Impact of Changing Inlet Modes in Ski Face Masks on Adolescent Skiing: A Finite Element Analysis Based on Head Models

Due to the material properties of current ski face masks for adolescents, moisture in exhaled air can become trapped within the material fibers and freeze, leading to potential issues such as breathing difficulties and increased risk of facial frostbite after prolonged skiing. This paper proposes a...

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Bibliographic Details
Published inModelling Vol. 5; no. 3; pp. 936 - 950
Main Authors Huang, Minxin, Zhang, Ruiqiu, Zhang, Xiaocheng
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2024
Subjects
adolescents
Air flow
Air intakes
Carbon dioxide
Carbon dioxide concentration
Computational fluid dynamics
Configuration management
Ergonomics
Expulsion
Finite element method
Frostbite
Head
Holes
Impact analysis
Masks
Material properties
Mathematical models
Olympic games
parametric simulation
Respiration
Side inlets
ski face protection
Skiing
Teenagers
Thermal insulation
ventilation study
Beijing China
Asia-Pacific region
China
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Summary:Due to the material properties of current ski face masks for adolescents, moisture in exhaled air can become trapped within the material fibers and freeze, leading to potential issues such as breathing difficulties and increased risk of facial frostbite after prolonged skiing. This paper proposes a research approach combining computational fluid dynamics (CFD) and ergonomics to address these issues and enhance the comfort of adolescent skiers. We developed head and face mask models based on the head dimensions of 15–17-year-old males. For enclosed cavities, ensuring the smooth expulsion of exhaled air to prevent re-inhalation is the primary challenge. Through fluid simulation of airflow characteristics within the cavity, we evaluated three different inlet configurations. The results indicate that the location of the air inlets significantly affects the airflow characteristics within the cavity. The side inlet design (type II) showed an average face temperature of 35.35 °C, a 38.5% reduction in average CO2 concentration within the cavity, and a smaller vortex area compared to the other two inlet configurations. Although the difference in airflow velocity within the cavity among the three configurations was minimal, the average exit velocity differed by up to 0.11 m/s. Thus, we conclude that the side inlet configuration offers minimal obstruction to airflow circulation and better thermal insulation when used in the design of fully enclosed helmets. This enhances the safety and comfort of adolescent wearers during physical activities in cold environments. Through this study, we aim to further promote the development of skiing education, enhance the overall quality of adolescents’ skiing, and thus provide them with more opportunities for the future.
ISSN:2673-3951
DOI:10.3390/modelling5030049