087060d4-acf4-42f8-8145-ae4822e5c81cSteel sheet EGBF route - Flat C-steelproduction mix, at plantSteel sheet 0.75mm EG (0.01mm Zn; 2sides)Electrogalvanized steel (EG)ProcessesProductionMaterial productionMetal productionThe data set covers all relevant process steps / technologies over the supply chain of the represented cradle to gate inventory with a good overall data quality. The inventory is mainly based on industry data and is completed, where necessary, by secondary data.99The data set represents the country / region specific situation, focusing on the main technologies, the region specific characteristics and / or import statistics.The data set represents the steel production in Germany based on the main production steps which take place within an integrated steel plant. These production steps as well as the main upstream process steps are described in the following. The main primary products are iron ore, pellets and hard coal. The import mix for the German steel production concerning iron ore and pellets is: Canada 50%, Brazil 25%, Australia 25%. The import mix for the German steel production concerning hard coal is: 100% Canada. The iron ore mining is explained in detail in the respective documentation file (please see link below). The preparation of the iron ore includes mainly the crushing. The average iron content in the iron ore is 60%. Pellets are small crystallized balls of iron ore. The pelletisation process consists of grinding and drying, balling and induration followed by screening and handling. The provision of hard coal is described in the respective documentation file (please see link below). For every fraction the transport to Germany is considered in the data set. The transportation includes all necessary transportation means like ship and where required railway. The coke oven produces as main product coke out of hard coal. The main by-product resulting from this operation is coke oven gas (COG gas) which is used as energy carrier within the steel production. Further by-products as tar, benzene and sulphur are sold and therefore excluded from the system by allocation to (net) calorific value. In the sinter plant sinter feed is produced based on the major inputs coke, iron ore and additives. Sintering is an agglomeration process which takes place under high temperatures. The raw materials (fine iron ore, coke breeze, additives) are blended, then the coke breeze is ignited. The result of the sinter process is the so-called sinter cake which has to be broken up, screened and cooled down. The blast furnace is a closed system into which iron bearing materials (iron ore lump, sinter and / or pellets), additives (slag formers such as limestone) and reducing agents (coke) are continuously fed from the top of the furnace shaft through a charging system. A hot air blast, enriched with oxygen and auxiliary reducing agents (e.g. pulverized coal) is injected providing a counter-current of reducing gases. The air blast reacts with the reducing agents to produce mainly carbon monoxide which in turn reduces iron oxides to metal iron. The main products of the blast furnace operation are hot metal, blast furnace gas (BF gas) and blast furnace slag (BF slag). The BF gas is used as fuel for heating comparable to the COG gas or for electricity production. The objective in oxygen steelmaking is to burn (i.e., oxidise) the undesirable impurities contained in the metallic feedstock. The main elements thus converted into oxides are carbon, silicon, manganese, phosphorus and sulphur. The purpose of this oxidation process, therefore, are to reduce the carbon content to a specified level to adjust the contents of desirable foreign elements and to remove undesirable impurities to the greatest possible extent. The production of steel by the basic oxygen furnace (BOF) process is a discontinuous process which involves the following steps: transfer and storage of hot metal, pre-treatment of hot metal (desulphurisation), oxidation in the BOF (decarburisation and oxidation of impurities) and secondary metallurgical treatment (e.g. vacuum treatment and adding alloying elements). Within the main step of the oxygen steelmaking, the hot metal feeds together with steel scrap the converter. The main products of the converter are the liquid steel, the converter gas or basic oxygen furnace gas (BOF gas) and the BOF slag. The gas is as well used as energy carrier within the steel production. Afterwards the continuous casting takes place whereby the liquid steel is cast in continuous strand. The output of the continuous casting process is the slab. The following operations are two rolling processes: the hot strip mill and the cold rolling mill. In the hot rolling mill the slab is reshaped above the recrystallization temperature. The qualities obtained in this process are e.g. strength and surface quality. During the rolling process the material passes through the furnace and the rolling line. In the furnace the metal is preheated by natural gas. There is no need for an additional warming, if the hot slabs are directly charged into the rolling mill. The forming is done in various rolling frames until the final shape is obtained. The steel scrap in this process are directly recycled. In the cold rolling mill the material is reshaped below the recrystallization temperature. Thereby a enhanced surface quality, an improved dimensional accuracy as well as a higher strength are achieved. The different process steps are: pickling, the rolling line and the heat treatment. The electro-galvanising is mainly used for the galvanisation of outside parts, having the highest requirements on the parts surface (e.g. automotive industry). The cold rolled strip runs through the electro-galvanisation process whereby the metal strip serves as cathode. The zinc is fixed on the metal in the electrolysis bath with the help of electric power.
The background system is addressed as follows: Electricity, Thermal energy: The electricity (and thermal energy as by-product) used is modelled according to the individual country-specific situation. The country-specific modelling is achieved on multiple levels. Firstly the individual power plants in service are modelled according to the current national grid. This includes net losses and imported electricity. Second, the national emission and efficiency standards of the power plants are modelled. Third, the country-specific fuel supply (share of resources used, by import and / or domestic supply) including the country-specific properties (e.g. element and energy contents) are accounted for. Fourth, the import, transport, mining and exploration processes for the energy carrier supply chain are modelled according to the specific situation of each power-producing country. The different mining and exploration techniques (emissions and efficiencies) in the different exploration countries are accounted for according to current engineering knowledge and information. Steam: The steam supply is modelled according to the individual country-specific situation with regard to the technology efficiencies and energy carriers used. Efficiencies range from 84% to 94% in relation to the representative energy carrier (gas, oil, coal). Coal, crude oil and natural gas used for the generation of steam are modelled according to the specific import situation (see electricity). Transports: All relevant and known transport processes used are included. Overseas transport including rail and truck transport to and from major ports for imported bulk resources are included. Furthermore all relevant and known pipeline and / or tanker transport of gases and oil imports are included. Energy carriers: Coal, crude oil, natural gas and uranium are modelled according to the specific import situation (see electricity). Refinery products: Diesel, gasoline, technical gases, fuel oils, basic oils and residues such as bitumen are modelled via a country-specific, refinery parameterized model. The refinery model represents the current national standard in refinery techniques (e.g. emission level, internal energy consumption,...) as well as the individual country-specific product output spectrum, which can be quite different from country to country. Hence the refinery products used show the individual country-specific use of resources. The supply of crude oil is modelled, again, according to the country-specific crude oil situation with the respective properties of the resources.Hard coal mixZinc redistilled mixProvision of a standard technical product according to the applied technology.Metals_GLO_Carbon steel production - BF route.JPGPartly terminated systemAttributionalNoneAllocation - market valueAllocation - net calorific valueAllocation - exergetic contentAllocation - massFOREGROUND system: None. For details please see the document "GaBi Databases Modelling Principles"All data used in the calculation of the LCI results refer to net calorific value.NoneGaBi Modelling PrinciplesGaBi Water Modelling PrinciplesGaBi Agriculture Model DocumentationGaBi Land Use Change Model DocumentationGaBi Energy Modelling PrinciplesGaBi Refinery Modelling PrinciplesCut-off rules for each unit process: Coverage of at least 95 % of mass and energy of the input and output flows, and 98 % of their environmental relevance (according to expert judgement).
For further details please see the document "GaBi Databases Modelling Principles"NoneAll relevant background data such as energy and auxiliary material are taken from the GaBi Databases, keeping consistency.NoneFor details please see the document "GaBi Databases Modelling Principles"NoneKompendium "Abenteuer Stahl", 2003Best Available Techniques Reference Document on the Production of Iron and Steel., 2001Ref. Doc. on Best Available Techniques in the Ferrous Metals Processing Industry - Endentwurf 2005Stahldaten der ThyssenKrupp AG, 200495.0NoneThe data set represents a cradle to gate inventory. It can be used to characterise the supply chain situation of the respective commodity in a representative manner. Combination with individual unit processes using this commodity enables the generation of user-specific (product) LCAs.All relevant flows quantifiedCML2001 - Apr. 2015, Photochem. Ozone Creation Potential (POCP)CML2001 - Apr. 2015, Eutrophication Potential (EP)CML2001 - Apr. 2015, Freshwater Aquatic Ecotoxicity Pot. (FAETP inf.)CML2001 - Apr. 2015, Acidification Potential (AP)CML2001 - Apr. 2015, Marine Aquatic Ecotoxicity Pot. (MAETP inf.)CML2001 - Apr. 2015, Ozone Layer Depletion Potential (ODP, steady state)CML2001 - Apr. 2015, Terrestric Ecotoxicity Potential (TETP inf.)CML2001 - Apr. 2015, Human Toxicity Potential (HTP inf.)CML2001 - Apr. 2015, Global Warming Potential (GWP 100 years)CML2001 - Apr. 2015, Global Warming Potential (GWP 100 years), excl biogenic carbonCML2001 - Apr. 2015, Abiotic Depletion (ADP elements)CML2001 - Apr. 2015, Abiotic Depletion (ADP fossil)CML2001 - Apr. 2015, Global Warming Potential (GWP 100), Land Use Change only, no norm/weightCML2001 - Apr. 2015, Global Warming Potential (GWP 100), excl bio. C, incl LUC, no norm/weightCML2001 - Apr. 2015, Global Warming Potential (GWP 100), incl bio. C, incl LUC, no norm/weightAnthropogenic Abiotic Depletion Potential (AADP), TU BerlinResource depletion water, midpoint (v1.06)Resource depletion, mineral, fossils and renewables, midpoint (v1.06)Climate change midpoint, incl biogenic carbon (v1.06)Particulate matter/Respiratory inorganics midpoint (v1.06)Acidification midpoint (v1.06)Eutrophication terrestrial midpoint (v1.06)Climate change midpoint, excl biogenic carbon (v1.06)Eutrophication freshwater midpoint (v1.06)Ionizing radiation midpoint, human health (v1.06)Eutrophication marine midpoint (v1.06)Ozone depletion midpoint (v1.06)Photochemical ozone formation midpoint, human health (v1.06)Ecotoxicity freshwater midpoint (v1.06)Human toxicity midpoint, cancer effects (v1.06)Human toxicity midpoint, non-cancer effects (v1.06)IPCC AR5 GWP20, incl biogenic carbonIPCC AR5 GWP100, incl biogenic carbonIPCC AR5 GTP50, incl biogenic carbonIPCC AR5 GTP20, incl biogenic carbonIPCC AR5 GTP100, incl biogenic carbonIPCC AR5 GTP100, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP100, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP20, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, Land Use Change only, no norm/weightIPCC AR5 GWP20, Land Use Change only, no norm/weightIPCC AR5 GWP100, Land Use Change only, no norm/weightIPCC AR5 GTP50, Land Use Change only, no norm/weightIPCC AR5 GTP100, Land Use Change only, no norm/weightIPCC AR5 GWP20, excl biogenic carbonIPCC AR5 GWP100, excl biogenic carbonIPCC AR5 GTP50, excl biogenic carbonIPCC AR5 GTP20, excl biogenic carbonIPCC AR5 GTP100, excl biogenic carbonIPCC AR5 GWP100, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP20, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP100, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP20, Land Use Change only, no norm/weightIPCC AR5 GWP100, Land Use Change only, no norm/weightIPCC AR5 GTP50, Land Use Change only, no norm/weightIPCC AR5 GTP20, Land Use Change only, no norm/weightIPCC AR5 GTP100, Land Use Change only, no norm/weightPrimary energy from non renewable resources (gross cal. value)Primary energy from non renewable resources (net cal. value)Primary energy from renewable resources (gross cal. value)Primary energy from renewable resources (net cal. value)Primary energy demand from ren. and non ren. resources (net cal. value)Primary energy demand from ren. and non ren. resources (gross cal. value)ReCiPe 1.08 Endpoint (H) - Agricultural land occupationReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, default, excl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Human Health, default, excl biogenic carbonReCiPe 1.08 Endpoint (H) - Fossil depletionReCiPe 1.08 Endpoint (H) - Freshwater ecotoxicityReCiPe 1.08 Endpoint (H) - Freshwater eutrophicationReCiPe 1.08 Endpoint (H) - Human toxicityReCiPe 1.08 Endpoint (H) - Ionising radiationReCiPe 1.08 Endpoint (H) - Marine ecotoxicityReCiPe 1.08 Endpoint (H) - Metal depletionReCiPe 1.08 Endpoint (H) - Ozone depletionReCiPe 1.08 Endpoint (H) - Particulate matter formationReCiPe 1.08 Endpoint (H) - Photochemical oxidant formationReCiPe 1.08 Endpoint (H) - Terrestrial acidificationReCiPe 1.08 Endpoint (H) - Terrestrial ecotoxicityReCiPe 1.08 Endpoint (H) - Urban land occupationReCiPe 1.08 Midpoint (H) - Agricultural land occupationReCiPe 1.08 Midpoint (H) - Climate change, default, excl biogenic carbonReCiPe 1.08 Midpoint (H) - Fossil depletionReCiPe 1.08 Midpoint (H) - Freshwater ecotoxicityReCiPe 1.08 Midpoint (H) - Freshwater eutrophicationReCiPe 1.08 Midpoint (H) - Human toxicityReCiPe 1.08 Midpoint (H) - Ionising radiationReCiPe 1.08 Midpoint (H) - Marine ecotoxicityReCiPe 1.08 Midpoint (H) - Marine eutrophicationReCiPe 1.08 Midpoint (H) - Metal depletionReCiPe 1.08 Midpoint (H) - Natural land transformationReCiPe 1.08 Midpoint (H) - Particulate matter formationReCiPe 1.08 Midpoint (H) - Photochemical oxidant formationReCiPe 1.08 Midpoint (H) - Terrestrial acidificationReCiPe 1.08 Midpoint (H) - Terrestrial ecotoxicityReCiPe 1.08 Midpoint (H) - Urban land occupationReCiPe 1.08 Midpoint (H) - Water depletionReCiPe 1.08 Midpoint (H) - Ozone depletionReCiPe 1.08 Endpoint (H) - Natural land transformationReCiPe 1.08 Midpoint (H) - Climate change, incl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, incl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Human Health, incl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Human Health, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (H) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Human Health, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (H) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (H) - Climate change, LUC only, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, LUC only, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Human Health, LUC only, no norm/weightReCiPe 1.08 Midpoint (E) - Climate change, default, excl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, default, excl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Human Health, default, excl biogenic carbonReCiPe 1.08 Endpoint (E) - Freshwater eutrophicationReCiPe 1.08 Midpoint (E) - Freshwater eutrophicationReCiPe 1.08 Midpoint (E) - Marine eutrophicationReCiPe 1.08 Endpoint (E) - Ozone depletionReCiPe 1.08 Midpoint (E) - Ozone depletionReCiPe 1.08 Endpoint (E) - Terrestrial acidificationReCiPe 1.08 Midpoint (E) - Terrestrial acidificationReCiPe 1.08 Endpoint (E) - Photochemical oxidant formationReCiPe 1.08 Midpoint (E) - Photochemical oxidant formationReCiPe 1.08 Endpoint (E) - Particulate matter formationReCiPe 1.08 Midpoint (E) - Particulate matter formationReCiPe 1.08 Endpoint (E) - Ionising radiationReCiPe 1.08 Midpoint (E) - Ionising radiationReCiPe 1.08 Endpoint (E) - Agricultural land occupationReCiPe 1.08 Endpoint (E) - Urban land occupationReCiPe 1.08 Midpoint (E) - Agricultural land occupationReCiPe 1.08 Midpoint (E) - Urban land occupationReCiPe 1.08 Endpoint (E) - Natural land transformationReCiPe 1.08 Midpoint (E) - Natural land transformationReCiPe 1.08 Midpoint (E) - Fossil depletionReCiPe 1.08 Endpoint (E) - Fossil depletionReCiPe 1.08 Endpoint (E) - Metal depletionReCiPe 1.08 Midpoint (E) - Metal depletionReCiPe 1.08 Midpoint (E) - Water depletionReCiPe 1.08 Midpoint (E) - Terrestrial ecotoxicityReCiPe 1.08 Midpoint (E) - Marine ecotoxicityReCiPe 1.08 Midpoint (E) - Human toxicityReCiPe 1.08 Midpoint (E) - Freshwater ecotoxicityReCiPe 1.08 Endpoint (E) - Terrestrial ecotoxicityReCiPe 1.08 Endpoint (E) - Marine ecotoxicityReCiPe 1.08 Endpoint (E) - Human toxicityReCiPe 1.08 Endpoint (E) - Freshwater ecotoxicityReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, incl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Human Health, incl biogenic carbonReCiPe 1.08 Midpoint (E) - Climate change, incl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Human Health, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (E) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (E) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Human Health, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, LUC only, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Human Health, LUC only, no norm/weightReCiPe 1.08 Midpoint (E) - Climate change, LUC only, no norm/weightReCiPe 1.08 Endpoint (I) - Natural land transformationReCiPe 1.08 Midpoint (I) - Ozone depletionReCiPe 1.08 Midpoint (I) - Climate change, default, excl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, default, excl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Human Health, default, excl biogenic carbonReCiPe 1.08 Endpoint (I) - Freshwater eutrophicationReCiPe 1.08 Midpoint (I) - Freshwater eutrophicationReCiPe 1.08 Midpoint (I) - Marine eutrophicationReCiPe 1.08 Endpoint (I) - Ozone depletionReCiPe 1.08 Endpoint (I) - Terrestrial acidificationReCiPe 1.08 Midpoint (I) - Terrestrial acidificationReCiPe 1.08 Endpoint (I) - Photochemical oxidant formationReCiPe 1.08 Midpoint (I) - Photochemical oxidant formationReCiPe 1.08 Endpoint (I) - Particulate matter formationReCiPe 1.08 Midpoint (I) - Particulate matter formationReCiPe 1.08 Endpoint (I) - Ionising radiationReCiPe 1.08 Midpoint (I) - Ionising radiationReCiPe 1.08 Endpoint (I) - Agricultural land occupationReCiPe 1.08 Endpoint (I) - Urban land occupationReCiPe 1.08 Midpoint (I) - Agricultural land occupationReCiPe 1.08 Midpoint (I) - Urban land occupationReCiPe 1.08 Midpoint (I) - Natural land transformationReCiPe 1.08 Endpoint (I) - Fossil depletionReCiPe 1.08 Midpoint (I) - Fossil depletionReCiPe 1.08 Endpoint (I) - Metal depletionReCiPe 1.08 Midpoint (I) - Metal depletionReCiPe 1.08 Midpoint (I) - Water depletionReCiPe 1.08 Endpoint (I) - Freshwater ecotoxicityReCiPe 1.08 Endpoint (I) - Human toxicityReCiPe 1.08 Endpoint (I) - Marine ecotoxicityReCiPe 1.08 Endpoint (I) - Terrestrial ecotoxicityReCiPe 1.08 Midpoint (I) - Freshwater ecotoxicityReCiPe 1.08 Midpoint (I) - Human toxicityReCiPe 1.08 Midpoint (I) - Marine ecotoxicityReCiPe 1.08 Midpoint (I) - Terrestrial ecotoxicityReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, incl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Human Health, incl biogenic carbonReCiPe 1.08 Midpoint (I) - Climate change, incl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Human Health, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (I) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Human Health, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (I) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Human Health, LUC only, no norm/weightReCiPe 1.08 Midpoint (I) - Climate change, LUC only, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, LUC only, no norm/weightTRACI 2.1, Ecotoxicity (recommended)TRACI 2.1, Human toxicity, cancer (recommended)TRACI 2.1, Human toxicity, non-canc. (recommended)TRACI 2.1, Global Warming Air, excl. biogenic carbonTRACI 2.1, Resources, Fossil fuelsTRACI 2.1, Human Health Particulate AirTRACI 2.1, Ozone Depletion AirTRACI 2.1, Smog AirTRACI 2.1, Global Warming Air, incl. biogenic carbonTRACI 2.1, AcidificationTRACI 2.1, EutrophicationTRACI 2.1, Global Warming Air, incl biogenic carbon, incl LUC, no norm/weightTRACI 2.1, Global Warming Air, excl biogenic carbon, incl LUC, no norm/weightTRACI 2.1, Global Warming Air, LUC only, no norm/weightUBP 2013, Global warmingUBP 2013, Pesticides into soilUBP 2013, Radioactive waste to depositUBP 2013, Radioactive substances into airUBP 2013, Water resourcesUBP 2013, Energy resourcesUBP 2013, Water pollutantsUBP 2013, Heavy metals into soilUBP 2013, Mineral resourcesUBP 2013, POP into waterUBP 2013, Radioactive substances into waterUBP 2013, Carcinogenic substances into airUBP 2013, Heavy metals into airUBP 2013, Land useUBP 2013, Heavy metals into waterUBP 2013, Main air pollutantsUBP 2013, Ozone layer depletionUBP 2013, Non radioactive waste to depositUBP 2013, Global warming, incl Land Use ChangeUBP 2013, Global warming, Land Use Change onlyUSEtox, Ecotoxicity (recommended)USEtox, Human toxicity, cancer (recommended)USEtox, Human toxicity, non-canc. (recommended)Total freshwater consumption (including rainwater)Blue water consumptionBlue water useTotal freshwater useThe LCI method applied is in compliance with ISO 14040 and 14044. The documentation includes all relevant information in view of the data quality and scope of the application of the respective LCI result / data set. The dataset represents the state-of-the-art in view of the referenced functional unit.thinkstepLBP-GaBiIBP-GaBiOverall quality according to different validation schemes
GaBi = 1,5 interpreted into "good overall quality" in the GaBi quality validation scheme
ILCD = 1,7 interpreted into "basic overall quality" in the ILCD quality validation scheme
PEF = 1,5 interpreted into "excellent overall quality" in the PEF quality validation schemeThe dataset and systems, which are provided with our software and databases for public use into a broad user community, are constantly used, compared, benchmarked, screened, reviewed and results published in various external, professional and third party LCA applications in industry, academia and politics. So user feedback via the online GaBi forum or direct via user information is a standard routine in the maintenance and update process and leads to stable quality and constant control and improvement of data, if knowledge or technology improves or industrial process chains develop or change.GaBi user forumGaBi bug forumGaBi user communityGaBi conformity systemFully compliantFully compliantFully compliantFully compliantFully compliantNot definedUNEP SETAC Life Cycle InitiativeNot definedNot definedNot definedNot definedNot definedNot definedILCD Data Network - Entry-levelNot definedFully compliantFully compliantNot definedFully compliantNot definedthinkstepThis background LCI dataset can be used for any type of LCA studythinkstep2016-01-01T00:00:00+01:00ILCD format 1.1thinkstepNo official approval by producer or operator2016-01-01T00:00:00+01:0010.00.000Data set finalised; entirely publishedGaBi databasesthinksteptrueOtherGaBi (source code, database including extension databases modules and single data sets, documentation) remains property of thinkstep AG. thinkstep AG delivers GaBi licenses comprising data storage medium and manual as ordered by the customer. The license guarantees the right of use for one installation of GaBi. Further installations using the same license are not permitted. Additional licenses are only valid if the licensee holds at least one main license. Licenses are not transferable and must only be used within the licensee's organisation. Data sets may be copied for internal use. The number of copies is restricted to the number of licenses of the software system GaBi the licensee owns. The right of use is exclusively valid for the licensee. All rights reserved.Steel sheet 0.75mm el. zinc plated (0.01mm; 2s)Output110.000Mixed primary / secondaryUnknown derivation