Title :
Numerical simulation of gas-particle two phase flow in Aluminum-oxide ceramics powder spraying process
Author :
Liu, Chuanshao ; Chen, Song ; Zheng, Jianxin
Author_Institution :
Sch. of Mech. & Power Eng., Henan Polytech. Univ., Jiaozuo, China
Abstract :
The quality of spraying is influenced by the gas velocity and particle velocity in the cold spraying process. A physical model for supersonic gas-particle two phase flow in cold spraying process is established. Numerical simulation for inlet and outlet flow field of Laval nozzle is carried out. The effects of throat diameter, spraying pressure, temperature and particle size on the gas velocity and particle velocity are investigated. The simulation results show that the gas velocity and particle velocity increase with the increment of spraying pressure and temperature, and the smaller throat diameter, the better gas acceleration in the nozzle, while the particle velocity increases when particle diameter decreases.
Keywords :
ceramics; cold working; intake systems (machines); nozzles; numerical analysis; particle velocity analysis; powder technology; pressure; spray coating techniques; supersonic flow; temperature; two-phase flow; Laval nozzle; aluminum-oxide ceramics powder spraying process; cold spraying process; gas acceleration; gas velocity; inlet flow field; numerical simulation; outlet flow field; particle size; particle velocity; physical model; spraying pressure; supersonic gas-particle two phase flow; temperature; throat diameter; Ceramics; Equations; Mathematical model; Numerical simulation; Resistance; Spraying; Temperature; cold spraying; gas-particle two phase flow; numerical simulation;
Conference_Titel :
Consumer Electronics, Communications and Networks (CECNet), 2011 International Conference on
Conference_Location :
XianNing
Print_ISBN :
978-1-61284-458-9
DOI :
10.1109/CECNET.2011.5768755
