The surface resistivity and shear characteristics of the polyaniline/ polyester fabrics produced by varying the number of coatings with different fabric structures were studied. With increase in number of coatings, the resistivity of the fabric decreases. The plain woven fabric gives higher surface resistivity than twill and satin weaves. Shear rigidity of twill and satin fabrics are lower than that of plain woven fabrics.
Joyner, K.H. , Copeland, P.R. and Macfarlane , I.P. (1989). An Evaluation of a Radio Frequency Protective Suit and Electrically Conductive Fabrics, IEEE Transactions on Electromagnetic Compatibility , 31(2): 129.
2.
Chen, H.C., Lee, K.C., Lin, J.H. and Koch, M. ( 2007). Comparison of Electromagnetic Shielding Effectiveness Properties of Diverse Conductive Textiles via Various Measurement Techniques , Journal of Materials Processing Technology, 184: 124-130.
3.
Gan, X., Wu, Y., Liu, L., Shen, B. and Hu, W. ( 2008). Electroless Plating of Cu-Ni-P Alloy on PET Fabrics and Effect of Plating Parameters on the Properties of Conductive Fabrics, Journal of Alloys and Compounds, 455: 308-313.
4.
Han, E.G. , Kim, E.A. and Oh, K.W. (2001). Electromagnetic Interference Shielding Effectiveness of Electroless Cu-plated PET Fabrics, Synthetic Metals, 123: 469-476.
5.
Cheng, K.B., Cheng, T.W., Lee, K.C., Ueng, T.H. and Hsing, W.H. ( 2003). Effects of Yarn Constitutions and Fabric Specifications on Electrical Properties of Hybrid Woven Fabrics, Applied Science and Manufacturing, 34: 971-978.
6.
Park, J.M., Kim, B.W., Jeong, S.H., Byun, S.K., Lee, J.Y., Joo, J.S., Jeong, S.H. and Park, M-J. ( 2003). Electrical Properties and EMI Shielding Characteristics of Polypyrrole-nylon 6 Composite Fabrics, Journal of Applied Polymer Science, 87: 1969-1974.
7.
Hansen, T.S. , West, K., Hassager, O. and Larsen, N.B. (2006). Integration of Conducting Polymer Network in Non-conductive Polymer Substrates, Synthetic Metals, 156: 1203-1207.
8.
Hakansson, E. , Amiet, A. and Kaynak, A. (2006). Electromagnetic Shielding Properties of Polypyrrole/polyester Composites in the 1-18 GHz Frequency Range , Synthetic Metals, 156: 917-925.
9.
Choi, S. and Jiang, Z. ( 2006). A Novel Wearable Sensor Device with Conductive Fabric and PVDF Film for Monitoring Cardiorespiratory Signals, Sensors and Actuators A, 128: 317-326.
10.
Dhawan, S.K., Sing, N. and Venkatachalam, S. ( 2001). Shielding Effectiveness of Conducting Polyaniline Coated Fabrics at 101 GHz, Synthetic Metals, 125: 389-393.
11.
Hakansson, E. , Kaynak, A., Lin, T., Nahavandi, S., Jones, T. and Hub, E. (2004). Characterization of Conducting Polymer Coated Synthetic Fabrics for Heat Generation, Synthetic Metals, 144: 21-28.
12.
Wu, J., Zhou, D., Too, C.O. and Wallace, G.G. ( 2005). Conducting Polymer Coated Lycra, Synthetic Metals, 155: 698-701.
13.
Foitzik, R.C. , Kaynak, A., Pfeffer, F.M. and Beckman, J. (2006). Synthesis, Polymerization and Wool Coating Studies of 3-iso-butylpyrrole and 3-iso-pentylpyrrole, Synthetic Metals, 156: 1333-1340.
14.
Behre, B. ( 1961). Mechanical Properties ofTextile Fabrics, Textile Research Journal, 31(2): 87-99.
15.
Behera, B.K. ( 2007). Comfort and Handle Behaviour of Linen-blended Fabrics , AUTEX Research Journal, 7(1): 32-47.
16.
Hersh, S.P. and Montgomery, D.J. (1952). Electrical Resistance Measurements on Fibers and Fiber Assemblies, Textile Research Journal, 22, 805-818.
17.
Chen, H.C., Lee, K.C., Lin, J.H. and Koch, M. ( 2007). Fabrication of Conductive Woven Fabric and Analysis of Electromagnetic Shielding via Measurement and Empirical Equation, Journal of Materials Processing Technology, 184: 124-130.
18.
Lo, W.M. , Hu, J.L., Lo, W.M. and Hu, J.L. (2002). Modelling a Fabric Drape Profile, Textile Research Journal, 72: 383-390.
19.
Mahar, T.J. , Dhingra, R.C. and Postle, R. (1987). Measuring and Interpreting Low-Stress Fabric Mechanical and Surface Properties, Part I: Precision of Measurement, Textile Research Journal, 57: 357-368.
20.
Stejskal, J. and Gilbert, R.G. (2002). Polyaniline Preparation of a Conducting Polymer (IUPAC Technical Report), Pure and Applied Chemistry, 74: 857-867.
21.
Oh, K.W. , Hong, K.H. and Kim, S.H. (1999). Electrically Conductive Textile by in situ Polymerisation of Aniline, Journal of Applied Polymer Science, 74: 2094-2101.
22.
. Behera, B.K. , Ishtiaque, S.M. and Chand, S. (1997). Comfort Properties of Fabrics Woven from Ring, Rotor, and Friction-Spun Yarns, Journal of Textile Institute, 88: 255-263.
23.
Kutanis, S. , Karakışla , M., Akbulut, U. and Saçak, M. (2007). The Conductive Polyaniline/poly (Ethylene Terephthalate) Composite Fabrics , Composites Part A: Applied Science and Manufacturing, 38: 609-614.
24.
. Lord, P.R. and Mohamed, M.H. ( 1976). Weaving: Conversion of Yarn to Fabric, Merrow Publishing Co Ltd., UK.
