在多材料三维打印中增强层间附着力:通过熔融长丝制造对导电聚乳酸和热塑性聚氨酯界面的研究

G. L. Goh, Samuel Lee, Shi Hui Cheng, Daniel Jee Seng Goh, Pothunuri Laya, Van Pho Nguyen, Boon Siew Han, Wai Yee Yeong
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引用次数: 0

摘要

在快速发展的增材制造领域,多材料熔融长丝制造是一个具有巨大潜力的前沿领域,可以制造出融合不同材料特性优势的复合材料结构。不同材料之间的层间附着力仍然是实现多功能结构的一个挑战。本研究调查了导电聚乳酸和热塑性聚氨酯之间的层间粘附力,这两种材料分别代表了刚性和柔性特性。我们对两种增强粘附力的方法进行了比较分析:加入机械互锁功能和改变界面表面粗糙度。通过拉伸测试,我们评估了这些方法与未修改界面的基准试样相比的有效性。微计算机断层扫描分析、表面形态分析和机械性能评估阐明了这些界面设计的失效模式和界面行为。我们发现,经过顶部填充改性的界面设计显示出最高的层间粘附强度,与基准试样相比至少提高了 25%。我们的研究结果旨在为多材料三维打印的设计和制造实践提供参考,并为多功能复合材料三维打印系统的开发开辟新途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhancing interlaminar adhesion in multi-material 3D printing: A study of conductive PLA and TPU interfaces through fused filament fabrication
In the rapidly expanding field of additive manufacturing, multi-material fused filament fabrication represents a frontier with vast potential for creating composite structures that blend the benefits of different material properties. Interlaminar adhesion between dissimilar materials remains a challenge for the realization of multifunctional structure for practical use. This study investigates the interlaminar adhesion between conductive polylactic acid and thermoplastic polyurethane, materials representative of rigid and flexible characteristics, respectively. We present a comparative analysis of two adhesion enhancement approaches: the incorporation of mechanical interlocking features and the modification of surface roughness at the interface. Through tensile testing, we evaluate the effectiveness of these methods against a benchmark coupon with unmodified interface. Micro-computed tomography analysis, surface morphology analysis, and mechanical performance assessments elucidate the failure modes and provide insights into the interfacial behavior of these interface designs. We found that the interface design with top infill modification showed the highest interlaminar adhesion strength, with an improvement of at least 25% compared to the benchmark coupon. Our findings aim to inform the design and manufacturing practices in multi-material 3D printing and to open new avenues for the development of multifunctional, composite 3D-printed systems.
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