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Recycling of Metals and Engineered Materials IV
by Don Stewart, R. Stephens, and J.C. Daley, editors
 
 
Publisher:TMS
Product Format:e-Book
Pages: 1397
Date published:08/01/2000
ISBN:0-87339-494-1
Contents:[pp. 3-18]Technology Commercialization in the New Millennium: Lessons From the Previous Millenium[pp. 19-28]The Importance of Recycling to the Environmental Profile of Metal Products[pp. 31-45]An Improved Non-Conventional Method for Obtaining Nuclear Pure Uranium Oxides and Uranium Tetrafluoride from Actual Mill Strip Solution[pp. 47-59]Processing of Televisions by Mechanical Separation Techniques: Implications for Future Work in Product Design and Recycling[pp. 63-72]Operations at the Doe Run Company's Buick Resource Recycling Division[pp. 73-78]Operation of a High-Output, One-Pass Smelting System for Recycling Lead-Acid Batteries[pp. 79-92]Technology for Processing of Lead-Acid Batteries at Mulden-Hutten Recycling Und Umwelttechnik GmBH[pp. 93-101]Recovery of Polypropylene from Lead-Acid Battery Scrap[pp. 103-115]Sulfur Injection to Remove Copper from Recycled Lead[pp. 117-122]Waste-Less Technology for Processing of Subgrade Lead Concentrates and Flotation Middlings Containing Precious Metals[pp. 123-131]Modernisation of the Lead Acid Battery Scrap Smelting Technology at Orzel Bialy S.A.[pp. 133-140]Reduction of Lead in the Separator Fraction[pp. 141-151]The Role of Electrochemistry at East Perm Manufacturing[pp. 153-163]Viscosity Measurements of Lead Slags[pp. 165-173]CTP's Experience in the Removal of Contaminants and Odors in the Recycling Industry - A New Process for Simultaneously Removing VOCs and Dioxins and Furans[pp. 177-184]The Need to Recycle Zinc: A Consideration of Public Perception, Politics and Competitiveness[pp. 185-191]Electrolytic Zinc Recovery in the EMEW® Cell[pp. 193-200]Zinc Recycling Via the Imperial Smelting Technology - Latest Developments and Possibilities[pp. 201-209]Dezincing of Zinc Coated Steel Scrap: Current Situation at Saint-Saulve Dezincing Plant of Compagnie Europeenne De Dezingage (C.E.D.)[pp. 211-223]Recovery of Zinc from Zinc Ash and Flue Dust by Pyrometallurgical Processing[pp. 227-236]Recovering Zinc and Lead from Electric Arc Furnace Dust: A Technology Status Report[pp. 237-250]The Current Status of Electric Arc Furnace Dust Recycling in North America[pp. 251-259]Reclamation of Valuable Metals' from Hazardous Waste[pp. 261-269]Fundamental Study of Fe-Zn Intermetallic Compounds for Zinc Evaporation from Galvanized Steel Sheet[pp. 271-280]Characterisation and Removal of Halogens in the EAF Dust and Zinc Oxide Fume Obtained from Thermal Treatment of EAF Dust[pp. 281-295]Upgrading of EAF Dust by Injection into Iron and Steel Melts[pp. 297-311]Volatilization Kinetics of Zinc and Lead in Zn-Pb Bearing Dust Pellets Containing Carbon[pp. 313-327]Turning Blast Furnace Dust Into a Source of Zinc and Lead Units: A Progress Report on Testwork at Corns Ijmuiden[pp. 329-344]Recovery of Zinc Oxide from Secondary Raw Materials: New Developments of the Waelz Process[pp. 345-359]Operational Practice with the Waelz Kiln and Leaching Plant of TSU in Taiwan[pp. 361-368]Production of Crude Zinc Oxide from Steel Mill Waste Oxides Using a Rotary Hearth Furnace[pp. 369-377]Processing of Zinc-Containing Wastes with the Liquid-Phase Reduction Romelt Process[pp. 379-396]Electrolytic Zinc Production from Crude Zinc Oxides with the Ezinex® Procress[pp. 397-408]Processing Steel Wastes Pyrometallurgically at INMETCO[pp. 409-420]Treatment of Secondary Zinc Oxides for Use in an Electrolytic Zinc Plant[pp. 421-426]EAF Dust Recycling at Ameristeel[pp. 427-441]Recycling EAF Dust with CONTOP Technology[pp. 445-454]Recovery of Copper from Effluents by Supported Liquid Ion Exchange Membranes - From Laboratory Scale to an Integrated Pilot Plant[pp. 455-469]Copper and Zinc Recovery with Emulsion Membranes from Mine Waste Waters[pp. 471-478]Laboratory and Pilot Plant Processing of Spent Ni-Cd Batteries[pp. 479-486]Preparation of Nickel Sulfate from Spent Nickel-Cadmium Batteries[pp. 487-491]Recycling Metals Using the MOCVD Process[pp. 493-501]Removal of Copper from Slag with the Aid of Reducing and Sulfiding Gas Mixtures[pp. 503-516]Electroslag Melting for Recycling Scrap of Valuable Metals and Alloys[pp. 517-527]Melt Refining of Grinding Sludge Containing Cobalt and Nickel in an ESCR Furnace[pp. 529-536]The Use of Secondary Copper for the Production of Rods and Tubes by Continuous Casting in an Electron-Beam Installation[pp. 537-549]Lead Sulfate Scale in a Copper Smelter Acid Plant[pp. 551-565]Recollections of Operations at a Secondary Copper Smelter And Refinery: The U.S. Metals Refining Company, Carteret, NJ[pp. 567-581]Sampling of FSD-Type Cathodes Made from Recycled Copper[pp. 583-593]Arsenic Sludge Recycle at Caraiba Metais S.A.[pp. 597-612]Recycling of Mobile Phone Batteries Using the Ausmelt Catalytic Waste Converter[pp. 613-623]Zimaval (Zinc Manganese Valorization) Technology for Recycling Of Batteries and Other Complex Zinc Bearing Materials[pp. 625-634]The Oxyreducer Technology - A New Technology to Recycle Metal Containing Waste[pp. 637-642]Commercial Practices of US. Specialty Recycling Operations[pp. 643-654]Development and Manufacture of an Innovative Mineral Feed Ingredient Produced from Recycled Copper[pp. 655-660]Electrochemical Treatment of Spent Electroless Nickel Solution[pp. 661-664]Recycling of TidLead Bearing By-products from the Electronics Industry[pp. 665-673]Success Stories of an Innovative Water Recycling Method Using Carbon Adsorption to Recover Heavy Metals from Industrial Wastewater[pp. 675-685]Lead Removal by Ion Exchange[pp. 689-689]The Rebirth of UMPM Hoboken - Executive Summary[pp. 691-700]Metal Recycling at Kosaka Smelter[pp. 701-710]Ausmelt Technology for Recycling of Computer Boards and Other High Value Materials[pp. 711-721]Recycling Used Photographic Chemicals into High Quality Fertilizer[pp. 723-729]Precious Metal Recovery with Electronically Conducting Polymers[pp. 731-737]A New Technology for the Processing of Precious Metal Containing Secondary Raw Materials[pp. 741-758]Recovery of Non-Ferrous Metals from Spent Catalysts[pp. 759-771]Evolution of GCMCÆs Spent Catalyst Operations[pp. 773-780]Novel DC Furnace Design for Smelting Nickel and Cobalt Bearing Concentrate from Spent Alumina Catalyst[pp. 781-793]Recovery of Vanadium, Molybdenum, Nickel, and Cobalt from Spent Catalysts: A New Processing Plant in China[pp. 795-806]Reactor Design for Nickel Recovery from HDS Waste Catalyst[pp. 809-822]Aluminum Scrap Supply and Environmental Impact Model[pp. 823-833]Continuous Measurement of UBC Decoating Efficiency[pp. 835-844]A Basic Study on Development of a Swell-Peeling Method in UBC Recycling System[pp. 845-856]Aluminum Recycling Via Near Room Temperature Electrolysis In Ionic Liquids[pp. 857-866]Transportation of Molten Aluminum[pp. 869-875]Explosions During Aluminum Scrap Melting in the Recycling Industry - Causes and Prevention[pp. 877-886]MeltSim: Melting Optimization for Aluminum Reverb Furnaces[pp. 887-900]A Vertical Floatation Melter for Decoating and Melting Scrap Aluminum[pp. 901-908]An Innovative Stack Melter for Use in the Aluminum Casting Industry[pp. 909-913]Thermal Dynamic Visualization Modeling and Optimization of Aluminum Sidewell Melting Furnaces - Executive Summary[pp. 915-915]The Use of Electro-Magnetic Pumping for Melting and Circulation of Aluminium to Provide Production and Quality Benefits to the Aluminium Cast House - - Abstract[pp. 919-922]The Importance of Metal Quality in Molten Secondary Aluminum - Executive Summary[pp. 923-949]Recycling - A Fan of the Can[pp. 951-961]Development of New Filter for Removal of Non-Metallic Inclusions From the Molten Aluminum[pp. 963-977]Refining Aluminium Scrap by Means of Fractional Crystallisation: Basic Experimental Investigations[pp. 979-991]Refining of a 5XXX Series Aluminum Alloy Scrap by Alcoa Fractional Crystallization Process[pp. 993-1003]A New Proposal of Continuous Agitation Vacuum Distillation Process (CAVP) to Remove Zn from Aluminum Scrap Melt[pp. 1007-1027]UBC Recycling Complex Mass Balance[pp. 1029-1033]Commerical Scale Melt Loss Testing -- Executive Summary[pp. 1035-1044]Dross Analysis Methods and Their Application for Evaluating Secondary Furnace Operations[pp. 1045-1062]Aluminum Sidewell Melting Furnace Heat Transfer Analysis[pp. 1063-1074]Historical Data Analysis in Quality Improvement of Aluminum Recycling Process[pp. 1075-1087]Experimental Study on Aluminum Scrap Recycling[pp. 1089-1102]Metal Values from Used Beverage Cans[pp. 1105-1112]Cold Cleaning and Concentrating of Non-Ferrous Dross[pp. 1113-1121]Numerical Modelling of a Rotary Aluminum Recycling Furnace[pp. 1123-1133]Dross Reclamation at Aluminum Melting Furnace Sites[pp. 1135-1145]Drosrite Salt-Free Processing of Hot Aluminum Dross[pp. 1147-1154]Improvements in Scrap Recycling and Dross Processing Using Oxygen[pp. 1157-1157]Regulatory Issues Associated with Salt Cake and Dross Processing In USA and Europe - - Abstract[pp. 1159-1170]Electrodialysis Technology for Salt Recovery from Aluminum Salt Cake Waste Brines[pp. 1171-1179]Reclaiming Salt Flux from Aluminum Salt Slag Wastes Process Design - Product Performance[pp. 1181-1181]Eddy Current Separation of Aluminum Smelting By-products - - Abstract[pp. 1183-1194]Aluminum Plasma Dross Treatment Process and Calcium Aluminate Production: Closing the Loop with No Residue[pp. 1195-1207]Assuring the Benefits of Aluminum Recycling: Engineering Economical Environmental Solutions to the Issues of Black Dross and Saltcake[pp. 1209-1221]R&D on Treatment and Recycling of Dross Residue[pp. 1223-1228]Conversion of Aluminium Industry Wastes into Glass- Ceramic Products[pp. 1233-1249]Scrap Preparation for Aluminum Alloy Sorting[pp. 1251-1262]Thermomechanical Treatments for the Separation of Cast and Wrought Aluminum[pp. 1263-1275]Sensor Controlled Quality Control and Sorting of Scrap Aluminium Alloys[pp. 1277-1284]Materials Recovery from Shredder Residues[pp. 1285-1302]Recycling Plastics Scrap and ASR: The Simplicity of Automotive Recycling[pp. 1303-1314]A Novel Approach to the Mechanical Processing of ASR[pp. 1317-1329]Magnesium Recycling Yesterday, Today, Tomorrow[pp. 1333-1340]Preparation of Secondary Magnesium for Use in Hot Metal Desulfurization[pp. 1341-1348]Remelting of Magnesium Type 1 Scrap With or Without Flux?[pp. 1351-1351]Overview of Refractory Recycling -- Executive Summary[pp. 1353-1367]Spent Refractory Recycling/Reuse Efforts in the Steel and Aluminum Industries[pp. 1369-1383]Modeling the Reuse of Spent Basic Refractory Material in an EAF[pp. 1385-1394]Spent Refractory Waste Recycling from Non-Ferrous Metals Manufacturers in Missouri
 
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Description
This proceedings collection continues the tradition established by earlier TMS Recycling Meetings in this series by presenting fundamental and practical aspects of recycling metals and engineered materials. This collection concentrates on fundamental and applied research and industrial practices in the recycling of a wide variety of materials including aluminum scrap recycling; aluminum dross processing; aluminum by-product recovery; automotive recycling; magnesium & titanium recycling; EAF dust processing; secondary zinc; secondary lead; secondary copper, nickel & cobalt; spent catalyst recycling; precious metals recycling; refractory recycling; and electronics/plating.

NOTE: Purchase of this product will enable you to download all of the papers shown in the Table of Contents. Simply return to this page after completing the purchase; you will see a "Use Download Privilege" button adjacent to each paper. Click it to begin download of the PDF file.

A collection of papers from the 2000 TMS Fall Extraction & Processing Meeting held in Pittsburgh, Pennsylvania, October 22-25.

To gain a flavor of the content of the volume, a number of supporting pages (e.g., table of contents, subject index) are available for complimentary download in portable document format.

The book can be purchased on CD-ROM or in downloadable portable document format.
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