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A Review: Conductive Textiles for the Usages of Renewable Energy

Yıl 2021, Cilt: 6 Sayı: 1, 6 - 11, 16.12.2021

Öz

From thousands of years textiles is associated with human civilization. Now-a-days renewable energy sources is one of the crucial factor for humanity. Green chemistry increases the necessity of producing energy-storage equipment more rapidly as time goes on. Today energy and environmental technologies combined with polymer and textile science together to develop technical polymers and textiles. For energy storage and conversion systems, various kind of devices was developed including super capacitors, Li-ion batteries and microbial fuel cells. Those devices can be integrated easily with textiles without affecting their performances. As renewable materials, textiles shows great importance to cope with our future energy and environmental challenges. An overview of conductive textiles is discussed in this review paper.

Kaynakça

  • Aacciona. (2021). Retrieved from Aacciona: https://www.acciona.com/renewable-energy/
  • Abu, T., & Nedal, Y. (2016). Chemical oxidative polymerization of polyaniline: A practical approach for preparation of smart conductive textiles. Journal of Chemical Education, 1606-1611.
  • Bao, L., & Li, X. (2012). Towards textile energy storage from cotton T‐shirts. Advanced materials, 3246-3252.
  • Chen, G., Li, Y., Bick, M., & Chen, J. (2020). Smart Textiles for Electricity Generation. Chemical Reviews, 3668-3720.
  • Hatamvand, M., Kamrani, E., & others, a. (2020). Recent advances in fiber-shaped and planar-shaped textile solar cells. Nano Energy, 104609.
  • Huang, Q., Wang, D., & Zheng, Z. (2016). Textile‐based electrochemical energy storage devices. Advanced Energy Materials, 1600783.
  • Huang, Y., & others, &. (2015). From industrially weavable and knittable highly conductive yarns to large wearable energy storage textiles. ACS nano, 4766-4775.
  • Inspirecleanenergy . (2021). (Inspire) Retrieved from https://www.inspirecleanenergy.com/blog/clean-energy-101/why-is-renewable-energy-important/
  • Jost, K., & others, &. (2011). Carbon coated textiles for flexible energy storage. Energy & Environmental Science, 5060-5067.
  • Kaushik, V., & others, &. (2015). Textile-based electronic components for energy applications: Principles, problems, and perspective. Nanomaterials, 1493-1531.
  • Li, Z., Ma, Y., & others, a. (2019). Multidimensional hierarchical fabric-based supercapacitor with bionic fiber microarrays for smart wearable electronic textiles. ACS applied materials & interfaces, 46278-46285.
  • Liu, W., Yan, X., Lang, J., Peng, C., & Xue, Q. (2012). Flexible and conductive nanocomposite electrode based on graphene sheets and cotton cloth for supercapacitor. Journal of Materials Chemistry, 17245-17253.
  • Liu, Z., & others, &. (2018). Advances in flexible and wearable energy‐storage textiles. Small Methods, 1800124.
  • Mao, M., Hu, J., & Liu, H. (2015). Graphene‐based materials for flexible electrochemical energy storage. International Journal of Energy Research, 727-740.
  • Montazer, M., & Nia, Z. (2015). Conductive nylon fabric through in situ synthesis of nano-silver: Preparation and characterization. Materials Science and Engineering: C, 341-347.
  • Shahzad, U. (2012). The need for renewable energy sources. Energy , 16-18.
  • Sun, H., Zhang, Y., Zhang, J., Sun, X., & Peng, H. (2017). Energy harvesting and storage in 1D devices. Nature Reviews Materials, 1-12.
  • Sun, P., Qiu, M., Li, M., Mai, W., Cui, G., & Tong, Y. (2019). Stretchable Ni@ NiCoP textile for wearable energy storage clothes. Nano Energy, 506-515.
  • swift-textile. (2021). (swift-textile) Retrieved from http://www.swift-textile.com/swift-textile-metalizing-advantages.html
  • technicaltextile.net. (2021). Retrieved from https://technicaltextile.net/articles/conductive-yarns-and-their-use-in-technical-textiles-3739
  • TextileBlog. (2021). Retrieved from https://www.textileblog.com/conductive-textiles-types-properties-and-applications/#more-1268
  • Tseghai, G., Mengistie, D., Malengier, B., Fante, K., & Van Langenhove, L. (2020). PEDOT: PSS-based conductive textiles and their applications. Sensors, 1881.
  • Vatansever, D., Siores, E., Hadimani, R., & Shah, T. (2011). Smart woven fabrics in renewable energy generation. Advances in modern woven fabrics technology, 23-38.
  • Wan, C., Jiao, Y., Liang, D., Wu, Y., & Li, J. (2018). A high-performance, all-textile and spirally wound asymmetric supercapacitors based on core–sheath structured MnO2 nanoribbons and cotton-derived carbon cloth. Electrochimica Acta, 285, 262-271.
  • Yang, B., Xiong, Y., Ma, K., Liu, S., & Tao, X. (2020). Recent advances in wearable textile‐based triboelectric generator systems for energy harvesting from human motion. EcoMat, 12054.
  • Yu, G., & others, a. (2011). Solution-processed graphene/MnO2 nanostructured textiles for high-performance electrochemical capacitors. Nano letters, 2905-2911.
  • Yun, M., Cha, S., Seo, S., & Lee, D. (2015). Insertion of dye-sensitized solar cells in textiles using a conventional weaving process. Scientific reports, 1-8.
  • Zhang, L., & others, a. (2016). All‐textile triboelectric generator compatible with traditional textile process. Advanced Materials Technologies, 1600147.

A Review: Conductive Textiles for the Usages of Renewable Energy

Yıl 2021, Cilt: 6 Sayı: 1, 6 - 11, 16.12.2021

Öz

From thousands of years textiles is associated with human civilization. Now-a-days renewable energy sources is one of the crucial factor for humanity. Green chemistry increases the necessity of producing energy-storage equipment more rapidly as time goes on. Today energy and environmental technologies combined with polymer and textile science together to develop technical polymers and textiles. For energy storage and conversion systems, various kind of devices was developed including super capacitors, Li-ion batteries and microbial fuel cells. Those devices can be integrated easily with textiles without affecting their performances. As renewable materials, textiles shows great importance to cope with our future energy and environmental challenges. An overview of conductive textiles is discussed in this review paper.

Kaynakça

  • Aacciona. (2021). Retrieved from Aacciona: https://www.acciona.com/renewable-energy/
  • Abu, T., & Nedal, Y. (2016). Chemical oxidative polymerization of polyaniline: A practical approach for preparation of smart conductive textiles. Journal of Chemical Education, 1606-1611.
  • Bao, L., & Li, X. (2012). Towards textile energy storage from cotton T‐shirts. Advanced materials, 3246-3252.
  • Chen, G., Li, Y., Bick, M., & Chen, J. (2020). Smart Textiles for Electricity Generation. Chemical Reviews, 3668-3720.
  • Hatamvand, M., Kamrani, E., & others, a. (2020). Recent advances in fiber-shaped and planar-shaped textile solar cells. Nano Energy, 104609.
  • Huang, Q., Wang, D., & Zheng, Z. (2016). Textile‐based electrochemical energy storage devices. Advanced Energy Materials, 1600783.
  • Huang, Y., & others, &. (2015). From industrially weavable and knittable highly conductive yarns to large wearable energy storage textiles. ACS nano, 4766-4775.
  • Inspirecleanenergy . (2021). (Inspire) Retrieved from https://www.inspirecleanenergy.com/blog/clean-energy-101/why-is-renewable-energy-important/
  • Jost, K., & others, &. (2011). Carbon coated textiles for flexible energy storage. Energy & Environmental Science, 5060-5067.
  • Kaushik, V., & others, &. (2015). Textile-based electronic components for energy applications: Principles, problems, and perspective. Nanomaterials, 1493-1531.
  • Li, Z., Ma, Y., & others, a. (2019). Multidimensional hierarchical fabric-based supercapacitor with bionic fiber microarrays for smart wearable electronic textiles. ACS applied materials & interfaces, 46278-46285.
  • Liu, W., Yan, X., Lang, J., Peng, C., & Xue, Q. (2012). Flexible and conductive nanocomposite electrode based on graphene sheets and cotton cloth for supercapacitor. Journal of Materials Chemistry, 17245-17253.
  • Liu, Z., & others, &. (2018). Advances in flexible and wearable energy‐storage textiles. Small Methods, 1800124.
  • Mao, M., Hu, J., & Liu, H. (2015). Graphene‐based materials for flexible electrochemical energy storage. International Journal of Energy Research, 727-740.
  • Montazer, M., & Nia, Z. (2015). Conductive nylon fabric through in situ synthesis of nano-silver: Preparation and characterization. Materials Science and Engineering: C, 341-347.
  • Shahzad, U. (2012). The need for renewable energy sources. Energy , 16-18.
  • Sun, H., Zhang, Y., Zhang, J., Sun, X., & Peng, H. (2017). Energy harvesting and storage in 1D devices. Nature Reviews Materials, 1-12.
  • Sun, P., Qiu, M., Li, M., Mai, W., Cui, G., & Tong, Y. (2019). Stretchable Ni@ NiCoP textile for wearable energy storage clothes. Nano Energy, 506-515.
  • swift-textile. (2021). (swift-textile) Retrieved from http://www.swift-textile.com/swift-textile-metalizing-advantages.html
  • technicaltextile.net. (2021). Retrieved from https://technicaltextile.net/articles/conductive-yarns-and-their-use-in-technical-textiles-3739
  • TextileBlog. (2021). Retrieved from https://www.textileblog.com/conductive-textiles-types-properties-and-applications/#more-1268
  • Tseghai, G., Mengistie, D., Malengier, B., Fante, K., & Van Langenhove, L. (2020). PEDOT: PSS-based conductive textiles and their applications. Sensors, 1881.
  • Vatansever, D., Siores, E., Hadimani, R., & Shah, T. (2011). Smart woven fabrics in renewable energy generation. Advances in modern woven fabrics technology, 23-38.
  • Wan, C., Jiao, Y., Liang, D., Wu, Y., & Li, J. (2018). A high-performance, all-textile and spirally wound asymmetric supercapacitors based on core–sheath structured MnO2 nanoribbons and cotton-derived carbon cloth. Electrochimica Acta, 285, 262-271.
  • Yang, B., Xiong, Y., Ma, K., Liu, S., & Tao, X. (2020). Recent advances in wearable textile‐based triboelectric generator systems for energy harvesting from human motion. EcoMat, 12054.
  • Yu, G., & others, a. (2011). Solution-processed graphene/MnO2 nanostructured textiles for high-performance electrochemical capacitors. Nano letters, 2905-2911.
  • Yun, M., Cha, S., Seo, S., & Lee, D. (2015). Insertion of dye-sensitized solar cells in textiles using a conventional weaving process. Scientific reports, 1-8.
  • Zhang, L., & others, a. (2016). All‐textile triboelectric generator compatible with traditional textile process. Advanced Materials Technologies, 1600147.
Toplam 28 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Enerji Sistemleri Mühendisliği (Diğer), Giyilebilir Malzemeler
Bölüm Makaleler
Yazarlar

Md Safuan Islam 0000-0002-8711-6297

Dicle Özdemir Küçükçapraz

Yayımlanma Tarihi 16 Aralık 2021
Kabul Tarihi 16 Aralık 2021
Yayımlandığı Sayı Yıl 2021 Cilt: 6 Sayı: 1

Kaynak Göster

IEEE M. S. Islam ve D. Özdemir Küçükçapraz, “A Review: Conductive Textiles for the Usages of Renewable Energy”, Yekarum, c. 6, sy. 1, ss. 6–11, 2021.