Predicting the Risk of Freezing the Skin

It is well known that wind increases the risk of frostbite during exposure in a cold climate. The explanation is that increased airspeeds enhance heat transfer from the body. This effect was quantified by Siple and Passel in the 1940's. They measured the time needed for water, inside a cylinder...

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Bibliographic Details
Main Author: Danielsson, Ulf
Other Authors: SWEDISH DEFENCE RESEARCH AGENCY STOCKHOLM DEPT OF DEFENSE MEDICINE
Format: Text
Language:English
Published: 2002
Subjects:
Biology
Stress Physiology
*HEAT TRANSFER
*FREEZING
*EXPOSURE(PHYSIOLOGY)
*SKIN(ANATOMY)
*FROSTBITE
SIMULATION
RISK
WATER
CLIMATE
AIRSPEED
SOLAR RADIATION
COLD WEATHER
PUBLIC OPINION
ANTARCTIC REGIONS
FINGERS
COMPONENT REPORTS
FOREIGN REPORTS
NATO FURNISHED
Antarctic
Passel
Siple
The Antarctic
Antarc*
Online Access:http://www.dtic.mil/docs/citations/ADP012437
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADP012437
Description
Summary:It is well known that wind increases the risk of frostbite during exposure in a cold climate. The explanation is that increased airspeeds enhance heat transfer from the body. This effect was quantified by Siple and Passel in the 1940's. They measured the time needed for water, inside a cylinder, to freeze during exposure to various combinations of air speed and temperature. From these data, they developed the so-called windchill index (WCI) for predicting the heat transfer from nude body parts. Later WCI was also expressed as 'equivalent temperature (T(sub c)) However, a reexamination of the Siple and Passel data has shown that WCI (and T(sub c)) does not correctly describe the wind induced heat transfer. As charts based on WCI and T(sub c) are frequently used to express cold weather severity these indices should be corrected. Another shortage is that important parameters for predicting windchill are limited to air speed and temperature. A previously presented skin-frostbite risk model has been developed further, now also allowing simulation of wet skin and solar radiation. The model suggests that the risk for finger frostbite increases from 30 to 70% after wetting the skin when the air speed and temperature is 6, 8 m/s and - 15 deg C, respectively. This prediction is similar to experimental results found in the literature. There is a common opinion that windchill skin injuries are rare in the Antarctic during the summer. It is estimated that solar radiation corresponds to 5 to 10 deg C higher air temperature. These values are much the same as those suggested by the model at solar intensities common during the Antarctic summer. Another opinion is that time spent in cold weather regions reduces the risk of skin frostbite considerably. This adaptation has been found to reduce the risk of finger frostbite from 74% (1st year men) to 29% (2nd year men). 8 Oct 2001 to 10 Oct 2001, "The original document contains color images" Papers presented at the RTO Human Factors and Medicine Panel (HFM) Symposium held in Dresden, Germany, 8-10 Oct 2001, p28-1/28-12. This article is from ADA403853 Blowing Hot and Cold: Protecting Against Climatic Extremes (Souffler le chaud et le froid: comment se proteger contre les conditions climstiques extremes)

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