非连续增强铝基复合材料的热变形行为研究进展

doi:10.11900/0412.1961.2018.00461

金属学报

2019, Vol. 55

Issue (1): 59-72 DOI: 10.11900/0412.1961.2018.00461

本期目录 | 过刊浏览

非连续增强铝基复合材料的热变形行为研究进展

肖伯律(

), 黄治冶, 马凯, 张星星, 马宗义

中国科学院金属研究所沈阳材料科学国家研究中心沈阳 110016

Research on Hot Deformation Behaviors of Discontinuously Reinforced Aluminum Composites

Bolü XIAO(

), Zhiye HUANG, Kai MA, Xingxing ZHANG, Zongyi MA

Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

引用本文:

肖伯律, 黄治冶, 马凯, 张星星, 马宗义. 非连续增强铝基复合材料的热变形行为研究进展[J]. 金属学报, 2019, 55(1): 59-72.
Bolü XIAO, Zhiye HUANG, Kai MA, Xingxing ZHANG, Zongyi MA. Research on Hot Deformation Behaviors of Discontinuously Reinforced Aluminum Composites[J]. Acta Metall Sin, 2019, 55(1): 59-72.

全文: PDF(4377 KB) HTML

摘要:

本文综述了非连续增强铝基复合材料的热变形行为理论研究方法,并描述了典型铝基复合材料的热变形机制和可加工性特征。对本构方程、加工图理论方法对流变行为和变形机制研究的可靠性进行了讨论,同时介绍了引入应变速率敏感指数和温度敏感指数作为基体合金变形机制演化辅助判据的方法。根据铝合金常见变形机制,讨论了不同类型增强体的铝基复合材料热加工变形行为特征。最后,对该领域未来的研究方向进行了展望。

关键词 ：金属基复合材料, 热加工, 本构方程, 加工图, 变形机制

Abstract：

This paper describes the research progress in hot deformation behaviors of discontinuously reinforced aluminum (DRA) composite, including research method, deformation mechanism and hot workability. The reliability of constitutive equation and processing map for description of flowing behaviors and deformation mechanisms in the previous studies were discussed. Based on that, the strain rate and temperature sensitivities of flow stress were introduced to further identify the deformation mechanisms. Deformation characteristics and microstructures of the composites with different reinforcements were illustrated. Finally, the future researches of hot deformation of DRA composite are suggested.

Key words： metal matrix composite hot working constitutive equation processing map deformation mechanism

收稿日期: 2018-10-08

ZTFLH:

TB333

基金资助:国家重点研发计划项目No.2017YFB0703104,国家自然科学基金委员会-辽宁省人民政府联合基金项目No.U1508216

作者简介:

作者简介肖伯律,男,1975年生,研究员,博士

	服务

	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	肖伯律
	黄治冶
	马凯
	张星星
	马宗义
44.8K

链接本文:

https://www.ams.org.cn/CN/10.11900/0412.1961.2018.00461 或 https://www.ams.org.cn/CN/Y2019/V55/I1/59

表1 不同DRA复合材料的热加工表观变形激活能对比[44,45,46,47,48,49]

图1 铝合金弹性模量随温度变化的经验公式与实测值对比

图2 2.0%CNT/2024Al (质量分数)复合材料的三维加工图[74]

图3 14%SiCp/2014Al (体积分数)复合材料的应变速率敏感指数(m)图与加工图及其预测的流变失稳区域中的试样损伤[9]

图4 14%SiCp/2014Al (体积分数)复合材料在应变量0.8时的温度敏感指数(s)图[9]

图5 17%SiCp/2009Al (体积分数)复合材料在压缩变形后(ε =0.7)剪切变形区的电子背散射(EBSD)图

图6 17%SiCp/2009Al (体积分数)复合材料压缩变形后(ε =0.7)压缩变形区的TEM像

图7 轧制前后的1.5%CNT/2009Al (体积分数)复合材料中的CNT形态[117]

[1]	MarketsandMarkets. Metal matrix composite market by type (aluminum MMC, magnesium MMC, refractory MMC), production technology, reinforcement (continuous, discontinuous, particle), end use industry, and region-global forecast to 2021 [R]. Birmingham: Marketsandmarkets, 2017
[2]	Nardone V C, Prewo K M.On the strength of discontinuous silicon carbide reinforced aluminum composites[J]. Scr. Metall., 1986, 20: 43
[3]	Evans A, San Marchi C, Mortensen A.Metal Matrix Composites in Industry: An Introduction and a Survey[M]. Boston, MA: Springer, 2003: 22
[4]	Divecha A P, Fishman S G, Karmarkar S D.Silicon carbide reinforced aluminum—A formable composite[J]. JOM, 1981, 33(9): 12
[5]	Zhang W L, Wang J X, Yang F, et al.Recrystallization kinetics of cold-rolled squeeze-cast Al/SiC/15w composites[J]. J. Compos. Mater., 2006, 40: 1117
[6]	Jahedi M, Mani B, Shakoorian S, et al.Deformation rate effect on the microstructure and mechanical properties of Al-SiCp composites consolidated by hot extrusion[J]. Mater. Sci. Eng., 2012, A556: 23
[7]	Stonis M, Rüther T, Behrens B A.Analysis of material characteristics and forging parameters for flashless forged aluminum-matrix composites[J]. Mater. Manuf. Processes, 2014, 29: 140
[8]	Tham L M, Gupta M, Cheng L.Effect of reinforcement volume fraction on the evolution of reinforcement size during the extrusion of Al-SiC composites[J]. Mater. Sci. Eng., 2002, A326: 355
[9]	Huang Z Y, Zhang X X, Xiao B L, et al.Hot deformation mechanisms and microstructure evolution of SiCp/2014Al composite[J]. J. Alloys Compd., 2017, 722: 145
[10]	El-Sabbagh A M, Soliman M, Taha M A, et al. Effect of rolling and heat treatment on tensile behaviour of wrought Al-SiCp composites prepared by stir-casting[J]. J. Mater. Process. Technol., 2013, 213: 1669
[11]	Zhou L, Huang Z Y, Wang C Z, et al.Constitutive flow behaviour and finite element simulation of hot rolling of SiCp/2009Al composite[J]. Mech. Mater., 2016, 93: 32
[12]	Pakdel A, Witecka A, Rydzek G, et al.A comprehensive analysis of extrusion behavior, microstructural evolution, and mechanical properties of 6063 Al-B4C composites produced by semisolid stir casting[J]. Mater. Sci. Eng., 2018, A721: 28
[13]	Shi W C, Shan D B.Effect of whisker breakage on the forgeability and the tensile properties of the forged 2024Al/Al18B4O33w composite[J]. Mater. Charact., 2018, 135: 303
[14]	Zhang J Q, Di H S, Mao K, et al.Processing maps for hot deformation of a high-Mn TWIP steel: A comparative study of various criteria based on dynamic materials model[J]. Mater. Sci. Eng., 2013, A587: 110
[15]	Cui X F, Mi X J, Luo Z, et al.Effects of Cr content on the hot compression deformation behavior of Ti5Mo5V3Al-xCr alloys[J]. J. Mater. Eng. Perform., 2015, 24: 67
[16]	Johnson G R, Cook W H.A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures [R]. The Hague: International ballistics Society, 1983
[17]	Bodner S R, Partom Y.Constitutive equations for elastic-viscoplastic strain-hardening materials[J]. J. Appl. Mech., 1975, 42: 385
[18]	Fields D S, Backofen W A.Determination of strain hardening characteristics by torsion testing [A]. Proceedings of the 60th Annual Meeting of the American Society for Testing and Materials[C]. West Conshohocken: ASTM International, 1957: 1259
[19]	Khan A S, Huang S J.Experimental and theoretical study of mechanical behavior of 1100 aluminum in the strain rate range 10-5-104 s-1[J]. Int. J. Plast., 1992, 8: 397
[20]	Khan A S, Liang R Q.Behaviors of three BCC metal over a wide range of strain rates and temperatures: Experiments and modeling[J]. Int. J. Plast., 1999, 15: 1089
[21]	Khan A S, Liang R Q.Behaviors of three BCC metals during non-proportional multi-axial loadings: Experiments and modeling[J]. Int. J. Plast., 2000, 16: 1443
[22]	Khan A S, Suh Y S, Kazmi R.Quasi-static and dynamic loading responses and constitutive modeling of titanium alloys[J]. Int. J. Plast., 2004, 20: 2233
[23]	Chen G, Li J, He Y L, et al.A new approach to the determination of plastic flow stress and failure initiation strain for aluminum alloys cutting process[J]. Comput. Mater. Sci., 2014, 95: 568
[24]	Siswanto W A, Nagentrau M, Mohd Tobi A L, et al. Prediction of plastic deformation under contact condition by quasi-static and dynamic simulations using explicit finite element analysis[J]. J. Mech. Sci. Technol., 2016, 30: 5093
[25]	Zerilli F J, Armstrong R W.Dislocation-mechanics-based constitutive relations for material dynamics calculations[J]. J. Appl. Phys., 1987, 61: 1816
[26]	Follansbee P S, Kocks U F.A constitutive description of the deformation of copper based on the use of the mechanical threshold stress as an internal state variable[J]. Acta Metall., 1988, 36: 81
[27]	Nemat-Nasser S, Isaacs J B.Direct measurement of isothermal flow stress of metals at elevated temperatures and high strain rates with application to Ta and Ta-W alloys[J]. Acta Mater., 1997, 45: 907
[28]	Shafieizad A H, Zarei-Hanzaki A, Ghambari M, et al.High temperature flow behavior and microstructure of Al-Cu/Mg2Si metal matrix composite[J]. J. Eng. Mater. Technol., 2015, 137: 021006
[29]	Sellars C M, McTegart W J. On the mechanism of hot deformation[J]. Acta Metall., 1966, 14: 1136
[30]	Nardone V C, Strife J R.Analysis of the creep behavior of silicon carbide whisker reinforced 2124 Al(T4)[J]. Metall. Trans., 1987, 18A: 109
[31]	Nieh T G, Xia K, Langdon T G.Mechanical properties of discontinuous SiC reinforced aluminum composites at elevated temperatures[J]. J. Eng. Mater. Technol., 1988, 110: 77
[32]	McQueen H J, Ryan N D. Constitutive analysis in hot working[J]. Mater. Sci. Eng., 2002, A322: 43
[33]	Mohamed F A, Park K T, Lavernia E J.Creep behavior of discontinuous SiC-Al composites[J]. Mater. Sci. Eng., 1992, A150: 21
[34]	Park K T, Lavernia E J, Mohamed F A.High-temperature deformation of 6061 Al[J]. Acta Metall. Mater., 1994, 42: 667
[35]	Mishra R S, Bieler T R, Mukherjee A K.Superplasticity in powder metallurgy aluminum alloys and composites[J]. Acta Metall. Mater., 1995, 43: 877
[36]	Li Y, Nutt S R, Mohamed F A.An investigation of creep and substructure formation in 2124 Al[J]. Acta Mater., 1997, 45: 2607
[37]	Mishra R S, Bieler T R, Mukherjee A K.Mechanism of high strain rate superplasticity in aluminium alloy composites[J]. Acta Mater., 1997, 45: 561
[38]	Li Y, Langdon T G.A unified interpretation of threshold stresses in the creep and high strain rate superplasticity of metal matrix composites[J]. Acta Mater., 1999, 47: 3395
[39]	Kaibyshev R, Kazyhanov V, Musin F.Hot plastic deformation of aluminium alloy 2009-15%SiCw composite[J]. Mater. Sci. Technol., 2002, 18: 777
[40]	Kocks U F.A statistical theory of flow stress and work-hardening[J]. Philos. Mag., 1966, 13A: 541
[41]	Arzt E, Wilkinson D S.Threshold stresses for dislocation climb over hard particles: The effect of an attractive interaction[J]. Acta Metall., 1986, 34: 1893
[42]	Arzt E, R?sler J.The kinetics of dislocation climb over hard particles—II. Effects of an attractive particle-dislocation interaction[J]. Acta Metall., 1988, 36: 1053
[43]	Mishra R S, Nandy T K, Greenwood G W.The threshold stress for creep controlled by dislocation-particle interaction[J]. Philos. Mag., 1994, 69A: 1097
[44]	Xia X X, McQueen H J, Sakaris P. Hot deformation mechanisms in a 10 vol% Al2O3 particle reinforced 6061 Al matrix composite[J]. Scr. Metall. Mater., 1995, 32: 1185
[45]	Xia X X, McQueen H J. Deformation behaviour and microstructure of a 20% Al2O3 reinforced 6061 Al composite[J]. Appl. Compos. Mater., 1997, 4: 333
[46]	Cerri E, Spigarelli S, Evangelista E, et al.Hot deformation and processing maps of a particulate-reinforced 6061+20% Al2O3 composite[J]. Mater. Sci. Eng., 2002, A324: 157
[47]	Ferry M, Munroe P R.Hot working behaviour of Al-Al2O3 particulate reinforced metal matrix composite[J]. Mater. Sci. Technol., 1995, 11: 633
[48]	Qin J, Zhang Z, Chen X G.Hot deformation and processing maps of Al-15%B4C composites containing Sc and Zr[J]. J. Mater. Eng. Perform., 2017, 26: 1673
[49]	Sun Y L, Xie J P, Hao S M, et al.Dynamic recrystallization model of 30%SiCp/Al composite[J]. J. Alloys Compd., 2015, 649: 865
[50]	Yavari P, Mohamed F A, Langdon T G.Creep and substructure formation in an Al-5% Mg solid solution alloy[J]. Acta Metall., 1981, 29: 1495
[51]	Li Y, Langdon T G.Creep behavior of an Al-6061 metal matrix composite reinforced with alumina particulates[J]. Acta Mater., 1997, 45: 4797
[52]	Kaibyshev R, Sitdikov O, Mazurina I, et al.Deformation behavior of a 2219 Al alloy[J]. Mater. Sci. Eng., 2002, A334: 104
[53]	Wang S, Luo J R, Hou L G, et al.Physically based constitutive analysis and microstructural evolution of AA7050 aluminum alloy during hot compression[J]. Mater. Des., 2016, 107: 277
[54]	Wang S, Luo J R, Hou L G, et al.Identification of the threshold stress and true activation energy for characterizing the deformation mechanisms during hot working[J]. Mater. Des., 2017, 113: 27
[55]	European Committee for Standardization. EVS-EN 1999-1-2:2007 Design of aluminium structures—Part 1-2: Structural fire design[S]. London: British Standard Institute, 2007: 21
[56]	Maljaars J, Soetens F, Katgerman L.Constitutive model for aluminum alloys exposed to fire conditions[J]. Metall. Mater. Trans., 2008, 39A: 778
[57]	Prasad Y V R K, Gegel H L, Doraivelu S M, et al. Modeling of dynamic material behavior in hot deformation: Forging of Ti-6242[J]. Metall. Trans., 1984, 15A: 1883
[58]	Prasad Y V R K. Author's reply: Dynamic materials model: Basis and principles[J]. Metall. Mater. Trans., 1996, 27A: 235
[59]	Murty S V S N, Sarma M S, Rao B N. On the evaluation of efficiency parameters in processing maps[J]. Metall. Mater. Trans., 1997, 28A: 1581
[60]	Bhat B V R, Mahajan Y R, Roshan H M, et al. Processing maps for hot-working of powder metallurgy 1100 Al-10 vol % SiC-particulate metal-matrix composite[J]. J. Mater. Sci., 1993, 28: 2141
[61]	Bhat B V R, Mahajan Y R, Roshan H M, et al. Characteristics of superplasticity domain in the processing map for hot working of an Al alloy 2014-20vol.%Al2O3 metal matrix composite[J]. Mater. Sci. Eng., 1994, A189: 137
[62]	Murty S V S N, Rao B N. Instability map for hot working of 6061 Al-10 vol% Al2O3 metal matrix composite[J]. J. Phys., 1998, 31D: 3306
[63]	Kai X Z, Zhao Y T, Wang A D, et al.Hot deformation behavior of in situ nano ZrB2 reinforced 2024Al matrix composite[J]. Compos. Sci. Technol., 2015, 116: 1
[64]	Xu W C, Jin X Z, Xiong W D, et al.Study on hot deformation behavior and workability of squeeze-cast 20 vol%SiCw/6061Al composites using processing map[J]. Mater. Charact., 2018, 135: 154
[65]	Zhu F J, Wu H Y, Lin M C, et al.Hot workability analysis and development of a processing map for homogenized 6069 Al alloy cast ingot[J]. J. Mater. Eng. Perform., 2015, 24: 2051
[66]	Kai X Z, Chen C, Sun X F, et al.Hot deformation behavior and optimization of processing parameters of a typical high-strength Al-Mg-Si alloy[J]. Mater. Des., 2016, 90: 1151
[67]	Fan C H, Peng Y B, Yang H T, et al.Hot deformation behavior of Al-9.0Mg-0.5Mn-0.1Ti alloy based on processing maps[J]. Trans. Nonferrous Met. Soc. China, 2017, 27: 289
[68]	Shao J C, Xiao B L, Wang Q Z, et al.Constitutive flow behavior and hot workability of powder metallurgy processed 20 vol.%SiCp/2024Al composite[J]. Mater. Sci. Eng., 2010, A527: 7865
[69]	Bhat B V R, Mahajan Y R, Roshan H M, et al. Processing map for hot working of 6061 Al-10 vol.-%Al2O3 metal matrix composite[J]. Mater. Sci. Technol., 1995, 11: 167
[70]	Xiao B L, Fan J Z, Tian X F, et al.Hot deformation and processing map of 15%SiCp/2009 Al composite[J]. J. Mater. Sci., 2005, 40: 5757
[71]	Wang C X, Yu F X, Zhao D Z, et al.Hot deformation and processing maps of DC cast Al-15%Si alloy[J]. Mater. Sci. Eng., 2013, A577: 73
[72]	Wang K X, Zeng W D, Zhao Y Q, et al.Hot working of Ti-17 titanium alloy with lamellar starting structure using 3-D processing maps[J]. J. Mater. Sci., 2010, 45: 5883
[73]	Wang S, Hou L G, Luo J R, et al.Characterization of hot workability in AA 7050 aluminum alloy using activation energy and 3-D processing map[J]. J. Mater. Process. Technol., 2015, 225: 110
[74]	Mokdad F, Chen D L, Liu Z Y, et al.Three-dimensional processing maps and microstructural evolution of a CNT-reinforced Al-Cu-Mg nanocomposite[J]. Mater. Sci. Eng., 2017, A702: 425
[75]	Liu J, Cui Z S, Li C X.Analysis of metal workability by integration of FEM and 3-D processing maps[J]. J. Mater. Process. Technol., 2008, 205: 497
[76]	Weertman J.Steady-state creep of crystals[J]. J. Appl. Phys., 1957, 28: 1185
[77]	Mabuchi M, Iwasaki H, Higashi K, et al.Processing and superplastic properties of fine grained Si3N4/Al-Mg-Si composites[J]. Mater. Sci. Technol., 1995, 11: 1295
[78]	Zhang J Q, Di H S, Wang H T, et al.Hot deformation behavior of Ti-15-3 titanium alloy: A study using processing maps, activation energy map, and Zener-Hollomon parameter map[J]. J. Mater. Sci., 2012, 47: 4000
[79]	Watanabe H, Mukai T, Higashi K.Influence of temperature and grain size on threshold stress for superplastic flow in a fine-grained magnesium alloy[J]. Metall. Mater. Trans., 2008, 39A: 2351
[80]	Malas J C.A thermodynamic and continuum approach to the design and control of precision forging processes [D]. Dayton, Ohio: Wright State University, 1985
[81]	Gegel H L, Malas J C, Doraivelu S M, et al.Metals Handbook[M]. Chagrin Falls: ASM International, 1988: 417
[82]	Alexander J M.Mapping dynamic material behaviour [A]. Modelling Hot Deformation of Steels[M]. Berlin, Heidelberg: Springer, 1989: 101
[83]	Malas III J C. Methodology for design and control of thermomechanical processes [D]. Ann Arbor: Ohio University, 1991
[84]	Murty S V S N, Rao B N, Kashyap B P. Instability criteria for hot deformation of materials[J]. Int. Mater. Rev., 2000, 45: 15
[85]	Cavaliere P, Cerri E, Leo P.Hot deformation and processing maps of a particulate reinforced 2618/Al2O3/20p metal matrix composite[J]. Compos. Sci. Technol., 2004, 64: 1287
[86]	Gholinia A, Humphreys F J, Prangnell P B.Production of ultra-fine grain microstructures in Al-Mg alloys by coventional rolling[J]. Acta Mater., 2002, 50: 4461
[87]	Exell S F, Warrington D H.Sub-grain boundary migration in aluminium[J]. Philos. Mag., 1972, 26A: 1121
[88]	Huang Y, Humphreys F J, Brough I.The application of a hot deformation SEM stage, backscattered electron imaging and EBSD to the study of thermomechanical processing[J]. J. Microsc., 2002, 208: 18
[89]	Humphreys F J, Hatherly M.Recrystallization and Related Annealing Phenomena[M]. 2nd Ed., Amsterdam: Elsevier, 2004: 169
[90]	Fatemi-Varzaneh S M, Zarei-Hanzaki A, Beladi H. Dynamic recrystallization in AZ31 magnesium alloy[J]. Mater. Sci. Eng., 2007, A456: 52
[91]	Al-Samman T, Gottstein G.Dynamic recrystallization during high temperature deformation of magnesium[J]. Mater. Sci. Eng., 2008, A490: 411
[92]	Ponge D, Gottstein G.Necklace formation during dynamic recrystallization: mechanisms and impact on flow behavior[J]. Acta Mater., 1998, 46: 69
[93]	Marandi A, Zarei-Hanzaki R, Zarei-Hanzaki A, et al.Dynamic recrystallization behavior of new transformation-twinning induced plasticity steel[J]. Mater. Sci. Eng., 2014, A607: 397
[94]	Azarbarmas M, Aghaie-Khafri M, Cabrera J M, et al.Dynamic recrystallization mechanisms and twining evolution during hot deformation of Inconel 718[J]. Mater. Sci. Eng., 2016, A678: 137
[95]	Galiyev A, Kaibyshev R, Gottstein G.Correlation of plastic deformation and dynamic recrystallization in magnesium alloy ZK60[J]. Acta Mater., 2001, 49: 1199
[96]	Drury M R, Humphreys F J.The development of microstructure in Al-5% Mg during high temperature deformation[J]. Acta Metall., 1986, 34: 2259
[97]	Cavaliere P, Evangelista E.Isothermal forging of metal matrix composites: Recrystallization behaviour by means of deformation efficiency[J]. Compos. Sci. Technol., 2006, 66: 357
[98]	Hu H E, Zhen L, Zhang B Y, et al.Microstructure characterization of 7050 aluminum alloy during dynamic recrystallization and dynamic recovery[J]. Mater. Charact., 2008, 59: 1185
[99]	Lee J W, Son K T, Jung T K, et al.Continuous dynamic recrystallization behavior and kinetics of Al-Mg-Si alloy modified with CaO-added Mg[J]. Mater. Sci. Eng., 2016, A673: 648
[100]	Humphreys F J, Miller W S, Djazeb M R.Microstructural deve-lopment during thermomechanical processing of particulate metal-matrix composites[J]. Mater. Sci. Technol., 1990, 6: 1157
[101]	Humphreys F J.The thermomechanical processing of Al-SiC particulate composites[J]. Mater. Sci. Eng., 1991, A135: 267
[102]	Xia X X, Sakaris P, McQueen H J. Hot deformation, dynamic recovery, and recrystallisation behaviour of aluminium 6061-SiCp composite[J]. Mater. Sci. Technol., 1994, 10: 487
[103]	Ashby M F.The deformation of plastically non-homogeneous materials[J]. Philos. Mag., 1970, 21A: 399
[104]	Humphreys F J.The nucleation of recrystallization at second phase particles in deformed aluminium[J]. Acta Metall., 1977, 25: 1323
[105]	Clyne T W, Withers P J.An Introduction to Metal Matrix Composites [M]. Cambridge: Cambridge University Press, 1993: 73
[106]	Ceschini L, Minak G, Morri A.Forging of the AA2618/20 vol.% Al2O3p composite: Effects on microstructure and tensile properties[J]. Compos. Sci. Technol., 2009, 69: 1783
[107]	Xu H, Palmiere E J.Particulate refinement and redistribution during the axisymmetric compression of an Al/SiCp metal matrix composite[J]. Composites, 1999, 30A: 203
[108]	Seo Y H, Kang C G.Effects of hot extrusion through a curved die on the mechanical properties of SiCp/Al composites fabricated by melt-stirring[J]. Compos. Sci. Technol., 1999, 59: 643
[109]	Hanada K, Murakoshi Y, Negishi H, et al.Microstructures and mechanical properties of Al-Li/SiCp composite produced by extrusion processing[J]. J. Mater. Process. Technol., 1997, 63: 405
[110]	Essa Y E S, Fernández-Sáez J, Pérez-Castellanos J L. Some aspects of damage and failure mechanisms at high strain-rate and elevated temperatures of particulate magnesium matrix composites[J]. Composites, 2003, 34B: 551
[111]	Yuan L, Shi W C, Shivpuri R, et al.Increased hot forgeability of 2024Al/Al18B4O33w whisker composites at high strain rates[J]. J. Mater. Process. Technol., 2017, 243: 456
[112]	Zhao P T, Wang L D, Du Z M, et al.Low temperature extrusion of 6061 aluminum matrix composite reinforced with SnO2-coated Al18B4O33 whisker[J]. Composites, 2012, 43A: 183
[113]	Borrego A, Fernández R, del Carmen Cristina M, et al. Influence of extrusion temperature on the microstructure and the texture of 6061Al-15 vol.% SiCw PM composites[J]. Compos. Sci. Technol., 2002, 62: 731
[114]	Shi W C, Yuan L, Xu F C, et al.Refining whisker size of 2024Al/Al18B4O33w composite through extrusion and its effects on the material's micro-structures and mechanical properties[J]. Mater. Charact., 2018, 138: 98
[115]	Hong S H, Chung K H, Lee C H.Effects of hot extrusion parameters on the tensile properties and microstructures of SiCw-2124Al composites[J]. Mater. Sci. Eng., 1996, A206: 225
[116]	Choi H, Shin J, Min B, et al.Reinforcing effects of carbon nanotubes in structural aluminum matrix nanocomposites[J]. J. Mater. Res., 2011, 24: 2610
[117]	Liu Z Y, Xiao B L, Wang W G, et al.Effect of carbon nanotube orientation on mechanical properties and thermal expansion coefficient of carbon nanotube-reinforced aluminum matrix composites[J]. Acta Metall. Sin.(Engl. Lett.), 2014, 27: 901
[118]	Mokdad F, Chen D L, Liu Z Y, et al.Deformation and strengthening mechanisms of a carbon nanotube reinforced aluminum composite[J]. Carbon, 2016, 104: 64
[119]	Kwon H, Estili M, Takagi K, et al.Combination of hot extrusion and spark plasma sintering for producing carbon nanotube reinforced aluminum matrix composites[J]. Carbon, 2009, 47: 570

[1]	张雷雷, 陈晶阳, 汤鑫, 肖程波, 张明军, 杨卿. K439B铸造高温合金800℃长期时效组织与性能演变[J]. 金属学报, 2023, 59(9): 1253-1264.
[2]	张海峰, 闫海乐, 方烽, 贾楠. FeMnCoCrNi高熵合金双晶微柱变形机制的分子动力学模拟[J]. 金属学报, 2023, 59(8): 1051-1064.
[3]	丁桦, 张宇, 蔡明晖, 唐正友. 奥氏体基Fe-Mn-Al-C轻质钢的研究进展[J]. 金属学报, 2023, 59(8): 1027-1041.
[4]	马国楠, 朱士泽, 王东, 肖伯律, 马宗义. SiC颗粒增强Al-Zn-Mg-Cu复合材料的时效行为和力学性能[J]. 金属学报, 2023, 59(12): 1655-1664.
[5]	罗旋, 韩芳, 黄天林, 吴桂林, 黄晓旭. 层状异构Mg-3Gd合金的微观组织和力学性能[J]. 金属学报, 2022, 58(11): 1489-1496.
[6]	范根莲, 郭峙岐, 谭占秋, 李志强. 金属材料的构型化复合与强韧化[J]. 金属学报, 2022, 58(11): 1416-1426.
[7]	张金钰, 屈启蒙, 王亚强, 吴凯, 刘刚, 孙军. 金属/高熵合金纳米多层膜的力学性能及其辐照效应研究进展[J]. 金属学报, 2022, 58(11): 1371-1384.
[8]	朱士泽, 王东, 王全兆, 肖伯律, 马宗义. Cu含量对SiC/Al-Mg-Si-Cu复合材料自然时效负面效应的影响[J]. 金属学报, 2021, 57(7): 928-936.
[9]	余倩, 陈雨洁, 方研. 高熵合金中的元素分布规律及其作用[J]. 金属学报, 2021, 57(4): 393-402.
[10]	倪珂, 杨银辉, 曹建春, 王刘行, 刘泽辉, 钱昊. 18.7Cr-1.0Ni-5.8Mn-0.2N节Ni型双相不锈钢的大变形热压缩软化行为[J]. 金属学报, 2021, 57(2): 224-236.
[11]	李金山, 唐斌, 樊江昆, 王川云, 花珂, 张梦琪, 戴锦华, 寇宏超. 高强亚稳β钛合金变形机制及其组织调控方法[J]. 金属学报, 2021, 57(11): 1438-1454.
[12]	刘庆琦, 卢晔, 张翼飞, 范笑锋, 李瑞, 刘兴硕, 佟雪, 于鹏飞, 李工. Al_19.3Co₁₅Cr₁₅Ni_50.7高熵合金的热变形行为[J]. 金属学报, 2021, 57(10): 1299-1308.
[13]	张瑞, 刘鹏, 崔传勇, 曲敬龙, 张北江, 杜金辉, 周亦胄, 孙晓峰. 国内航空发动机涡轮盘用铸锻难变形高温合金热加工研究现状与展望[J]. 金属学报, 2021, 57(10): 1215-1228.
[14]	周丽, 李明, 王全兆, 崔超, 肖伯律, 马宗义. 31%B₄Cp/6061Al复合材料的热变形及加工图的研究[J]. 金属学报, 2020, 56(8): 1155-1164.
[15]	李天瑞, 刘国怀, 于少霞, 王文娟, 张风奕, 彭全义, 王昭东. 直接包套轧制铸态Ti-46Al-8Nb合金的组织特征及热变形机制[J]. 金属学报, 2020, 56(8): 1091-1102.

Viewed

Full text

Abstract

Cited

Shared

Discussed