Comparison of three arrangements of internal combustion engine-driven energy systems boosted with PEM fuel cell towards net-zero energy systems

[1]  G. Smaisim,et al.  Joint chance-constrained multi-objective optimal function of multi-energy microgrid containing energy storages and carbon recycling system , 2022, Journal of Energy Storage.

[2]  D. Toghraie,et al.  The numerical analysis of the melting process in a modified shell-and-tube phase change material heat storage system , 2022, Journal of Energy Storage.

[3]  A. M. Abed,et al.  Economic cost and efficiency analysis of a lithium-ion battery pack with the circular and elliptical cavities filled with phase change materials , 2022, Journal of Energy Storage.

[4]  Moram A. Fagiry,et al.  Impact of phase change material-based heatsinks on lithium-ion battery thermal management: A comprehensive review , 2022, Journal of Energy Storage.

[5]  I. Mansir Investigation of heat transfer, melting and solidification of phase change material in battery thermal management system based on blades height , 2022, Journal of Energy Storage.

[6]  C. Depcik,et al.  Review of thermoelectric generation for internal combustion engine waste heat recovery , 2022, Progress in Energy and Combustion Science.

[7]  A. M. Abed,et al.  Simulation of solar thermal panel systems with nanofluid flow and PCM for energy consumption management of buildings , 2022, Journal of Building Engineering.

[8]  D. Toghraie,et al.  Numerical study of anomalous heat conduction in absorber plate of a solar collector using time-fractional single-phase-lag model , 2022, Case Studies in Thermal Engineering.

[9]  G. Smaisim,et al.  Synthesis of Biodiesel from Fish Processing Waste by Nano Magnetic Catalyst and its Thermodynamic Analysis , 2022, SSRN Electronic Journal.

[10]  I. Mansir,et al.  Comparative transient simulation of a renewable energy system with hydrogen and battery energy storage for residential applications , 2022, International Journal of Hydrogen Energy.

[11]  M. Asadi,et al.  Comparing the profitability of waste heat electricity generation of internal combustion engines: an exergoeconomic analysis through optimization of two different Organic Rankine Cycle scenarios , 2022, Applied Thermal Engineering.

[12]  P. Ahmadi,et al.  Soft computing based optimization of a novel solar heliostat integrated energy system using artificial neural networks , 2022, Sustainable Energy Technologies and Assessments.

[13]  I. Mansir,et al.  Dynamic simulation of hydrogen-based zero energy buildings with hydrogen energy storage for various climate conditions , 2022, International Journal of Hydrogen Energy.

[14]  Xinxing Lin,et al.  Performances of Transcritical Power Cycles with CO2-Based Mixtures for the Waste Heat Recovery of ICE , 2021, Entropy.

[15]  Yan Cao,et al.  Design analysis and tri-objective optimization of a novel integrated energy system based on two methods for hydrogen production: By using power or waste heat , 2021, International Journal of Hydrogen Energy.

[16]  F. Musharavati,et al.  Multi-objective optimization of a biomass gasification to generate electricity and desalinated water using Grey Wolf Optimizer and artificial neural network. , 2021, Chemosphere.

[17]  Recep Yumrutaş,et al.  Optimisation of simple and regenerative organic Rankine cycles using jacket water of an internal combustion engine fuelled with biogas produced from agricultural waste , 2021, Process Safety and Environmental Protection.

[18]  F. Musharavati,et al.  Multi-generation energy system based on geothermal source to produce power, cooling, heating, and fresh water: Exergoeconomic analysis and optimum selection by LINMAP method , 2021 .

[19]  F. Musharavati,et al.  Proposed a new geothermal based poly-generation energy system including Kalina cycle, reverse osmosis desalination, elecrolyzer amplified with thermoelectric: 3E analysis and optimization , 2021 .

[20]  D. D. Battista,et al.  An improvement to waste heat recovery in internal combustion engines via combined technologies , 2021 .

[21]  Lan Xia,et al.  Design and optimization of hydrogen production by solid oxide electrolyzer with marine engine waste heat recovery and ORC cycle , 2021 .

[22]  Sadegh Hasanpour Omam,et al.  Exhaust waste energy recovery using Otto-ATEG-Stirling engine combined cycle , 2021, Applied Thermal Engineering.

[23]  Behnam Sobhani,et al.  Exergoeconomic analysis and optimization of a hybrid Kalina and humidification-dehumidification system for waste heat recovery of low-temperature Diesel engine , 2020, Desalination.

[24]  M. Afrand,et al.  Development, evaluation, and multi-objective optimization of a multi-effect desalination unit integrated with a gas turbine plant , 2020 .

[25]  D. D. Battista,et al.  Integrated evaluation of Inverted Brayton cycle recovery unit bottomed to a turbocharged diesel engine , 2020 .

[26]  A. Baccioli,et al.  Techno-economic analysis of combined inverted Brayton – Organic Rankine cycle for high-temperature waste heat recovery , 2020, Energy Conversion and Management.

[27]  Jun Li,et al.  Proposal and assessment of a combined cooling and power system based on the regenerative supercritical carbon dioxide Brayton cycle integrated with an absorption refrigeration cycle for engine waste heat recovery , 2020 .

[28]  L. Gosselin,et al.  Maximizing specific work output extracted from engine exhaust with novel inverted Brayton cycles over a large range of operating conditions , 2020, Energy.

[29]  G. Shu,et al.  How to approach optimal practical Organic Rankine cycle (OP-ORC) by configuration modification for diesel engine waste heat recovery , 2019, Energy.

[30]  F. Mohammadkhani,et al.  A 0D model for diesel engine simulation and employing a transcritical dual loop Organic Rankine Cycle (ORC) for waste heat recovery from its exhaust and coolant: Thermodynamic and economic analysis , 2019, Applied Thermal Engineering.

[31]  H. Bedir,et al.  Optimization and application of Stirling engine for waste heat recovery from a heavy-duty truck engine , 2019, Energy Conversion and Management.

[32]  Ehsan Amiri Rad,et al.  Introducing a novel optimized Dual Fuel Gas Turbine (DFGT) based on a 4E objective function , 2019, Journal of Cleaner Production.

[33]  K. Atashkari,et al.  Modeling and multi-objective optimization of a novel biomass feed polygeneration system integrated with multi effect desalination unit , 2018, Thermal Science and Engineering Progress.

[34]  Saeed Javan,et al.  Exergy-based optimization of an organic Rankine cycle (ORC) for waste heat recovery from an internal combustion engine (ICE) , 2017 .

[35]  Rodolfo Taccani,et al.  A review of waste heat recovery and Organic Rankine Cycles (ORC) in on-off highway vehicle Heavy Duty Diesel Engine applications , 2017 .

[36]  Meng Li,et al.  Historical (1750–2014) anthropogenic emissions of reactive gases and aerosols from the Community Emissions Data System (CEDS) , 2017 .

[37]  Oluwamayowa O. Amusat,et al.  Optimal integrated energy systems design incorporating variable renewable energy sources , 2016, Comput. Chem. Eng..

[38]  Simon Peyton Jones,et al.  Modelling and simulation of an inverted Brayton cycle as an exhaust-gas heat-recovery system , 2016 .

[39]  R. Chiriac,et al.  On the possibility to reduce CO2 emissions of heat engines fuelled partially with hydrogen produced by waste heat recovery , 2015 .

[40]  Colin Copeland,et al.  The Benefits of an Inverted Brayton Bottoming Cycle as an Alternative to Turbocompounding , 2015 .

[41]  Scott A. Miers,et al.  Review of Waste Heat Recovery Mechanisms for Internal Combustion Engines , 2014 .

[42]  L. Lu,et al.  Energy Analysis for Hydrogen Generation with the Waste Heat of Internal Combustion Engine , 2012 .

[43]  Gequn Shu,et al.  A review of researches on thermal exhaust heat recovery with Rankine cycle , 2011 .

[44]  Henrik Lund,et al.  Integrated energy systems and local energy markets , 2006 .

[45]  S. Thahab,et al.  The Heat Transfer from Fined Perforated Pipe Improved due to Nano-Fluid , 2021 .

[46]  Sara Walker,et al.  An integrated energy system , 2018 .