Citations (15)
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HUI LI & YUJI TOMITA. (2002) Measurements of Particle Velocity and Concentration for Dilute Swirling Gas-Solid Flow in a Vertical Pipe. Particulate Science and Technology 20:1, pages 1-13.
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Hui Li & Yuji Tomita. (2001) A Numerical Simulation of Swirling Flow Pneumatic Conveying in a Vertical Pipeline. Particulate Science and Technology 19:4, pages 355-368.
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Articles from other publishers (13)
Kun Han, Yongfa Diao, Jiawei Zhuang & Minghao Chu. (2023) The effects of imposed swirling flow on the transport and deposition of particulate pollutants in the 90° industrial duct bends: An Eulerian-Lagrangian approach. Indoor and Built Environment.
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Hiroka Rinoshika, Yusei Mori & Akira Rinoshika. (2023) Influence of vortical flow induced by a wall-mounted short cylinder with a streamlined front side on a horizontal air–solid two-phase flow. Powder Technology, pages 118774.
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Lin Dong, Mingjie Ding, Akira Rinoshika, Yongli Wang & Chunping Yuan. (2022) Application of oscillation flow to horizontal gas–particle two-phase flow. Powder Technology 406, pages 117580.
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Lin Dong, Yongli Wang & Akira Rinoshika. (2021) Effect of oscillation flow induced by lattices on a horizontal gas–solid two-phase flow. Powder Technology 394, pages 926-934.
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Lin Dong & Akira Rinoshika. (2020) Self-excited gas–solid two-phase flow using non-uniform soft fins. Powder Technology 367, pages 317-325.
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Lin Dong & Akira Rinoshika. (2019) Self-excited pneumatic conveying through vertical curved 90° bends. Powder Technology 346, pages 291-300.
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Lin Dong & Akira Rinoshika. (2019) Comparison between rotation swirler and non-rotation swirler in a horizontal swirling flow pneumatic conveying. Powder Technology 346, pages 396-402.
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Akbar Arsalanloo & Majid Abbasalizadeh. (2017) Numerical study on deposition of particles in a 90° bend in the presence of swirling flow using Eulerian-Lagrangian method. Powder Technology 320, pages 285-294.
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Akira Rinoshika. (2015) Self-excited pneumatic conveying of granular particles in various horizontal curved 90° bends. Experimental Thermal and Fluid Science 63, pages 9-19.
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Akira Rinoshika. (2014) Dilute pneumatic conveying of a horizontal curved 90° bend with soft fins or dune model. Powder Technology 254, pages 291-298.
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Akira Rinoshika. (2013) Effect of oscillating soft fins on particle motion in a horizontal pneumatic conveying. International Journal of Multiphase Flow 52, pages 13-21.
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Akira Rinoshika & Masahito Suzuki. (2010) An experimental study of energy-saving pneumatic conveying system in a horizontal pipeline with dune model. Powder Technology 198:1, pages 49-55.
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Yuji Tomita, Vijay Kumar Agarwal, Hiroyuki Asou & Katsuya Funatsu. (2008) Low-velocity pneumatic conveying in horizontal pipe for coarse particles and fine powders. Particuology 6:5, pages 316-321.
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