Background
The Institute of Process and Particle Engineering is a world leader in the development of simulation tools for industrial-scale bioprocessing units. For example, our current code can model processes in large-scale bioreactors, up to 200m³.

We are therefore looking for a bachelor
or  master  student  with  engineering
background  (chemical  engineering,
bioprocess  engineering,  physics  or
similar)  interested  in  extending  the
simulation  tool  by  adding  an  adaptive
grid refinement algorithm.

The  simulation  code  currently  uses  a  regular  grid.  For  small  structures,  i.e.  small stirrers, the grid around the structure may be too coarse to resolve fine details, e.g. the fluid jet coming from the stirrer. Hence, the objective of this thesis is to employ a new grid addressing scheme and advanced interpolation methods to be able to define areas with a finer grid efficiently within the simulation code.

The coding is done in C++ in combination with the CUDA library on high-performance graphic cards.

Tasks
      • Find and implement a new grid addressing scheme
      • Research and choose interpolation methods
      • Literature study on test cases to validate the program module
      • Include the validation in the test harness of the code

Requirements
      • Background in chemical or bioprocess engineering, physics or similar
      • Basic biotechnological knowledge
      • Being familiar with thermodynamics, simulation and modeling

What we offer
      • Integration in an internationally leading team
      • Opportunity to be part of a commercialization project
      • Paid master thesis
      • Start of a future career in software creation

Start: Summer/Fall 2019

Contact
Dr. Christian Witz
0316 873 30416
christian.witznoSpam@tugraz.at

Background

The  Institute  of  Process  and  Particle  Engineering  is  a
world leader in the development of  simulation tools for        
industrial-scale  bioprocessing  units.  For  example,  our
current  code  can  model  processes  in  large-scale
bioreactors, up to 200m³.

We are therefore looking for a bachelor or master student
with  engineering  background  (chemical  engineering,
bioprocess engineering, physics or similar) interested in
extending  the  simulation  tool by  adding  highly  efficient
and  fast  models  to  calculate  the  heat  transfer  from
heat jackets, heat exchanger or air bubbles to the fluid
in the reactor by employing dimensionless relations like
the Nusselt number. An algorithm for the convective heat
transport is already included in the code.

The coding is done in C++ in combination with the CUDA library on high-performance graphic cards.

Tasks
      • Implement the respective heat transfer by the heat exchanger, heat jacket or air
        bubbles to the fluid as sources in the convective heat
      • Literature study on test cases to validate the program module
      • Include the validation in the test harness of the code

Requirements
      • Background in chemical or bioprocess engineering, physics or similar
      • Basic biotechnological knowledge
      • Being familiar with thermodynamics, simulation and modeling

What we offer
      • Integration in an internationally leading team
      • Opportunity to be part of a commercialization project
      • Paid master thesis
      • Start of a future career in software creation

Start: Summer/Fall 2019

Contact
Dr. Christian Witz
0316 873 30416
christian.witznoSpam@tugraz.at

Background

The Institute of Process and Particle Engineering is a world leader in the development of simulation tools for industrial-scale bioprocessing units. For example, our current code can model processes in large-scale bioreactors, up to 200m³.

We are therefore looking for design exercise (Konstruktionsübung) student with engineering background (chemical engineering, bioprocess engineering, physics or similar) interested in extending the simulation tool by adding algorithms for the automation of the setup and the post processing of the simulation.

The simulation code currently uses a JSON text file as interface to the user to define the simulation parameters. The task of this exercise is to extend a HTML page with Java Script to create this JSON file. A working example already exists.

The second task is to create Python scripts to control the software Paraview, which is currently used to post process the simulation results (e.g. create videos, images and plots automatically).

Tasks
      • Expand the existing HTML/Java Script page
      • Write the Python scripts necessary to create videos, images, plots with Paraview automatically

Requirements
      • Background in chemical or bioprocess engineering, physics or similar
      • Being familiar with programming, simulation and modeling

What we offer
      • Integration in an internationally leading team
      • Opportunity to be part of a commercialization project
      • Paid design exercise
      • Start of a future career in software creation

Start: Summer/Fall 2019

Contact
Dr. Christian Witz
0316 873 30416
christian.witznoSpam@tugraz.at

Experimental Evaluation of a Particle Fractionator

Current trends in paper and pulp production aim on product diversification covering new markets, i.e. fibre-plastic compounds. Separating fibres and fines (i.e., particles smaller than 200μm) may become a crucial process step in future. Answering to this future need, we developed a novel fractionation device in a collaborative project with industry.

First studies revealed a dependence of the separation performance on key flow parameters, and was investigated by means of high-speed imaging (Figure 1, right panel).

Figure 1: Illustration of the fractionation device. (© Jakob D. Redlinger-Pohn, IPPT, TUG)

Bachelor projects will aim on detail investigations of how the fibre network formation affects separation performance. The bachelor students will receive training in the handling of the fractionator, image recording and post-processing with our existing high-speed camera.

We offer

• high industrial and scientific relevance (i.e., a novel separation process which will be applied in “real-world” trials at a paper mill)
• bleeding edge high-speed camera equipment and image post-processing routines
• desk and office space

Contact

Stefan Radl, radl(at)tugraz.at; 0316 873 30412

The bachelor thesis projects can be started earliest in summer 2018

Current trends in advanced multiphase flow prediction aim at the usage of machine learning algorithms and deep neural networks to improve the accuracy and to speed-up numerical simulations. Overall, it can be expected that these tools (and artificial intelligence, AI, in a wider context) will become an important part of numerical modelling used in chemical engineering applications.

The overarching goal of this Master Thesis project is to increase the speed of gas-particle flow simulations (see the right panel in the Figure below) by using an AI-powered prediction algorithm.

Your tasks will include (i) a literature review on the usage of deep learning in numerical simulations, (ii) an investigation related to key parameters of a neural net structure to speed up a widely-used gas-particle flow simulator, and (iii) application of the improved simulator to a use case. The machine learning and deep neural nets will be based on existing open source AI platforms (e.g., Tensorflow), for which expert knowledge is already available at our institute.

Qualification

• Interest in Computational Fluid Dynamics (CFD), Discrete Element Method (DEM)
• Basics programming skills (Matlab/octave, Python, C/C++ or other), and interest to refine your programming skills during the Master Thesis project

We offer

• Extremely high scientific and industrial relevance
• Introduction to the leading open-source gas-particle simulation tools OpenFOAM® and CFDEM®. Support with the AI platform, as well as with respect to programming.
• Computer power, desk and office space
• Possibility to publish the results and findings in a scientific journal

Contact

Josef Tausendschön: josef.tausendschoennoSpam@tugraz.at, Stefan Radl: radlnoSpam@tugraz.at