6. LCA: InterpretationThe following figure shows the relative contributions ofdifferent Life Cycle processes and the primary energydemand in the form of a dominance analysis.Indicators of the impact assessmentThe contributions from module A1 (raw materials)dominate in almost all environmental impactcategories, except Depletion potential of thestratospheric ozone layer (ODP). Contributions fromtransport throughout the life cycle are below 1% for allenvironmental impact categories. The credits inmodule D originate from the avoided environmentaleffects in other product systems and arise almostexclusively through the recycling of steel scrap.Global warming potential (GWP)The global warming potential is mainly determined bythe supply of raw materials, i.e. by the primaryproducts. Within these, the production of steel primaryproducts, including the upstream chains for steelrecovery, has the greatest influence on the GWP factorof > 97%. However, at the end of life, the cost ofproviding the steel precursors is offset by theenvironmental benefits in the form of credits for therecycling of steel products. Along the entire life cycle,approximately 55 % of GWP emissions are credited bysteel recycling at the end of life.Depletion potential of the stratospheric ozone layer(ODP)The Ozone depletion potential is dominated by steelrecycling at the end of life (about 66 %).Acidification potential of land and water (AP)The Acidification potential is triggered to 96 % in theproduction stage by the raw material supply. Theremaining 4 % is caused by the production of the metalceiling systems itself. A credit of approximately 37 % ofthe total AP emissions along the life cycle is creditedmainly by steel recycling.Eutrophication potential (EP)The greatest contribution to the EP arises from theprovision of raw materials with 91 %, in particular dueto the high energy demand in the form of natural gasand electricity. A total of 8 % results from theproduction of metal ceilings and 1 % from the transportof primary products and auxiliary materials.8Potential of tropospheric ozone photochemicaloxidants (POCP)About 97 % of the POCP value is generated in theproduction stage by the provision of raw materials inthe form of steel sheets. Another 3 % arise from themetal ceiling manufacturing process.Abiotic depletion potential for non-fossil resources(ADPE)The ADPE value is predominantly conditioned by theproduction stage module A1. Here, mainly theupstream chain of the steel sheet contributes almost100 % to the overall ADPE.Abiotic depletion potential for fossil resources (ADPF)Within the production (A1-3), the ADPF value mainlyresults from the upstream chains in module A1 (about88 %). Almost 12 % is attributable to the production ofthe metal ceiling systems. A credit of about 52 % isobtained mainly through the recycling of the steel.Within the production (A1-3), the total primary energydemand is divided between approx. 84 % nonrenewable energy sources and approx. 16 %renewable energies.Total use of non-renewable primary energyresources (PENRT)The upstream chains associated with manufacturing ofthe preliminary products (Module A1) contribute with87 % to the production caused by the steel sheet. Theproduction of the metal ceiling systems contributesabout 13 % to non-renewable energy consumption. Acredit is issued at the end of life (48 %), which isgenerated by the recycling of the preliminary products.Total use of renewable primary energy resources(PERT)The PERT value along the entire life cycle results to64 % from the upstream chains associated with thepreliminary products (A1), and the production of themetal ceiling systems (A3) with 23 %. Another 15 % isattributable to the credit (module D) from steelrecycling.Environmental Product Declaration TAIM e.V. - Verband Industrieller Metalldeckenhersteller – Metal ceiling systemsmade of steel
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