Table III from Comparative Life Cycle Assessment of Lithium-Ion
Table III Comparison of Terrestrial Acidification Impact of the Main Product Stages for the - "Comparative Life Cycle Assessment of Lithium-Ion Capacitors Production from Primary Ore and Recycled Minerals : Using LCA to balance environmental, economic and social performance in early phase research and development"
Life cycle assessment and environmental profile evaluations of
• The high proportion of tantalum in TECs results in an overall greater environmental impact compared to MLCCs. • Of the recovery processes considered,
Comparative Life Cycle Assessment of aluminum electrolytic
The aim of this study is to compare the environmental impact due to the stages of production (from the raw materials supply to the assembly) and end-of-life (recycle or disposal of wastes)
Comparative Life Cycle Assessment of Lithium-Ion Capacitors Production
The life cycle assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to evaluate the environmental burdens associated with manufacturing a
Comparative life cycle assessment of lithium-ion
The Life Cycle Assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to evaluate the
Environmental impact assessment of aluminum electrolytic capacitors
Environmental impact assessment of aluminum electrolytic capacitors in a product family from the manufacturer''s perspective Aluminum electrolytic capacitors (AECs) are a type of indispensable electronic components in modern electronic and electrical products. a parametric LCI model for the product family was established by combining
Environmental impact assessment of aluminum electrolytic capacitors
Efficient assessment of the potential environmental impact on AECs with different speci-fication parameters in the product family is essential to implement sustainable product development for the manufacturers. Methods A cradle-to-gate life cycle assessment (LCA) was performed to evaluate the environmental impact of 38 types of AECs
Life cycle assessment and environmental profile evaluations of high
The UK alone accommodates substantial cluster of manufacturers and end users of functional materials devices such as capacitors, production of capacitors in the UK reached over €1 million in 2013 [2]. The work demonstrates the analytical capability of LCA for the environmental impact assessment of new device versus existing device across
Environmental impact assessment of aluminum electrolytic capacitors
The impact assessment method, ReCiPe2016 (midpoint, hierarchist perspective), was used to quantitatively calculate the potential environmental impacts of the AECs. Results and discussion Based on the generated LCIs of the AECs and ReCiPe2016, fossil depletion, climate change, and terrestrial ecotoxicity were identified as the key environmental impact categories in the
Comparative life cycle assessment of lithium-ion capacitors
The life cycle assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to
Understanding the impact of environmental impact assessment
The environmental impact assessment (EIA) community comprises a range of professionals engaged in all aspects of impact assessment practice (including but not limited to EIA, strategic environmental assessment, social and health impact assessment), and which might involve development of policies and procedures for EIA as well as teaching, training, and
Comparative Life Cycle Assessment of aluminum electrolytic capacitors
performances, decrease the production footprint on the environment. Functional unit Since both capacitors are produced in different sizes, a reference product has been selected for the analysis of the environmental impact to define the functional unit (FU) of the LCA study. Hence, the FU is the capacitor having a mass of 0.06 kg. System boundaries
Environmental impact assessment of aluminum electrolytic
Based on the generated LCIs of the AECs and ReCiPe2016, fossil depletion, climate change, and terrestrial ecotoxicity were identified as the key environmental impact categories in the
Life cycle assessment and environmental profile evaluations of
The results of this study showed an overwhelming environmental impact relating to tantalum electrolytic capacitors due to the tantalum mining process, compared to multi
A cradle-to-grave life cycle assessment of high-voltage aluminum
The LCI data throughout the entire life cycle of the AECs provide elementary data for environmental impact assessment of the products containing high-voltage AECs. c) an industrial byproduct resulting from the increasing production of capacitors, a vital component in the modern electronics industry, as a reinforcement material for buildings
Life cycle assessment and environmental profile evaluations of
1 Life Cycle Assessment and Environmental Profile Evaluations of High Volumetric Efficiency Capacitors Lucy Smith*a, Taofeeq Ibn-Mohammed*b, c, S. C. Lenny Koh b, c, Ian M. Reaney a a Department of Materials Science and Engineering, The University of Sheffield, Sheffield S1 3JD, UK b Centre for Energy, Environment and Sustainability, The University of Sheffield, Sheffield,
Environmental impact assessment of aluminum electrolytic
Aluminum ingots (anode), aluminum ingots (cathode), case, and electricity are the main contributors to the environmental impacts, accounting for over 85% of carbon
(PDF) Introduction To Environmental
Introduction to Environmental Impact Assessment provides students and practitioners with a clearly structured overview of the subject, as well as critical analysis
Comparative life cycle assessment of lithium-ion capacitors production
The life cycle assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to evaluate the environmental burdens associated with manufacturing a 48 V lithium-ion capacitor (LIC) module.n The prospective LCA compared the environmental impact of
Environmental life cycle assessment of
The production stages of GOA and graphene oxide and stages of nitrogen-doped biochar aerogel production and Entermorpha prolifera drying were identified as the hotspots of environmental impact
(PDF) Environmental Impact Assessment as a Tool for
The EIA concept supports sustainable development through the evaluation of impacts arising from a proposed development that are likely to significantly affect the natural and manmade environment
Capacitor Factory: A Comprehensive Guide to Manufacturing and Production
In addition, we comply with all environmental regulations and standards set by the government and industry bodies. We regularly conduct environmental audits and assessments to ensure that we are operating in an environmentally responsible manner. Our commitment to minimizing our environmental impact extends beyond our factory walls.
Environmental impact assessment of aluminum electrolytic capacitors
Article "Environmental impact assessment of aluminum electrolytic capacitors in a product family from the manufacturer''s perspective" Detailed information of the J-GLOBAL is an information service managed by the Japan Science and Technology Agency (hereinafter referred to as "JST"). It provides free access to secondary information on researchers, articles, patents, etc.,
Life cycle assessment and environmental profile evaluations of
By taking the environmental impact assessments from existing lithium-ion battery technology—it is possible to derive energy density, cycle life and % active material targets required to achieve
Environmental impact assessment of aluminum electrolytic capacitors
The impact assessment method, ReCiPe2016 (midpoint, hierarchist perspective), was used to quantitatively calculate the potential environmental impacts of the AECs. Results and discussion Based on the generated LCIs of the AECs and ReCiPe2016, fossil depletion, climate change, and terrestrial ecotoxicity were identified as the key environmental impact categories
Environmental life cycle assessment of supercapacitor electrode
2.1 Definition of LCA: goal, system boundary, and functional unit. In this study, the goal was to comparatively assess the environmental performances of BA-electrode and GOA-electrode. Moreover, hotspot life cycle stages for each assessed environmental impact/damage category and each technology, and the environmental improvement potentials were also
Environmental impact assessment of aluminum
This paper analyzes and compares the life cycle environmental impacts of two major types of Li-ion batteries using process-based and integrated hybrid life-cycle assessment (LCA) approaches.
Comparative life cycle assessment of lithium-ion capacitors production
which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to evaluate the environmental burdens associated with manufacturing a 48 V lithium-ion capacitor (LIC) module. The prospective LCA compared the environmental impact of manufacturing a LIC
Environmental Impact Assessment as a Tool for Sustainable
Environmental impact assessment (EIA) is defined as the systematic identification and evaluation of the potential impacts (effects) of proposed projects, plans, programs, or legislative actions relative to the physical, chemical, biological, cultural, and socioeconomic components of the environment (Canter 1997).According to the Ministry of
Environmental impact assessment of aluminum electrolytic
A cradle-to-gate life cycle assessment (LCA) was performed to evaluate the environmental impact of 38 types of AECs in a product family from the manufacturer''s