Wear Behavior of 3D Printed PLA Surfaces for Superhydrophobic Interaction

TESConf 2020: Full Papers Pub Date : 2020-10-23 DOI:10.2139/ssrn.3717991

H. Shams, K. Basit, M. Khan, A. Mansoor

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引用次数: 3

Abstract

Polylactic Acid (PLA) is a biodegradable thermoplastic polymer known for its widescale application in bio-tribology. A known problem with PLA is its high level of water adsorption due to its hydrophilic nature which can lead to growth of mold and other fungal derivatives due to water stagnation. In our investigation we developed a re-entrant pattern using a standard fused-deposition modelling (FDM) 3D printer with the aim to achieve surfaces which are superhydrophobic in nature. The layer heights of the re-entrant profiles were systematically modified while keeping all other printing parameters constant to achieve a multi-edge ladder effect. The samples were then investigated for their superhydrophobic characteristics by measurement of Contact and Tilt Angles and thereafter characterized for wear resistance using a ball-on-disc tribometer. A fixed low rpm setting was used to eliminate the effect of temperature. Wear parameters including Wear Depth and Coefficient of Friction were recorded after each cycle using until the sample’s re-entrant structure was damaged and no longer supported water-repellent behavior shown by a considerable decrease in water contact angle. The effect of layer height variation in the re-entrant profiles for effective wear resistance was established as a preliminary study for our subsequent research in the area. It can be concluded that the layer height plays a vital role in achieving superhydrophobicity and has a direct influence on the wear resistant of the surface.

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3D打印PLA表面超疏水相互作用的磨损行为

聚乳酸(PLA)是一种生物可降解的热塑性聚合物，在生物摩擦学中有着广泛的应用。PLA的一个已知问题是，由于其亲水性，它的高吸水性可能导致霉菌和其他真菌衍生物由于水停滞而生长。在我们的研究中，我们使用标准的熔融沉积建模(FDM) 3D打印机开发了一种可重新进入的图案，目的是实现本质上的超疏水性表面。在保持所有其他打印参数不变的情况下，系统地修改了重入轮廓的层高度，以实现多边阶梯效果。然后通过测量接触角和倾斜角来研究样品的超疏水特性，然后使用球盘摩擦计对其耐磨性进行表征。采用固定的低转速设置来消除温度的影响。每次循环使用后，记录磨损参数，包括磨损深度和摩擦系数，直到样品的可重新进入的结构被破坏，不再支持防水行为，表现为水接触角的显著减少。地层高度变化对重入剖面的有效耐磨性的影响是我们在该地区后续研究的初步研究。综上所述，层高对实现超疏水性起着至关重要的作用，并直接影响到表面的耐磨性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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TESConf 2020: Full Papers

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