References
- Anon. (1996). Protective clothing ensemble for structural firefighting. Quincy, MA: National Fire Protection Association.
- Anon. (2001). Aramid fibers. Retrieved from www.chem.uwec.edu: https://www.chem.uwec.edu/chem405_s01/malenirf/project.html
- Anon. (2002). ISO 6942. Protective clothing—Protection against heat and fire—evaluation of materials and material assemblies when exposed to a source of radiant heat. Retrieved from https://www.iso.org/standard/26327.html
- Anon. (2014). UHV magnetron sputtering system (MDS). Retrieved from http://www.adnano-tek.com/magnetron-sputtering-deposition-msd.html
- Anon. (2018a). ARAMID HMP, LLC, high performance materials. Retrieved from https://www.aramid.com/
- Anon. (2018b). Swicofil. Retrieved from https://www.swicofil.com/consult/consulting-research-and-development
- Azom. (2013). Silver (Ag)–Properties, applications. Retrieved from https://www.azom.com/article.aspx?ArticleID=9282
- Bajaj, P., & Sengupta, A. (1992). Protective clothing. Textile Progress, 22(2–4), 1–110.
- Burrow, T., & Lenzing, A. (2013). Flame Resistant Man made Fibers. In F. S. Kilinc, Hand book of fire resistant textile (pp. 221–243). Oxford: Wood Head Publishing.
- Celcar, D., Meinander, H., & Jelka, G. (2008). Heat and moisture transmission properties of clothing systems evaluated by using a sweating thermal manikin under different environmental conditions. International Journal of Clothing Science and Technology, 20(4), 240–252.
- Cui, Z., Ma, C., & Lv, N. (2015). Effects of heat treatment on the mechanical and thermal performance of fabric used in firefighting protective clothing. Fibers and Textiles in Eastern Europe, 23, 74–78.
- Fridrichová, L. (2013). A new method of measuring the bending rigidity of fabrics and its application to the determination of the their anisotropy. Textile Research Journal, 83(9), 883–892.
- Fu, M., Weng, W., & Yuan, H. (2013). Effects of multiple air gaps on the thermal performance of firefighter protective clothing under low-level heat exposure. Textile Research Journal, 84(9), 1–11.
- Holcombe, B. (1983). Heat transfer through fire beds by radiation with shading and conduction. Fire Safety Journal, 6(2), 129–141.
- Holmer, I. (2006). Protective clothing in hot environments. Industrial Health, 44, 404–413.
- Huang, J. (2006). Thermal parameters for assessing thermal properties of clothing. Journal of Thermal Biology, 31, 61–466.
- Jin, L., Hong, K.-A., Nam, H. D., & Yoon, K. J. (2011). Effect of thermal barrier on thermal protective performance of firefighter garments. Journal of Fiber Bioengineering and Informatics, 4(3), 245–252.
- Jin, L., Honga, K., & Yoona, K. (2013). Effect of aerogel on thermalprotective performance of Firefighter clothing. Journal of Fiber Bioengineering and Informatics, 6, 315–324.
- Keiser, C., & Rossi, R. (2008). Temperature analyssis for prediction of steam formation and transfer in multilayer thermal protective clothing at low level thermal radiation. Textile Research Journal, 78(11), 1025–1035.
- Lawson, J. (1997). Fire fighters protective clothing and thermal environments of structural fire-fighting. ASTM Special Technical Publication, 1273, 334–335.
- Lee, J., Ko, E., Lee, H., Kim, J., & Choi, J. (2011). Validation of clothing insulation estimated by global and serial methods. International Journal of Clothing Science and Technology, 23(2/3), 184–198.
- Li, Y. (2001). The science of clothing comfort. Textile Progress, 31, 1–135.
- Lu, J., Hong, K., & Yoon, K. (2013). Effect of aerogel on thermal protective performance of firefighter clothing. Journal of Fiber Bioengineering and Informatics, 6, 315–324.
- Matt, H. (2014). What is magnetron sputtering. Retrieved from http://www.semicore.com/what-is-sputtering
- Meb, G. W., & Gmbh, P. (2002). Combustion behavior test equipment according to ISO 6492 manual. Berlin: Wazau.
- Min, K., Son, Y., Kim, C., Lee, Y., & Hong, K. (2007). Heat and moisture transfer from skin to environment through fabrics: A mathematical model. International Journal of Heat and Mass Transfer, 50(25–26), 5292–5304.
- M.¨ Kinen, H. (2005). Firefighter’s protective clothing. In S. RA (Ed.), Textile for protection (pp. 622–647). Cambridge: Woodhead Publishing.
- Onofrei, E., Petrusic, S., & Bedek, G. (2015). Study of heat transfer through multilayer protective clothing at low-level thermal radiation. Journal of Industrial Textile, 45, 1–17.
- Rajkishore, N., Shadi, H., & Rajiv Padhye, P. (2014). Recent trends and future scope in the protection and comfort of firefighter’s personal protective clothing. Fire Science Reviews, 3, 1–9.
- Raslan, W. M., Rashed, U. S., El-Sayad, H., & El-Halwagy, A. A. (2011). Ultraviolet protection, flame retardancy and antibacterial properties of treated polyester fabric using plasma-nano technology. Materials Sciences and Applications, 02(10), 2, 1432–1442.
- Roguski, J., Stegienko, K., Kubis, D., & Błokowski, M. (2016). Comparison of the requirements and directions of development of methods for testing protective clothing for firefighting. Fibres and Textiles in Eastern Europe, 24(5(119), 132–136.
- Schacher, L., Adolphe, D. C., & Drean, J. Y. (2000). Comparison between thermal insulation and thermal properties of classical and microfibres polyester fabrics. International Journal of Clothing Science and Technology, 12(2), 84–95.
- Shaid, A., Wang, L., & Padhye, R. (2016). The thermal protection and comfort properties of aerogel and PCM-coated fabric for firefighter garment. Textile Research Journal, 45, 1–15.
- Song, G. (2007). Clothing air gap layers and thermal protective performance in single layer garment. Journal of Industrial Textiles, 36(3), 193–205.
- Song, G., Chitrphiromsri, P., & Ding, D. (2008). Numerical simulations of heat and moisture transport in thermal protective clothing under flash fire conditions. International Journal of Occupational Saftery Ergonomics, 14(1), 89–106.
- Song, G., Paskaluk, S., Sati, R., Crown, E., Dale, J., & Ackerman, M. (2011). Thermal protective performance of protective clothing used for low radiant heat protection. Textile Research Journal, 81, 311–323.
- Tolera, A. (2015). Analyzing and modelling of comfort and protection properties of firefighters protective clothing (Master Thesis). Department of Textile Engineering, Istanbul Technical University, Istanbul, Turkey.
- Venkataraman, M., Mishra, R., & Kotresh, T. (2015). Effect of compressibility on heat transport phenomena in aerogel-treated nonwoven fabrics. The Journal of the Textile Institute, 107, 1–9.
- Zhu, G., Kremenakova, D., Wang, Y., Militky, J., & Mishra, R. (2015). Study on air permeability and thermal resistance of textiles under heat convection. Textile Research Journal, 85(16), 1681–1690.
- Zupin, Ž., Hladnik, A., & Dimitrovski, K. (2011). Prediction of one-layer woven fabrics air permeability using porosity parameters. Textile Research Journal, 82(2), 117–128.