Tao Liu , Ji-hong Zhu , Weihong Zhang , Sofiane Belhabib , Sofiane Guessasma
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引用次数: 0
摘要
本研究调查了使用熔融长丝制造(FFF)工艺制造的聚乳酸/聚羟乙酸木质晶格结构的微观结构和压缩行为。主要目的是评估缺陷(如孔隙率和表面粗糙度)对这些晶格结构机械性能的影响。利用 X 射线显微层析成像 (XRT) 和有限元分析将 CAD 模型与实际晶格结构进行比较,从而深入了解缺陷引起的性能偏差。这种新方法综合了实验和数值方法,能更好地理解多孔结构中的损伤积累。该方法包括单轴压缩测试和用于微结构表征的图像处理。结果显示,由于制造缺陷,相对密度和应力集中存在明显差异。特别是,3D 打印晶格结构显示出典型的蜂窝材料行为,具有主要的弯曲变形机制。X 射线断层扫描显示,加工过程引起的孔隙率会产生应力异质性,而基于 CAD 的模型无法捕捉到这种应力异质性,导致刚度被高估。研究得出结论,可以通过改变目标相对密度来量化这些缺陷,以弥补 3D 打印晶格材料性能的不足。
Microstructure and compressive behaviour of PLA/PHA-wood lattice structures processed using additive manufacturing
This study investigates the microstructure and compressive behaviour of PLA/PHA-wood lattice structures manufactured using fused filament fabrication (FFF). The primary objective is to evaluate the effects of defects, such as porosity and surface roughness, on the mechanical properties of these lattice structures. X-ray micro-tomography (XRT) and finite element analysis are employed to compare CAD models with real lattice structures, offering insights into defect-induced performance deviations. The novel approach integrates experimental and numerical methods to better understand damage accumulation in porous structures. The methodology includes uniaxial compression testing and image processing for microstructural characterization. Results reveal significant differences in relative density and stress concentration due to manufacturing defects. In particular, 3D printed lattice structures display typical cellular material behaviour with a primary bending deformation mechanism. X-ray tomography reveals that process-induced porosity generate stress heterogeneity, which is not captured from CAD-based model resulting in an overestimation of the stiffness. The study concludes that accounting for these defects can be quantified by shifting the target relative density to compensate lack of performance in 3D-printed lattice materials.
期刊介绍:
Polymer Testing focuses on the testing, analysis and characterization of polymer materials, including both synthetic and natural or biobased polymers. Novel testing methods and the testing of novel polymeric materials in bulk, solution and dispersion is covered. In addition, we welcome the submission of the testing of polymeric materials for a wide range of applications and industrial products as well as nanoscale characterization.
The scope includes but is not limited to the following main topics:
Novel testing methods and Chemical analysis
• mechanical, thermal, electrical, chemical, imaging, spectroscopy, scattering and rheology
Physical properties and behaviour of novel polymer systems
• nanoscale properties, morphology, transport properties
Degradation and recycling of polymeric materials when combined with novel testing or characterization methods
• degradation, biodegradation, ageing and fire retardancy
Modelling and Simulation work will be only considered when it is linked to new or previously published experimental results.
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