DOI: https://doi.org/10.9767/jcerp.20584

Process Optimization for Enhanced Dimethyl Ether Yield through Methanol Synthesis and Dehydration of Syngas-Derived Methanol

Department of Chemical Engineering, Universitas Diponegoro, Jl. Prof. Sudarto, SH, Tembalang, Semarang, Indonesia

Received: 12 Dec 2025; Revised: 15 Dec 2025; Accepted: 17 Dec 2025; Available online: 26 Dec 2025; Published: 30 Dec 2025.
Editor(s): Istadi Istadi
Open Access Copyright (c) 2025 by Authors, Published by Universitas Diponegoro and BCREC Publishing Group
Creative Commons License This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
Fulltext View|Download

Citation Format:
Cover Image
Abstract

The global energy crisis and continued reliance on fossil fuels highlight the urgent need for sustainable alternatives. Dimethyl ether (DME) has emerged as a promising low carbon fuel owing to its clean combustion properties and versatility as an LPG substitute, diesel replacement, and chemical feedstock. This study focuses on optimizing the design of DME production from syngas derived methanol, with particular emphasis on conversion efficiency and thermal management. Base case simulations revealed that higher methanol dehydration conversion elevated reactor temperatures by nearly 100 °C, thereby disrupting equilibrium and hindering effective separation. To address these challenges, a modified process integrating cooling, heating, and distillation units was developed, achieving an 80% conversion and a DME yield of 97.6%, while simultaneously reducing excessive cooling requirements. These findings demonstrate that improved thermal control and separation strategies can significantly enhance both energy efficiency and environmental performance, reinforcing DME’s potential role in the transition toward cleaner energy systems. 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: Dimethyl ether (DME); Methanol dehydration; Process optimization; Sustainable production

Article Metrics:

Article Info
Section: Original Research Articles
Language : EN
Recent articles
Conversion Improvement of Propylene to Acrylic Acid Process Integrated Optimization of Cyclohexane Production via Benzene Hydrogenation Incorporating Advanced Separation, Extended Distillation, and Heat Exchanger Integration to Enhance Product Purity and Energy Efficiency Enhance Removal Pollutant from Batik Industrial Wastewater via Photo- Fenton Process: Efficiency and Kinetic Study More recent articles
  1. Holechek, J.L., Geli, H.M., Sawalhah, M.N., Valdez, R. (2022). A global assessment: can renewable energy replace fossil fuels by 2050?. Sustainability, 14(8), 4792. DOI: 10.3390/su14084792
  2. Gayen, D., Chatterjee, R., Roy, S. (2024). A review on environmental impacts of renewable energy for sustainable development. International Journal of Environmental Science and Technology, 21(5), 5285-5310. DOI: 10.1007/s13762-023-05380-z
  3. Mondal, U., Yadav, G.D. (2019). Perspective of dimethyl ether as fuel: Part I. Catalysis. Journal of CO2 Utilization, 32, 299-320. DOI: 10.1016/j.jcou.2019.02.003
  4. Soltic, P., Hilfiker, T., Wright, Y., Hardy, G., Fröhlich, B., Klein, D. (2024). The potential of dimethyl ether (DME) to meet current and future emissions standards in heavy-duty compression-ignition engines. Fuel, 355, 129357. DOI: 10.1016/j.fuel.2023.129357
  5. Semelsberger, T.A., Borup, R.L., Greene, H.L. (2006). Dimethyl ether (DME) as an alternative fuel. Journal of power sources, 156(2), 497-511. DOI: 10.1016/j.jpowsour.2005.05.082
  6. Matzen, M., Demirel, Y. (2016). Methanol and dimethyl ether from renewable hydrogen and carbon dioxide: Alternative fuels production and life-cycle assessment. Journal of Cleaner Production, 139, 1068-1077. DOI: 10.1016/j.jclepro.2016.08.163
  7. Medaiyese, F.J., Nasriani, H.R., Khajenoori, L., Asimakopoulou, E., Khan, K., Graham, T. L., ..., Farzaneh, S.A. (2023). Energy Transition with Dimethyl Ether (An Alternative Fuel to Diesel) to minimise the Environmental Impact. In 84th EAGE Annual Conference & Exhibition (Vol. 2023). European Association of Geoscientists and Engineering (EAGE) Publications. DOI: 10.3997/2214-4609.202310330
  8. Michailos, S., McCord, S., Sick, V., Stokes, G., Styring, P. (2019). Dimethyl ether synthesis via captured CO2 hydrogenation within the power to liquids concept: A techno-economic assessment. Energy Conversion and Management, 184, 262-276. DOI: 10.1016/j.enconman.2019.01.046
  9. Prabasari, I.G., Permata, N.P., Hutagalung, W.L.C., Bahar, F.F., Kumalasari, D. (2024). Optimalisasi Produksi Di-Metil Eter dari Syngas Menggunakan Perangkat Aspen HYSYS: Di-Methyl Ether Production from Syngas Optimalization using Aspen HYSYS software. Jurnal Engineering, 6(2), 30-36. DOI: 10.22437/jurnalengineering.v6i2.34557
  10. Giuliano, A., Catizzone, E., Freda, C. (2021). Process simulation and environmental aspects of dimethyl ether production from digestate-derived syngas. International Journal of Environmental Research and Public Health, 18(2), 807. DOI: 10.3390/ijerph18020807
  11. Yuanyuan, H.A.N., Zhang, H., Weiyong, Y.I.N.G., Dingye, F.A.N.G. (2009). Modeling and simulation of production process on dimethyl ether synthesized from coal-based syngas by one-step method. Chinese Journal of Chemical Engineering, 17(1), 108-112. DOI: 10.1016/S1004-9541(09)60041-0
  12. Murakami, K., Honda, M., Wahyudiono, Kanda, H., Goto, M. (2017). Thermal isomerization of (all-E)-lycopene and separation of the Z-isomers by using a low boiling solvent: Dimethyl ether. Separation Science and Technology, 52(16), 2573-2582. DOI: 10.1080/01496395.2017.1374412
  13. Barber, C.R., Horsford, A. (1963). The determination of the boiling and triple points of equilibrium hydrogen and its vapour pressure-temperature relation. British Journal of Applied Physics, 14(12), 920. DOI: 10.1088/0508-3443/14/12/324
  14. Ma, X., Albertsma, J., Gabriels, D., Horst, R., Polat, S., Snoeks, C., Kapteijn, F., Eral, H.B., Vermaas, D.A., Mei, B., de Beer, S., van der Veen, M.A. (2023). Carbon monoxide separation: past, present and future. Chemical Society Reviews, 52(11), 3741-3777. DOI: 10.1039/D3CS00147D
  15. Yaws, C.L. (1996). Chemical Properties Handbook Physical. McGraw-Hill
  16. Peinado, C., Liuzzi, D., Ladera-Gallardo, R. M., Retuerto, M., Ojeda, M., Peña, M.A., Rojas, S. (2020). Effects of support and reaction pressure for the synthesis of dimethyl ether over heteropolyacid catalysts. Scientific Reports, 10(1), 8551. DOI: 10.1038/s41598-020-65296-3
  17. Motie, M., Moein, P., Palayesh, T.O., Moghadasi, R., Palayesh, T.O. (2019). Separator pressure optimisation and cost evaluation of a multistage production unit using genetic algorithm. International Petroleum Technology Conference. DOI: 10.2523/IPTC-19396-MS
  18. Guo, C., Wang, F., Xing, J., Cui, P. (2022). Thermodynamic and economic comparison of extractive distillation sequences for separating methanol/dimethyl carbonate/water azeotropic mixtures. Separation and Purification Technology, 282, 120150. DOI: 10.3390/separations9080189
  19. Afokin, M.I., Magomedova, M.V. (2021). Process Solutions for Recovery of Dimethyl Ether Produced Through One-Step Synthesis and Their Assessment. Petroleum Chemistry, 61(2), 115-122. DOI: 10.1134/S0965544121020109
  20. Wahid, A., Gunawan, T.A. (2015). Pengendalian proses purifikasi DME dan metanol pada pabrik DME dari gas sintesis. Sinergi, 19(1), 57-66. DOI: 10.22441/sinergi.2015.1.010
  21. Grasia, J.L., Wijaya, A.A., Ramadhan, N.D., Saputro, A.N., Maharani, A. (2024). Energy Optimization of Dimethyl Ether (DME) Production Process from Methanol Dehydration. Journal of Chemical Engineering Research Progress, 1(2), 122-131. DOI: 10.9767/jcerp.20269
  22. Chmielarz, L. (2024). Dehydration of Methanol to Dimethyl Ether—Current State and Perspectives. Catalysts, 14(5), 308. DOI: 10.3390/catal14050308

Last update:

No citation recorded.

Last update:

No citation recorded.