纺织学报 ›› 2024, Vol. 45 ›› Issue (09): 175-182.doi: 10.13475/j.fzxb.20231006901

• 服装工程 • 上一篇    下一篇

面向老年人局部差异热需求的加热被褥设计

顾舒婷, 陈晨依, 许静娴()   

  1. 苏州大学 纺织与服装工程学院, 江苏 苏州 215006
  • 收稿日期:2023-10-20 修回日期:2024-05-14 出版日期:2024-09-15 发布日期:2024-09-15
  • 通讯作者: 许静娴(1992—),女,讲师,博士。主要研究方向为服装舒适性与热管理。E-mail: xujingxian1992@hotmail.com
  • 作者简介:顾舒婷(1999—),女,硕士生。主要研究方向为服装舒适性。
  • 基金资助:
    江苏省高等学校自然科学研究面上项目(23KJD540002)

Design of heated bedding for localized differential thermal needs of the elderly

GU Shuting, CHEN Chenyi, XU Jingxian()   

  1. College of Textile and Clothing Engineering, Soochow University, Suzhou, Jiangsu 215006, China
  • Received:2023-10-20 Revised:2024-05-14 Published:2024-09-15 Online:2024-09-15

摘要:

为改善老年人冬季睡眠热舒适性,提高睡眠质量,基于老年人睡眠局部差异热需求研究了分区加热被褥。使用暖体假人及人工气候舱模拟老年人冬季睡眠场景,进行睡眠实验,探究老年人冬季睡眠的加热需求,并比较电加热和热水袋2种加热方式的作用机制,以此为依据提出分区加热被褥设计方案。结果表明:当被褥无加热时,老年人胸部、背部、手部和脚部皮肤温度低于热舒适温度0.5~2.6 ℃,而背部和脚部更适宜进行局部加热;热水袋加热方式因升温速率高且水温下降后给人体带来接触冷感,而电加热方式升温速率平缓且能维持皮肤温度在34.5~35 ℃的舒适范围;在背部和脚部组合电加热作用下,被下微环境整体温度得以提升,胸部和手部皮肤温度也升高至热舒适温度范围,即分区电加热方案可有效改善老年人整体及局部睡眠热舒适性。本文研究结果可为开发高性能分区加热被褥提供理论参考及数据支撑。

关键词: 老年人, 睡眠热舒适, 局部热需求, 加热被褥, 差异热需求, 被服系统

Abstract:

Objective Studies on winter bedding systems have been carried out to improve the thermal comfort and sleep quality of the elderly. Previous studies mainly focused on the overall thermal needs of the human body during sleep, such as temperature-control mattresses and electric blankets, while ignoring the specificity of the thermo-physiology in the elderly and the variability of localized thermal needs of the body. In order to make the temperature control more targeted, localized heating was proposed instead of whole-body heating to meet the local thermal needs of the human body, which would help save energy at the same time.

Method An artificial climate chamber, along with a lying thermal manikin, was adopted to simulate the real sleep scene of the elderly in winter. Three groups of sleeping tests were conducted. The first scenario involved no heating elements in the bedding system, and the body parts which need additional heating were figured out by comparing the measured skin temperatures with neutral skin temperatures. In the other two groups of tests, electrical heating pads and hot water bags were attached to the quilt and mattress separately to heat the body parts which need heating. By comparing the skin temperatures under the two heating methods, the design of a localized heating bedding system was proposed.

Results It was found that the skin temperature at chest, back, hands and feet were significantly (p<0.05) lower than the corresponding neutral skin temperature. This indicates that these four body parts would need additional heating to satisfy the thermal comfort needs of the elderly. After applying the electric heating pads, the skin temperature of back increased rapidly at a rate of 0.224 ℃/min. The lowest and highest comfortable skin temperature of 32.8 ℃ and 35 ℃ were reached in 10 min and 22 min, respectively. The skin temperature of the back continued rising for another 2 min before starting to decrease after turning off the heater, and after 20 min it stays within the comfortable temperature range of around 33.7 ℃ for sleeping. After applying the heating pad for 15min, the skin temperature of the foot reached the lowest comfortable temperature of 32.2 ℃, and the maximum comfortable temperature of 35.8 ℃ was reached after 43 min. The skin temperature of the feet continued rising for another 2 min before it started to decrease after turning off the heater, and after 16 min it stably stayed within the comfortable temperature range of around 35.3 ℃ for sleeping. The data suggests that electrical heating of the chest and hands improves their localized thermal comfort. However, considering the really sleep scenario, heating at chest is somewhat unsafe due to its proximity to the heart. The human hand moves a lot during sleep and is difficult to be fixed. The lowest (32.8 ℃) and highest (35 ℃) comfortable skin temperature of the feet were reached in 10 min and 22 min, respectively under the hot water bag heating. After 10 min, the temperature of the foot rose to 38.02 ℃ and then began to gradually decrease to a cooler temperature. In the heated futon design scheme, when the back and feet were heated with electric heating pads, there was no significant difference between the human local skin temperature and the comfortable skin temperature range (P>0.05).

Conclusion Local body parts of chest, back, hands and feet of the elderly need additional heating during sleep in winter. Taking both the safety and practicality into consideration, auxiliary heating system is suggested to be applied to back and feet. The heating method of hot water bag leads to a fast increase of skin temperature, while the water temperature would drop and cause cold contract feeling for the elderly. Thus, the heating method of electric heating pad, which brings a slow increase of skin temperature but can maintain the skin temperature in the comfortable rang of 34.5-35 ℃, overwhelms the heating method of hot water bag. Bedding system with localized electric heating pads are proposed and verified to effectively improve overall and local sleep thermal comfort for the elderly. These research findings can provide evidence for the design of high-performance localized heated futons to achieve thermal comfort during sleeping.

Key words: the elderly, sleep thermal comfort, local thermal need, heated bedding, differential thermal demand, bedding system

中图分类号: 

  • TS941.75

图1

电加热片"

图2

实验设备"

图3

各局部加热位置图"

表1

热中性环境中老年人平均皮肤温度和局部皮肤温度"

部位 平均值 标准偏差 最高温度 最低温度
头部 33.9 0.5 34.9 32.8
胸部 34.0 0.6 35.0 32.8
前臂 32.8 0.8 34.0 30.8
手部 33.4 1.0 35.5 30.7
大腿 33.6 0.7 35.5 31.7
小腿 33.5 0.6 34.3 31.6
脚部 33.8 0.8 35.8 32.2
平均皮肤温度 33.6 0.5 34.6 32.3

表2

老年人各局部皮肤温度方差齐性检验"

部位 莱文统计 自由度1 自由度2 显著性P
胸部 20.147 1 218 <0.001
背部 9.116 1 218 0.003
前臂 1.911 1 160 0.169
手部 39.154 1 192 <0.001
大腿 0.071 1 190 0.790
小腿 0.321 1 136 0.572
脚部 14.855 1 180 <0.001

图4

加热部位图"

图5

各局部电加热皮肤温度"

表3

人体局部电加热前后皮肤温度方差齐性检验"

部位 莱文统计 自由度1 自由度2 显著性P
胸部 103.118 1 158 <0.001
背部 26.381 1 166 <0.001
手部 57.681 1 166 <0.001
脚部 61.299 1 234 <0.001

图6

脚部2种加热方式对照"

表4

热水袋加热脚部温度与电加热脚部温度的方差齐性分析"

数值类型 莱文统计 自由度1 自由度2 显著性P
基于平均数 17.982 1 142 <0.001
基于中位数 7.135 1 142 0.008
基于中位数并具有调整后自由度 7.135 1 92.559 0.009
基于剪除后平均值 15.013 1 142 <0.001

图7

被褥系统结构图"

表5

背部和脚部电加热作用下局部皮肤温度与舒适皮肤温度方差齐性检验"

部位 莱文统计 自由度1 自由度2 显著性P
胸部 0.367 1 146 0.546
背部 1.378 1 88 0.244
手部 0.337 1 320 0.562
脚部 0.220 1 120 0.640
[1] 邬林果, 武荣伟, 杨德刚. 2000—2020年中国人口老龄化时空演变及影响因素研究[J]. 世界地理研究, 2023, 32: 1-16.
WU Linguo, WU Rongwei, YANG Degang. Spatial temporal patterns and influencing factors of populationaging in China from 2000 to 2020[J]. World Geographical Studies, 2023, 32:1-16.
[2] 张芮仙, 张善东, 齐涵, 等. 老年人睡眠障碍的影响因素及对机体免疫状态、认知功能和生活质量的影响[J]. 现代生物医学展, 2022, 22(21): 4071-4075.
ZHANG Ruixian, ZHANG Shandong, QI Han, et al. Influencing factors of sleep disorders in the elderly and their effects on immune status, cognitive function and quality of life[J]. Advances in Modern Biomedicine, 2022, 22(21): 4071-4075.
[3] 袁源. 社区中老年人睡眠质量及相关因素、证候分布调查研究[D]. 北京: 北京中医药大学, 2021: 7-8.
YUAN Yuan. A survey study on sleep quality, related factors and evidence distribution of the elderly in the community[D]. Beijing: Beijing University of Chinese Medicine, 2021: 7-8.
[4] 刘海娟, 陈长香, 郝习君. 老年人睡眠障碍及其影响因素[J]. 中国老年学杂志, 2010, 30(15): 2198-2200.
LIU Haijuan, CHEN Changxiang, HAO Xijun. Sleep disorders in the elderly and their influencing factors[J]. Chinese Journal of Gerontology, 2010, 30(15): 2198-2200.
[5] KIM M, UM Y H, KIM T W, et al. Association between age and sleep quality: findings from a community health survey[J]. Sleep Medicine Research, 2021, 12(2): 155-160.
[6] NGUYEN V, ZAINAL N, NEWMAN M. Why sleep is key: poor sleep quality is a mechanism for the bidirectional relationship between major depressive disorder and generalized anxiety disorder across 18 years[J]. Journal of Anxiety Disorders, 2022, 90: 1-7.
[7] LAN L, PAN L, LIAN Z, et al. Experimental study on thermal comfort of sleeping people at different air temperatures[J]. Building and Environment, 2014, 73: 24-31.
[8] 李霞霞, 申黎明, 高婧淑. 冬季温控床垫对人体热舒适的影响机理[J]. 林业工程学报, 2020, 5(3): 175-182.
LI Xiaxia, SHEN Liming, GAO Jingshu. Investigation of influence mechanism of temperature-controlled mattress on human thermal comfort in winter[J]. Journal of Forestry Engineering, 2020, 5(3): 175-182.
[9] XIA L, LAN L, TANG J, et al. Bed heating improves the sleep quality and health of the elderly who adapted to no heating in a cold environment[J]. Energy & Buildings, 2020, 210: 2-6.
[10] XIA L, LAN L, TANG J, et al. Using footwarmers in offices for thermal comfort and energy savings[J]. Energy and Buildings, 2015, 104: 233-243.
[11] 姚彬. 浅析冬季取暖方式的选择[J]. 门窗, 2018, 12(2): 52-53.
YAO Bin. Analyzing the choice of heating methods in winter[J]. Doors & Windows, 2018, 12(2): 52-53.
[12] 王兴卫, 刘艳峰, 宋聪, 等. 冬季室内热环境与被褥微气候的匹配[J]. 土木建筑与环境工程, 2016, 38(2): 91-96.
WANG Xingwei, LIU Yanfeng, SONG Cong, et al. Matching the indoor thermal environment to the bedding microclimate in winter[J]. Journal of Civil Architechural Environmental Engineering, 2016, 38(2): 91-96.
[13] QUESADA J, CALVO M, CUEVAS A, et al. Assessment of a mattress with phase change materials using a thermal and perception test[J]. Experimental Thermal and Fluid Science, 2017, 81: 358-363.
[14] SONG C, LIU Y, LIU J. The sleeping thermal comfort model based on local thermal requirements in winter[J]. Energy & Buildings, 2018, 173: 163-175.
[15] LIU C, TANG Y, SUN L, et al. Effects of local heating of body on human thermal sensation and thermal comfort[J]. Journal of Building Engineering, 2022, 53, 2-9.
[16] 刘玉萍, 卢业虎, 王来力. 被服系统热舒适性研究进展[J]. 纺织学报, 2020, 41(1): 190-196.
LIU Yuping, LU Yehu, WANG Laili. Research progress on thermal comfort of bedding system[J]. Journal of Textile Research, 2020, 41(1): 190-196.
[17] 杨在春, 李庆棣. 新编临床医学数据手册[M]. 北京: 金盾出版社, 1992,282-283.
YANG Zaichun, LI Qingdi. New clinical medicine date book[M]. Beijing: Jindun Publishing House, 1992:282-283.
[18] CHEN Y, ZHANG H, YOSHINO H, et al. Winter indoor environment of elderly households: a case of rural regions in northeast and southeast China[J]. Building and Environment, 2019, 165: 8-9.
[19] TANG Y, YU H, WANG Z, et al. Validation of the stolwijk and tanabe human thermoregulation models for predicting local skin temperatures of older people under thermal transient conditions[J]. Energies, 2020, 13(24): 7-14.
[20] 戴金辉. 单因素方差分析中异方差的检验与修正[J]. 统计与决策, 2017, 33(8): 23-26.
DAI Jinhui. Test and correction of heteroscedasticity in the single-factor variance analysis[J]. Statistics & Decision, 2017, 33(8): 23-26.
[21] 周浩. 人体皮肤温度影响因素实验研究[D]. 西安: 西安建筑科技大学, 2014: 11-12.
ZHOU Hao. Experimental study on the influence factors of human skin temperature[D]. Xi'an: Xi'an University of Architecture and Technology, 2014: 11-12.
[1] 郑晴, 严芳英, 柯莹, 王鸿博. 基于睡袋温标模型的被子舒适温度测定与可行性验证[J]. 纺织学报, 2023, 44(02): 151-158.
[2] 田苗, 雷烨, 王云仪, 李俊, 张向辉. 老年行动模拟服在步态稳定性研究中的应用[J]. 纺织学报, 2021, 42(08): 144-148.
[3] 刘玉萍, 卢业虎, 王来力. 被服系统热舒适性研究进展[J]. 纺织学报, 2020, 41(01): 190-196.
[4] 王慧娟;王宏付. 陕北地区老年人服装号型的细分[J]. 纺织学报, 2009, 30(12): 108-112.
[5] 刘国联;张莉. 东北地区老年人服装态度研究[J]. 纺织学报, 2003, 24(02): 175-177.
Viewed
Full text


Abstract

Cited

  Shared   
  Discussed   
No Suggested Reading articles found!