Scipediacontent: Scipediacontent moved page Draft content 633300514 to Aleksieienko et al 2025a

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Scipediacontent moved page Draft content 633300514 to Aleksieienko et al 2025a

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← Older revision		Revision as of 09:54, 15 October 2025
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	approach for modeling aircraft icing. The results obtained can be used to ensure flight safety,		approach for modeling aircraft icing. The results obtained can be used to ensure flight safety,
	design anti-icing systems, and investigate aviation accidents		design anti-icing systems, and investigate aviation accidents
		+
		+	== Full Paper ==
		+	<pdf>Media:Draft_content_633300514pap_103.pdf</pdf>

← Older revision	Revision as of 09:54, 15 October 2025
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	+
	+	==Abstract==

	+	In-flight aircraft icing is a serious problem affecting flight safety and operational
	+	reliability. Atmospheric supercooled water droplets impinge on aircraft surfaces and freeze,
	+	forming ice, which can severely degrade aerodynamic performance and operational safety,
	+	potentially leading to a complete loss of control. Computational fluid dynamics is an important
	+	tool in the development of aircraft anti-icing systems, and modeling icing processes is a
	+	complex, interdisciplinary, and multi-physics task. This study presents approaches to describing
	+	the air-droplet incoming flow in aircraft icing modeling and analyzes the behavior of droplets
	+	interacting with an ice-covered aerodynamic surface. The Navier-Stokes equations coupled
	+	with the Spalart-Allmaras turbulence model are used to describe the motion of the carrier
	+	medium. The applicability of the polydisperse Eulerian, Lagrangian trajectory, and
	+	homogeneous models is analyzed for supercooled droplet dynamics. Numerical simulation of
	+	icing processes is performed using the control volume method, taking into account the
	+	conservation laws of mass, momentum, and energy. The analysis conducted in this work
	+	showed that the homogeneous model is appropriate for conditions near the phase transition
	+	point. The freezing of moisture that impinges on the aerodynamic surface is primarily governed
	+	by the temperature of the aerodynamic body and its heat exchange with the incoming flow. In
	+	cases where supercooled atmospheric droplets play a dominant role in the icing process, the
	+	Lagrangian trajectory model and the polydisperse Eulerian model are preferable for describing
	+	the air-droplet flow. The primary conclusion is that the polydisperse Eulerian model is
	+	preferable, as it best accounts for the characteristics of two-phase viscous compressible flow
	+	around bodies and the interaction of the carrier and liquid phases, making it the most promising
	+	approach for modeling aircraft icing. The results obtained can be used to ensure flight safety,
	+	design anti-icing systems, and investigate aviation accidents

← Older revision	Revision as of 09:54, 15 October 2025
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Aleksieienko et al 2025a - Revision history

Scipediacontent: Scipediacontent moved page Draft content 633300514 to Aleksieienko et al 2025a

Scipediacontent at 09:54, 15 October 2025

Scipediacontent at 09:54, 15 October 2025

Scipediacontent: Created blank page