[1] [1] Jia Wenpeng, Lin Xin, Chen Jing et al.. Temperature/ stress field numerical simulation of hollow blade produced by laser rapid forming[J]. Chinese J. Lasers, 2007, 34(9):1308～1312

[2] [2] Han Yanfeng, Gao Bo, Hu Jiang et al.. Titanium coping fabricated with laser rapid forming[J]. Chinese Journal of lasers, 2007, 34(6):876～880

[3] [3] Yu Jun, Chen Jing, Tan Hua et al.. Effect of process parameters in the laser rapid forming on deposition layer[J]. Chinese J. Lasers, 2007, 34(7): 1014～1018.

[4] [4] Zhu Juanfang, Gao Bo, Wang Zhongyi et al.. Properties of pure titanium for dental implants fabricated by rapid laser forming[J]. Chinese J. Lasers, 2007, 34(4):588～592

[5] [5] Huang Weidong, Lin Xin, Chen Jing et al.. Laser Solid Forming Technology[M]. Xi′an: Northwestern Polytechnical University Press, 2007. 1～20, 340

[6] [6] Takeda T., Steen W. M., West D. R. F.. Laser cladding with mixed powder feed [C]. Proc. ICALEO 1984. Boston, USA: Laser Institute of America. 1984, 44:151

[7] [7] Steen W. M., Vilar R. M., Watkins K. G. et al.. Alloy system analysis by laser cladding[C]. Proc. ICALEO ′92. Orlando: Laser Institute of America. 1992, 52: 278～287

[8] [8] Watkins K. G.. Achieving the potential of direct fabrication with lasers[C]. Proc. Fourth Laser Assisted Net Shape Engineering, LANE 2001. Erlangen(Germany). 2001. 25～38

[9] [9] Banerjee R., Collins P. C., Bhattacharyya D. et al.. Microstructural evolution in laser deposited compositionally graded α/β titanium-vanadium alloys[J]. Acta Materialia, 2003, 51: 3277～3292

[10] [10] Collins P. C., Banerjee R., Banerjee S. et al.. Laser deposition of compositionally graded titanium-vanadium and titanium-molybdenum alloys[J]. Materials Science and Engineering A, 2003, 352: 118～128

[11] [11] Banerjee R., Bhattacharyya D., Collins P. C. et al.. Precipitation of grain boundary \a in a laser deposited compositionally graded Ti-8Al-xV alloy-an orientation microscopy study[J]. Acta Materialia, 2004,52: 377～385

[12] [12] Banerjee R., Collins P. C., Genc A. et al.. Direct laser deposition of in situ Ti-6Al-4V-TiB composites[J]. Material Science and Engineering A, 2003, 358: 343～349

[13] [13] Banerjee R, Genc A, Hill D et al.. Nanoscale TiB precipitates in laser deposited Ti-matrix composites[J]. Scripta Materialia, 2005,53: 1433～1437

[14] [14] Nag S, Banerjee R, Fraser H L. A novel combinatorial approach for understanding microstructural evolution and its relationship to mechanical properties in metallic biomaterials[J]. Acta Biomaterialia, 2007, 3: 369～376

[15] [15] X. Lin, T. M. Yue, H. O. Yang et al.. Solidification behavior and the evolution of phase in laser rapid forming of graded Ti6Al4V-Rene88DT alloy[J]. Metall Mater Trans A, 2007, 38A: 127～137

[16] [16] Xin Lin, Haiou Yang, Jing Chen et al.. Microstructural evolution in laser rapid forming of a graded titanium-nickel alloy\[C\]. ICALEO 2007 Congress Proceedings, 197～199

[17] [17] X. Lin, T. M. Yue, H. O. Yang et al.. Microstructure and phase evolution in laser rapid forming of a functionally graded Ti-Rene88DT alloy[J]. Acta Mater, 2006,54: 1901～1915

[18] [18] Jing Chen, Haiou Yang, Xin Lin et al.. Influences of powder specifications and powder delivery on laser and powder particles interaction during the LRF process\[C\]. SPIE, 2005,5629: 103～113

[19] [19] Jehnming Lin. Temperature analysis of the powder streams in coaxial laser cladding[J]. Optics & Laser Technology, 1999, 31: 565～570

[20] [20] Kong Long. Two-Phase Fluid Dynamics[M]. Bijing: Higher Education Press, 2004. 118～119

[21] [21] Ma Qingfang, Fang Rongsheng. Practical Handbook of Physical Properties[M]. Agricultural Machinery Press of China,1986.69～76