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9 results on '"Lippert, Anja"'

1. Fluid wetting and penetration characteristics in T-shaped microchannels

Author

Zhang, Huijie, Lippert, Anja, Leonhardt, Ronny, Tolle, Tobias, Nagel3, Luise, and Maric, Tomislav

Subjects
Physics - Fluid Dynamics
Abstract

A thorough understanding of media tightness in automotive electronics is crucial for ensuring more reliable and compact product designs, ultimately improving product quality. Concerning the fundamental characteristics of fluid leakage issues, the dynamic wetting and penetration behavior on small scales is of special interest and importance. In this work, four T-shaped microchannels with one inlet and two outlets are experimentally investigated in terms of contact angle dynamics and interface movement over time, generating novel insight into the wetting mechanisms and fluid distribution. With a main channel width of 1 mm, a crevice width of w = 0.3 mm, 0.4 mm and a rounding edge radius of r = 0.1 mm, 0.2 mm, the geometrical effects on the fluid penetration depth in the crevice and the interface edge pinning effect are analyzed quantitatively using an automated image processing procedure. It is found that the measured dynamic contact angles in all parts can be well described by molecular kinetic theory using local contact line velocities, even with local surface effects and abrupt geometry changes. Moreover, a smaller crevice width, a sharper edge and a larger flow velocity tend to enhance the interface pinning effect and prevent fluid penetration into the crevice. The rounding radius has a more significant effect on the interface pinning compared with crevice width. The experimental data and image processing algorithm are made publicly available.

Published
2024

2. Experimental and Numerical Study of Microcavity Filling Regimes for Lab-on-a-Chip Applications

Author

Nagel, Luise, Lippert, Anja, Leonhardt, Ronny, Tolle, Tobias, Zhang, Huijie, and Maric, Tomislav

Subjects
Physics - Fluid Dynamics
Abstract

The efficient and voidless filling of microcavities is of great importance for Lab-on-a-Chip applications. However, predicting whether microcavities will be filled or not under different circumstances is still difficult due to the local flow effects dominated by surface tension. In this work, a close-up study of the microcavity filling process is presented, shedding light on the mechanisms of the filling process using experimental insights accompanied by 3D numerical simulations. The movement of a fluid interface over a microcavity array is investigated optically under consideration of different fluids, capillary numbers, and cavity depths, revealing a regime map of different filling states. Moreover, the transient interface progression over the cavities is analyzed with attention to small-scale effects such as pinning. Besides the visual analysis of the image series, quantitative data of the dynamic contact angle and the interface progression is derived using an automated evaluation workflow. In addition to the experiments, 3D Volume-of-Fluid simulations are employed to further investigate the interface shape. It is shown that the simulations can not only predict the filling states in most cases, but also the transient movement and shape of the interface. The data and code associated with this work are publicly available at Bosch Research GitHub and at the TUDatalib data repository., Comment: submitted to International Journal of Multiphase Flow

Published
2024

3. Experimental study of dynamic wetting behavior through curved microchannels with automated image analysis

Author

Zhang, Huijie, Lippert, Anja, Leonhardt, Ronny, Tolle, Tobias, Nagel, Luise, Fricke, Mathis, and Maric, Tomislav

Subjects
Physics - Fluid Dynamics
Abstract

Preventing fluid penetration poses a challenging reliability concern in the context of power electronics, which is usually caused by unforeseen microfractures along the sealing joints. A better and more reliable product design heavily depends on the understanding of the dynamic wetting processes happening inside these complex microfractures, i.e. microchannels. A novel automated image processing procedure is proposed in this work for analyzing the moving interface and the dynamic contact angle in microchannels. In particular, the developed method is advantageous for experiments involving non-transparent samples, where extracting the fluid interface geometry poses a significant challenge. The developed method is validated with theoretical values and manual measurements and exhibits high accuracy. The implementation is made publicly available. The developed method is validated and applied to experimental investigations of forced wetting with two working fluids (water and 50 wt% glycerin/water mixture) in four distinct microchannels characterized by different dimensions and curvature. The comparison between the experimental results and molecular kinetic theory (MKT) reveals that the dynamic wetting behavior can be described well by MKT, even in highly curved microchannels. The dynamic wetting behavior shows a strong dependency on the channel geometry and curvature.

Published
2024
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5. Stabilizing the unstructured Volume-of-Fluid method for capillary flows in microstructures using artificial viscosity

Author

Nagel, Luise, Lippert, Anja, Tolle, Tobias, Leonhardt, Ronny, Zhang, Huijie, and Maric, Tomislav

Subjects
Physics - Fluid Dynamics, Physics - Computational Physics
Abstract

Parasitic currents still pose a significant challenge for the investigation of two-phase flow in Lab-on-Chip (LoC) applications with Volume-of-Fluid (VoF) simulations. To counter the impact of such spurious velocity fields in the vicinity of the fluid interface, this work presents an implementation of an artificial interface viscosity model in OpenFOAM. The model is introduced as an additional dampening term in the momentum conservation equation. It is implemented as a fvOption, allowing for its simple application to existing VoF solvers. Validation is performed with hydrodynamic and wetting cases, in which constant artificial viscosity values are prescribed to examine the sensitivity of the solution to the artificial dampening. The artificial viscosity model shows promising results in reducing spurious currents for two considered geometrical VoF solvers, namely interIsoFoam and InterFlow. It is found that the influence of the artificial viscosity heavily depends on the fluid properties. Applying the model to simulations of an interface traversing through microcavities relevant in LoC applications, experimental results of the interface progression are predicted well, while spurious currents are effectively reduced by approximately one order of magnitude due to the artificial viscosity model. The code is publicly available on GitHub (https://github.com/boschresearch/sepMultiphaseFoam/tree/publications/ArtificialInterfaceViscosity)., Comment: author manuscript of published article

Published
2023
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6. A benchmark for surface-tension-driven incompressible two-phase flows

Author

Lippert, Anja, Tolle, Tobias, Dörr, Aaron, and Maric, Tomislav

Subjects
Physics - Fluid Dynamics, Physics - Computational Physics
Abstract

The Volume-of-Fluid (VoF) method for simulating incompressible two-phase flows is widespread in academic and commercial simulation software because of its many advantages: a high degree of volume conservation, applicability to unstructured domain discretization (relevant for engineering applications), straightforward parallel implementation with the domain-decomposition and message-passing approach (important for large-scale simulations), and intrinsic handling of strong deformations and topological changes of the fluid interface. However, stable and accurate handling of small-scale capillary flows (dominated by surface tension forces) is still challenging for VoF methods. With many different VoF methods making their way into commercial and open-source software, it becomes increasingly important to compare them quantitatively and directly. For this purpose, we propose a set of simulation benchmarks and use them to directly compare VoF methods available in OpenFOAM, Basilisk, and Ansys Fluent. We use Jupyter notebooks to document and process the benchmark results, making a direct comparison of our results with other two-phase simulation methods very straightforward. The publicly available input data, secondary benchmark data, and post-processing Jupyter notebooks can be re-used by any two-phase flow simulation method that discretizes two-phase Navier-Stokes equations in a one-fluid formulation, which can save a significant amount of person-hours.

Published
2022

9. Direct Numerical Simulations of Thermocapillary Driven Motions in Two-phase Flows

Author

Lippert, Anja Charlotte

Subjects
Physics::Fluid Dynamics
Abstract

In this thesis, a code framework is created to allow further insight into thermocapillary driven flows through direct numerical simulation of two-phase flows. For the numerical simulations, the full Navier-Stokes equations and energy equation are solved in a Volume of Fluid framework. To this end, the underlying sets of equations for each phase are conditioned, volume averaged and added to obtain one set of equations valid within the whole physical domain, incorporating the corresponding jump conditions. The interface between the two phases is captured by piecewise linear reconstruction from the volume fraction field. Apart from providing a sharp interface, such a geometrical reconstruction allows a specific position to store interface values and generate additional information around the interface via subgrid-scale modeling. For the energy transport in temperature form, a novel algorithm avoids mixed quantities, as present in the one-field formulation. Based on cut-cell methods, the interface reconstruction is used to generate two grids on which phase specific, averaged, but not mixed, quantities are stored for each phase. The exchange between both phases takes place according to the jump condition at the reconstructed interface. Additionally, the interface values are stored at the plane barycenters. The thermal Marangoni forces are calculated directly from these interface temperatures by discretizing the interface gradient. To prevent artificial accelerations in the vicinity of the interface, the surface tension is applied via a balanced continuous surface force algorithm. A library of common macroscopic contact angle models and different contact line velocities is created to capture contact line dynamics. Based on the contact angle for each contact line cell, the surface tension and normal vectors are adapted such that the interface encloses this angle with the solid wall. Three algorithms are implemented for contact line pinning. The new developments are incorporated within the in-house code Free Surface 3D. They are thoroughly validated, in isolation as well as in combination. With this extended framework thermocapillary driven flows are investigated in applications relevant for industrial processes. These investigations include short-scale Marangoni flows in a film on an evenly heated horizontal wall with a structured surface. Simulations are performed to study the influence of film height, wall temperature, topography changes and the effect of gravity on flow characteristics like interface velocity, flow patterns and heat transport. Furthermore, the physical mechanisms and acting forces of a thermally actuated droplet on a inhomogeneously heated wall are investigated. The droplet motion is studied both in two and three dimensions, where a movement either towards the cold or the warm side can be observed. The last application concerns liquid bridges as a model of half-zone melting, where the effects of contact angle and contact line pinning on flow patterns are captured by the numerical simulation.

Published
2016

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