The Techno-Economic Benefit of Sorption Enhancement: Evaluation of Sorption-Enhanced Dimethyl Ether Synthesis for CO2 Utilization

• Published in: Frontiers in chemical engineering Vol. 2
• Main Authors: Skorikova, Galina, Saric, Marija, Sluijter, Soraya Nicole, van Kampen, Jasper, Sánchez-Martínez, Carlos, Boon, Jurriaan
• Format: Journal Article
• Language: English
• Published: Frontiers Media S.A 22.12.2020
• Subjects: dimethyl ether; electrification; electrolysis; industry; power-to-X; sorption-enhanced reaction
• ISSN: 2673-2718; 2673-2718
• DOI: 10.3389/fceng.2020.594884

Dimethyl ether (DME) is an important platform chemical and fuel that can be synthesized from CO 2 and H 2 directly. In particular, sorption-enhanced DME synthesis (SEDMES) is a novel process that uses the in situ removal of H 2 O with an adsorbent to ensure high conversion efficiency in a single unit operation. The in situ removal of steam has been shown to enhance catalyst lifetime and boost process efficiency. In addition, the hydrogen may be supplied through water electrolysis using renewable energy, making it a promising example of the (indirect) power-to-X technology. Recently, major advances have been made in SEDMES, both experimentally and in terms of modeling and cycle design. The current work presents a techno-economic evaluation of SEDMES using H 2 produced by a PEM electrolyzer. A conceptual process design has been made for the conversion of CO 2 and green H 2 to DME, including the purification section to meet ISO fuel standards. By means of a previously developed dynamic cycle model for the SEDMES reactors, a DME yield per pass of 72.4 % and a carbon selectivity of 84.7% were achieved for the studied process design after optimization of the recycle streams. The production costs for DME by the power-to-X technology SEDMES process at 23 kt/year scale are determined at ∼€1.3 per kg. These costs are higher than the current market price but lower than the cost of conventional DME synthesis from CO 2 . Factors with the highest impact on the business cases are the electricity and CO 2 cost price as well as the CAPEX of the electrolyzer, which is considered an important component for technology development. Furthermore, as the H 2 cost constitutes the largest part of the DME production cost, SEDMES is demonstrated to be a powerful technology for efficient conversion of green H 2 into DME.