Search results for "Aluminium recycling"

showing 5 items of 5 documents

Evaluating the material resource efficiency of secondary aluminium production: A Monte Carlo-based decision-support tool

2019

The contamination of aluminium streams during the different life cycle stages by alloy mixing and/or accumulation of foreign elements, in combination with the limited melt purification options during remelting, represents an important limiting factor in recycling. Consequently, in secondary aluminium production, primary aluminium is used to dilute the concentration of the residual elements, and alloying elements are added to adjust the composition to the target alloy specifications. However, adding elements, for which their refinement in a subsequent recycling step is problematic, results in permanent down-cycling or ‘quality losses’. Hence, it is crucial to more efficiently control the com…

020209 energyStrategy and ManagementMonte Carlo methodResource efficiencychemistry.chemical_elementScrapAlloying element02 engineering and technologyIndustrial and Manufacturing EngineeringLife cycle assessmentAluminium0202 electrical engineering electronic engineering information engineeringProcess engineeringLife-cycle assessment0505 lawGeneral Environmental Science2300business.industryRenewable Energy Sustainability and the Environment05 social sciencesSortingAluminium recyclingMaterial efficiencyAluminium recyclingMaterial efficiencyScrap sortingStrategy and Management1409 Tourism Leisure and Hospitality Managementchemistry050501 criminologyEnvironmental sciencebusiness
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On the impact of recycling strategies on energy demand and CO2 emissions when manufacturing Al-based components

2016

Abstract The industrial world is facing the challenge of reducing emissions by means of energy- and resource-efficient manufacturing strategies. In some cases, the exerted emissions and the energy demands related to conventional manufacturing processes are not as intensive as those required to extract and produce the raw materials of which the workpieces are made. Therefore, the consciousness of the impact of material usage and the eco-informed choice of the end-of-life scenarios are both needed in view of sustainable development. Aim of this paper is to offer a contribution to a better understanding of the environmental impact of forming and machining processes, for the production of Al-ba…

0209 industrial biotechnologyEngineeringSustainable manufacturingSustainable manufacturing; Recycling; Aluminum; Machining; Forming.02 engineering and technology010501 environmental sciencesRaw material01 natural sciencesSustainable manufacturing; Recycling; Aluminum; Machining; Forming020901 industrial engineering & automationMachiningProduction (economics)Environmental impact assessmentRecyclingSettore ING-IND/16 - Tecnologie E Sistemi Di Lavorazione0105 earth and related environmental sciencesGeneral Environmental ScienceSustainable developmentEnergy demandbusiness.industrySustainable manufacturingAluminium recyclingForming.Environmental economicsMachiningManufacturing engineeringGeneral Earth and Planetary SciencesbusinessFormingAluminum
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Aluminium sheet metal scrap recycling through friction consolidation

2019

Abstract In the last decades, several direct-recycling techniques have been developed and investigated in order to avoid material remelting, typical of the conventional aluminum alloys recycling processes. Moreover, the remelting step for aluminum recycling is affected by permanent material losses. Solid-state recycling processes have proven to be a suitable strategy to face such issues. Friction Consolidation is an innovative solid state-recycling technology developed for metal chips. During the process, a rotating die is plunged into a hollow chamber containing the material to be processed. The work of friction forces decaying into heat soften the material and, together with the stirring …

0209 industrial biotechnologyWork (thermodynamics)business.product_categoryMaterials scienceAluminum alloychemistry.chemical_elementScrap02 engineering and technologyIndustrial and Manufacturing EngineeringScrap recycling020901 industrial engineering & automation0203 mechanical engineeringArtificial IntelligenceAluminiumSettore ING-IND/16 - Tecnologie E Sistemi Di LavorazioneFriction consolidationConsolidation (soil)MetallurgyAluminium recycling020303 mechanical engineering & transportschemistryvisual_artvisual_art.visual_art_mediumDie (manufacturing)Sheet metalbusiness
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An energy efficiency analysis of Single Point Incremental Forming as an Approach for Sheet Metal Based Component Reuse

2020

Abstract Producing materials causes about 25% of all anthropogenic CO2 emissions. Metals play a significant role, steel and aluminum account for 24% and 3% of worldwide material related emissions respectively. Fostering resources efficiency strategies in the field of sheet components could lead to a significant environmental impact reduction. Reshaping could be one of the most efficient strategy to foster material reuse and lower the environmental impact due to material production. Specifically, for aluminum recycling, the overall energy efficiency of conventional route is very low and, more importantly, permanent material losses occur during re-melting because of oxidation. The present pap…

0209 industrial biotechnologybusiness.industryAluminium recycling02 engineering and technology010501 environmental sciencesReuse01 natural sciencesTechnical feasibility020901 industrial engineering & automationComponent (UML)visual_artvisual_art.visual_art_mediumGeneral Earth and Planetary SciencesEnvironmental scienceProduction (economics)Process engineeringbusinessSheet metalEnergy (signal processing)0105 earth and related environmental sciencesGeneral Environmental ScienceEfficient energy useProcedia CIRP
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Screening of halogenated aromatic compounds in some raw material lots for an aluminium recycling plant

2004

Four samples of scrap raw materials for an aluminium recycling plant were screened for the occurrence of persistent halogenated aromatic compounds. The samples contained waste from handling of electric and electronic plastics, filter dust from electronic crusher, cyclone dust from electronic crusher and light fluff from car shredder. In our screening analyses, brominated flame retardants were observed in all samples. Polybrominated diphenyl ethers (PBDE) were identified in all samples in amounts of 245–67450 ng/g. The major PBDE congeners found were decabromo- and pentabromodiphenyl ethers. 1,1-bis(2,4,6-tribromophenoxy)ethane, hexabromobenzene, ethyl-pentabromobenzene, tetrabromobisphenol-…

lcsh:GE1-350Conservation of Natural ResourcesWaste managementPhenyl EthersPolybrominated BiphenylsIndustrial WasteAluminium recyclingScrapRaw materialHydrocarbons AromaticHydrocarbons Brominatedchemistry.chemical_compoundPolybrominated diphenyl etherschemistryEnvironmental chemistryHexabromobenzeneHalogenated Diphenyl EthersSoil PollutantsPentabromotolueneWater Pollutants Chemicallcsh:Environmental sciencesAluminumEnvironmental MonitoringFlame RetardantsGeneral Environmental ScienceEnvironment International
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