激波对电场辅助冷喷涂纳米粒子速度的影响

材料热处理学报, 2012, 33(11): 153-157.

激波对电场辅助冷喷涂纳米粒子速度的影响

唐文勇 ^1, , 陈清华 ^2, , 柴伟伟 ^3, , 陈子云 ^4, , 张学清 ^5, , 贺志强 ^6,

1.重庆大学低品位能源利用技术及系统教育部重点实验室,重庆400030 重庆大学动力工程学院,重庆400030

2.重庆大学低品位能源利用技术及系统教育部重点实验室,重庆400030 重庆大学动力工程学院,重庆400030

3.重庆大学低品位能源利用技术及系统教育部重点实验室,重庆400030 重庆大学动力工程学院,重庆400030

4.重庆大学低品位能源利用技术及系统教育部重点实验室,重庆400030 重庆大学动力工程学院,重庆400030

5.重庆大学低品位能源利用技术及系统教育部重点实验室,重庆400030 重庆大学动力工程学院,重庆400030

6.重庆大学低品位能源利用技术及系统教育部重点实验室,重庆400030 重庆大学动力工程学院,重庆400030

基金项目: 国家自然科学基金资助项目(50276073) 重庆市自然科学基金(CSTC,2011BB4074)

关键词：冷喷涂 , 电场辅助加速 , 激波 , 纳米粒子 , 数值模拟

Effects of shock wave on velocity of nano-particles in electrostatic-force assisted cold spraying

Keywords： cold spraying , electrostatic-force assisted acceleration , shock wave , nano particle , numerical simulation

通过建立二维数值分析模型,分析了不同进气温度及压力时,带电纳米粒子在激波和电场力耦合作用下的加速特性以及对粒子撞击基板速度的影响。结果表明：弓形激波气体压缩层是造成纳米粒子减速的主要因素,弓形激波气体压缩层越薄粒子撞击基板时速度越大;外加电场时,带电纳米粒子撞击基板的速度得到较大提升。

The numerical simulation using an established two-dimensional(2D) numerical model was performed to analyze the effects of the bow shock coupled with electrostatic field on the acceleration of charged particles and the particle impact speed at different inlet nitrogen temperatures and pressures.The results show that the compression layer in the bow shock is a major factor for slowing down nano and submicron particles.And the thinner the compression layer in bow shock is the higher the particle impact speed is.The particle impact speed can be improved significantly by applying the electrostatic force on the charged nano and submicron particles.

参考文献

[1]	徐滨士.纳米表面工程[M].北京:化学工业出版社,2004:35-40.
[2]	Eidelman S;Yang X L .Three dimensional simulation of HVOF spray deposition of nanoscale materials[J].Nano-Structured Materials,1997,9(1-8):79-84.
[3]	Kim J;Yang H;Baik K et al.Development and properties of nanostructured thermal spray coatings[J].Current Applied Physics,2006,6(06):1002-1006.
[4]	Pavitra Bansal;Nitin P. Padture;Alexandre Vasiliev .Improved interfacial mechanical properties of Al_2O_3-13 wt percent TiO_2 plasma- sprayed coatings derived from nanocrystalline powders[J].Acta materialia,2003(10):2959-2970.
[5]	Eric Irissou;Jean-Gabriel Legoux;Anatoly N. Ryabinin;Bertrand Jodoin;Christian Moreau .Review on Cold Spray Process and Technology: Part I - Intellectual Property[J].Journal of Thermal Spray Technology,2008(4):495-516.
[6]	Champagne V K.The Cold Spray Materials Deposition Process:Fundamentals and Applications[M].Cambridge:Woodhead Publishing Limited,2007:16-19.
[7]	Papyrin A;Kosarev V;Klinkov S.Cold Spray Technology[M].Amsterdam:Elsevier Science,2007:29-34.
[8]	Maev R G;Leshchinsky V.Introduction to Low Pressure Gas Dynamic Spray:Physics & Technology[M].Weinheim:Wiley-VCH Verlag GmbH,2008:22-35.
[9]	Alkhimov A P;Klinkov S V;Kosarev V F et al.Gas-dynamic spraying study of a plane supersonic two-phase jet[J].Journal of Applied Mechanics and Technical Physics,1997,38(02):324-330.
[10]	Alkhimov A P;Kosarev V F;Klinkov S V .The features of cold spray nozzle design[J].Journal of Thermal Spray Technology,2001,10(02):375-381.
[11]	Pattison J;Celotto S;Khan A;O'Neill W .Standoff distance and bow shock phenomena in the Cold Spray process[J].Surface & Coatings Technology,2008(8):1443-1454.
[12]	Tien-Chien Jen;Longjian Li;Wenzhi Cui;Qinghua Chen;Xinming Zhang .Numerical investigations on cold gas dynamic spray process with nano- and microsize particles[J].International Journal of Heat and Mass Transfer,2005(21/22):4384-4396.
[13]	LEONARDO AJDELSZTAJN;BERTRAND JODOIN;GEORGE E. KIM .Cold Spray Deposition of Nanocrystalline Aluminum Alloys[J].Metallurgical and Materials Transactions, A. Physical Metallurgy and Materials Science,2005(3):657-666.
[14]	Kiz M M;Byakova A V;Sirko A I et al.Cold spray coatings of A1-Fe-Cr alloy reinforced by nano-sized quasicrystalline particles[J].Ukrainian Journal of Physics,2009,54(06):594-599.
[15]	Dominique Poirier;Jean-Gabriel Legoux;Robin A. L. Drew;Raynald Gauvin .Consolidation of Al_2O_3/Al Nanocomposite Powder by Cold Spray[J].Journal of Thermal Spray Technology,2011(1/2):275-284.
[16]	Tien-Chien Jen;Liangming Pan;Longjian Li;Qinghua Chen;Wenzhi Cui .The acceleration of charged nano-particles in gas stream of supersonic De-Lavel-type nozzle coupled with static electric field[J].Applied thermal engineering: Design, processes, equipment, economics,2007(17-18):2877-2885.
[17]	Kim H J;Lee C H;Hwang S Y .Superhard nano WC-12% Co coating by cold spray deposition[J].Materials Science and Engineering A,2005,391(1-2):243-248.
[18]	Hidemasa Takana;Kazuhiro Ogawa;Tetsuo Shoji;Hideya Nishiyama .Computational Simulation on Performance Enhancement of Cold Gas Dynamic Spray Processes With Electrostatic Assist[J].Journal of Fluids Engineering: Transactions of the ASME,2008(8):081701-1-081701-7-0.
[19]	Hidemasa Takana;Kazuhiro Ogawa;Tetsuo Shoji .Computational simulation of cold spray process assisted by electrostatic force[J].Powder Technology: An International Journal on the Science and Technology of Wet and Dry Particulate Systems,2008(2):116-123.
[20]	Yakhot V;Orszag S A .Renormalization group analysis of turbulence(I)basic theory[J].Journal of Scientific Computing,1986,1(01):3-51.
[21]	Hamid Assadi;Frank Gartner;Thorsten Stoltenhoff .Bonding mechanism in cold gas spraying[J].Acta materialia,2003(15):4379-4394.

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