基于分析方法和有限元法的金属-聚合物髋关节植入物最大接触压力预测评估

Q3 Engineering
M. Chernets, Yu. M. Chernets’
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引用次数: 0

摘要

在90%以上的髋关节置换术中,髋臼杯由超高分子量聚乙烯(UHMWPE)制成,股骨头由不锈钢、钴铬钼合金、钛或陶瓷制成。评估软硬内假体的主要因素是作为UHMWPE接触强度的最大接触压力。在特定患者的关节成形术过程中,这些压力的水平被用作正确选择股骨头大小和连接处径向间隙的标准。根据先前开发的新分析方法,提出了估算热扩散氮化(TDN)钛GRADE 2–UHMWPE髋关节植入物最大接触压力的新方法。对于平均载荷,确定植入物股骨头直径和径向间隙对最大接触压力的影响。建立了最大接触压力与上述参数之间的关系。将所提出的分析方法估计的最大接触压力与ANSYS(二维和三维)的数值分析进行了比较。使用2D模型计算的最大接触压力是下限,使用ANSYS中的3D模型计算的压力是分析计算的上限。因此,应预计,在杯厚度~7…8mm时,接触应力将与通过上述方法从溶液中获得的接触应力没有显著差异。所开发的分析方法不仅可以有效地用于软对硬内假体(金属对聚合物、陶瓷对聚合物)的研究,还可以有效地应用于硬对硬内假肢(金属对金属、陶瓷对陶瓷)的研究。分析计算的结果也与文献中已知的有限元计算结果有关,并建立了它们的收敛性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Predictive Assessment of Maximum Contact Pressures in Metal-on-Polymer Hip Joint Implants by Analytical Method and FEM
In more than 90% of hip replacements, the acetabular cup is made of ultra-high molecular weight polyethylene (UHMWPE) and the femoral head is made of stainless steel, cobalt-chromium-molybdenum alloys, titanium or ceramic. The primary factor in evaluating soft-on-hard endoprostheses is the maximum contact pressure as the contact strength of UHMWPE. The level of these pressures is used as a criterion for the correct selection of the femoral head size and radial clearance in the connection during arthroplasty for a specific patient. According to the previously developed new analytical method is proposed for estimating maximum contact pressures in thermo-diffusion nitrided (TDN) titanium GRADE 2 – UHMWPE hip joint implant. The effects of implant femoral head diameter and radial clearance on maximum contact pressures are determined for the average load. Relationships between maximum contact pressures and the above-mentioned parameters are established. A comparison is made between maximum contact pressures estimated by the proposed analytical method and numerical analysis with ANSYS (2D and 3D). The maximum contact pressures calculated using the 2D model have been found to be the lower limit, and the pressures calculated using the 3D model in ANSYS are the upper limit for analytical calculations. Therefore, it should be expected that at thickness of cup ˜ 7…8 mm the contact stresses will not be significantly different than those obtained from the solution by the above method. The developed analytical method can be effectively used for research not only soft-on-hard endoprostheses (metal-on-polymer, ceramics-on-polymer), but also hard-on-hard endoprostheses (metal-on-metal, ceramics-on-ceramics). The results of analytical calculations were also related to the results of FEM calculations known in the literature and their convergence was established.
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来源期刊
Tribology in Industry
Tribology in Industry Engineering-Mechanical Engineering
CiteScore
2.80
自引率
0.00%
发文量
47
审稿时长
8 weeks
期刊介绍: he aim of Tribology in Industry journal is to publish quality experimental and theoretical research papers in fields of the science of friction, wear and lubrication and any closely related fields. The scope includes all aspects of materials science, surface science, applied physics and mechanical engineering which relate directly to the subjects of wear and friction. Topical areas include, but are not limited to: Friction, Wear, Lubricants, Surface characterization, Surface engineering, Nanotribology, Contact mechanics, Coatings, Alloys, Composites, Tribological design, Biotribology, Green Tribology.
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