LCA of Fibre Flax Thermal Insulation

2016 ◽  
Vol 824 ◽  
pp. 761-769
Author(s):  
Karel Struhala ◽  
Zuzana Stránská ◽  
Jiří Sedlák
Keyword(s):  
Life Cycle Assessment ◽  
Environmental Impacts ◽  
Thermal Insulation ◽  
Insulation Material ◽  
Production Facility ◽  
Chemical Additives ◽  
Fibre Flax ◽  
Gate System ◽  
Cradle To Gate ◽  
Main Components

This paper brings readers a study of Life-Cycle Assessment of thermal insulation panels made of the stems of fibre flax. This study uses cradle-to-gate system boundaries, which means that only growing and harvesting of flax and subsequent processing and manufacturing of the insulation material are included in the assessment. Transport between the facilities is also included, because it has significant impact on the results - the production facility is located in Czech Republic, but thanks to the costs main components (fibre flax stems and chemical additives) are grown or produced in various countries around the globe. The paper shows that production of such insulation material has environmental impacts comparable with other insulation materials. Conclusion of the paper includes discussion about share of individual parts of the production process (growing, harvesting, transport, processing and manufacturing) on the overall results and recommendations of changes that would lead to decrease the overall environmental impacts.

scholarly journals Environmental Life Cycle Assessment of Thermal Insulation Tiles for Flat Roofs

Materials ◽  
2019 ◽  
Vol 12 (16) ◽  
pp. 2595 ◽  
Author(s):  
Raul Gomes ◽  
José D. Silvestre ◽  
Jorge de Brito
Keyword(s):  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impacts ◽  
Thermal Insulation ◽  
Raw Materials ◽  
Environmental Costs ◽  
Economic Costs ◽  
Life Cycle Stages ◽  
Cradle To Gate ◽  
Flat Roofs

Envelope insulation and protection is an important technical solution to reduce energy consumption, exterior damage, and environmental impacts in buildings. Thermal insulation tiles are used simultaneously as thermal insulation of the building envelope and protection material of under layers in flat roofs systems. The purpose of this research is to assess the environmental impacts of the life cycle of thermal insulation tiles for flat roofs. This research presents the up-to-date “cradle to gate” environmental performance of thermal insulation tiles for the environmental categories and life-cycle stages defined in European standards on environmental evaluation of building. The results presented in this research were based on site-specific data from a Portuguese factory and resulted from a consistent methodology that is here fully described, including the raw materials extraction and production, and the modelling of energy and transport processes at the production stage of thermal insulation tiles. These results reflect the weight of the raw-materials within the production process of thermal insulation tiles in all environmental categories and show that some life cycle stages, such as transportation of raw materials (A2) and packaging and packaging waste (A3.1 and A3.3, respectively), may not be discarded in a cradle to gate study of a construction material because they can make a significant contribution to some environmental categories. Moreover, complementary results regarding the economic, environmental, and energy performance Life Cycle Assessment (LCA) of flat roofs solutions incorporating the thermal insulation tiles studied showed that the influence of the economic costs on the total aggregated costs of these solutions is much higher than that of the environmental costs due to the lower environmental costs of the thermal insulation tiles at the product stage (A1–A3). These costs influenced the corresponding percentage of the environmental costs (between 14% and 18%) and the percentage of the economic costs (between 70% and 75%) in the total aggregated (environmental, economic, and energy) net present value (NPV). Finally, a complementary “cradle to cradle” environmental LCA discussion is presented including the following additional life cycle stages: maintenance and replacement (B2–B4), operational energy use (B6), and end-of-life stage and benefits and loads beyond the system boundary (C1–C4 and D).

Considerations in Design of Centralizers for Pipe-in-Pipe Systems

2018 ◽  
Author(s):  
Soheil Manouchehri
Keyword(s):  
Heat Loss ◽  
Thermal Insulation ◽  
Insulation Material ◽  
Loading History ◽  
Pipe Systems ◽  
Main Components ◽  
Outer Pipe

For un-bonded (sliding) Pipe-In-Pipe (PIP) systems, one of the main components is the centralizers (also called spacers). The main functions of the centralizers are to centralize the inner pipe inside the outer pipe, to transfer the loads between inner pipe and outer pipe and to safeguard the insulation material in the annulus from excessive compression during fabrication, installation and operation. Centralizers must also have good thermal insulation properties so that the heat loss is minimized. Different designs are now available for centralizers but the majority are based on two half shells which are bolted together. During fabrication, installation and operation, centralizers subject to different loads under which they are required to continue functioning properly. This paper provides an overview of centralizer design aspects and then focuses on the loading history during installation using reeling method. The main contributing parameters to centralizer loading during reeled installation technique are discussed and conclusions are drawn. It is believed that this will enable Pipeline Engineers to select the most appropriate material and design for centralizers.

Study and Design of Sustainable Packaging for Household Hoods

2018 ◽  
Author(s):  
Daniele Landi ◽  
Leonardo Postacchini ◽  
Paolo Cicconi ◽  
Filippo E. Ciarapica ◽  
Michele Germani
Keyword(s):  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impacts ◽  
Secondary Data ◽  
International Standards ◽  
Primary Data ◽  
Industrialized Countries ◽  
Iso 14040 ◽  
Attributional Life Cycle Assessment ◽  
Cradle To Gate

In industrialized countries, packaging waste is one of the major issues to deal with, representing around 35% of the total municipal solid waste yearly generated. Therefore, an analysis and an environmental assessment of packaging systems are necessary. This paper aims at analyzing and comparing the environmental performances of two different packaging for domestic hoods. It shows how, through a packaging redesign, it is possible to obtain a reduction of the environmental impacts. This study has been performed in accordance with the international standards ISO 14040/14044, by using attributional Life Cycle Assessment (LCA) from Cradle to Gate. The functional unit has been defined as the packaging of a single household hood. Primary data have been provided by a household hood manufacturer, while secondary data have been obtained from the Ecoinvent database. LCA software SimaPro 8.5 has been used to carry out the life cycle assessment, and ReCiPe method has been chosen for the life cycle impact assessment (LCIA) stage. The results have shown the new packaging model being able to cut down the environmental impacts of approximately 30%. These outcomes may be used by household manufacturers to improve performances and design solutions of their different packaging.

scholarly journals Factors for Eco-Efficiency Improvement of Thermal Insulation Materials

2016 ◽  
Vol 678 ◽  
pp. 1-13 ◽  
Author(s):  
Jun Kono ◽  
Yutaka Goto ◽  
York Ostermeyer ◽  
Rolf Frischknecht ◽  
Holger Wallbaum
Keyword(s):  
Life Cycle ◽  
Physical Properties ◽  
Production Process ◽  
Environmental Impacts ◽  
Thermal Insulation ◽  
Foam Glass ◽  
Insulation Material ◽  
Contributing Factors ◽  
Insulation Materials ◽  
Thermo Physical Properties

Thermal insulation material is an important component to reduce the environmental impact of buildings through the reduction of energy consumption in the operation phase. However, the material itself has embodied environmental impacts for the value it provides. Eco-efficiency is a method that quantifies relation between the environmental performance and the created value of a product system. This study investigated contributing factors of the eco-efficiency of thermal insulation materials to support decision making of material manufacturers. For the improvement of eco-efficiency, the assessment was made in two scopes: investigating the contributing factors of impact caused at production processes; and thermal performance through thermo-physical properties. For quantifying environmental impacts, cradle-to-grave life cycle assessment (LCA) of each materials were made. The life cycle impact assessment (LCIA) indicators used were ReCiPe H/A and global warming potential (GWP100a). For the assessment of production process, the inventories of the materials were assigned to six categories: heat, chemicals, electricity, transportation, raw materials and wastes. Among the assessed materials, contribution of electricity and heat within the production process was large for foam glass which had the highest potential to improve the eco-efficiency which was by factor 1.72. The analysis on relation between thermo-physical properties and eco-efficiency based on product data of the materials highlighted the importance of density as an indicator upon development and use. Althoughdensity often gains less attention,the finding suggested the effectiveness of improving the efficiency by having lower density without compensating the performance of the materials.

Comparative process-based life-cycle assessment of bioconcrete and conventional concrete

2017 ◽  
Vol 15 (5) ◽  
pp. 667-688 ◽  
Author(s):  
Milad Soleimani ◽  
Mohsen Shahandashti
Keyword(s):  
Global Warming ◽  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impacts ◽  
Global Warming Potential ◽  
Fossil Fuel ◽  
Human Toxicity ◽  
Conventional Concrete ◽  
Content Type ◽  
Cradle To Gate

Purpose Bioconcrete is widely believed to be environmentally beneficial over conventional concrete. However, the process of bioconcrete production involves several steps, such as waste recovery and treatment, that potentially present significant environmental impacts. Existing life-cycle assessments of bioconcrete are limited in the inventory and impact analysis; therefore, they do not consider all the steps involved in concrete production and the corresponding impacts. The purpose of this study is to extensively study the cradle-to-gate environmental impacts of all the production stages of two most common bioconcrete types (i.e. sludge-based bioconcrete and cement kiln dust-rice husk ash (CKD-RHA) bioconcrete) as opposed to conventional concrete. Design/methodology/approach A cradle-to-gate life-cycle assessment process model is implemented to systematically analyze and quantify the resources consumed and the environmental impacts caused by the production of bioconcrete as opposed to the production of conventional concrete. The impacts analyzed in this assessment include global warming potential, ozone depletion potential, eutrophication, acidification, ecotoxicity, smog, fossil fuel use, human toxicity, particulate air and water consumption. Findings The results indicated that sludge-based bioconcrete had higher levels of global warming potential, eutrophication, acidification, ecotoxicity, fossil fuel use, human toxicity and particulate air than both conventional concrete and CKD-RHA bioconcrete. Originality/value The contribution of this study to the state of knowledge is that it sheds light on the hidden impacts of bioconcrete. The contribution to the state of practice is that the results of this study inform the bioconcrete production designers about the production processes with the highest impact.

scholarly journals Life Cycle Assessment of North American Laminated Strand Lumber (LSL) Production

2021 ◽  
Vol 3 (4) ◽  
pp. 1-1
Author(s):  
Poonam Khatri ◽  
◽  
Kamalakanta Sahoo ◽  
Richard Bergman ◽  
Maureen Puettmann ◽  
...  
Keyword(s):  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impacts ◽  
North American ◽  
Wood Products ◽  
Resource Extraction ◽  
Study Results ◽  
Cradle To Gate ◽  
Whole Life Cycle ◽  
Lca Results

Raw materials for buildings and construction account for more than 35% of global primary energy use and nearly 40% of energy-related CO2 emissions. The Intergovernmental Panel on Climate Change (IPCC) emphasized the drastic reduction in GHG emissions and thus, wood products with very low or negative carbon footprint materials can play an important role. In this study, a cradle-to-grave life cycle assessment (LCA) approach was followed to quantify the environmental impacts of laminated strand lumber (LSL). The inventory data represented North American LSL production in terms of input materials, including wood and resin, electricity and fuel use, and production facility emissions for the 2019 production year. The contribution of cradle-to-gate life cycle stages was substantial (>70%) towards the total (cradle-to-grave) environmental impacts of LSL. The cradle-to-gate LCA results per m³ LSL were estimated to be 275 kg CO2 eq global warming, 39.5 kg O3eq smog formation, 1.7 kg SO2 eq acidification, 0.2 kg N eq eutrophication, and 598 MJ fossil fuel depletion. Resin production as a part of resource extraction contributed 124 kg CO2 eq (45%). The most relevant unit processes in their decreasing contribution to their cradle-to-grave GW impacts were resource extraction, end-of-life (EoL), transportation (resources and product), and LSL manufacturing. Results of sensitivity analysis showed that the use of adhesive, consumption of electricity, and transport distance had the greatest influences on the LCA results. Considering the whole life cycle of the LSL, the final product stored 1,010 kg CO2 eq/m³ of LSL, roughly two times more greenhouse gas emissions over than what was released (493 kg CO2 eq/m³ of LSL) from cradle-to-grave. Overall, LSL has a negative GW impact and acts as a carbon sink if used in the construction sector. The study results are intended to be important for future studies, including waste disposal and recycling strategies to optimize environmental trade-offs.

scholarly journals Environmental Impacts of Styrene-Butadiene-Styrene Toughened Wood Fiber/Polylactide Composites: A Cradle-to-Gate Life Cycle Assessment

2019 ◽  
Vol 16 (18) ◽  
pp. 3402
Author(s):  
Tao Qiang ◽  
Yaxuan Chou ◽  
Honghong Gao
Keyword(s):  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impacts ◽  
Natural Fiber ◽  
Wood Fiber ◽  
Environmental Benefits ◽  
Cradle To Gate ◽  
Styrene Butadiene Styrene ◽  
Styrene Butadiene ◽  
Butadiene Styrene

In this study, a life cycle assessment (LCA) was used to investigate the environmental benefits of using styrene-butadiene-styrene (SBS) to modify polylactide (PLA)-based wood plastic composites (WPCs), with a process-based and input–output hybrid model. The results showed that one metric ton of the SBS-modified WPCs required 1.93 × 108 kJ of energy (Sample 2) and 46 m3 of water (Sample 4), and that it could produce 42.3 kg of solid waste (Sample 2) during its cradle-to-gate life cycle phases. The environmental impact load (EIL) and photochemistry oxidation potential (PCOP) accounted for the largest share, while the eutrophication potential (EP) took the smallest one. The total EIL index of Samples 1, 2, 3, and 4 added up to 1.942, 1.960, 1.899, and 1.838, respectively. The SBS-modified WPCs were found to be more environmentally friendly than their unmodified counterparts when they had the same or higher wood fiber (WF) content. SBS was viable to toughen the PLA-based WPCs from an environmental perspective. This cradle-to-gate LCA is likely to help optimize the manufacturing process and mitigate environmental impacts for the natural fiber-reinforced polymer biocomposites.

scholarly journals Impact of the Degree Days of the Heating Period on Economically and Ecologically Optimal Thermal Insulation Thickness

Energies ◽  
2020 ◽  
Vol 14 (1) ◽  
pp. 97
Author(s):  
Robert Dylewski ◽  
Janusz Adamczyk
Keyword(s):  
Life Cycle Assessment ◽  
Life Cycle ◽  
Heat Source ◽  
Thermal Insulation ◽  
Insulation Material ◽  
Heating Period ◽  
Degree Days ◽  
Ecological Analysis ◽  
Ecological Benefits ◽  
Insulation Thickness

The article proposes methods for determining the optimal thermal insulation thickness for economic and ecological reasons, depending on the number of degree days of the heating period. Life cycle assessment was used for the ecological analysis. Analyses were performed for selected variants typical of Polish conditions. The optimal thermal insulation thickness as well as the amount of economic and ecological benefits depends very much on the condition of the building without thermal insulation, but also on the heat source used and the thermal insulation material to be used. For each variant, the optimal thermal insulation thickness for ecological reasons is much greater than the optimal for economic reasons. Taking into consideration the climatic zone and the associated number of degree days of the heating period, the colder the zone, the greater the optimal insulation thickness, as well as economic and ecological benefits.

scholarly journals Environmental Impact and Life Cycle Assessment of Economically Optimized Thermal Insulation Materials for Different Climatic Region in Iraq

2018 ◽  
Vol 7 (4.37) ◽  
pp. 163
Author(s):  
Murad Saeed Sedeeq ◽  
Shadan Kareem Ameen ◽  
Ali Bolatturk
Keyword(s):  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impact ◽  
Thermal Insulation ◽  
Impact Analysis ◽  
Expanded Polystyrene ◽  
Insulation Material ◽  
Insulation Materials ◽  
Climatic Regions ◽  
Damage Categories

Environmental pollution is one of the biggest problems facing the world, even it is the most dangerous. Therefore, it becomes necessary to combine all efforts to reduce or eliminate it. Iraq is at the forefront of countries that suffer from major environmental problems. The present study aims to perform a comparative environmental assessment for three commonly available thermal insulation materials in Iraq namely expanded polystyrene (EPS), extruded polystyrene (XPS), and rock wool (RW) to select least environmental impact material. A cradle to gate life cycle assessment is performed to assess the environmental impact of each insulation material taking into account manufacturing, transportation, and installation and disposal stages. A life cycle assessment program SimaPro is used to model thermal insulation materials during its life cycle. A life cycle impact analysis method CML 2001 has been selected to assess the environmental aspects associated with two global damage categories as ozone layer depletion and global warming and two regional damage categories as acidification and eutrophication. Economically optimized amount of each insulation material is selected to represent the functional unit of life cycle assessment. The results illustrate that the EPS has the lower contribution in all environmental impact categories for all climatic regions. So, the EPS can be select as a proper thermal insulation material for the building sector from an economic and environmental perspective. The results of LCA are used to determine the amount of CO2 can be reduced per meter square of the exterior wall by using the economical amount of EPS during the lifetime of insulation material. The environmental impact results show that using EPS will contribute in CO2 emission reduction at about 81.5 % in all climatic regions in Iraq. 

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