材料科学
复合材料
熔丝制造
极限抗拉强度
选择性激光烧结
碳化硼
制作
聚合物
3D打印
喷嘴
烧结
热固性聚合物
先进复合材料
热的
熔融沉积模型
航空航天
碳纤维
碳化物
碳化硅
挤压
蛋白质丝
疲劳极限
图层(电子)
作者
N. Karthik,Siddappa I. Bekinal,Satvasheel Powar,Mrityunjay Doddamani
摘要
ABSTRACT This review comprehensively examines the synthesis, material characterization, and diverse applications of additively manufactured poly(ether ketone ketone) (PEKK) and its composites. The paper highlights that, through optimized additive manufacturing techniques such as fused filament fabrication (FFF) and selective laser sintering (SLS), PEKK composites can achieve up to 90% of the tensile strength of injection‐molded counterparts after post‐process annealing. The review details how processing parameters—including nozzle temperature, layer thickness, and build orientation—significantly influence the microstructure, crystallinity, and mechanical behavior of PEKK parts. Incorporation of fillers such as carbon fibers, graphene, and boron carbide further enhances thermal stability, electrical conductivity, and wear resistance, expanding PEKK's suitability for aerospace, biomedical, tribological, and space applications. Notably, PEKK demonstrates exceptional radiation resistance, retaining over 90% mechanical performance after prolonged space exposure, and exhibits high shape recovery ratios (> 90%) in 4D‐printed shape memory devices. The review also discusses PEKK's recyclability and circularity potential, as well as current challenges such as achieving consistent filament quality and minimizing porosity. These insights establish PEKK as a versatile, high‐performance polymer for advanced engineering and medical applications.
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