Effects of Heat and Momentum Gain Differentiation during Gas Detonation Spraying of FeAl Powder Particles into the Water

Effects of Heat and Momentum Gain Differentiation during Gas Detonation Spraying of FeAl Powder Particles into the Water

In this paper, dynamic interactions between the FeAl particles and the gaseous detonation stream during supersonic D-gun spraying (DGS) conditions into the water are discussed in detail. Analytical and numerical models for the prediction of momentum and complex heat exchange, that includes radiative...

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Veröffentlicht in:Materials 2021-12, Vol.14 (23), p.7443
Hauptverfasser: Senderowski, Cezary, Panas, Andrzej J., Fikus, Bartosz, Zasada, Dariusz, Kopec, Mateusz, Korytchenko, Kostyantyn V.
Format: Artikel
Sprache:eng
Schlagworte:
Agglomeration
Chemical reactions
Ferrous alloys
Flow velocity
Gas detonation
Gas flow
Gases
Grain size
Heat
Heat exchange
Intermetallic compounds
Iron aluminides
Momentum
Numerical models
Particle acceleration
Phase transitions
Powder spraying
Raw materials
Substrates
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Zusammenfassung:In this paper, dynamic interactions between the FeAl particles and the gaseous detonation stream during supersonic D-gun spraying (DGS) conditions into the water are discussed in detail. Analytical and numerical models for the prediction of momentum and complex heat exchange, that includes radiative effects of heat transfer between the FeAl particle and the D-gun barrel wall and phase transformations due to melting and evaporation of the FeAl phase, are analyzed. Phase transformations identified during the DGS process impose the limit of FeAl grain size, which is required to maintain a solid state of aggregation during a collision with the substrate material. The identification of the characteristic time values for particle acceleration in the supersonic gas detonation flux, their convective heating and heat diffusion enable to assess the aggregation state of FeAl particles sprayed into water under certain DGS conditions.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma14237443