeneities on large scale. A first characterization can be done by taking into account buoyancy driven flows superimposing the flow imposed by the impeller. A correlation is presented to estimate the transition between a loading and flooding regime on large scale. This correlation enables the calculation of mixing times for a wide range of stirrer frequencies and superficial gas velocities. Furthermore, this publication emphasizes the challenges of scale-up on the basis of laboratory experiments in small scale.