{"title":"Investigation of Heating Behaviour of E-textile Structures","authors":"H. Sezgin, S. Kursun Bahad\u0131r, Y. E. Boke, F. Kalao\u011flu ","volume":101,"journal":"International Journal of Materials and Textile Engineering","pagesStart":491,"pagesEnd":495,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/10001259","abstract":"
By textile science incorporating with electronic
\r\nindustry, developed textile products start to take part in different
\r\nareas such as industry, military, space, medical etc. for health,
\r\nprotection, defense, communication and automation. Electronic
\r\ntextiles (e-textiles) are fabrics that contain electronics and
\r\ninterconnections with them. In this study, two types of base yarns
\r\n(cotton and acrylic) and three types of conductive steel yarns with
\r\ndifferent linear resistance values (14Ω\/m, 30Ω\/m, 70Ω\/m) were used
\r\nto investigate the effect of base yarn type and linear resistance of
\r\nconductive yarns on thermal behavior of e-textile structures. Thermal
\r\nbehavior of samples was examined by thermal camera.<\/p>\r\n","references":"[1] I. Locher and G. Tr\u00f6ster, \u201cEnabling technologies for electrical circuits\r\non a woven monofilament hybrid fabric,\u201d Text. Res. J., vol. 78, pp. 583-\r\n594, 2008.\r\n[2] A. A. Kohler, L. M. Hilty and C. Bakker, \u201cProspective impacts of\r\nelectronic textiles on recycling and disposal,\u201d J. Ind. Ecol., vol. 15, pp.\r\n496-511, 2011.\r\n[3] A. Dhawan, A. M. Seyam, T. K. Ghosh and J. F. Muth, \u201cWoven fabricbased\r\nelectrical circuits: part I: evaluating interconnect methods,\u201d Text.\r\nRes. J., vol. 74, pp. 913-919, 2004.\r\n[4] K. Cherenack and L. V. Pieterson, \u201cSmart textiles: challenges and\r\noppurtunities,\u201d J. Appl. Phys., vol. 112, pp. 1-13, 2012. [5] H. Cherenack, C. Zysset, T. Kinkeldei, N. M\u00fcnzenrieder and G. Tr\u00f6ster,\r\n\u201cWoven electronic fibers with sensing and display functions for smart\r\ntextiles,\u201d Adv. Mater., vol. 22, pp. 5178-5182, 2010.\r\n[6] J. Choi and T. S. Oh, \u201cContact resistance of flip-chip joints in wearable\r\nelectronic textiles,\u201d J. Electron. Mater., vol. 43, pp. 4464-4471, 2014.\r\n[7] S. T. A. Hamdani, P. Potluri and A. Fernando, \u201cThermo-mechanical\r\nbehavior of textile heating fabric based on silver coated polymeric yarn,\u201d\r\nMaterials, vol. 6, pp. 1072-1089, 2013.\r\n[8] R. Alagirusamy, J. Eichhoff, T. Gries and S. Jockenhoevel, \u201cCoating of\r\nconductive yarns for electrotextile applications,\u201d J. Text. Inst., vol. 104,\r\npp. 270-277, 2013.\r\n[9] L. Li, W. M. Au, Y. Li, K. M. Wan, S. H. Wan and K. S. Wong, \u201c\r\nDesign of intelligent garment with transcutaneous electrical nerve\r\nstimulation function based on the intarsia knitting technique,\u201d Text. Res.\r\nJ., vol. 80, pp. 279\u2013286, 2010.\r\n[10] C. Hertleer, A. Tronquo, H. Rogier and L. V. Langenhove, \u201cThe use of\r\ntextile materials to design wearable microstrip patch antennas,\u201d Text.\r\nRes. J., vol. 78, pp. 651\u2013658, 2008.\r\n[11] Y. Senol, T. Akkan and E. Y. Bulgun, \u201cActive T-shirt,\u201d Int. J. Cloth.\r\nSci. Technol., vol. 23, pp. 249\u2013257, 2011.\r\n[12] S. K. Bahad\u0131r, F. Kalaoglu and S. A. Thomassey, \u201cStudy on the beam\r\npattern of ultrasonic sensor integrated to textile structure,\u201d Int. J. Cloth.\r\nSci. Technol., vol. 23, pp. 232\u2013241, 2011.","publisher":"World Academy of Science, Engineering and Technology","index":"Open Science Index 101, 2015"}