Home Articles List Article Information
International Design Journal
Journal Archive
Volume Volume 15 (2025)
Volume Volume 14 (2024)
Volume Volume 13 (2023)
Volume Volume 12 (2022)
Volume Volume 11 (2021)
Volume Volume 10 (2020)
Volume Volume 9 (2019)
Volume Volume 8 (2018)
Volume Volume 7 (2017)
Volume Volume 6 (2016)
Volume Volume 5 (2015)
Volume Volume 4 (2014)
Volume Volume 1 (2012)
Sabry, M., Baioumy, G., Taha, A. (2024). Influence of Multilayer Fabric Construction on Thermal Conductivity of Protective Fabrics. International Design Journal, 14(3), 21-27. doi: 10.21608/idj.2024.347715
Mohamed Sabry; Ghada Baioumy; Amr Magdy Taha. "Influence of Multilayer Fabric Construction on Thermal Conductivity of Protective Fabrics". International Design Journal, 14, 3, 2024, 21-27. doi: 10.21608/idj.2024.347715
Sabry, M., Baioumy, G., Taha, A. (2024). 'Influence of Multilayer Fabric Construction on Thermal Conductivity of Protective Fabrics', International Design Journal, 14(3), pp. 21-27. doi: 10.21608/idj.2024.347715
Sabry, M., Baioumy, G., Taha, A. Influence of Multilayer Fabric Construction on Thermal Conductivity of Protective Fabrics. International Design Journal, 2024; 14(3): 21-27. doi: 10.21608/idj.2024.347715

Influence of Multilayer Fabric Construction on Thermal Conductivity of Protective Fabrics

Article 2, Volume 14, Issue 3 - Serial Number 61, May and June 2024, Page 21-27  XML PDF (310.66 K)
Document Type: Original Article
DOI: 10.21608/idj.2024.347715
View on SCiNiTO View on SCiNiTO
Authors
Mohamed Sabry1; Ghada Baioumy2; Amr Magdy Taha3
1Professor of Textile Testing, Faculty of Applied Arts, Helwan University, Cairo.
2Professor of Textile Testing, Faculty of Applied Arts, Helwan University, Cairo
3Engineer at Spinning and Weaving Dep., Industrial Development Authority, Cairo,
Abstract
The effect of layering on properties such as air and water vapor permeability, and thermal conductivity is crucial for materials meant to be worn as clothing. The majority of these multi-layered assemblies are three-layered, as each layer performing a specific function and working together to achieve of thermal physiological equilibrium. One of the main factors that contribute to thermal resistance is the still air trapped in the fabric. Thermal protective clothing is primarily designed to provide protection from thermal hazards such as exposure to high temperature sources and hot gases. Heat transfer from the thermal hazards can be by radiation, convection or conduction. This study identifies the relationship between the construction of multilayer fabrics used in the production of protective fabrics, and their thermal conductivity property by using 3 layers and 4 materials. The results show that there are opportunities to control protective fabric thermal conductivity. Further, thermal management attributes of Protective Fabrics materials can also be significantly improved to reduce thermal loss
Keywords
Technical Textiles; Protective Textiles; Thermal Protective Textiles; Multilayer Fabrics; Thermal Comfort
Supplementary Files
References

[1] A Richard Horrocks and Subhash C. Anand. (2016). "Handbook of Technical Textiles Second edition Volume 1: Technical Textile Processes", Woodhead Publishing, UK.

[2] A. R Horrocks and S C Anand. (2000). Handbook of Technical Textiles. Woodhead Publishing Limited, England.

[3] Yasir Nawab. (2016). Textile Engineering. Walter de Gruyter GmbH, Germany.

[4] Mahmoud Azzam. (2019). Using Cellulosic Fiber Wastes to Produce Eco-friendly Geotextile Materials have Functional Properties Required in Agriculture Sector. Unpublished Master Degree Thesis, Helwan University, Egypt.

[5] Tamer F. Khalifa. (2012). Technical Textile; Design & Methodology. International Design Journal, Vol.2 No.1.

[6] Dalia Saber, and Khaled Abd El-Aziz. (2022). Advanced materials used in wearable health care devices and medical textiles in the battle against coronavirus (COVID-19): A review. Journal of Industrial Textiles, Vol. 51.

[7] Richard A. Scott. (2005). Textiles for Protection. Woodhead Publishing Limited, England.

[8] Faming Wang, and Chuansi Gao. (2014). Protective Clothing. Woodhead Publishing Limited, UK.

[9] Samridhi Garg, Vinay K Midha, and Monica Sikka. (2022). Studies on thermal comfort of multi-layered fabric assembly after wetting with sweat and distilled water. Journal of Industrial Textiles, Vol. 52.

[10] Ali Aldalbahi, Mehrez E. El-Naggar, Mohamed H. El-Newehy, Mostafizur Rahaman, Mohammad Rafe Hatshan, and Tawfik A. Khattab. (2021). Effects of Technical Textiles and Synthetic Nanofibers on Environmental Pollution. Polymers, 13, 155.

[11] Fawzy Saied Sherif. (January 2016). A New Prospects to Enhance the Commercial and Economical Status in Textile Industry. International Design Journal, Volume 6, Issue 1.

[12] C. N. Sivaramakrishnan. (July 2015). Functional Finishes on Technical Textiles. International journal on Textile Engineering and Processes, Volume 1, Issue 3.

[13] Jana Svecova­, Jan Strohmandl, Jan Fi­ser, Robert Toma, Petr Hajna, and Antonın Havelka. (2021). A comparison of methods for measuring thermal insulation of military clothing. Journal of Industrial Textiles, Vol. 51.

[14] Patricia Dolez. (2018). Advanced Characterization and Testing of Textiles. Woodhead Publishing, United Kingdom.

[15] Yasir Nawab. (2016). Textile Engineering. Walter de Gruyter GmbH, Germany.

[16] B P Saville. (2000). Physical testing of textiles. Woodhead Publishing Limited.

[17] Yaya Zhang, Jiyong Hu, and Xiong Yan. (April 2020). Dielectric constants of sewed multilayer fabric for wearable e-textiles. Journal of Industrial Textiles.

[18] ASTM D 737, "Standard test methods for air Permeability of textile fabrics".

[19] JIS L 1927, "Textiles-Measurement method of cool touch feeling property".

Statistics
Article View: 205
PDF Download: 232