创新型双功能材料挤出 3D 打印机可实现极高的粗糙度降低和超精细质量

Muhammad Ibnu Rashyid, Mahendra Jaya, M. Muflikhun
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引用次数: 0

摘要

目的 本文旨在利用混合制造(HM)技术克服材料挤压三维(3D)打印机的几个缺点,如尺寸过低(0.2 至 0.5 µm),导致明显的阶梯效应和表面粗糙度升高。本研究将增材制造(AM)和减材制造(SM)集成到一个材料挤压三维打印机平台中,创建了一个 HM 系统。研究对两组试样进行了尺寸精度和表面粗糙度评估,一组试样是完全打印出来的,另一组试样则同时进行了打印和铣削。90°(从 15.598 微米降至 1.030 微米,降幅达 93.4%)、45°(从 26.727 微米降至 2.946 微米,降幅达 89%)和面平面(从 12.176 微米降至 3.535 微米,降幅达 71%)的表面粗糙度显著降低。基于制造成本的经济评估表明,制造这种双功能三维打印机的材料成本不到 560 美元,这为希望复制类似机器的研究人员提供了宝贵的启示。原创性/价值经改进的通用三维打印机平台提供了一种简便的后处理方法,无需将工件从床身移除。这种机制可以减少更换机器的停机时间。经证实,尺寸精度的提高和表面粗糙度值的降低提高了三维打印试样的价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Extreme roughness reduction and ultrafine quality of innovative dual function material extrusion 3D printer
Purpose This paper aims to use hybrid manufacturing (HM) to overcome several drawbacks of material extrusion three-dimensional (3D) printers, such as low dimension ranging from 0.2 to 0.5 µm, resulting in a noticeable staircase effect and elevated surface roughness. Design/methodology/approach Subtractive manufacturing (SM) through computer numerical control milling is renowned for its precision and superior surface finish. This study integrates additive manufacturing (AM) and SM into a single material extrusion 3D printer platform, creating a HM system. Two sets of specimens, one exclusively printed and the other subjected to both printing and milling, were assessed for dimension accuracy and surface roughness. Findings The outcomes were promising, with postmilling accuracy reaching 99.94%. Significant reductions in surface roughness were observed at 90° (93.4% decrease from 15.598 to 1.030 µm), 45° (89% decrease from 26.727 to 2.946 µm) and the face plane (71% decrease from 12.176 to 3.535 µm). Practical implications The 3D printer was custom-built based on material extrusion and modified with an additional milling tool on the same gantry. An economic evaluation based on cost-manufacturing demonstrated that constructing this dual-function 3D printer costs less than US$560 in materials, offering valuable insights for researchers looking to replicate a similar machine. Originality/value The modified general 3D printer platform offered an easy way to postprocessing without removing the workpiece from the bed. This mechanism can reduce the downtime of changing the machine. The proven increased dimension accuracy and reduced surface roughness value increase the value of 3D-printed specimens.
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