采用自主研发的高精度短纤维力学性能测试仪(SF-I)研究了毛竹、杉木、洋麻、苎麻单根纤维的纵向力学性能。结果表明,4种纤维的应力应变曲线均表现出明显的线弹性行为,直至断裂。毛竹、杉木、洋麻、苎麻的平均断裂强度分别为1 710、1 258 、1 019、1 001 MPa,平均弹性模量分别为27.1、199、30.8、11.4 GPa,平均伸长率分别为7.0 %、6.6 %、3.2 %、8.9 %。由此可见所测4种纤维的力学性能特点各异。毛竹的拉伸强度最大,最高达2 708 MPa;苎麻纤维断裂伸长率最大、韧性最好,但强度和刚度均最小;洋麻纤维虽然韧性最差,但弹性模量值明显高于其他3种纤维,刚性最好。就综合性能而言,毛竹纤维力学性能最优。
Abstract
The object of this paper was to investigate the tensile properties of single fibers bamboo, Chinese fir, kenaf and ramie by a newly designed micro tension tester (SFI). The loaddeflection curve of single fiber testing showed that a linear behavior presented to failure. The average values of tensile strength of bamboo, Chinese fir, kenaf and ramie single fibers were 1 710, 1 258, 1 019, 1 001 MPa, respectively, and their tensile modulus were 27.1, 19.9, 30.8, 11.4 GPa, elongation were 7.0 %, 6.6 %, 3.2 %, 8.9 %, respectively. It showed that the mechanical properties of the four fibers were different. Among the fibers investigated, the bamboo fiber had the biggest tensile strength with the peak value reaching 2 708 MPa. The ramie fiber had the biggest fracture strain and the best flexibility but the smallest tensile strength and stiffness. The toughness of the kenaf fiber was the poorest but the elastic modulus value was significantly higher than others, its stiffness was the best. Bamboo fiber is the best from comprehensive mechanical properties.
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参考文献
[1]Shaler S M, Groom L H, Mott L. The mechanical properties of individual lignocellulosic fibers[J]. Forest Product Journal, 1995, 32(2): 33-40. [2]Groom L H, Mott L, Shaler S M. Mechanical properties of individual southern pine fibers. Part I: Determination and variability of stressstrain curves with respect to tree height and juvenility[J]. Wood and Fiber Science, 2002a, 34 (1): 14-27. [3]Groom L, Shaler S M, Mott L. Mechanical properties of individual southern pine fibers. Part III: Global relationships between fiber properties and fiber location within an individual tree[J]. Wood and Fiber Science, 2002b, 34 (2): 238-250. [4]Ehrnrooth E M L, Kolseth P. The tensile testing of single wood pulp fibers in air and in water[J]. Wood and Fiber Science, 1984, 16(4): 549-566. [5]李栋高. 纤维材料学[M]. 北京:中国纺织出版社,2006. [6]Mark R E, Gills P P. New models in cellwall mechanics[J]. Wood and Fiber Science, 1970, 2(2): 79-95. [7]Burgert I, Keckes J, Fruhmann, et al. A comparison of two techniques for wood fiber isolationevaluation by tensile tests on single fibers with different microfibril angle[J]. Plant Biol, 2002, 4(1): 9-12. [8]邵卓平,周学辉,魏涛,等. 竹材在不同介质中加热处理后的强度变异[J]. 林产工业,2003,30(3):26-29. [9]黄安民,费本华,刘君良. 杉木木材性质研究进展[J]. 世界林业研究,2006,19(1):47-52. [10]Mott L, Shaler S. The tensile testing of individual wood fibers using environmental scanning electron microscopy and video image[J]. Tappi Journal, 1995, 78(5): 143-148.
基金
收稿日期:2010-01-12修回日期:2010-04-22基金项目:国家林业局“948”创新项目(2006-4-104);国家自然科学基金重点项目(30730076);“十一五”国家科技支撑计划(2008BADA9B01)作者简介:曹双平(1984—),硕士生。*王戈(通信作者),教授。Email: wangge@icbr.ac.cn。引文格式:曹双平,王戈,余雁,等. 种植物单根纤维力学性能对比[J]. 南京林业大学学报:自然科学版,2010,34(5):87-90.
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