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http://dx.doi.org/10.12772/TSE.2021.58.167

Effect of Surface Roughness of Fabrics on Tensile Properties of 3D Printing Auxetic Re-entrant Pattern/Textile Composites  

Jung, Imjoo (Department of Fashion and Textiles, Dong-A University)
Lee, Sunhee (Department of Fashion and Textiles, Dong-A University)
Publication Information
Textile Science and Engineering / v.58, no.4, 2021 , pp. 167-176 More about this Journal
Abstract
In this study, we aimed to manufacture a 3D printed composite fabric that can be used as a shoe upper based on an auxetic re-entrant pattern. Four types of substrate material-cotton fabric (CO), polyester fabric (PET), aramid knit (ARNT), and neoprene (NP)-with different surface roughness were selected. Then, in combination with a 3D printing auxetic re-entrant pattern (3DP-RE), composite fabrics were prepared to analyze Poisson's ratio, the surface roughness, the peel strength, and tensile properties. The analysis of Poisson's ratios indicate that 3DP-RE presented a negative Poisson's ratio from 0% to 30%. 3DP-RE/CO and 3DP-RE/PET showed a positive Poisson's ratio at a strain at 5% or more due to limited deformation of the woven fabric. However, 3DP-RE/ARNT and 3DP-RE/NP showed negative Poisson's ratios with up to 25% and 30% strain, respectively, due to the stretchability of the substrate fabric. Evidently, 3DP-RE/textile composite fabrics were affected by surface roughness, including the fabric structure, density, and microfibers of the substrate fabric. Based on these results, the surface roughness of the raw materials was quantitatively measured. That of 3DP-RE was the lowest, at 0.9 ㎛. Those of CO, PET, ARNT, and NP used as the substrate fabric were 6.1, 4.6, 3.5, and 2.1 ㎛, respectively, in the order of NP < ARNT < PET < CO. It also affected the peel strength. The peel strength of 3DP-RE/CO had the highest value according to the fabric structure characteristics and its surface roughness. With regard to the tensile properties of 3DP-RE/textile composites, the higher the surface roughness, the higher are the peel strength and the maximum strength. However, the lower the surface roughness, the lower is the peel strength but more improved are the elongation at break and the toughness. In addition, the elongation at break and the toughness of 3DP-RE/textile composite fabrics were improved as compared with those of the substrate fabric.
Keywords
3D printing; auxetic re-entrant pattern; 3D printed composite fabric; surface roughness; peel strength;
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1 A. V. Mazaev, O. Ajeneza, and M. V. Shitikova, "Auxetic Materials: Classification Mechanical Properties and Applications", 2020 IOP Conf Ser: Mater Sci Eng., 2020, 747, 012008.
2 W. Yang, Z. M. Li, W. Shi, B. H. Xie, and M. B. Yang, "Review on Auxetic Materials", J. Mater. Sci., 2004, 39, 3269-3279.   DOI
3 X. Ren, R. Das, P. Tran, T. D. Ngo, and Y. M. Xie, "Auxetic Metamaterials and Structures: A Review", Smart Mater. Struct., 2018, 27, 023001.   DOI
4 L. Hu, M. Zhou, and H. Deng, "Dynamic Indentation of Auxetic and Non-auxetic Honeycombs under Large Deformation", Compos. Struct., 2019, 207, 323-330.   DOI
5 S. Lee, "Evaluation of Mechanical Properties and Washability of 3D Printed Lace/Voil Composite Fabrics Manufactured by FDM 3D Printing Technology", Fashion & Text. Res. J., 2018, 20, 353-359.   DOI
6 S. Kabir, H. Kim, and S. Lee, "Physical Property of 3D-printed Sinusoidal Pattern Using Shape Memory TPU filament", Text. Res. J., 2020, 90, 2399-2410.   DOI
7 O. Duncan, T. Shepherd, C. Moroney, L. Foster, P. D. Venkatraman, K. Winwood, T. Allen, and A. Alderson, "Review of Auxetic Materials for Sports Applications: Expanding Options in Comfort and Protection", Appl. Sci., 2018, 8, 941.   DOI
8 M. Lei, W. Hong, Z. Zhao, C. Hamel, M. Chen, H. Lu, and H. J. Qi, "3D Printing of Auxetic Metamaterials with Digitally Reprogrammable Shape", ACS Appl. Mater. Interface, 2019, 11, 22768-22776.   DOI
9 D. Sitotaw, D. Ahrendt, Y. Kyosev, and A. K. Kabish, "Additive Manufacturing and Textiles-state-of-the-art", Appl. Sci., 2020, 10, 5033.   DOI
10 V. Sular, E. Oner, and A. Okur, "Roughness and Frictional Properties of Cotton and Polyester Woven Fabrics", Indian J. Fibre. Text. Res., 2013, 38, 349-356.
11 N. Grimmelsmann, H. Meissner, and A. Ehrmann, "3D Printed Auxetic Forms on Knitted Fabrics for Adjustable Permeability and Mechanical Properties", IOP Conf Ser: Mater. Sci. Eng., 2016, 137, 012011.
12 P. Eutionnat-Diffo, Y. Chen, J. Guan, A. Cayla, C. Campagne, X. Zeng, and V. Nierstrasz, "Optimization of Adhesion of Poly Lactic Acid 3D Printed onto Polyethylene Terephthalate Woven Fabrics Through Modelling Using Textile Properties", Rapid Prototyping J., 2020, 26, 390-401.   DOI
13 S. Zhao, H. Hu, H. Kamrul, Y. Chang, and M. Zhang, "Development of Auxetic Warp Knitted Fabrics Based on Reentrant Geometry", Text. Res. J., 2020, 90, 344-356.   DOI
14 J. Zhang, G. Lu, and Z. You, "Large Deformation and Energy Absorption of Additively Manufacture Auxetic Materials and Structures: A Review", Comps. B., 2020, 201, 108340.   DOI
15 S. Chakrabory and M. Biswas, "3D Printing Technology of Polymer-fiber Composites in Textile and Fashion Industry: A Potential Roadmap of Concept to Consumer", Compos. Struct., 2020, 248, 112562.   DOI
16 S. Kim and H. Kim, "The Recent Tendency of Fashion Textiles by 3D Printing", Fashion & Text. Res. J., 2018, 20, 117-127.   DOI
17 Y. Han and J. Kim, "A Study on the Mechanical Properties of Knit Fabric Using 3D Printing - Focused on PLA, TPU Filament -", J. Fash. Bus., 2018, 22, 93-105.   DOI
18 N. Grimmelsmann, M. Kreuziger, M. Korger, H. Meissmer, and A. Ehrmann, "Adhesion of 3D Printed Material on Textile Substrates", Rapid Prototyping J., 2018, 24, 166-170.   DOI
19 Y. Han and J. Kim, "Study on Peel Strength Measurement of 3D Printing Composite Fabric by Using FDM", J. Fash. Bus., 2019, 23, 77-88.   DOI
20 A. Narula, C. Pastore, D. Schemelzeisen, S. E. Basri, J. Schenk, and S. Shajoo, "Effect of Knit and Print Parameters on Peel Strength of Hybrid 3-D Printed Textiles", J. Text. Fibrous Mater., 2018, 1, 1-10.
21 H. Kim, S. Kabir, and S. Lee, "Mechanical Properties of 3D Printed Re-entrant Pattern/neoprene Composite Textile by Pattern Tilitng Angle of Pattern", J. Korean Soc. Cloth. Text., 2020, 45, 106-122.
22 G. Loh, A. Sotayo, and E. Pei, "Development and Testing of Material Extrusion Additive Manufactured Polymer-textile Composites", Fash. Text., 2021, 8, 1-21.   DOI
23 S. Kabir, H. Kim, and S. Lee, "Characterization of 3D Printed Auxetic Sinusoidal Patterns/Nylon Composite Fabrics", Fiber, Polym., 2020, 21, 1372-1381.   DOI
24 H. Kim and S. Lee, "Mechanical Properties of 3D Printed Reentrant Pattern with Various Hardness of TPU Filament Manufactured Through FDM 3D Printing", Text. Sci. Eng., 2020, 57, 166-176.   DOI