Acta Aeronautica et Astronautica Sinica ›› 2024, Vol. 45 ›› Issue (5): 529677-529677.doi: 10.7527/S1000-6893.2023.29677
• Reviews • Previous Articles Next Articles
Received:
2023-09-05
Revised:
2023-09-21
Accepted:
2023-10-17
Online:
2024-03-15
Published:
2023-12-13
Contact:
Rui SI
E-mail:sirui@comac.cc
CLC Number:
Rui SI, Yong CHEN. Application trends of additive manufacturing technology for civil aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(5): 529677-529677.
Table 1
Raw materials and bonding mechanisms for different additive manufacturing processes
增材制造工艺 | 原材料 | 结合机制 | 激活源 |
---|---|---|---|
立体光固化(SLA) | 液态或糊状的光敏树脂 | 化学反应固化 | 能量光源照射 |
材料喷射 | 液态光敏树脂或熔融态的蜡 | 化学反应粘结或将熔融材料固化粘结 | 用于实现化学反应粘结的辐射光源或实现熔融材料固化粘结的温度场 |
粘结剂喷射 | 粉末、粉末混合物或特殊材料及液态粘结剂、交联剂 | 化学反应和(或)热反应固化粘结 | 取决于粘结剂和(或)交联剂,与所发生的化学反应相关 |
粉末床熔融 | 热塑性聚合物、纯金属或合金、陶瓷等各种不同粉末 | 热反应固结 | 激光、电子束和(或)红外灯等产生的热能 |
材料挤出 | 线材或膏体,典型材料包括热塑性和结构陶瓷材料 | 热黏结或化学反应粘结 | 热、超声或部件之间的化学反应 |
定向能量沉积 | 以金属为主的粉材或丝材,为实现特定用途可加入陶瓷颗粒 | 热反应固结(熔化和凝固) | 激光、电子束、电弧或等离子束等 |
复合增材制造 | 纸、金属箔、聚合物等复合片材 | 热反应、化学反应结合或超声连接 | 局部或大范围加热,化学反应和超声换能器 |
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All copyright © editorial office of Chinese Journal of Aeronautics
Total visits: 6658907 Today visits: 1341