Effectiveness of ventilated helmets in providing thermal comfort to a motorcycle rider is studied. Computational fluid dynamics (CFD) simulations of human thermoregulation system and the air flow in the air gap of a full-face motorcycle helmet are carried out. The thermal comfort of a rider is predicted using apparent temperature (AT) and wet-bulb global temperature (WBGT) heat indices. The effect of an increase in ambient temperature and relative humidity (RH) of air on the air flow and temperature in the region above the head is studied to predict the thermal comfort of the rider wearing full-face helmets. The effect of increasing the air gap between the head and the helmet is also studied. The results are then compared with the conditions when the rider is not wearing helmet. It is observed that the ventilated helmet is effective in providing thermal comfort to the rider only if the ambient air temperature is less than normal body temperature. For air temperature higher than the body temperature, vents do not provide any cooling to the head and the nonventilated helmet is more comfortable. Furthermore, CFD simulations are performed to investigate the effect of increase in RH in the ambient air on the thermal comfort of the rider. The increase in RH of air from 50% to 90% at a fixed ambient air temperature leads to an increase in AT and WBGT, indicating reduced thermal comfort of the rider.
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June 2017
Research-Article
Numerical Investigation of Ventilation and Human Thermoregulation for Predicting Thermal Comfort of a Rider Wearing Ventilated Helmet
Bhagwat Singh Shishodia,
Bhagwat Singh Shishodia
Applied Mechanics Department,
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: bhagwat.shishodia@gmail.com
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: bhagwat.shishodia@gmail.com
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Sanjeev Sanghi,
Sanjeev Sanghi
Applied Mechanics Department,
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: sanghi@am.iitd.ac.in
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: sanghi@am.iitd.ac.in
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Puneet Mahajan
Puneet Mahajan
Applied Mechanics Department,
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: mahajan@am.iitd.ac.in
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: mahajan@am.iitd.ac.in
Search for other works by this author on:
Bhagwat Singh Shishodia
Applied Mechanics Department,
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: bhagwat.shishodia@gmail.com
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: bhagwat.shishodia@gmail.com
Sanjeev Sanghi
Applied Mechanics Department,
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: sanghi@am.iitd.ac.in
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: sanghi@am.iitd.ac.in
Puneet Mahajan
Applied Mechanics Department,
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: mahajan@am.iitd.ac.in
Indian Institute of Technology Delhi,
New Delhi 110016, India
e-mail: mahajan@am.iitd.ac.in
1Corresponding author.
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received May 16, 2016; final manuscript received January 28, 2017; published online April 6, 2017. Assoc. Editor: Elias Balaras.
J. Fluids Eng. Jun 2017, 139(6): 061103 (13 pages)
Published Online: April 6, 2017
Article history
Received:
May 16, 2016
Revised:
January 28, 2017
Citation
Shishodia, B. S., Sanghi, S., and Mahajan, P. (April 6, 2017). "Numerical Investigation of Ventilation and Human Thermoregulation for Predicting Thermal Comfort of a Rider Wearing Ventilated Helmet." ASME. J. Fluids Eng. June 2017; 139(6): 061103. https://doi.org/10.1115/1.4036084
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