High‐frequency (470 kHz ) ultrasonics‐assisted room temperature CO 2 stripping and fate of Sono exposed solvent
Abstract BACKGROUND The conventional CO 2 stripping process in solvent‐based postcombustion CO 2 capture (PCCC) process uses heating to strip the CO 2 (~120 °C). However, the challenges associated with this method are high energy consumption in degassing the CO 2 from solvent, solvent loss and degra...
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Published in | Journal of chemical technology and biotechnology (1986) |
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Main Authors | , , |
Format | Journal Article |
Language | English |
Published |
01.10.2024
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Online Access | Get full text |
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Summary: | Abstract BACKGROUND The conventional CO 2 stripping process in solvent‐based postcombustion CO 2 capture (PCCC) process uses heating to strip the CO 2 (~120 °C). However, the challenges associated with this method are high energy consumption in degassing the CO 2 from solvent, solvent loss and degradation resulting from the high –temperatures, resulting in high energy consumption typical of solvent‐based PCCC. The present study demonstrates the use of bath‐type sonication (470 kHz frequency) to remove CO 2 from CO 2 loaded 30 wt% Monoethanolamine under controlled temperature conditions. Solvent performance was evaluated following exposure to 2 h conventional heating and 75 h sonication. RESULTS In a batch sono‐assisted process, CO 2 stripping became possible at 17.5 °C compared to 102.2 °C using the conventional method. Increasing the sonication time led decreased carbon loading and increased stripping efficiency. The stripping rate was high at the initial stages of treatment. Evaluation of sono‐exposed solvents exhibited decreased pH during CO 2 loading and decreased absorption capacity of the conventionally heated sample. CONCLUSION The sono‐assisted method consumes 3.57‐foldless energy than conventional heating. Its CO 2 stripping rate was found to be higher within 5 min of sonication. Notably, the maximum temperature reached for the 1 h intervening mode of sonication at 470 kHz was 49.49 °C. The reduction in absorption capacity per hour of conventional heating was 24.5%, whereas for sonication it was <0.4% and solvent loss was 19.7% lower than conventional. There was no significant change in the color, pH and density of the sample. A 20.4% higher surface tension than that of the virgin sample was observed. © 2024 Society of Chemical Industry (SCI). |
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ISSN: | 0268-2575 1097-4660 |
DOI: | 10.1002/jctb.7763 |