Study of CO2 Absorption Into Aqueous Diethanolamine (DEA) Using Microchannel Reactors

Bangerth, Stefan; Ganapathy, Harish; Ohadi, Michael M.; Khan, Tariq S.; Alshehhi, Mohamed

doi:10.1115/imece2014-36348

Cited by 2 publications

(1 citation statement)

References 0 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Due to the higher surface area to volume ratio and higher mass‐transfer rates, the minichannel technology is seeing rapid implementation in diverse engineering applications. Several studies have reported the mass‐transfer characterization of chemical absorption of acid gases using microchannels and minichannels . These studies were mainly conducted using amines while piperazine, water, and NaHCO 3 are also used in some cases.…”

Section: Introductionmentioning

confidence: 99%

Economic assessment of carbon capture by minichannel absorbers

Yang¹,

Khan²,

Alshehhi³

et al. 2017

AIChE Journal

Self Cite

View full text Add to dashboard Cite

In this work, a physio-economic model supported by lab-scale experiments assessing the economic viability of minichannel based carbon capture units is presented. The net present value of (capital and operating) costs (NPVC) ensued throughout the plant life is selected as the benchmarking parameter. An optimization problem is formulated and solved with the objective of minimizing the NPVC of the unit subject to constraints imposed by the physics of absorption and pressure drop limits; both of which are captured via experimentally deduced empirical correlations. The results show that the minichannel absorbers are economically competitive to conventional systems for low capacity CO 2 capture achieving savings ranging from $50% to 3% for plant capacities ranging from 5 to 50 MMSCFD, respectively, primarily due to their lower capital costs. At higher plant capacities, the higher operating costs of the minichannel units dominate their NPVC and as such lead them to lose their competitiveness.

show abstract

Section: Introductionmentioning

confidence: 99%

Economic assessment of carbon capture by minichannel absorbers

Yang¹,

Khan²,

Alshehhi³

et al. 2017

AIChE Journal

Self Cite

View full text Add to dashboard Cite

show abstract

Capillary Microreactor for Initial Screening of Three Amine-Based Solvents for CO2 Absorption, Desorption, and Foaming

et al. 2022

View full text Add to dashboard Cite

Microreactor is a very attractive laboratory device for screening conditions and solvents in an efficient, safe and fast manner. Most reported work on microreactors for CO2 capturing deals with absorption and mass transfer performance with a limited number of studies on solvent regeneration. For the first time, foaming, which is a major operational challenge of CO2 capturing is being studied in combination with absorption and desorption in a capillary microreactor setup. To demonstrate the setup capabilities, three known amine-based solvents (MEA, MDEA, and AMP) were selected for the screening and evaluation studies. MEA had the highest CO2 absorption efficiency while MDEA had the lowest one. CO2 absorption efficiency increased with temperature, liquid flow rate, and amine concentration as per the literature. During the absorption work, the Taylor flow regime was maintained at the reactor inlet. CO2 desorption of loaded amine solutions was investigated at different concentrations and temperatures up to 85°C. MDEA solution had the highest desorption efficiency, followed by AMP and the least desorption efficiency was that of MEA. Foaming experimental results showed that MEA had a larger foaming region compared to AMP. However, more foaming happened with AMP at higher gas and liquid flow rates. A plug flow mathematical reactor model was developed to simulate the MEA-CO2 system. The model captured well the performance and trends of the studied system, however the absolute prediction deviated due to uncertainties in the used physical properties and mass transfer correlation. Selecting a solvent for chemical absorption depends on many more factors than these three studied parameters. Still, microreactor proves a valuable tool to generate experimental results under different conditions, with the least amount of consumables (less than 1 L solvents were used), in a fast manner, combined with a knowledge insight because of the uniqueness of the Taylor flow regime.

show abstract

Study of CO2 Absorption Into Aqueous Diethanolamine (DEA) Using Microchannel Reactors

Cited by 2 publications

References 0 publications

Economic assessment of carbon capture by minichannel absorbers

Economic assessment of carbon capture by minichannel absorbers

Capillary Microreactor for Initial Screening of Three Amine-Based Solvents for CO2 Absorption, Desorption, and Foaming

Contact Info

Product

Resources

About