Double-Tube Reactor Design and Process Optimization for On-Site Steam Methane Reforming Processes

Lee, Jaewon; Cho, Hyungtae; Kim, Myung-Jun; Hall, Steve; Moon, Il

doi:10.1021/acs.iecr.0c02875

Cited by 33 publications

(13 citation statements)

References 27 publications

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“…Therefore, conversion of the most unreactive hydrocarbon of methane under mild reaction condition is quite challenging and remains one of the globally important agendas for the development of green society 1 . Industrially, methane is utilized in the catalytic steam reforming reaction (SRM, CH4 + H2O → CO + 3H2) at high temperatures and pressures (700-1100 °C and 20-40 atm) to produce synthesis gas, a feedstock for the production of various chemical products [1][2][3] . To overcome this energy-intensive process 1,4,5 and realize on-site and ondemand methane conversion technologies for sustainable methane utilization 3 , it is indispensable to develop an effective methane activation method at ambient temperatures and pressures.…”

Section: Introductionmentioning

confidence: 99%

Critical impacts of interfacial water on the photocatalytic C–H conversion of methane

Sato

Ishikawa

Saito

et al. 2022

Preprint

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On-site and on-demand photocatalytic methane conversion under mild conditions is one of the urgent global challenges for the sustainable use of ubiquitous methane resources. However, the lack of accurate knowledge of the reaction mechanism prevents the development of engineering strategies for methane photocatalysis. Combining real-time mass spectrometry and operando infrared absorption spectroscopy with ab initio molecular dynamics simulations, here we report key molecular-level insights into photocatalytic green utilization of methane. The photoactivated water dramatically promotes the activation of robust C–H bond of methane, and stabilizes the •CH3 intermediates in the interfacial hydrogen-bond network of water. Owing to the moderate stabilization of •CH3, the overall photocatalytic conversion rates are dramatically improved by typically more than 30 times at ambient temperatures (~300 K) and pressures (~1 atm). The increase in reaction activity is noticeable also in C1 to C2 evolution of methane, although water is not explicitly involved in the reaction equation (2CH4 → C2H6 + H2). These marked water-assisted effects in the interfacial chemistry should affect the basic understanding and the designing strategies on the non-thermal heterogeneous catalysis of methane under ambient conditions.

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Section: Introductionmentioning

confidence: 99%

Critical impacts of interfacial water on the photocatalytic C–H conversion of methane

Sato

Ishikawa

Saito

et al. 2022

Preprint

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“…Optimization is the process of determining the optimal solution of an objective function in the search space of a given system. − Multiobjective optimization problems (MOOPs) require multiple optimal solutions, which are not easy to find owing to their conflicting objectives. Although many solution methods have been developed to solve MOOPs, multiobjective evolutionary algorithms (MOEAs) are preferable because the algorithms can maintain the solutions that are well-distributed or diverse in population at each generation without any predefined values in objective functions .…”

Section: Methodsmentioning

confidence: 99%

Multiobjective Optimization of Plastic Waste Sorting and Recycling Processes Considering Economic Profit and CO₂ Emissions Using Nondominated Sorting Genetic Algorithm II

Lee

Lim

Joo

et al. 2022

ACS Sustainable Chem. Eng.

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Plastic waste has become a severe threat to the environment as increasing amounts of plastic waste are generated every year. To solve this problem, it is crucial to increase the recycling rate of plastic waste with proper sorting and recycling processes. However, sorting and recycling costs vary depending on the specific process, and CO 2 is inevitably generated during recycling. Therefore, this study developed a novel multiobjective optimization model based on mixed-integer nonlinear programming to optimize plastic waste sorting and recycling processes according to target polymer types while maximizing net profit and minimizing CO 2 emissions. Recycling solutions were proposed using a nondominated sorting genetic algorithm, which enabled the selection of a portfolio of plastic recycling methods for each plastic type depending on the importance of the two objectives: maximum net profit and minimum total CO 2 emissions. As a result, Pareto-optimal solutions with a net profit distribution of 35− 1936 million USD/year and CO 2 emissions of 9.7−17.0 kt/year were obtained. Furthermore, the Pareto-optimal front was analyzed to provide representative optimal solutions, which can provide decision makers with a wide range of choices when determining process specifications.

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“…28 The mass flow rate of LNG was determined based on the assumption that the SMR process has a thermal efficiency of 81.3% and a yield of 30.4%. 28 The LNG composition derived from a published study 27 is shown in Table 3. LNG was pressurized by pump-2, passed through the C. An additional valve was installed to expand the LNG to approximately the atmospheric pressure.…”

Section: Base Case Designmentioning

confidence: 99%

Comparative design, thermodynamic and techno‐economic analysis of utilizing liquefied natural gas cold energy for hydrogen liquefaction processes

Noh

Park

Kim

et al. 2022

Intl J of Energy Research

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Summary This study mainly focuses on determining the optimal configuration that efficiently utilizes liquefied natural gas (LNG) cold energy in hydrogen precooling for liquid hydrogen production. To achieve this goal, two different configurations are designed: (a) adding LNG cold energy to the existing hydrogen precooling cycle and (b) replacing the existing hydrogen precooling cycle with LNG cold energy. An equilibrium hydrogen model is developed to reflect the thermodynamic property of ortho‐para conversion of hydrogen. Bayesian optimization is performed to determine the optimal operating conditions which minimize the specific energy consumption for all configurations. The specific energy consumption of the configuration involving hydrogen precooling with only LNG is 5.613 kWh/kg‐LH2, and it is reduced by 8.13% and 3.19% from the base case design and the configuration involving hydrogen precooling with both LNG and a mixed refrigerant cycle, respectively. In addition, a techno‐economic analysis is conducted. Compare to the base case design, the capital cost and operating cost of the design replacing hydrogen precooling with LNG are reduced by 31.76% and 11.55%, respectively. This study shows that the proposed design of replacing the hydrogen precooling cycle with an LNG stream can save energy consumption, moreover, it is highly effective for capital investment saving due to its simple configuration.

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Double-Tube Reactor Design and Process Optimization for On-Site Steam Methane Reforming Processes

Cited by 33 publications

References 27 publications

Critical impacts of interfacial water on the photocatalytic C–H conversion of methane

Critical impacts of interfacial water on the photocatalytic C–H conversion of methane

Multiobjective Optimization of Plastic Waste Sorting and Recycling Processes Considering Economic Profit and CO₂ Emissions Using Nondominated Sorting Genetic Algorithm II

Comparative design, thermodynamic and techno‐economic analysis of utilizing liquefied natural gas cold energy for hydrogen liquefaction processes

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Double-Tube Reactor Design and Process Optimization for On-Site Steam Methane Reforming Processes

Cited by 33 publications

References 27 publications

Critical impacts of interfacial water on the photocatalytic C–H conversion of methane

Critical impacts of interfacial water on the photocatalytic C–H conversion of methane

Multiobjective Optimization of Plastic Waste Sorting and Recycling Processes Considering Economic Profit and CO2 Emissions Using Nondominated Sorting Genetic Algorithm II

Comparative design, thermodynamic and techno‐economic analysis of utilizing liquefied natural gas cold energy for hydrogen liquefaction processes

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Product

Resources

About

Multiobjective Optimization of Plastic Waste Sorting and Recycling Processes Considering Economic Profit and CO₂ Emissions Using Nondominated Sorting Genetic Algorithm II