Abstract
A modular helium-filled soap bubble (HFSB) generator consisting of 3D-printed nozzles and developed for use in a wind tunnel is characterized. A multi-syringe pump accurately feeds bubble film solution (BFS) to each nozzle while air and helium flow rates are regulated using mass flow controllers. The modular design of the system allows for the customization of the HFSB streamtube to each unique experiment. Modules can be arranged in various configurations to increase seeding density and manipulate the size of the streamtube. Shadowgraphy, particle image velocimetry, particle tracking velocimetry, and laser-based imaging are used to characterize the particle sizes, tracing fidelity, production rates, and seeding density of a system consisting of two modules (8 nozzles in total). It is shown that nozzle performance, particle time response, and production rates can be controlled by varying the flow rates of air, helium, and BFS into the system, respectively. The optimal operating case resulted in the production of approximately 70,000 bubbles/s from each nozzle. The bubbles were neutrally buoyant on average and had a mean diameter of 0.46 mm. The two modules resulted in a streamtube with an effective cross-section of 15 × 15 cm2. The streamtube was produced continuously, resulting in a seeding density of 1.6 bubbles/cm3 at free stream velocity of 10.3 m/s.
Graphical abstract
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Babie BM, Nelson RC (2010) An experimental investigation of bending wave instability modes in a generic four-vortex wake. Phys Fluids 22:077101
Biwole PH, Yan W, Zhang Y, Roux JJ (2009) A complete 3D particle tracking algorithm and its application to the indoor airflow study. Meas Sci Technol 20:115403
Bosbach J, Kühn M, Wagner C (2009) Large scale particle image velocimetry with helium filled soap bubbles. Exp Fluids 46:539–547
Caridi GCA, Ragni D, Sciacchitano A, Scarano F (2016) HFSB-seeding for large-scale tomographic PIV in wind tunnels. Exp Fluids 57:190
Caridi GCA, Sciacchitano A, Scarano F (2017) Helium-filled soap bubbles for vortex core velocimetry. Exp Fluids 58:130
Elsinga GE, Scarano F, Wieneke B, van Oudheusden BW (2006) Tomographic particle image velocimetry. Exp Fluids 41:933–947
Engler Faleiros D, Tuinstra M, Sciacchitano A, Scarano F (2018) Helium-filled soap bubbles tracing fidelity in wall-bounded turbulence. Exp Fluids 59:56
Hale RW, Tan P, Stowell RC, Ordway DE (1971) Development of an integrated system for flow visualization in air using neutrally buoyant bubbles. SAI-RR 7107, SAGE ACTION Inc, Ithaca
Huhn F, Schanz D, Gesemann S, Dierksheide U, van de Meerendonk R, Schröder A (2017) Large-scale volumetric flow measurement in a pure thermal plume by dense tracking of helium-filled soap bubbles. Exp Fluids 58:116
Johnson MR, Kostiuk LW (2000) Efficiencies of low-momentum jet diffusion flames in crosswinds. Combust Flame 123(1):189–200
Kerho MF, Bragg MB (1994) Neutrally buoyant bubbles used as flow tracers in air. Exp Fluids 16:393–400
Kühn M, Ehrenfried K, Bosbach J, Wagner C (2011) Large-scale tomographic particle image velocimetry using helium-filled soap bubbles. Exp Fluids 50:929–948
Meinhart CD, Wereley ST, Santiago JG (2000) A PIV algorithm for estimating time-averaged velocity fields. J Fluids Eng 122:285–289
Müller D, Müller B, Renz U (2001) Three-dimensional particle-streak tracking (PST) velocity measurements of a heat exchanger inlet flow. Exp Fluids 30:645–656
Raffel M, Willert CE, Wereley ST, Kompenhans J (2007) Particle image velocimetry: a practical guide. Springer, Berlin
Scarano F (2013) Tomographic PIV: principles and practice. Meas Sci Technol 24:012001
Scarano F, Ghaemi S, Caridi GCA, Bosbach J, Dierksheide U, Sciacchitano A (2015) On the use of helium-filled soap bubbles for large-scale tomographic PIV in wind tunnel experiments. Exp Fluids 56:42
Schanz D, Gesemann S, Schröder A (2016) Shake-The-Box: Lagrangian particle tracking at high particle image densities. Exp Fluids 57:70
Schneiders JFG, Caridi GCA, Sciacchitano A, Scarano F (2016) Large-scale volumetric pressure from tomographic PTV with HFSB tracers. Exp Fluids 57:164
Terra W, Sciacchitano A, Scarano F (2017) Aerodynamic drag of a transitioning sphere by large-scale tomographic-PIV. Exp Fluids 58:83
Tropea C, Yarin AL, Foss J (2007) Handbook of experimental fluid mechanics. Springer, Berlin
Acknowledgements
The authors would like to thank Findlay McCormick, Sen Wang, and Desiree Reholon for assisting with various aspects of this project. We would also like to thank Prof. David Nobes for allowing us to use his equipment for our experiments.
Funding
The funding was received by Future Energy Systems (Grant no. T14-P05).
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Gibeau, B., Ghaemi, S. A modular, 3D-printed helium-filled soap bubble generator for large-scale volumetric flow measurements. Exp Fluids 59, 178 (2018). https://doi.org/10.1007/s00348-018-2634-9
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00348-018-2634-9