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Year 2022, Volume: 32 Issue: 1, 77 - 85, 29.03.2022
https://doi.org/10.32710/tekstilvekonfeksiyon.783997

Abstract

References

  • References 1.Ma, W. S., Ma, Z.Y., Ren B. J., & Fan, W. F. (2017). Meso-structure and modeling of a new three-dimensional braided tubular material. Journal of Reinforced Plastics and Composites, 37(5), 310-320.
  • 2.Zhong, W. X., Sun, X. L., & Ma, P. B. (2015). Application and Development of tubular composites. Fiber Glass, 000(001), 47-52.
  • 3.Luo, S. H., & Yang, C. Y. (2015). Research progress on the mechanical properties of tubular composite. Technical Textiles, 33(008), 1-5.
  • 4.Bharti, K., Kumaraswamidhas, L. A., & Das, R. R. (2020). Detailed investigation of adhesive fillet tubular T-joint of laminated FRP composite tube under axial compressive load. Welding in the World, 64(7), 1279-1292.
  • 5.Tong, Y. (2016). Design and Production of Partial Warp Tubular Fabric. Cotton Textile Technology, 044(005), 67-70.
  • 6.Wang, W., Zhu, J. H., Zhang, R. Y., Li, Y. L., Ji, F., & Yu, J. Y. (2018). Numerical characterization and simulation of the three-dimensional tubular woven fabric. 47(8), 2112-2127.
  • 7.Gu, P. (2002). A New Weaving Technique of 3-Dimensional Preforms for Composites by Conventional Loom. Journal of Textile Research, 23(5), 24-26+2.
  • 8.Wang, L. L., Xu, A. C., & Zhang, S. Y. (2017). Study on Tensile Mechanical Properties of Three-dimensional Tubular Composites. Journal of Wuhan Textile University, 30(03), 12-16.
  • 9.Wang, G. J., Wang, J. J., & Lyu, L. H. (2019). Design and Trial Weaving of Two abnormal 3D Tubular Woven Fabric. Cotton Textile Technology, 47(05), 64-67.
  • 10.Yan, G., Han, X. J., Yan, C. L., Zuo, C. C., & Cheng X. Q. (2014). Buckling analysis of composite cylindrical shell under axial compression load. Acta Materiae Compositae Sinica, 31(03), 781-787.
  • 11.He, B., Mi, Z. X., Wang, Y. J., & Gu, B. H. (2019). Unit cell modeling on torsion damage behavior of a novel three-dimensional integrated multilayer fabric-reinforced composite tubular structure. Textile Research Journal, 89(19-20), 4253-4264.
  • 12.Cao, H. J., Qian, K., & Luo, B. R. PREPARATION AND COMPRESSION PROPERTIES OF NEW THREE-DIMENSIONAL MULTI-LAYER TUBULAR BRAIDED COMPOSITES. Fiber Reinforced Plastics/Composites, (03), 19-22.
  • 13.Zhu, L. M., Zhang, H. W., Guo, J., Wang, Y., & Lyu, L. H. (2020). Axial Compression Experiments and Finite Element Analysis of Basalt Fiber/Epoxy Resin Three-Dimensional Tubular Woven Composites. MATERIALS, 13(11). (DOI: 10.3390/ma13112584).
  • 14.Palanivelu, S., Paepegem, W. V., Degrieck, J., Kakogiannis, D., Ackeren, J. V., Hemelrijck, D. V., Wastiels, J., & Vantomme, J. (2010). Comparative study of the quasi-static energy absorption of small-scale composite tubes with different geometrical shapes for use in sacrificial cladding structures. POLYMER TESTING, 29(3), 381-396.
  • 15.Ma, Y., & Yang, Y. Q. (2015). Energy absorption mechanism of circular-square irregular section composite tubes. Acta Materiae Compositae Sinica, 32(01), 243-249.
  • 16.Chambe, J. E, Bouvet, C., Dorival, O., & Ferrero, J. F. (2020). Energy absorption capacity of composite thin-wall circular tubes under axial crushing with different trigger initiations. JOURNAL OF COMPOSITE MATERIALS, 54(10), 1281-1304.
  • 17.Zheng, Z. C., Ge, L. H., Chen, Y., Sun, S. Y., & Wang, Q. (2011). Research on Mechanical Properties of Continuous Basalt Fiber Reinforced Resin Composites. Aeronautical Manufacturing Technology, (17), 58-60+64.
  • 18.Bu, F. Q., Dong, Y., Jin, W. G., Zhang, W. Z., & Du, X. G. (2019). Characteristics and application of basalt fiber composites. Brand & Standardization, (03), 56-58+61.

Lateral Compression Properties of Special-Shaped 3D Tubular Woven Composites

Year 2022, Volume: 32 Issue: 1, 77 - 85, 29.03.2022
https://doi.org/10.32710/tekstilvekonfeksiyon.783997

Abstract

In order to avoid the instability of composite materials laminated tube connection between layer and layer, with green basalt fiber as raw material, through the reasonable design, the special-shaped 3D (three-dimensional) tubular woven fabrics with two different thicknesses and shapes were fabricated on a semi-automatic sample loom with low cost. The special-shaped 3D tubular woven composites were fabricated by VARTM (vacuum assisted resin transfer molding) process. Load-displacement scatter plots and fitting curves and energy-displacement scatter plots and fitting curves were obtained by lateral compression tests. The results showed that the same shape,the load and energy absorption values increased with thickness and compression property was better. For the special-shaped 3D tubular woven composites with the same thickness, the load and energy absorption values of the circular tube was larger than the square tube. The correlation coefficients of load-displacement and energy-displacement polynomial fitting formulas calculated by the least square method in the Origin 8.5 software were all close to 1, indicated that the fitting effect was good. This method provided a direction for the research of special-shaped 3D tubular woven composites.

References

  • References 1.Ma, W. S., Ma, Z.Y., Ren B. J., & Fan, W. F. (2017). Meso-structure and modeling of a new three-dimensional braided tubular material. Journal of Reinforced Plastics and Composites, 37(5), 310-320.
  • 2.Zhong, W. X., Sun, X. L., & Ma, P. B. (2015). Application and Development of tubular composites. Fiber Glass, 000(001), 47-52.
  • 3.Luo, S. H., & Yang, C. Y. (2015). Research progress on the mechanical properties of tubular composite. Technical Textiles, 33(008), 1-5.
  • 4.Bharti, K., Kumaraswamidhas, L. A., & Das, R. R. (2020). Detailed investigation of adhesive fillet tubular T-joint of laminated FRP composite tube under axial compressive load. Welding in the World, 64(7), 1279-1292.
  • 5.Tong, Y. (2016). Design and Production of Partial Warp Tubular Fabric. Cotton Textile Technology, 044(005), 67-70.
  • 6.Wang, W., Zhu, J. H., Zhang, R. Y., Li, Y. L., Ji, F., & Yu, J. Y. (2018). Numerical characterization and simulation of the three-dimensional tubular woven fabric. 47(8), 2112-2127.
  • 7.Gu, P. (2002). A New Weaving Technique of 3-Dimensional Preforms for Composites by Conventional Loom. Journal of Textile Research, 23(5), 24-26+2.
  • 8.Wang, L. L., Xu, A. C., & Zhang, S. Y. (2017). Study on Tensile Mechanical Properties of Three-dimensional Tubular Composites. Journal of Wuhan Textile University, 30(03), 12-16.
  • 9.Wang, G. J., Wang, J. J., & Lyu, L. H. (2019). Design and Trial Weaving of Two abnormal 3D Tubular Woven Fabric. Cotton Textile Technology, 47(05), 64-67.
  • 10.Yan, G., Han, X. J., Yan, C. L., Zuo, C. C., & Cheng X. Q. (2014). Buckling analysis of composite cylindrical shell under axial compression load. Acta Materiae Compositae Sinica, 31(03), 781-787.
  • 11.He, B., Mi, Z. X., Wang, Y. J., & Gu, B. H. (2019). Unit cell modeling on torsion damage behavior of a novel three-dimensional integrated multilayer fabric-reinforced composite tubular structure. Textile Research Journal, 89(19-20), 4253-4264.
  • 12.Cao, H. J., Qian, K., & Luo, B. R. PREPARATION AND COMPRESSION PROPERTIES OF NEW THREE-DIMENSIONAL MULTI-LAYER TUBULAR BRAIDED COMPOSITES. Fiber Reinforced Plastics/Composites, (03), 19-22.
  • 13.Zhu, L. M., Zhang, H. W., Guo, J., Wang, Y., & Lyu, L. H. (2020). Axial Compression Experiments and Finite Element Analysis of Basalt Fiber/Epoxy Resin Three-Dimensional Tubular Woven Composites. MATERIALS, 13(11). (DOI: 10.3390/ma13112584).
  • 14.Palanivelu, S., Paepegem, W. V., Degrieck, J., Kakogiannis, D., Ackeren, J. V., Hemelrijck, D. V., Wastiels, J., & Vantomme, J. (2010). Comparative study of the quasi-static energy absorption of small-scale composite tubes with different geometrical shapes for use in sacrificial cladding structures. POLYMER TESTING, 29(3), 381-396.
  • 15.Ma, Y., & Yang, Y. Q. (2015). Energy absorption mechanism of circular-square irregular section composite tubes. Acta Materiae Compositae Sinica, 32(01), 243-249.
  • 16.Chambe, J. E, Bouvet, C., Dorival, O., & Ferrero, J. F. (2020). Energy absorption capacity of composite thin-wall circular tubes under axial crushing with different trigger initiations. JOURNAL OF COMPOSITE MATERIALS, 54(10), 1281-1304.
  • 17.Zheng, Z. C., Ge, L. H., Chen, Y., Sun, S. Y., & Wang, Q. (2011). Research on Mechanical Properties of Continuous Basalt Fiber Reinforced Resin Composites. Aeronautical Manufacturing Technology, (17), 58-60+64.
  • 18.Bu, F. Q., Dong, Y., Jin, W. G., Zhang, W. Z., & Du, X. G. (2019). Characteristics and application of basalt fiber composites. Brand & Standardization, (03), 56-58+61.
There are 18 citations in total.

Details

Primary Language English
Subjects Wearable Materials
Journal Section Articles
Authors

Lvlihua Lvlihua

Tingting Lyu This is me

Jingjing Wang This is me

Xiaoqing Xıong This is me

Early Pub Date March 29, 2022
Publication Date March 29, 2022
Submission Date August 22, 2020
Acceptance Date December 2, 2021
Published in Issue Year 2022 Volume: 32 Issue: 1

Cite

APA Lvlihua, L., Lyu, T., Wang, J., Xıong, X. (2022). Lateral Compression Properties of Special-Shaped 3D Tubular Woven Composites. Textile and Apparel, 32(1), 77-85. https://doi.org/10.32710/tekstilvekonfeksiyon.783997

No part of this journal may be reproduced, stored, transmitted or disseminated in any forms or by any means without prior written permission of the Editorial Board. The views and opinions expressed here in the articles are those of the authors and are not the views of Tekstil ve Konfeksiyon and Textile and Apparel Research-Application Center.