References
- Stull JO. The effect of moisture on firefighter protective clothing thermal insulation: a review of industry research. In: Nelson C, Henry N, editors. Performance of Protective Clothing: Issues and Priorities for the 21st Century, Seventh Volume (ASTM STP 1386). West Conshohocken, Pa, Usa: American Society for Testing and Materials (ASTM); 2000. p. 557–76.
- Mäkinen H, Smolander J, Vuorinen H. Simulation of the effect of moisture content in underwear and on the skin surface on steam burns of fire fighters. In: Mansdorf SZ, Sager R, Nielsen AP, editors. Performance of Protective Clothing: Issues and Priorities for the 21st Century, Second Symposium (ASTM STP 989). Philadelphia, PA, USA: American Society for Testing and Materials (ASTM); 1988. p. 415–21.
- Farnworth B. A numerical model of the combined diffusion of heat and water vapour through clothing. Text Res J 1986; 56:653–65.
- Gibson PW. Factors influencing steady-state heat and water transfer measurements for clothing materials. Text Res J 1993;63:749–64.
- Parsons KC. Heat transfer through human body and clothing systems. In: Raheel M, editor. Protective clothing systems and materials. New York, NY, USA: Decker; 1994. p. 137–71.
- Weder MS, Zimmerli T, Rossi RM. A sweating and moving arm for the measurement of thermal insulation and water vapour resistance of clothing. In: Johnson JS, Mansdorf SZ, editors. Performance of Protective Clothing: Issues and Priorities for the 21st Century, Fifth Volume (ASTM STP 1237). West Conshohocken, PA, USA: American Society for Testing and Materials (ASTM); 1996. p. 257–68.
- Yoo H, Hu YS, Kim EA. Effects of heat and moisture transport in fabrics and garments determined with a vertical plate sweating skin model. Text Res J 2000;70:542–9.
- Chen NY. Transient heat and moisture transfer through thermally irradiated cloth [dissertation]. Cambridge, MA, USA: MIT; 1959. Retrieved October 14, 2001 from http://theses.mit.edu:80/Dienst/UI/2.0/Describe/0018.mit.theses/1959-2
- Lee YM, Barker RL. Effect of moisture on the thermal protective performance of heat-resistant fabrics. Journal of Fire Sciences 1986;4:315–31.
- Rossi RM, Zimmerli T. Influence of humidity on the radiant, convective, and contact heat transmission through protective clothing materials. In: Johnson JS, Mansdorf SZ, editors. Performance of Protective Clothing: Issues and Priorities for the 21st Century, Fifth Volume (ASTM STP 1237). West Conshohocken, PA, USA: American Society for Testing and Materials (ASTM) 1996. p. 269–80.
- Stull JO. Comparative thermal insulative performance of reinforced knee areas of firefighter protective clothing. In: Nelson C, Henry N, editors. Performance of Protective Clothing: Issues and Priorities for the 21st Century, Seventh Volume (ASTM STP 1386). West Conshohocken, PA, USA: American Society for Testing and Materials (ASTM); 2000. p. 312–28.
- Torvi DA, Dale JD. Effects of variations in thermal properties on the performance of flame resistant fabrics for flash fires. Text Res J 1998;68:787–96.
- Veghte J. Effect of moisture on the burn potential in fire fighter’s gloves. Fire Technol 1987;23:313–22.
- Canadian General Standards Board (CGSB). Conditioning textile materials for testing (National Standard of Canada CAN/CGSB-4.2, No. 2-M88). Ottawa, Ont., Canada: CGSB; 1993.
- American Society for Testing and Materials (ASTM). Standard test method for felts (Standard No. ASTM D-461). Annual book for ASTM standards. Vol. 07.01. Philadelphia, PA, USA: ASTM; 1999.
- Canadian General Standards Board (CGSB). Thermal protective performance of materials for clothing (National Standard of Canada CAN/CGSB-4.2 No. 78.1-2001). Ottawa, Ont., Canada: CGSB; 2001.
- National Fire Protection Association (NFPA). NFPA 1977 standard on protective clothing and equipment for wildland fire fighting. Quincy, MA, USA: NFPA; 1998.
- Lawson L. Effects of moisture on heat transfer through thermal protective fabric systems [Master of Science thesis]. Edmonton, Alta., Canada: University of Alberta; 2002.