Litcius/Paper detail

3D-printed clay components with high surface area for passive indoor moisture buffering

Vincenzo Gentile, Juan D. Velásquez, Stefano Fantucci, Giorgia Autretto, Roberta Gabrieli, Pardeep Kumar Gianchandani, Marco Armandi, Francesco Baino

2024Journal of Building Engineering19 citationsDOIOpen Access PDF

Abstract

This study focuses on implementing a novel approach in which clay 3D-printed matrices were designed as a passive comfort solution to enhance indoor moisture buffering and air quality. Liquid Deposition Modeling additive manufacturing and parametric design were implemented to develop the components, which were characterized for having an increased specific surface exposed to air and moisture per volume unit, which showed to significantly enhance moisture buffering. This revealed a clear linear relationship between the two parameters. Additionally, the components showed a significant increase in the practical Moisture Buffering Value (MBV) and mass reduction compared to a solid clay reference. Furthermore, this research analyzed the influence of two stabilization techniques on the moisture uptake capacity of the samples, i.e. thermal treatment at different temperatures between 600-1000°C and mixing with calcium hydroxide paste within the 10-40% range. Finally, the morphological (scanning electron microscopy) and crystallographic (X-ray diffraction) analyses of the samples show a correlation between microstructural modifications and the variations of moisture uptake capacity and MBV. In addition, nitrogen adsorption-desorption measurements revealed that sample porosity decreased as the temperature of the thermal treatment increased, showing a correlation with the decrease of practical MBV.

Topics & Concepts

MoistureEnvironmental scienceMaterials scienceComposite materialAdditive Manufacturing and 3D Printing TechnologiesInnovations in Concrete and Construction MaterialsAdvanced Manufacturing and Logistics Optimization