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用于纤维增强热塑性3D打印复合材料的扩展帕克与舒尔曼纤维间断裂准则

Expanding Puck and Schürmann Inter Fiber Fracture Criterion for Fiber Reinforced Thermoplastic 3D-Printed Composite Materials.

作者信息

Dutra Thiago Assis, Ferreira Rafael Thiago Luiz, Resende Hugo Borelli, Blinzler Brina Jane, Larsson Ragnar

机构信息

GPMA-Research Group on Additive Manufacturing, DCTA ITA IEM, ITA-Aeronautics Institute of Technology, São José dos Campos, São Paulo 12228-900, Brazil.

Division of Material and Computational Mechanics, Department of Industrial and Materials Science, Chalmers University of Technology, SE-412 96 Gothenburg, Sweden.

出版信息

Materials (Basel). 2020 Apr 2;13(7):1653. doi: 10.3390/ma13071653.

DOI:10.3390/ma13071653
PMID:32252397
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7178404/
Abstract

The present work expands the application of Puck and Schürmann Inter-Fiber Fracture criterion to fiber reinforced thermoplastic 3D-printed composite materials. The effect of the ratio between the transverse compressive strength and the in-plane shear strength is discussed and a new transition point between the fracture conditions under compressive loading is proposed. The recommended values of the inclination parameters, as well as their effects on the proposed method, are also discussed. Failure envelopes are presented for different 3D-printed materials and also for traditional composite materials. The failure envelopes obtained here are compared to those provided by the original Puck and Schürmann criterion and to those provided by Gu and Chen. The differences between them are analyzed with the support of geometrical techniques and also statistical tools. It is demonstrated that the Expanded Puck and Schürmann is capable of providing more suitable failure envelopes for fiber reinforced thermoplastic 3D-printed composite materials in addition to traditional semi-brittle, brittle and intrinsically brittle composite materials.

摘要

本工作将帕克和舒尔曼纤维间断裂准则的应用扩展到纤维增强热塑性3D打印复合材料。讨论了横向抗压强度与面内剪切强度之比的影响,并提出了压缩载荷下断裂条件之间的一个新的转变点。还讨论了倾斜参数的推荐值及其对所提方法的影响。给出了不同3D打印材料以及传统复合材料的失效包络线。将这里得到的失效包络线与原始帕克和舒尔曼准则以及顾和陈所提供的失效包络线进行了比较。借助几何技术和统计工具对它们之间的差异进行了分析。结果表明,扩展的帕克和舒尔曼准则除了能为传统的半脆性、脆性和本征脆性复合材料提供更合适的失效包络线外,还能为纤维增强热塑性3D打印复合材料提供更合适的失效包络线。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2278/7178404/2f9f162d9c85/materials-13-01653-g015.jpg
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本文引用的文献

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Materials (Basel). 2020 Feb 3;13(3):672. doi: 10.3390/ma13030672.
2
Performance of 3D-Printed Continuous-Carbon-Fiber-Reinforced Plastics with Pressure.3D打印连续碳纤维增强塑料在压力下的性能
Materials (Basel). 2020 Jan 19;13(2):471. doi: 10.3390/ma13020471.
3
Static and Dynamic Mechanical Properties of 3D Printed ABS as a Function of Raster Angle.
碳纤维增强聚合物
Materials (Basel). 2021 Sep 24;14(19):5545. doi: 10.3390/ma14195545.
三维打印丙烯腈-丁二烯-苯乙烯共聚物(ABS)的静态和动态力学性能与光栅角度的关系
Materials (Basel). 2020 Jan 9;13(2):297. doi: 10.3390/ma13020297.
4
Acrylonitrile Butadiene Styrene and Polypropylene Blend with Enhanced Thermal and Mechanical Properties for Fused Filament Fabrication.用于熔融长丝制造的具有增强热性能和机械性能的丙烯腈-丁二烯-苯乙烯共聚物与聚丙烯共混物
Materials (Basel). 2019 Dec 11;12(24):4167. doi: 10.3390/ma12244167.
5
Selectively Enhanced 3D Printing Process and Performance Analysis of Continuous Carbon Fiber Composite Material.连续碳纤维复合材料的选择性增强3D打印工艺及性能分析
Materials (Basel). 2019 Oct 28;12(21):3529. doi: 10.3390/ma12213529.
6
The proof and measurement of association between two things. By C. Spearman, 1904.两件事物之间关联的证明与度量。作者C. 斯皮尔曼,1904年。
Am J Psychol. 1987 Fall-Winter;100(3-4):441-71.