Numerical surface characterization of wear debris from artificial joints using atomic force microscopy 被引量：5

Numerical surface characterization of wear debris from artificial joints using atomic force microscopy

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摘要 Study on surface features of wear particles generated in wear process provides an insight into the progress of material failure of artificial joints. It is very important to quantify the surface features of wear particles in three dimensions. In this study, a new approach using atomic force microscopy was proposed to carry out 3D numerical surface characterization of wear debris generated from artificial joints. Atomic force microscopy combined with image processing techniques was used to acquire appropriate 3D images of wear debris. Computerized image analysis techniques were then used to quantify surface texture features of wear debris such as surface roughness parameters and surface texture index. The method developed from the present study was found to be feasible to quantity the surface characterization of nanoand micro-sized wear debris generated from artificial joints. Study on surface features of wear particles generated in wear process provides an insight into the progress of material failure of artificial joints. It is very important to quantify the surface features of wear particles in three dimensions. In this study, a new approach using atomic force microscopy was proposed to carry out 3D numerical surface characterization of wear debris generated from artificial joints. Atomic force microscopy combined with image processing techniques was used to acquire appropriate 3D images of wear debris. Computerized image analysis techniques were then used to quantify surface texture features of wear debris such as surface roughness parameters and surface texture index. The method developed from the present study was found to be feasible to quantity the surface characterization of nanoand micro-sized wear debris generated from artificial joints.

作者 YUAN ChengQing JIN ZhongMin TIPPER J L YAN XinPing

机构地区 Reliability Engineering Institute Institute of Medical and Biological Engineering

出处《Chinese Science Bulletin》 SCIE EI CAS 2009年第24期4583-4588,共6页

基金 Supported by UK Royal Society K C Wong Fellowship and National Natural Science Foundation of China (Grant No. 50705070)

关键词原子力显微镜人工关节表面特性数值磨粒表面粗糙度参数磨损颗粒三维图像 wear debris, artificial joints, atomic force microscopy, numerical surface characterization

分类号 TP301.6 [自动化与计算机技术—计算机系统结构] TH742 [机械工程—光学工程]

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Chinese Science Bulletin

2009年第24期

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