桑蚕的强制牵伸抽丝及其纤维性能

doi:10.13475/j.fzxb.20230204501

摘要/Abstract

摘要：

为提升蚕丝的力学性能,采用一种圆锥斜面牵伸装置对五龄桑蚕进行强制牵伸抽丝以制备高强牵伸丝,研究不同牵伸速度对桑蚕牵伸丝形貌、力学性能的影响,并将牵伸丝与蚕丝进行对比与分析。结果表明:由强制抽丝获得的牵伸丝表面光滑平坦,丝胶均匀附着;随着牵伸速度的增加,牵伸丝截面逐渐向弓形转变;牵伸丝的综合力学性能显著优于蚕丝,且其断裂强度、弹性模量、断裂比功与断裂伸长率随着牵伸速度的增加均有不同程度的增加;其中,以接近桑蚕自然吐丝速度(1 cm/s)牵伸制备的牵伸丝的断裂强度与蚕丝相当,约为3.00 cN/dtex,但其弹性模量(93.10 cN/dtex)远高于蚕丝(76.90 cN/dtex);当牵伸速度增加至4 cm/s时,可获得力学性能最佳的牵伸丝,其断裂伸长率为22.49%,断裂强度为3.39 cN/dtex,弹性模量为95.76 cN/dtex,断裂比功为0.62 cN/dtex,相比于蚕丝的平均值分别提高了7%、13.76%、24.53%、31.91%。

关键词: 桑蚕, 蚕丝, 强制抽丝, 牵伸丝, 力学性能

Abstract:

Objective Bombyx mori silk fibers have an interesting and elaborate structure, but its mechanical properties are inferior to spider dragline silk. Therefore, it is of great significance to prepare Bombyx mori silk comparable to spider silk. Traditional silk processing technology, however, is difficult to enhance the performance of cocoon silk, and even damage its morphology and properties. In addition, artificial silk produced by a variety of spinning methods cannot fully replicate the properties of natural silk. Herein, we proposed a simple and effective strategy for preparing high-strength Bombyx mori silk, which not only retains the hierarchical structure of natural silk, but also advances its mechanical properties.

Method Inspired by spider silking, this work designed a conical forced reeling device that can consistently reel silk from the fifth instar silkworm at controlled reeling speed. In this study, the silkworms were forcibly reeled at 1-4 cm/s, resulting in the force-reeled silk fibers (FRSF-1, FRSF-2, FRSF-3, and FRSF-4). During forced reeling, the silk was fully stretched due to a recombination of the reeling force and the gravity of silkworm, which increased the orientation and crystallinity of FRSFs. Meanwhile, the cocoon silk fibers (CSFs) selected from the same batch were set as a control group. In addition, the characteristic of fiber morphology, fineness, and mechanical properties of all silk samples were performed.

Results The FRSFs have a smooth and uniform morphology, and a bow-shaped cross-section, which differs significantly from that of CSFs. Specifically, the transversal surface of FRSF-1 is almost a round triangular cross-section shaped like CSFs, and both the rounded triangular and bow-shaped cross-section appeared in FRSF-2. With the reeling speed further increasing, only bow-shaped transverse section can be found in FRSF-3 and FRSF-4. Furthermore, the mechanical properties including breaking elongation, stress, elastic modulus, and specific work of rupture of FRSFs are superior to that of CSFs. First of all, the stress of FRSFs increases with reeling speed increasing. More specifically, the stress of FRSF-1 is approximately 3.0 cN/dtex, which is similar to CSFs. In addition, the stress of the FRSF-2, FRSF-3, FRSF-4 increases to 3.20 cN/dtex, 3.34 cN/dtex, and 3.39 cN/dtex, respectively, with the increasing reeling speed. As for the elastic modulus, there is a clear phenomenon that the modulus of FRSFs is obviously larger than that of the CSFs, and increases with reeling speed. Accordingly, FRSF-1 has an elastic modulus of 93.10 cN/dtex, while the elastic modulus of CSFs is 76.90 cN/dtex. Besides, the specific work of rupture of FRSF-1, FRSF-2, FRSF-3, and FRSF-4 is as follows: 0.54 cN/dtex, 0.55 cN/dtex, 0.60 cN/dtex, and 0.62 cN/dtex. In contrast, the specific work of rupture of CFSs is 0.47 cN dtex. Moreover, the breaking elongation of FRSFs increases after force-reeling and shows a similar value with increasing reeling speed. As a result, the FRSF-4 exhibits integrated mechanical properties of superior breaking elongation (22.49%), excellent strength (3.39 cN/dtex), outstanding elastic modulus (95.76 cN/dtex), and supreme specific work of fracture (0.62 cN/dtex), which increases by 7%, 13.76%, 24.53%, and 31.91%, as compared to the average values of CSFs.

Conclusion In summary, the FRSFs with smooth morphology and improved mechanical properties was achieved by force-reeling. Notably, stress of the FRSFs increases as the reeling speed increases, and the elastic modulus of all these FRSFs is significantly higher than that of CSFs. This is due to the strong shear effect of the high-speed stretch that facilitates the orientation of the nanofibrils and improves the crystal structure of the nanocrystallites, thereby promoting the mechanical properties of FRSFs. The obtained FRSFs with satisfying elongation, high strength, superior modulus, and specific work of rupture broaden its application prospects in impact-resisting materials, biomedical materials, smart textiles and wearable electronics. Besides, the forced reeling processes and device need to be further modified to reduce the unstability of reeling tension and the fluctuation of fiber fineness.

Key words: Bombyx mori silkworm, silk, forced reeling, force-reeled silk, mechanical property

中图分类号:

TS102.3

刘术, 侯腾, 周乐乐, 李祥龙, 杨斌. 桑蚕的强制牵伸抽丝及其纤维性能[J]. 纺织学报, 2024, 45(06): 11-15.

LIU Shu, HOU Teng, ZHOU Lele, LI Xianglong, YANG Bin. Properties of Bombyx mori silkworm silk obtained by forced reeling[J]. Journal of Textile Research, 2024, 45(06): 11-15.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20230204501

http://www.fzxb.org.cn/CN/Y2024/V45/I06/11

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参考文献 16

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