Details

Title

Dual Phase Lag Model of Melting Process in Domain of Metal Film Subjected to an External Heat Flux

Journal title

Archives of Foundry Engineering

Yearbook

2016

Issue

No 4

Authors

Keywords

solidification process ; Theoretical basis of foundry processes ; Micro-scale heat transfer ; Dual phase lag model ; Controlvolume method

Divisions of PAS

Nauki Techniczne

Publisher

The Katowice Branch of the Polish Academy of Sciences

Date

2016

Type

Artykuły / Articles

Identifier

DOI: 10.1515/afe-2016-0089 ; eISSN 2299-2944

Source

Archives of Foundry Engineering; 2016; No 4

References

Tang (1999), Wavy wavelike diffusive thermal responses of finite rigid slabs to high - speed heating of laser pulses of Heat and Mass Transfer, International Journal, 42, 855. ; Mochnacki (2007), Application of Thiessen polygons in control volume model of solidification of Achievements of Materials and Manufacturing, Journal Engineering, 23, 75. ; Mochnacki (2010), Numerical modeling of casting solidification using generalized finite difference method, Materials Science Forum, 638. ; Ivanova (2012), Calculation of phase change boundary position in continuous casting of Foundry, Archives Engineering, 13, 57. ; Szopa (2015), Numerical modeling of pure metal solidification using the one domain approach of Applied Mathematics and Computational, Journal Mechanics, 14, 28. ; Majchrzak (2016), Modeling of melting and resolidification in domain of metal film subjected to a laser pulse of Foundry, Archives Engineering, 16, 41. ; Majchrzak (2012), Numerical modeling of melting process of thin metal film subjected to the short laser pulse of Foundry, Archives Engineering, 12, 105. ; Mochnacki (2011), Computational simulations and applications Numerical modeling of solidification process Chapter, INTECH, 24, 513. ; Chen (2004), Nanoscale heat Transfer , Encyclopedia of NanoScience, Nanotechnology, 7, 429. ; Bondarenko (2015), The mathematical model of hydrodynamics and heat and mass transfer at formation of steel ingots and castings of Foundry, Archives Engineering, 15, 13. ; Mochnacki (2015), Micro - scale heat transfer Algorithm basing on the Control Volume Method and the identification of relaxation and thermalization times using the search method Computer Methods in Materials, Science, 15, 353. ; Mochnacki (2012), Definition of alloy substitute thermal capacity using the simple macrosegregation models of Foundry, Archives Engineering, 19, 113. ; Kumar (2010), Mathematical modeling of freezing and thawing process in tissues : a porous media approach, Int J Appl Mechanics, 2, 617, doi.org/10.1142/S1758825110000688
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