块状金属玻璃Zr55Cu30Al10Ni5的微压痕尺寸效应

材料科学与工程学报, 2014, 32(1): 74-78.

块状金属玻璃Zr55Cu30Al10Ni5的微压痕尺寸效应

郝毅 ^1, , 冯露 ^2, , 王静 ^3, , 刘美华 ^4, , 陈振飞 ^5, , 赵阳 ^6,

1.天津大学机械学院力学系,天津300072

2.天津大学机械学院力学系,天津300072

3.天津大学机械学院力学系,天津300072

4.天津商业大学机械工程学院力学系,天津300134

5.天津大学机械学院力学系,天津300072

6.天津大学机械学院力学系,天津300072

基金项目: 国家自然科学基金资助项目(11272231,11072169)

关键词： CMSG理论 , Drucker-Prager屈服准则 , 压敏尺寸效应 , 圆锥压痕 , UMAT

Micro-indentation Size Effect of a Zr55Cu30Al10Ni5 Bulk Metallic Glass

HAO Yi ^1, , FENG Lu ^2, , WANG Jing ^3, , LIU Mei-hua ^4, , CHEN Zhen-fei ^5, , ZHAO Yang ^6,

1.天津大学机械学院力学系,天津300072

2.天津大学机械学院力学系,天津300072

3.天津大学机械学院力学系,天津300072

4.天津商业大学机械工程学院力学系,天津300134

5.天津大学机械学院力学系,天津300072

6.天津大学机械学院力学系,天津300072

Keywords： CMSG theory , Drucker-Prager yield criterion , pressure-sensitive size effect , conical indentation , UMAT

本文根据Drucker-Prager屈服准则建立了适用于压敏材料的低阶应变梯度塑性(CMSG)理论.在此基础上,通过ABAQUS用户自定义材料子程序(UMAT)接口,建立了CMSG理论本构关系的有限元计算格式,结合该子程序对块状金属玻璃Zr55Cu30Al10Ni5的圆锥压痕响应进行了数值模拟,分析了不同压痕深度和压敏系数的影响.计算结果与实验数据吻合较好,表明该理论可以很好地描述金属玻璃Zr55Cu30Al10Ni5等一类材料的弹塑性行为.计算结果显示Zr55Cu30Al10Ni5的硬度随着压痕深度的增大而减小,由此说明基于Drucker-Prager屈服准则的CMSG理论可以很好地预测金属玻璃Zr55Cu30Al10Ni5在微尺度下表现出来的压敏尺寸效应.

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