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纤维增强复合材料(FRCs)受传统制造工艺的技术限制,难以被加工出复杂的结构。近年来3D打印复合材料复杂结构的技术逐渐受到关注。本文综述了立体光固化成型技术(SLA)、选择性激光烧结(SLS)、熔融沉积成型(FDM)三类3D打印技术,并以FDM为例讨论了打印温度、速度、层厚对力学性能的影响,阐述了3D打印在纤维增强热塑性与热固性复合材料方面的应用,总结了FRCs在航空航天、汽车制造、体育器材、医疗领域行业的应用现状,指出了目前3D打印FRCs应用中存在的问题和可能的解决方案,并展望了FRCs智能化、绿色化的发展趋势。
Abstract:Fiber reinforced composites(FRCs) have long been constrained by the technical limitations of conventional manufacturing processes, making it challenging to fabricate complex structural configurations. In recent years, the technology of 3D printing complex structures of composite materials has gradually attracted attention. This paper provides a comprehensive review of three major 3D printing techniques—stereolithography(SLA), selective laser sintering(SLS), and fused deposition modeling(FDM). Using FDM as a representative example, the effects of printing temperature, speed, and layer thickness on mechanical properties are examined. The applications of 3D printing in both thermoplastic and thermoset fiber-reinforced composites are elaborated. Furthermore, the current utilization status of FRCs in sectors such as aerospace, automotive manufacturing, sports equipment, and medical devices is summarized. Existing challenges in the application of 3D printed FRCs are identified along with potential solutions, and future prospects for the intelligent and sustainable development of FRCs are outlined.
[1] WAMBUA P,IVENS J,VERPOEST I.Natural fibres:can they replace glass in fibre reinforced plastics?[J].Composites Science and Technology,2003,63(9):1259-1264.
[2] 关博文,张代军,王成博,等.基于FDM的连续纤维增强复合材料3D打印技术研究进展 [J].复合材料科学与工程,2025(11):145-152.GUAN B W,ZHANG D J,WANG C B,et al.Research progress on 3D printing technology of continuous fiber reinforced composites based on FDM [J].Composites Science and Engineering,2025(11):145-152.
[3] WAN X,LUO L,LIU Y J,et al.Direct ink writing based 4D printing of materials and their applications [J].Advanced Science,2020,7(16):2001000.
[4] WU J J,GUO J,LINGHU C H,et al.Rapid digital light 3D printing enabled by a soft and deformable hydrogel separation interface [J].Nature Communications,2021,12:6070.
[5] GAO Y,XU L,ZHAO Y,et al.3D printing preview for stereo-lithography based on photopolymerization kinetic models [J].Bioactive Materials,2020,5(4):798-807.
[6] ZUO H,LIU Z H,ZHANG L Z,et al.Self-healing materials enable free-standing seamless large-scale 3D printing [J].Science China Materials,2021,64(7):1791-1800.
[7] LI N Y,LINK G,WANG T,et al.Path-designed 3D printing for topological optimized continuous carbon fibre reinforced composite structures [J].Composites Part B:Engineering,2020,182:107612.
[8] FIJUL KABIR S M,MATHUR K,SEYAM A M.A critical review on 3D printed continuous fiber-reinforced composites:History,mechanism,materials and properties [J].Composite Structures,2020,232:111476.
[9] SCHMIDT L.21st century sports[M].Springer,2020.
[10] HORVATH J,CAMERON R.Mastering 3D printing[M].Apress,2020.
[11] LIU Z,SONG K,GAO B,et al.Microstructure and mechanical properties of Al2O3/ZrO2 directionally solidified eutectic ceramic prepared by laser 3D printing [J].Journal of Materials Science & Technology,2016,32(4):320-325.
[12] WANG C,HUANG W,ZHOU Y,et al.3D printing of bone tissue engineering scaffolds [J].Bioactive Materials,2020,5(1):82-91.
[13] HAIBE A A,VEMUGANTI S.Flexural response comparison of nylon-based 3D-printed glass fiber composites and epoxy-based conventional glass fiber composites in cementitious and polymer concretes [J].Polymers,2025,17(2):218.
[14] RANEY J R,COMPTON B G,MUELLER J,et al.Rotational 3D printing of damage-tolerant composites with programmable mechanics [J].Proceedings of the National Academy of Sciences of the United States of America,2018,115(6):1198-1203.
[15] LI T T,CHEN Y Y,WANG L F.Enhanced fracture toughness in architected interpenetrating phase composites by 3D printing [J].Composites Science and Technology,2018,167:251-259.
[16] MUKHTARKHANOV M,PERVEEN A,Talamona D.Application of stereolithography based 3D printing technology in investment casting [J].Micromachines,2020,11(10):946.
[17] MELCHELS F P W,FEIJEN J,GRIJPMA D W.A review on stereolithography and its applications in biomedical engineering [J].Biomaterials,2010,31(24):6121-6130.
[18] LI W L,WANG M,MA H L,et al.Stereolithography apparatus and digital light processing-based 3D bioprinting for tissue fabrication [J].iScience,2023,26(2):106039.
[19] LUPONE F,PADOVANO E,CASAMENTO F,et al.Process phenomena and material properties in selective laser sintering of polymers:a review [J].Materials,2022,15(1):183.
[20] KOLOSSOV S,BOILLAT E,GLARDON R,et al.3D FE simulation for temperature evolution in the selective laser sintering process [J].International Journal of Machine Tools and Manufacture,2004,44(2/3):117-123.
[21] MA F,ZHANG H,HON K K B,et al.An optimization approach of selective laser sintering considering energy consumption and material cost [J].Journal of Cleaner Production,2018,199:529-537.
[22] MAZZOLI A.Selective laser sintering in biomedical engineering [J].Medical & Biological Engineering & Computing,2013,51(3):245-256.
[23] 龙昱,李岩,付昆昆.3D打印纤维增强复合材料工艺和力学性能研究进展 [J].复合材料学报,2022,39(9):4196-4212.LONG Y,LI Y,FU K K.Recent advances in 3D printed fiber reinforced composites:Processing technique and mechanical performance [J].Acta Materiae Compositae Sinica,2022,39(9):4196-4212.
[24] RAJAN K,SAMYKANO M,KADIRGAMA K,et al.Fused deposition modeling:process,materials,parameters,properties,and applications [J].The International Journal of Advanced Manufacturing Technology,2022,120(3):1531-1570.
[25] MOHAMED O A,MASOOD S H,BHOWMIK J L.Optimization of fused deposition modeling process parameters:a review of current research and future prospects [J].Advances in Manufacturing,2015,3(1):42-53.
[26] 明越科,王奔,周晋,等.基于3D打印的连续纤维增强热固性复合材料性能及其应用探索 [J].航空制造技术,2021,64(15):58-65.MING Y K,WANG B,ZHOU J,et al.Performance and applications of 3D printed continuous fiber-reinforced thermosetting composites [J].Aeronautical Manufacturing Technology,2021,64(15):58-65.
[27] DING S L,ZOU B,WANG P,et al.Effects of nozzle temperature and building orientation on mechanical properties and microstructure of PEEK and PEI printed by 3D-FDM [J].Polymer Testing,2019,78:105948.
[28] DOU H,CHENG Y Y,YE W G,et al.Effect of process parameters on tensile mechanical properties of 3D printing continuous carbon fiber-reinforced PLA composites [J].Materials,2020,13(17):3850.
[29] COPPOLA B,CAPPETTI N,DI MAIO L,et al.Influence of 3D printing parameters on the properties of PLA/clay nanocomposites [J].AIP Conference Proceedings,2018,1981:020064.
[30] TIAN X Y,LIU T F,YANG C C,et al.Interface and performance of 3D printed continuous carbon fiber reinforced PLA composites [J].Composites Part A:Applied Science and Manufacturing,2016,88:198-205.
[31] GENG P,ZHAO J,WU W Z,et al.Effects of extrusion speed and printing speed on the 3D printing stability of extruded PEEK filament [J].Journal of Manufacturing Processes,2019,37:266-273.
[32] WU W Z,GENG P,LI G W,et al.Influence of layer thickness and raster angle on the mechanical properties of 3D-printed PEEK and a comparative mechanical study between PEEK and ABS [J].Materials,2015,8(9):5834-5846.
[33] PAPPAS J M,THAKUR A R,LEU M C,et al.A comparative study of pellet-based extrusion deposition of short,long,and continuous carbon fiber-reinforced polymer composites for large-scale additive manufacturing [J].Journal of Manufacturing Science and Engineering,2021,143(7):071012.
[34] 任佳军,孙颖,鞠博文,等.纤维增强热塑性复合材料3D打印研究进展 [J].复合材料科学与工程,2023(11):122-128.REN J J,SUN Y,JU B W,et al.Research progress in 3D printing of fiber-reinforced thermoplastic composites [J].Composites Science and Engineering,2023(11):122-128.
[35] MING Y K,ZHANG S Q,HAN W,et al.Investigation on process parameters of 3D printed continuous carbon fiber-reinforced thermosetting epoxy composites [J].Additive Manufacturing,2020,33:101184.
[36] DONG J H,DING H X,WANG Q,et al.A 3D-printed scaffold for repairing bone defects [J].Polymers,2024,16(5):706.
[37] UEDA M,KISHIMOTO S,YAMAWAKI M,et al.3D compaction printing of a continuous carbon fiber reinforced thermoplastic [J].Composites Part A:Applied Science and Manufacturing,2020,137:105985.
[38] ICHIHARA N,OHNO S,UEDA M,et al.High axial compressive strength in 3D-printed continuous carbon fiber reinforced thermoplastics by controlling printing forces [J].Composites Part B:Engineering,2025,291:112052.
[39] EL-JAKL M,LABERGE LEBEL L.Fibre waviness reduction in thermoplastic pultrusion by using DREF yarns [J].Composites Part B:Engineering,2025,288:111908.
[40] NAWAFLEH N,CELIK E.Additive manufacturing of short fiber reinforced thermoset composites with unprecedented mechanical performance [J].Additive Manufacturing,2020,33:101109.
[41] MONTICELI F,NEVES R,ORNAGHI H,et al.Prediction of bending properties for 3D-printed carbon fibre/epoxy composites with several processing parameters using ANN and statistical methods [J].Polymers,2022,14(17):3668.
[42] 明越科,段玉岗,王奔,等.高性能纤维增强树脂基复合材料3D打印 [J].航空制造技术,2019,62(4):34-38.MING Y K,DUAN Y G,WANG B,et al.3D printing for high performance fiber reinforced polymer composites [J].Aeronautical Manufacturing Technology,2019,62(4):34-38.
[43] TEKLAL F,DJEBBAR A,ALLAOUI S,et al.A review of analytical models to describe pull-out behavior-Fiber/matrix adhesion [J].Composite Structures,2018,201:791-815.
[44] TIAN X Y,TODOROKI A,LIU T F,et al.3D printing of continuous fiber reinforced polymer composites:development,application,and prospective [J].Chinese Journal of Mechanical Engineering:Additive Manufacturing Frontiers,2022,1(1):100016.
[45] 田小永,刘腾飞,杨春成,等.高性能纤维增强树脂基复合材料3D打印及其应用探索 [J].航空制造技术,2016,59(15):26-31.TIAN X Y,LIU T F,YANG C C,et al.3D printing for high performance fiber reinforced polymer composites and exploration on its applications [J].Aeronautical Manufacturing Technology,2016,59(15):26-31.
[46] SONG Y Z,GHAFARI Y,ASEFNEJAD A,et al.An overview of selective laser sintering 3D printing technology for biomedical and sports device applications:Processes,materials,and applications [J].Optics & Laser Technology,2024,171:110459.
[47] YAO X H,LUAN C C,ZHANG D M,et al.Evaluation of carbon fiber-embedded 3D printed structures for strengthening and structural-health monitoring [J].Materials & Design,2017,114:424-432.
[48] GUAN T R,ZHU J X,CHEN Z F,et al.Effect of shallow straight-joint braided fabric geometrical parameters on fiber volume fraction [J].Science and Engineering of Composite Materials,2012,19(2):139-144.
[49] 杨来侠,刘波,刘腾飞,等.3D打印连续纤维增强聚碳酸酯复合材料预浸丝制备与性能 [J].复合材料学报,2023,40(10):5654-5665.YANG L X,LIU B,LIU T F,et al.Preparation and properties of 3D printing continuous fiber reinforced polycarbonate composite prepreg filaments [J].Acta Materiae Compositae Sinica,2023,40(10):5654-5665.
[50] CHENG P,PENG Y,LI S X,et al.3D printed continuous fiber reinforced composite lightweight structures:a review and outlook [J].Composites Part B:Engineering,2023,250:110450.
[51] LECHOWICZ P,KOSZALKA L,POZNIAK-KOSZALKA I,et al.Path optimization in 3D printer:Algorithms and experimentation system [C]//2016 4th International Symposium on Computational and Business Intelligence (ISCBI).Olten,Switzerland.IEEE,2016:137-142.
基本信息:
DOI:10.19886/j.cnki.dhdz.2025.0243
中图分类号:TB33;TP391.73
引用信息:
[1]彭清可,乔小兰,管清宝,等.3D打印纤维增强复合材料的研究进展[J].东华大学学报(自然科学版),2026,52(02):200-211.DOI:10.19886/j.cnki.dhdz.2025.0243.
基金信息:
国家自然科学基金(52073049); 载人空间站工程空间科学与应用项目(KJZ-YY-NJS0601); 东华大学2025年学科创新领域培育项目(xkcx-202521)
2026-01-30
2026-01-30
2026-01-30