CO<sub>2</sub> Utilization Process Simulation for Enhancing Production of Dimethyl Ether (DME)

Kartohardjono, Sutrasno; Adji, Bayu Sari; Muharam, Yuswan

doi:10.1155/2020/9716417

Cited by 14 publications

(14 citation statements)

References 49 publications

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“…Process reactions for indirect DME synthesis can be described as follows. Methanol synthesis was obtained as a result of the reaction between carbon dioxide and hydrogen [44]:…”

Section: Production Of Dmementioning

confidence: 99%

Direct catalytic production of dimethyl ether from CO and CO2: A review

Akhoondi

Osman

Eslami³

2021

Synth. Sinter.

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Dimethyl ether (DME) is a synthetically produced alternative fuel to diesel-based fuel and could be used in ignition diesel engines due to increasing energy demand. DME is considered extremely clean transportation and green fuel because it has a high cetane number (around 60), low boiling point (−25 °C), and high oxygen amount (35 wt%) which allow fast evaporation and higher combustion quality (smoke-free operation and 90% fewer NOx emissions) than other alternative CO2-based fuels. DME can be synthesized from various routes such as coal, petroleum, and bio-based material (i.e., biomass and bio-oil). Dimethyl ether can be produced from CO2 to prevent greenhouse gas emissions. This review aims to summarize recent progress in the field of innovative catalysts for the direct synthesis of dimethyl ether from syngas (CO+H2) and operating conditions. The problems of this process have been raised based on the yield and selectivity of dimethyl ether. However, regardless of how syngas is produced, the estimated total capital and operating costs in the industrial process depend on the type of reactor and the separation method.

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“…Process reactions for indirect DME synthesis can be described as follows. Methanol synthesis was obtained as a result of the reaction between carbon dioxide and hydrogen [44]:…”

Section: Production Of Dmementioning

confidence: 99%

Direct catalytic production of dimethyl ether from CO and CO2: A review

Akhoondi

Osman

Eslami³

2021

Synth. Sinter.

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show abstract

“…DME is regarded as a colorless, nontoxic, and clean fuel. It is a sustainable substitute for diesel fuel because of its low autoignition temperature and high cetane number [5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Alternative Strategies for Effective Utilization of Carbon Dioxide in Dimethyl Ether Synthesis

et al. 2023

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Converting CO2 into chemicals, e.g., methanol and dimethyl ether (DME), has been an attractive way to protect the global environment. In this process, the total catalyst volume of the methanol reactor was split into two sections to load the reactors. The catalyst volume of each reactor was optimized by the differential evolution technique. It was concluded that the indirect route yields a higher DME production rate than the direct one, as it produces higher amounts of methanol. CO2 conversions increased by 79 % in the indirect two‐stage process, which resulted in the highest DME production rate of 343 t per day. The results demonstrate how the concept of a two‐stage process in the indirect conversion of CO2 is feasible and beneficial for fuel production.

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“…Several industries use two reactors with the help of two catalysts, namely metal (for the CO/CO 2 hydrogenation reaction to methanol) and solid acid (for the methanol dehydration reaction to DME). However, this method requires a lot of costs [2]. Therefore, many studies have combined metals and solid acids to produce bifunctional catalysts so that reactions in two reactors can occur instantly in one reactor assisted by this catalyst.…”

Section: ■ Introductionmentioning

confidence: 99%

CuO, MgO, and ZrO<sub>2</sub> Loading on HZSM5 by Deposition-precipitation: Study of Crystallinity, Specific Surface Area, and Morphology

2022

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Bifunctional catalysts are often used in multiple reactions to synthesize certain products. The catalytic activity of bifunctional catalysts is influenced by parameters such as crystallinity, specific surface area, metal distribution, and morphology. Bifunctional catalysts are manufactured by adding metal to the support. The metal loading to the support often affects these parameters. Therefore, this research was conducted to determine the effect of CuO, MgO, and ZrO2 addition to HZSM5 on these parameters. The often-used loading method was deposition precipitation. The pH of the metal-support precursors' solution was increased to basic (pH of 8) to deposit the metal on the support. The loading effect was investigated by producing the following materials: CuO/HZSM5, CuO/ZrO2/HZSM5, CuO/MgO/HZSM5, and CuO/MgO/ZrO2/HZSM5. Each material was characterized using XRD, SAA, SEM, Mapping, EDS, and XRF. The results showed that all metal oxides could be embedded in the HZSM5. The loading of CuO, MgO, and ZrO2 to HZSM5 did not affect the crystallinity (structure) and morphology, increased the specific surface area, and was evenly distributed inside the pore of HZSM5. Further research is needed to determine the effect of crystallinity, specific surface area, and morphology on other metals and support types.

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CO₂ Utilization Process Simulation for Enhancing Production of Dimethyl Ether (DME)

Cited by 14 publications

References 49 publications

Direct catalytic production of dimethyl ether from CO and CO2: A review

Direct catalytic production of dimethyl ether from CO and CO2: A review

Alternative Strategies for Effective Utilization of Carbon Dioxide in Dimethyl Ether Synthesis

CuO, MgO, and ZrO<sub>2</sub> Loading on HZSM5 by Deposition-precipitation: Study of Crystallinity, Specific Surface Area, and Morphology

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CO2 Utilization Process Simulation for Enhancing Production of Dimethyl Ether (DME)

Cited by 14 publications

References 49 publications

Direct catalytic production of dimethyl ether from CO and CO2: A review

Direct catalytic production of dimethyl ether from CO and CO2: A review

Alternative Strategies for Effective Utilization of Carbon Dioxide in Dimethyl Ether Synthesis

CuO, MgO, and ZrO<sub>2</sub> Loading on HZSM5 by Deposition-precipitation: Study of Crystallinity, Specific Surface Area, and Morphology

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CO₂ Utilization Process Simulation for Enhancing Production of Dimethyl Ether (DME)