Publikation: Thermal-responsive soil-hydrogel composite for additive construction
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To improve the formability and bonding strength of 3D printing soil, a temperature-stimulating responsive intelligent soil-hydrogel 3D printing formula was innovatively developed by combining soil and gelatin. Varied soil-gelatin composites, featuring different gelatin content by weight of soil (0 %, 0.5 %, 1 %, and 1.5 %), were prepared and cured at 5 °C to facilitate the crosslinking of gelatin. An array of tests, including rheological assessments, compressive tests, and scanning electron microscopy analysis. Were conducted to thoroughly characterize the performance of gelatin-soil composites for 3D printing. Our findings unveiled that, following the cross-linking of gelatin at 5 °C, the gelatin-soil composites exhibited superior formability and bond strength compared to the reference. Furthermore, the soil-gelatin composites demonstrated not only comparable compressive strength to the reference but also enhanced interlayer bond strength. This innovative soil-hydrogel 3D printing formula, combining the versatility of soil and the responsive characteristics of gelatin, presents a promising avenue for advancing the capabilities of 3D printed soil.
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ZHUANG, Haidong, Zhenbang GUO, Yuanwang LAN, Cristina RUIZ AGUDO, Fazhou WANG, Helmut CÖLFEN, Zhengyao QU, 2024. Thermal-responsive soil-hydrogel composite for additive construction. In: Journal of Building Engineering. Elsevier. 2024, 98, 111118. eISSN 2352-7102. Verfügbar unter: doi: 10.1016/j.jobe.2024.111118BibTex
@article{Zhuang2024-12Therm-71104, year={2024}, doi={10.1016/j.jobe.2024.111118}, title={Thermal-responsive soil-hydrogel composite for additive construction}, volume={98}, journal={Journal of Building Engineering}, author={Zhuang, Haidong and Guo, Zhenbang and Lan, Yuanwang and Ruiz Agudo, Cristina and Wang, Fazhou and Cölfen, Helmut and Qu, Zhengyao}, note={Article Number: 111118} }
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