Multi-material Printing of Direct Ink Writing: a State of the Art Review
ZHANG Jing1, ZHOU Jing2, DUAN Guolin1
1 School of Mechanical Engineering, Hebei University of Technology, Tianjin 300401, China 2 College of Mechanical Engineering, Tianjin University of Science and Technology, Tianjin 300222, China
Abstract: As a widely used process and method in additive manufacturing technology, direct ink writing has the advantages of low equipment cost, high material utilization rate, simple operation process, low energy requirement and environmental friendliness. In recent years, direct ink writing technology has become one of the research hotspots of additive manufacturing technology. This paper introduces the mechanism and advantages of direct ink writing technology, from the three aspects of mixed material printing, material mixed printing and functionally graded material printing, elaborates the application of direct ink writing technology in biomedicine, construction engineering, energetic materials and food engineering, etc., and summarizes the technical difficulties and key issues of printing methods of different materials.It also discusses the challenges and the future development trend of direct ink writing technology.
张静, 周婧, 段国林. 基于直写成型技术的多材料打印研究进展[J]. 材料导报, 2022, 36(8): 20080135-8.
ZHANG Jing, ZHOU Jing, DUAN Guolin. Multi-material Printing of Direct Ink Writing: a State of the Art Review. Materials Reports, 2022, 36(8): 20080135-8.
1 Li Q, Li B, Zhou J, et al. Journal of Inorganic Materials,2005(1),13(in Chinese). 李琦,李勃,周济,等.无机材料学报,2005(1),13. 2 Sun Y H, Peng C Q, Wang X F, et al. Chinese Journal of Nonferrous Metals,2015,25(6),1525(in Chinese). 孙月花,彭超群,王小锋,等.中国有色金属学报,2015,25(6),1525. 3 Wang S Y, Li S J, Tu Y Y, et al. Chinese Journal of New Drugs,2020,29(8),881(in Chinese). 王森怡,李思佳,涂迎盈,等.中国新药杂志,2020,29(8),881. 4 Ghidini T. Journal of Thoracic Disease,2018,10(20),S2363. 5 Nadagouda M N, Rastogi V, Ginn M. Current Opinion in Chemical Engineering,2020,28,152. 6 Zhang X, Zhang Y. Cell Biochem Biophys,2015,72(3),777. 7 Cesarano J, Segalman R, Calvert P. Ceramics Industry,1998,148(4),94. 8 Liu C Q, Wang H X, Li Z, et al. Chinese Journal of Experimental Formulae,2020,26(3),236(in Chinese). 刘长青,王海霞,李正,等.中国实验方剂学杂志,2020,26(3),236. 9 Kabir S M, Mathur K, Seyam A M. Composite Structures,2020,232,111476. 10 Cheng K, Lan H B, Zou S T, et al. Science in China: Science of Techno-logy,2017,47(2),149(in Chinese). 程凯,兰红波,邹淑亭,等.中国科学:技术科学,2017,47(2),149. 11 Ge J, Bai J, Yang Y, et al. Journal of Building Materials,2020,23(2),414(in Chinese). 葛杰,白洁,杨燕,等.建筑材料学报,2020,23(2),414. 12 Lille M, Nurmela A, Nordlund E, et al. Journal of Food Engineering,2018,220,20. 13 Zhong G,Mohammad V,Mei X, et al. ACS Omega,2019,4(21),19238. 14 Nida S, Anukiruthika T, Moses J A, et al. Waste and Biomass Valorization,2021,12(1),81. 15 Zhang B, Luo Y, Ma L, et al. Bio-design and Manufacturing,2018,1(1),2. 16 Mao Y, Zhong L, Zhou X, et al. Advanced Engineering Materials,2019,21,1900825. 17 Godoi F C, Prakash S, Bhandari B, et al. Journal of Food Engineering,2016,179,44. 18 Smay J E, Cesarano J, Lewis J A, et al. Langmuir,2002,18(14),5429. 19 Perrot A, Rangeard D, Pierre A. Materials & Structures,2016,49(4),1213. 20 Le T T, Austin S A, Lim S, et al. Materials and Structures,2012,45(8),1221. 21 Zhu S, Stieger M A, Goot A J, et al. Innovative Food Science and Emerging Technologies,2019,58,102214. 22 An T, Hwang K T, Kim J. Ceramics International,2020,46(5),6469. 23 Liu Z B, Zhang M, Bhandari B, et al. Trends in Food Science & Techno-logy,2017,69,83. 24 Cotabarren I M, Cruces S, Palla C A. Food Research International,2019,126,108676. 25 Liu Q L, Yang Q R. Journal of Building Materials,2020,23(5),6(in Chinese). 刘巧玲,杨钱荣.建筑材料学报,2020,23(5),6. 26 Durban M M, Golobic A M, Bukovsky E V, et al. Advanced Materials Technologies,2018,3(12),1800120. 27 Liu Y W, Yu Y, Liu C S, et al. LWT,2019,102,338. 28 Smay J E, Cesarano J, Lewis J A. Langmuir,2002,18,5429. 29 Lewis J A, Smay J E, Stuecker J, et al. Journal of the American Ceramic Society,2006,89(12),3599. 30 Leo S, Tallon C, Franks G V. Journal of the American Ceramic Society,2014,97,3807. 31 Rueschhoff L M, Costakis W J, Michie M, et al. International Journal of Applied Ceramic Technology,2016,13(5),821. 32 Wang H Y, Shen J P, Kline D J, et al. Advanced Materials,2019,31(23),1806575. 33 Liao J, Chen H, Luo H, et al. Journal of Materials Chemistry C,2017,24(5),5867. 34 Cotabarren I M, Cruces S, Palla C A. Food Research International,2019,126,108676. 35 Leo S, Tallon C, Franks G V. Journal of the American Ceramic Society,2014,97,3807. 36 Sun J, Gao L. Journal of the European Ceramic Society,2001,21,2447. 37 Cesarano J, Aksay I A. Journal of the American Ceramic Society,1988,71,1062. 38 Costakis W J, Rueschhoff L M, Diaz-Cano A I, et al. Journal of the European Ceramic Society,2016,14(36),3249. 39 Truby R L, Lewis J A. Nature: International Weekly Journal of Science,2016,540(7633),371. 40 Lozano R, Stevens L,Thompson B C, et al. Biomaterials,2015,67,264. 41 Li T, Zhai D, Ma B, et al. Advanced Science,2019,6(19),1901146. 42 Kim G H, Ahn S, Kim Y Y, et al. Journal of Materials Chemistry,2011,21(17),6165. 43 Kolesky D B, Truby R L, Sydney G A, et al. Advanced Materials (Deerfield Beach, Fla.),2014,26(19),2966. 44 Hansen C J, Saksena R, Kolesky D B. Advanced Materials,2013,25(1),96. 45 Lee V, Singh G, Trasatti J P, et al. Tissue Engineering: Part C,2014,20(6),473. 46 Lee W, Debasitis J C, Lee V K, et al. Biomaterials,2009,30(8),1587. 47 He C, Zhang M, Guo C F. Innovative Food Science and Emerging Technologies,2020,59,102250. 48 Zhu Y, Huan S Q, Bai L, et al. ACS Applied Materials & Interfaces,2020,12(9),11240. 49 Dick A, Bhandari B, Prakash S. Meat Science,2019,153,35. 50 Aebe M, Shirvanimoghaddam K. Applied Materials Today,2016,5(1),223. 51 Niu R Q, Zou H T, Wu Q, et al. Materials Reports A: Review papers,2015,29(10),128(in Chinese). 牛瑞琴,邹汉涛,吴倩,等.材料导报:综述篇,2015,29(10),128. 52 Liu Y F, Li Y N, Liu K, et al. New Chemical Materials,2020,48(2),15(in Chinese). 刘亚飞,李亚楠,刘奎,等.化工新型材料,2020,48(2),15. 53 Liu W, Li N, Zhou B, et al. Journal of Mechanical Engineering,2019,55(20),128(in Chinese). 刘伟,李能,周标,等.机械工程学报,2019,55(20),128. 54 Giachini P A, Gupta S S, Wang W, et al. Science Advances,2020,6(8),6. 55 Deuser B K, Tang L, Landers R G, et al. Journal of Manufacturing Science & Engineering,2013,135(4),041015. 56 Ma W D, Li S J, Yang L P, et al. China Mechanical Engineering,2019,30(13),1600(in Chinese). 马维东,李淑娟,杨磊鹏,等.中国机械工程,2019,30(13),1600. 57 Jiao P D, Li S J, Yang L P, et al. China Mechanical Engineering,2017,28(6),733(in Chinese). 焦盼德,李淑娟,杨磊鹏,等.中国机械工程,2017,28(6),733. 58 Tang D, Hao L, Li Y, et al. Journal of Alloys and Compounds,2019,814,152275. 59 Studart A R, Libanori R, Erb R M. Functional gradients in biological composites, Bio- and Bioinspired Nanomaterials, Verlag GmbH & Co.KGaA, Germany,2014,pp.337. 60 Li S, Wang K W. Bioinspiration & Biomimetics,2016,12(1),011001. 61 Studart A R. Advanced Materials,2012,24(37),5024. 62 Claussen K U, Scheibel T, Schmidt H W, et al. Macromolecular Mate-rials and Engineering,2012,297(10),938. 63 Ren L Q, Song Z Y, Liu H L,et al. Materials & Design,2018,156,470.