Prediction of brittle fracture propagation behaviour of hydroxyapatite (HAp) coating in artificial femoral stem component

Q3 Materials Science

Archives of materials science and engineering Pub Date : 2022-03-01 DOI:10.5604/01.3001.0015.9851

C. Sheng, Nagentrau Muniandy, N. H. Ibrahim

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引用次数: 0

Abstract

Purpose: This study addresses the brittle fracture propagation behaviour modelling of hydroxyapatite (HAp) coating in artificial femoral stem component. Design/methodology/approach: A simple two dimensional flat-on-flat contact configuration finite element model consisting contact pad (bone), Ti-6Al-4V substrate and HAp coating is employed in static simulation. The HAp coating is modelled as elastic layer with pre-microcrack which assumed to be initiated due to stress singularity. Findings: The study revealed that reducing coating thickness, pre-microcrack length and artificial femoral stem elastic modulus along with increasing bone elastic modulus will result in significant stress intensity factor (SIF) to promote brittle fracture propagation behaviour. Research limitations/implications: The influence of coating thickness, pre-microcrack length, bone and artificial femoral stem elastic modulus on fracture behaviour is examined under different stress ratio using J-integral analysis approach. Practical implications: The proposed finite element model can be easily accommodating different Hap coating thickness, pre-microcrack length, bone and artificial femoral stem elastic modulus to perform detailed parametric studies with minimal costly experimental works. Originality/value: Limited research focussing on brittle fracture propagation behaviour of HAp coating in artificial femoral stem component. Thus, present study analysed the influence of coating thickness, pre-microcrack length, bone and artificial femoral stem elastic modulus on stress intensity factor (SIF) of HAp coating.

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羟基磷灰石(HAp)涂层人工股骨假体脆性断裂扩展行为的预测

目的：本研究探讨羟基磷灰石（HAp）涂层在人工股骨干假体中的脆性骨折扩展行为模型。设计/方法/方法：在静态模拟中采用了一个简单的二维平面接触配置有限元模型，该模型由接触垫（骨）、Ti-6Al-4V基底和HAp涂层组成。HAp涂层被建模为具有预微裂纹的弹性层，该预微裂纹假设是由于应力奇异性引起的。研究结果：研究表明，随着骨弹性模量的增加，减少涂层厚度、微裂纹前长度和人工股骨干弹性模量将导致显著的应力强度因子（SIF），从而促进脆性骨折的扩展行为。研究局限性/意义：使用J积分分析方法，研究了涂层厚度、微裂纹前长度、骨和人工股骨干弹性模量对不同应力比下骨折行为的影响。实际意义：所提出的有限元模型可以很容易地适应不同的Hap涂层厚度、微裂纹前长度、骨骼和人工股骨干弹性模量，以最低成本的实验工作进行详细的参数研究。独创性/价值：有限的研究集中在人工股骨干组件中HAp涂层的脆性断裂扩展行为上。因此，本研究分析了涂层厚度、微裂纹前长度、骨和人工股骨干弹性模量对HAp涂层应力强度因子（SIF）的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Archives of materials science and engineering Materials Science-Materials Science (all)

CiteScore

2.90

自引率

0.00%

发文量