Search results for "Waste heat recovery unit"

showing 7 items of 7 documents

Concepts for medium-high to high temperature thermoelectric heat-to-electricity conversion: a review of selected materials and basic considerations o…

2015

Within the last decade, novel materials concepts and nanotechnology have resulted in a great increase of the conversion efficiency of thermoelectric materials. Despite this, a mass market for thermoelectric heat-to-electricity conversion is yet to be opened up. One reason for this is that the transfer of the lab records into fabrication techniques which enable thermoelectric generator modules is very challenging. By closing the gap between record lab values and modules, broad industrial applications may become feasible. In this review, we compare three classes of materials, all designed for medium-high to high temperature applications in the field of waste heat recovery: skutterudites, half…

FabricationMaterials sciencebusiness.industryEnergy conversion efficiencyMechanical engineeringThermoelectric materialsWaste heat recovery unitThermoelectric generatorThermoelectric effectSustainable designElectricitybusinessProcess engineeringElektrotechnikTranslational Materials Research
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Methods for Enhancing the Thermal Durability of High-Temperature Thermoelectric Materials

2013

Author's version of an article in the journal: Journal of Electronic Materials. Also available from the publisher at: http://dx.doi.org/10.1007/s11664-013-2917-0 Thermoelectric materials, for example skutterudites and magnesium silicides, are being investigated as promising materials for medium-to-high-temperature waste heat recovery in transport and in industry. A crucial aspect of the success of a thermoelectric material is its stability over time when exposed to rapid heating and cooling. In this work different aspects of the degradation of these thermoelectric materials at high temperature were examined. Initial thermal durability was studied, and several candidate coatings were evaluat…

Materials scienceoxidationMetallurgycoatingengineering.materialCondensed Matter PhysicsThermoelectric materialsMagnesium silicide7. Clean energyDurabilityVDP::Teknologi: 500::Elektrotekniske fag: 540Electronic Optical and Magnetic MaterialsWaste heat recovery unitSkutteruditechemistry.chemical_compoundCoatingchemistryThermalMaterials ChemistryengineeringdurabilitySublimation (phase transition)SkutteruditeElectrical and Electronic Engineeringmagnesium silicideJournal of Electronic Materials
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Combined membrane and thermal desalination processes for the treatment of ion exchange resins spent brine

2019

Abstract The disposal of industrial wastewater effluents represents a critical environmental issue. This work focuses on the treatment of the spent brine produced by the regeneration of ion exchange resins employed for water softening. For the first time, a comprehensive techno-economic assessment and an analysis of the energy requirements of the treatment chain are carried out, via the simulation of ad hoc implemented models. The chain is composed of nanofiltration, double-stage crystallization and multi-effect distillation. The valuable product is the brine produced by the multi-effect distillation, which can be re-used for the regeneration. Therefore, the treatment chain’s economic feasi…

Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciCircular economy020209 energyLow-temperature thermal desalination02 engineering and technologyWastewater treatmentManagement Monitoring Policy and Law7. Clean energy12. Responsible consumptionWaste heat recovery unitlaw.inventionIndustrial wastewater treatmentIndustrial wastewater020401 chemical engineeringlawWaste heat0202 electrical engineering electronic engineering information engineeringTechno-economic analysi0204 chemical engineeringDistillationWaste heat recoveryTechno-economic analysisWaste managementbusiness.industryMechanical EngineeringBuilding and Construction6. Clean waterNanofiltrationGeneral EnergyBrineEnvironmental scienceNanofiltrationbusinessThermal energy
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Reverse electrodialysis with NH4HCO3-water systems for heat-to-power conversion

2017

Abstract A Reverse ElectroDialysis Heat Engine (REDHE) system operating with “thermolytic” ammonium hydrogen-carbonate (NH4HCO3) aqueous solutions as working fluids is studied. The engine is constituted by (i) a RED unit to produce electric power by mixing the solutions at different salinity and (ii) a thermally-driven regeneration unit including a stripping and an absorption column to restore the initial salinity gradient thus closing the cycle. In the present work only the RED unit and the stripping column are taken into account. In particular, a simplified integrated process model for the whole cycle was developed: it consists of (i) a lumped parameter model for the RED unit validated wi…

Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciStripping (chemistry)Salinity gradient power (SGP)020209 energyAnalytical chemistry02 engineering and technology7. Clean energyThermolytic saltIndustrial and Manufacturing EngineeringWaste heat recovery unitReversed electrodialysisThermal0202 electrical engineering electronic engineering information engineeringElectrical and Electronic EngineeringClosed-loop reverse electrodialysiWaste heat recoveryAmmonium hydrogen carbonateCivil and Structural EngineeringPower densityHeat engineWaste managementChemistryMechanical EngineeringAmmonium hydrogen carbonate; Closed-loop reverse electrodialysis; Reverse ElectroDialysis Heat Engine (REDHE); Salinity gradient power (SGP); Thermolytic salts; Waste heat recovery; Civil and Structural Engineering; Building and Construction; Pollution; Energy (all); Mechanical Engineering; Industrial and Manufacturing Engineering; Electrical and Electronic EngineeringBuilding and ConstructionElectrodialysis021001 nanoscience & nanotechnologyPollution6. Clean waterEnergy (all)General EnergyReverse ElectroDialysis Heat Engine (REDHE)Electric power0210 nano-technology
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Heat Recovery Systems for Agricultural Vehicles: Utilization Ways and Their Efficiency

2018

The focus of today&rsquo

Waste managementbusiness.industryPlant ScienceDiesel enginelcsh:S1-972Waste heat recovery unitInternal combustion engineefficiencyAir conditioningHeat recovery ventilationWaste heatinternal combustion engineheat recoveryFuel efficiencyEnvironmental sciencemedia_common.cataloged_instancelcsh:Agriculture (General)European unionbusinessAgronomy and Crop ScienceagricultureFood Sciencemedia_commonAgriculture
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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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Waste heat recovery from a marine waste incinerator using a thermoelectric generator

2012

Published version of an article published in the journal: Journal of Electronic Materials. Also available from the publisher at: http://dx.doi.org/10.1007/s11664-012-2009-6 A marine waste incinerator has been evaluated for waste heat harvesting using thermoelectric generators (TEG). The application has been evaluated using mathematical modeling to optimize the heat exchanger and some vital design parameters of the TEG. The calculation shows that it is possible to extract 58 kW el at a price of 6.6 US$/W from an 850-kW th incinerator when optimizing for maximum power. However, minimizing the cost, it is possible to get 25 kW el at a price of 2.5 US$/W. A trade-off between the two targets lea…

waste heat recoveryMaximum power principleWaste managementVDP::Technology: 500::Marine technology: 580TEGwaste heatCondensed Matter PhysicsthermoelectricElectronic Optical and Magnetic MaterialsIncinerationWaste heat recovery unitThermoelectric generatorWaste heatmarine incineratorThermoelectric effectHeat exchangerMaterials ChemistryEnvironmental scienceElectrical and Electronic Engineeringmathematical model
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