论文信息 - Using CFD Technology to Simulate a Model of Human Thermoregulation in the Stable Temperature Environment

Using CFD Technology to Simulate a Model of Human Thermoregulation in the Stable Temperature Environment

A coupling system was developed in the present study to simulate the heat transfer and physiological responses of the unclothed human body in hot and cold environments. This system included a computational thermal manikin controlled by a multi-node thermal model, which could dynamically respond to the environmental conditions. The computational thermal manikin was employed to determine the heat transfer between the human body and ambient environment as well as heat transfer coefficients at each body segment. The CFD simulation was then coupled with a multi-node thermal model to predict the heat transfer and human physiological responses in real time. The performance of coupling system was examined by comparing the simulated skin temperatures with the published measurements from human trials in hot and cold environments. The coupling system reasonably predicted the skin temperatures at local body segments with the maximum discrepancies between the observed values and simulated ones no more than 1.0 °C.

[1] Satoru Takada,et al. Thermal model of human body fitted with individual characteristics of body temperature regulation , 2009 .

[2] Wenguo Weng,et al. Experimental and numerical study of physiological responses in hot environments. , 2014, Journal of thermal biology.

[3] Kamel Ghali,et al. A multi-segmented human bioheat model for transient and asymmetric radiative environments , 2008 .

[4] S. Tanabe,et al. Evaluation of thermal comfort using combined multi-node thermoregulation (65MN) and radiation models and computational fluid dynamics (CFD) , 2002 .

[5] Chengwen Zhong,et al. Three-dimensional human thermoregulation model based on pulsatile blood flow and heating mechanism , 2018, Chinese Physics B.

[6] George Havenith,et al. Thermal Indices and Thermophysiological Modeling for Heat Stress. , 2015, Comprehensive Physiology.

[7] Satoru Takada,et al. Re-evaluation of Stolwijk's 25-node human thermal model under thermal-transient conditions: Prediction of skin temperature in low-activity conditions , 2009 .

[8] K. Lomas,et al. Computer prediction of human thermoregulatory and temperature responses to a wide range of environmental conditions , 2001, International journal of biometeorology.

[9] Tong Yang,et al. Simulation of human thermal responses in a confined space , 2008 .

[10] Nobuyuki Abe,et al. An integrated numerical simulator for thermal performance assessments of firefighters’ protective clothing , 2010 .