Abstract

Abstract A new type of process for producing high‐purity calcium carbonate from waste cement powder was developed. The process consists of two main reactions; extraction of calcium in the form of calcium ions from waste cement powder in a water slurry by pressurized CO 2 (typically at several MPa), and precipitation of calcium carbonate (CaCO 3 ) from the extracted solution by reduction of the CO 2 pressure. The process can be recognized as the emission reduction process of CO 2 as well. Laboratory‐scale experimental studies were conducted for both the extraction reaction and the precipitation reaction, to examine the feasibility of the process. The extraction process was found to proceed at a relatively high rate, especially during the initial 10 min. The concentration of calcium ions exceeded the thermodynamic solubility of CaCO 3 (supersaturation) when abundant waste cement was available. After filtration of the residues, CaCO 3 particles with >98% purity were obtained by depressurizing the CO 2 . The dependency of the reaction rates on the operating conditions, such as the ratio of waste cement to water, CO 2 pressure, and particle size of waste cement particles, was investigated. A process design was carried out based on the experimental results, assuming that the present process is applied to two types of CaCO 3 production process: flue gas desulfurization and production of ultrahigh‐purity CaCO 3 . The estimated costs per 1 metric ton of CaCO 3 were USD 136 for desulfurization and USD 323 for high‐purity CaCO 3 . © 2005 American Institute of Chemical Engineers Environ Prog, 2005