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Investigation of an integrated hydrogen production system based on nuclear and renewable energy sources: a new approach for sustainable hydrogen production via copper-chlorine thermochemical cycles
(2011-10)
Hydrogen production via thermochemical water decomposition is a potential process for direct utilization of nuclear thermal energy to increase efficiency and thereby facilitate energy savings. Thermochemical water splitting ...
An exergy-cost-energy-mass analysis of a hybrid copper-chlorine thermochemical cycle for hydrogen production
(2010-05)
An exergoeconomic assessment using exergy-cost-energy-mass (EXCEM) analysis is reported of a copper-chlorine (Cu-Cl) thermochemical water splitting cycle for hydrogen production. The quantitative relation is identified ...
Process simulation and analysis of a five-step copper-chlorine thermochemical water decomposition cycle for sustainable hydrogen production
(2014-01)
A process model of a five-step copper–chlorine (Cu–Cl) cycle is developed and simulated with the Aspen Plus simulation code. Energy and mass balances, stream flows and properties, heat exchanger duties, and shaft work are ...
Design and simulation of a UOIT copper-chlorine cycle for hydrogen production
(Wiley, 2013-08)
A design and simulation study of the four-step copper–chlorine (Cu–Cl) cycle using Aspen Plus software (Aspen Technology Inc., Cambridge, MA)is reported. The simulation consists of four main sections: hydrolysis, ...
Integrated hydrogen production options based on renewable and nuclear energy sources
(2012-10)
Due to varied global challenges, potential energy solutions are needed to reduce environmental impact and improve sustainability. Many of the renewable energy resources are of limited applicability due to their reliability, ...
Exergy analysis of heat exchangers in the copper-chlorine thermochemical cycle to enhance thermal effectiveness and cycle efficiency
(2011-08)
Most existing nuclear power plants in North America are typically water-cooled and operate at 250–5008C. For this temperature level, the copper–chlorine (Cu–Cl) cycle is one of the most promisingcycles that can be integrated ...
Coupling of copper-chloride hybrid thermochemical water splitting cycle with a desalination plant for hydrogen production from nuclear energy
(2010-02)
Energy and environmental concerns have motivated research on clean energy resources. Nuclear energy has the potential to provide a significant share of energy supply without contributing to environmental emissions and ...
Efficiency comparison of various design schemes for copper-chlorine (Cu-Cl) hydrogen production processes using Aspen Plus software
(2012-11)
In this study, simulation models are developed to analyze, design and optimize the Cu–Cl cycles using the Aspen PlusTM chemical process simulation package. Energy, exergy and yield effectiveness of the process, based on ...
Design of systems for hydrogen production based on the Cu-Cl thermochemical water decomposition cycle: Configurations and performance
(2011-08)
In this study, we analyze several Cu-Cl cycles by examining various design schemes for an overall system and its components, in order to identify potential performance improvements. The factors that determine the number ...
Exergy analysis of heat exchangers in the copper–chlorine thermochemical cycle to enhance thermal effectiveness and cycle efficiency
(Oxford University Press, 2011)
Most existing nuclear power plants in North America are typically water-cooled and operate at 250–500°C. For this temperature level, the copper–chlorine (Cu–Cl) cycle is one of the most promising cycles that can be integrated ...