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Title: ELECTRICAL RESISTIVITY DISTRIBUTION ANALYSIS FOR TEXTILE STRUCTURES BASED ON COPPER YARNS
ELECTRICAL RESISTIVITY DISTRIBUTION ANALYSIS FOR TEXTILE STRUCTURES BASED ON COPPER YARNS

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Marian Catalin Grosu; Raluca Maria Aileni; Teodor Sarbu
10.5593/sgem2023/4.1/s17.07
10.5593/sgem2023/4.1
1314-2704
978-619-7603-59-0
English
23
4.1
•    Prof. DSc. Oleksandr Trofymchuk, UKRAINE 
•    Prof. Dr. hab. oec. Baiba Rivza, LATVIA
Renewable Energy Sources and Clean Technologies
The paper presents a new approach to the design and development of textile woven structures with copper yarn content intended for heating systems. Copper is known for its high electrical conductivity, meaning it can easily transfer electrical energy through its surface. This makes copper yarns ideal for heating applications, as they can quickly and efficiently transfer heat to the surrounding environment. In addition to their electrical properties, copper yarns also have good thermal conductivity, which means that they can transfer heat from one surface to another without losing much energy.
Copper yarns are also highly durable and flexible, assuring comfort to wear, non-toxic, reliable, and safe which makes them ideal for use in a range of textile performance applications, including clothing and non-clothing systems, with reduced risk of fire or electrical hazards. The analysis of the surface electrical resistivity as a function of the structural parameters of the woven textile structures, namely the distribution and the thickness of the copper yarns in the fabric's weft will highlight the variations between the conductive fabrics developed.
[1] Aileni R.M, Valderrama A C, Strungaru R., Chapter 10 - Wearable Electronics for Elderly Health Monitoring and Active Living, Ambient Assisted Living and Enhanced Living Environments, Butterworth-Heinemann, 2017, Pages 247-269, ISBN 9780128051955, https://doi.org/10.1016/B978-0-12-805195-5.00010-7.
[2] Libanori, A., Chen, G., Zhao, X. et al. Smart textiles for personalized healthcare. Nat Electron 5, 142–156 (2022). https://doi.org/10.1038/s41928-022-00723-z
[3] Safety and Effectiveness – Sunlighten Sauna. https://sunlightensauna.com.sg/safetyand- effectiveness
[4] Avdelidis, N. P., & Moropoulou, A. (2003). Emissivity considerations in building thermography. Energy and Buildings, 35(7), 663-667.
[5] Morgan, R. V., Reid, R. S., Baker, A. M., Lucero, B., & Bernardin, J. D. (2017). Emissivity measurements of additively manufactured materials (No. LA-UR-7-20513). Los Alamos National Lab.(LANL), Los Alamos, NM (United States).
[6] Yao, W. E., Intrator, T., & Hershkowitz, N. (1985). Direct indication technique of plasma potential with differential emissive probe. Review of scientific instruments, 56(4), 519-524.
[7] Lin, J. H., Lin, T. A., Lin, T. R., Jhang, J. C., & Lou, C. W. (2019). Processing techniques and properties of metal/polyester composite plain material: Electromagnetic shielding effectiveness and far-infrared emissivity. Journal of Industrial Textiles, 49(3), 365-382.
[8] Raji RK, Miao X, Boakye A. Electrical Conductivity in Textile Fibers and Yarns— Review. AATCC Journal of Research. 2017;4(3):8-21. doi:10.14504/ajr.4.3.2
[9] Choudhry, N.A.; Arnold, L.; Rasheed, A.; Khan, I.A.; Wang, L. Textronics—A Review of Textile-Based Wearable Electronics. Adv. Eng. Mater. 2021, 23, 2100469.
[10] Zhu, S.; Wang, M.; Qiang, Z.; Song, J.; Wang, Y.; Fan, Y.; You, Z.; Liao, Y.; Zhu, M.; Ye, C. Multi-functional and highly conductive textiles with ultra-high durability through ‘green’ fabrication process. Chem. Eng. J. 2021, 406, 127140
The Ministry of Research, Innovation and Digitalization funded this research through the Program Nucleu, Contract PN 23 26 01 03 (3D-WearIot), and the participation in the International Conference SGEM within Program 1 - Development of the national R&D system, Subprogram 1.2 - Institutional Performance - RDI excellence funding projects, Contract no. 4 PFE/2021.
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https://doi.org/10.5593/sgem2023/4.1/s17.07
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Proceedings of 23rd International Multidisciplinary Scientific GeoConference SGEM 2023
23rd International Multidisciplinary Scientific GeoConference SGEM 2023, 03 - 09 July, 2023
Proceedings Paper
STEF92 Technology
International Multidisciplinary Scientific GeoConference SGEM
SWS Scholarly Society; Acad Sci Czech Republ; Latvian Acad Sci; Polish Acad Sci; Russian Acad Sci; Serbian Acad Sci and Arts; Natl Acad Sci Ukraine; Natl Acad Sci Armenia; Sci Council Japan; European Acad Sci, Arts and Letters; Acad Fine Arts Zagreb Croatia; Croatian Acad Sci and Arts; Acad Sci Moldova; Montenegrin Acad Sci and Arts; Georgian Acad Sci; Acad Fine Arts and Design Bratislava; Russian Acad Arts; Turkish Acad Sci.
51-58
03 - 09 July, 2023
website
9176
conductive fabric, copper yarns, electrical resistivity, structural analysis