Investigation of an integrated solar thermochemical plant for hydrogen production using high-temperature molten salt

Abstract One of the most promising methods for producing hydrogen is the use of a water splitting process utilising the copper-chlorine (Cu-Cl) thermochemical cycle. The Cu-Cl cycle uses heat and electricity to produce hydrogen and oxygen from the decomposition of water molecules. In this paper, a n...

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Published in	IOP conference series. Materials Science and Engineering Vol. 1067; no. 1; p. 12100
Main Authors	Sadeghi, S, Ghandehariun, S
Format	Journal Article
Language	English
Published	Bristol IOP Publishing 01.02.2021
Subjects	Chlorine Copper Cost analysis Economic analysis Electricity Energy storage Heat Heat exchangers High temperature Hydrogen Hydrogen production Molten salts Optimization Production costs Production methods Rankine cycle Solar energy Thermal energy Thermodynamic efficiency Water chemistry Water splitting
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Abstract	Abstract One of the most promising methods for producing hydrogen is the use of a water splitting process utilising the copper-chlorine (Cu-Cl) thermochemical cycle. The Cu-Cl cycle uses heat and electricity to produce hydrogen and oxygen from the decomposition of water molecules. In this paper, a new solar-powered integrated system is proposed which utilises (LiNaK) 2 CO 3 high-temperature carbonate molten salt as both a heat transfer fluid and a thermal energy storage medium to provide the required heat for the Cu-Cl cycle reactors and heat exchangers. The system is integrated with a supercritical regenerative steam Rankine cycle (SRC) which produces the required electricity for the electrolyser unit. Thermodynamic and economic analyses were conducted to evaluate the proposed system in terms of hydrogen production cost and system performance. For the base case, the integrated system was found to be capable of producing 823.71 kg/h of hydrogen. The system is optimised for two objective parameters, overall system thermal efficiency and the levelized cost of hydrogen. The results of optimisation analysis indicated that, for the optimal Pareto solution, the overall system thermal efficiency and levelized cost of hydrogen were 29.17%, and $7.58/kg of H 2 , respectively.
AbstractList	One of the most promising methods for producing hydrogen is the use of a water splitting process utilising the copper-chlorine (Cu-Cl) thermochemical cycle. The Cu-Cl cycle uses heat and electricity to produce hydrogen and oxygen from the decomposition of water molecules. In this paper, a new solar-powered integrated system is proposed which utilises (LiNaK)2CO3 high-temperature carbonate molten salt as both a heat transfer fluid and a thermal energy storage medium to provide the required heat for the Cu-Cl cycle reactors and heat exchangers. The system is integrated with a supercritical regenerative steam Rankine cycle (SRC) which produces the required electricity for the electrolyser unit. Thermodynamic and economic analyses were conducted to evaluate the proposed system in terms of hydrogen production cost and system performance. For the base case, the integrated system was found to be capable of producing 823.71 kg/h of hydrogen. The system is optimised for two objective parameters, overall system thermal efficiency and the levelized cost of hydrogen. The results of optimisation analysis indicated that, for the optimal Pareto solution, the overall system thermal efficiency and levelized cost of hydrogen were 29.17%, and $7.58/kg of H2, respectively. Abstract One of the most promising methods for producing hydrogen is the use of a water splitting process utilising the copper-chlorine (Cu-Cl) thermochemical cycle. The Cu-Cl cycle uses heat and electricity to produce hydrogen and oxygen from the decomposition of water molecules. In this paper, a new solar-powered integrated system is proposed which utilises (LiNaK) 2 CO 3 high-temperature carbonate molten salt as both a heat transfer fluid and a thermal energy storage medium to provide the required heat for the Cu-Cl cycle reactors and heat exchangers. The system is integrated with a supercritical regenerative steam Rankine cycle (SRC) which produces the required electricity for the electrolyser unit. Thermodynamic and economic analyses were conducted to evaluate the proposed system in terms of hydrogen production cost and system performance. For the base case, the integrated system was found to be capable of producing 823.71 kg/h of hydrogen. The system is optimised for two objective parameters, overall system thermal efficiency and the levelized cost of hydrogen. The results of optimisation analysis indicated that, for the optimal Pareto solution, the overall system thermal efficiency and levelized cost of hydrogen were 29.17%, and $7.58/kg of H 2 , respectively.
Author	Sadeghi, S Ghandehariun, S
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References	Sadeghi (MSE_1067_1_012100bib14) 2020 Sadeghi (MSE_1067_1_012100bib20) 2020; 225C Ghandehariun (MSE_1067_1_012100bib10) 2012; 229 Thomas (MSE_1067_1_012100bib1) 2020; 51 Pinsky (MSE_1067_1_012100bib11) 2020; 123 Sadeghi (MSE_1067_1_012100bib3) 2020; 208 Fernández (MSE_1067_1_012100bib13) 2019; 140 Borgnakke (MSE_1067_1_012100bib18) 2019 Vignarooban (MSE_1067_1_012100bib16) 2015; 146 Ghandehariun (MSE_1067_1_012100bib6) 2015; 157 Serrano-López (MSE_1067_1_012100bib15) 2013; 73 Bejan (MSE_1067_1_012100bib19) 1995 Ghandehariun (MSE_1067_1_012100bib12) 2010; 35 Rabbani (MSE_1067_1_012100bib7) 2012; 37 Alamdari (MSE_1067_1_012100bib21) 2013; 21 Ghandehariun (MSE_1067_1_012100bib5) 2013 Liu (MSE_1067_1_012100bib4) 2019; 1 Pivovar (MSE_1067_1_012100bib2) 2018; 27 Khalid (MSE_1067_1_012100bib9) 2018; 43 Razi (MSE_1067_1_012100bib8) 2020; 29 Sadeghi (MSE_1067_1_012100bib17) 2020
References_xml	– volume: 123 year: 2020 ident: MSE_1067_1_012100bib11 publication-title: Comparative review of hydrogen production technologies for nuclear hybrid energy systems contributor: fullname: Pinsky – volume: 29 year: 2020 ident: MSE_1067_1_012100bib8 publication-title: Energy and exergy analyses of a new integrated thermochemical copper-chlorine cycle for hydrogen production contributor: fullname: Razi – volume: 146 start-page: 383 year: 2015 ident: MSE_1067_1_012100bib16 publication-title: Heat transfer fluids for concentrating solar power systems-a review contributor: fullname: Vignarooban – volume: 37 start-page: 11021 year: 2012 ident: MSE_1067_1_012100bib7 article-title: Determining parameters of heat exchangers for heat recovery in a Cu-Cl thermochemical hydrogen production cycle publication-title: International Journal of Hydrogen Energy doi: 10.1016/j.ijhydene.2012.05.004 contributor: fullname: Rabbani – volume: 35 start-page: 8511 year: 2010 ident: MSE_1067_1_012100bib12 article-title: Solar thermochemical plant analysis for hydrogen production with the copper-chlorine cycle publication-title: International Journal of Hydrogen Energy doi: 10.1016/j.ijhydene.2010.05.028 contributor: fullname: Ghandehariun – volume: 208 year: 2020 ident: MSE_1067_1_012100bib3 publication-title: Comparative economic and life cycle assessment of solar-based hydrogen production for oil and gas industries contributor: fullname: Sadeghi – volume: 157 start-page: 267 year: 2015 ident: MSE_1067_1_012100bib6 publication-title: Experimental investigation of molten salt droplet quenching and solidification processes of heat recovery in thermochemical hydrogen production contributor: fullname: Ghandehariun – start-page: 1 year: 2013 ident: MSE_1067_1_012100bib5 contributor: fullname: Ghandehariun – volume: 1 year: 2019 ident: MSE_1067_1_012100bib4 publication-title: Research advances towards large-scale solar hydrogen production from water contributor: fullname: Liu – volume: 229 start-page: 48 year: 2012 ident: MSE_1067_1_012100bib10 article-title: Reduction of hazards from copper (I) chloride in a Cu-Cl thermochemical hydrogen production plant publication-title: Journal of Hazardous Materials doi: 10.1016/j.jhazmat.2012.05.057 contributor: fullname: Ghandehariun – volume: 73 start-page: 87 year: 2013 ident: MSE_1067_1_012100bib15 publication-title: Molten salts database for energy applications contributor: fullname: Serrano-López – year: 2020 ident: MSE_1067_1_012100bib14 contributor: fullname: Sadeghi – year: 2019 ident: MSE_1067_1_012100bib18 contributor: fullname: Borgnakke – volume: 51 start-page: 405 year: 2020 ident: MSE_1067_1_012100bib1 publication-title: Decarbonising energy: The developing international activity in hydrogen technologies and fuel cells contributor: fullname: Thomas – year: 2020 ident: MSE_1067_1_012100bib17 contributor: fullname: Sadeghi – volume: 225C year: 2020 ident: MSE_1067_1_012100bib20 publication-title: Exergoeconomic and Multi-objective Optimization of a Solar Thermochemical Hydrogen Production Plant with Heat Recovery contributor: fullname: Sadeghi – volume: 21 start-page: 778 year: 2013 ident: MSE_1067_1_012100bib21 publication-title: Solar energy potentials in Iran: A review contributor: fullname: Alamdari – volume: 27 start-page: 47 year: 2018 ident: MSE_1067_1_012100bib2 publication-title: Hydrogen at scale (H2@ scale): key to a clean, economic, and sustainable energy system contributor: fullname: Pivovar – volume: 43 start-page: 18783 year: 2018 ident: MSE_1067_1_012100bib9 article-title: Thermodynamic viability of a new three step high temperature Cu-Cl cycle for hydrogen production publication-title: International Journal of Hydrogen Energy doi: 10.1016/j.ijhydene.2018.08.093 contributor: fullname: Khalid – volume: 140 start-page: 152 year: 2019 ident: MSE_1067_1_012100bib13 publication-title: Mainstreaming commercial CSP systems: A technology review contributor: fullname: Fernández – year: 1995 ident: MSE_1067_1_012100bib19 contributor: fullname: Bejan
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Snippet	Abstract One of the most promising methods for producing hydrogen is the use of a water splitting process utilising the copper-chlorine (Cu-Cl) thermochemical... One of the most promising methods for producing hydrogen is the use of a water splitting process utilising the copper-chlorine (Cu-Cl) thermochemical cycle....
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SubjectTerms	Chlorine Copper Cost analysis Economic analysis Electricity Energy storage Heat Heat exchangers High temperature Hydrogen Hydrogen production Molten salts Optimization Production costs Production methods Rankine cycle Solar energy Thermal energy Thermodynamic efficiency Water chemistry Water splitting
Title	Investigation of an integrated solar thermochemical plant for hydrogen production using high-temperature molten salt
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