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http://dx.doi.org/10.5407/jksv.2021.19.1.036

Flow Visualization of Magnetic Particles under the external magnetic field in bubbly flow using Single Plane Illumination Microscopy - MicroPIV  

Lee, Changje (Research Institute of Maritime Industry, Korea Maritime and Ocean University)
Cho, Gyeong-rae (Department of Mechanical Engineering, Korea Maritime and Ocean University)
Lee, Sangyoup (Center for Bionics, Korea Institute Science and Technology)
Publication Information
Journal of the Korean Society of Visualization / v.19, no.1, 2021 , pp. 36-42 More about this Journal
Abstract
This study measured the velocity of magnetic particles inside the power generation using external heat sources. Single Plane Illumination Microscopy (SPIM) was used to measure magnetic particles that are simultaneously affected by bubbly flow and magnetic field. It has the advantage of reducing errors due to particle superposition by illuminating the thin light sheet. The hydraulic diameter of the power generation is 3mm. Its surface is covered with a coil with a diameter of 0.3 mm. The average diameter of a magnetic particle is 200nm. The excitation and emission wavelengths are 530 and 650nm, respectively. In order to find out the flow characteristics, a total of four velocity fields were calculated in wide and narrow gap air bubbles, between the wall and the air bubble and just below the air bubble. Magnetic particles showed up to 8.59% velocity reduction in the wide gap between air bubbles due to external magnetic field.
Keywords
Single Plane Illumination Microscopy; Exteranl magnetic field; Bubbly flow; Magnetic particle; Micro Particle Image Velocimetry;
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1 Bibo, A., Masana, R., King, A., Li, G. and Daqaq, M. F., 2012, "Electromagnetic ferrofluid-based energy harvester," Physics Letters, Section A: General, Atomic and Solid State Physics, Vol. 376(32), pp. 2163-2166.
2 Seol, M.-L., Jeon, S.-B., Han, J.-W. and Choi, Y.-K, 2017, "Ferrofluid-based triboelectric-electromagnetic hybrid generator for sensitive and sustainable vibration energy harvesting," Nano Energy, Vol. 31, pp. 233-238.   DOI
3 Yun, H. R., Lee, D. J., Youn, J. R. and Song, Y. S., 2015, "Ferrohydrodynamic energy harvesting based on air droplet movement," Nano Energy, Vol. 11, pp. 171-178.   DOI
4 A. Kvon, Y.H. Lee, T.A. Cheema and C.W. Park, 2014, "Development of dual micro-PIV system for simultaneous velocity measurements: optical arrangement techniques and application to blood flow measurements," Measurement Science and Technology, Vol. 25, pp. 75302.   DOI
5 B.H. Jun, N. Saikrishnan and A.P. Yoganathan, 2014, "Micro particle image velocimetry measurements of steady diastolic leakage flow in the hinge of a St. Jude Medical Regent mechanical heart valve," Annals of Biomedical Engineering, Vol. 42, pp. 526-540.   DOI
6 Donata M. Fries, severin Waelchli and Philipp Rudolf von Rohr, 2008, "Gas-liquid two-phase flow in meandering microchannels," Chemical Engineering Journal, Vol 135, pp. S37-45.   DOI
7 Sheikholeslami, M., Barzegar Gerdroodbary, M., Mousavi, S. V., Ganji, D. D. and Moradi, R., 2018, "Heat transfer enhancement of ferrofluid inside an 90° elbow channel by non-uniform magnetic field," Journal of Magnetism and Magnetic Materials, Vol. 460, pp. 302-311.   DOI
8 Asfer, M., Prasad Prajapati, A., Kumar, A. and Kumar Panigrahi, P., 2015, "Visualization and Motion of Curcumin Loaded Iron Oxide Nanoparticles During Magnetic Drug Targeting," Journal of Nanotechnology in Engineering and Medicine, Vol. 6(1), pp. 011004   DOI
9 Hamdipoor, V., Afzal, M., Le, T.-A. and Yoon, J., 2018, "Haptic-Based Manipulation Scheme of Magnetic Nanoparticles in a Multi-Branch Blood Vessel for Targeted Drug Delivery," Micromachines, Vol. 9(1), pp. 14.   DOI
10 Yun, H. R., Lee, D. J., Youn, J. R. and Song, Y. S., 2015, "Ferrohydrodynamic energy harvesting based on air droplet movement," Nano Energy, Vol, 11, pp. 171-178.   DOI
11 Zeng, J., Deng, Y., Vedantam, P., Tzeng, T.-R. and Xuan, X., 2013, "Magnetic separation of particles and cells in ferrofluid flow through a straight microchannel using two offset magnets," Journal of Magnetism and Magnetic Materials, Vol. 346, pp. 118-123.   DOI
12 Sheikholeslami, M. and Rokni, H.B., 2017, "Simulation of nanofluid heat transfer in presence of magnetic field: A review," International Journal of Heat and Mass Transfer, Vol. 115, pp. 1203-1233.   DOI
13 Berensmeier, S., 2006. "Magnetic particles for the separation and purification of nucleic acids," Applied Microbiology and Biotechnology, Vol. 73, pp. 495-504.   DOI
14 Weijian Zong, Jia Zhao, Xuanyang Chen, Yuan Lin, Huixia Ren, Yunfeng Zhang, Ming Fan, Zhuan Zhou, Heping Cheng, Yujie Sun and Liangyi Chen, 2014, "Large-field high-resolution two-photon digital scanned light-sheet microscopy," Cell Research, Vol. 25, pp. 254-257.   DOI
15 J.G. Santiago, S.T. Wereley, C.D. Meinhart, D.J. Beebe and R.J. Adrian, 1998, "A particle image velocimetry system for microfluidics," Experiments in Fluids, Vol. 25, pp. 316-319   DOI
16 Zickus V. and Taylor JM., 2018, "3D + time blood flow mapping using SPIM-microPIV in the developing zebrafish heart," BBiomedical Optics Express, vol. 9(5), pp. 2418-2435.   DOI
17 Hartshorne, H., Backhouse, C. J. and Lee, W. E., 2004, "Ferrofluid-based microchip pump and valve," Sensors and Actuators, B: Chemical, Vol. 99(2-3), pp. 592-600.   DOI
18 Kim, S.H., Park, J.H., Choi, H.S. and Lee, S.H. (2017). "Power Generation Properties of Flow Nanogenerator With Mixture of Magnetic Nanofluid and Bubbles in Circulating System," Ieee Transactions on Magnetics, Vol. 53(11). pp. 4600904
19 Bibo, A., Masana, R., King, A., Li, G. and Daqaq, M. F., 2012, "Electromagnetic ferrofluid-based energy harvester," Physics Letters, Section A: General, Atomic and Solid State Physics, Vol, 376(32), pp. 2163-2166.
20 Raju Tomer, Matthew Lovett-Barron, Isaac Kauvar, Aaron Andalman, Vanessa M. Burns, Sethuraman Sankaran, Logan Grosenick, Michael Broxton, Samuel Yang, and Karl Deisseroth, 2015, "SPED Light Sheet Microscopy: Fast Mapping of Biological System Structure and Function," Cell, Vol. 163 pp. 1796-1806.   DOI
21 Engelbrecht, C. J. and Stelzer, E. H., 2006, "Resolution enhancement in a light-sheet-based microscope (SPIM)," Optics Letters, Vol. 31(10), pp. 1477-1479.   DOI
22 B. Wieneke, 2015, "PIV uncertainty quantification from correlation statistics," Measurement Science and Technology. Vol. 26(7), pp. 074002   DOI