不同填充率下FDM 3D打印预制件建模及力学性能分析

doi:10.19491/j.issn.1001-9278.2020.06.011

中国塑料 ›› 2020, Vol. 34 ›› Issue (6): 66-72.DOI: 10.19491/j.issn.1001-9278.2020.06.011

不同填充率下FDM 3D打印预制件建模及力学性能分析

张春蕊(), 鞠锦勇

安徽工程大学工程训练中心，安徽芜湖 241000

收稿日期:2019-12-26 出版日期:2020-06-26 发布日期:2020-06-26
基金资助:
安徽省自然科学基金青年基金项目(1908085QE193);安徽工程大学校级科研项目(Xjky0192019021)

Modeling and Mechanical Performance Analysis of FDM 3D Printed Preforms with Different Filling Rates

Chunrui ZHANG(), Jinyong JU

Engineering Training Center, Anhui Polytechnic University, Wuhu 241000, China

Received:2019-12-26 Online:2020-06-26 Published:2020-06-26
Contact: Chunrui ZHANG E-mail:zhangchunrui2009@163.com

摘要/Abstract

摘要：

以拉伸、压缩、弯曲、扭转4种受载情况下的熔融沉积型三维（FDM 3D）打印预制件为研究对象，以填充率、填充单元结构类型为分析参数，通过确定3D打印预制件填充率的影响因素，建立了填充率与格子形填充单元几何参数的通用解析式，据此构建不同填充率下3D打印预制件的三维几何模型；然后对不同受载类型3D打印预制件进行有限元仿真分析，明确填充率对不同载荷工况下3D打印预制件力学特性的影响规律。仿真和实验结果表明，填充率对3D打印预制件所受拉伸应力、压缩应力、弯曲应力均有较大影响，而扭转情况下影响较小，据此进一步确定了一定受载情况下3D打印预制件的较优填充率；基于本文提出的不同填充率下预制件三维模型建立方法，可有效实现对预制件的力学性能仿真分析，对减少产品试验验证次数、降低研发成本具有积极作用。

关键词: 熔融沉积, 三维打印, 预制件, 有限元, 力学性能

Abstract:

Fused deposition modeling (FDM) 3D printed process has the advantages of low cost and high adaptability, and however the poor mechanical performance of the 3D printed preforms limits their wide applications. In this paper, the 3D printed preforms fabricated under four loading conditions of tension, compression, bending and torsion were taken as the research objects, and the filling rate and fill cell type were taken as the analysis parameters. The impact parameters for the filling rates of the 3D printed preforms were first determined to establish a general analytical relationship between the filling rate and geometric parameter of the lattice filling unit, and then the 3D geometric models were constructed for the 3D printed preforms with different filling rates. Furthermore, the finite element simulation analysis was performed for the 3D printed preforms to clarify the influence of filling rates on the mechanical properties under different load conditions. The simulation and experimental results indicated that there was a great influence from the filling rate on the tensile stress, compressive stress and bending stress of the 3D printed preforms, and however the influence could be ignored under the torsion. In this case, the optimum filling rates could be determined for the 3D printed preforms under the certain loading conditions. On the basis of the proposed three?dimensional modeling method, the mechanical properties of the 3D printed preforms can be simulated and analyzed effectively. This study generates a positive effect on reducing the test number of products and R&D cost.

Key words: fused deposition modeling, three dimensional printing, preform, finite element, mechanical property

中图分类号:

TQ325.2

张春蕊, 鞠锦勇. 不同填充率下FDM 3D打印预制件建模及力学性能分析[J]. 中国塑料, 2020, 34(6): 66-72.

Chunrui ZHANG, Jinyong JU. Modeling and Mechanical Performance Analysis of FDM 3D Printed Preforms with Different Filling Rates[J]. China Plastics, 2020, 34(6): 66-72.

图/表 11

图1 FDM 3D打印预制件格子形填充单元与填充区域平面位置关系

Fig.1 Plane position relationship between FDM 3D printed preform filling unit and the filling area

填充率/%	壁厚/mm
填充率/%	0.1	0.2	0.3
20	1.89	3.79	5.68
40	0.89	1.77	2.66
60	0.54	1.09	1.63
80	0.36	0.72	1.09
100	0.20	0.40	0.60

表1 不同填充率、壁厚时四边形格子填充单元边长 (mm)

Tab.1 Side lengths of the quadrilateral filling element with different filling rate and wall thickness mm

图2 不同受载情况时40 %填充率的FDM 3D打印预制件三维模型

Fig. 2 3D models of the FDM 3D printed preforms under four loading conditions with 40 % filling rate

图3 不同填充率与不同填充单元时FDM 3D打印拉伸预制件受力分析

Fig.3 Force analysis of FDM 3D printed stretch preforms with different filling rates and filling units

填充率/%	填充类型
填充率/%	三角形	四边形	六边形
0	0	0	0
20	-2.5	0	4.4
40	-5.0	0	-1.0
60	4.2	0	1.4
80	2.3	0	-4.9
100	0	0	0

表2 不同填充率与不同填充单元时FDM 3D打印拉伸预制件最大拉伸应力偏差率 (%)

Tab.2 Deviation values of the maximum tensile stress for FDM 3D printed stretch preforms with different filling rates and filling units %

图4 不同填充率下3D打印压缩预制件受力分析

Fig.4 Force analysis of 3D printed compression preforms with different filling rates

图5 不同填充率时FDM 3D打印弯曲预制件受力分析

Fig.5 Force analysis of FDM 3D printed bending preforms with different filling rates

图6 不同填充率时FDM 3D打印扭转预制件受力分析

Fig.6 Force analysis of FDM 3D printed torsion preforms with different filling rates

图7 不同受载情况时FDM 3D打印预制件最大应力偏差值与填充率关系曲线

Fig.7 Relationship between the maximum stress deviation and filling rates of the FDM 3D printed preforms under different loading conditions

图8 FDM 3D打印拉伸预制件实验断裂位置与理论分析最大应力位置对比

Fig.8 Comparison of the experimental break location and the maximum stress position of the FDM 3D printed stretch preforms

填充率/%	变形量/mm
20	0.121
80	0.092
100	0.038

表3 200 N拉力时不同填充率条件下FDM 3D打印拉伸预制件的变形量

Tab.3 Deformations of the FDM 3D printed stretch preforms with different filling rates under 200 N tension

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不同填充率下FDM 3D打印预制件建模及力学性能分析

Modeling and Mechanical Performance Analysis of FDM 3D Printed Preforms with Different Filling Rates

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