基于电场驱动熔融喷射聚合物基复合材料高分辨率3D打印

doi:10.3901/JME.2020.23.193

机械工程学报 ›› 2020, Vol. 56 ›› Issue (23): 193-202.doi: 10.3901/JME.2020.23.193

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基于电场驱动熔融喷射聚合物基复合材料高分辨率3D打印

杨昆, 张广明, 李晓强, 杨建军, 彭子龙, 兰红波

青岛理工大学山东省增材制造工程技术研究中心青岛 266520

收稿日期:2020-01-17 修回日期:2020-09-16 出版日期:2020-12-05 发布日期:2021-01-11
作者简介:杨昆,女,1993年出生,主要研究方向为复合材料3D打印、微纳3D打印。E-mail:1419216282@qq.com;兰红波(通信作者),男,1970年出生,博士,教授,博士研究生导师。主要研究方向为微纳尺度3D打印、复合材料3D打印、多材料3D打印、大面积纳米压印光刻、微纳制造等。E-mail:hblan99@126.com
基金资助:
国家自然科学基金（51775288，51805287）和山东省重点研发计划（2018GGX103022）资助项目。

High-resolution 3D Printing of Polymer Matrix Composites Based on Electric-field-driven Fusion Jetting

YANG Kun, ZHANG Guangming, LI Xiaoqiang, YANG Jianjun, PENG Zilong, LAN Hongbo

Shandong Engineering Research Center for Additive Manufacturing, Qingdao University of Technology, Qingdao 266520

Received:2020-01-17 Revised:2020-09-16 Online:2020-12-05 Published:2021-01-11

摘要/Abstract

摘要： 针对当前聚合物基复合材料（Polymer matrix composites，PMC）成型存在打印分辨率低、打印材料受限、成型结构较为简单、工序复杂等方面的不足和局限性，尤其是还面临难以实现宏/微结构跨尺度高效制造的挑战性难题，提出一种基于电场驱动熔融喷射PMC高分辨率3D打印新工艺。阐述了基于电场驱动熔融喷射PMC高分辨率3D打印的基本原理和工艺流程。通过试验，揭示了主要工艺参数（碳填料含量、施加电压、螺杆转速、打印速度、加热温度等）对于打印件分辨率（精度）和质量的影响及其规律。利用自主搭建的试验平台，并结合试验优化的工艺参数和提出的两种打印模式，实现了多层石墨烯/聚乳酸（Polylactic acid，PLA）和多壁碳纳米管/PLA复合材料微尺度三维网格、多层石墨烯/PLA大高宽比薄壁圆环、多壁碳纳米管/PLA复合材料柔性导电网格以及其他聚合物复合材料3D结构典型工程案例的制造。研究结果表明，提出的电场驱动熔融喷射3D打印能实现高分辨聚合物基复合材料成型（使用内径300 μm喷嘴，实现了分辨率为40 μm的PMC特征结构制造），而且还具有大面积宏/微结构跨尺度集成制造的优势。

关键词: 电场驱动熔融喷射, 聚合物基复合材料, 高分辨3D打印, 跨尺度制造

Abstract: There are many disadvantages for existing forming methods of polymer matrix composites which involve the low resolution, limited printed materials, and poor capability of making complex structures, tedious processes, etc. In particular, it is always a challenge issue to implement multi-scale fabrication for macro/micro structures with high effectiveness. A high-resolution 3D printing process of polymer matrix composites based on electric-field-driven fusion jet is proposed. The fundamental principle and process flow of the proposed method are described. Furthermore, the effects and rules of main process parameters (mass fraction of carbon filler, applied voltage, screw speed, printing speed, heating temperature, etc.) on the resolution (accuracy) and quality of printed parts are revealed by a series of experiments. Finally, using the experimental setup independently developed by the research group, combining with the optimized process parameters and two printing modes proposed, some typical cases are demonstrated which include the micro 3D grids of multi-layer graphene (MLG)/polylactic acid (PLA) and multi-walled carbon nanotubes (MWCNT)/PLA composites, the large-aspect-ratio thin-walled ring of MLG/PLA composite, and flexible conductive structures of MWCNT/PLA composite, as well as some PMC 3D functional parts. The results show that the new 3D printing process can implement the high resolution printing for various PMS (using the nozzle with an inner diameter of 300 μm, the feature size of 40 μm for PMC has been achieved), and the multi-scale manufacturing of macro/micro-structures made of MWCNT, MLG, short carbon fiber reinforcement material and PLA matrix material can be realized.

Key words: electric-field-driven fusion jetting, polymer matrix composites, high-resolution 3D printing, multi-scale fabrication

中图分类号:

TB332

杨昆, 张广明, 李晓强, 杨建军, 彭子龙, 兰红波. 基于电场驱动熔融喷射聚合物基复合材料高分辨率3D打印[J]. 机械工程学报, 2020, 56(23): 193-202.

YANG Kun, ZHANG Guangming, LI Xiaoqiang, YANG Jianjun, PENG Zilong, LAN Hongbo. High-resolution 3D Printing of Polymer Matrix Composites Based on Electric-field-driven Fusion Jetting[J]. Journal of Mechanical Engineering, 2020, 56(23): 193-202.

参考文献

[1] WANG X,JIANG M,ZHOU Z,et al. 3D printing of polymer matrix composites:A review and prospective[J]. Composites Part B,2017,110:442-458.
[2] GUPTA S,TAI N H. Carbon materials and their composites for electromagnetic interference shielding effectiveness in X-band[J]. Carbon,2019,152:159-187.
[3] HUSSAIN F,HOJJATI M,OKAMOTO M,et al. Polymer-matrix nanocomposites,processing,manufacturing,and application:An overview[J]. Journal of Composite Materials,2006,40(17):1511-1575.
[4] BEKAS D G,HOU Y,LIU Y,et al. 3D printing to enable multifunctionality in polymer-based composites:A review[J]. Composites Part B:Engineering,2019,179:107540.
[5] LEIGH S J,BRADLEY R J,PURSSELL C P,et al. A simple,low-cost conductive composite material for 3D printing of electronic sensors[J]. PloS ONE,2012,7(11):e49365.
[6] LEE S J,ZHU W,NOWICKI M,et al. 3D printing nano conductive multi-walled carbon nanotube scaffolds for nerve regeneration[J]. Journal of Neural Engineering,2018,15(1):016018.
[7] BARILE C,CASAVOLA C,DE CILLIS F. Mechanical comparison of new composite materials for aerospace applications[J]. Composites Part B:Engineering,2019,162:122-128.
[8] WEI Y,QIAO Y,JIANG G,et al. A wearable skin-like ultra-sensitive artificial graphene throat[J]. ACS Nano,2019,13(8):8639-8647.
[9] GUPTA P,RAJPUT M,SINGLA N,et al. Electric field and current assisted alignment of CNT inside polymer matrix and its effects on electrical and mechanical properties[J]. Polymer,2016,89:119-127.
[10] VALINO A D,DIZON J R,ESPERA JR A H,et al. Advances in 3D printing of thermoplastic polymer composites and nanocomposites[J]. Progress in Polymer Science,2019,98:101162.
[11] LEWICKI J P,RODRIGUEZ J N,ZHU C,et al. 3D-printing of meso-structurally ordered carbon fiber/polymer composites with unprecedented orthotropic physical properties[J]. Scientific Reports,2017,7:43401.
[12] TEKINALP H L,KUNC V,VELEZ-GARCIA G M,et al. Highly oriented carbon fiber-polymer composites via additive manufacturing[J]. Composites Science and Technology,2014,105:144-150.
[13] PATTINSON S W,HUBER M E,KIM S,et al. Additive manufacturing of biomechanically tailored meshes for compliant wearable and implantable devices[J]. Advanced Functional Materials,2019,29(32):1901815.
[14] BAGHERIASL D,CARREAU P J,RIEDL B,et al. Shear rheology of polylactide (PLA)-cellulose nanocrystal (CNC) nanocomposites[J]. Cellulose,2016,23(3):1885-1897.
[15] Zamani F,Amani-Tehran M,Zaminy A,et al. Conductive 3D structure nanofibrous scaffolds for spinal cord regeneration[J]. Fibers& Polymers,2017,18(10):1874-1881.

基于电场驱动熔融喷射聚合物基复合材料高分辨率3D打印

High-resolution 3D Printing of Polymer Matrix Composites Based on Electric-field-driven Fusion Jetting

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