期刊
CHEMICAL ENGINEERING JOURNAL
卷 425, 期 -, 页码 -出版社
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2021.131469
关键词
Cellulose; Light management; Strong; Robust; Energy efficient material
资金
- National key research and development plan [2019YFC1905903]
- National Natural Science Foundation of China [31971612, 31700520]
- Scientific and technological innovation funding of Fujian Agriculture and Forestry University [CXZX2018007, CXZX2017040]
The cellulose composite film developed in this study plays a crucial role in energy-efficient buildings by effectively propagating and scattering light while possessing superior UV resistance and mechanical strength. It offers a promising option for creating a comfortable, healthy, and safe lighting environment in sustainable buildings.
Energy-saving materials in buildings enable meaningful reduction of indoor energy consumption and are critical to develop a carbon-neutrality society. Accordingly, lighting in modern buildings should be properly managed toward energy-efficient buildings. Here, we developed a broadband light-management cellulose composite film, composed of 75 wt% cellulose bonded by phenol formaldehyde resin, which shows a high transparency (similar to 86%) and haze (similar to 90%) for effective light propagating and scattering, and more importantly, a superior anti-ultraviolet capability (similar to 83% absorptance and similar to 17% reflectance), thus enabling a soft, uniform, large areal, and safe illumination of the sunlight in buildings toward a comfortable, healthy yet energy-saving environment. In addition, our cellulose composite film features a strong mechanical strength (140 MPa tensile strength) and superior robustness (e.g., high hydro-stability with a high wet strength of 135 MPa, thermal stability and fire-resistance ability, as well as excellent impact absroption capacity), proving its durability for long-term indoor or outdoor applications. The cellulose composite film is synthesized by a simple and scalable calendaring-like process which can be fully compatible with current paper-making industry. These integrated merits of our cellulose composite film make a promising candidate for energy efficient building applications toward a sustainable society.
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