Browsing by Keyword "Life Cycle Assessment"
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Item Environmental assessment of domestic solar hot water systems: a case study in residential and hotel buildings: A case study in residential and hotel buildings(2015-02-01) Zambrana-Vasquez, David; Aranda-Usón, Alfonso; Zabalza-Bribián, Ignacio; Jañez, Alberto; Llera-Sastresa, Eva; Hernández, Patxi; Arrizabalaga, Eneko; PLANIFICACIÓN ENERGÉTICADomestic solar hot water systems (SHWS), which are used to reduce domestic energy use, represent one of the most widely known technologies of solar thermal applications. Taking into account the sizing of these systems during its design phase, it is also important to consider the effects on the environment of their use from a life cycle perspective. An evaluation method based on the Life Cycle Assessment (LCA) methodology is used in this paper to analyse the environmental implications of SHWS considering the production, use, maintenance and end-of-life stages. As a case study, 32 different types of SWHS to meet the hot water demand (HWD) of 2 dwellings and 2 hotels, located in the region of Aragón in Spain, are studied. The aim of the case study is to compare the environmental performance of SHWS and to select the best environmentally friendly solution while considering their energy pay-back time (EPBT). From an environmental point of view, comparing the results obtained in all cases studies, e.g., in terms of kg CO2 eq, the use of biomass as fuel for the auxiliary system in each SHWS considered provides the greatest environmental benefit in comparison with the other fuels, usually followed by the use of natural gas. However, in terms of the EPBT, because biomass is the fuel with lowest environmental impact and associated embodied energy, the avoided embodied energy due to the solar contribution in SHWS is the lowest in the biomass case, thereby resulting in a higher value of the EPBT.Item Evaluating energy and resource efficiency for recovery of metallurgical residues using environmental and economic analysis(2022-07-01) Di Maria, Andrea; Merchán, Mikel; Marchand, Muriel; Eguizabal, David; De Cortázar, Maider García; Van Acker, Karel; CIRMETALEnergy and resource efficiency are today key elements for the metallurgical industry in the context of the new European Green Deal. Although the currently available technologies have recently led to an optimisation of energy and materials use, the decarbonisation targets may not be met without the development of new and innovative technologies and strategies. In this context, the goal of the H2020 project CIRMET (Innovative and efficient solution, based on modular, versatile, and smart process units for energy and resource flexibility in highly energy-intensive processes) is to develop and validate an innovative and flexible circular solution for energy and resource efficiency in a metallurgical plant. The circular model proposed is composed of three units: (1) a metallurgical furnace for the recovery of valuable metals from industrial metallic wastes, (2) a unit for heat recovery from the furnace’s exhaust gases, and (3) a digital platform for the optimisation of the whole process. Also, the circular model investigates the possibilities of substituting the metallurgical coke used in the furnace with biobased material (BIOCHAR). This study presents an environmental and economic assessment of the circular model, based on a real pilot testing campaign in which residues from non-ferrous metals production are treated for the recovery of metals, mechanical energy from waste heat, and inert fraction. Life Cycle Assessment (LCA) and Life Cycle Costing (LCC) are used to assess the environmental and economic performances of the circular model. The results of the LCA and the LCC highlight the main environmental and economic hot spots of the proposed technologies. The environmental analysis showed the environmental positive effects of recovering secondary metals and energy. However, for some environmental impact categories (e.g. climate change), the benefits are balanced out by the high electricity and natural gas demand in the metallurgical furnace. In this regard, the substitution of metallurgical coke with BIOCHAR can significantly lower the environmental impacts of the whole process. The economic analysis showed the potential economic profitability of the whole process, depending mostly on the quantity and marketability of the recovered metals. For both environmental and economic analysis, the electricity demand in the metallurgical furnace represents the main barrier that can hinder the viability of the process. Therefore, looking for alternative energy sources (e.g. waste heat from other industries) is identified as the most effective strategy to push the sustainability of the whole process. As the proposed technology is under development, these preliminary results can provide useful insights and contribute to the environmental and economic optimisation of the technology.