Search results for "exergy efficiency"

showing 3 items of 13 documents

Towards the first proof of the concept of a Reverse ElectroDialysis - Membrane Distillation Heat Engine

2019

Abstract The coupling of Reverse Electrodialysis with Membrane Distillation is a promising option for the conversion of waste heat into electricity. This study evaluates the performances of the integrated system under different operating conditions, employing validated model and correlations. This work provides a detailed description of the behaviour of a real RED-MD heat engine and indicates the set of inlet concentrations, velocities and equipment size which returns the highest cycle exergy efficiency. These operating conditions were selected for the pilot plant developed within the EU-funded project RED Heat to Power. For the first time, a perspective analysis was also included, consider…

Work (thermodynamics)020209 energyGeneral Chemical EngineeringReverse Electrodialysis Heat EngineMembrane distillation02 engineering and technologyMembrane distillation7. Clean energyWaste heat recovery unitReversed electrodialysisWaste heatReverse electrodialysi0202 electrical engineering electronic engineering information engineeringOsmotic powerGeneral Materials ScienceChemical Engineering (all)Process engineeringSalinity Gradient PowerWaste heat recoveryHeat engineWater Science and Technologybusiness.industryMechanical EngineeringChemistry (all)General Chemistry021001 nanoscience & nanotechnology6. Clean waterReverse ElectroDialysisExergy efficiencyEnvironmental scienceMaterials Science (all)0210 nano-technologybusiness
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Thermolytic reverse electrodialysis heat engine: model development, integration and performance analysis

2019

Abstract Salinity gradient heat engines represent an innovative and promising way to convert low-grade heat into electricity by employing salinity gradient technology in a closed-loop configuration. Among the aqueous solutions which can be used as working fluid, ammonium bicarbonate-water solutions appear very promising due to their capability to decompose at low temperature. In this work, an experimentally validated model for a reverse electrodialysis heat engine fed with ammonium bicarbonate-water solutions was developed. The model consists of two validated sub-models purposely integrated, one for the reverse electrodialysis unit and the other for the stripping/absorption regeneration uni…

Work (thermodynamics)Absorption (acoustics)Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciMaterials science020209 energySettore ING-IND/25 - Impianti ChimiciEnergy Engineering and Power Technology02 engineering and technology7. Clean energyStripping (fiber)020401 chemical engineeringReversed electrodialysis0202 electrical engineering electronic engineering information engineering0204 chemical engineeringProcess engineeringHeat engineThermolytic salts Salinity gradient heat engine Regeneration unit Reverse electrodialysis Ammonium bicarbonate solutions Waste heat recoveryRenewable Energy Sustainability and the Environmentbusiness.industry6. Clean waterFuel TechnologyMembraneNuclear Energy and EngineeringExergy efficiencyWorking fluidbusinessEnergy Conversion and Management
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Regeneration units for thermolytic salts applications in water & power production: State of the art, experimental and modelling assessment

2021

Abstract Thermolytic solutions are often proposed as high salinity or “draw” stream to generate a chemical potential driving force in Salinity Gradient Power (SGP) and Forward Osmosis (FO) technologies. Depleted “draw” solutions exiting the process can be regenerated by a thermal process powered at very-low grade heat, which is able to decompose the salt into gaseous ammonia and carbon dioxide, which can be stripped and then reabsorbed in the draw solution, restoring its initial concentration. In this work, two different experimental prototypes for the regeneration of ammonium bicarbonate aqueous solution were designed, built and tested. The effect of several operating parameters on the reg…

Work (thermodynamics)Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciGeneral Chemical EngineeringForward osmosis02 engineering and technologychemistry.chemical_compound020401 chemical engineeringOsmotic powerGeneral Materials Science0204 chemical engineeringProcess simulationProcess engineeringWater Science and TechnologyHeat enginebusiness.industryMechanical EngineeringHCO3NH4 Osmotic heat engine Heat-to-power RED-HE OHE.General Chemistry021001 nanoscience & nanotechnologyAmmonium bicarbonatechemistryScientific methodExergy efficiencyEnvironmental science0210 nano-technologybusiness
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