Development of Flexible Smart Fabric Sensor for Wearable Electrocardiogram
Yıl 2017,
, 10 - 15, 30.10.2017
Suat Çetiner
,
Beytullah Göl
,
Hidayet Köse
Öz
Smart electronic
textiles which represent a new model for generating novel solutions for
integrating electronics into fabrics or garments able to sense outer conditions
or stimuli, reply and adapt behaviour to them in an intelligent way and exhibit
a challenge in several fields such as health, sport, automotive and aerospace.
Intelligent textiles may show health monitoring systems that greatly benefit
from the integration of electronics in textile materials.The main purpose of
electronic textiles is to become a part of everyday garments. Equipping the
ready-made clothing with soft, flexible and comfortable structural components
having different functions such as transforming into a structure with sensing
properties makes it the most appropriate environment for the emergence of smart
/ electronic textiles. In this study, a flexible smart fabric sensor was
developed and a smart garment was produced to detect the electrical activity of
a human heart for electrocardiogram monitoring (ECG). The smart garment that
displays heartbeats offers a different perpective for wearable electronic
textiles that incorporate textile-based sensors instead of external electrodes
connected to the body.
Kaynakça
- Axisa, Fabrice et al. (2005). Flexible Technologies and Smart Clothing for Citizen Medicine , Home Healthcare , and Disease Prevention. 9(3): 325–36.
- Carvalho H, Catarino AP, Rocha A, et al. (2014). Health monitoring using textile sensors and electrodes: An overview and integration of technologies. In: IEEE international symposium on medical measurements and applications (MeMeA), Lisbon, Portugal, pp.1–6.
- Erol, A.D., Cetiner , S. (2017).Wearable Electronic/Smart Textiles and Their Applications. Kahramanmaras Sutcu Imam University. Journal of Engineering Sciences. 20(1):1-20.
- Grancarić, Ana M et al. (2017). Conductive Polymers for Smart Textile Applications. Journal of Industrial Textiles
- Haghdoost, Fatemeh, Vahid Mottaghitalab, and Akbar Khodaparast Haghi. (2015). Comfortable Textile-Based Electrode for Wearable Electrocardiogram. Sensor Review 35(1): 20.
- Hong, K. H., Oh K. W., and Kang, T. J. (2005). Preparation and Properties of Electrically Conducting Textiles by in Situ Polymerization of poly(3,4-Ethylenedioxythiophene). Journal of Applied Polymer Science 97(3): 1326–32.
- Knittel, D., and Eckhard Schollmeyer. (2009). Electrically High-Conductive Textiles. Synthetic Metals 159(14): 1433–37.
- Köse, H. (2015). Investigation of Electrical and Electromagnetic Shielding Behaviors of Polypyrrole and Poly (3,4- ethylenedioxythiophene) coated fabrics, M.Sc. Thesis. KSU. Kahramanmaras
- Li, L., Frey, M. and Browning, K. J. (2010). Biodegradability Study on Cotton and Polyester Fabrics. Journal of Engineered Fibers and Fabrics 5(4): 42–53.
- Mankodyia K., Hassan Y.A., Vogt S., Gehring H., Hofmann U.G. (2010). Proc. UbiComp Copenhagen 211–220.
- Özdemir, H., and S. Kılınç. (2015). Smart Woven Fabrics with Portable and Wearable Vibrating Electronics. Autex Research Journal 15(2): 99–103.
- Selvaganesh, S. Vinod, J. Mathiyarasu, K. L N Phani, and V. Yegnaraman. 2007. “Chemical Synthesis of PEDOT-Au Nanocomposite.” Nanoscale Research Letters 2(11): 546–49.
- Trindade, I. G., Martins, F. and Baptista, P. (2015). High Electrical Conductance poly(3,4-Ethylenedioxythiophene) Coatings on Textile for Electrocardiogram Monitoring. Synthetic Metals 210: 179–85.
- Wu, J. 2011. “Morphology of Poly (3, 4-Ethylene dioxythiophene)(PEDOT) Thin Films, Crystals, Cubic Phases, Fibers and Tubes.” Vasa.
Yıl 2017,
, 10 - 15, 30.10.2017
Suat Çetiner
,
Beytullah Göl
,
Hidayet Köse
Kaynakça
- Axisa, Fabrice et al. (2005). Flexible Technologies and Smart Clothing for Citizen Medicine , Home Healthcare , and Disease Prevention. 9(3): 325–36.
- Carvalho H, Catarino AP, Rocha A, et al. (2014). Health monitoring using textile sensors and electrodes: An overview and integration of technologies. In: IEEE international symposium on medical measurements and applications (MeMeA), Lisbon, Portugal, pp.1–6.
- Erol, A.D., Cetiner , S. (2017).Wearable Electronic/Smart Textiles and Their Applications. Kahramanmaras Sutcu Imam University. Journal of Engineering Sciences. 20(1):1-20.
- Grancarić, Ana M et al. (2017). Conductive Polymers for Smart Textile Applications. Journal of Industrial Textiles
- Haghdoost, Fatemeh, Vahid Mottaghitalab, and Akbar Khodaparast Haghi. (2015). Comfortable Textile-Based Electrode for Wearable Electrocardiogram. Sensor Review 35(1): 20.
- Hong, K. H., Oh K. W., and Kang, T. J. (2005). Preparation and Properties of Electrically Conducting Textiles by in Situ Polymerization of poly(3,4-Ethylenedioxythiophene). Journal of Applied Polymer Science 97(3): 1326–32.
- Knittel, D., and Eckhard Schollmeyer. (2009). Electrically High-Conductive Textiles. Synthetic Metals 159(14): 1433–37.
- Köse, H. (2015). Investigation of Electrical and Electromagnetic Shielding Behaviors of Polypyrrole and Poly (3,4- ethylenedioxythiophene) coated fabrics, M.Sc. Thesis. KSU. Kahramanmaras
- Li, L., Frey, M. and Browning, K. J. (2010). Biodegradability Study on Cotton and Polyester Fabrics. Journal of Engineered Fibers and Fabrics 5(4): 42–53.
- Mankodyia K., Hassan Y.A., Vogt S., Gehring H., Hofmann U.G. (2010). Proc. UbiComp Copenhagen 211–220.
- Özdemir, H., and S. Kılınç. (2015). Smart Woven Fabrics with Portable and Wearable Vibrating Electronics. Autex Research Journal 15(2): 99–103.
- Selvaganesh, S. Vinod, J. Mathiyarasu, K. L N Phani, and V. Yegnaraman. 2007. “Chemical Synthesis of PEDOT-Au Nanocomposite.” Nanoscale Research Letters 2(11): 546–49.
- Trindade, I. G., Martins, F. and Baptista, P. (2015). High Electrical Conductance poly(3,4-Ethylenedioxythiophene) Coatings on Textile for Electrocardiogram Monitoring. Synthetic Metals 210: 179–85.
- Wu, J. 2011. “Morphology of Poly (3, 4-Ethylene dioxythiophene)(PEDOT) Thin Films, Crystals, Cubic Phases, Fibers and Tubes.” Vasa.