|
|
- 2020
纤维束波动效应对平纹编织复合材料损伤行为的影响
|
Abstract:
平纹编织复合材料中纤维束波动效应会引起随动材料主方向变化及面外剪切应力集中,为了研究其对平纹编织复合材料力学性能及损伤行为的影响,提出改进的像素法细观有限元单胞模型。模型根据纤维束波动曲线定义了材料主方向的变化,采用Hashin准则模拟纤维束的损伤起始,并引入剪切修正因子考虑面外剪切应力对面内拉伸损伤的影响。模型可以预测平纹编织复合材料的面内拉伸强度和损伤演化过程,结果表明:纤维束材料主方向波动会引起平纹编织复合材料面内拉伸强度下降;面外剪切应力集中是导致复合材料最终失效的主要原因,且随着剪切修正因子增大,复合材料面内拉伸强度显著降低;纤维束材料主方向波动和面外剪切应力集中均对平纹编织复合材料的损伤行为和破坏机理产生了影响,需要在数值分析中对其进行准确描述。 The undulation effect of fiber bundles on plain weave composites causes the variety of slave material principal direction and the concentration of out-of-plane shear stress. A meso-scale finite model based on the improved voxel meshes for a unit cell was utilized to explore the influence on the mechanical properties and damage behavior for plain weave composites. In the model, the variety of slave material principal direction was defined according to the undulated curve of fiber bundles, and a shear correction factor was introduced into Hashin criterion which was used to predict the initial damage of fiber bundles to consider the effect of out-of-plane shear stress on in-plane tensile damage. The model can accurately simulate the in-plane tensile strength and damage process. The results indicate that the undulation of slave material principle direction gives rise to the decline of in-plane tensile strength for plain weave composite. The concentration of out-of-plane shear stress is the main factor leading to the failure of composites, and reduces the tensile strength significantly with the increase of shear correction factor. In addition, both the two factors have affected the damage behavior and failure mechanism of plain weave composites, which need to be expressed accurately in numerical analysis
| [1] | NAIK N K, GANESH V K. Failure behavior of plain weave fabric laminates under on-axis uniaxial tensile loading Ⅲ:Effect of fabric geometry[J]. Journal of Composite Materials, 1996, 30(16):1823-1856 |
| [2] | LI J J, ZHAO M Y, GAO X S, et al. Modelling the stiffness, strength, and progressive failure behavior of woven fabric-reinforced composites[J]. Journal of Composite Materials, 2014, 48(6):735-747. |
| [3] | 王荣桥, 刘茜, 胡殿印, 等. 一种改进的三维四向编织复合材料单胞模型及宏观弹性常数预测方法[J]. 复合材料学报, 2017, 34(9):1973-1981.WANG R Q, LIU X, HU D Y, et al. Improved unit cell model and elastic constant prediction method of 3D four-directional braided composites[J]. Acta Materiae Compositae Sinica, 2017, 34(9):1973-1981(in Chinese). |
| [4] | NAIK N K, GANESH V K. Failure behavior of plain weave fabric laminates under on-axis uniaxial tensile loading I:Analytical predictions[J]. Journal of Composite Materials, 1996, 30(16):1779-1822. |
| [5] | 王新峰. 机织复合材料多尺度渐进损伤研究[D]. 南京:南京航空航天大学, 2007.WANG X F. Multi-scale analyses of damage evolution in woven composite materials[D]. Nanjing:Nanjing University of Aeronautics and Astronautics, 2007(in Chinese). |
| [6] | HASHIN Z. Failure criteria for unidirectional fiber composites[J]. Journal of Applied Mechanics, 1980, 47(2):329-234. |
| [7] | HOU J P, PETRINIC N, RUIZ C, et al. Prediction of impact damage in composite plates[J] Composite Science and Technology, 2000, 60(2):273-281. |
| [8] | GUO W, XUE P, JUN Y. Nonlinear progressive damage model for composite laminates used for low-velocity impact[J]. Applied Mathematics and Mechanics, 2013, 34(9):1145-1154. |
| [9] | LI X, BINIENDA W K, GOLDBERG R K. Finite-element model for failure study of two-dimensional triaxially braided composite[J]. Journal of Aerospace Engineering, 2010, 24(2):170-180. |
| [10] | MATZENMILLER A, LUBLINER J, TAYLOR R L. A constitutive model for anisotropic damage in fiber-composites[J]. Mechanics of Materials, 1995, 20(2):125-152. |
| [11] | LI Y, YAN Y, LIU Y, et al. Microscopic failure mechanisms of fiber-reinforced polymer composites under transverse tension and compression[J]. Composites Science and Technology, 2012, 72(15):1818-1825. |
| [12] | LUBLINER J, OLIVER J, OLLER S, et al. A plastic-damage model for concrete[J]. International Journal of Solids & Structures, 1989, 25(3):299-326. |
| [13] | 张芳芳. 编织复合材料力学性能及热物理性能预报研究[D]. 秦皇岛:燕山大学, 2014.ZHANG F F. Research on prediction of mechanical properties and thermal physics properties of braided composites[D]. Qinhuangdao:Yanshan University, 2014(in Chinese). |
| [14] | SEVENOIS R D B, GAROZ D, GILABERT F A, et al. Avoiding interpenetrations and the importance of nesting in analytic geometry construction for representative unit cells of woven composite laminates[J]. Composite Science and Technology, 2016, 136:119-132. |
| [15] | JACQUES S, BAERE I D, PAEPEGEM W V. Application of periodic boundary conditions on multiple part finite element meshes for the meso-scale homogenization of textile fabric composites[J]. Composites Science and Technology, 2014, 92:41-54. |
| [16] | ZHANG C, BINIENDA W K, GOLDBERG R K. Free-edge effect on the effective stiffness of single-layer triaxially braid composite[J]. Composites Science and Technology, 2015, 107:145-153. |
| [17] | SHERBURN M. Geometric and mechanical modelling of textiles[D]. Nottingham:University of Nottingham, 2007. |
| [18] | 张芳芳, 姜文光, 刘才, 等. 基于区域叠合技术的三维编织复合材料渐进损伤过程数值模拟[J]. 复合材料学报, 2013, 30(6):227-236.ZHANG F F, JIANG W G, LIU C, et al. Simulation of progressive damage of 3D braided composites using domain superposition technique[J]. Acta Materiae Compositae Sinica, 2013, 30(6):227-236(in Chinese). |
| [19] | ZHOU Y, LU Z, YANG Z. Progressive damage analysis and strength prediction of 2D plain weave composites[J]. Composites Part B:Engineering, 2013, 47:220-229. |
| [20] | BARBERO E J, TROVILLION J, MAYUGO J A, et al. Finite element modeling of plain weave fabrics from photomicrograph measurements[J]. Composite Structures, 2006, 73(1):41-52. |
| [21] | ZHANG C. Multi-scale characterization and failure modeling of carbon/epoxy triaxially braided composite[D]. Akron:The University of Akron, 2003. |
| [22] | DIXIT A, MALI H S, MISRA R K. Unit cell model of woven fabric textile composite for multiscale analysis[J]. Procedia Engineering, 2013, 68:352-358. |
| [23] | BEDMARCYK B A, STIER B, SIMON J W, et al. Meso-and micro-scale modeling of damage in plain weave composites[J]. Composite Structures, 2015, 121:258-270. |
| [24] | LIU X, ROUF K, FENG B, et al. Two-step homogenization of textile composites using mechanics of structure genome[J]. Composite Structures, 2017, 171:252-262, |
| [25] | ZHANG C, LI N, WANG W, et al. Progressive damage simulation of triaxially braided composite using a 3D meso-scale finite element model[J]. Composite Structures, 2015, 125:104-116. |
