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Comparative techno-economic and environmental analysis of a new CO2 to diethyl carbonate production process

Thuy Thi Nguyen, Wahyu S. Putro, Satoshi Hamura, Makoto Nakashige, Jun‐Chul Choi, Norihisa Fukaya, Satoshi Taniguchi, Takehiro Yamaki, Nobuo Hara, Sho Kataoka

2023Journal of Cleaner Production10 citationsDOIOpen Access PDF

Abstract

Direct conversion of CO2 to dialkyl carbonates such as diethyl carbonate (DEC) can contribute to mitigate CO2 emissions. We previously proposed a new DEC synthesis method from the reaction of CO2 and tetraethoxysilane (TEOS), an expensive functional chemical. After being used for DEC synthesis, TEOS can be regenerated from reaction of ethanol and hexaethoxy disiloxane (DS), the byproduct produced along with DEC. However, TEOS regeneration requires several processing units and high energy demand. In this study, we designed and evaluated feasibility of this new DEC synthesis process. Based on data obtained from lab experiments, the entire process, which comprised DEC synthesis and TEOS regeneration sections, was designed and optimized using process simulator Pro/II. Cradle-to-gate life cycle assessment method was applied to comprehensively evaluate the total CO2 emissions caused by the consumption of raw materials and utilities in DEC synthesis and TEOS regeneration sections. In addition, the total production cost was evaluated. On the basis of the evaluation results, process hotspots were identified. Optimal conditions used for TEOS regeneration (ethanol/DS = 18.2) were proposed to improve total process performances. The total production cost and CO2 emissions are 1.7 $/kg DEC, 3.6 kg CO2/kg DEC, respectively. The new process was compared to the most commonly used process which synthesizes DEC from the reaction of CO2 with ethanol, assisted by the dehydrating agent 2-cyanopyridine. Our results show that the new DEC synthesis process gains higher economic and environmental viability.

Topics & Concepts

Raw materialDiethyl carbonateProcess (computing)Process engineeringProduction (economics)Environmental scienceLife-cycle assessmentCarbonateWaste managementPulp and paper industryEngineeringChemistryComputer scienceOrganic chemistryOperating systemEthylene carbonatePhysical chemistryElectrodeMacroeconomicsEconomicsElectrolyteCarbon dioxide utilization in catalysisCarbon Dioxide Capture TechnologiesCO2 Reduction Techniques and Catalysts