基于多维度建模的碳/碳软硬混编预制体孔隙分析与单胞模型

doi:10.13475/j.fzxb.20220600301

纺织学报 ›› 2023, Vol. 44 ›› Issue (09): 108-115.doi: 10.13475/j.fzxb.20220600301

基于多维度建模的碳/碳软硬混编预制体孔隙分析与单胞模型

梅宝龙¹^,², 董九志¹^,³(), 任洪庆¹^,³, 蒋秀明¹^,³

1.天津工业大学机械工程学院, 天津 300387
2.中国纺织机械协会, 北京 100020
3.天津工业大学天津市现代化机电装备技术重点实验室, 天津 300387

收稿日期:2022-06-01 修回日期:2022-11-29 出版日期:2023-09-15 发布日期:2023-10-30
通讯作者: 董九志(1981—),男,副教授,博士。主要研究方向为复合材料预制件成型技术、新型纺织机械机电一体化。E-mail:dongjiuzhi@tiangong.edu.cn。
作者简介:梅宝龙(1988—),男,博士生。主要研究方向为复合材料预制件成型技术与复合材料力学。
基金资助:
天津市科技支撑重点计划项目(15ZSZDGX00840);天津市自然科学基金资助项目(18JCYBJC20200)

Unit modeling and pore analysis of C/C soft-hard blended preform based on multi-dimensional modeling

MEI Baolong¹^,², DONG Jiuzhi¹^,³(), REN Hongqing¹^,³, JIANG Xiuming¹^,³

1. School of Mechanical Engineering,Tiangong University, Tianjin 300387, China
2. China Textile Machinery Association, Beijing 100020, China
3. Tianjin Key Laboratory of Advanced Mechatronics Equipment Technology, Tiangong University, Tianjin 300387, China

Received:2022-06-01 Revised:2022-11-29 Published:2023-09-15 Online:2023-10-30

摘要/Abstract

摘要：

为探究碳/碳软硬混编预制体在压实过程初始和最终密实2个阶段中孔隙分布及变化,解决成型后孔隙率无法预测的问题。基于碳/碳软硬混编预制体成型工艺构建一种三维四向孔隙模型,在无压缩载荷和施加压缩载荷2种工况下,从单胞模型的xoy平面和xoz平面2个维度、4个方向观测孔隙;从介观和微观2个尺度研究载荷下纤维形态与截面形状变化对单胞孔隙的影响,建立了纤维尺寸截面变化与孔隙率映射关系,提出影响孔隙率的尺寸系数,使预制体最终孔隙率具有可设计性;通过单胞孔隙模型计算得到预制体在压实阶段最小孔隙率。利用万能拉伸试验机对不同尺寸的预制体进行压实致密实验,得到不同尺寸预制体所受压缩载荷与高度变化曲线,揭示了预制体高度与孔隙率的关系并得到压实致密阶段最小孔隙率。实验结果表明最小孔隙率与理论模型误差小于3%,验证了软硬混编单胞孔隙模型表征预制体孔隙率的正确性。

关键词: 碳/碳软硬混编预制体, 多维度, 单胞孔隙模型, 压实致密, 孔隙率

Abstract:

Objective In order to explore the pore distribution and change of the C/C soft-hard blended preform in the initial and final stages of the compaction process, the problem that the porosity can not be predicted at the completion of the preform was set and research focus.

Method A 3-D four-direction pore model was established based on the C/C soft-hard weaving preform process. The pores from the xoy plane and xoz plane of the unit model in two dimensions and four directions were studied with and without compression load. The influences of fiber shape and cross section shape of the pore of the unit under the load were studied from mesoscopic and microscopic scales. The mapping relationship between the change of fiber size and porosity was solved by using the geometric model and the size coefficient affecting the porosity was proposed.

Results The minimum porosity of the unit preform in the final compaction stage was found to be 26.1% by using the 3-D four-direction preform unit pore model and parameters (Tab. 1). A universal tensile testing machine was used to perform compaction and densification experiments on the preforms of different sizes. Resin curing was performed on the preform under different compression loads, before the pore morphologies were observed. The results show that the compaction process of the preform consists of three stages, i.e. initial linear, nonlinear and final linear. In the initial linear stage, the height of the preform was compressed rapidly by small pressure, the load increases and the height decreases slowly in the nonlinear stage, and in the final linear stage, the load was increased while the height of the preform does not change. The porosity in the compaction process was obtained using the weighing method, and the mapping relationship between the height and porosity of the preform was obtained. The compression load and height variation curve of the three groups of preform with different bottom areas and the same height was showed, and the compression load of the three groups of experiments approximately increased by multiple times (Fig. 10(a)). The porosity decreased with the decrease of the height of the preform (Fig. 10(b)). When the height was kept constant, the porosity of the preform reached the minimum value of 27.4%. The compression load and height variation curve of three groups of preform with different heights and the same base area was reveal, and the compression load of the three groups of experiments was approximately equal (Fig. 11(a)). The minimum porosity of the preform at the compaction and densification stage was 27.9%, 28.4% and 28.7%, respectively (Fig. 11(b)). The experimental results show that the maximum error between the theoretical model and the actual minimum porosity was 2.6%.

Conclusion The experimental results verify the feasibility and correctness of the 3-D four-direction C/C soft-hard blended preform unit pores, which were observed and virtually constructed in two dimensions and four directions of xoy plane and xoz plane. At mesoscopic and microscopic scales, the influences of fiber shape and cross section shape on the porosity of the preform under load were studied. The mapping relationship between fiber size change and porosity was established by geometric modeling, and the size coefficient affecting the porosity was proposed to make the final porosity of the preform designable. At the same time, the compaction and densification process law of the 3-D four-direction preform was revealed, The results show that the final linear stage determines the porosity of the preform. The modeling method can also be applied to the pore model of the preform fabric of the integrated piercing fabric and the 3-D orthogonal fabric, providing theoretical guidance for the regulation and prediction of the final porosity of the preform fabric.

Key words: C/C soft-hard weaving preform, multi-dimension, unit porous model, compaction, porosity

中图分类号:

TB332

梅宝龙, 董九志, 任洪庆, 蒋秀明. 基于多维度建模的碳/碳软硬混编预制体孔隙分析与单胞模型[J]. 纺织学报, 2023, 44(09): 108-115.

MEI Baolong, DONG Jiuzhi, REN Hongqing, JIANG Xiuming. Unit modeling and pore analysis of C/C soft-hard blended preform based on multi-dimensional modeling[J]. Journal of Textile Research, 2023, 44(09): 108-115.

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参考文献 12

[1]	GUTOWSK T G, CAI Z, BAUER S, et al. Consolidation experiments for laminate composites[J]. Journal of Composite Materials, 1987, 21(7):650-669. doi: 10.1177/002199838702100705
[2]	TREVINO L, RUPEL K, YOUNG W B, et al. Analysis of resin injection molding in molds with preplaced fiber mats: I: permeability and compressibility measur-ements[J]. Polymer Composites, 1991, 12(1):20-29. doi: 10.1002/pc.v12:1
[3]	胡培利, 单忠德, 刘云志, 等. 复合材料构件预制体压实致密工艺研究[J]. 机械工程学报, 2019, 55(9):191-197. doi: 10.3901/JME.2019.09.191
	HU Peili, SHAN Zhongde, LIU Yunzhi, et al. Compaction and densification process of composite component preforms[J]. Journal of Mechanical Engineering, 2019, 55(9):191-197. doi: 10.3901/JME.2019.09.191
[4]	CHEN Z R, YE L, KRUCKENBER T. A micromechanical compaction model for woven fabric preforms: part I: single layer[J]. Composites Ence and Technology, 2006, 66(16):3254-3262.
[5]	CHEN Z R, YE L, KRUCKENBER T. A micromechanical compaction model for woven fabric preforms: Part II: multilayer[J]. Composites Ence and Technology, 2006, 66(16):3263-3272.
[6]	KELLY P A. A viscoelastic model for the compaction of fibrous materials[J]. Journal of The Textile Institute, 2011, 102(8):689-699. doi: 10.1080/00405000.2010.515103
[7]	GREEN S D, LONG A C, SAID B S F E, et al. Numerical modelling of 3D woven preform deform-ations[J]. Composite Structures, 2014, 108(1):747-756. doi: 10.1016/j.compstruct.2013.10.015
[8]	GREEN S D, MATVEEV M Y, LONG A C, et al. Mechanical modelling of 3D woven composites considering realistic unit cell geometry[J]. Composite Structures, 2014, 118(12):284-293. doi: 10.1016/j.compstruct.2014.07.005
[9]	刘云志, 单忠德, 战丽, 等. 柔性导向三维正交结构复合材料预制体建模研究[J]. 工程塑料应用, 2016, 44(6):63-66,83.
	LIU Yunzhi, SHAN Zhongde, ZHAN Li, et al. Research on modeling of 3D orthogonal flexible weavon composite preform[J]. Engineering Plastics Application, 2016, 44(6):63-66,83.
[10]	BROWN D, WU Z J. Stiffness properties of 3-D orthogonally woven fabric composites[J]. Advances in Composite Materials & Structures VII, 2014, 28(1):377-386.
[11]	蒋建军, 陈星, 邓国力, 等. 嵌套效应对单向织物压缩行为的影响[J]. 复合材料学报, 2017, 34(11):2463-2472.
	JIANG Jianjun, CHEN Xing, DENG Guoli, et al. Effect of nesting on the compaction behavior of unidirectional fabrics[J]. Acta Materiae Compositae Sinica, 2017, 34(11):2463-2472.
[12]	杨彩云, 李嘉禄. 三维机织复合材料纤维体积含量计算方法[J]. 固体火箭技术, 2005, 28(3):224-227.
	YANG Caiyun, LI Jialu. Calculation methods of 3D woven composites fiber volume fraction[J]. Journal of Solid Rocket Technology, 2005, 28(3):224-227.

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预制体编号	尺寸/ mm	压缩载荷/ N	最终孔隙率/%	孔隙率误差/%
1	32×30×30	151	27.4	1.3
2	64×60×30	314	27.4	1.3
3	96×90×30	582	27.4	1.3
4	32×30×30	148	27.9	1.8
5	32×30×60	166	28.4	2.3
6	32×30×120	172	28.7	2.6

基于多维度建模的碳/碳软硬混编预制体孔隙分析与单胞模型

Unit modeling and pore analysis of C/C soft-hard blended preform based on multi-dimensional modeling

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