1. Process design and optimization of MEA-based CO2 capture processes for non-power industries
- Author
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Jin Kuk Kim, Seokwon Yun, Jaeuk Choi, Michael Binns, Mun Gi Jang, Habin Cho, and Se Young Oh
- Subjects
Optimal design ,Flue gas ,business.industry ,020209 energy ,Mechanical Engineering ,Process (computing) ,Process design ,02 engineering and technology ,Building and Construction ,Energy consumption ,Energy minimization ,Pollution ,Industrial and Manufacturing Engineering ,Refinery ,General Energy ,Flow conditions ,020401 chemical engineering ,0202 electrical engineering, electronic engineering, information engineering ,Environmental science ,0204 chemical engineering ,Electrical and Electronic Engineering ,Process engineering ,business ,Civil and Structural Engineering - Abstract
Aqueous MEA-based CO2 capture is one of main technologies for CO2 capture. However, there are various different sources of flue gases from different industries which have different flow conditions. In particular the CO2 content is very important and it will have a critical impact on the associated design of CO2 capture processes. In this study a superstructure optimization methodology is applied to ranges of different flue gases found in non-power industries such as cement, steel and refinery plants. Optimization of both operating conditions and structural modifications reveals the optimal configurations of equipment for the different industrial sources of CO2. A case study is given to address how energy consumption and process design of MEA-based CO2 capture systems is influenced by CO2 concentration in the feed gas. It is shown that flue gas splitting is the most significant and useful process modification for all the different flue gases tested in particular for low CO2 content flue gases. At higher CO2 contents the optimal designs are shown to require a combination of process modifications to give an even greater reduction of energy requirements.
- Published
- 2019