Description: technologyComment of cobalt production (GLO): Cobalt, as a co-product of nickel and copper production, is obtained using a wide range of technologies. The initial life cycle stage covers the mining of the ore through underground or open cast methods. The ore is further processed in beneficiation to produce a concentrate and/or raffinate solution. Metal selection and further concentration is initiated in primary extraction, which may involve calcining, smelting, high pressure leaching, and other processes. The final product is obtained through further refining, which may involve processes such as re-leaching, selective solvent / solution extraction, selective precipitation, electrowinning, and other treatments. Transport is reported separately and consists of only the internal movements of materials / intermediates, and not the movement of final product. Due to its intrinsic value, cobalt has a high recycling rate. However, much of this recycling takes place downstream through the recycling of alloy scrap into new alloy, or goes into the cobalt chemical sector as an intermediate requiring additional refinement. Secondary production, ie production from the recycling of cobalt-containing wastes, is considered in this study in so far as it occurs as part of the participating companies’ production. This was shown to be of very limited significance (less than 1% of cobalt inputs). The secondary materials used for producing cobalt are modelled as entering the system free of environmental burden. technologyComment of primary zinc production from concentrate (RoW): The technological representativeness of this dataset is considered to be high as smelting methods for zinc are consistent in all regions. Refined zinc produced pyro-metallurgically represents less than 5% of global zinc production and less than 2% of this dataset. Electrometallurgical Smelting The main unit processes for electrometallurgical zinc smelting are roasting, leaching, purification, electrolysis, and melting. In both electrometallurgical and pyro-metallurgical zinc production routes, the first step is to remove the sulfur from the concentrate. Roasting or sintering achieves this. The concentrate is heated in a furnace with operating temperature above 900 °C (exothermic, autogenous process) to convert the zinc sulfide to calcine (zinc oxide). Simultaneously, sulfur reacts with oxygen to produce sulfur dioxide, which is subsequently converted to sulfuric acid in acid plants, usually located with zinc-smelting facilities. During the leaching process, the calcine is dissolved in dilute sulfuric acid solution (re-circulated back from the electrolysis cells) to produce aqueous zinc sulfate solution. The iron impurities dissolve as well and are precipitated out as jarosite or goethite in the presence of calcine and possibly ammonia. Jarosite and goethite are usually disposed of in tailing ponds. Adding zinc dust to the zinc sulfate solution facilitates purification. The purification of leachate leads to precipitation of cadmium, copper, and cobalt as metals. In electrolysis, the purified solution is electrolyzed between lead alloy anodes and aluminum cathodes. The high-purity zinc deposited on aluminum cathodes is stripped off, dried, melted, and cast into SHG zinc ingots (99.99 % zinc). Pyro-metallurgical Smelting The pyro-metallurgical smelting process is based on the reduction of zinc and lead oxides into metal with carbon in an imperial smelting furnace. The sinter, along with pre-heated coke, is charged from the top of the furnace and injected from below with pre-heated air. This ensures that temperature in the center of the furnace remains in the range of 1000-1500 °C. The coke is converted to carbon monoxide, and zinc and lead oxides are reduced to metallic zinc and lead. The liquid lead bullion is collected at the bottom of the furnace along with other metal impurities (copper, silver, and gold). Zinc in vapor form is collected from the top of the furnace along with other gases. Zinc vapor is then condensed into liquid zinc. The lead and cadmium impurities in zinc bullion are removed through a distillation process. The imperial smelting process is an energy-intensive process and produces zinc of lower purity than the electrometallurgical process. technologyComment of treatment of used Li-ion battery, hydrometallurgical treatment (GLO): Shredder, followed by a chemical treatment in order to separate the various fractions produced technologyComment of treatment of used Li-ion battery, pyrometallurgical treatment (GLO): Crushing of the batteries, followed by a neutralization and a processing step.
Types:
Text { text_type: Report, }
Comment: This is a market activity. Each market represents the consumption mix of a product in a given geography, connecting suppliers with consumers of the same product in the same geographical area. Markets group the producers and also the imports of the product (if relevant) within the same geographical area. They also account for transport to the consumer and for the losses during that process, when relevant. This is the market for 'cobalt', in the Global geography. Transport from producers to consumers of this product in the geography covered by the market is included. This market is supplied by the following activities with the given share: primary zinc production from concentrate, RoW: 0.157260247113523 cobalt production, GLO: 0.837023494872712 treatment of used Li-ion battery, hydrometallurgical treatment, GLO: 0.00365324760278205 treatment of used Li-ion battery, pyrometallurgical treatment, GLO: 0.00206301041098281 generalComment of cobalt production (GLO): This dataset represents the production of cobalt by the global cobalt industry. Reference: "The Environmental Performance of Refined Cobalt - Life Cycle Inventory and Life Cycle Assessment of Refined Cobalt - Summary Report", CDI & ERM, Novermber 2016. PM2.5-10 and PM10 emissions to air arise from mine ventillation systems. generalComment of primary zinc production from concentrate (RoW): The multi-output "primary zinc production from concentrate" process includes all steps required to produce special high grade zinc from zinc concentrate using the electrometallurgical and pyrometallurgical (less common) processes. Electrometallurgical zinc smelting includes roasting, leaching, purification, electrolysis, melting, and sulfur dioxide gas treatment. Pyrometallurgical zinc smelting includes sintering, leaching, refining, and sulfur dioxide gas treatment. The dataset describes the production of zinc and additional co-products, primarily sulfuric acid. Data is based on a study undertaken by the International Zinc Association (IZA) in conjunction with thinkstep (the LCA practitioner) for reference year 2012. Participating companies provided annual primary data on inputs and outputs for each process step, which was aggregated into a single production-weighted dataset. The below images present the system boundary in relation to the primary product, special high grade zinc. imageUrlTagReplacec1fef210-e0fd-48fd-9cea-351f6a190ca8 imageUrlTagReplace27d4da96-9dfb-45d5-ac34-9f40810abac8 generalComment of treatment of used Li-ion battery, hydrometallurgical treatment (GLO): [This dataset was already contained in the ecoinvent database version 2. It was not individually updated during the transfer to ecoinvent version 3. Life Cycle Impact Assessment results may still have changed, as they are affected by changes in the supply chain, i.e. in other datasets. This dataset was generated following the ecoinvent quality guidelines for version 2. It may have been subject to central changes described in the ecoinvent version 3 change report (http://www.ecoinvent.org/database/ecoinvent-version-3/reports-of-changes/), and the results of the central updates were reviewed extensively. The changes added e.g. consistent water flows and other information throughout the database. The documentation of this dataset can be found in the ecoinvent reports of version 2, which are still available via the ecoinvent website. The change report linked above covers all central changes that were made during the conversion process.] generalComment of treatment of used Li-ion battery, pyrometallurgical treatment (GLO): [This dataset was already contained in the ecoinvent database version 2. It was not individually updated during the transfer to ecoinvent version 3. Life Cycle Impact Assessment results may still have changed, as they are affected by changes in the supply chain, i.e. in other datasets. This dataset was generated following the ecoinvent quality guidelines for version 2. It may have been subject to central changes described in the ecoinvent version 3 change report (http://www.ecoinvent.org/database/ecoinvent-version-3/reports-of-changes/), and the results of the central updates were reviewed extensively. The changes added e.g. consistent water flows and other information throughout the database. The documentation of this dataset can be found in the ecoinvent reports of version 2, which are still available via the ecoinvent website. The change report linked above covers all central changes that were made during the conversion process.]
Origin: /Bund/UBA/ProBas
Tags: Aluminiumoxid ? Recycling ? Sinterung ? Zinksulfat ? Zinksulfid ? Gold ? Aluminium ? Ammoniak ? Bleioxid ? Kobalt ? Nickel ? Silber ? Zinkoxid ? Eisen ? Kupfer ? Lithium-Batterie ? Main ? Kohlenstoff ? Koks ? Lösungsmittel ? Metalloxid ? Raffination ? Brüden ? Sauerstoff ? Altmetall ? Schwefelsäure ? Cadmium ? Chemische Industrie ? Zink ? Staub ? Blei ? Schwefel ? Abfallverwertung ? Kohlenmonoxid ? Umweltbelastung ? Aufbereitungstechnik ? Batterie ? Elektrolyse ? Metall ? Schwefeldioxid ? Recyclingquote ? Shredder ? Erzbergbau ? Kalzinierung ? Untertagebau ? Gasförmiger Stoff ? Sickerwasser ? Nebenprodukt ? Schmelzofen ? Studie ? Destillation ? Zwischenprodukt ? Erz ? Reinigungsverfahren ? Ofen ? Niederschlag ? Legierung ? Chemische Aufbereitung ? Manufacture of basic precious and other non-ferrous metals ? Manufacture of basic metals ? Manufacturing ?
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