Microstructure of Al-5Ti-1B-1RE nanoribbon and its refining efficiency on as-cast A356 alloys 被引量：11

Microstructure of Al-5Ti-1B-1RE nanoribbon and its refining efficiency on as-cast A356 alloys

导出

摘要 The novel A1-5Ti-IB-1RE nanoribbons were synthesized by melt-spinning. The microstructure showed that the A1-5Ti- 1B-1RE nanoribbon consisted of granular-like TiB2 and core-shell-like TiA13/Ti2A120Ce. The A1-5Ti-IB-1RE nanoribbon could give rise to the excellent refining effect on as-cast A356 alloys. The refining efficiency and formation mechanism of A1-5Ti-IB-IRE nanoribbons were investigated. In accordance with the experimental results, it could be seen that the A1-5Ti-IB-1RE nanoribbon could maintain the refining effect after 60 min of holding. Additionally, owing to the addition of A1-5Ti-IB-1RE nanoribbon, the mechanical properties of A356 alloys could be enhanced significantly. The novel A1-5Ti-IB-1RE nanoribbons were synthesized by melt-spinning. The microstructure showed that the A1-5Ti- 1B-1RE nanoribbon consisted of granular-like TiB2 and core-shell-like TiA13/Ti2A120Ce. The A1-5Ti-IB-1RE nanoribbon could give rise to the excellent refining effect on as-cast A356 alloys. The refining efficiency and formation mechanism of A1-5Ti-IB-IRE nanoribbons were investigated. In accordance with the experimental results, it could be seen that the A1-5Ti-IB-1RE nanoribbon could maintain the refining effect after 60 min of holding. Additionally, owing to the addition of A1-5Ti-IB-1RE nanoribbon, the mechanical properties of A356 alloys could be enhanced significantly.

作者王奎崔春翔王倩赵立臣胡源

机构地区 Key Laboratory for New Type of Functional Materials in Hebei Province

出处《Journal of Rare Earths》 SCIE EI CAS CSCD 2013年第3期313-318,共6页 稀土学报（英文版）

基金 Project supported by National Science and Technology Program-International Collaborative Research Project (2010DFA51920)

关键词 MELT-SPINNING NANORIBBON refining effect rare earths melt-spinning nanoribbon refining effect rare earths

分类号 TG136.1 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献13

1Zalensas D L, Ed. Aluminum Casting Technology, 2nd Ed. Des Plaines: AFS Inc, 1993.
2Liao B C, Park Y K, Ding H S. Effects of rheocasting and heat treatment on microstructure and mechanical proper- ties of A356 alloy. Mater. Sci. Eng. A, 2011,528: 986.
3Wang K, Cui C X, Wang Q, Qi Y M, Wang C. Fabrication of in situ AlN-TiN/Al inoculant and its refining efficiency and reinforcing effect on pure aluminum. J. Alloys Compd., 2013, 547: 5.
4Li P T, Tian W J, Wang D, Liu X F. Grain refining po- tency of LaB6 on aluminum alloy. J. Rare Earths, 2012, 30: 1172.
5Wang T M, Fu H W, Chen Z N, Xu J, Zhu J, Cao F, Li T J.A novel fading-resistant Al-3Ti-3B grain refiner for Al-Si alloys. J. Alloys Compd., 2012, 511: 45.
6Zhao H L, Song Y, Li M, Guan S K. Grain refining effi- ciency and microstructure of Al-Ti-C-RE master alloy. J. Alloys Compd., 2010, 508: 206.
7Cornish L A, Witcomb M J. An investigation of the Al-Re phase diagram. J. Alloys Compd., 1999, 291:117.
8John C, Slattery S, Lee J. Analysis of melt spinning. Non- Newton Fluid Mech., 2000, 89: 273.
9Van der Ven A, Wagemaker M. Effect of surface energies and nano-particle size distribution on open circuit voltage of Li-electrodes. Electrochem. Commun., 2009, 11: 881.
10Greer A L, Bunn A M, Tronche A, Evans P V, Bristow D J Modelling of inoculation of metallic melts application to grain refinement of aluminium by Al-Ti-B. Acta Mater., 2000, 48: 2823.

同被引文献135

1蔡建国.ZL104热处理工艺探讨[J].航天工艺,1994(3):24-27. 被引量：4
2陈祥,耿慧远,李言祥.亚共晶Al-Si合金变质级别的定量金相分析[J].金属学报,2005,41(8):891-896. 被引量：8
3朱兆军,王宏伟,魏尊杰.Al-5Ti-1B对A357合金晶粒细化作用的研究[J].材料科学与工艺,2006,14(2):171-173. 被引量：8
4周洁,白杉.铝合金轮毂的市场、特点和制造工艺[J].铝加工,2006,29(3):43-44. 被引量：17
5王正军,刘天佐,王晓军,夏天东,赵文军.Al-10Ce中间合金对α铝变质的长效性及其重熔稳定性[J].有色金属,2006,58(3):10-12. 被引量：9
6李克,饶磊,闫洪,王俊,孙宝德.快速凝固处理对Al-Ti-B中间合金组织和细化效果的影响[J].铸造,2006,55(9):894-897. 被引量：9
7陈祥,耿慧远,李言祥.B,Sr联合处理Al-7Si合金及细化变质效果评估[J].金属学报,2006,42(11):1130-1136. 被引量：5
8陈亚军,许庆彦,黄天佑.铝合金晶粒细化剂研究进展[J].材料导报,2006,20(12):57-61. 被引量：40
9邹亮,潘清林,何运斌,王昌臻,梁文杰.Effect of minor Sc and Zr addition on microstructures and mechanical properties of Al-Zn-Mg-Cu alloys[J].中国有色金属学会会刊：英文版,2007,17(2):340-345. 被引量：31
10陈亚军,许庆彦,黄天佑.稀土对铝钛硼中间合金组织及细化性能的影响[J].清华大学学报（自然科学版）,2007,47(5):618-622. 被引量：15

引证文献11

1刘璐宁,陈刚,赵玉涛,李玉麟,王金凤.Al-Ti-B-O复合细化剂对A356合金组织及力学性能的影响[J].热加工工艺,2016,45(21):52-55.
2何兵,覃铭,李德贵,覃乃领.固溶时间对含钪A356铝合金组织与力学性能的影响[J].金属热处理,2018,43(3):185-189. 被引量：1
3于小健,宁萌,刘书明,张献,浦晨晔,卢雅琳.T6热处理工艺对Al-7Si-0.3Mg-0.3Y合金组织和性能的影响[J].有色金属工程,2018,8(2):1-5. 被引量：1
4缪欢,阎峰云,陈体军,刘洪军.Al-Ti-B晶粒细化剂的研究进展[J].中国铸造装备与技术,2018,53(4):11-16. 被引量：1
5许萍,翟景宇,刘慧敏,张瑞英.稀土La2O3对Al2O3/Cu复合材料组织和显微硬度及导电性能影响[J].内蒙古工业大学学报（自然科学版）,2019,38(5):345-348.
6付原科,杜义涵,段红阳,韩维超,周强,李瑞雪.变质温度对ZL114合金铸态显微组织和力学性能的影响[J].机械工程师,2020(11):30-33. 被引量：1
7王正军,张满,张秋阳,吕建强.复合细化变质多元铝硅合金的强化机制[J].稀有金属材料与工程,2020,49(10):3402-3411. 被引量：3
8陈志强,贾锦玉,胡文鑫,王玮,刘峰.铝合金稀土复合细化剂的研究进展[J].材料导报,2020,34(S02):365-370. 被引量：4
9付原科,杜义涵,段红阳,韩维超,周强.稀土Ce对ZL114合金的细化变质[J].哈尔滨理工大学学报,2021,26(4):14-19. 被引量：3
10丁万武,苟璐珉.新型Al-Ti-La中间合金对亚共晶Al-7Si合金显微组织和力学性能的影响[J].有色金属工程,2022,12(11):7-14. 被引量：1

二级引证文献15

1王建刚,高士友,陈旭升,张梦雨.激光重熔A356铝合金表面的力学性能[J].中国激光,2020,47(4):64-73. 被引量：16
2韩纪层,何建,林德源,邵艳群,郑跃胜.某变电站电容式电压互感器附件L型接线板的断裂原因[J].机械工程材料,2020,44(7):98-102. 被引量：1
3刘亚,刘亚玲,彭浩平,涂浩,王建华,苏旭平.Al-3B变质对铸造Al-10Si合金显微组织与力学性能的影响[J].稀有金属,2021,45(2):154-162. 被引量：4
4崔晓明,孟闯,石博,白朴存,杜赵新,赵学平,王慧新.Al-Si-Mg-Sc铸造合金微观组织演变及其细化变质机制[J].稀有金属材料与工程,2022,51(7):2529-2535. 被引量：6
5李春晖,黄新忠,何平,李炜,龚子杰,李晓宇,刘润芳.稀土Sc、La对ZL205A合金铸态组织和时效行为的影响[J].精密成形工程,2022,14(9):92-96. 被引量：1
6陈晖,周烨,曾敏,杜丘美,胡文华.混合稀土(Pr+Ce)变质处理ZL105铝合金摩擦磨损性能研究[J].稀有金属与硬质合金,2022,50(4):71-76. 被引量：3
7张艺杰,杜景红,吉全鑫,孙彦华,冯伟光,包崇军,李玉章,严继康.Sr和Y添加对A356铝合金显微组织和力学性能的影响及机理[J].稀有金属材料与工程,2022,51(10):3588-3595. 被引量：1
8李召华,许永春.某型飞机ZL114A铝合金支架断裂失效分析[J].铸造,2023,72(4):443-446.
9曾扬帆,芦刚,陈义斯,朱伟明,毛蒲,涂志新,严青松.Ce变质与牵引速度对定向凝固ZL114A合金组织与性能的影响[J].特种铸造及有色合金,2023,43(5):682-689.
10谭国寅.固溶时效处理对2A14铝合金冲击性能的影响[J].金属热处理,2023,48(9):126-128.

1罗成,熊翔,董仕节.电火花沉积法在铜电极表面制备TiB_2/Ni涂层(英文)[J].Transactions of Nonferrous Metals Society of China,2011,21(2):317-321. 被引量：13
2贾宝平,贺跃辉.TiB_2表面渗层材料的研究和应用现状[J].材料导报,2004,18(6):29-31. 被引量：5
3尉法兵,刘海云,孟庆森,王皇,陈少平.TiB2强化高硬度高耐磨堆焊自保护药芯焊丝堆焊层性能分析[J].焊接学报,2013,34(3):97-101. 被引量：4
4章桥新,毛天尔,汪声瑞.TiB_2基烧结材料的研究现状与进展[J].材料科学与工程,1993,11(4):43-46. 被引量：5
5沈明,李群华,王零森,高荣根.Ti_3Al和Ti+Al在TiB_2—Fe系陶瓷中的反应机理研究和比较[J].硬质合金,2002,19(1):6-9.
6邵周俊.TiB2金属陶瓷—一种新的耐磨涂层[J].国外金属加工,1991(2):35-36.
7Qin Bai,Yan-fei Hao,Jiao Wang,Hua Man,Yong-jun Tang,Hui Xu,Shuang Xia.Effect of cooling rate on the magnetic properties of Fe_(53)Nd_(37)Al_(10) alloy[J].International Journal of Minerals,Metallurgy and Materials,2013,20(5):440-444.
8高荣根.二硼化钛基金属陶瓷的开发与应用[J].硬质合金,1998,15(4):235-240. 被引量：16
9杨红旺,佟伟平,赵骧,左良,王建强.Observation of β-Relaxation in Sub-T9 Isothermally Annealed Al-Based Metallic Glasses[J].Chinese Physics Letters,2008,25(9):3357-3359.
10Zhu Man,Yang Gencang,Yao Lijuan,Cheng Suling,Zhou Yaohe.Influence of Al-Ti-B addition on the microstructure and mechanical properties of A356 alloys[J].Rare Metals,2009,28(2):181-186. 被引量：12

Journal of Rare Earths

2013年第3期

浏览历史

内容加载中请稍等...

Microstructure of Al-5Ti-1B-1RE nanoribbon and its refining efficiency on as-cast A356 alloys 被引量：11

参考文献13

同被引文献135

引证文献11

二级引证文献15

相关作者

相关机构

相关主题

浏览历史