Rouway Marwane, Tarfaoui Mostapha, Chakhchaoui Nabil, Omari Lhaj El Hachemi, Fraija Fouzia, Cherkaoui Omar
LPMAT Laboratory, FSAC, Hassan II University, Casablanca, Morocco.
REMTEX Laboratory, ESITH, Casablanca, Morocco.
3D Print Addit Manuf. 2023 Dec 1;10(6):1309-1319. doi: 10.1089/3dp.2021.0194. Epub 2023 Dec 11.
The global trend in additive manufacturing is the technology of three-dimensional (3D) printing with a high potential to avoid some of the weaknesses of conventional fabrication techniques. This new technology has been used to manufacture small tidal and wind turbines. In isolated areas, small turbines can be manufactured and assembled on-site for green energy production. The purpose of this document is to evaluate the thermomechanical behavior of a printed tidal turbine using Digimat-AM (Additive Manufacturing) with fused filament fabrication method. The finite element computes the mechanical deflection, temperature, residual stresses, and warpage fields of the printed part. The composites used during printing are thermoplastic polymers (acrylonitrile butadiene styrene, polyamide 6 [PA6], polyamide 12 [PA12], and polyetherimide [PEI]) reinforced with carbon and glass fillers in the form of fibers and beads (CF/GF and CB/GB). Through the simulation, one could show that the blade printed with PEI-CB/CF has excellent mechanical performance of low mechanical deflection and warpage, compared to PA6-CB/CF. In addition, the fiber-shaped fillers are better than the bead-shaped ones for the 3D printing process. In general, this study has shown the potential and feasibility of 3D printing as an excellent opportunity in the fabrication of small blades in the future, but more studies are required to understand this potential.
增材制造的全球趋势是三维(3D)打印技术,它具有避免传统制造技术某些弱点的巨大潜力。这项新技术已被用于制造小型潮汐和风力涡轮机。在偏远地区,可以现场制造和组装小型涡轮机以生产绿色能源。本文档的目的是使用具有熔丝制造方法的Digimat-AM(增材制造)来评估打印潮汐涡轮机的热机械行为。有限元计算打印部件的机械挠度、温度、残余应力和翘曲场。打印过程中使用的复合材料是热塑性聚合物(丙烯腈丁二烯苯乙烯、聚酰胺6 [PA6]、聚酰胺12 [PA12] 和聚醚酰亚胺 [PEI]),用纤维和珠粒形式的碳和玻璃填料(CF/GF和CB/GB)增强。通过模拟可以表明,与PA6-CB/CF相比,用PEI-CB/CF打印的叶片具有低机械挠度和翘曲的优异机械性能。此外,对于3D打印过程,纤维状填料比珠粒状填料更好。总体而言,本研究表明3D打印在未来制造小型叶片方面具有潜力和可行性,但需要更多研究来了解这种潜力。