Numerical study to examine the effect of porosity on in-flight particle dynamics

S. Kamnis; S. Gu; M. Vardavoulias

doi:10.1007/s11666-010-9606-9

Numerical study to examine the effect of porosity on in-flight particle dynamics

S. Kamnis, S. Gu^*, M. Vardavoulias

^*Corresponding author for this work

Department of Civil Engineering

Research output: Contribution to journal › Review article › peer-review

24 Citations (Scopus)

Abstract

High velocity oxygen fuel (HVOF) thermal spray has been widely used to deposit hard composite materials such as WC-Co powders for wear-resistant applications. Powder morphology varies according to production methods while new powder manufacturing techniques produce porous powders containing air voids which are not interconnected. The porous microstructure within the powder will influence in-flight thermal and aerodynamic behavior of particles which is expected to be different from fully solid powder. This article is devoted to study the heat and momentum transfer in a HVOF sprayed WC-Co particles with different sizes and porosity levels. The results highlight the importance of thermal gradients inside the particles as a result of microporosity and how HVOF operating parameters need to be modified considering such temperature gradient.

Original language	English
Pages (from-to)	630-637
Number of pages	8
Journal	Journal of Thermal Spray Technology
Volume	20
Issue number	3
DOIs	https://doi.org/10.1007/s11666-010-9606-9
Publication status	Published - Mar 2011

Keywords

CFD
HVOF
WC-Co
in-flight
porous powder

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10.1007/s11666-010-9606-9

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title = "Numerical study to examine the effect of porosity on in-flight particle dynamics",

abstract = "High velocity oxygen fuel (HVOF) thermal spray has been widely used to deposit hard composite materials such as WC-Co powders for wear-resistant applications. Powder morphology varies according to production methods while new powder manufacturing techniques produce porous powders containing air voids which are not interconnected. The porous microstructure within the powder will influence in-flight thermal and aerodynamic behavior of particles which is expected to be different from fully solid powder. This article is devoted to study the heat and momentum transfer in a HVOF sprayed WC-Co particles with different sizes and porosity levels. The results highlight the importance of thermal gradients inside the particles as a result of microporosity and how HVOF operating parameters need to be modified considering such temperature gradient.",

keywords = "CFD, HVOF, WC-Co, in-flight, porous powder",

author = "S. Kamnis and S. Gu and M. Vardavoulias",

note = "Funding Information: The authors gratefully acknowledge the financial support from EU FP7 SIMUSPRAY Project (Grant No. 230715).",

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AU - Kamnis, S.

AU - Gu, S.

AU - Vardavoulias, M.

N1 - Funding Information: The authors gratefully acknowledge the financial support from EU FP7 SIMUSPRAY Project (Grant No. 230715).

PY - 2011/3

Y1 - 2011/3

N2 - High velocity oxygen fuel (HVOF) thermal spray has been widely used to deposit hard composite materials such as WC-Co powders for wear-resistant applications. Powder morphology varies according to production methods while new powder manufacturing techniques produce porous powders containing air voids which are not interconnected. The porous microstructure within the powder will influence in-flight thermal and aerodynamic behavior of particles which is expected to be different from fully solid powder. This article is devoted to study the heat and momentum transfer in a HVOF sprayed WC-Co particles with different sizes and porosity levels. The results highlight the importance of thermal gradients inside the particles as a result of microporosity and how HVOF operating parameters need to be modified considering such temperature gradient.

AB - High velocity oxygen fuel (HVOF) thermal spray has been widely used to deposit hard composite materials such as WC-Co powders for wear-resistant applications. Powder morphology varies according to production methods while new powder manufacturing techniques produce porous powders containing air voids which are not interconnected. The porous microstructure within the powder will influence in-flight thermal and aerodynamic behavior of particles which is expected to be different from fully solid powder. This article is devoted to study the heat and momentum transfer in a HVOF sprayed WC-Co particles with different sizes and porosity levels. The results highlight the importance of thermal gradients inside the particles as a result of microporosity and how HVOF operating parameters need to be modified considering such temperature gradient.

KW - CFD

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KW - WC-Co

KW - in-flight

KW - porous powder

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Numerical study to examine the effect of porosity on in-flight particle dynamics

Abstract

Keywords

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