An investigation of in-situ AFP process parameters using CF/LM-PAEK

IF 1.8 Q3 ENGINEERING, MANUFACTURING

Advanced Manufacturing: Polymer & Composites Science Pub Date : 2020-10-07 DOI:10.1080/20550340.2020.1826772

I. Schiel, L. Raps, A. Chadwick, I. Schmidt, Manuel Simone, S. Nowotny

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引用次数: 13

Abstract

Abstract In recent years the use of thermoplastics has become popular in aerospace applications, with a primary focus on fiber-reinforced composites. Displaying greatly improved mechanical properties, new components using these materials still need to be characterized and their suitability for aviation applications demonstrated. A common restriction to the implementation of fiber-reinforced thermoplastic parts is the almost default autoclave manufacturing, which is both time consuming and expensive. Aiming for a more economical final product, this study utilizes a one-step in-situ Automated Fiber Placement (AFP) process to produce samples for mechanical and thermal characterization. The recently developed and highly popular material CF/LM-PAEK was used within this study, with the four major AFP processing parameters varied to assess material sensitivity. Test samples were manufactured using Design of Experiment (DoE). Subsequently, single lap shear (SLS) and differential scanning calorimetry (DSC) tests were performed to assess consolidation quality. With rising tooling temperature, both SLS strength and crystallinity increase up to 31 MPa and 25%, respectively. A post-manufacturing tempering process improved crystallinity of the tested CF/LM-PAEK specimens up to 29% and SLS strength up to 38 MPa. Within the tested parameter range, CF/LM-PAEK appeared to be unaffected by increasing layup speed, which is a promising aspect with regard to faster industrial production. Graphical Abstract

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基于CF/LM-PAEK的原位AFP工艺参数研究

近年来，热塑性塑料在航空航天领域的应用越来越广泛，主要集中在纤维增强复合材料上。使用这些材料的新部件显示出大大改善的机械性能，但仍需要对其进行表征，并证明其在航空应用中的适用性。实现纤维增强热塑性塑料部件的一个常见限制是几乎默认的高压灭菌器制造，这既耗时又昂贵。为了获得更经济的最终产品，本研究利用一步原位自动纤维放置(AFP)工艺来生产用于机械和热表征的样品。本研究使用了最近开发和非常流行的材料CF/LM-PAEK，四个主要的AFP处理参数不同，以评估材料的敏感性。试验样品采用试验设计(Design of Experiment, DoE)制作。随后，进行单搭剪(SLS)和差示扫描量热(DSC)试验来评估固结质量。随着加工温度的升高，SLS的强度和结晶度分别增加了31 MPa和25%。制造后回火工艺使CF/LM-PAEK试样的结晶度提高了29%，SLS强度提高了38 MPa。在测试参数范围内，CF/LM-PAEK似乎不受增加上铺速度的影响，这对于更快的工业生产来说是一个有希望的方面。图形抽象

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