@article{35063, author = {Yucan Peng and Wei Li and Bofei Liu and Weiliang Jin and Joseph Schaadt and Jing Tang and Guangmin Zhou and Guanyang Wang and Jiawei Zhou and Chi Zhang and Yangying Zhu and Wenxiao Huang and Tong Wu and Kenneth E Goodson and Chris Dames and Ravi S Prasher and Shanhui Fan and Yi Cui}, title = {Integrated cooling (i-Cool) textile of heat conduction and sweat transportation for personal perspiration managementAbstract}, abstract = {
Perspiration evaporation plays an indispensable role in human body heat dissipation. However, conventional textiles tend to focus on sweat removal and pay little attention to the basic thermoregulation function of sweat, showing limited evaporation ability and cooling efficiency in moderate/profuse perspiration scenarios. Here, we propose an integrated cooling (i-Cool) textile with unique functional structure design for personal perspiration management. By integrating heat conductive pathways and water transport channels decently, i-Cool exhibits enhanced evaporation ability and high sweat evaporative cooling efficiency, not merely liquid sweat wicking function. In the steady-state evaporation test, compared to cotton, up to over 100% reduction in water mass gain ratio, and 3 times higher skin power density increment for every unit of sweat evaporation are demonstrated. Besides, i-Cool shows about 3 °C cooling effect with greatly reduced sweat consumption than cotton in the artificial sweating skin test. The practical application feasibility of i-Cool design principles is well validated based on commercial fabrics. Owing to its exceptional personal perspiration management performance, we expect the i-Cool concept can provide promising design guidelines for next-generation perspiration management textiles.
}, year = {2021}, journal = {Nature Communications}, volume = {12}, month = {12/2021}, doi = {10.1038/s41467-021-26384-8}, language = {eng}, }