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基于聚丙烯的增材制造踝足矫形器的工艺参数优化及力学性能

Process Parameters Optimization and Mechanical Properties of Additively Manufactured Ankle-Foot Orthoses Based on Polypropylene.

作者信息

Swesi Sahar, Yousfi Mohamed, Tardif Nicolas, Banoune Abder

机构信息

Université de Lyon, CNRS, UMR 5223, Ingénierie des Matériaux Polymères, Université Claude Bernard Lyon 1, INSA Lyon, Université Jean Monnet, 69621 Villeurbanne Cedex, France.

Univ Lyon, INSA-Lyon, CNRS, LaMCoS, UMR5259, 69621 Villeurbanne, France.

出版信息

Polymers (Basel). 2025 Jul 11;17(14):1921. doi: 10.3390/polym17141921.

DOI:10.3390/polym17141921
PMID:40732800
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12299998/
Abstract

Nowadays, Fused Filament Fabrication (FFF) 3D printing offers promising opportunities for the customized manufacturing of ankle-foot orthoses (AFOs) targeted towards rehabilitation purposes. Polypropylene (PP) represents an ideal candidate in orthotic applications due to its light weight and superior mechanical properties, offering an excellent balance between flexibility, chemical resistance, biocompatibility, and long-term durability. However, Additive Manufacturing (AM) of AFOs based on PP remains a major challenge due to its limited bed adhesion and high shrinkage, especially for making large parts such as AFOs. The primary innovation of the present study lies in the optimization of FFF 3D printing parameters for the fabrication of functional, patient-specific orthoses using PP, a material still underutilized in the AM of medical devices. Firstly, a thorough thermomechanical characterization was conducted, allowing the implementation of a (thermo-)elastic material model for the used PP filament. Thereafter, a Taguchi design of experiments (DOE) was established to study the influence of several printing parameters (extrusion temperature, printing speed, layer thickness, infill density, infill pattern, and part orientation) on the mechanical properties of 3D-printed specimens. Three-point bending tests were conducted to evaluate the strength and stiffness of the samples, while additional tensile tests were performed on the 3D-printed orthoses using a home-made innovative device to validate the optimal configurations. The results showed that the maximum flexural modulus of 3D-printed specimens was achieved when the printing speed was around 50 mm/s. The most significant parameter for mechanical performance and reduction in printing time was shown to be infill density, contributing 73.2% to maximum stress and 75.2% to Interlaminar Shear Strength (ILSS). Finally, the applicability of the finite element method (FEM) to simulate the FFF process-induced deflections, part distortion (warpage), and residual stresses in 3D-printed orthoses was investigated using a numerical simulation tool (Digimat-AM). The combination of Taguchi DOE with Digimat-AM for polypropylene AFOs highlighted that the 90° orientation appeared to be the most suitable configuration, as it minimizes deformation and von Mises stress, ensuring improved quality and robustness of the printed orthoses. The findings from this study contribute by providing a reliable method for printing PP parts with improved mechanical performance, thereby opening new opportunities for its use in medical-grade additive manufacturing.

摘要

如今,熔融沉积成型(FFF)3D打印为定制制造用于康复目的的踝足矫形器(AFO)提供了广阔的前景。聚丙烯(PP)因其重量轻和机械性能优越,在矫形应用中是理想的材料,在柔韧性、耐化学性、生物相容性和长期耐用性之间实现了良好的平衡。然而,基于PP的AFO增材制造仍然是一个重大挑战,因为其床层附着力有限且收缩率高,特别是对于制造如AFO这样的大型部件。本研究的主要创新在于优化FFF 3D打印参数,以使用PP制造功能性、针对患者的矫形器,PP这种材料在医疗器械增材制造中仍未得到充分利用。首先,进行了全面的热机械表征,从而能够为所用的PP细丝实施一个(热)弹性材料模型。此后,建立了田口实验设计(DOE),以研究几个打印参数(挤出温度、打印速度、层厚、填充密度、填充图案和部件方向)对3D打印试样机械性能的影响。进行了三点弯曲试验以评估样品的强度和刚度,同时使用自制的创新装置对3D打印的矫形器进行了额外的拉伸试验,以验证最佳配置。结果表明,当打印速度约为50毫米/秒时,3D打印试样达到最大弯曲模量。对于机械性能和减少打印时间而言,最显著的参数是填充密度,它对最大应力的贡献为73.2%,对层间剪切强度(ILSS)的贡献为75.2%。最后,使用数值模拟工具(Digimat-AM)研究了有限元方法(FEM)模拟3D打印矫形器中FFF工艺引起的挠度、部件变形(翘曲)和残余应力的适用性。将田口DOE与Digimat-AM结合用于聚丙烯AFO突出表明,90°方向似乎是最合适的配置,因为它能使变形和冯·米塞斯应力最小化,确保打印矫形器的质量和稳健性得到改善。本研究的结果通过提供一种可靠的方法来打印具有改善机械性能的PP部件,从而为其在医疗级增材制造中的应用开辟了新机会。

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本文引用的文献

1
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2
Additive Manufacturing of Polyolefins.聚烯烃的增材制造
Polymers (Basel). 2022 Nov 26;14(23):5147. doi: 10.3390/polym14235147.
3
Feasibility of designing, manufacturing and delivering 3D printed ankle-foot orthoses: a systematic review.3D 打印踝足矫形器的设计、制造和交付的可行性:系统评价。
J Foot Ankle Res. 2019 Feb 7;12:11. doi: 10.1186/s13047-019-0321-6. eCollection 2019.
4
The impact of ankle-foot orthosis stiffness on gait: A systematic literature review.踝足矫形器刚度对步态的影响:系统文献回顾。
Gait Posture. 2019 Mar;69:101-111. doi: 10.1016/j.gaitpost.2019.01.020. Epub 2019 Jan 15.
5
Is 3D printing safe? Analysis of the thermal treatment of thermoplastics: ABS, PLA, PET, and nylon.3D打印安全吗?热塑性塑料(ABS、PLA、PET和尼龙)的热处理分析。
J Occup Environ Hyg. 2017 Jun;14(6):D80-D85. doi: 10.1080/15459624.2017.1285489.
6
Polypropylene ankle foot orthoses to overcome drop-foot gait in central neurological patients: a mechanical and functional evaluation.用于克服中枢神经系统疾病患者足下垂步态的聚丙烯踝足矫形器:力学与功能评估
Prosthet Orthot Int. 2010 Sep;34(3):293-304. doi: 10.3109/03093646.2010.495969.
7
A three centre study of the variability of ankle foot orthoses due to fabrication and grade of polypropylene.一项关于因制作工艺和聚丙烯等级导致的踝足矫形器变异性的三中心研究。
Prosthet Orthot Int. 2004 Aug;28(2):175-82. doi: 10.1080/03093640408726702.
8
Design enhancement of a solid ankle-foot orthosis: real-time contact pressures evaluation.固体踝足矫形器的设计改进:实时接触压力评估
J Rehabil Res Dev. 2000 May-Jun;37(3):273-81.
9
Walking ability of stroke patients: efficacy of tibial nerve blocking and a polypropylene ankle-foot orthosis.中风患者的行走能力:胫神经阻滞和聚丙烯踝足矫形器的疗效
Arch Phys Med Rehabil. 1996 Nov;77(11):1144-51. doi: 10.1016/s0003-9993(96)90138-0.