Design Enhancement of Methanol Purification in Syngas-Based Production: The Role of Additional Distillation and Cooling

Angela Gracelly; Jhilena Abigail Luberzky Sinuraya; Laurentia Auren Yoicy Talentina; Mathias Jesse Gandy; Rhadisza Octa Aslam Arnata; Siti Rodifatul Ilaiah

doi:10.9767/jcerp.20570

DOI: https://doi.org/10.9767/jcerp.20570

Design Enhancement of Methanol Purification in Syngas-Based Production: The Role of Additional Distillation and Cooling

Angela Gracelly¹, Jhilena Abigail Luberzky Sinuraya¹, Laurentia Auren Yoicy Talentina¹

, Mathias Jesse Gandy¹, Rhadisza Octa Aslam Arnata¹, Siti Rodifatul Ilaiah²

¹Department of Chemical Engineering, Universitas Diponegoro, Semarang 50275, Indonesia

²Department of Chemical Engineering, Universitas Indonesia, Depok 16424, Indonesia

Received: 11 Dec 2025; Revised: 14 Dec 2025; Accepted: 15 Dec 2025; Available online: 22 Dec 2025; Published: 30 Dec 2025.

Editor(s): Istadi Istadi

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

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@article{JCERP20570,
    author = {Angela Gracelly and Jhilena Abigail Luberzky Sinuraya and Laurentia Auren Yoicy Talentina and Mathias Jesse Gandy and Rhadisza Octa Aslam Arnata and Siti Rodifatul Ilaiah},
    title = {Design Enhancement of Methanol Purification in Syngas-Based Production: The Role of Additional Distillation and Cooling},
    journal = {Journal of Chemical Engineering Research Progress},
  volume = {2},
    number = {2},
    year = {2025},
    keywords = {Methanol Purification; Syngas; Distillation; Cooling system},
    abstract = { Methanol is an essential industrial chemical with increasing global demand, yet conventional syngas-based production often encounters challenges related to energy efficiency and separation performance. This study seeks to design and evaluate an improved methanol purification process aimed at maximizing yield and purity through advanced heat management and separation strategies. Employing a rigorous process simulation environment and the Peng–Robinson Equation of State (PR-EOS) for thermodynamic modeling, a comparative analysis was conducted between a conventional base case and a modified process configuration. The base case comprised a single cooling unit, a separator, and one distillation column, whereas the modified design incorporated an additional upstream cooler and a secondary distillation column to enhance phase conditioning and recovery. Simulation results indicate that the proposed modifications substantially outperform the conventional design. The base case achieved a methanol purity of 59.26%, while the modified configuration increased purity to 71.07%. This 11.8% improvement demonstrates that multi-stage distillation combined with enhanced cooling effectively reduces vapor-phase losses and improves separation efficiency, offering a more sustainable pathway for industrial methanol production. Copyright © 2025 by Authors, Published by Universitas Diponegoro and BCREC Publishing Group. This is an open access article under the CC BY-SA License ( https://creativecommons.org/licenses/by-sa/4.0 ). },
   issn = {3032-7059},   pages = {270--276}  doi = {10.9767/jcerp.20570},
    url = {https://journal.bcrec.id/index.php/jcerp/article/view/20570}
}

Citation Format:

Abstract

Methanol is an essential industrial chemical with increasing global demand, yet conventional syngas-based production often encounters challenges related to energy efficiency and separation performance. This study seeks to design and evaluate an improved methanol purification process aimed at maximizing yield and purity through advanced heat management and separation strategies. Employing a rigorous process simulation environment and the Peng–Robinson Equation of State (PR-EOS) for thermodynamic modeling, a comparative analysis was conducted between a conventional base case and a modified process configuration. The base case comprised a single cooling unit, a separator, and one distillation column, whereas the modified design incorporated an additional upstream cooler and a secondary distillation column to enhance phase conditioning and recovery. Simulation results indicate that the proposed modifications substantially outperform the conventional design. The base case achieved a methanol purity of 59.26%, while the modified configuration increased purity to 71.07%. This 11.8% improvement demonstrates that multi-stage distillation combined with enhanced cooling effectively reduces vapor-phase losses and improves separation efficiency, offering a more sustainable pathway for industrial methanol production. Copyright © 2025 by Authors, Published by Universitas Diponegoro and BCREC Publishing Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0).

Keywords: Methanol Purification; Syngas; Distillation; Cooling system

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Section: Original Research Articles

Language : EN

In 2025: JCERP, Volume 2 Issue 2 Year 2025 (December)

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