Acta Metall Sin  1998, Vol. 34 Issue (2): 211-215    DOI:

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IMPROVEMENT OF SHORT-FIBRE REINFORCED COMPOSITE MATERIALS WITH WEAK INTERFACE

SUN Xuekun;ZHOU Benlian;WANG Guodong (Institate of Metal Research; The Chinese Academy of Sciences; Shenyang 110015)(International Centre for Materials Physics; Institute of Metal Research; The Chinese Academy of Sciences;Shenyang 110015)(State Key Laboratory of Rolling and Automation; Northeastern University; Shenyang 110006)

SUN Xuekun;ZHOU Benlian;WANG Guodong (Institate of Metal Research; The Chinese Academy of Sciences; Shenyang 110015)(International Centre for Materials Physics; Institute of Metal Research; The Chinese Academy of Sciences;Shenyang 110015)(State Key Laboratory of Rolling and Automation; Northeastern University; Shenyang 110006). IMPROVEMENT OF SHORT-FIBRE REINFORCED COMPOSITE MATERIALS WITH WEAK INTERFACE. Acta Metall Sin, 1998, 34(2): 211-215.

Abstract References Related Articles Recommended Metrics Download:  PDF(388KB)  Export:  BibTeX | EndNote (RIS)       Abstract  The improvement of short-fibre reinforced composite materials under weak interface was discussed. Comparison between plain short-fibre model and dumbbell short-fibre model has been done. Effectivity of dumbbell model under different strength ratios of mains to fibre was discussed. born abate element analysis it was concluded that dumbbell model could well improve the performance of composite materials with weak interface. The lower strength ratio of mains to fibre, the better -improvement is. Key words:  short-fibre reinforced composite material      weak interface      finite element      Received:  18 February 1998      Service E-mail this article Add to citation manager E-mail Alert RSS （） Articles by authors URL:  https://www.ams.org.cn/EN/     OR     https://www.ams.org.cn/EN/Y1998/V34/I2/211 1Zhou B L, Shi C X. In: Kong M, Hung L eds, Proceedings of C-MRS Iuter, '90, Amsterdam: Elsevier Science Publishers, 1991: 137 2田晓滨.赵晓鹏周本濂.金属学报,1994;30:180(Tian x B,Zhao X P, Zhou B L. Acta Metall Sci,1994;30: 180) 3赵晓鹏,田晓滨,周本濂.金属学报,1994;30:187(Zhao X P, Tian X B, Zhou B L. Acta Metall Sin, 1994; 30: 187) 4 Fukuda H, Chai T W.J Comp Mater, 1981;15: 79 5 Chon C T, Sun C T.J Mater, Sci 1980; 15: 931 6 Broutman L J,Agarwal B D. Polymer Eng Sci 1974; 14: 581 7 Agarwal B D, Nansal R K. Fibre Sci Tech, 1979; 12: 149 8孙雪坤,郭燕阳,杜善义,林德春.复合材料学报,1997;14:116 (Sun X K, Guo Y Y, Du S Y, Lin D C. Acta Mater. Composite Sin 1997; 14: 116) 9Chang F K,Kutlu Z.J Comp Mater ,1989;23:11 10徐次达,华伯浩.固体力学有限元理论方法及程序,北京:水利电力出版社,1983 (Xu C D, Hua B H. Program and Finite Element Analysis Method of Solid Mechanics , Beijing, Water Conservancy & Elactric Power Publisher, 1983: 130)d [1] ZHANG Lu, YU Zhiwei, ZHANG Leicheng, JIANG Rong, SONG Yingdong. Thermo-Mechanical Fatigue Cycle Damage Mechanism and Numerical Simulation of GH4169 Superalloy[J]. 金属学报, 2023, 59(7): 871-883. [2] LI Shaojie, JIN Jianfeng, SONG Yuhao, WANG Mingtao, TANG Shuai, ZONG Yaping, QIN Gaowu. Multimodal Microstructure of Mg-Gd-Y Alloy Through an Integrated Simulation of “Process-Structure-Property”[J]. 金属学报, 2022, 58(1): 114-128. [3] ZHAO Yuhong, JING Jianhui, CHEN Liwen, XU Fanghong, HOU Hua. Current Research Status of Interface of Ceramic-Metal Laminated Composite Material for Armor Protection[J]. 金属学报, 2021, 57(9): 1107-1125. [4] LI Suo, CHEN Weiqi, HU Long, DENG Dean. Influence of Strain Hardening and Annealing Effect on the Prediction of Welding Residual Stresses in a Thick-Wall 316 Stainless Steel Butt-Welded Pipe Joint[J]. 金属学报, 2021, 57(12): 1653-1666. [5] CHEN Yongjun, BAI Yan, DONG Chuang, XIE Zhiwen, YAN Feng, WU Di. Passivation Behavior on the Surface of Stainless Steel Reinforced by Quasicrystal-Abrasive via Finite Element Simulation[J]. 金属学报, 2020, 56(6): 909-918. [6] WANG Xia, WANG Wei, YANG Guang, WANG Chao, REN Yuhang. Dimensional Effect on Thermo-Mechanical Evolution of Laser Depositing Thin-Walled Structure[J]. 金属学报, 2020, 56(5): 745-752. [7] JIANG Lin, ZHANG Liang, LIU Zhiquan. Effects of Al Interlayer and Ni(V) Transition Layer on the Welding Residual Stress of Co/Al/Cu Sandwich Target Assembly[J]. 金属学报, 2020, 56(10): 1433-1440. [8] Xuexiong LI,Dongsheng XU,Rui YANG. Crystal Plasticity Finite Element Method Investigation of the High Temperature Deformation Consistency in Dual-Phase Titanium Alloy[J]. 金属学报, 2019, 55(7): 928-938. [9] MA Rongyao, MU Xin, LIU Bo, WANG Changgang, WEI Xin, ZHAO Lin, DONG Junhua, KE Wei. Effect of Hydrostatic Pressure on Corrosion Behavior of Ultra Pure Al Coupled with Ultra Pure Fe[J]. 金属学报, 2019, 55(12): 1593-1605. [10] MA Kai, ZHANG Xingxing, WANG Dong, WANG Quanzhao, LIU Zhenyu, XIAO Bolv, MA Zongyi. Optimization and Simulation of Deformation Parameters of SiC/2009Al Composites[J]. 金属学报, 2019, 55(10): 1329-1337. [11] Shu WEN, Anping DONG, Yanling LU, Guoliang ZHU, Da SHU, Baode SUN. Finite Element Simulation of the Temperature Field and Residual Stress in GH536 Superalloy Treated by Selective Laser Melting[J]. 金属学报, 2018, 54(3): 393-403. [12] Jialin LIU, Yumin WANG, Guoxing ZHANG, Xu ZHANG, Lina YANG, Qing YANG, Rui YANG. Research on Single SiC Fiber Reinforced TC17 CompositesUnder Transverse Tension[J]. 金属学报, 2018, 54(12): 1809-1817. [13] Yu LIU, Shengwei QIN, Xunwei ZUO, Nailu CHEN, Yonghua RONG. Finite Element Simulation and Experimental Verification of Quenching Stress in Fully Through-Hardened Cylinders[J]. 金属学报, 2017, 53(6): 733-742. [14] Shu GUO,En-Hou HAN,Haitao WANG,Zhiming ZHANG,Jianqiu WANG. Life Prediction for Stress Corrosion Behavior of 316L Stainless Steel Elbow of Nuclear Power Plant[J]. 金属学报, 2017, 53(4): 455-464. [15] Li ZHOU,Chao CUI,Qing JIA,Yingshi MA. Experimental and Finite Element Simulation of Milling Process for γ-TiAl Intermetallics[J]. 金属学报, 2017, 53(4): 505-512. No Suggested Reading articles found! Viewed Full text Abstract Cited   Shared      Discussed