摘要:SummaryA 10,000 ton-CO2/y mineralization curing (CMC) process was demonstrated in Jiaozuo city, China by retrofitting a traditional autoclaved curing plant. An industrial concrete formula with synergistic effects of aggregate gradation, early hydration, and alkali excitation was developed using local solid wastes resources. Approximately 90% of the raw materials, including fly ash, furnace blaster slag, steel slag, and carbide slag, came from coal-based industries. An extraordinary phenomenon of high-temperature accumulation from room temperature to 140°C was first observed in an industrial scale because of the rapid and strong exothermic carbonation reaction. A step pressure-equalizing procedure was developed to achieve a rapid carbonation rate, a high CO2conversion ratio of >98%, and efficient carbonation exotherm recycling. The global warming potential life cycle analysis revealed that compared with autoclaved curing, CMC showed significantly decreased the emission of 182 kg CO2-Eq/m3-product, with direct CO2sequestration accounting for ∼65% of the reduction.Graphical abstractDisplay OmittedHighlights•A full-scale 10,000 ton/y CO2mineralization curing project•The CO2conversion rate is >98% with step pressure-equalizing process•High-temperature accumulation in industrial CMC process is first reported•The economic benefit of CMC technology is approximately 35 USD/t-CO2Energy sustainability; Civil engineering; Mechanical engineering; Green engineering
