Effect of Tesla valve geometry on unsteady flow behavior and pressure drop
a CFD study
DOI:
https://doi.org/10.36561/ING.29.5Keywords:
Pressure drop, Computational Fluid Dynamics, Tesla Valve, Micro/Nano Fluidics, DiodicityAbstract
Computational fluid dynamics (CFD) simulations are carried out to examine the effect of geometric
parameters of Tesla valve on flow patterns, pressure drop and flow diodicity. In forward flow, the flow is relatively smooth with less flow resistance. The low velocity regions are present at the entrance to the curved section and at the
junction of the curved section and the exit channel, where flow separation takes place. In reverse flow, the flow is quite irregular, and major recirculation zones are observed in the bottom branch, in addition to the top-curved and exit sections. The simulations with small time steps show that the flow is steady when the flow takes place in the forward
direction. The flow is mostly transient; however, when the fluid flows in the reverse direction, particularly at higher Reynolds numbers. The effect of geometric parameters such as the angles subtended by the curved section (with the
horizontal) shows that optimal values of these angles exist. For a certain range of angles, diodicity is greater than 2.
The effect of multi-staging of the Tesla valve is studied, and it is found that the flow unsteadiness and overall diodicity increase with the number of stages.
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Copyright (c) 2025 Muhammad Shakaib, Muhammad Ehtisharn ul Haq, Syed Muhammad Fakhir Hasani
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