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竹材横向断裂的物理模型与能量吸收机制:纤维束的断裂与抽拔 被引量:3

The Physical Model and Energy Absorbing Mechanism of Bamboo Transverse Fracture: The Fracture and Pulling-Out of fiber Bundles
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摘要 采用细观力学方法,研究竹材在横弯断裂过程中竹纤维束断裂与抽拔这2种损伤模式的能量吸收机制,并实际计算基本组织开裂、界面分层、竹纤维束断裂、竹纤维束抽拔4种损伤模式对竹材横弯断裂的增韧贡献。结果表明:1)不同组织结构在损伤演化过程中会因不同的能耗而具有不同的增韧贡献,在这4种导致竹材优良强韧性能的主要结构因素中,单位面积上纤维束拔出功对断裂功的贡献最大,其次是纤维束断裂;2)通过对试件的断裂总耗能试验值与按照4种损伤模型计算的耗能理论值进行比较,二者结果很接近,表明本文对竹材不同组织结构在横弯失效中的力学功能所建立的物理模型基本正确。 In this paper, the moso-mechanics method was applied to study the energy absorbing mechanism of the fracture pattern and pulling-out pattern of bamboo fiber during process of bamboo transverse bending fracture. The toughness contributed by the cracking pattern of ground tissue, the layering pattern of interface, the fracture pattern and pulling-out pattern of fiber was calculated actually. The results indicated that: 1 ) different organization structures contributed different toughness to the evolution of damage because of different energy wastage and among the four main structure factors that lead to the excellent toughness property of bamboo,the pulling-out of fiber contributed most and the fracture of fiber second. 2) the comparison between the test value of the total energy wastage of fracture and the calculated theory value of the total energy wastage of the four damage patterns showed that the two values were very close. It indicated that the physical model founded for the mechanics functions of different organization structures in the process of transverse bending damage was right.
作者 邵卓平 王福利 吴贻军
机构地区 安徽农业大学林学与园林院
出处 《林业科学》 EI CAS CSCD 北大核心 2012年第8期118-122,共5页 Scientia Silvae Sinicae
基金 国家自然科学基金项目(11008250) 安徽省高校重点实验室资助
关键词 竹材 横纹断裂 断裂损伤模型 能量吸收机制 bamboo transverse fracture damage pattern energy absorbing mechanism
分类号 S781.9 [农业科学—木材科学与技术]
  • 相关文献

参考文献8

  • 1邵卓平,吴贻军,王福利.竹材横向断裂的物理模型与能量吸收机制:基本组织开裂与界面脱粘[J].林业科学,2012,48(7):108-113. 被引量:5
  • 2Cooper G A, Kelly A. 1970. Mechanics of composite materials//Wenat FW. London: Pergamon Prss, Oxford, 653.
  • 3Wang Fuli, Shao Zhuoping, Wu Yijun. 2012. Mode II inlerlaminar fractureproperties of moso bamboo. Composites : Part B ( http : // www.sciencedirect. com/science/article/pii/Sl359836812003617).
  • 4Outwater J 0,Murphy M C. 1993. The influence of environment andclass finishes on the fracture energy of glass - epoxy jionts. Proc24th Conf SPI.
  • 5Piggott M R. 1970. Theoretical estimation of fracture toughness of fibercomposites. J Maler Sci, 5:669.
  • 6Shao Zhuoping, Fang CKanghua, Tian Genlin. 2009. Mode Iinteriaminar fraclure property of moso bamboo ( Phyllosiachyspubescens). Wood Science and Technology, 43(3) :527 - 536.
  • 7Shao Zhuoping, Fang Changhua, Huang Shengxia, et al. 2010a. Tensileproperties of inoso bamboo ( Phyilostachys pubescens ) and itscomponents with respect lo ilsnber-reinforced composite structure.Wood Soia/ice and Technology, 44(4) ;655 - 666.
  • 8Shao Zhuoping, Zhou Liang, Liu Yamei, et al. 2010b. Difference ofstructure and strength between intemodes part and node part of mosobamboo. Journal of Tropical Forest Science,22(2) :133 - 138.

二级参考文献15

  • 1张青,戴起勋,赵玉涛,程晓农.仿生材料设计与制备的研究进展[J].江苏大学学报(自然科学版),2003,24(6):55-60. 被引量:5
  • 2周本濂,冯汉保,张弗天,师昌绪.复合材料的仿生探索[J].自然科学进展(国家重点实验室通讯),1994,4(6):713-725. 被引量:11
  • 3周本濂.复合材料的仿生研究[J].物理,1995,24(10):577-582. 被引量:11
  • 4关锡鸿,冼定国,叶颖薇.1987.竹材--一种天然的复合材料.复合材料学报,4(4):79-83.
  • 5Amada S, Untao S. 2001. Fracture properties of bamboo. Composites Part B: Engineering,32(5) : 451 -459.
  • 6Cooper G A,Kelly A. 1970. Mechanics of composite materials. London: Pergamon Press, Oxford ,653.
  • 7Outwater J O,Murphy M C. 1993. The influence of enviroment and class finishes on the fracture energy of glass-epoxy jionts. Proc 24^th Conf SPI.
  • 8Reeder J R, Crews J H. 1990. Mixed-mode bending methed for delamination testing, ALAA Journal,28 ( 7 ) : 1270.
  • 9Reeder J R,Crews J H. 1991. Redesigm of mixed-mode bending test for delamination toughness. Proc of ICCM-8 Section,13 -36.
  • 10Williams J G. 1988. On the calculation of energy release rates for ceack laminates. International Journal of Fracture,36 (2) : 101 - 119.

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林业科学
2012年 第8期

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