Experimental Study on Igniting Self-propagating High-temperature Synthesis by Laser
CHEN Senchang, SHI Yusheng, HUANG Shuhuai. Experimental Study on Igniting Self-propagating High-temperature Synthesis by Laser[J]. Chinese Journal of Lasers B, 2002, 11(1): 66.
CHEN Senchang, SHI Yusheng, HUANG Shuhuai. Experimental Study on Igniting Self-propagating High-temperature Synthesis by Laser[J]. 中国激光(英文版), 2002, 11(1): 66.
[1] Liang Shuqan, Zheng Zijiao. The synthesis of materials by self-propagating-combustion method. Journal of The Chinese Ceramic Society, 1993, 21(3):261~271 (in Chinese)
[2] Yan Xinyan, Sun Guoxiong, Zhang Shuge. Developments and application of SHS process. Materials for Mechanical Engineering, 1995, 19(5):1~5 (in Chinese)
[3] Yin Sheng, Lai Heyi. Development in self-propagating high-temperature synthesis (SHS). Powder Metallurgy Technology, 1992, 10(3):223~227 (in Chinese)
[4] Fu Zhengyi, Wang Weiming, Yuan Runzhang. Ignition process model and analysis of self-propagating high-temperature synthesis. Journal of The Chinese Ceramic Society, 1994, 22(5):447~452 (in Chinese)
[5] Duan Huiping, Yin Sheng, Lai Heyi. Reactive characteristics of multi-component thermit. Journal of University of Science and Technology Bejing, 1997, 19(1):109~116 (in Chinese)
[6] Zhao Kunyu, Zhu Xinkun, Zhang Jiaqi. Production TiB2 by self-propagating high-temperature synthesis. Powder Metallurgy Technology, 1997, 15(1):26~28 (in Chinese)
[7] Atong D., Clark D. E.. Microwave-induced combustion synthesis of TiC-Al2O3 composites. Ceram. Eng. and Sc. Proceedings, 1999, 20(3):111~118
[8] Xu Gengfu, Zhang Hanrui, Li Wenlan et al.. Microwave sintering of SHS-prepared β-sialon powders with Y2O3 as additive. Acta Electronica Sinica, 1998, 26(5):79~82
[9] A. P. Amosov, B. S. Seplyarskii, K. Yu. Voronin et al.. SHS mixture ignition at adiabatic. Int. J. of SHS, 1994, 3(3):253~260
[10] Keizo Kobayashi, Akihro Matsumoto, Kimihiro Ozaki et al.. Pulsed current sintering of mechanically alloyed Ni-Ti powder. J. Japan Inst. Material, 1999, 63(9):1161~1164 (in Japanese)
[11] A. G. Makarenko, A. L. Petrov, I. V. Shishkovsky. Direct SLS of powder compositions used for super high-temperature synthesis. In 8th Inter. Symp. ‘Solid Free-Form Fabrication’, Austin, Texas, USA., August, 11~13, 1997
[12] V. M. Filatov, YU. S. Naiborodenko. Ignition and development of a chemical reaction of titanium and carbon under shock loading. Int. J. of SHS, 1992, 1(3):343~347
[13] A. A. Zhukov, J. Dutta Ma Jumdar, I. Manna. Surface treatment by laser-melting induced self-propagating high-temperature synthesis. Journal of Material Science Letters, 1995, 14(11):828~829
[14] Geng Jianfen, Li Hailin, Wu Dongdi. Structures and property analysis of ceramic coating produced by SHS RFA process. Journal of East China University of Science and Technology, 1997, 23(2):228~231
[15] V. I. Itin,V. N. Hachin. Izvestia Vuzon. Fizika. Structure and properties of NiTi materials obtained with use of self-propagated high-temperature synthesis. Izvestia vuzov, 1997, 2:117~120 (in Russian)
[16] Gureev D. M., Petrov A. L., Shishkovsky I. V.. Formation of intermetallic phases under laser sintering of powdered SHS compositions. In 6th International Conference on Industrial Lasers and Laser Applications, Shatura, RUS, Jun 27~ 29, 1998. 273~242
CHEN Senchang, SHI Yusheng, HUANG Shuhuai. Experimental Study on Igniting Self-propagating High-temperature Synthesis by Laser[J]. Chinese Journal of Lasers B, 2002, 11(1): 66. CHEN Senchang, SHI Yusheng, HUANG Shuhuai. Experimental Study on Igniting Self-propagating High-temperature Synthesis by Laser[J]. 中国激光(英文版), 2002, 11(1): 66.
PDF全文
