Bioinspired thermochromic transparent hydrogel wood with advanced optical regulation abilities and mechanical properties for windows

[Display omitted] •A bioinspired flexible thermochromic transparent hydrogel wood is achieved.•A high solar modulation ability with a low transition temperature is obtained.•Robust mechanical properties and low thermal conductivity are demonstrated.•The thermochromic hydrogel wood can be applied on...

Full description

Saved in:
Bibliographic Details
Published in:Applied energy 2021-09, Vol.297, p.117207, Article 117207
Main Authors: Liu, Sai, Tso, Chi Yan, Du, Yu Wei, Chao, Luke Christopher, Lee, Hau Him, Ho, Tsz Chung, Leung, Michael Kwok Hi
Format: Article
Language:English
Subjects:
Bionics
Energy-efficient buildings
Hydrogel
Smart windows
Thermochromism
Transparent woods
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:[Display omitted] •A bioinspired flexible thermochromic transparent hydrogel wood is achieved.•A high solar modulation ability with a low transition temperature is obtained.•Robust mechanical properties and low thermal conductivity are demonstrated.•The thermochromic hydrogel wood can be applied on windows for energy-saving. The huge heat loss/gain through windows is the cause of great energy consumption in buildings. In addition, the traditional fabrication method for glass causes many environmental problems. Recently, transparent wood has emerged as a promising alternative to traditional glass because of its high transmittance, strong mechanical properties, excellent thermal insulation ability and sustainability. In this study, inspired by jellyfish, a thermochromic transparent hydrogel wood that can smartly regulate solar irradiation is proposed as a smart window material by impregnating Poly(N-isopropylacrylamide)-polyacrylamide hydrogel into delignified wood. The novel thermochromic transparent hydrogel wood inherits the excellent thermochromic properties of PNIPAM and strong mechanical properties of wood, showing advanced optical regulation ability (i.e. Tlum = 82.7% and 39.8% at the cold and hot states &ΔTsol = 38.1%), low transition temperature (i.e. Tc = 22.9 °C), mechanically robust (i.e. σ = 11.6 MPa along the axial direction) and low thermal conductivity (i.e. K = 0.37 W m−1 K−1 along the perpendicular direction of the wood growth). A field test conducted in October in Hong Kong shows that thermochromic transparent hydrogel wood can reduce the indoor air temperature by 4.3 °C. Furthermore, a computational simulation for an office building proves that 2.6–10.2% energy could be saved by thermochromic transparent hydrogel wood in four different climate-zone cities. Besides, thanks to the flexibility, thermochromic transparent hydrogel wood can be easily fitted on existing windows, demonstrating the great potential for use in energy-efficient buildings.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2021.117207