Investigation of indoor thermal comfort in warm-humid conditions at a German climate test facility

• Published in: Building and environment Vol. 128; pp. 216 - 224
• Main Authors: Kleber, Michael, Wagner, Andreas
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 15.01.2018; Elsevier BV
• Subjects: Climate; Climate change; Human behavior; Humid climates; Humidity; Humidity sensation; Indoor air quality; Labor study; Perceived air quality; Regression models; Relative humidity; Summer; Temperature effects; Thermal acceptability; Thermal comfort; Warm-humid environment; Warm-humid environment; Thermal comfort; Perceived air quality; Labor study; Thermal acceptability; Humidity sensation
• ISSN: 0360-1323; 1873-684X
• DOI: 10.1016/j.buildenv.2017.11.018

As a result of climate change outdoor temperature and humidity are predicted to increase within the next decades in Germany, especially in the Upper Rhine area. As indoor summer conditions will be affected by this change, responses of 136 subjects to warm-humid conditions have been investigated in a test-facility at the Karlsruhe Institute of Technology (KIT). Nine experimental conditions with high operative temperature (to) and different relative humidity (RH) levels (26 °C, 28 °C or 30 °C combined with 50%, 65% or 80%) were scheduled, with each participant experiencing two of the possible combinations. In contradiction to the German addendum of the European standard EN 15251, where a single upper limit for humidity ratio (HR) of 11.5 g/kg is recommended in summer, results indicate that human responses are additionally dependent on current temperature and other factors like thermal history. A linear regression model using operative temperature and humidity ratio is shown to describe the percentage of acceptability and is used to derive an extended comfort zone for seated activity in summer conditions (met = 1.1 and clo = 0.5). Thermal acceptance is compared to other studies (using effective temperature) and proves to be significantly lower with the German subjects than with participants who are adapted to a hot-humid climate. PMV shows underestimation of thermal sensation at elevated air humidity, up to 0.5 scale points under certain conditions. •First known laboratory study with German subjects at warm and humid conditions.•Large sample size with 136 subjects so far.•A simple model for thermal acceptability at warm and humid conditions is presented.•Extended comfort criteria in comparison to the German standards (National Annex to EN 15251) are suggested.