TY - CONF
T1 - Technique for Characterization of 3D Unsteady Fluid-Structure Interactions via a Single Plenoptic Camera
AU - Thurow, Brian S.
AU - Tan, Zu Puayen
AU - Tiwari, Bipin
AU - Raghav, Vrishank
PY - 2019/11
Y1 - 2019/11
N2 - Due to flexible boundaries, many flows are unsteady, three-dimensional and subjected to fluid-structure interactions (FSI). Conventional studies of FSI nominally treat the flow and boundary surface measurements separately, resulting in a loss of true FSI physics, especially for aperiodic flows. More recently, simultaneous multi-camera approaches using tomographic-PIV/3D-PTV and Digital Image Correlation (DIC) have been explored. However, this approach is cumbersome to arrange in confined spaces, and challenging to align with each camera's shallow depth-of-field. Here, we propose an alternative method of simultaneous FSI measurement using a single plenoptic camera. Equipped with a microlens array, plenoptic cameras capture a volume's light-field in 4D, which enables single-camera 3D measurements. In this study, a newly developed \textit{kHz}-rate plenoptic camera is applied to characterize the FSI of a flexible 50x 30 x 30\textit{mm}3 tube model. Macroscopic painted dots were used to track surface motion, while micron-sized particles were used as the flow tracer. A pulsatile flow was applied to intermittently collapse the tube, during which the dots and seeds were simultaneously imaged. In post-processing, dots and seeds are separated by diameters and/or shape, after which their 3D trajectories are tracked separately via a plenoptic-PTV algorithm. Preliminary proof-of-concept results are presented, along with further analyses to optimize particles/dots sizes and densities.
AB - Due to flexible boundaries, many flows are unsteady, three-dimensional and subjected to fluid-structure interactions (FSI). Conventional studies of FSI nominally treat the flow and boundary surface measurements separately, resulting in a loss of true FSI physics, especially for aperiodic flows. More recently, simultaneous multi-camera approaches using tomographic-PIV/3D-PTV and Digital Image Correlation (DIC) have been explored. However, this approach is cumbersome to arrange in confined spaces, and challenging to align with each camera's shallow depth-of-field. Here, we propose an alternative method of simultaneous FSI measurement using a single plenoptic camera. Equipped with a microlens array, plenoptic cameras capture a volume's light-field in 4D, which enables single-camera 3D measurements. In this study, a newly developed \textit{kHz}-rate plenoptic camera is applied to characterize the FSI of a flexible 50x 30 x 30\textit{mm}3 tube model. Macroscopic painted dots were used to track surface motion, while micron-sized particles were used as the flow tracer. A pulsatile flow was applied to intermittently collapse the tube, during which the dots and seeds were simultaneously imaged. In post-processing, dots and seeds are separated by diameters and/or shape, after which their 3D trajectories are tracked separately via a plenoptic-PTV algorithm. Preliminary proof-of-concept results are presented, along with further analyses to optimize particles/dots sizes and densities.
M3 - Paper
ER -