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热处理对Fe-B-C合金显微组织和性能的影响 被引量:19

Effect of Heat Treatment on Microstructures and Properties of Fe-B-C Alloy
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摘要 研究含1.4%-2.0%B和0.4%-0.6%C的Fe-B-C合金凝固过程和凝固组织以及不同淬火加热温度下的显微组织、力学性能和耐磨性的变化规律。结果表明,Fe-B-C合金凝固组织由Fe2B、Fe3(C, B)和Fe23(C, B)6等硼化物及马氏体、珠光体和铁素体等金属基体组成。淬火后硼化物局部断网且无硼化物新相出现,基体全部转变成马氏体,硬度大于55 HRC。随淬火温度升高,Fe-B-C合金硬度增加,冲击韧性变化不明显。Fe-B-C合金在静载销盘磨损和动载冲击磨损条件下,都具有优异的耐磨性。 The solidification process and solidification structures of Fe-B-C alloy containing 1.4%-2.0% B and 0.4%-0.6% C were researched. The change of microstructures, mechanical properties and wear resistance of the alloy at different quenching temperatures were also studied. The results show that the solidification structures of Fe-B-C alloy consist of borides such as Fe2B, Fe3(C, B) and Fe23(C,B)6 and metallic matrix such as martensite, pearlite and ferrite. The part of boride network is broken and there is no new phase after quenching. The matrix transforms into the single martensite completely and the hardness exceeds 55 HRC. The hardness of Fe-B-C alloy increases while the impact toughness has no obvious change with increase of the quenching temperature. Under the conditions of static load pin-on-disc wear and dynamic load impact wear, Fe-B-C alloy has excellent wear resistance and the quenching temperature has no marked effect on the wear resistance
作者 符寒光 宋绪丁 刘海明 雷永平 成小乐 邢建东
机构地区 北京工业大学 西安交通大学 长安大学
出处 《稀有金属材料与工程》 SCIE EI CAS CSCD 北大核心 2010年第6期1125-1128,共4页 Rare Metal Materials and Engineering
基金 国家高技术研究发展计划(2007AA03Z510)
关键词 Fe-B-C合金 硼化物 淬火温度 力学性能 耐磨性 Fe-B-C alloy boride quenching temperature mechanical property wear resistance
分类号 TG156 [金属学及工艺—热处理]
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参考文献13

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二级参考文献14

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共引文献43

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引证文献19

二级引证文献46

稀有金属材料与工程
2010年 第6期

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