Abstract
In order to assess the non-evaporative components of the reduced thermal insulation of wet clothing, experiments were performed with a manikin and with human subjects in which two layers of underwear separated by an impermeable barrier were worn under an impermeable overgarment at 20°C, 80% RH and 0.5 ms−1 air velocity. By comparing manikin measurements with dry and wetted mid underwear layer, the increase in heat loss caused by a wet layer kept away from the skin was determined, which turned out to be small (5–6 W m−2), irrespective of the inner underwear layer being dry or wetted, and was only one third of the evaporative heat loss calculated from weight change, i.e. evaporative cooling efficiency was far below unity. In the experiments with eight males, each subject participated in two sessions with the mid underwear layer either dry or wetted, where they stood still for the first 30 min and then performed treadmill work for 60 min. Reduced heat strain due to lower insulation with the wetted mid layer was observed with decreased microclimate and skin temperatures, lowered sweat loss and cardiac strain. Accordingly, total clothing insulation calculated over the walking period from heat balance equations was reduced by 0.02 m2 °C W−1 (16%), while for the standing period the same decrease in insulation, representing 9% reduction only showed up after allowing for the lower evaporative cooling efficiency in the calculations. As evaporation to the environment and inside the clothing was restricted, the observed small alterations may be attributed to the wet mid layer’s increased conductivity, which, however, appears to be of minor importance compared to the evaporative effects in the assessment of the thermal properties of wet clothing.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aoyagi Y, McLellan T, Shephard R (1996) Residual analysis in the determination of factors affecting the estimates of body heat storage in clothed subjects. Eur J Appl Physiol 73:287–298 doi:10.1007/BF02425489
Borg G (1998) Borg’s perceived exertion and pain scales. Human kinetics, Champaign
Candas V, Bröde P, Havenith G, THERMPROTECT network (2006) Classical approach to heat and vapour resistance calculations cannot explain heat transfer in wet clothing. In: Fan J (ed) Thermal manikins and modelling. The Hong Kong Polytechnic University, Hong Kong, pp 235–246
Chen YS, Fan J, Zhang W (2003) Clothing thermal insulation during sweating. Text Res J 73:152–157
Cheuvront SN, Montain SJ, Goodman DA, Blanchard L, Sawka MN (2007) Evaluation of the limits to accurate sweat loss prediction during prolonged exercise. Eur J Appl Physiol 101:215–224 doi:10.1007/s00421-007-0492-x
Craig FN, Moffitt JT (1974) Efficiency of evaporative cooling from wet clothing. J Appl Physiol 36:313–316
DIN 50010-2 (1981) Klimate und ihre technische Anwendung, Klimabegriffe, Physikalische Begriffe. Beuth, Berlin
Havenith G, Nilsson HO (2004) Correction of clothing insulation for movement and wind effects, a meta-analysis. Eur J Appl Physiol 92:636–640
Havenith G, Holmér I, Meinander H, den Hartog EA, Richards M, Bröde P, Candas V (2005) THERMPROTECT. Assessment of thermal properties of protective clothing and their use. Summary Technical Report European Union Contract N°: G6RD-CT-2002-00846 (accessible at http://www.lboro.ac.uk/departments/hu/groups/htel/THERMPROTECT/THERMPROTECT%20report%201.htm)
Havenith G, Wang X, Richards M, Bröde P, Candas V, den Hartog E, Holmér I, Meinander H, Nocker W (2006) Evaporative cooling in protective clothing. In: European Society of Protective Clothing (ed) 3rd European conference on protective clothing. Central Institute for Labour Protection, National Research Institute, Warsaw, ISBN: 83-7373-097-4 (CD-ROM, 6 p)
Havenith G, Richards M, Wang X, Bröde P, Candas V, den Hartog EA, Holmér I, Kuklane K, Meinander H, Nocker W (2007a) Apparent latent heat of evaporation from clothing: attenuation and ‘heat pipe’ effects. J Appl Physiol (in press). doi:10.1152/japplphysiol.00612.2007
Havenith G, Wang X, Richards M, Candas V, Meinander H, Broede P, den Hartog EA, Holmér I, Nocker W (2007b) Apparent and real cooling efficiency of moisture evaporation from the skin while wearing protective clothing. J Physiol Anthropol 26:272–273
ISO 9886 (1992) Evaluation of thermal strain by physiological measurements. International Organisation for Standardisation, Geneva
ISO 10551 (1995) Ergonomics of the thermal environment—assessment of the influence of the thermal environment using subjective judgement scales. International Organisation for Standardisation, Geneva
ISO 15831 (2004) Clothing. Physiological effects. Measurement of thermal insulation by means of a thermal manikin. International Organisation for Standardisation, Geneva
ISO 8996 (2004) Ergonomics of the thermal environment—determination of metabolic rate. International Organisation for Standardisation, Geneva
ISO 9920 (2007) Ergonomics of the thermal environment—estimation of thermal insulation and water vapour resistance of a clothing ensemble. International Organisation for Standardisation, Geneva
Lotens WA, Havenith G (1995) Effects of moisture absorption in clothing on the human heat balance. Ergonomics 38:1092–1113
Lotens WA, van de Linde FJ, Havenith G (1995) Effects of condensation in clothing on heat transfer. Ergonomics 38:1114–1131
Malchaire J, Piette A, Kampmann B, Mehnert P, Gebhardt H, Havenith G, den Hartog EA, Holmér I, Parsons K, Alfano G, Griefahn B (2001) Development and validation of the predicted heat strain model. Ann Occup Hyg 45:123–135
McCullough EA, Huang J, Deaton S (2005) Methods for measuring the clothing area factor. In: Holmér I, Kuklane K, Gao C (eds) Environmental ergonomics XI. Lund University, Lund, pp 433–436
McLellan T, Pope J, Cain J, Cheung S (1996) Effects of metabolic rate and ambient vapour pressure on heat strain in protective clothing. Eur J Appl Physiol 74:518–527 doi:10.1007/BF02376767
Meinander H, Anttonen H, Bartels V, Holmér I, Reinertsen RE, Soltynski K, Varieras S (2004) Manikin measurements versus wear trials of cold protective clothing (subzero project). Eur J Appl Physiol 92:619–621
Nunneley SA (1989) Heat stress in protective clothing. Interactions among physical and physiological factors. Scand J Work Environ Health 15(Suppl 1):52–57
Acknowledgment
This work was funded by European Union GROWTH programme project “THERMPROTECT, Assessment of Thermal Properties of Protective Clothing and Their Use”, contract G6RD-CT-2002–00846.
Author information
Authors and Affiliations
Corresponding author
Additional information
The content of this manuscript was presented at the International Conference on Environmental Ergonomics 2007.
Electronic supplementary material
Below is the link to the electronic supplementary material.
421_2007_629_MOESM1_ESM.doc
Clothing layers worn by the manikin (a, photos by EMPA) and the subjects (b): 1) CO (a) and HHS underwear with humidity sensor at the chest (b), 2) Tyvek® (a) and Tychem® (b) coverall as separating layer, 3) CO mid layer and 4) PVC outer layer. (DOC 1,969 kb)
Rights and permissions
About this article
Cite this article
Bröde, P., Havenith, G., Wang, X. et al. Non-evaporative effects of a wet mid layer on heat transfer through protective clothing. Eur J Appl Physiol 104, 341–349 (2008). https://doi.org/10.1007/s00421-007-0629-y
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00421-007-0629-y