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Heat Gain From Thermal Radiation Through Protective Clothing With Different Insulation, Reflectivity and Vapour Permeability

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The heat transferred through protective clothing under long wave radiation compared to a reference condition without radiant stress was determined in thermal manikin experiments. The influence of clothing insulation and reflectivity, and the interaction with wind and wet underclothing were considered. Garments with different outer materials and colours and additionally an aluminised reflective suit were combined with different number and types of dry and pre-wetted underwear layers. Under radiant stress, whole body heat loss decreased, i.e., heat gain occurred compared to the reference. This heat gain increased with radiation intensity, and decreased with air velocity and clothing insulation. Except for the reflective outer layer that showed only minimal heat gain over the whole range of radiation intensities, the influence of the outer garments’ material and colour was small with dry clothing. Wetting the underclothing for simulating sweat accumulation, however, caused differing effects with higher heat gain in less permeable garments.
Rocznik
Strony
231--244
Opis fizyczny
Bibliogr. 40 poz., tab., wykr.
Twórcy
autor
  • Leibniz Research Centre for Working Environment and Human Factors (IfADo), Germany
autor
  • Department of Design Sciences, EAT, Lund University, Lund, Sweden
autor
  • Centre d’Etudes de Physiologie Appliquee, CNRS, Strasbourg, France
  • TNO Defence, Security and Safety, Rijswijk, The Netherlands
autor
  • Leibniz Research Centre for Working Environment and Human Factors (IfADo), Germany
autor
  • Department of Design Sciences, EAT, Lund University, Lund, Sweden
autor
  • SmartWearLab, Tampere University of Technology, Tampere, Finland
autor
  • W.L. Gore & Associates GmbH, Putzbrunn, Germany
autor
  • Humanikin GmbH, St. Gallen, Switzerland
autor
  • Department of Human Sciences, Loughborough University, Loughborough, UK
Bibliografia
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  • 6.Malchaire J, Piette A, Kampmann B, Mehnert P, Gebhardt H, Havenith G, et al. Development and validation of the predicted heat strain model. Ann Occup Hyg. 2001;45(2):123–35.
  • 7.Cheuvront S, Montain S, Goodman D, Blanchard L, Sawka M. Evaluation of the limits to accurate sweat loss prediction during prolonged exercise. Eur J Appl Physiol. 2007;101(2):215–24.
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  • 10.Havenith G, Holmer I, Meinander H, den Hartog EA, Richards M, Brode P, et al. THERMPROTECT. Assessment of thermal properties of protective clothing and their use. Summary Technical Report, European Union Contract No. G6RD-CT-2002-00846. 2005. Retrieved March 18, 2010, from: http://www.lboro.ac.uk/departments/hu/groups/htel/THERMPROTECT/THERMPROTECT%20report%201.htm.
  • 11.Kuklane K, Gao C, Holmer I, Giedraityte L, Brode P, Candas V, et al. Calculation of clothing insulation by serial and parallel methods: effects on clothing choice by IREQ and thermal responses in the cold. International Journal of Occupational Safety and Ergonomics (JOSE). 2007;13(2):103–16.
  • 12.Havenith G, Richards MG, Wang X, Brode P, Candas V, den Hartog E, et al. Apparent latent heat of evaporation from clothing: attenuation and “heat pipe” effects. J Appl Physiol. 2008;104(1):142–9.
  • 13.Richards MGM, Rossi RM, Meinander H, Brode P, Candas V, den Hartog E, et al. Dry and wet heat transfer through clothing dependent on the clothing properties under cold conditions. International Journal of Occupational Safety and Ergonomics (JOSE). 2008;14(1):69–76.
  • 14.Brode P, Havenith G, Wang X, Candas V, den Hartog E, Griefahn B, et al. Nonevaporative effects of a wet mid layer on heat transfer through protective clothing. Eur J Appl Physiol. 2008;104(2):341–9.
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  • 16.Meinander H, Brode P, THERMPROTECT network. Effect of long wave radiation on heat loss through protective clothing ensembles—material, manikin and human subject evaluation. In: 6th International Thermal Manikin and Modeling Meeting (6I3M): Thermal Manikins and Modelling. Hong Kong: The Hong Kong Polytechnic University; 2006. p. 29–40.
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  • 18.van Es EM, den Hartog EA, Brode P, Candas V, Heus R, Havenith G et al. Effects of short wave radiation and radiation area on human heat strain in reflective and non-reflective protective clothing. In: 3rd European Conference on Protective Clothing (ECPC) and NOKOBETEF 8. Protective Clothing Towards Balanced Protection [CD-ROM]. Warszawa, Poland: CIOP–PIB; 2006.
  • 19.Neuschulz H. Thermophysiologische Beanspruchung des menschlichen Organismus durch anisotrope Infrarotstrahlung [Thermal strain of the human organism by anisotropic infrared radiation]. Bremerhaven, Germany: Wirtschaftsverlag N. W. Verlag fur neue Wissenschaft; 2003.
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  • 21.Muller BH, Hettinger T. Influence and assessment of heat radiation. Ergonomics. 1995;38(1):128–37.
  • 22.Shapiro Y, Moran D, Epstein Y, Stroschein L, Pandolf KB. Validation and adjustment of the mathematical prediction model for human sweat rate responses to outdoor environmental conditions. Ergonomics. 1995;38(5):981–6.
  • 23.Keiser C, Rossi RM. Temperature analysis for the prediction of steam formation and transfer in multilayer thermal protective clothing at low level thermal radiation. Text Res J. 2008;78(11):1025–35.
  • 24.Barker RL, Guerth-Schacher C, Grimes RV, Hamouda H. Effects of moisture on the thermal protective performance of firefighter protective clothing in low-level radiant heat exposures. Text Res J. 2006;76(1):27–31.
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  • 27.Brode P, Candas V, Kuklane K, den Hartog EA, Havenith G, Griefahn B et al. Effects of heat radiation on the heat exchange with protective clothing—a thermal manikin study. In: 3rd European Conference on Protective Clothing and NOKOBETEF 8: Protective Clothing—Towards Balanced Protection [CD-ROM]. Warszawa: CIOP-PIB; 2006.
  • 28.Kuklane K, Gao C, Holmer I, THERMPROTECT network. Effects of natural solar radiation on manikin heat exchange. In: 3rd European Conference on Protective Clothing and NOKOBETEF 8: Protective Clothing—Towards Balanced Protection [CD-ROM]. Warszawa: CIOPPIB; 2006.
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  • 31.International Organization for Standardization (ISO). Ergonomics of the thermal environment—estimation of thermal insulation and water vapour resistance of a clothing ensemble (Standard No. ISO 9920:2007). Geneva, Switzerland: ISO; 2007.
  • 32.International Organization for Standardization (ISO). Textiles—physiological effects— measurement of thermal and water-vapour resistance under steady-state conditions (sweating guarded-hotplate test) (Standard No. ISO 11092:1993). Geneva, Switzerland: ISO; 1993.
  • 33.International Organization for Standardization (ISO). Textiles—determination of the permeability of fabrics to air (Standard No. ISO 9237:1995). Geneva, Switzerland: ISO; 1995.
  • 34.Bonnaire T, Touchais G. NF P 92-501. Epiradiateur test. In: Troitzsch J, editor. Plastics flammability handbook. Principles, regulations, testing, and approval. Munich, Germany: Hanser; 2004. p. 298–9.
  • 35.International Organization for Standardization (ISO). Clothing. Physiological effects. Measurement of thermal insulation by means of a thermal manikin (Standard No. ISO 15831:2004). Geneva, Switzerland: ISO; 2004.
  • 36.Havenith G, Wang X, THERMPROTECT network. Interaction effects of radiation and convection measured by a thermal manikin wearing protective clothing with different radiant properties. In: The Third International Conference on Human–Environment System: ICHES ‘05. Tokyo, Japan: Bunka Women’s University; 2005. p. 47–50.
  • 37.den Hartog EA, Brode P, Candas V, Havenith G. Effect of clothing insulation on attenuation of radiative heat gain. In: 12th International Conference on Environmental Ergonomics: Environmental ergonomics XII. Ljubljana, Slovenia: Biomed; 2007. p. 157–8.
  • 38.Clark JA, Cena K. Net radiation and heat transfer through clothing: the effects of insulation and colour. Ergonomics. 1978;21(9):691–6.
  • 39.Havenith G, Nilsson HO. Correction of clothing insulation for movement and wind effects, a meta-analysis. Eur J Appl Physiol. 2004;92(6):636–40.
  • 40.Lotens WA. Heat exchange in clothing. In: Stellman JM, editor. Encyclopaedia of occupational health and safety. 4th ed. Geneva, Switzerland: International Labour Organization; 1998. p. 42.23–9.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-096932c6-aab5-4c55-89aa-a212f83cff6d
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