Design and study of a novel ammonia‐based CO₂ capture process with bipolar membrane electrodialysis

Abstract: Aqueous ammonia is a promising absorbent in the field of post combustion CO2 capture. However, the high volatilization of NH3 results in a high energy requirement, as well as solid precipitation during the CO2 regeneration process. A novel process was designed to reduce energy consumption and solve the problem. The bipolar membrane electrodialysis (EDBM) unit and CO2 regeneration reactor were taken as the regeneration part. In the novel process, the bubble in the EDBM unit would be eliminated, and the regenera… Show more

“…A study by Song et al introduced a novel approach for reducing energy consumption in post-combustion CO 2 capture using aqueous ammonia as the absorbent . The conventional process faces challenges such as high levels of NH 3 volatilization and solid precipitation during CO 2 regeneration.…”

“…A study by Song et al introduced a novel approach for reducing energy consumption in post-combustion CO 2 capture using aqueous ammonia as the absorbent. 115 The conventional process faces challenges such as high levels of NH 3 volatilization and solid precipitation during CO 2 regeneration. In the novel process, the BMED unit and CO 2 regeneration reactor were employed separately, eliminating bubbles in the BMED unit and avoiding the risk of precipitation during regeneration.…”

Advancements in Bipolar Membrane Electrodialysis Techniques for Carbon Capture

“…A study by Song et al introduced a novel approach for reducing energy consumption in post-combustion CO 2 capture using aqueous ammonia as the absorbent . The conventional process faces challenges such as high levels of NH 3 volatilization and solid precipitation during CO 2 regeneration.…”

“…A study by Song et al introduced a novel approach for reducing energy consumption in post-combustion CO 2 capture using aqueous ammonia as the absorbent. 115 The conventional process faces challenges such as high levels of NH 3 volatilization and solid precipitation during CO 2 regeneration. In the novel process, the BMED unit and CO 2 regeneration reactor were employed separately, eliminating bubbles in the BMED unit and avoiding the risk of precipitation during regeneration.…”

Advancements in Bipolar Membrane Electrodialysis Techniques for Carbon Capture

Advances in Carbon Control Technologies for Flue Gas Cleaning