基于材料挤压的聚醚醚酮增材制造在不同打印条件下的微结构演变及在脊柱植入物中的应用

IF 3.2 4区 工程技术 Q2 ENGINEERING, CHEMICAL
Alaeddin Burak Irez, Alperen Dogru
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引用次数: 0

摘要

随着增材制造技术的发展,聚醚醚酮(PEEK)这种生物相容性聚合物可用于脊柱植入物等生物医学领域。本文旨在研究基于材料挤压(MEX)的增材制造技术在不同打印参数下制造的 PEEK 零件微观结构的演变。通过拉伸、夏比冲击和短束强度(SBS)测试,研究了层厚(LT)和喷嘴直径对机械性能的影响。打印参数采用了两种不同的层厚度(0.1 毫米和 0.2 毫米)和两种不同的喷嘴直径(0.6 毫米和 0.8 毫米)。通过增加LT,拉伸强度下降了约24%,冲击强度下降了近55%。此外,从 SBS 试验来看,改变 LT 会导致层间剪切强度(ILSS)下降 15%。此外,增加喷嘴直径也导致拉伸强度、夏比冲击强度和层间剪切强度等所有结果显著降低。扫描电子显微镜也对结果进行了综合分析。主要发现是,LT 的增加会导致作为应力集中器的微结构缺陷的增加。测试之后,采用响应面方法(RSM)确定了最佳印刷参数。最后,利用 RSM 研究得出的最佳打印参数,通过有限元法对 MEX 打印脊柱植入物进行了结构分析,并考虑了模拟人体日常运动的加载情况。随着喷嘴直径的增大,拉伸强度和冲击强度确实有所下降。扫描电子显微镜(SEM)显示,层厚度增加会导致更多微观结构缺陷。有限元分析表明,基于 PEEK 的植入物具有结构完整性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The microstructural evolution of material extrusion based additive manufacturing of polyetheretherketone under different printing conditions and application in a spinal implant
With the advances in additive manufacturing, polyetheretherketone (PEEK), a biocompatible polymer, can be used in biomedical applications such as spinal implants. This paper aims to investigate the evolution of the microstructure of PEEK parts manufactured by material extrusion (MEX)‐based additive manufacturing with different printing parameters. The effect of layer thickness (LT) and nozzle diameter on mechanical properties was investigated using tensile, Charpy impact, and short beam strength (SBS) tests. Two different LTs, 0.1 and 0.2 mm, and two different nozzle diameters, 0.6 and 0.8 mm, were used as printing parameters. By increasing the LT, tensile strength dropped by around 24%, and impact strength by almost 55%. Moreover, altering the LT resulted in a 15% decrease in interlaminar shear strength (ILSS) from the SBS test. In addition, increasing the nozzle diameter also led to a significant reduction in all of the results as tensile strength, Charpy impact strength, and ILSS. The results were also consolidated by scanning electron microscopy. The main findings were that increasing LT leads to an increase in microstructural defects that act as stress concentrators. Following the tests, response surface methodology (RSM) was used to determine optimal printing parameters. In the end, using the optimum printing parameters from the RSM study, a structural analysis of a MEX‐printed spinal implant was conducted through finite element method, considering the loading cases mimicking daily human body motions.Highlights As layer thickness increased, tensile and impact strength dropped. Tensile and impact strength dropped truly with increasing nozzle diameter. SEM revealed that increasing layer thickness causes more microstructural flaws. FEM analysis showed that PEEK‐based implant provides structural integrity.
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来源期刊
Polymer Engineering and Science
Polymer Engineering and Science 工程技术-高分子科学
CiteScore
5.40
自引率
18.80%
发文量
329
审稿时长
3.7 months
期刊介绍: For more than 30 years, Polymer Engineering & Science has been one of the most highly regarded journals in the field, serving as a forum for authors of treatises on the cutting edge of polymer science and technology. The importance of PE&S is underscored by the frequent rate at which its articles are cited, especially by other publications - literally thousand of times a year. Engineers, researchers, technicians, and academicians worldwide are looking to PE&S for the valuable information they need. There are special issues compiled by distinguished guest editors. These contain proceedings of symposia on such diverse topics as polyblends, mechanics of plastics and polymer welding.
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