Interface Structure and Stress Analysis of Carbon Fiber Reinforced Laminated Woodceramics

doi:10.15541/jim20160049

Abstract

Abstract:

To study the interface structure and loading conditions of fiber reinforced woodceramics composite, a laminated woodceramics were prepared by using liquification wood, carbon power and carbon fiber. Scanning electron microscope (SEM) and a high-revolution transmission electron microscope (HRTEM) were employed to observe the basic structure and interface, and a micro-raman spectrometer (MRS) was used to detect the G’ band shifts of stretch sample to judge the situation of interface bond. Meanwhile, the function and way of interface layer in the process of stress transfer were numerical analyzed by using Abaqus based on bilinear softening constitutive mode. The observation of SEM and HRTEM indicates the carbon fiber reinforced woodceramics presents a clear laminated structure, of which has a strong interface bonding between amorphous carbon and glassy carbon. The test of MRS show that the G’ band of pressure sintering specimen shifts to low wavenumber at high extent, which proves that pressure sintering can improve the interface bonding strength between glassy carbon and carbon fiber. The numerical analysis shows that the interface layer plays an important role in the stress transfer between carbon fiber and matrix material in the loading process. As the intension and thickness of interface layer increase, the loading and the equivalent stress transfer to matrix material increases.

Key words: laminated woodceramics, carbon fiber reinforced, interface structure, stress analysis

CLC Number:

TB39

SUN De-Lin, HAO Xiao-Feng, HONG Lu, TANG Zhi-Hong, ZHANG Shao-Ming. Interface Structure and Stress Analysis of Carbon Fiber Reinforced Laminated Woodceramics[J]. Journal of Inorganic Materials, 2016, 31(9): 969-975.

Figures/Tables 11

Fig. 1 End face photo of carbon fiber reinforced laminated woodceramics

Fig. 2 SEM (a) and HRTEM (b) images of matrix

Fig. 3 SEM images of pressureless sintered sample (a) and pressure sintered sample (b)

Fig. 4 Raman spectra (a) and enlarge spectrogram of G’ band (b) for pressure sintering sample and no pressure sintering sample Sintered at 1300℃, tensile strain of 0.5%

Fig. 5 Characteristic voxel model of glassy carbon and carbon fiber

Fig. 6 Bilinear softening constitutive model

Fig. 7 Stress transfer sketch diagram of interface

Fig. 8 Stress distribution of matrix, interface and carbon fiber with different moments

Fig. 9 Stress-time distribution diagram of interface layer (a) and matrix (b) in the early loading

Fig. 10 Effects of different elasticity modulus of interface layer (a) and matrix (b) on the stress distribution

Fig. 11 Effects of different thickness of interface layer (a) and matrix (b) on the stress distribution

References 18

[1]	IZUKA H, FUSHITANI M, OKABE T, et al.Mechanical properties of wood-ceramics: a porous carbon material.Journal of Porous Materials, 1999, 6(3): 175-184.
[2]	HIROSE T, FAN T X, OKABE T, et al.Effect of carbonization temperature on the basic properties of woodceramics impregnated with liquefied wood.Journal of Materials Science, 2002, 37(16): 3453-3458.
[3]	QIAN J M, JIN Z H, WANG J P.Structure and basic properties made from phenolic resin-basswood powder composite.Materials Science and Engineering: A, 2004, 368(1/2): 71-79.
[4]	YU X C, SUN D L, SUN D B, et al.Basic properties of woodceramics made from bamboo powder and epoxy resin.Wood Science and Technology, 2012, 46(1/2/3): 23-31.
[5]	KWON J H, PARK S B, AYRILMIS N, et al.Effect of carbonization temperature on electrical resistivity and physical properties of wood and wood-based composites.Composite: Part B, 2013, 46(3): 102-107.
[6]	FANG GUANG-WU, GAO XI-GUANG, SONG YING-DONG.Interface slip distribution of unidirectional fiber-reinforced ceramic matrix composites.Acta Materiae Compositae Sinica, 2013, 30(4): 101-107.
[7]	RAJAN V P, ZOK F W.Remediation of a constitutive model for ceramic composite laminates.Composites part A: Applied Science and Manufacturing, 2013, 52(9): 80-88.
[8]	COX H L.The elasticity and strength of paper and other fibrous materials.British Journal of Applied Physics, 1952, 3: 72-79.
[9]	SUN D L, YU X C, WANG R.Characterization of woodceramics prepared from liquefied corncob and poplar powder.Asian Journal of Chemistry, 2013, 25(1): 373-376.
[10]	YU XIAN-CHUN, REN SI-JING, HAO XIAO-FENG, et al.Preparation and mechanical property of carbon fiber /laminated woodceramics.Transactions of Materials and Heat Treatment, 2016, 37(1): 1-6.
[11]	ZHENG RUI-TING, CHENG GUO-AN, ZHAO YONG, et al.Preparation and characterization of carbon nanoribbons produced by the catalytic chemical vapor deposition of acetylene.New Carbon Materials, 2005, 20(4): 355-359.
[12]	YANG YA-YUN, LIN WEN-SONG, YAN XUE-ZENG, et al.Research status of fiber-reinforced reaction bonded silicon carbide matrix composites.Journal Shanghai University of Engineering Science, 2015, 29(3): 253-257.
[13]	LEI ZHEN-KUN, WANG QUAN, QIU WEI, et al.On the tensile deformation behavior of M55JB carbon fiber / microdroplet based on micro-raman spectroscopy. Journal of Experimental Mechanics, 2012, 27(1): 30-36.
[14]	杨序纲. >复合材料界面. 化学工业出版社, 2010: 8.
[15]	BERNARD B, JOHN W H, ANTHONY G E.Matrix fracture in fiber-reinforced ceramics.Journal of the Mechanics and Physics of Solids, 1986, 34(2): 167-189.
[16]	FANG GUANG-WU, GAO XI-GUANG, SONG YING-DONG.Interface slip distribution of unidirectional fiber-reinforced ceramic matrix composites.Acta Materiae Compositae Sinica, 2013, 30(4): 101-107.
[17]	许睿. 随机云杉短纤维增强热塑性复合材料界面对拉伸行为的影响. 天津: 天津大学硕士学位论文, 2011: 12.
[18]	陈腾飞. 炭纤维坯体结构及增密方式对炭-炭复合材料界面及性能的影响研究. 长沙: 中南大学博士学位论文, 2003: 4.