Theoretical and Experimental Investigation of Gas Flows, Powder Transport and Heating in Coaxial Laser Direct Metal Deposition (DMD) Process

被引:0
作者
O. B. Kovalev
A. V. Zaitsev
D. Novichenko
I. Smurov
机构
[1] Khristianovich Institute of Theoretical and Applied Mechanics,
[2] Siberian Branch of Russian Academy of Sciences,undefined
[3] Ecole Nationale d’Ingénieurs de Saint-Etienne (ENISE),undefined
[4] DIPI Laboratory,undefined
来源
Journal of Thermal Spray Technology | 2011年 / 20卷
关键词
collision of particles against a wall; direct metal deposition; gas flow with particles; laser cladding; mathematical and numerical simulation; metal powder; particle flux focusing; triple coaxial nozzle;
D O I
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中图分类号
学科分类号
摘要
The results of theoretical and experimental investigations of direct metal deposition (DMD) processes involving a CO2-laser with the power up to 5 kW and wave length of 10.6 μm are presented. The physical and mathematical model of multi-layer gas flows with gas-jet transportation of metal powder particles has been developed. To simulate the flows of carrier and shaping gases in annular channels of a triple coaxial nozzle, Navier-Stokes equations were applied for an axisymmetric flow. Thermodynamics and powder particles transport are calculated from a discrete-trajectory model with due regard to particle collision with solid walls of the transport nozzle. It is shown that particles may overheat on their way between the nozzle and substrate; the overheating depends on the trajectories by which particles move, on their size, and time of their retention in the laser-radiation region. The results of performed experimental researches on DMD processes visualization are presented. Some results of numerical simulation and experimental data are compared and analyzed.
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页码:465 / 478
页数:13
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