Concept of the equivalent wet bulb globe temperature index for indicating safe thermal occupational environments

We propose the concept of the equivalent wet bulb globe temperature (eWBGT) index, which requires no adjustment procedures to indicate the upper limit of safe thermal occupational environments in various conditions. We clarify that the original wet bulb globe temperature (WBGT) is an index that expresses the heat storage rate of the human body (S) in its standard condition for acclimatized workers, and demonstrate the relationship between S and WBGT in the standard condition. Based on these findings, we introduce the concept of the eWBGT, which enables conversion of the heat risk in a given condition into the WBGT heat risk scale in the standard condition. The eWBGT estimates heat strain of S under a given condition by using the heat balance equation for the human body. S was converted into the corresponding WBGT heat stress risk scale by referring to the relation between the WBGT and S in the standard condition. The eWBGT changes with the heat and vapor transfer properties of clothing, even when the air temperature, thermal radiation, water vapor pressure, and air velocity are constant. The eWBGT increases as the thermal insulation of clothing increases, and the influence of environmental water vapor pressure on the eWBGT decreases with decreasing vapor permeability index for the clothing layer. The eWBGT has the potential to provide a more accurate evaluation of the effects of heat and vapor transfer properties of clothing on occupational heat risk than the original WBGT.

[1]  T. Bernard,et al.  WBGT Clothing Adjustments for Four Clothing Ensembles Under Three Relative Humidity Levels , 2005, Journal of occupational and environmental hygiene.

[2]  G Havenith,et al.  Development and validation of the predicted heat strain model. , 2001, The Annals of occupational hygiene.

[3]  Tomonori Sakoi,et al.  Differential Coefficient of Equal Warm Sensation Line , 1999 .

[4]  T E Bernard,et al.  Physiological evaluation of liquid-barrier, vapor-permeable protective clothing ensembles for work in hot environments. , 1993, American Industrial Hygiene Association journal.

[5]  T. Y. Bong,et al.  Modeling of thermal environment and human response in a crowded space for tropical climate , 2001 .

[6]  T. Ohnaka,et al.  Physiological responses of men and women during exercise in hot environments with equivalent WBGT. , 1996, Applied human science : journal of physiological anthropology.

[7]  A. Pharo Gagge,et al.  Heat Exchange Between Human Skin Surface and Thermal Environment , 2011 .

[8]  Shilei Lu,et al.  A new environmental heat stress index for indoor hot and humid environments based on Cox regression , 2011 .

[9]  D. Quintela,et al.  Physical modelling of globe and natural wet bulb temperatures to predict WBGT heat stress index in outdoor environments , 2009, International journal of biometeorology.

[10]  G. M. Budd,et al.  Wet-bulb globe temperature (WBGT)--its history and its limitations. , 2008, Journal of science and medicine in sport.

[11]  D E Hyde,et al.  Psychrometric limits to prolonged work in protective clothing ensembles. , 1988, American Industrial Hygiene Association journal.

[12]  K. Nagano,et al.  Characteristics and Consideration of Required Sweat Rate Standard of the Previous ISO 7933 , 2006 .

[13]  Dusan Fiala,et al.  Physiological responses to temperature and humidity compared to the assessment by UTCI, WGBT and PHS , 2012, International Journal of Biometeorology.

[14]  G Havenith,et al.  Criteria for estimating acceptable exposure times in hot working environments: a review , 2000, International archives of occupational and environmental health.

[15]  Thomas E. Bernard,et al.  Heat strain at the critical WBGT and the effects of gender, clothing and metabolic rate , 2008 .

[16]  C. P. Yaglou,et al.  Control of heat casualties at military training centers. , 1957, A.M.A. archives of industrial health.

[17]  Ryozo Ooka,et al.  Improvement of sweating model in 2-Node Model and its application to thermal safety for hot environments , 2010 .

[18]  J D Ramsey Abbreviated guidelines for heat stress exposure. , 1978, American Industrial Hygiene Association journal.

[19]  Guozhong Zheng,et al.  Experimental study on physiological and psychological effects of heat acclimatization in extreme hot , 2011 .

[20]  J. Sánchez-Hermosilla,et al.  Approach to the evaluation of the thermal work environment in the greenhouse-construction industry o , 2011 .

[21]  Ingvar Holmér,et al.  Can the PHS model (ISO7933) predict reasonable thermophysiological responses while wearing protective clothing in hot environments? , 2011, Physiological measurement.

[22]  Shilei Lu,et al.  Productivity model in hot and humid environment based on heat tolerance time analysis , 2009 .

[23]  G. Havenith,et al.  Correction of clothing insulation for movement and wind effects, a meta-analysis , 2004, European Journal of Applied Physiology.

[24]  E. Arens,et al.  Convective and radiative heat transfer coefficients for individual human body segments , 1997, International journal of biometeorology.

[25]  Wen Yi,et al.  Determining an optimal recovery time for construction rebar workers after working to exhaustion in a hot and humid environment , 2012 .

[26]  P. O. Fanger,et al.  Thermal comfort: analysis and applications in environmental engineering, , 1972 .

[27]  Ken Parsons,et al.  Heat stress standard ISO 7243 and its global application. , 2006, Industrial health.

[28]  Jose´ Jabaloyes,et al.  Experimental investigation on the thermal comfort in the city: relationship with the green areas, interaction with the urban microclimate , 2004 .