Penelitian ini bertujuan mengevaluasi kinerja termal kain pemanas tipe rangkap yang memanfaatkan kawat nikelin sebagai elemen pemanas untuk aplikasi tekstil cerdas. Prototipe kain diproduksi menggunakan mesin narrow fabric dengan penyisipan kawat berdiameter 0,1 mm dan 0,3 mm dalam variasi jumlah serta tegangan suplai. Pengujian dilakukan untuk mengukur kecepatan kenaikan suhu, suhu maksimum yang dicapai, kemampuan mempertahankan panas setelah sumber energi dihentikan, serta pengaruh jumlah kawat terhadap karakteristik termal kain. Hasil menunjukkan bahwa jumlah kawat dan besar tegangan berperan penting dalam menentukan laju pemanasan dan suhu akhir. Konfigurasi paling optimal diperoleh pada 4 kawat 0,1 mm dengan tegangan 3 V, serta 2–3 kawat 0,3 mm pada tegangan yang sama, yang mampu mencapai suhu terapi aman (<50 °C) secara cepat. Sebaliknya, penggunaan tegangan 6 V menghasilkan suhu berlebih yang berpotensi membahayakan. Selain itu, kawat berdiameter 0,3 mm menunjukkan kemampuan penyimpanan panas lebih baik dibandingkan kawat 0,1 mm. Temuan ini menegaskan pentingnya penentuan jumlah kawat dan tegangan yang tepat untuk menghasilkan kain pemanas yang aman dan efisien bagi aplikasi tekstil cerdas.

Wang, Y., Yang, R., & Zhang, X. Structural parameters affecting electrothermal properties of conductive fabrics. Textile Research Journal 85, 174–184 (2015).

Pragya, S., Singh, R., & Kumar, A. Development and evaluation of braided-cum-woven conductive fabrics for heating applications. Journal of Industrial Textiles (n.d.).

Zhao, Y. & Li, X. Design optimization of conductive pathways for uniform heat distribution in textile heating fabrics. Materials & Design 202, 109515 (2021).

Craighero, M., et al. Poly(benzodifurandione) coated silk yarn for thermoelectric textiles: durability and thermal stability. Materials 17, 1532 (2024).

Hao, L., et al. Joule heating behaviour of woven fabrics integrated with conductive elements. Fibers and Polymers 13, 1040–1046 (2012).

Tong, J., et al. Wearable electric heating fabrics based on metal fiber yarns. Fibers and Textiles in Eastern Europe 22, 105–110 (2014).

Bu, Y. Thermo-mechanical behavior of textile heating fabric. Fibers and Polymers 14, 163–169 (2013).

Sezgin, B., et al. Effect of different conductive yarns on heating behaviour of woven fabrics. Journal of Industrial Textiles 42, 234–247 (2012).

Noda, K. & Shinoda, H. Power and data transfer over double-sided conductive textiles for wearable devices. IEEE Transactions on Industrial Electronics 65, 2764–2772 (2018).

Halliday, D., Resnick, R., & Walker, J. Fundamentals of Physics 10th edn. (Wiley, 2014).

MedCrave. Development and characterization of electric heating fabric based on silver coated nylon yarn. J Textile Eng Fashion Technol (n.d.).

Sezgin, B., et al. Effect of Different Conductive Yarns on Heating Behaviour of Woven Fabrics. Journal of Industrial Textiles (2012).

Wang, R., et al. Structural Parameters Affecting Electrothermal Properties of Conductive Knitted Fabrics. Materials (2020).

Boushehri, A. N., et al. Fabrication and thermal assessment of three-layer woven heating fabrics. Textile Research Journal (2022).

Lee, S. Analysis of electrical and comfort properties of conductive knitted fabrics. Fibers and Polymers (2022).

Wang, R., et al. Structural Parameters Affecting Electrothermal Properties of Conductive Knitted Fabrics. Materials (2020).

Sezgin, B., et al. Effect of Different Conductive Yarns on Heating Behaviour of Woven Fabrics. Journal of Industrial Textiles (2012).

MedCrave. Development and characterization of electric heating fabric based on silver coated nylon yarn. J Textile Eng Fashion Technol (n.d.).

Zhao, H. & Li, X. Thermal performance of conductive textile heaters with different conductive path designs. Journal of Materials Science (2021).