On high-speed impingement of cylindrical droplets upon solid wall considering cavitation effects

Abstract: The high-speed impingement of droplets on a wall occurs widely in nature and industry. However, there is limited research available on the physical mechanism of the complicated flow phenomena during impact. In this study, a simplified multi-component compressible two-phase fluid model, coupled with the phase-transition procedure, is employed to solve the two-phase hydrodynamics system for high-speed cylindrical droplet impaction on a solid wall. The threshold conditions of the thermodynamic parameters of the f… Show more

“…Local cavitation may be generated inside the droplet due to the convergence of the proper waves, as verified by experiments (Lesser & Field 1983;Field et al 1989Field et al , 2012Obreschkow et al 2011) and subsequent numerical simulations during high-speed impingement (Sanada, Ando & Colonius 2011;Kondo & Ando 2016;Kyriazis, Koukouvinis & Gavaises 2018). The cavitation evolution mechanisms during a droplet's high-speed impingement on a flat solid surface were discussed in our previous works (Wu, Xiang & Wang 2018;Wu, Wang & Xiang 2019). Some researchers deduced that cavity collapse especially near-surface cavity collapse may also induce surface damage (Okada et al 1995;Obreschkow et al 2011;Kyriazis et al 2018).…”

“…A high-speed multi-phase flow problem including complex cavitation phenomena is studied in the present work, and the compressible multi-phase fluid model including phase transition is used (Wu et al 2018). The governing equations are…”

“…The same Courant-Friedrich-Lewis (CFL) number, 0.4, is used for all of the computations. The numerical verification of the grid sensitivity refers to the treatment methods in the present authors' previous work (Wu et al 2018(Wu et al , 2019.…”

“…In the present study, the expansion speeds of the wavelets are all assumed to be constant for simplification. In the earlier impinging stage, the envelop of the compression wavelets form the front of the water-hammer shock wave (Wu et al 2018). For droplet impingement on a concave surface (as shown in figure 4a), the initial contact region is a circular arc, and hence many compression wavelets are simultaneously emitted at the initial interaction instant.…”

“…According to the droplet's geometrical profile, the intersection angle between the interface of the droplet and the solid surface increases with the impinging process, and the expansion velocity of the periphery of the contact region between the droplet and the surface gradually decreases from an infinite value at the initial interaction instant ( Wu et al 2018). Owing to the limitation of the sound speed, the propagation velocity of the water-hammer shock wave is lower than the expansion velocity of the periphery of the contact region at the very beginning.…”

Curved surface effect on high-speed droplet impingement

“…Local cavitation may be generated inside the droplet due to the convergence of the proper waves, as verified by experiments (Lesser & Field 1983;Field et al 1989Field et al , 2012Obreschkow et al 2011) and subsequent numerical simulations during high-speed impingement (Sanada, Ando & Colonius 2011;Kondo & Ando 2016;Kyriazis, Koukouvinis & Gavaises 2018). The cavitation evolution mechanisms during a droplet's high-speed impingement on a flat solid surface were discussed in our previous works (Wu, Xiang & Wang 2018;Wu, Wang & Xiang 2019). Some researchers deduced that cavity collapse especially near-surface cavity collapse may also induce surface damage (Okada et al 1995;Obreschkow et al 2011;Kyriazis et al 2018).…”

“…A high-speed multi-phase flow problem including complex cavitation phenomena is studied in the present work, and the compressible multi-phase fluid model including phase transition is used (Wu et al 2018). The governing equations are…”

“…The same Courant-Friedrich-Lewis (CFL) number, 0.4, is used for all of the computations. The numerical verification of the grid sensitivity refers to the treatment methods in the present authors' previous work (Wu et al 2018(Wu et al , 2019.…”

“…In the present study, the expansion speeds of the wavelets are all assumed to be constant for simplification. In the earlier impinging stage, the envelop of the compression wavelets form the front of the water-hammer shock wave (Wu et al 2018). For droplet impingement on a concave surface (as shown in figure 4a), the initial contact region is a circular arc, and hence many compression wavelets are simultaneously emitted at the initial interaction instant.…”

“…According to the droplet's geometrical profile, the intersection angle between the interface of the droplet and the solid surface increases with the impinging process, and the expansion velocity of the periphery of the contact region between the droplet and the surface gradually decreases from an infinite value at the initial interaction instant ( Wu et al 2018). Owing to the limitation of the sound speed, the propagation velocity of the water-hammer shock wave is lower than the expansion velocity of the periphery of the contact region at the very beginning.…”

Curved surface effect on high-speed droplet impingement

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