Abstract
Wet bulb globe temperature (WBGT) index is used by many professionals in combination with metabolic rate and clothing adjustments to assess whether a heat stress exposure is sustainable. The progressive heat stress protocol is a systematic method to prescribe a clothing adjustment value (CAV) from human wear trials, and it also provides an estimate of apparent total evaporative resistance (R(e,T,a)). It is clear that there is a direct relationship between the two descriptors of clothing thermal effects with diminishing increases in CAV at high R(e,T,a). There were data to suggest an interaction of CAV and R(e,T,a) with relative humidity at high evaporative resistance. Because human trials are expensive, manikin data can reduce the cost by considering the static total evaporative resistance (R(e,T,s)). In fact, as the static evaporative resistance increases, the CAV increases in a similar fashion as R(e,T,a). While the results look promising that R(e,T,s) can predict CAV, some validation remains, especially for high evaporative resistance. The data only supports air velocities near 0.5 m/s.