高性能聚合物粘合PEEK-NdFeB磁性复合材料的3D打印

L. Pigliaru, M. Rinaldi, L. Ciccacci, A. Norman, T. Rohr, T. Ghidini, F. Nanni
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引用次数: 28

摘要

稀土永磁体在高效、高能量密度的电机和发电机中发挥着越来越重要的作用。其中使用最多的是钕铁硼磁体,钕铁硼具有较高的剩余力、高矫顽力和能量积。然而,它们较差的耐腐蚀性使它们易于磁性退化。一种可能的解决方案是开发创新的高分子复合磁性材料。提出了制备钕铁硼填充聚合物基体(PEEK)粉末的双重目标,即保护磁性合金,使其免受腐蚀,并实现可形成长丝形式的新材料。该材料被用作3D打印过程中的原料,用于生产具有定制和优化设计的高性能磁铁。采用3 %的填料量(即:25、50和75?wt%)。制备了PEEK整齐长丝作为参考。通过不同的研究技术(DSC、DMTA、XRD、拉伸测试)评估了填料对复合材料主要热力学性能的影响,以及对3D打印过程的影响。熔丝制造(FFF)打印部件所表现出的磁性能证实了采用这种创新制造技术和高性能PEEK-NdFeB化合物相结合的可行性。对纯丝和复合丝进行的表征表明,填料的存在略微降低了热稳定性,提高了弹性模量,但降低了延性和最大抗拉强度。通过DSC分析,证实了填料的存在对结晶度有影响。在3D打印部件上进行的磁性测量表明,获得了有趣的磁性,证实了PEEK磁性3D打印复合材料的可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

3D printing of high performance polymer-bonded PEEK-NdFeB magnetic composite materials

3D printing of high performance polymer-bonded PEEK-NdFeB magnetic composite materials

Permanent Rare Earth magnets are becoming more and more important in efficient motors and generators with high energy density. Among them NdFeB magnets are the most employed, with NdFeB having higher remanence, high coercivity and energy product. Nevertheless,their poor corrosion resistance makes them susceptible to degradation of the magnetic properties. One possible solution is the development of innovative polymeric composite magnetic materials. The preparation of NdFeB powders filled polymeric matrix (PEEK), with a double goal of protecting the magnetic alloy is proposed, thus preventing it from corrosion, and to realize a new material that can be shaped in the form of filaments. This material was used as feedstock in the 3D printing process to produce high performance magnets with customized and optimized design. The PEEK-NdFeB filaments were produced with three percentages of filler amount(i.e. 25, 50 and 75?wt%). PEEK neat filaments were produced as reference. The influence of the filler on the main thermomechanical properties of the resulting composites, as well as its effect onthe 3D printing process were evaluated by means of different investigation techniques (DSC, DMTA, XRD, tensile testing). The magnetic properties exhibited by Fused Filament Fabrication (FFF) printed parts confirmed the feasibility of employing such a combination of an innovative manufacturing technique and high-performance PEEK-NdFeB compounds.

The characterization carried out on both neat and composite filaments evidenced that the presence of the filler slightly decreased the thermal stability, increased the elastic modulus while decreasing ductility and maximum tensile strength. By means of DSC analysis, it was confirmed that the crystallinity is influenced by the presence of the filler. Magnetic measurement performed on the 3D printed parts demonstrate that interesting magnetic properties were achieved, confirming the feasibility of the magnetic 3D printed composite with PEEK.

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