Maximum vehicle cabin temperatures under different meteorological conditions

A variety of studies have documented the dangerously high temperatures that may occur within the passenger compartment (cabin) of cars under clear sky conditions, even at relatively low ambient air temperatures. Our study, however, is the first to examine cabin temperatures under variable weather conditions. It uses a unique maximum vehicle cabin temperature dataset in conjunction with directly comparable ambient air temperature, solar radiation, and cloud cover data collected from April through August 2007 in Athens, GA. Maximum cabin temperatures, ranging from 41–76°C, varied considerably depending on the weather conditions and the time of year. Clear days had the highest cabin temperatures, with average values of 68°C in the summer and 61°C in the spring. Cloudy days in both the spring and summer were on average approximately 10°C cooler. Our findings indicate that even on cloudy days with lower ambient air temperatures, vehicle cabin temperatures may reach deadly levels. Additionally, two predictive models of maximum daily vehicle cabin temperatures were developed using commonly available meteorological data. One model uses maximum ambient air temperature and average daily solar radiation while the other uses cloud cover percentage as a surrogate for solar radiation. From these models, two maximum vehicle cabin temperature indices were developed to assess the level of danger. The models and indices may be useful for forecasting hazardous conditions, promoting public awareness, and to estimate past cabin temperatures for use in forensic analyses.

[1]  Lynn I. Gibbs,et al.  Heat exposure in an enclosed automobile. , 1995, The Journal of the Louisiana State Medical Society : official organ of the Louisiana State Medical Society.

[2]  K. King,et al.  Heat stress in motor vehicles: a problem in infancy. , 1981, Pediatrics.

[3]  Scott C Sheridan,et al.  A survey of public perception and response to heat warnings across four North American cities: an evaluation of municipal effectiveness , 2007, International journal of biometeorology.

[4]  R. Steadman The Assessment of Sultriness. Part I: A Temperature-Humidity Index Based on Human Physiology and Clothing Science , 1979 .

[5]  J S Surpure,et al.  Heat-related illness and the automobile. , 1982, Annals of emergency medicine.

[6]  Yutaka Tochihara,et al.  Thermoregulation during heat exposure of young children compared to their mothers , 2004, European Journal of Applied Physiology and Occupational Physiology.

[7]  T Sigrist,et al.  Temperature Variations in Automobiles in Various Weather Conditions: An Experimental Contribution to the Determination of Time of Death , 2001, The American journal of forensic medicine and pathology.

[8]  C. McLaren,et al.  Significant Temperature Rise in Enclosed Vehicles Heat Stress From Enclosed Vehicles: Moderate Ambient Temperatures Cause , 2005 .

[9]  K B Roberts,et al.  The automobile and heat stress. , 1976, Pediatrics.

[10]  Stanley A. Changnon Midwestern Cloud, Sunshine and Temperature Trends since 1901: Possible Evidence of Jet Contrail Effects , 1981 .

[11]  C. McGraw,et al.  Heat related deaths to young children in parked cars: an analysis of 171 fatalities in the United States, 1995-2002 , 2006 .

[12]  Jan Null,et al.  Heat Stress From Enclosed Vehicles: Moderate Ambient Temperatures Cause Significant Temperature Rise in Enclosed Vehicles , 2005, Pediatrics.