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Effects of CO2 capture on waste concrete/sodium nitrate form-stable phase change composites for energy storage

Yaxuan Xiong, Xi Tian, Miao He, Jing Ren, Qian Xu, Yuting Wu, Yanqi Zhao, Yulong Ding

2024Journal of Cleaner Production13 citationsDOIOpen Access PDF

Abstract

A large quantity of building waste concrete is produced annually in China, which pollutes our ecological environment with its strong alkalinity . To recycle the building waste concrete, capture carbon dioxide at a low price, produce low-carbon, low-cost energy storage materials to provide clean energy for buildings. This work showcases a clever and forward-thinking approach by harnessing the carbon sequestration potential of building waste concrete. In a groundbreaking move, the researchers ingeniously exploited concrete from building waste to not only capture carbon dioxide , but also convert it into form-stable phase change composites, which were later carried out in detailed comparative analysis . Results show that the carbon capture efficiency of the building waste concrete reaches 24.7 % under the specific experimental conditions. The latent heat of the form-stable phase change composite prepared by carbon capture is higher (C-SS3, 50.31 J/g) than that without carbon capture (SS3, 39.84 J/g) by adding the same mass fraction of phase change material . In the range of 100–400 °C, the highest TES densities of sample SS4 and sample C-SS3 reached 339.78 J/g and 303.30 J/g, respectively. The compressive strength of SS2 is the highest, which is 121.54 MPa, and the compressive strength of both the building waste concrete and the form-stable phase change composite increased after carbon capture process. The thermal conductivity of the samples after carbonization (0.648 W/(m∙K)) was lower than that of before carbonization (0.884 W/(m∙K)). The form-stable phase change composites before and after carbon capture have good chemical compatibility among the components, and the form-stable phase change materials are densely bonded with the skeleton materials. Experimental verified the feasibility of preparing form-stable phase change composites using building waste concrete before and after carbon capture as a skeleton material.

Topics & Concepts

CarbonizationCompressive strengthMaterials scienceCarbon fibersCarbon dioxideWaste managementComposite numberEnvironmental scienceBiomass (ecology)Composite materialChemistryEngineeringOceanographyOrganic chemistryScanning electron microscopeGeologyPhase Change Materials ResearchAdsorption and Cooling SystemsChemical Looping and Thermochemical Processes