Analyze the physical interaction between the user and the furniture design to optimize comfort and functionality

  • Mingxing Gao College of Arts, Gansu University of Political Science and Law, Lanzhou 730070, China
DOI: https://doi.org/10.62617/mcb457
Keywords: furniture designs; muscle fatigue; dynamic movements; biomechanical sensors; motion tracking
Ariticle ID: 457

Abstract

The physical interaction between users and furniture is pivotal in determining comfort and functionality, particularly in environments where individuals spend extended periods, such as offices, homes, and public spaces. This study aims to analyze how different furniture designs impact user comfort, postural stability, and long-term usability. By employing a hybrid research framework combining observational studies, simulations, and advanced technological tools such as motion tracking, pressure mapping, and biomechanical sensors, the research provides a comprehensive evaluation of user-furniture interaction. The study involved 178 participants with diverse demographic backgrounds, allowing for a broad range of body types, ages, and activity levels to be examined. Key findings indicate that ergonomic features such as adjustable seat height, lumbar support, and reclining mechanisms significantly enhance comfort, particularly when customized to the user’s anthropometric profile. For example, adjustable seat height reduced pressure on the thighs, improving comfort by 8.5% over prolonged periods. Additionally, lumbar support was the most compelling feature in alleviating muscle strain, improving overall comfort by 9.0%. The analysis of long-term comfort revealed that postures supporting dynamic movements, such as using a standing desk, maintained higher comfort levels over time compared to static postures like leaning forward, which showed a marked increase in muscle fatigue. Postural stability analysis showed that sitting at a 90° angle provided the best balance of stability and long-term comfort, with a usability rating 8.4. In contrast, leaning forward exhibited the lowest postural stability and the highest discomfort, making it unsuitable for prolonged tasks.

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Published
2024-11-07
How to Cite
Gao, M. (2024). Analyze the physical interaction between the user and the furniture design to optimize comfort and functionality. Molecular & Cellular Biomechanics, 21(2), 457. https://doi.org/10.62617/mcb457
Issue
Vol. 21 No. 2 (2024)
Section
Article

Copyright (c) 2024 Mingxing Gao

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