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DY: Fachverband Dynamik und Statistische Physik

DY 5: Poster Session III: Statistical Physics, Complex Fluids and Soft Matter

DY 5.15: Poster

Dienstag, 28. September 2021, 17:30–19:30, P

Topological optimization of microfluidic Tesla valves for applications with low Reynold numbers — •Sebastian Bohm¹, Hai Binh Phi², Ayaka Moriyama³, and Erich Runge¹ — ¹TU Ilmenau, FG Theoretische Physik I, DE — ²TU Ilmenau, FG Mikrosystemtechnik, DE — ³Carleton College, Physics Department, USA

Passive Tesla valves represent a promising method for rectifying flows in microfluidic systems because no moving parts are needed. The efficiency of the valves is characterised by the diodicity which can be defined as the pressure drop ratio of the forward and the reverse flow direction. To obtain efficient valve designs, topological optimization has proven to be a particularly suitable method [1]. The challenge is the dependency of the diodicity on the Reynolds number. Normally, the valves are only efficient at Reynolds numbers much greater than 100. In microfluidics, Reynolds numbers are usually very low, which hitherto limits the applicability of Tesla valves. Therefore a novel approach for the topological optimization of valves that work at very small Reynolds numbers is presented: To ensure that the optimization yields meaningful designs, a customized objective function is introduced and a multi-stage optimization procedure is used. In addition, a method is presented to optimize the diodicity over a given range of Reynolds numbers simultaneously. The resulting valves achieve a diodicity of up to 2 already at Reynolds numbers smaller than 20. The simulated predictions are in close agreement to experimental results.
[1] S. Lin et al., Topology Optimization of Fixed-Geometry Fluid Diodes, J. Mech. Des., 137 (8), (2015)