Feasibility of CaO/CuO/NiO sorption-enhanced steam methane reforming integrated with solid-oxide fuel cell for near-zero-CO2 emissions cogeneration system

Hanak, Dawid P.; Mancusi, Erasmo; Pepe, Francesco; Montagnaro, Fabio; Manović, Vasilije

doi:10.1016/j.apenergy.2018.08.118

Cited by 26 publications

(10 citation statements)

References 69 publications

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“…However, it should be noted that, depending on the type of catalyst, feed gas composition, and operating conditions, carbon deposition on the supported catalyst can occur (according to Boudouard reaction 2CO C+CO 2 ); to avoid solid carbon formation, the temperature should be kept high or CO 2 and/or H 2 O has to be added to the feed (e.g. [16]). Under the current assumption that H 2 and CO 2 are stoichiometrically fed to the methanation unit, no carbon deposition occurs.…”

Section: Resultsmentioning

confidence: 99%

Feasibility analysis of a combined chemical looping combustion and renewable-energy-based methane production system for CO2 capture and utilization

et al. 2020

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Power-to-Methane represents an innovative approach to convert electrical into chemical energy. Such a technology could actually be successful only when the coupling of a cost-effective source of electrical energy and a pure CO2 stream is carried out. Under this perspective, this paper numerically investigates an innovative process layout that integrates a fluidized beds chemical looping system for the combustion of solid fuels and a renewable- based Power-to-Methane system. Process performances were evaluated by considering a coal and three sewage sludge, differing in water content, as fuels, CuO supported on zirconia as oxygen carrier, hydrogen production via water electrolysis, and Ni supported on alumina as methanation catalyst. Autothermal feasibility of the process was assessed by considering that part of the produced methane can eventually be burned to dry high-moisture-content fuels. Finally, by considering that only electric energy from renewable sources is used, the capability of the proposed process to be used as an energy storage system was evaluated.

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Section: Resultsmentioning

confidence: 99%

Feasibility analysis of a combined chemical looping combustion and renewable-energy-based methane production system for CO2 capture and utilization

et al. 2020

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“…where TCC are the total capital costs of the reactor network, FCF is the fixed charged factor, FOM are the fixed operating and maintenance costs, CF is the capacity factor of the plant, set at 0.85, [34,37] 8760 is the average number of hours in a year, VOM are the variable operating and maintenance costs, and SFC is the specific fuel cost, set equal to 19.1 € MW À1 h À1 (5.3 € GJ À1 ). [38] TCC was assessed by estimating the costs of the main components of the reactor network. FCF was estimated as…”

Section: Economic Analysismentioning

confidence: 99%

“…The reference cost of the inert material was instead set at 1000 € ton À1 . [38] The cost of the compressors was estimated as [39] C comp ½$ ¼ 39.5W comp 0. where W comp is the mass flow rate of the stream fed to the compressor, η comp is the efficiency of the compressor, and p out,comp and p in,comp are the outlet and inlet pressure of the compressor, respectively. The capital cost of the compressor was updated to present value by referring to the chemical engineering plant cost index for the year 2019.…”

Section: Economic Analysismentioning

confidence: 99%

Technoeconomic Analysis of a Fixed Bed System for Single/Two–Stage Chemical Looping Combustion

et al. 2021

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Chemical looping combustion (CLC) is a promising carbon capture technology allowing integration with high-efficiency Brayton cycles for energy production and yielding a concentrated CO 2 stream without requiring air separation units. Recently, dynamically operated fixed bed reactors have been proposed and investigated for CLC. This study deals with the technoeconomic assessment of a CLC process performed in packed beds. Following a previously published work on the topic, two different configurations are considered: one relying on a single oxygen carrier (Cu/CuO based) and the other on two in-series oxygen carriers (Cu/CuO based first, Ni/NiO based later). For both configurations, relevant process schemes are devised to obtain continuous power generation. Despite slightly larger capital costs, two-stage CLC performs better in terms of efficiency, levelized cost of electricity, and avoided CO 2 costs. Fuel price and high-temperature valves costs are identified as the main variables influencing the economic performance. The use of two in-parallel packed bed reactors (2.0 m length, 0.7 m internal diameter) enables a power output of 386 kW e , a net electric efficiency of 37.2%, a levelized cost of electricity of 91 € MWh e À1 , and avoided CO 2 costs of 55 € ton CO2À1 with respect to a reference pulverized coal power plant.

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“…Therefore, about 32 Gt of CO 2 was released to the atmosphere. As the global energy demand is growing, it is expected that the CO 2 emissions will increase to about 48 Gt/year by 2040. , Hence, major efforts are needed to meet the emissions reduction targets. In this context, “hydrogen economy” has been acknowledged as an emission-free technology.…”

Section: Introductionmentioning

confidence: 99%

Embedding Ni in Ni–Al Mixed-Metal Alkoxide for the Synthesis of Efficient Coking Resistant Ni–CaO-Based Catalyst-Sorbent Bifunctional Materials for Sorption-Enhanced Steam Reforming of Glycerol

Yancheshmeh

Iliuta

2020

ACS Sustainable Chem. Eng.

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The sorption-enhanced steam reforming of glycerol (SESRG) is a sustainable approach to produce high-purity hydrogen in a single step by valorizing waste raw material. Fabricating Ni–CaO-based catalyst-sorbent bifunctional materials with highly dispersed Ni active sites is vital in suppressing coke formation during this process. While embedding Ni in the spinel structure of NiAl2O4 can provide a high distribution of Ni active sites, it can prevent an intimate contact between Ni, Al, and Ca species and adversely affect the efficiency of the SESRG process for high-purity hydrogen production. Due to the easiness to react in protic reagents and provide uniform distribution of metals, Ni–Al mixed-metal alkoxides can act as potential alternatives to NiAl2O4 to provide both the high distribution of Ni active sites and the close contact between Ni, Al, and Ca species. Herein, we developed two new Ni–CaO-based bifunctional materials, by adding the NiAl2O4 and Ni–Al mixed-metal alkoxide synthesized through a solvothermal approach during the treatment of the limestone-derived CaO sorbent with ethanol/water solution, to investigate the effects of using these kinds of Ni-containing structures on the development of coke-resistant efficient materials for SESRG. Testing the developed materials in 10 SESRG/regeneration cycles revealed that using Ni–Al mixed-metal alkoxide during the synthesis of Ca3Al2O6–CaO/NiO–CeO2 led to a higher hydrogen purity (96.30 vs 90.18%) and stability than using NiAl2O4 during the synthesis of NiAl2O4–CaO/NiAl2O4–CeO2. This indicates a more efficient coupling of reforming reaction and CO2 capture over Ca3Al2O6–CaO/NiO–CeO2 due to a far better distribution of active Ni and CaO sites. Almost no carbon deposits were detected on the materials surface after the reaction, attributed to the uniform distribution of small Ni particles achieved by using Ni–Al mixed-metal alkoxide and NiAl2O4 during the synthesis. These results confirm that using Ni–Al mixed-metal alkoxide in alternative to NiAl2O4 during the synthesis of Ni–CaO-based bifunctional materials can guarantee a more efficient coke-resistant material for the SESRG process by providing both the high distribution of small Ni particles and the intimate contact between active Ni and CaO sites.

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Feasibility of CaO/CuO/NiO sorption-enhanced steam methane reforming integrated with solid-oxide fuel cell for near-zero-CO2 emissions cogeneration system

Cited by 26 publications

References 69 publications

Feasibility analysis of a combined chemical looping combustion and renewable-energy-based methane production system for CO2 capture and utilization

Feasibility analysis of a combined chemical looping combustion and renewable-energy-based methane production system for CO2 capture and utilization

Technoeconomic Analysis of a Fixed Bed System for Single/Two–Stage Chemical Looping Combustion

Embedding Ni in Ni–Al Mixed-Metal Alkoxide for the Synthesis of Efficient Coking Resistant Ni–CaO-Based Catalyst-Sorbent Bifunctional Materials for Sorption-Enhanced Steam Reforming of Glycerol

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