Influence of Dry Cleaning on the Electrical Resistance of Screen Printed Conductors on Textiles

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Abstract

Electrically conducting inks were screen printed on various textile substrates. The samples were dry cleaned with the usual chemicals in order to investigate the influence of the mechanical treatment on the electrical conductivity. It was found that dry cleaning has a tremendous influence on this electrical conductivity. For several samples, it is observed that the electrical resistance increases with the square of the number of dry cleaning cycles. In order to explain this observation a theoretical model and a numerical simulation have been carried out, by assuming that dry cleaning cycles introduce a crack in the conducting layer. The theoretical analysis and the numerical analysis both confirmed the experimental observations.

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  • [1] MeoliD. May-PlumleeT. 2002. Interactive electronic textile development: A review of technologies» Journal of Textile and Apparel Technology and Management. vol.2 p.1-12.

  • [2] Merilampi S. Laine-Ma T. Ruuskanen P. 2009. The characterisation of electrically conductive silver ink patterns on flexible substrates. Microelectronics Reliability. vol.49 p.782-790.

  • [3] Yang Y.L. Chuang M.C. Lou S.L. Wang J. 2010. Thick-film textile-based amperometric sensors and biosensors. Royal Society of Chemistry. vol.135 p.1230-1234.

  • [4] Kim Y. Kim H. Yoo H.J. 2010. Electrical characterisation of screen – printed circuits on the fabric. IEEE Transactions on Advanced Packaging. vol. 33 p. 196-205.

  • [5 Karaguze lB. Using conductive inks and nonwoven textiles for wearable computing.http://www.ntcresearch.org/projectapp/project_pages/F04-NS17/pdf_files/Karaguzel%20-%20TIWC%20SPRG%20Paper.pdf/. NTC Project: F04-NS17. - North Carolina

  • [6] Karaguzel B. Merritt CR. Kang T. Wilson J.M Nagle HT Grant E Polurdeyhimi B. 2009. Flexible durable printed electrical circuits. The Journal of the Textile Institute. vol.100 p.1-9.

  • [7] Merritt C. R. Karaguzel B. Kang T-H. Wilson J. M. Franzon P.D.. Nagle H. T Poudeyhimi B. Grant E. 2005. Electrical characterization of Transmission Lines on Nonwoven Textile substrates. Material Research Society. vol. 870 p. 87-95.

  • [8] Hertleer C. Van Langenhove L. Rogier H. 2008. Printed Textile Antennas for Off-body Communication. Advances in Science and Technology. vol.60 p.64-66.

  • [9] Scarpello M. L. KazaniI. Hertleer C. Rogier H. Ginste D. V. 2012. Stability and efficiency of screen-printed wearable and washable antennas. IEEE Antennas and Wireless Propagation Letters. vol.11 p.838 - 841.

  • [10] Kazani I. Hertleer C. De Mey G. Guxho G. Van Langenhove L. 2013. Dry cleaning of electroconductive layers screen printed on flexible substrates. Textile Research Journal. vol. 83 p. 1541-1548.

  • [11] Varnaité S. Katunskis J. 2009. Influence of washing on the electric charge decay of fabrics with conductive yarns. FIBRES & TEXTILES in Eastern Europe 5 (76) vol.17 p.69-75.

  • [12] Varnaité S. Vitkauskas A. Abraitiené A. Rubžiené V. Valiené V. 2008. The features of electric charge decay in the Polyester Fabric containing metal fibres. Materials Science. vol.14 p.157-161.

  • [13] Van Der Pauw L. J. 1958. A method of measuring specific resistivity and Hall effect of discs of arbitrary shape. Philips Research Reports. vol.13 p.1-9.

  • [14] Banaszczyk J. De Mey G. Schwarz A. Van Langenhove L. 2010. The Van Der Pauw method for sheet resistance measurements of polypyrole coated para aramide woven fabrics» Journal of Applied Polymer Science vol.117 p.2553-2558.

  • [15] Kazani I. De Mey G. Hertleer C. Banaszczyk J. Schwarz A. Guxho G. Van Langenhove. L. 2011. Van der Pauw method for measuring resistivities of anisotropic layers printed on textile substrates. Textile Research Journal. vol.81 p.2117-2124.

  • [16] Churchill R. 1960. Complex variables and applications. Mc Graw Hill NY p.191-195.

  • [17] Kober H. 1957. Dictionary of conformal representations. Dover NY p.95-96.

  • [18] Abramowitz M. and StegunI. 1970. Handbook of mathematical functions. Dover New York p.885.

  • [19] Cengel Y. 2003. Heat transfer. Mc Graw Hill Boston p.281-291.

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