Herald of Technological University Herald of Technological University ВЕСТНИК ТЕХНОЛОГИЧЕСКОГО УНИВЕРСИТЕТА 3034-4689 61213 ПРОЦЕССЫ И АППАРАТЫ ХИМИЧЕСКОЙ ТЕХНОЛОГИИ ПРОЦЕССЫ И АППАРАТЫ ХИМИЧЕСКОЙ ТЕХНОЛОГИИ ADVANCES IN NANOTEXTILE TECHNOLOGIES Haghi A K Haghi A K Haghi@Canada.com Zaikov G E Zaikov G E Sofina S Yu Sofina S Yu Stoyanov O V Stoyanov O V ov_stoyanov@mail.ru University of Guilan, Rasht, Iran ru University of Guilan, Rasht, Iran ru Institute of Biochemical Physics, Russian Academy of Sciences ru Institute of Biochemical Physics, Russian Academy of Sciences ru Kazan National Research Technological University ru Kazan National Research Technological University ru Kazan National Research Technological University ru Kazan National Research Technological University ru 01 08 2025 01 08 2025 16 14 189 192 19 04 2023 https://vestniktu.ru/en/nauka/article/61213/view

Целью данного исследования является разработка датчиков, адаптированных к текстильной структуре, которые в состоянии обнаружить изменения длины и применимые для приобретения биомеханических сигналов. Для оптимизации готовой продукции выполняли контроль условий производственного процесса путем определения самого лучшего качества и количества окислителя, используемого в химической полимеризации. Чувствительные образцы ткани были подготовлены на месте осаждения полипиррола как электроактивного материала на материал лайкра/полиэстер. Критические свойства для характеристики коммерческих тензодатчиков, такие как чувствительность, время отклика и линейность процента, были измерены с использованием исходных данных, полученных из умной двигательной системы. Была измерена электропроводность в диапазоне между 7,2×10 -4 и 6,9×10 -3 См/см. По результатам измерений максимальные значения коэффициента датчика и линейности процентов принадлежат образцам с высокой электропроводностью, но лучшие линейности процентов, равные 92%, принадлежат образцам, на чьи поверхности процесс нанесения покрытия из проводящих частиц был выполнен без каких-либо помех.

The aim of this study is to develop fabric sensors adapted to textile structure able to detect length variations, applicable to acquire biomechanical signals. To optimization of final products, controlling of production process conditions through determination of the best quality and quantity of oxidant agent using in chemical polymerization, have performed. The sensing fabric samples were prepared with in-situ deposition of Polypyrrole as electro active material on Lycra/Polyester fabric. Critical properties for characterize commercial strain gauges such as sensitivity , response time, and linearity percent , have been measured using raw data obtained from smart motor system. A range of electrical conductivity between 7.2×10 -4 to 6.9×10 -3 S/cm has been measured. According to results the maximum value of gauge factor and linearity percent belong to the samples with the highest electrical conductivity, but the best linearity percent equal to 92% belong to the samples that coating process of conductive particles on their surface have performed with no disturbance.

fabric sensor biomechanical oxidant conducting polymers датчик биомеханический окислитель проводящие полимеры fabric sensor biomechanical oxidant conducting polymers датчик биомеханический окислитель проводящие полимеры

ARC Centers of Excellence and ARC Centers 2006 Extension Reviews selection Report for funding commencing in 2008, www.arc.gov.au/ncgp/celce-default.htm ARC Centers of Excellence and ARC Centers 2006 Extension Reviews selection Report for funding commencing in 2008, www.arc.gov.au/ncgp/celce-default.htm D. Diamond, Internet-scale sensing. Analytical Chemistry, 76(15), pp. 278A-286A, 2004. D. Diamond, Internet-scale sensing. Analytical Chemistry, 76(15), pp. 278A-286A, 2004. Venture Development Corporation, Wearable Systems: Global Market Demand Analysis. Vol. III: Infotainment Solutions, 2005. Venture Development Corporation, Wearable Systems: Global Market Demand Analysis. Vol. III: Infotainment Solutions, 2005. P.F. Binkley, W. Frontera, D.G. Standaert, and J. Stein, Predicting the potential of wearable technology Physicians share their vision of future clinical applications of wearable technology. IEEE engineering in Medicine and Biology Magazine, 22(3), pp. 23-27, 2003. P.F. Binkley, W. Frontera, D.G. Standaert, and J. Stein, Predicting the potential of wearable technology Physicians share their vision of future clinical applications of wearable technology. IEEE engineering in Medicine and Biology Magazine, 22(3), pp. 23-27, 2003. F.H. Wilhelm, W.T. Roth, and M.A. Sackner, The life Shirt. An advanced system for ambulatory measurement of respiratory and cardiac function. Behav Modif, 27(5), pp. 671-691, 2003. F.H. Wilhelm, W.T. Roth, and M.A. Sackner, The life Shirt. An advanced system for ambulatory measurement of respiratory and cardiac function. Behav Modif, 27(5), pp. 671-691, 2003. M. Arzt, T. Young, L. Finn, J.B. Skatrud, and T.D. Bradley, Association of sleep-disordered breathing and the occurrence of stroke. Am J Respir Crit Care Med, 172(11), pp. 1447-1451, 2005. M. Arzt, T. Young, L. Finn, J.B. Skatrud, and T.D. Bradley, Association of sleep-disordered breathing and the occurrence of stroke. Am J Respir Crit Care Med, 172(11), pp. 1447-1451, 2005. G.M. Spinks, G.G. Wallace, L. Liu, and D. Zhou, Conducting polymers electromechanical actuators and strain sensors. Macromolecular Symposia, 192, pp. 161-169, 2003. G.M. Spinks, G.G. Wallace, L. Liu, and D. Zhou, Conducting polymers electromechanical actuators and strain sensors. Macromolecular Symposia, 192, pp. 161-169, 2003. R. Ishida, Y. Yonezawa, H. Maki, H. Ogawa, I. Ninomiya, K. Sada, S. Hamada, A.W. Hahn, and W.M. Caldwell, A wearable, mobile phone-based respiration monitoring system for sleep apnea syndrome detection. Biomed Sci Instrum, 41, pp. 289-293, 2005. R. Ishida, Y. Yonezawa, H. Maki, H. Ogawa, I. Ninomiya, K. Sada, S. Hamada, A.W. Hahn, and W.M. Caldwell, A wearable, mobile phone-based respiration monitoring system for sleep apnea syndrome detection. Biomed Sci Instrum, 41, pp. 289-293, 2005. M.L. Davies, C.J. Hamilton, S.M. Murphy, and B.J. Tighe, Polymer Membranes in Clinical Sensor Applications.1. An Overview of Membrane-Function. Biomaterials, 13(14), pp. 971-978, 1992. M.L. Davies, C.J. Hamilton, S.M. Murphy, and B.J. Tighe, Polymer Membranes in Clinical Sensor Applications.1. An Overview of Membrane-Function. Biomaterials, 13(14), pp. 971-978, 1992. T. Someya, T. Sekitani, S. Iba, Y. Kato, H. Kawaguchi, and T. Sakurai, A large-area, flexible pressure sensor matrix with organic field-effect transistors for artificial skin applications. Proceedings of the National Academy of Sciences of the United States of America, 101(27), p. 9966-9970, 2004. T. Someya, T. Sekitani, S. Iba, Y. Kato, H. Kawaguchi, and T. Sakurai, A large-area, flexible pressure sensor matrix with organic field-effect transistors for artificial skin applications. Proceedings of the National Academy of Sciences of the United States of America, 101(27), p. 9966-9970, 2004.