Toward the practical application of direct CO2 hydrogenation technology for methanol production

Authors
Lee, Hee W.Kim, KyeongsuAn, JinJooNa, JonggeolKim, HonggonLee, HyunjooLee, Ung
Issue Date
2020-09
Publisher
WILEY
Citation
INTERNATIONAL JOURNAL OF ENERGY RESEARCH, v.44, no.11, pp.8781 - 8798
Abstract
Methanol production via direct CO2 hydrogenation is one of the most promising means of utilizing greenhouse gases owing to the significant market for methanol and the potential to simultaneously reduce CO2 emissions. However, the practical applications of this process still suffer from high production costs owing to the expensive raw materials required and the severe operating conditions. Herein, we propose an economically attractive methanol production process that also works to sequester CO2, developed through technoeconomic optimization. This economically optimized process design and the associated operating conditions were simultaneously obtained from among thousands of possible configurations using a superstructure optimization. A modified machine learning-based optimization algorithm was also employed to efficiently achieve this complex superstructure optimization. The optimum process design involves a multistage reactor together with an interstage product recovery system and substantially improves the CO2 conversion to greater than 52%. Consequently, the revenue obtained from methanol production changes from a $4.3 deficit to a $2.5 profit per ton. In addition, the proposed process is capable of generating the same amount of methanol with only half the CO2 emissions associated with conventional methanol production methods. A comprehensive sensitivity analysis is also provided along with the optimum process design to identify the influence of various technoeconomic parameters.
Keywords
CARBON-DIOXIDE HYDROGENATION; MULTIOBJECTIVE OPTIMIZATION; SENSITIVITY-ANALYSIS; CAPTURED CO2; CATALYST; REACTOR; CONVERSION; SIMULATION; SOLVENT; SYSTEMS; CARBON-DIOXIDE HYDROGENATION; MULTIOBJECTIVE OPTIMIZATION; SENSITIVITY-ANALYSIS; CAPTURED CO2; CATALYST; REACTOR; CONVERSION; SIMULATION; SOLVENT; SYSTEMS; Bayesian optimization; CO2; hydrogenation; Methanol; superstructure; technoeconomic optimization
ISSN
0363-907X
URI
https://pubs.kist.re.kr/handle/201004/118172
DOI
10.1002/er.5573
Appears in Collections:
KIST Article > 2020
Files in This Item:
There are no files associated with this item.
Export
RIS (EndNote)
XLS (Excel)
XML

qrcode

Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.

BROWSE