Thermal sensation and comfort in non-uniform thermal environment

被引:0
作者
Muro K. [1 ]
Saito H. [1 ]
机构
[1] Faculty of Engineering, Division of Architecture and Civil Engineering, Ashikaga Univ.
来源
AIJ Journal of Technology and Design | 2019年 / 25卷 / 61期
关键词
Effect of interaction; Floor temperature; Non-uniform thermal environment; Skin temperature; Thermal sensation; Vertical temperature difference;
D O I
10.3130/aijt.25.1179
中图分类号
TU [建筑科学];
学科分类号
0813 ;
摘要
We conducted subjective experiments of heating condition using the small room of which temperature of the upper and the lower part and the floor could be controlled separately. The results show: 1) the thermal sensation shifted to the warmer level when the temperatures of both the lower part and the floor were higher than the upper part temperature, and 2) it was modeled by Structural Equation Modeling that the lower body thermal sensation was influenced by the thermal sensations of the upper body and the bottom of the foot, as well as the temperatures of the lower and the floor. © 2019 Architectural Institute of Japan. All rights reserved.
引用
收藏
页码:1179 / 1184
页数:5
相关论文
共 50 条
  • [21] Thermal sensation and physiological responses in non-uniform bathing thermal environment: A comparative study on 25-, 52-, and 71-year-old participants
    Liu, Han
    Ogura, Daisuke
    Hokoi, Shuichi
    Iba, Chiemi
    BUILDING AND ENVIRONMENT, 2023, 246
  • [22] A new simplified model for evaluating non-uniform thermal sensation caused by wearing clothing
    Zolfaghari, Alireza
    Maerefat, Mehdi
    BUILDING AND ENVIRONMENT, 2010, 45 (03) : 776 - 783
  • [23] Assessment indices for uniform and non-uniform thermal environments
    Zhang Y.
    Sun S.
    Zhao R.
    Frontiers of Energy and Power Engineering in China, 2008, 2 (2): : 129 - 133
  • [24] Thermal comfort of Frail People under dynamic and non-uniform thermal environments using a thermal manikin with thermoregulatory control: An experimental study
    El akili Z.
    Bouzidi Y.
    Merabtine A.
    Polidori G.
    Kauffmann J.
    Energy and Built Environment, 2023, 4 (04): : 477 - 491
  • [25] A Physiological-Signal-Based Thermal Sensation Model for Indoor Environment Thermal Comfort Evaluation
    Pao, Shih-Lung
    Wu, Shin-Yu
    Liang, Jing-Min
    Huang, Ing-Jer
    Guo, Lan-Yuen
    Wu, Wen-Lan
    Liu, Yang-Guang
    Nian, Shy-Her
    INTERNATIONAL JOURNAL OF ENVIRONMENTAL RESEARCH AND PUBLIC HEALTH, 2022, 19 (12)
  • [26] Indoor thermal environment optimal control for thermal comfort and energy saving based on online monitoring of thermal sensation
    Li, Wei
    Zhang, Jili
    Zhao, Tianyi
    ENERGY AND BUILDINGS, 2019, 197 : 57 - 67
  • [27] Overall thermal sensation, acceptability and comfort
    Zhang, Yufeng
    Zhao, Rongyi
    BUILDING AND ENVIRONMENT, 2008, 43 (01) : 44 - 50
  • [28] Investigation into effect of non-uniform thermal environment on thermal sensation under stratum ventilation for heating by using interpolation-based multi-level fuzzy comprehensive evaluation
    Wan, Taocheng
    Cheng, Fanghui
    Cheng, Yong
    Liao, Chunhui
    Bai, Yan
    JOURNAL OF BUILDING ENGINEERING, 2023, 64
  • [29] Modeling non-uniform thermal environment of stratum ventilation with supply and exit air conditions
    Zhang, Sheng
    Cheng, Yong
    Huan, Chao
    Lin, Zhang
    BUILDING AND ENVIRONMENT, 2018, 144 : 542 - 554
  • [30] Dynamic thermal environment and thermal comfort
    Zhu, Y.
    Ouyang, Q.
    Cao, B.
    Zhou, X.
    Yu, J.
    INDOOR AIR, 2016, 26 (01) : 125 - 137
12345