电阻电热合金材料弥散强化技术研究综述
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摘要
电阻电热合金是金属功能材料的重要组成部分,历经多年发展,产品质量和制造工艺技术及装备水平不断取得新的进步。弥散强化技术有助于产品性能的再提高。随着研究工作的不断深入,将会为该类产品赶超世界先进水平发挥重要作用。
Resistance electrothermal alloy is an important component of metal functional materials.After years of development, new progress has been made in product quality, manufacturing technology and equipment level. Dispersion strengthening technology is helpful to improve the product performance. With the deepening of the research work, it will play an important role in catching up with the advanced level of the world.
Resistance electrothermal alloy is an important component of metal functional materials.After years of development, new progress has been made in product quality, manufacturing technology and equipment level. Dispersion strengthening technology is helpful to improve the product performance. With the deepening of the research work, it will play an important role in catching up with the advanced level of the world.
引文
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[7]岳丽杰.Cu-P-RE耐蚀钢中稀土行为作用机理的研究[D].东北大学,2006.
[8]李腾训,孔建.合金元素和热处理对电阻炉寿命的影响分析[J].热加工工艺,2013(24):222-224.
[9]Charleux M,Poole W J,Militzer M,et al.Precipitation behavior and its effect on strengthening of an HSLA-Nb/Ti steel[J].Metallurgical and Materials Transactions A(Physical Metallurgy and Materials Science),2001,32(7):1635-1647.
[10]震向东,毛新平,吕盛夏,等.CSP生产Ti微合金化高强钢中纳米碳化物[J].北京科技大学学报,2011,33(8):941-946.
[11]陆阳,郭占成,高金涛,等.轧制水冷速度对Ti微合金钢中纳米碳化物及其强化作用的影响[J].有色金属科学与工程,2016,7(6):56-61.
[12]杜开平,于月光,张淑婷,等.超快速冷却条件下Ti微合金钢中纳米碳化物及其强化作用[J].有色金属科学与工程,2016,7(4):27-32.
[13]Gladman T.Second phase particle distribution and secondary recrystallisation[J].Scripta Metallurgica et Materialia,1992,27(11):1569-1573.
[2]干勇,田志凌,董瀚,等.中国材料工程大典:钢铁材料工程[M].2006.
[3]于梦羲,郭汉杰,郭靖,等.电渣冶金熔炼Fe-Cr-Al高温合金抑制镧、铈稀土氧化的研究[J].材料与冶金学报,2016,15(4):247-253.
[4]张路明,林勤,李军,等.高强耐蚀钢中稀土含量对夹杂物和性能的影响规律[J].稀土,2005,26(5):65-68.
[5]林勤,陈邦文,唐历,等.微合金钢中稀土对沉淀相和性能的影响[J].中国稀土学报2002,20(3):256-260.
[6]Frangini S,Loreti S.The role of alkaline-earth additives on the molten carbonate corrosion of 316L stainless steel[J].Corrosion Science,2007,49(10):3969-3987.
[7]岳丽杰.Cu-P-RE耐蚀钢中稀土行为作用机理的研究[D].东北大学,2006.
[8]李腾训,孔建.合金元素和热处理对电阻炉寿命的影响分析[J].热加工工艺,2013(24):222-224.
[9]Charleux M,Poole W J,Militzer M,et al.Precipitation behavior and its effect on strengthening of an HSLA-Nb/Ti steel[J].Metallurgical and Materials Transactions A(Physical Metallurgy and Materials Science),2001,32(7):1635-1647.
[10]震向东,毛新平,吕盛夏,等.CSP生产Ti微合金化高强钢中纳米碳化物[J].北京科技大学学报,2011,33(8):941-946.
[11]陆阳,郭占成,高金涛,等.轧制水冷速度对Ti微合金钢中纳米碳化物及其强化作用的影响[J].有色金属科学与工程,2016,7(6):56-61.
[12]杜开平,于月光,张淑婷,等.超快速冷却条件下Ti微合金钢中纳米碳化物及其强化作用[J].有色金属科学与工程,2016,7(4):27-32.
[13]Gladman T.Second phase particle distribution and secondary recrystallisation[J].Scripta Metallurgica et Materialia,1992,27(11):1569-1573.