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software tools for infrastructure simulation. To extend the tools usability, we are seeking a working student who as knowledge in fluid dynamics, has interest in open-source and is skilled in Python
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computational fluid dynamics and its application in electrochemical devices; familiarity with OpenFOAM is advantageous First experience in interdisciplinary projects with an open-minded and flexible work ethic A
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physically compatible computational fluid dynamics (CFD) model of the heat exchanger. The CFD model may utilize different layers of fidelity and complexity from which a reduced-order representation of
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simulators (on various abstraction levels using, e.g., Computational Fluid Dynamics) which enables us to verify designs of microfluidic devices even before the first prototype is fabricated. Fabrication: We
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that eventually will automate crucial design steps. In addition, we are developing simulators (on various abstraction levels; using, e.g., Computational Fluid Dynamics) which enables us to validate designs
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context. The project is carried out in cooperation with the TUM Chair of Flight System Dynamics. The work is based on existing research results such as a GPU-based Lattice-Boltzmann solver and a modular
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investigate methods that eventually will automate crucial design steps. In addition, we are developing simulators (on various abstraction levels; using, e.g., Computational Fluid Dynamics) which enables us to