2a1842a1-8451-4ad0-b405-c4658ad67171Municipal waste water treatment (sludge incineration)technology mixproduction mix, at plantsludge incinerationProcessesDisposalwastewater treatmentThe data set covers all relevant process steps / technologies over the supply chain of the represented end-of-life inventory with a good overall data quality. The inventory is mainly based on industry data and is completed, where necessary, by secondary data.0The data set represents the country / region specific situation, focusing on the main technologies, the region specific characteristics and / or import statistics.This data set covers all relevant inputs and outputs from the treatment of incoming waste water from industrial processes. It contains mechanical, biological and chemical treatment steps for the waste water (including precipitation and neutralisation), and treatment steps for the sludge (thickening, dewatering, drying, conditioning). The outflow goes directly to the receiving water (natural surface water). The waste water composition to the plant represents an average outflow of a chemical industry commodity to the treatment plant with organic and inorganic substances or derivates from this average composition (see document "waste water composition"). The process steps are taking average elimination and transfer coefficients into account. The sewage passes through the bar screens for rag removal. In this section, automatic bar screen cleaners remove large solids (rags, plastics, etc.) from the raw sewage. Next, the sewage is transported to the grit tanks. These tanks reduce the velocity of the sewage so that heavy particles can settle to the bottom. In the separator suspended particles such as oils, fats are removed. The settlement tank can remove the larger suspended solids. FeSO4, and Ca(OH)2 are used as precipitant agents in the mixing tank to remove metals. Ca(OH)2 and H2SO4 to regulate the pH value. The primary clarifiers remove the suspended solids from the mixing tank prior to discharge to the aeration tanks. The aeration tanks provide a location where biological treatment of the sewage takes place. The activated sludge converts organic substances into oxidised products, which are settled out in the secondary clarifiers. Phosphoric acid is used as nutrient for micro-organisms. The cleared overflow in the secondary clarifiers goes to a natural surface water body (stream, river or bay). The settled solids, from the settlement tank, the primary clarifiers and secondary clarifiers, are pumped to the primary thickener where the solids are thickened (water content thickened sludge 96 %). The sludge is pumped to filter presses for dewatering, which use chemical flocculants to separate the water from the solids (water content dewatered sludge 65 %). Next, the sludge is getting dried with thermal energy (water content of dried sludge 25 %). The content from the screen and grit chamber can be mixed with the dried sludge and fed into an incinerator, which produces energy (electricity and thermal energy) for the wastewater treatment plant.
The composition of the sludge refers to the output of the municipal sewage plant modeled as described above.
The background system is addressed to average European conditions as follows:
As auxiliaries are used: precipitation agents, nutrients, neutralisation chemicals and conditioning agents. For these processes, cradle to gate data sets have been chosen for the following chemicals: Iron (II) sulphate, calcium hydroxide, sulphuric acid and phosphoric acid. When connecting the municipal sewage plant with waste incinerator the power and thermal energy resulting from the incineration process may either be looped back, neglected (worst case), credited completely (best case).
For the way of handling of these flows a standard procedure cannot be recommended. It must be decided dependent on the overall situation and the system considered. In this data set the power and thermal energy resulting from the incineration process is looped back.
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.EU-27: Calcium hydroxide (Ca(OH)2; dry; slaked lime) PE (data set not included in documentation)EU-27: Ferric chloride PE (data set not included in documentation)EU-27: Sodium hydroxide from chlorine-alkali-electrolysis (Diaphragm) PE (data set not included in documentation)Sulphuric acid (96%)DE: Aluminium chloride hexahydrate PE (data set not included in documentation)EU-27: Iron (II) sulfate PE (data set not included in documentation)Phosphoric acid (75%)EU-27: Waste Incineration Plant dry process (Basic plan) KKA (reduced efficiency)) PE <t-agg> (data set not included in documentation)Provision of a standard technical product according to the applied technology.EoL_Municipal waste water treatment (sludge incineration).JPGEoL_Municipal waste water treatment with biotic CO2-emission_Output dried sludge.JPGEoL_CEWEP Waste Incineration Plant dry process (Basic plan) KKA.jpgLCI resultAttributionalNoneAllocation - market valueAllocation - net calorific valueAllocation - exergetic contentAllocation - massForeground system: None.
Background system: For the combined heat and power production, allocation by exergetic content is applied. For the electricity generation and by-products, e.g. gypsum, allocation by market value is applied due to no common physical properties. Within the refinery allocation by net calorific value and mass is used. For the combined crude oil, natural gas and natural gas liquids production allocation by net calorific value is applied.
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"NoneFor details please see the document "GaBi Databases Modelling Principles"NoneFor details please see the document "GaBi Databases Modelling Principles"NoneÖkoinventare von Entsorgungsprozessen - Grundlagen zur Integration der Entsorgung in Ökobilanzen ESURückgewinnungspotenzial für Närstoffe aus Abwasser und Schlamm.Bildung von Organohalogenen in einer kommunalen KläranlageWastewater treatment: biological and chemical processes, second ed.Kläranlage Geiselbullach. Auswertung von Betriebsergebnissen 2009Arbeitsblatt ATV-DVWK-A 131- Bemessung von einstufigen Belebungsanlagen ab 5000 EinwohnerwertenEnergie in ARA- Energiesparmassnahmen in AbwasserreinigungsanlagenHandbuch des U-schutzes und der U-technik, Additiver Umweltschutz: Behandlung von Abwässern, 1996Abwassertechnologie (2. Auflage), 1994ATV Lehr- u. Handbuch der Abwassertechnik B.VI:Org. verschmutze Abwässer sonstiger IndustriegruppenBayer AG: Sustainable development report 2001, 2001Umwelt, Sicherheit, Gesundheit 2002 - Daten und Fakten BASF AG Werk Ludwigshafen, 2002ATV Handbuch Industrieabwasser Grundlagen, 1999Ref. Doc. on Best Available Techniques in Common Waste Water and Waste Gas TreatmentCouncil Directive 91/271/EEC of 21 May 1991 concerning urban waste-water treatment, 1991GaBi databases 200695.0NoneThe data set represents an end-of-life inventory. It can be used to characterise theend-of-life situation of the respective commodity in a representative manner. Combination with individual unit processes using this commodity user-specific (product) LCAs to be generated.All relevant flows quantifiedAcidification, accumulated exceedanceAnthropogenic Abiotic Depletion Potential (AADP), TU BerlinBlue water consumptionBlue water useCML2001 - Apr. 2013, Abiotic Depletion (ADP elements)CML2001 - Apr. 2013, Abiotic Depletion (ADP fossil)CML2001 - Apr. 2013, Acidification Potential (AP)CML2001 - Apr. 2013, Eutrophication Potential (EP)CML2001 - Apr. 2013, Freshwater Aquatic Ecotoxicity Pot. (FAETP inf.)CML2001 - Apr. 2013, Global Warming Potential (GWP 100 years)CML2001 - Apr. 2013, Global Warming Potential (GWP 100 years), excl biogenic carbonCML2001 - Apr. 2013, Global Warming Potential (GWP 100), excl bio. C, incl LUC, no norm/weightCML2001 - Apr. 2013, Global Warming Potential (GWP 100), incl bio. C, incl LUC, no norm/weightCML2001 - Apr. 2013, Global Warming Potential (GWP 100), Land Use Change only, no norm/weightCML2001 - Apr. 2013, Human Toxicity Potential (HTP inf.)CML2001 - Apr. 2013, Marine Aquatic Ecotoxicity Pot. (MAETP inf.)CML2001 - Apr. 2013, Ozone Layer Depletion Potential (ODP, steady state)CML2001 - Apr. 2013, Photochem. Ozone Creation Potential (POCP)CML2001 - Apr. 2013, Terrestric Ecotoxicity Potential (TETP inf.)Ecotoxicity for aquatic fresh water, USEtox (recommended)EDIP 2003, Acidification potentialEDIP 2003, Aquatic eutrophicationEDIP 2003, Global warmingEDIP 2003, Photochemical ozone formation - impact on human health and materialsEDIP 2003, Photochemical ozone formation - impact on vegetationEDIP 2003, Stratospheric ozone depletionEDIP 2003, Terrestrial eutrophicationFreshwater eutrophication, EUTREND model, ReCiPeHuman toxicity cancer effects, USEtox (recommended)Human toxicity non-canc. effects, USEtox (recommended)I02+ v2.1 - Aquatic acidification - MidpointI02+ v2.1 - Aquatic ecotoxicity - MidpointI02+ v2.1 - Aquatic eutrophication - MidpointI02+ v2.1 - Carcinogens - MidpointI02+ v2.1 - Global warming 500yr - MidpointI02+ v2.1 - Ionizing radiation - MidpointI02+ v2.1 - Land occupation - MidpointI02+ v2.1 - Mineral extraction - MidpointI02+ v2.1 - Non-carcinogens - MidpointI02+ v2.1 - Non-renewable energy - MidpointI02+ v2.1 - Ozone layer depletion - MidpointI02+ v2.1 - Photochemical oxidation - MidpointI02+ v2.1 - Respiratory effects - MidpointI02+ v2.1 - Terrestrial acidification/nutrification - MidpointI02+ v2.1 - Terrestrial ecotoxicity - MidpointIonising radiation, human health effect model, ReCiPeIPCC AR5 GTP100, excl biogenic carbonIPCC AR5 GTP100, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP100, incl biogenic carbonIPCC AR5 GTP100, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP100, Land Use Change only, no norm/weightIPCC AR5 GTP100, Land Use Change only, no norm/weightIPCC AR5 GTP20, excl biogenic carbonIPCC AR5 GTP20, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, incl biogenic carbonIPCC AR5 GTP20, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP20, Land Use Change only, no norm/weightIPCC AR5 GTP20, Land Use Change only, no norm/weightIPCC AR5 GTP50, excl biogenic carbonIPCC AR5 GTP50, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, incl biogenic carbonIPCC AR5 GTP50, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GTP50, Land Use Change only, no norm/weightIPCC AR5 GTP50, Land Use Change only, no norm/weightIPCC AR5 GWP100, excl biogenic carbonIPCC AR5 GWP100, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP100, incl biogenic carbonIPCC AR5 GWP100, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP100, Land Use Change only, no norm/weightIPCC AR5 GWP100, Land Use Change only, no norm/weightIPCC AR5 GWP20, excl biogenic carbonIPCC AR5 GWP20, excl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP20, incl biogenic carbonIPCC AR5 GWP20, incl biogenic carbon, incl Land Use Change, no norm/weightIPCC AR5 GWP20, Land Use Change only, no norm/weightIPCC AR5 GWP20, Land Use Change only, no norm/weightIPCC global warming, excl biogenic carbonIPCC global warming, incl biogenic carbonMarine eutrophication, EUTREND model, ReCiPeOzone depletion, WMO model, ReCiPeParticulate matter/Respiratory inorganics, RiskPollPhotochemical ozone formation, LOTOS-EUROS model, ReCiPePrimary energy demand from ren. and non ren. resources (gross cal. value)Primary energy demand from ren. and non ren. resources (net cal. value)Primary 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)ReCiPe 1.08 Endpoint (E) - Agricultural land occupationReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, default, excl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, incl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Ecosystems, LUC only, no norm/weightReCiPe 1.08 Endpoint (E) - Climate change Human Health, default, excl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Human Health, excl 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 Endpoint (E) - Climate change Human Health, incl biogenic carbonReCiPe 1.08 Endpoint (E) - Climate change Human Health, LUC only, no norm/weightReCiPe 1.08 Endpoint (E) - Fossil depletionReCiPe 1.08 Endpoint (E) - Freshwater ecotoxicityReCiPe 1.08 Endpoint (E) - Freshwater eutrophicationReCiPe 1.08 Endpoint (E) - Human toxicityReCiPe 1.08 Endpoint (E) - Ionising radiationReCiPe 1.08 Endpoint (E) - Marine ecotoxicityReCiPe 1.08 Endpoint (E) - Metal depletionReCiPe 1.08 Endpoint (E) - Natural land transformationReCiPe 1.08 Endpoint (E) - Ozone depletionReCiPe 1.08 Endpoint (E) - Particulate matter formationReCiPe 1.08 Endpoint (E) - Photochemical oxidant formationReCiPe 1.08 Endpoint (E) - Terrestrial acidificationReCiPe 1.08 Endpoint (E) - Terrestrial ecotoxicityReCiPe 1.08 Endpoint (E) - Urban land occupationReCiPe 1.08 Endpoint (H) - Agricultural land occupationReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, default, excl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, incl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Ecosystems, LUC only, no norm/weightReCiPe 1.08 Endpoint (H) - Climate change Human Health, default, excl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Human Health, excl 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 Endpoint (H) - Climate change Human Health, incl biogenic carbonReCiPe 1.08 Endpoint (H) - Climate change Human Health, LUC only, no norm/weightReCiPe 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) - Natural land transformationReCiPe 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 Endpoint (I) - Agricultural land occupationReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, default, excl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, incl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Ecosystems, LUC only, no norm/weightReCiPe 1.08 Endpoint (I) - Climate change Human Health, default, excl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Human Health, excl 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 Endpoint (I) - Climate change Human Health, incl biogenic carbonReCiPe 1.08 Endpoint (I) - Climate change Human Health, LUC only, no norm/weightReCiPe 1.08 Endpoint (I) - Fossil depletionReCiPe 1.08 Endpoint (I) - Freshwater ecotoxicityReCiPe 1.08 Endpoint (I) - Freshwater eutrophicationReCiPe 1.08 Endpoint (I) - Human toxicityReCiPe 1.08 Endpoint (I) - Ionising radiationReCiPe 1.08 Endpoint (I) - Marine ecotoxicityReCiPe 1.08 Endpoint (I) - Metal depletionReCiPe 1.08 Endpoint (I) - Natural land transformationReCiPe 1.08 Endpoint (I) - Ozone depletionReCiPe 1.08 Endpoint (I) - Particulate matter formationReCiPe 1.08 Endpoint (I) - Photochemical oxidant formationReCiPe 1.08 Endpoint (I) - Terrestrial acidificationReCiPe 1.08 Endpoint (I) - Terrestrial ecotoxicityReCiPe 1.08 Endpoint (I) - Urban land occupationReCiPe 1.08 Midpoint (E) - Agricultural land occupationReCiPe 1.08 Midpoint (E) - Climate change, default, excl biogenic carbonReCiPe 1.08 Midpoint (E) - Climate change, excl 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, incl biogenic carbonReCiPe 1.08 Midpoint (E) - Climate change, LUC only, no norm/weightReCiPe 1.08 Midpoint (E) - Fossil depletionReCiPe 1.08 Midpoint (E) - Freshwater ecotoxicityReCiPe 1.08 Midpoint (E) - Freshwater eutrophicationReCiPe 1.08 Midpoint (E) - Human toxicityReCiPe 1.08 Midpoint (E) - Ionising radiationReCiPe 1.08 Midpoint (E) - Marine ecotoxicityReCiPe 1.08 Midpoint (E) - Marine eutrophicationReCiPe 1.08 Midpoint (E) - Metal depletionReCiPe 1.08 Midpoint (E) - Natural land transformationReCiPe 1.08 Midpoint (E) - Ozone depletionReCiPe 1.08 Midpoint (E) - Particulate matter formationReCiPe 1.08 Midpoint (E) - Photochemical oxidant formationReCiPe 1.08 Midpoint (E) - Terrestrial acidificationReCiPe 1.08 Midpoint (E) - Terrestrial ecotoxicityReCiPe 1.08 Midpoint (E) - Urban land occupationReCiPe 1.08 Midpoint (E) - Water depletionReCiPe 1.08 Midpoint (H) - Agricultural land occupationReCiPe 1.08 Midpoint (H) - Climate change, default, excl biogenic carbonReCiPe 1.08 Midpoint (H) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (H) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (H) - Climate change, incl biogenic carbonReCiPe 1.08 Midpoint (H) - Climate change, LUC only, no norm/weightReCiPe 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) - Ozone depletionReCiPe 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 (I) - Agricultural land occupationReCiPe 1.08 Midpoint (I) - Climate change, default, excl biogenic carbonReCiPe 1.08 Midpoint (I) - Climate change, excl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (I) - Climate change, incl biog. C, incl LUC, no norm/weightReCiPe 1.08 Midpoint (I) - Climate change, incl biogenic carbonReCiPe 1.08 Midpoint (I) - Climate change, LUC only, no norm/weightReCiPe 1.08 Midpoint (I) - Fossil depletionReCiPe 1.08 Midpoint (I) - Freshwater ecotoxicityReCiPe 1.08 Midpoint (I) - Freshwater eutrophicationReCiPe 1.08 Midpoint (I) - Human toxicityReCiPe 1.08 Midpoint (I) - Ionising radiationReCiPe 1.08 Midpoint (I) - Marine ecotoxicityReCiPe 1.08 Midpoint (I) - Marine eutrophicationReCiPe 1.08 Midpoint (I) - Metal depletionReCiPe 1.08 Midpoint (I) - Natural land transformationReCiPe 1.08 Midpoint (I) - Ozone depletionReCiPe 1.08 Midpoint (I) - Particulate matter formationReCiPe 1.08 Midpoint (I) - Photochemical oxidant formationReCiPe 1.08 Midpoint (I) - Terrestrial acidificationReCiPe 1.08 Midpoint (I) - Terrestrial ecotoxicityReCiPe 1.08 Midpoint (I) - Urban land occupationReCiPe 1.08 Midpoint (I) - Water depletionResource Depletion, fossil and mineral, reserve Based, CML2002Terrestrial eutrophication, accumulated exceedanceTotal freshwater consumption (including rainwater)Total freshwater consumption, including rainwater, Swiss EcoscarcityTotal freshwater useTRACI 2.1, AcidificationTRACI 2.1, Ecotoxicity (recommended)TRACI 2.1, EutrophicationTRACI 2.1, Global Warming Air, excl biogenic carbon, incl LUC, no norm/weightTRACI 2.1, Global Warming Air, excl. biogenic carbonTRACI 2.1, Global Warming Air, incl biogenic carbon, incl LUC, no norm/weightTRACI 2.1, Global Warming Air, incl. biogenic carbonTRACI 2.1, Global Warming Air, LUC only, no norm/weightTRACI 2.1, Human Health Particulate AirTRACI 2.1, Human toxicity, cancer (recommended)TRACI 2.1, Human toxicity, non-canc. (recommended)TRACI 2.1, Ozone Depletion AirTRACI 2.1, Resources, Fossil fuelsTRACI 2.1, Smog AirUBP 2013, Carcinogenic substances into airUBP 2013, Energy resourcesUBP 2013, Global warmingUBP 2013, Global warming, incl Land Use ChangeUBP 2013, Global warming, Land Use Change onlyUBP 2013, Heavy metals into airUBP 2013, Heavy metals into soilUBP 2013, Heavy metals into waterUBP 2013, Land useUBP 2013, Main air pollutantsUBP 2013, Mineral resourcesUBP 2013, Non radioactive waste to depositUBP 2013, Ozone layer depletionUBP 2013, Pesticides into soilUBP 2013, POP into waterUBP 2013, Radioactive substances into airUBP 2013, Radioactive substances into waterUBP 2013, Radioactive waste to depositUBP 2013, Water pollutantsUBP 2013, Water resourcesUSEtox, Ecotoxicity (recommended)USEtox, Human toxicity, cancer (recommended)USEtox, Human toxicity, non-canc. (recommended)The 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.PE INTERNATIONALLBP-GaBiIBP-GaBiOverall quality according to different validation schemes
GaBi = 1,8 interpreted into "good overall quality" in the GaBi quality validation scheme
ILCD = 1,9 interpreted into "basic overall quality" in the ILCD quality validation scheme
PEF = 1,8 interpreted into "very good 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 definedPE INTERNATIONALThe data set represents a cradle to gate inventory. It can be used to characterise the end-of-life 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. The data set does not necessarily fit for any possible specific supply situation - especially if significantly different technology routes exist - but is representative for a common supply chain situation.PE INTERNATIONAL2014-12-01T00:00:00+01:00ILCD format 1.1PE INTERNATIONALNo official approval by producer or operator2014-12-01T00:00:00+01:0009.00.000Data set finalised; entirely publishedGaBi databasesPE INTERNATIONALtrueOtherGaBi (source code, database including extension modules and single data sets, documentation) remains property of PE INTERNATIONAL AG. PE INTERNATIONAL 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.Water (waste water, untreated)Input110.000Mixed primary / secondaryUnknown derivation