Evaluation of Environmental Impact of Cement Production in Algeria Using Life Cycle Assessment

The aim of this study is the use of Life Cycle Assessment, to evaluate the impact generated by cement manufactory situated in Sour EL Ghozlane town in Algeria country, which use the dry process to produce cement Portland. The LCA method is used for compiling and examining the inputs and outputs of energy, raw material and environmental impacts directly attributable to the manufacture and functioning of a product throughout its life. It is also used to determine element and energy contributing to each impact evaluated. Potentials impacts are evaluated using the SimaProV.7.1 software and IMPACT2000+ method in this study.

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Environmental Impact for 3D Bone Tissue Engineering Scaffolds Life Cycle: An Assessment

Biointerface Research in Applied Chemistry ◽

10.33263/briac125.65046515 ◽

2021 ◽

Vol 12 (5) ◽

pp. 6504-6515

Keyword(s):

Tissue Engineering ◽

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Bone Tissue Engineering ◽

Bone Tissue ◽

Environmental Impacts ◽

Tissue Engineering Scaffolds ◽

Industrial Soil ◽

The Impact

With the development of additive manufacturing technology, 3D bone tissue engineering scaffolds have evolved. Bone tissue engineering is one of the techniques for repairing bone abnormalities caused by a variety of circumstances, such as injuries or the need to support damaged sections. Many bits of research have gone towards developing 3D bone tissue engineering scaffolds all across the world. The assessment of the environmental impact, on the other hand, has received less attention. As a result, the focus of this study is on developing a life cycle assessment (LCA) model for 3D bone tissue engineering scaffolds and evaluating potential environmental impacts. One of the methodologies to evaluating a complete environmental impact assessment is life cycle assessment (LCA). The cradle-to-grave method will be used in this study, and GaBi software was used to create the analysis for this study. Previous research on 3D bone tissue engineering fabrication employing poly(ethylene glycol) diacrylate (PEGDA) soaked in dimethyl sulfoxide (DMSO), and diphenyl (2,4,6-trimethylbenzoyl) phosphine oxide (TPO) as a photoinitiator will be reviewed. Meanwhile, digital light processing (DLP) 3D printing is employed as the production technique. The GaBi program and the LCA model developed to highlight the potential environmental impact. This study shows how the input and output of LCA of 3D bone tissue engineering scaffolds might contribute to environmental issues such as air, freshwater, saltwater, and industrial soil emissions. The emission contributing to potential environmental impacts comes from life cycle input, electricity and transportation consumption, manufacturing process, and material resources. The results from this research can be used as an indicator for the researcher to take the impact of the development of 3D bone tissue engineering on the environment seriously.

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An Environmental Evaluation of the Cut-Flower Supply Chain (Dendranthema grandiflora) Through a Life Cycle Assessment

Revista EIA ◽

10.24050/reia.v16i31.747 ◽

2019 ◽

Vol 16 (31) ◽

pp. 27-42 ◽

Cited By ~ 2

Author(s):

Carmen Alicia Parrado Moreno ◽

Ricardo Esteba Ricardo Hernández ◽

Héctor Iván Velásquez Arredondo ◽

Sergio Hernando Lopera Castro ◽

Christian Hasenstab --

Keyword(s):

Life Cycle Assessment ◽

Supply Chain ◽

Life Cycle ◽

Environmental Impact ◽

Environmental Impacts ◽

Raw Material ◽

Cut Flowers ◽

Environmental Evaluation ◽

Fertilizer Use ◽

Transport Phase

Colombia is a major flower exporter of a wide variety of species, among which the chrysanthemum plays a major role due to its exporting volume and profitability on the international market. This study examines the major environmental impacts of the chrysanthemum supply chain through a life cycle assessment (LCA). One kg of stems export quality was used as the functional unit (FU). The study examines cut-flowers systems from raw material extraction to final product commercialization for two markets (London and Miami) and analyzes two agroecosystems: one certified system and one uncertified system. The transport phase to London resulted in more significant environmental impacts than the transport phase to Miami, and climate change (GWP100) category was significant in both cities, generating values of 9.10E+00 and 2.51E+00 kg CO2-eq*FU for London and Miami, respectively. Furthermore, when exclusively considering pre-export phases, the uncertified system was found to have a greater impact than the certified system with respect to fertilizer use (certified 1,448E-02 kg*FU, uncertified 2.23E-01 kg*FU) and pesticide use (certified 1.24 E-04 kg*FU, uncertified 2.24E-03 kg*FU). With respect to the crop management, eutrophication (EP) and acidification (AP) processes imposed the greatest level of environmental impact. Strategies that would significantly reduce the environmental impact of this supply chain are considered, including the use of shipping and a 50% reduction in fertilizer use.

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Life Cycle Assessment of an NMC Battery for Application to Electric Light-Duty Commercial Vehicles and Comparison with a Sodium-Nickel-Chloride Battery

Applied Sciences ◽

10.3390/app11031160 ◽

2021 ◽

Vol 11 (3) ◽

pp. 1160

Author(s):

Antonella Accardo ◽

Giovanni Dotelli ◽

Marco Luigi Musa ◽

Ezio Spessa

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Environmental Impacts ◽

Nickel Chloride ◽

Impact Categories ◽

Commercial Vehicles ◽

Light Duty ◽

Electric Light ◽

The Impact

This paper presents the results of an environmental assessment of a Nickel-Manganese-Cobalt (NMC) Lithium-ion traction battery for Battery Electric Light-Duty Commercial Vehicles (BEV-LDCV) used for urban and regional freight haulage. A cradle-to-grave Life Cycle Inventory (LCI) of NMC111 is provided, operation and end-of-life stages are included, and insight is also given into a Life Cycle Assessment of different NMC chemistries. The environmental impacts of the manufacturing stages of the NMC111 battery are then compared with those of a Sodium-Nickel-Chloride (ZEBRA) battery. In the second part of the work, two electric-battery LDCVs (powered with NMC111 and ZEBRA batteries, respectively) and a diesel urban LDCV are analysed, considering a wide set of environmental impact categories. The results show that the NMC111 battery has the highest impacts from production in most of the impact categories. Active cathode material, Aluminium, Copper, and energy use for battery production are the main contributors to the environmental impact. However, when vehicle application is investigated, NMC111-BEV shows lower environmental impacts, in all the impact categories, than ZEBRA-BEV. This is mainly due to the greater efficiency of the NMC111 battery during vehicle operation. Finally, when comparing BEVs to a diesel LDCV, the electric powertrains show advantages over the diesel one as far as global warming, abiotic depletion potential-fossil fuels, photochemical oxidation, and ozone layer depletion are concerned. However, the diesel LDCV performs better in almost all the other investigated impact categories.

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Environmental Impact Assessment of Thai Minced Fish Paste (Surimi) Using Life Cycle Assessment Methodology

Environmental Research Engineering and Management ◽

10.5755/j01.erem.76.3.21928 ◽

2020 ◽

Vol 76 (3) ◽

pp. 137-153

Author(s):

Harnpon Phungrassami ◽

Phairat Usubharatana

Keyword(s):

Global Warming ◽

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Fuel Consumption ◽

Environmental Impacts ◽

Electricity Consumption ◽

Impact Categories ◽

Allocation Method ◽

The Impact

Environmental impacts of fishery production have resulted in increased concern and awareness. Thailand, as one of the largest global fish exporters, faces challenges related to environmental problems caused by fishery processes. Here, the environmental impact of Thai surimi production was estimated based on life cycle assessment (LCA) methodology, focusing specifically on two Thai surimi products made from goatfish and ponyfish caught within the southern region of Thailand. Three impact categories where explored: global warming, acidification and eutrophication. Life cycle impacts were calculated for one kg of product using both mass and economic allocations. Results of this study indicated that goatfish has lower impacts than ponyfish for all the impact categories. Fuel consumption during the fishery phase and electricity consumption during processing were the main parameters leading to most of the considered environmental impacts. The value of Global Warming Potential(GWP) ranged within 1.3‒3.0 kg CO2eq for goatfish and 2.2‒7.1 kg CO2eq ponyfish depending on the allocation method. The acidification impact of goatfish and ponyfish were revealed at 3.2‒7.3 gSO2eq and 12.7‒39.7 gSO2eq, respectively. The eutrophication of goatfish and ponyfish were 0.7‒1.6 gPO4eq and 2.5‒8.1 gPO4eq, respectively. Sensitivity analysis of fuel consumption, electricity consumption, product yield and allocation method were evaluated.

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Life Cycle Assessment (LCA) of an Innovative Compact Hybrid Electrical-Thermal Storage System for Residential Buildings in Mediterranean Climate

Sustainability ◽

10.3390/su13095322 ◽

2021 ◽

Vol 13 (9) ◽

pp. 5322

Author(s):

Gabriel Zsembinszki ◽

Noelia Llantoy ◽

Valeria Palomba ◽

Andrea Frazzica ◽

Mattia Dallapiccola ◽

...

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Mediterranean Climate ◽

Residential Buildings ◽

Renewable Energy Sources ◽

Storage System ◽

Hot Water ◽

Electrical Consumption ◽

The Impact

The buildings sector is one of the least sustainable activities in the world, accounting for around 40% of the total global energy demand. With the aim to reduce the environmental impact of this sector, the use of renewable energy sources coupled with energy storage systems in buildings has been investigated in recent years. Innovative solutions for cooling, heating, and domestic hot water in buildings can contribute to the buildings’ decarbonization by achieving a reduction of building electrical consumption needed to keep comfortable conditions. However, the environmental impact of a new system is not only related to its electrical consumption from the grid, but also to the environmental load produced in the manufacturing and disposal stages of system components. This study investigates the environmental impact of an innovative system proposed for residential buildings in Mediterranean climate through a life cycle assessment. The results show that, due to the complexity of the system, the manufacturing and disposal stages have a high environmental impact, which is not compensated by the reduction of the impact during the operational stage. A parametric study was also performed to investigate the effect of the design of the storage system on the overall system impact.

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Life Cycle Assessment of Households in Santiago, Chile: Environmental Hotspots and Policy Analysis

Sustainability ◽

10.3390/su13052525 ◽

2021 ◽

Vol 13 (5) ◽

pp. 2525

Author(s):

Camila López-Eccher ◽

Elizabeth Garrido-Ramírez ◽

Iván Franchi-Arzola ◽

Edmundo Muñoz

Keyword(s):

Global Warming ◽

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impacts ◽

Food Consumption ◽

Household Income ◽

Resource Scarcity ◽

Life Cycles ◽

The Impact ◽

Freshwater Eutrophication

The aim of this study is to assess the environmental impacts of household life cycles in Santiago, Chile, by household income level. The assessment considered scenarios associated with environmental policies. The life cycle assessment was cradle-to-grave, and the functional unit considered all the materials and energy required to meet an inhabitant’s needs for one year (1 inh/year). Using SimaPro 9.1 software, the Recipe Midpoint (H) methodology was used. The impact categories selected were global warming, fine particulate matter formation, terrestrial acidification, freshwater eutrophication, freshwater ecotoxicity, mineral resource scarcity, and fossil resource scarcity. The inventory was carried out through the application of 300 household surveys and secondary information. The main environmental sources of households were determined to be food consumption, transport, and electricity. Food consumption is the main source, responsible for 33% of the environmental impacts on global warming, 69% on terrestrial acidification, and 29% on freshwater eutrophication. The second most crucial environmental hotspot is private transport, whose contribution to environmental impact increases as household income rises, while public transport impact increases in the opposite direction. In this sense, both positive and negative environmental effects can be generated by policies. Therefore, life-cycle environmental impacts, the synergy between policies, and households’ socio-economic characteristics must be considered in public policy planning and consumer decisions.

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Attributional & Consequential Life Cycle Assessment: Definitions, Conceptual Characteristics and Modelling Restrictions

Sustainability ◽

10.3390/su13137386 ◽

2021 ◽

Vol 13 (13) ◽

pp. 7386

Author(s):

Thomas Schaubroeck ◽

Simon Schaubroeck ◽

Reinout Heijungs ◽

Alessandra Zamagni ◽

Miguel Brandão ◽

...

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Product Life Cycle ◽

Sustainability Assessment ◽

Consequential Life Cycle Assessment ◽

Modelling Framework ◽

Potential Environmental Impact ◽

Reference Environment ◽

The Impact

To assess the potential environmental impact of human/industrial systems, life cycle assessment (LCA) is a very common method. There are two prominent types of LCA, namely attributional (ALCA) and consequential (CLCA). A lot of literature covers these approaches, but a general consensus on what they represent and an overview of all their differences seems lacking, nor has every prominent feature been fully explored. The two main objectives of this article are: (1) to argue for and select definitions for each concept and (2) specify all conceptual characteristics (including translation into modelling restrictions), re-evaluating and going beyond findings in the state of the art. For the first objective, mainly because the validity of interpretation of a term is also a matter of consensus, we argue the selection of definitions present in the 2011 UNEP-SETAC report. ALCA attributes a share of the potential environmental impact of the world to a product life cycle, while CLCA assesses the environmental consequences of a decision (e.g., increase of product demand). Regarding the second objective, the product system in ALCA constitutes all processes that are linked by physical, energy flows or services. Because of the requirement of additivity for ALCA, a double-counting check needs to be executed, modelling is restricted (e.g., guaranteed through linearity) and partitioning of multifunctional processes is systematically needed (for evaluation per single product). The latter matters also hold in a similar manner for the impact assessment, which is commonly overlooked. CLCA, is completely consequential and there is no limitation regarding what a modelling framework should entail, with the coverage of co-products through substitution being just one approach and not the only one (e.g., additional consumption is possible). Both ALCA and CLCA can be considered over any time span (past, present & future) and either using a reference environment or different scenarios. Furthermore, both ALCA and CLCA could be specific for average or marginal (small) products or decisions, and further datasets. These findings also hold for life cycle sustainability assessment.

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Methodology for the quantification of concrete sustainability

MATEC Web of Conferences ◽

10.1051/matecconf/201817401006 ◽

2018 ◽

Vol 174 ◽

pp. 01006 ◽

Cited By ~ 1

Author(s):

Břetislav Teplý ◽

Tomáš Vymazal ◽

Pavla Rovnaníková

Keyword(s):

Decision Making ◽

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Service Life ◽

Circular Economy ◽

Point Of View ◽

Raw Material ◽

Load Bearing Capacity ◽

Sustainability Management

Efficient sustainability management requires the use of tools which allow material, technological and construction variants to be quantified, measured or compared. These tools can be used as a powerful marketing aid and as support for the transition to “circular economy”. Life Cycle Assessment (LCA) procedures are also used, aside from other approaches. LCA is a method that evaluates the life cycle of a structure from the point of view of its impact on the environment. Consideration is given also to energy and raw material costs, as well as to environmental impact throughout the life cycle - e.g. due to emissions. The paper focuses on the quantification of sustainability connected with the use of various types of concrete with regard to their resistance to degradation. Sustainability coefficients are determined using information regarding service life and "eco-costs". The aim is to propose a suitable methodology which can simplify decision-making in the design and choice of concrete mixes from a wider perspective, i.e. not only with regard to load-bearing capacity or durability.

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Analysis of the Characteristics of Environmental Impacts According to the Cut-Off Criteria Applicable to the Streamlined Life Cycle Assessment (S-LCA) of Apartment Buildings in South Korea

Sustainability ◽

10.3390/su13052898 ◽

2021 ◽

Vol 13 (5) ◽

pp. 2898

Author(s):

Rakhyun Kim ◽

Myung-Kwan Lim ◽

Seungjun Roh ◽

Won-Jun Park

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Environmental Impacts ◽

Impact Analysis ◽

Impact Categories ◽

Environmental Impact Analysis ◽

Apartment Buildings ◽

Environmental Impact Categories ◽

Weight Percentile

This study analyzed the characteristics of the environmental impacts of apartment buildings, a typical housing type in South Korea, as part of a research project supporting the streamlined life cycle assessment (S-LCA) of buildings within the G-SEED (Green Standard for Energy and Environmental Design) framework. Three recently built apartment building complexes were chosen as study objects for the quantitative evaluation of the buildings in terms of their embodied environmental impacts (global warming potential, acidification potential, eutrophication potential, ozone layer depletion potential, photochemical oxidant creation potential, and abiotic depletion potential), using the LCA approach. Additionally, we analyzed the emission trends according to the cut-off criteria of the six environmental impact categories by performing an S-LCA with cut-off criteria 90–99% of the cumulative weight percentile. Consequently, we were able to present the cut-off criterion best suited for S-LCA and analyze the effect of the cut-off criteria on the environmental impact analysis results. A comprehensive environmental impact analysis of the characteristics of the six environmental impact categories revealed that the error rate was below 5% when the cut-off criterion of 97.5% of the cumulative weight percentile was applied, thus verifying its validity as the optimal cut-off criterion for S-LCA.

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Der Umsatz-Nachhaltigkeitsindex*/The Turnover-Sustainability-Index

wt Werkstattstechnik online ◽

10.37544/1436-4980-2016-03-40 ◽

2016 ◽

Vol 106 (03) ◽

pp. 136-140

Author(s):

R. Miehe ◽

M. Wiedenmann ◽

T. Prof. Bauernhansl

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Environmental Impacts ◽

Sustainability Index ◽

Behavior Based ◽

Comparative Examination

Die Ökobilanz hat sich als Instrument zur Bewertung der Umweltauswirkungen von Produkten und Prozessen durchgesetzt. Dennoch stellt ihre Durchführung Nutzer immer wieder vor Herausforderungen. Der Fachartikel präsentiert einen Ansatz für eine vergleichende Betrachtung der ökologischen Auswirkungen des unternehmerischen Handelns auf Basis der jeweiligen Unternehmens- und Branchenumsätze. Der Umsatz-Nachhaltigkeitsindex soll als Konzept für ein Benchmark für Unternehmen einer Branche dienen.   Life Cycle Assessment has prevailed as an instrument to evaluate the environmental impact of products and processes. Its execution, however, poses a challenge to operators. In this paper, we present an approach for a comparative examination of environmental impacts of industrial behavior based on the turnover of companies and their equivalent sectors. The Turnover-Sustainability-Index serves as a benchmark for companies within a sector.

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