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基于大型机器人的聚合物与复合材料增材制造:失效模式与热模拟

Large-Scale Robot-Based Polymer and Composite Additive Manufacturing: Failure Modes and Thermal Simulation.

作者信息

Akbari Saeed, Johansson Jan, Johansson Emil, Tönnäng Lenny, Hosseini Seyed

机构信息

RISE Research Institutes of Sweden, Box 104, SE-431 22 Mölndal, Sweden.

Adaxis, 97 Allée Théodore Monod, 64210 Bidart, France.

出版信息

Polymers (Basel). 2022 Apr 24;14(9):1731. doi: 10.3390/polym14091731.

DOI:10.3390/polym14091731
PMID:35566900
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9105602/
Abstract

Additive manufacturing (AM) of large-scale polymer and composite parts using robotic arms integrated with extruders has received significant attention in recent years. Despite the contributions of great technical progress and material development towards optimizing this manufacturing method, different failure modes observed in the final printed products have hindered its application in producing large engineering structures used in aerospace and automotive industries. We report failure modes in a variety of printed polymer and composite parts, including fuel tanks and car bumpers. Delamination and warpage observed in these parts originate mostly from thermal gradients and residual stresses accumulated during material deposition and cooling. Because printing large structures requires expensive resources, process simulation to recognize the possible failure modes can significantly lower the manufacturing cost. In this regard, accurate prediction of temperature distribution using thermal simulations is the first step. Finite element analysis (FEA) was used for process simulation of large-scale robotic AM. The important steps of the simulation are presented, and the challenges related to the modeling are recognized and discussed in detail. The numerical results showed reasonable agreement with the temperature data measured by an infrared camera. While in small-scale extrusion AM, the cooling time to the glassy state is less than 1 s, in large-scale AM, the cooling time is around two orders of magnitudes longer.

摘要

近年来,使用与挤出机集成的机械臂对大型聚合物和复合材料部件进行增材制造(AM)受到了广泛关注。尽管在优化这种制造方法方面取得了巨大的技术进步和材料发展,但在最终打印产品中观察到的不同失效模式阻碍了其在航空航天和汽车工业中大型工程结构生产中的应用。我们报告了各种打印聚合物和复合材料部件中的失效模式,包括燃料箱和汽车保险杠。在这些部件中观察到的分层和翘曲主要源于材料沉积和冷却过程中积累的热梯度和残余应力。由于打印大型结构需要昂贵的资源,通过过程模拟来识别可能的失效模式可以显著降低制造成本。在这方面,使用热模拟准确预测温度分布是第一步。有限元分析(FEA)用于大型机械臂增材制造的过程模拟。介绍了模拟的重要步骤,并详细识别和讨论了与建模相关的挑战。数值结果与红外热像仪测量的温度数据显示出合理的一致性。在小规模挤出增材制造中,冷却至玻璃态所需的时间小于1秒,而在大规模增材制造中,冷却时间要长约两个数量级。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/c4bd47f2a80b/polymers-14-01731-g014.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/1fc58e2f9bb3/polymers-14-01731-g006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/9c7b3eb33c21/polymers-14-01731-g007.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/0d5520a5b56e/polymers-14-01731-g009.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/907a08ae88b9/polymers-14-01731-g010.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/7e7b34f52f6e/polymers-14-01731-g011.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b4d4/9105602/c4bd47f2a80b/polymers-14-01731-g014.jpg

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