Stripper modeling for CO₂ removal using monoethanolamine and piperazine solvents

Van Wagener, David Hamilton

13 October 2011

This dissertation seeks to reduce the energy consumption of steam stripping to regenerate aqueous amine used for CO₂ capture from coal-fired power plants. Rigorous rate-based models in Aspen Plus® were developed, and rate-based simulations were used for packed vapor/liquid separation units. Five main configurations with varying levels of complexity were evaluated with the two solvents. 8 m piperazine (PZ) always performed better than 9 m monoethanolamine (MEA). More complex flowsheets stripped CO₂ with higher efficiency due to the more reversible separation. Multi-stage flash configurations were competitive at their optimal lean loadings, but they had poor efficiency at low lean loading. The most efficient configuration was an interheated column, with more effective and distributed heat exchange. It had a secondary benefit of a cooler overhead temperature, so less water vapor exited with the CO₂. Using a rich loading of 0.40 mol CO₂/mol alkalinity in 8 m PZ, the optimal lean loading was 0.28 and the energy requirement was 30.9 kJ/mol CO₂. Case studies were also performed on cold rich bypass and the use of geothermal heat. When cold rich bypass is used with the 2-stage flash and 8 m PZ, it reduces equivalent work by 11% to 30.7 kJ/mol CO₂. PZ benefited the most from cold rich bypass because it had a higher water concentration in the overhead vapor than with MEA. In an advanced 2-stage flash with 8 m PZ, geothermal heat available from 150 down to 100 °C requires 35.5 kJ work/mol CO₂. The heat duty and equivalent work was higher than other optimized configurations, but it would be a valid option if separating the heat source from the steam cycle of a coal-fired power plant was highly valued. Pilot plant campaigns were simulated with the available thermodynamic models. Two campaigns with 8 m PZ were simulated within small deviation from the measured values. The average absolute errors in these campaigns were 2.5 and 2.7%. A campaign with 9 m MEA in a simple stripper demonstrated that the MEA model did not predict the solvent properties well enough to appropriately represent the pilot plant operation. / text

CO2 removal

Amines

Stripping

Regeneration

Energy

Reversibility

Efficiency

CO₂ Separation and Regeneration Study From Power Plant Flue Gases With Reclaimed Mg(OH)₂

Jung, Kyung Sook

27 September 2005

No description available.

Engineering, Environmental

CO2 removal

Power plant

Mg(OH)2

Absorption

Microgravity Vortex Phase Separator for Liquid Amine CO2 Removal System

Sarvadi, Alexander Armstrong

08 1900

The present study investigates vortex phase separator (VPS) technology as a new approach for a liquid amine CO2 removal system. Experimental results obtained using a 99.99% pure CO2 stream and liquid amine with varying concentrations demonstrate the VPS' ability to decrease CO2 volume at its gas outlet. Operating parameters such as CO2 flow rate, relative humidity (RH), and temperature were systematically varied during experimental procedure, as well as working fluid temperature, volume, and flow rate. The subscale design for a VPS with a 3" inner diameter, 3.5" outer diameter, and 3.63" height removed a maximum of 84% of CO2 from a CO2 stream at 3.7 SCFH flow rate, 14°C temperature, and 82% RH, using 100 mL of 100% amine circulated at 1.52 LPM flow rate. The designed VPS also showed to be effective in removing relative humidity of the CO2 stream by up to 26% for the stated parameters. Regeneration of liquid amine in the VPS system is also proposed to allow for continuous CO2 removal. The results obtained in this work characterize the VPS system for CO2 removal in terms of various operating parameters for the gas (CO2) and liquid (liquid amine) phases, as well as provide initial insights into how a VPS sized for stability and applied to CO2 removal performs. This work demonstrates VPS technology as an effective, alternative CO2 removal technology that could be scaled and used to support human exploration of space.

Air revitalization

Liquid Amine CO2 removal system

Microgravity vortex phase separator

Engineering, Mechanical