Barcza et al., 1995 - Google Patents
Enviroplas technology for the recovery of lead and zinc from lead blast furnace slagsBarcza et al., 1995
- Document ID
- 6029393052359399136
- Author
- Barcza N
- Robertson D
- Schoukens A
- Shaw F
- Denton G
- Worcester A
- Bailey D
- Publication year
- Publication venue
- International Lead and Zinc Study Group
External Links
Snippet
The extraction of zinc and lead from liquid slags from lead blast and imperial smelting furnaces direct into a lead splash condenser may offer an economically attractive alternative to fuming zinc and lead as oxides, since these oxides require further treatment to produce …
- 239000002893 slag 0 title abstract description 84
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Zhang et al. | Moderate dilution of copper slag by natural gas | |
| DK0770149T3 (en) | Process for manufacturing hydraulic binders and / or alloys, e.g. ferrochrome or ferrovanadium | |
| Junxue et al. | Issues Relevant to Recycling of Stainless-Steel Pickling Sludge: Junxue, Zhongyu, Ruimeng, Xiaoming, and Yaru | |
| Barcza et al. | Enviroplas technology for the recovery of lead and zinc from lead blast furnace slags | |
| Ponak | Carbo-thermal reduction of basic oxygen furnace slags with simultaneous removal of phosphorus via the gas phase | |
| Simoni et al. | Towards the circularity of the EU steel industry: modern technologies for the recycling of the dusts and recovery of resources | |
| Liu et al. | Recovery of iron and zinc from blast furnace dust using iron-bath reduction | |
| Xiang et al. | Low-temperature reduction of ferric iron in red mud | |
| Zhdanov et al. | Problems with waste generation and recycling in the ferroalloys industry | |
| Cavaliere | Basic oxygen furnace: most efficient technologies for greenhouse emissions abatement | |
| Singhal et al. | Conversion of entire dusts and sludges generated during manufacture of stainless steels into value added products | |
| Peaslee et al. | Fluid Dynamics of Inclined Jetting on a Slag-Metal Bath | |
| JP2022523397A (en) | Combined melting of molten slag and residues from stainless steel and ferrochrome plants | |
| Ito et al. | Slag foaming in electric furnace steelmaking | |
| Kluender | Quantification of water footprint: calculating the amount of water needed to produce steel | |
| Shevko et al. | The possibility of obtaining mangano ferro silico chromium from dusts of silicon and chromium ferroalloys production using high-ash coal | |
| Abulikemu et al. | Mineralogical phase of slag and its effect on dephosphorization during converter steelmaking using slag-remaining technology | |
| Shin et al. | Development of kinetic model for reactions between Cu-containing multicomponent slag and liquid sulfide using coupled reaction model | |
| Nicol et al. | Adaptability of the ISASMELT™ Technology for the Sustainable Treatment of Wastes | |
| Crites et al. | Refractory interactions with calcium ferrite slags | |
| Lee et al. | Modeling the viscosity of blast furnace slags containing FeO | |
| Li et al. | Effect of moisture, combined water, and volatile elements on fixed carbon requirement in a ferro-manganese smelting furnace | |
| Nakamura et al. | Dioxin emissions in recycling processes of metals | |
| Zhang et al. | Iron Recovery from Nickel Slag by Aluminum Dross: A Static Model from Industrial Practice View | |
| Deneys et al. | Fluid flow phenomena in a laboratory scale DC arc furnace for slag cleaning |