电场驱动喷射沉积微纳3D打印技术及应用
|
摘要
微纳尺度3D打印是增材制造的前沿和研究热点,在航空航天、组织工程、生物医疗、微纳机电系统、新材料(超材料、轻量化材料、智能材料、复合材料)、新能源、柔性电子、印刷电子、结构电子、微纳光学器件、微流控器件、可穿戴电子产品、软体机器人等诸多领域和行业有着非常广泛的应用。介绍了课题组近年提出并建立的一种微纳尺度增材制造新工艺——电场驱动喷射沉积微纳3D打印,并论述了近年研究进展和取得的重要成果,介绍了5个工程应用案例。电场驱动喷射沉积微纳3D打印为微纳尺度3D打印和微纳制造提供了一种全新的解决方案,具有良好的工业化应用前景。
Micro-and Nano-scale 3D printing is a new frontier in additive manufacturing. It has been used in various fields including the aerospace industry, tissue engineering, MEMS, new materials(metamaterials, lightweight materials, smart materials, composite materials), new energy, flexible electronics, printed electronics, micro/nano optical devices, soft-body robots, etc. This paper presents a novel micro-and nano-scale 3D printing developed by our research group which is named the electric-field-driven jet deposition based micro-and nano-scale 3D printing technique. The recent progresses and significant results of this technique are described. In addition, five typical cases are introduced. The electric-field-driven jet deposition based micro-and nano-scale 3D printing provides a new and prospect solution for micro-nano scale 3D printing and micro-and nano manufacturing, and shows a high potential in industrial applications.
Micro-and Nano-scale 3D printing is a new frontier in additive manufacturing. It has been used in various fields including the aerospace industry, tissue engineering, MEMS, new materials(metamaterials, lightweight materials, smart materials, composite materials), new energy, flexible electronics, printed electronics, micro/nano optical devices, soft-body robots, etc. This paper presents a novel micro-and nano-scale 3D printing developed by our research group which is named the electric-field-driven jet deposition based micro-and nano-scale 3D printing technique. The recent progresses and significant results of this technique are described. In addition, five typical cases are introduced. The electric-field-driven jet deposition based micro-and nano-scale 3D printing provides a new and prospect solution for micro-nano scale 3D printing and micro-and nano manufacturing, and shows a high potential in industrial applications.
引文
[1]LEWISJ A,AHN B Y.T h r e edimensional printed electronics[J].Nature,2015,518(7537):42-43.
[2]DERBY B.Printing and prototyping of tissues and scaffolds[J].Science,2012,338(6109):921-926.
[3]兰红波,李涤尘,卢秉恒.微纳尺度3D打印[J].中国科学:技术科学,2015,45(9):919-940.LAN Hongbo,LI Dichen,LU Bingheng.Micro-nanoscale 3D printing[J].Scientia Sinica Technologica,2015,45(9):919-940.
[4]VAEZI M,SEITZ H,YANG S.Areview on 3D micro-additive manufacturing technologies[J].International Journal of Advanced Manufacturing Technology,2013,67(5-8):1721-1754.
[5]MACDONALD E,WICK E RR.Multiprocess 3D printing for increasing component functionality[J].Science,2016,353(6307):2093-2093.
[6]TRUBY R L,LEWIS J A.Printing soft matter in three dimensions[J].Nature,2016,540(7633):371-378.
[7]COMPTON B G,LEWIS J A.3D-printing of lightweight cellular composites[J].Advanced Materials,2015,26(34):5930-5935.
[8]BARTLETT N W,TOLLEY M T,OVERVELDE J T,et al.A 3D-printed,functionally graded soft robot powered by combustion[J].Science,2015,349(6244):161-165.
[9]KONG Y L,TAMARGO I A,KIMH,et al.3D printed quantum dot light-emitting diodes[J].Nano Letters,2014,14(12):7017-7023.
[10]QIAN L,LAN H B,ZHANG G M,et al.A novel microscale 3D printing based on electric-field-driven jet deposition[C]//ASME 13th International Manufacturing Science and Engineering Conference.New Yo rk:American Society of Mechanical Engineers,2018.
[11]钱垒,兰红波,赵佳伟,等.电场驱动喷射沉积3D打印[J].中国科学:技术科学,2018,48(7):773-782.QIAN Lei,LAN Hongbo,ZHAO Jiawei,et al.Electric-field-driven jet deposition 3Dprinting[J].Scientia Sinica Technologica,2018,48(7):773-782.
[2]DERBY B.Printing and prototyping of tissues and scaffolds[J].Science,2012,338(6109):921-926.
[3]兰红波,李涤尘,卢秉恒.微纳尺度3D打印[J].中国科学:技术科学,2015,45(9):919-940.LAN Hongbo,LI Dichen,LU Bingheng.Micro-nanoscale 3D printing[J].Scientia Sinica Technologica,2015,45(9):919-940.
[4]VAEZI M,SEITZ H,YANG S.Areview on 3D micro-additive manufacturing technologies[J].International Journal of Advanced Manufacturing Technology,2013,67(5-8):1721-1754.
[5]MACDONALD E,WICK E RR.Multiprocess 3D printing for increasing component functionality[J].Science,2016,353(6307):2093-2093.
[6]TRUBY R L,LEWIS J A.Printing soft matter in three dimensions[J].Nature,2016,540(7633):371-378.
[7]COMPTON B G,LEWIS J A.3D-printing of lightweight cellular composites[J].Advanced Materials,2015,26(34):5930-5935.
[8]BARTLETT N W,TOLLEY M T,OVERVELDE J T,et al.A 3D-printed,functionally graded soft robot powered by combustion[J].Science,2015,349(6244):161-165.
[9]KONG Y L,TAMARGO I A,KIMH,et al.3D printed quantum dot light-emitting diodes[J].Nano Letters,2014,14(12):7017-7023.
[10]QIAN L,LAN H B,ZHANG G M,et al.A novel microscale 3D printing based on electric-field-driven jet deposition[C]//ASME 13th International Manufacturing Science and Engineering Conference.New Yo rk:American Society of Mechanical Engineers,2018.
[11]钱垒,兰红波,赵佳伟,等.电场驱动喷射沉积3D打印[J].中国科学:技术科学,2018,48(7):773-782.QIAN Lei,LAN Hongbo,ZHAO Jiawei,et al.Electric-field-driven jet deposition 3Dprinting[J].Scientia Sinica Technologica,2018,48(7):773-782.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |