碳含量对Si-Mn-B铸钢显微组织和抗磨性的影响

材料热处理学报, 2007, 28(6): 78-81. doi: 10.3969/j.issn.1009-6264.2007.06.019

碳含量对Si-Mn-B铸钢显微组织和抗磨性的影响

匡加才 ^1, , 符寒光 ^2, , 王林涛 ^3,

1.长沙理工大学材料科学与工程学院,湖南,长沙,410076

2.清华大学先进成形制造教育部重点实验室,北京,100084

3.意大利索萨集团中国办事处,北京,100037

基金项目: 湖南省科技攻关项目(S2006C3530;2007ck3048) 湖南省博士后基金(2006FJ4239) 中国博士后科学基金(20060400881)

关键词： Si-Mn-B铸钢 , 碳含量 , 贝氏体 , 正火 , 耐磨性

Influence of carbon content on microstructure and wear resistance of Si-Mn-B bainitic cast steel

研究了含1.5%Si-2.5%Mn-0.006%B和少量稀土、镍、铬、钛等合金的Si-Mn-B铸钢经900℃正火的显微组织和在销盘磨损和湿砂橡胶轮磨损条件下的抗磨损性能.钢中碳含量分别为0.17%、0.25%、0.34%、0.47%和0.53%.结果表明,碳含量较低时,主要形成粒状贝氏体,随着碳含量增加,钢的正火组织向针状贝氏体、上贝氏体和下贝氏体过渡,且组织变细.钢的硬度随碳含量增加而增大,冲击韧度随碳含量增加而下降.Si-Mn-B铸钢的耐磨性随碳含量的变化比较复杂.在销盘磨损条件下,使用低硬度玻璃砂磨料时,随着碳含量提高,磨损量减少,耐磨性增加,另外,材料的磨损量随着载荷的增加而增加,使用高硬度碳化硅磨料时,碳含量对磨损量的影响不明显.在湿砂橡胶轮磨损条件下,也呈现碳含量增加,磨损量减少的现象.

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