Effect of Fly Ash as an Additive on the Limestone Dissolution Rate Constant

Abstract: Limestone dissolution is a very important factor in flue gas desulfurization systems because it determines its reactivity toward SO 2 . Fly ash, a siliceous material, has been reported to improve sorbent reactivity. This study investigates the effect of adding fly ash to limestone on its dissolution rate constant. The experiments were carried out using a pH stat apparatus where the effects of the reaction variables, fly ash/limestone ratio, slurry pH, reaction temperature, and concentration of acid, used were … Show more

“…Reaction temperature has a significant role in the limestone dissolution process and is closely related to the dissolution rate-limiting step. The reaction rate in a fluid–solid system is primarily controlled by one of the following steps: diffusion through the fluid film, diffusion through the ash, or a chemical reaction between the fluid reactant and solid particles at the surface of the unreacted limestone sample . This paper treats the reaction process as a noncatalytic heterogeneous reaction system and the limestone particle as nonporous with no structural change as the dissolution progresses.…”

“…The reaction rate in a fluid−solid system is primarily controlled by one of the following steps: diffusion through the fluid film, diffusion through the ash, or a chemical reaction between the fluid reactant and solid particles at the surface of the unreacted limestone sample. 34 This paper treats the reaction process as a noncatalytic heterogeneous reaction system and the limestone particle as nonporous with no structural change as the dissolution progresses. As such, the shrinking core model 35 is used to describe the dissolution kinetics, and it considers the first reaction to occur at the particle surface before moving toward the core.…”

Dissolution Reactivity and Kinetics of Low-Grade Limestone for Wet Flue Gas Desulfurization

“…Reaction temperature has a significant role in the limestone dissolution process and is closely related to the dissolution rate-limiting step. The reaction rate in a fluid–solid system is primarily controlled by one of the following steps: diffusion through the fluid film, diffusion through the ash, or a chemical reaction between the fluid reactant and solid particles at the surface of the unreacted limestone sample . This paper treats the reaction process as a noncatalytic heterogeneous reaction system and the limestone particle as nonporous with no structural change as the dissolution progresses.…”

“…The reaction rate in a fluid−solid system is primarily controlled by one of the following steps: diffusion through the fluid film, diffusion through the ash, or a chemical reaction between the fluid reactant and solid particles at the surface of the unreacted limestone sample. 34 This paper treats the reaction process as a noncatalytic heterogeneous reaction system and the limestone particle as nonporous with no structural change as the dissolution progresses. As such, the shrinking core model 35 is used to describe the dissolution kinetics, and it considers the first reaction to occur at the particle surface before moving toward the core.…”

Dissolution Reactivity and Kinetics of Low-Grade Limestone for Wet Flue Gas Desulfurization

Assessment of Owhe kaolinite as potential aluminium source in hydrochloric acid and hydrogen peroxide solutions: Kinetics modeling and optimization