Single-camera PTV within interfacially sheared drops in microgravity

Development of experimental methods for in situ particle tracking velocimetry (PTV) is fundamental for allowing measurement of moving systems non-tailored for velocimetry. This investigation focuses on the development of a post-processing methodology for single-camera PTV, without laser-sheet illumi...

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Veröffentlicht in:	Experiments in fluids 2023-09, Vol.64 (9), Article 154
Hauptverfasser:	McMackin, Patrick M., Adam, Joe A., Riley, Frank P., Hirsa, Amir H.
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Sprache:	eng
Schlagworte:	Air bubbles Cameras Drops (liquids) Engineering Engineering Fluid Dynamics Engineering Thermodynamics Flow geometry Fluid flow Fluid- and Aerodynamics Heat and Mass Transfer Insulin International Space Station Light sheets Methodology Microgravity Microgravity technology Newtonian fluids Non Newtonian fluids Optical components Particle tracking Particle tracking velocimetry Ray tracing Research Article Tracer particles
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description	Development of experimental methods for in situ particle tracking velocimetry (PTV) is fundamental for allowing measurement of moving systems non-tailored for velocimetry. This investigation focuses on the development of a post-processing methodology for single-camera PTV, without laser-sheet illumination, tracking native air bubbles as tracer particles within a liquid drop of human insulin in microgravity. Human insulin functioned as a sufficiently complex, non-Newtonian fluid system for testing fluid measurement methodology. The PTV scenario was facilitated by microgravity technology known as the ring-sheared drop (RSD), aboard the International Space Station, which produced an optical imaging scenario and fluid flow geometry suitable as a testbed for PTV research. The post-processing methodology performed included five steps: (i) physical system characterization and native air bubble tracer identification, (ii) image projection and single-camera calibration, (iii) depth determination and 3D particle position determination, (iv) ray tracing and refraction correction, and (v) particle history and data expansion for suboptimal particles. Overall, this post-processing methodology successfully allowed for a total of 1085 particle measurements in a scenario where none were previously possible. Such post-processing methodologies have promise for application to other in situ PTV scenarios allowing better understanding of physical systems whose flow is difficult to measure and/or where PTV-specific optical elements (such as laser light sheets and dual-camera setups) are not permissible due to physical or safety constraints.
doi_str_mv	10.1007/s00348-023-03697-6
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This investigation focuses on the development of a post-processing methodology for single-camera PTV, without laser-sheet illumination, tracking native air bubbles as tracer particles within a liquid drop of human insulin in microgravity. Human insulin functioned as a sufficiently complex, non-Newtonian fluid system for testing fluid measurement methodology. The PTV scenario was facilitated by microgravity technology known as the ring-sheared drop (RSD), aboard the International Space Station, which produced an optical imaging scenario and fluid flow geometry suitable as a testbed for PTV research. The post-processing methodology performed included five steps: (i) physical system characterization and native air bubble tracer identification, (ii) image projection and single-camera calibration, (iii) depth determination and 3D particle position determination, (iv) ray tracing and refraction correction, and (v) particle history and data expansion for suboptimal particles. 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subjects	Air bubbles Cameras Drops (liquids) Engineering Engineering Fluid Dynamics Engineering Thermodynamics Flow geometry Fluid flow Fluid- and Aerodynamics Heat and Mass Transfer Insulin International Space Station Light sheets Methodology Microgravity Microgravity technology Newtonian fluids Non Newtonian fluids Optical components Particle tracking Particle tracking velocimetry Ray tracing Research Article Tracer particles
title	Single-camera PTV within interfacially sheared drops in microgravity
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