Search results for "Life Cycle Assessment"

showing 10 items of 172 documents

Long-term performance and life cycle assessment of energy piles in three different climatic conditions

2020

Abstract The main purpose behind the use of energy piles is to enable the exploitation of geothermal energy for meeting the heating/cooling demands of buildings in an efficient and environment-friendly manner. However, the long-term performance of energy piles in different climatic conditions, along with their actual environmental impacts, has not been fully assessed. In this paper, the results of a finite element model taking into consideration the heating and cooling demands of a reference building, and the intermittent operation of a ground source heat pump, are revealed to examine the long-term performance of energy piles. Furthermore, a life cycle assessment model is implemented to com…

020209 energy02 engineering and technology7. Clean energyCivil engineeringlaw.inventionspace heating–coolinglife cycle assessmentlawheat transfer0202 electrical engineering electronic engineering information engineeringWater cooling0601 history and archaeologyGeothermal gradientLife-cycle assessmentEnergy pile Geothermal energy Heat transfer Life cycle assessment Space heating–coolingSettore ICAR/07 - Geotecnica060102 archaeologyRenewable Energy Sustainability and the Environmentbusiness.industryGeothermal energy06 humanities and the arts13. Climate actiongeothermal energyHeat transferEnvironmental scienceenergy pilePilebusinessEnergy (signal processing)Heat pumpRenewable Energy
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Combined gasification-oxidation system for waste treatment with supercritical water: Lca and performance analysis

2020

In this study the environmental performance of a first-of-its-kind integrated process based on supercritical water gasification and oxidation (SCW-GcO), was evaluated using life cycle assessment (LCA). The process was applied to the treatment of carbon black and used oil as model wastes. Mass and energy balances were performed using Aspen Plus, and the environmental assessment was carried out through SimaPro. A “from cradle to grave” approach was chosen for the analysis, considering impact categories such as climate change, ozone depletion, human toxicity, particulate matter, land use, resource depletion, and other relevant indicators. The environmental profile of the SCW-GcO process was co…

020209 energySettore ING-IND/25 - Impianti ChimiciGeography Planning and DevelopmentEnergy balanceTJ807-83002 engineering and technologyManagement Monitoring Policy and Lawsupercritical waterTD194-195Renewable energy sourceslife cycle assessment0202 electrical engineering electronic engineering information engineeringEnvironmental impact assessmentGE1-350Life-cycle assessmentwaste treatmentsSettore ING-IND/11 - Fisica Tecnica AmbientaleWaste managementEnvironmental effects of industries and plantsRenewable Energy Sustainability and the EnvironmentLife cycle assessment Supercritical water Waste treatmentsParticulates021001 nanoscience & nanotechnologyResource depletionOzone depletionSupercritical fluidEnvironmental sciencesWaste treatmentEnvironmental science0210 nano-technologysupercritical water; life cycle assessment; waste treatments
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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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Life cycle energy performances and environmental impacts of a prefabricated building module

2018

Abstract The paper explores the energy performances and environmental impacts of a prefabricated building module located in Messina (Sicily, Italy) through an approach that combines both the non-steady state building simulation and the Life Cycle Assessment methodology. The building uses renewable energy technologies and is usable in emergency situations or as simply temporary housing. Results show that the building module causes the emission of 1.5 t of CO2eq/m2 and consumes 29.2 GJ/m2 of primary energy during its life cycle. The building achieves the Net Zero Energy Building target even if it has relevant environmental impacts in the materials production stage (72% on average of the total…

Architectural engineeringZero-energy buildingSettore ING-IND/11 - Fisica Tecnica AmbientalePrimary energybusiness.industryNZEBRenewable Energy Sustainability and the Environment020209 energyLCANet zero energy building02 engineering and technologyUSableEmergency situationsEdilizia sostenibileRenewable energyBuilding simulationLife cycle assessmentPrefabricated building0202 electrical engineering electronic engineering information engineeringProduction (economics)Environmental sciencebusinessLife-cycle assessmentEnergy (signal processing)
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Multi-objective optimization of building life cycle performance. A housing renovation case study in Northern Europe

2020

While the operational energy use of buildings is often regulated in current energy saving policies, their embodied greenhouse gas emissions still have a considerable mitigation potential. The study aims at developing a multi-objective optimization method for design and renovation of buildings incorporating the operational and embodied energy demands, global warming potential, and costs as objective functions. The optimization method was tested on the renovation of an apartment building in Denmark, mainly focusing envelope improvements as roof and exterior wall insulation and windows. Cellulose insulation has been the predominant result, together with fiber cement or aluminum-based cladding …

Architectural engineeringbuilding renovationLow-energy buildings020209 energylcsh:TJ807-830Geography Planning and Developmentlcsh:Renewable energy sources02 engineering and technology010501 environmental sciencesManagement Monitoring Policy and Law01 natural sciencesMulti-objective optimizationLife cycle assessmentlife cycle assessment0202 electrical engineering electronic engineering information engineeringBuilding life cycleCellulose insulationRoofLife-cycle assessmentlcsh:Environmental sciences0105 earth and related environmental scienceslcsh:GE1-350Settore ING-IND/11 - Fisica Tecnica Ambientalelow-energy buildingBuilding renovation Embodied Life cycle assessment Low-energy building Multiobjective optimizationRenewable Energy Sustainability and the Environmentlcsh:Environmental effects of industries and plantsEmbodiedSettore ING-IND/33 - Sistemi Elettrici Per L'EnergiaMulti-objective optimizationGlazinglcsh:TD194-195multi-objective optimizationGreenhouse gasembodiedEnvironmental scienceEmbodied energyBuilding renovation
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Artificial Neural Networks to assess energy and environmental performance of buildings: An Italian case study

2019

Abstract Approximately 40% of the European energy consumption and a large proportion of environmental impacts are related to the building sector. However, the selection of adequate and correct designs can provide considerable energy savings and reduce environmental impacts. To achieve this objective, a simultaneous energy and environmental assessment of a building's life cycle is necessary. To date, the resolution of this complex problem is entrusted to numerous software and calculation algorithms that are often complex to use. They involve long diagnosis phases and are characterised by the lack of a common language. Despite the efforts by the scientific community in the building sector, th…

Artificial neural networkDecision support systemSettore ICAR/12 - Tecnologia dell'ArchitetturaDecision support toolComputer science020209 energyStrategy and ManagementSettore ICAR/11 - Produzione EdiliziaEnergy balance02 engineering and technologyBuilding energy demandNetwork topologyIndustrial and Manufacturing EngineeringEnvironmental dataEnvironmental impactLife cycle assessmentSoftware0202 electrical engineering electronic engineering information engineeringEnvironmental impact assessmentLife-cycle assessment0505 lawGeneral Environmental ScienceArtificial neural networkRenewable Energy Sustainability and the Environmentbusiness.industry05 social sciencesEnergy consumptionEnvironmental impactsIndustrial engineeringArtificial neural network; Building energy demand; Decision support tool; Energy balance; Environmental impacts; Life cycle assessment050501 criminologybusinessJournal of Cleaner Production
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Life Cycle Assessment of Asphalt Mixtures with WMR

2023

This study aimed at providing pavement specialists with international average values of greenhouse gas emissions (GHG) and energy consumption related to the manufacturing of asphalt mixtures (cradle-to-gate), with and without waste and secondary materials for roads (WMRs). In order to achieve this goal, TG leaders first referred to current standards to define a methodology for obtaining benchmark values according to ISO 21678:2020. Then, a data collection tool was designed and provided to a group of international partners to build a life cycle inventory for asphalt mixtures including data from materials up to plant manufacturing (A1–A3). Partners were asked to provide information for any ty…

Asphalt mixtureLife Cycle AssessmentBenchmarkWaste Secondary materials
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MULTI-OBJECTIVE OPTIMISATION OF BUILDINGS AND BUILDING CLUSTERS PERFORMANCE: A LIFE CYCLE THINKING APPROACH

2021

BUILDINGS ENERGY PERFORMANCESettore ING-IND/33 - Sistemi Elettrici Per L'EnergiaECONOMIC ANALYSISLIFE CYCLE ASSESSMENTSettore ING-IND/11 - Fisica Tecnica AmbientaleBuilding clusterMULTI-OBJECTIVE OPTIMISATIONBUILDING ENERGY PERFORMANCEMICROGRIDBUILDING CLUSTERS
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Life Cycle Assessment for Supporting Eco-Design: The Case Study of Sodium–Nickel Chloride Cells

2021

The European Union is moving towards a sustainable, decarbonized, and circular economy. It has identified seven key value chains in which to intervene, with the battery and vehicle value chain being one of them. Thus, actions and strategies for the sustainability of batteries need to be developed. Since Life Cycle Assessment (LCA) is a strategic tool for evaluating environmental sustainability, this paper investigates its application to two configurations of a sodium–nickel chloride cell (planar and tubular), focusing on the active material and the anode, with the purpose of identifying the configuration characterized by the lowest environmental impacts. The results, based on a “from cradle…

Battery (electricity)Control and Optimization020209 energyEnergy Engineering and Power Technology02 engineering and technologylife cycle assessment; environmental impact; sodium–nickel chloride cells; environmental sustainabilityChlorideenvironmental impactlcsh:Technologysodium–nickel chloride celllife cycle assessment0202 electrical engineering electronic engineering information engineeringmedicinesodium–nickel chloride cellsmedia_common.cataloged_instanceEnvironmental impact assessmentElectrical and Electronic EngineeringEuropean unionenvironmental sustainabilityEngineering (miscellaneous)Life-cycle assessmentmedia_commonSettore ING-IND/11 - Fisica Tecnica AmbientaleEcological footprintRenewable Energy Sustainability and the Environmentlcsh:TCircular economyEnvironmental engineering021001 nanoscience & nanotechnologySustainabilityEnvironmental science0210 nano-technologyEnergy (miscellaneous)medicine.drugEnergies
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Life cycle assessment of storage systems: the case study of a sodium/nickel chloride battery

2014

This study assesses the energy and environmental impacts of sodium/nickel chloride batteries, one of the emerging battery technologies for energy storage and smart grids. The analysis was conducted using the Life Cycle Assessment methodology according to the standards of the ISO 14040 series. The study system was one sodium/nickel cell battery providing electric storage for a photovoltaic system, and the manufacturing, operation, and end-of-life steps were analysed. The results indicated that the operation step has the greatest energy impact (55-70% of the total), with the manufacturing step, particularly cell manufacturing, contributing the greatest environmental impact (>60% of the total)…

Battery (electricity)EngineeringEnergy storage systemsStrategy and Management[object Object]ChlorideIndustrial and Manufacturing EngineeringEnergy storageLife cycle assessmentmedicineOperations managementEnvironmental impact assessmentProcess engineeringLife-cycle assessmentGeneral Environmental ScienceSettore ING-IND/11 - Fisica Tecnica AmbientaleRenewable Energy Sustainability and the Environmentbusiness.industryLife cycle assessment Energy storage systems Na/NiCl2 battery ZEBRA Environmental impactsPhotovoltaic systemEnvironmental impactsSmart gridSustainabilitybusinessmedicine.drugZEBRA
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