posted on 2022-08-15, 19:49authored byLuc The Nguyen, Zhiqing Bai, Jingjing Zhu, Can Gao, Hoang Luu, Bin Zhang, Jiansheng Guo
Due to its multidimensional multilayer structure, elastic
3D space
fabric (3D@SF) has a large fog capture area. However, it is constrained
by droplet clogging. To solve the droplet clogging challenge, we created
a new tree structure (Tree 3D@SF) that is almost similar to the branch
of the Swamp Foxtail flower and to the two edges of a Shorebird’s
beaks. The filament surface of Tree 3D@SF’s was modified by
a simple bilayer method using silica nanoparticles and a hydrophobic
adhesive to form hydrophobic bumps that periodically alternated highly
hydrophobic sites. This formed the Hydrophobic/High Hydrophobic Bump-Tree
3D@SF. In addition, we adopted the sol–gel (polyurethane, tetraethyl
orthosilicate and methyltriethoxysilane) and electrospray (PVAc) methods
to develop High Hydrophobic-Tree 3D@SF and High Hydrophilic Knot-Tree
3D@SF. Specially, a novel-potential Auto 3D@SF fog collector was also
developed by taking advantage of elasticity and change in the V-thread
angle of 3D@SF, which was controlled by an automatic compression–relaxation
system. Auto 3D@SF can be used in complex windy environments. Our
results revealed that water harvesting rates using Auto 3D@SFs (4.31
g/cm2/h) and Tree 3D@SFs (4.29 g/cm2/h) were
twice that of Original 3D@SF. This was attributed to improved synergistic
effects of fog capturing, droplet growing and droplet shedding. These
findings will inform the development of suitable designs of improved
fog harvesters, particularly those that are based on elasticity of
3D space fabrics and textiles.