相关参考文献
注意:仅列出部分参考文献,下载原文获取全部文献信息。A three-dimensional cellular automaton model of dendrite growth with stochastic orientation during the solidification in the molten pool of binary alloy
C. Gu et al.
SCIENCE AND TECHNOLOGY OF WELDING AND JOINING (2017)
Lattice Boltzmann modeling of bubble formation and dendritic growth in solidification of binary alloys
Dongke Sun et al.
INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER (2016)
Multi-scale simulation of directional dendrites growth in superalloys
Hang Zhang et al.
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY (2016)
Numerical Simulation of Three-Dimensional Dendritic Growth of Alloy: Part II-Model Application to Fe-0.82WtPctC Alloy
Weiling Wang et al.
METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE (2016)
Numerical Simulation of Three-Dimensional Dendritic Growth of Alloy: Part I-Model Development and Test
Weiling Wang et al.
METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE (2016)
Growth competition of columnar dendritic grains: A phase-field study
D. Tourret et al.
ACTA MATERIALIA (2015)
Multi-scale modeling of solidification and microstructure development in laser keyhole welding process for austenitic stainless steel
Wenda Tan et al.
COMPUTATIONAL MATERIALS SCIENCE (2015)
In situ synchrotron X-ray studies of the coupled effects of thermal and solutal supercoolings on the instability of dendrite growth
Faguo Li et al.
MATERIALS CHARACTERIZATION (2015)
Cellular Automaton Modeling of Microporosity Formation during Solidification of Aluminum Alloys
Mingfang Zhu et al.
ISIJ INTERNATIONAL (2014)
Porosity formation mechanism and its prevention in laser lap welding for T-joints
Wei Meng et al.
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY (2014)
Virtual front tracking cellular automaton modeling of isothermal β to α phase transformation with crystallography preferred orientation of TA15 alloy
K. J. Song et al.
MODELLING AND SIMULATION IN MATERIALS SCIENCE AND ENGINEERING (2014)
Phase-Field Simulation of Concentration and Temperature Distribution During Dendritic Growth in a Forced Liquid Metal Flow
Lifei Du et al.
METALLURGICAL AND MATERIALS TRANSACTIONS B-PROCESS METALLURGY AND MATERIALS PROCESSING SCIENCE (2014)
Influence of CO2-Ar Mixtures as Shielding Gas on Laser Welding of Al-Mg Alloys
Zouhair Boukha et al.
METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE (2013)
Double-sided fiber laser beam welding process of T-joints for aluminum aircraft fuselage panels: Filler wire melting behavior, process stability, and their effects on porosity defects
Wang Tao et al.
OPTICS AND LASER TECHNOLOGY (2013)
On the mechanism of porosity formation during welding of titanium alloys
Jianglin L. Huang et al.
ACTA MATERIALIA (2012)
A three-dimensional sharp interface model for the quantitative simulation of solutal dendritic growth
Shiyan Pan et al.
ACTA MATERIALIA (2010)
An X-ray microtomographic and finite element modeling approach for the prediction of semi-solid deformation behaviour in Al-Cu alloys
D. Fuloria et al.
ACTA MATERIALIA (2009)
Columnar grain growth pattern with fluid flowing in molten pool
Rui Ma et al.
CRYSTAL RESEARCH AND TECHNOLOGY (2009)
Simulation of grain morphologies and competitive growth in weld pool of Ni-Cr alloy
X. H. Zhan et al.
JOURNAL OF CRYSTAL GROWTH (2009)
Hydrogen, porosity and oxide film defects in liquid Al
W. D. Griffiths et al.
JOURNAL OF MATERIALS SCIENCE (2009)
Cellular automaton simulation of grain growth with different orientation angles during solidification process
Xiaohong Zhan et al.
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY (2008)
Simulation of the columnar-to-equiaxed transition in directionally solidified Al-Cu alloys
HB Dong et al.
ACTA MATERIALIA (2005)
Mechanism of nucleation and growth of hydrogen porosity in solidifying A356 aluminum alloy: an analytical solution
KD Li et al.
ACTA MATERIALIA (2004)
Simulation of the three-dimensional morphology of solidification porosity in an aluminium-silicon alloy
RC Atwood et al.
ACTA MATERIALIA (2003)