Your search keyword '"Mendoza, Joan-Manuel F."' showing total 8 results

1. Life Cycle Management Applied to Urban Fabric Planning

Author

Gabarrell, Xavier, Rieradevall, Joan, Josa, Alejandro, Oliver-Solà, Jordi, Mendoza, Joan Manuel F., Sanjuan-Delmás, David, Petit-Boix, Anna, Sanyé-Mengual, Esther, Klöpffer, Walter, Series editor, Curran, Mary Ann, Series editor, Sonnemann, Guido, editor, and Margni, Manuele, editor

Published

2015

2. Circular economy performance and carbon footprint of wind turbine blade waste management alternatives.

Author

Diez-Cañamero, Borja and Mendoza, Joan Manuel F.

Subjects

*WIND turbine blades, *CIRCULAR economy, *ECOLOGICAL impact, *WASTE management, *CHEMICAL recycling, *PRODUCT life cycle assessment

Abstract

• Calculation of product circularity and global warming indicators. • Evaluation of end-of-life management solutions to slow and close resource loops. • Chemical recycling has the greater circularity and low-impact potential. • Thermal recycling has the lower circularity and higher carbon footprint. • Higher circularity does not always lead to carbon savings. It is estimated that 570 Mt of blade waste, whose management is complex and expensive, will be generated by 2030 in the European Union alone. Accordingly, alternative blade waste management techniques are being investigated to optimize material recovery. This study evaluates the correlation between the circular economy performance and the carbon footprint of seven end-of-life management solutions for wind turbine blades: repurposing, grinding, solvolysis, pyrolysis, co-processing in cement kilns, incineration with energy recovery and landfilling. The circular economy performance is analyzed through the calculation of the product circularity indicator, while the carbon footprint is determined through life cycle assessment, using the global warming indicator and considering the management of three blades from cradle-to-gate as functional unit. As the performance of solvolysis and pyrolysis recycling is expected to change in the future, a sensitivity analysis is also carried out to evaluate the variability of the results by changing their process efficiency and the quality of the recovered materials. The results indicate that blade recycling through solvolysis is the most circular (0.47–0.77) and low-carbon (225–503 CO 2 eq.) solution overall. Blade repurposing, grinding and cement co-processing have a similar circularity (0.52–0.55) and a global warming impact ranging from 499 t CO 2 eq. to 615 t CO 2 eq. Although the circularity of pyrolysis is 59% (0.35) to 118% (0.48) greater than the circularity of incineration and landfilling (0.22), its carbon footprint can range from 566 t CO 2 eq. to 744 t CO 2 eq, which could be up to 19% higher than the carbon footprint of these linear EoL management alternatives (623 t CO 2). Based on these findings, proposals for sustainable industrial innovation and methodological recommendations for the development of integrated circularity and sustainability studies are proposed. [ABSTRACT FROM AUTHOR]

Published

2023

3. Environmental impact of public charging facilities for electric two-wheelers

Author

Mendoza, Joan Manuel F., Josa Garcia-Tornel, Alejandro, Rieradevall Pons, Joan, Gabarrell Durany, Xavier, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. MECMAT - Mecànica de Materials

Subjects

life cycle assessment, Electric vehicles--Batteries, Desenvolupament humà i sostenible::Desenvolupament sostenible::Energia i sostenibilitat [Àrees temàtiques de la UPC], Electric vehicles--Environmental aspects, global warming potential, Vehicles elèctrics -- Bateries, Enginyeria mecànica::Motors::Motors elèctrics [Àrees temàtiques de la UPC], Vehicles elèctrics -- Aspectes ambientals, charging infrastructure, industrial ecology, electric vehicles, electricity mix

Abstract

The environmental characterization of the charging infrastructure required to operate electric vehicles (EVs) is usually overlooked in the literature. Only rudimentary life cycle inventories of EV charging facilities are available. This lack of information is especially noticeable in environmental studies of the environmental performance of electric two-wheelers (E2Ws), none of which have included an analysis of charging facilities, even though they constitute the most successful electric-drive market in the world. This article focuses on characterizing the life cycle of the global warming potential (GWP) and primary energy demand (PED) of two conventional charging facility designs that are widely implemented for charging E2Ws in public spaces. The relative environmental relevance of charging facilities per kilowatt-hour (kWh) supplied to E2Ws is determined by considering a range of use scenarios (variability in the service ratio) and the effect of upgrading the electricity mix to include more renewable energy sources. Savings of over 3 metric tons (tonnes) of carbon dioxide equivalent emissions and 56 equivalent gigajoules can be achieved by implementing an optimized charging facility design. The internalization of the relative environmental burden from the charging facility per kWh supplied to E2Ws can increase the GWP of E2Ws’ use phase from 1% to 20% and the PED from 1% to 13%. Although the article focuses on one particular case scenario, the research is intended to provide complementary criteria for further research on the life cycle management of electric mobility systems. Thus, a series of factors that can influence the environmental performance of EV charging networks at the macro scale are discussed.

Published

2016

4. Life cycle management applied to urban fabric planning

Author

Gabarrell Durany, Xavier, Rieradevall Pons, Joan, Josa Garcia-Tornel, Alejandro, Oliver Solà, Jordi, Fernández Mendoza, Joan-Manuel F., Sanjuan Demás, David, Petit Boix, Anna, Sanyé-Mengual, E., Universitat Politècnica de Catalunya. Departament d'Enginyeria del Terreny, Cartogràfica i Geofísica, and Universitat Politècnica de Catalunya. MECMAT - Mecànica de Materials

Subjects

Pavements Sidewalks, Desenvolupament humà i sostenible::Desenvolupament sostenible [Àrees temàtiques de la UPC], Life cycle assessment, Life cycle management, Ecologia urbana (Sociologia), Sustainability, Urbanisme [Àrees temàtiques de la UPC], Urban ecology (Sociology), City developments, Life cycle thinking

Abstract

Illustrates how Life Cycle Management is or can be integrated into business practice, thereby creating sustainability within organizations.

Published

2015

5. Disposable baby diapers: Life cycle costs, eco-efficiency and circular economy.

Author

Mendoza, Joan Manuel F., D'Aponte, Francesco, Gualtieri, Diego, and Azapagic, Adisa

Subjects

*DIAPERS & the environment, *WASTE products, *LIFE cycle costing, *ECONOMIC efficiency, *DIAPER manufacturing

Abstract

Abstract The literature on baby diapers has so far focused on environmental implications of using cloth instead of disposable products, utilising bio-materials or enabling recycling and composting. However, no study to date has examined the life cycle costs and eco-efficiency implications of cleaner production of disposable diapers. Therefore, this paper sets out to evaluate the economic and environmental savings that could be achieved by eco-design and cleaner production of disposable baby diapers. This involves the use of an optimised absorbent core and innovative bonding technologies to replace gluing systems in diaper manufacturing. The analysis is carried out at different production and consumption scales: a single production platform, a whole industrial plant, a country and the European Union (EU). A cradle-to-grave life cycle costing demonstrates that the novel design and manufacture of the so-called "glueless" diapers reduce costs by 11% compared to the conventional product. This is equivalent to saving €250 million at the EU level. Likewise, the eco-efficiency analysis shows that the glueless diapers are 7%–170% more eco-efficient (€/impact) than the standard diapers, depending on the environmental impact considered. Still, eco-design and cleaner production will not help to resolve the underlying critical issue of the linear material consumption and waste generation associated with the use of disposable baby diapers. Further industrial efforts must concentrate on finding solutions to facilitate implementation of circular economy principles for these products. This calls for the development of new circular business models as discussed in the paper. Graphical abstract Image 1 Highlights • New diapers are overall 32% more eco-efficient (€/impact) than the standard type. • Cleaner production of diapers reduces the life cycle costs by 11%. • At the EU level, this corresponds to an annual saving in costs of €250 million. • In addition, 192 kt materials and wastes and 184 kt of CO 2 eq. are saved annually. • Still, implementation of a circular economy is critical for the diapers industry. [ABSTRACT FROM AUTHOR]

Published

2019

6. Improving resource efficiency and environmental impacts through novel design and manufacturing of disposable baby diapers.

Author

Mendoza, Joan Manuel F., Popa, Simona Andreea, D'Aponte, Francesco, Gualtieri, Diego, and Azapagic, Adisa

Subjects

*WASTE management, *DIAPERS & the environment, *ENVIRONMENTAL impact analysis, *ENERGY consumption, *ENVIRONMENTAL toxicology

Abstract

Abstract The annual market demand for disposable baby diapers exceeds 20 billion units (690 kt) in the European Union (EU). Almost 40,000 disposable diapers are used every minute, producing 1.3 t/min (dry weight) of waste. Based on the estimates in this work, this requires 90.3 PJ of primary energy and emits 2.7 Mt CO 2 eq. annually. In an attempt to reduce resource, waste and environmental impacts associated with diapers, this paper focuses on novel design and manufacture of disposable baby diapers. This involves using optimised absorbent core and novel bonding technologies to replace conventional gluing of diaper materials. Life cycle assessment has been performed to compare the environmental performance of these new diapers, here termed "glueless", with standard designs. The annual resource consumption and environmental impacts of glueless diapers have been estimated at different production levels: a single production platform, an industrial plant, a country (Italy) and the EU, taking into account different production volumes, electricity mixes and waste management options. Different market penetration scenarios have been considered to determine potential environmental implications at the EU level by 2020. The results reveal that glueless diapers reduce the consumption of raw materials by 23% (9.2 g/diaper), primary energy demand by 25% (752 kJ/diaper) and global warming potential by 10% (10.4 g CO 2 eq./diaper) compared to the standard diapers. They also have more than 50% lower eutrophication, ozone depletion and human and eco-toxicity. Up to 16 PJ primary energy and 191,000 t CO 2 eq. would be saved annually in the EU by using glueless diapers. The cumulative savings would amount to 47 PJ and 566,000 t CO 2 eq. by 2020. The annual consumption of raw materials at the EU level would be reduced by 196,000 t with cumulative savings of up to 584,000 t by 2020, also reducing the equivalent amount of waste from the disposal of diapers. Consequently, glueless diapers can contribute to meeting the energy, climate and resource efficiency goals specified in the EU 2020 strategy. Graphical abstract Image 1 Highlights • Novel design and manufacture of "glueless" disposable baby diapers is considered. • Glueless diapers save 23% of materials and 25% of energy relative to standard type. • Most life cycle impacts are reduced by >50% and global warming potential by 10%. • Up to 584,000 t of waste and 566,000 t of CO 2 eq. can be saved by 2020. • Glueless diapers can help meet the EU energy, resource and climate change targets. [ABSTRACT FROM AUTHOR]

Published

2019

7. Environmental Impact of Public Charging Facilities for Electric Two-Wheelers.

Author

Mendoza, Joan‐Manuel F., Josa, Alejandro, Rieradevall, Joan, and Gabarrell, Xavier

Subjects

*ELECTRIC vehicle charging stations, *ELECTRIC vehicles, *BATTERY chargers, *PRODUCT life cycle assessment, *GLOBAL warming

Abstract

The environmental characterization of the charging infrastructure required to operate electric vehicles (EVs) is usually overlooked in the literature. Only rudimentary life cycle inventories of EV charging facilities are available. This lack of information is especially noticeable in environmental studies of the environmental performance of electric two-wheelers (E2Ws), none of which have included an analysis of charging facilities, even though they constitute the most successful electric-drive market in the world. This article focuses on characterizing the life cycle of the global warming potential (GWP) and primary energy demand (PED) of two conventional charging facility designs that are widely implemented for charging E2Ws in public spaces. The relative environmental relevance of charging facilities per kilowatt-hour (kWh) supplied to E2Ws is determined by considering a range of use scenarios (variability in the service ratio) and the effect of upgrading the electricity mix to include more renewable energy sources. Savings of over 3 metric tons (tonnes) of carbon dioxide equivalent emissions and 56 equivalent gigajoules can be achieved by implementing an optimized charging facility design. The internalization of the relative environmental burden from the charging facility per kWh supplied to E2Ws can increase the GWP of E2Ws' use phase from 1% to 20% and the PED from 1% to 13%. Although the article focuses on one particular case scenario, the research is intended to provide complementary criteria for further research on the life cycle management of electric mobility systems. Thus, a series of factors that can influence the environmental performance of EV charging networks at the macro scale are discussed. [ABSTRACT FROM AUTHOR]

Published

2016

8. Environmental management of granite slab production from an industrial ecology standpoint.

Author

Mendoza, Joan-Manuel F., Capitano, Cinzia, Peri, Giorgia, Josa, Alejandro, Rieradevall, Joan, and Gabarrell, Xavier

Subjects

*ENVIRONMENTAL management, *GRANITE, *INDUSTRIAL ecology, *SAWING, *ENERGY conservation, *MANUFACTURING processes, *WATER harvesting

Abstract

The granite production chain is high energy and water intensive with low resource efficiency. This paper focus on characterizing the potential for environmental improvement of the granite production chain by promoting the optimization of sawing technology, the implementation of rainwater harvesting (RWH) and the material recovery of wasted granite (sludge). The environmental performance of multi-blade gangsaw (MBGS) and diamond multi-wire saw (DMWS) technologies is compared by mean of life cycle assessment. Results demonstrate that DMWS technology contribute 30% of water savings, 40% of energy savings and 80% of material savings per square meter of polished granite tiles (60 x 40 x 2 cm) production. These resource savings contribute together to reduce the product's environmental footprint by 35% to 80%. The potential for RWH is analyzed using Plugrisost® simulation software based on system dynamics. RWH depends on the relationship between rainfall, catchment surface and tank size according to the industrial process’s water demand. The results demonstrate major potential to satisfy over 50% of the systemś daily water requirements using rainwater stored in rainwater tanks of varying capacity. RWH is a sustainable strategy for industrial water cycle management. A comprehensive review of literature reveals a range of technically feasible alternatives to promote material recovery of granite sludge. The ceramic industry is one promising industrial endpoint with which to avoid waste landfilling and contribute to mineral, energy and water savings. This by-product synergy could also serve as starting point for springboarding exchanges with other industrial agents, becoming a global extension of resource efficiency. [ABSTRACT FROM AUTHOR]

Published

2014