桥接(联网)
制作
减色
材料科学
过程(计算)
纳米技术
联轴节(管道)
机械工程
压实
计算机科学
领域(数学)
聚合物
多孔性
联动装置(软件)
联锁
在制品
稳健性(进化)
机械加工
工艺设计
硬化(计算)
过程集成
多尺度建模
作者
Hao Wang,Bing Han,Peiyuan Zheng,Zhipeng Liu,Qi Zhang
标识
DOI:10.1007/s42114-025-01573-x
摘要
This review proposes a defect-driven framework to advance extrusion-based polymeric hybrid additive manufacturing, systematically addressing three intrinsic limitations: geometric inaccuracy and surface roughness, high porosity, and weak interlayer bonding. By integrating additive manufacturing (AM) with subtractive machining, dynamic compaction, and multi-energy field assistance, we establish a multiscale process–structure–property linkage that connects interfacial micro-mechanisms to macroscopic structural performance. Three representative hybrid paradigms are highlighted: (1) additive–subtractive hybridization combining FDM/DIW with milling or laser cutting to effectively minimize dimensional deviation and improve surface finish through geometric recalibration; (2) additive–equivalent compaction utilizing roller- or hammer-assisted pressure to activate polymer chain diffusion across interlayer interfaces, markedly reducing porosity and enhancing bonding strength; and (3) multi-energy-field assistance, where ultrasonic, thermal, and magnetic fields modulate crystallization behavior and anisotropic functionality. Experimental studies across various materials and geometries collectively demonstrate that hybrid process integration can suppress defect formation by coupling molecular diffusion dynamics with process optimization. With continuing progress in multi-field coupling and intelligent process control, hybrid additive manufacturing is evolving toward more adaptive, digitally driven, and multifunctional fabrication systems. This technological convergence is expected to provide greater design freedom and improved manufacturing efficiency for next-generation polymers and composites.
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