1 - Preface [Seite 5]
2 - Contents [Seite 7]
3 - About the Editors [Seite 16]
4 - PbZn 2020: 9th International Symposium on Lead and Zinc Processing: Plenary Presentations [Seite 20]
5 - Part I Lead and Zinc Future Outlook: Plenary Session [Seite 24]
6 - 1 Evolution of Global Secondary Lead Production [Seite 25]
7 - Part II PbZn Process Fundamentals I [Seite 38]
8 - 2 Refractory Challenges in Lead and Zinc Furnaces [Seite 39]
9 - 3 Numerical Simulation of Gas-Liquid Flow Mixing Effect in Bottom-Blown Bath [Seite 51]
10 - 4 Slag Reduction Kinetics of a Lead Slag from a Secondary Lead Smelter [Seite 61]
11 - 5 Phase Evolution During the Oxidation Process of Low Grade Lead-Zinc Oxide Ore [Seite 71]
12 - Part III Secondary Zinc I [Seite 81]
13 - 6 A New Era in Smelting Sustainability-Intensification of the Outotec® Ausmelt Top Submerged Lance (TSL) Process for Zinc Production [Seite 82]
14 - 7 Production of SHG Zinc From 100% Recycled Materials [Seite 93]
15 - 8 Recent Development of EAF Dust Treating at Shisaka Smelting Co., Ltd. [Seite 109]
16 - Part IV Zinc Electrowinning [Seite 116]
17 - 9 Current Efficiency Increase in Zinc Electrodeposition at Cajamarquilla Refinery [Seite 117]
18 - 10 To Polarize or Not to Polarize: Practical Advice on How to Control Zinc Electrodeposition [Seite 126]
19 - 11 Optimizing Additive Ratios in Alkaline Zincate Electrodeposition [Seite 138]
20 - Part V Primary Lead I [Seite 147]
21 - 12 Lead Metal Production at Paroo Station Mine Using Leach-Electrowinning Process in Methane Sulfonic Acid Solution [Seite 148]
22 - 13 Lead Plant Transformations [Seite 177]
23 - 14 Reduction of Lead-Rich Slags with Coke in the Lead Blast Furnace [Seite 185]
24 - 15 Installation of a Brown Field Slag Reduction Furnace: State of the Art Off-Gas Treatment with Dry Gas Cleaning for SO? Capture [Seite 198]
25 - 16 Application of CSC Technology in Nonferrous Metallurgy [Seite 211]
26 - Part VI Primary Zinc I [Seite 228]
27 - 17 Start-up and Improvements of the New Electrolysis Plant at Annaka Refinery [Seite 229]
28 - 18 Zinc Recovery of Low Grade Concentrate from Vazante Mine by the Waelz Process [Seite 238]
29 - 19 A Dynamic Model of a Submerged Plasma Slag Fuming Process [Seite 244]
30 - 20 Increase in Zinc Recovery from a Silicate Concentrate by Pre-neutralization Process [Seite 253]
31 - 21 Recovery of Lead from Zinc Plant Residue by Alkaline Leaching Process Followed by Cementation [Seite 259]
32 - 22 Zinc Residue Fuming Process in Side-Submerged Combustion Furnace + Fuming Furnace [Seite 270]
33 - 23 A Critical Review on Generation, Characteristics, and Utilization of Zinc Slag [Seite 280]
34 - Part VII PbZn Process Technologies [Seite 287]
35 - 24 Contributions of Non-ferrous Smelters to Metal Resource Circulation in Japan [Seite 288]
36 - 25 The Process and Application of Oxygen-Enriched Air Side Blown Smelting of Lead-Zinc Materials [Seite 294]
37 - 26 New Ideas for the Design of Green Smelting Project of Domestic Lead and Zinc Resources [Seite 303]
38 - 27 Evaluation and Certification Strategies for Lead-Zinc-Bearing Residues [Seite 310]
39 - Part VIII Primary Lead II [Seite 320]
40 - 28 KCM-Innovator in the Pb Metal Production Through Ausmelt Technology and Variable SO? Concentration Off-Gas Utilization [Seite 321]
41 - 29 The Latest Development of Oxygen Bottom Blowing Lead Smelting Technology [Seite 326]
42 - 30 Characterization of Phase Equilibria and Thermodynamics with Integrated Experimental and Modelling Approach for Complex Lead Primary and Recycling Processing [Seite 336]
43 - 31 Resource Efficiency Evaluation of Pyrometallurgical Solutions to Minimize Iron-Rich Residues in the Roast-Leach-Electrowinning Process [Seite 349]
44 - 32 Zinc Plant Expansion and Modification for Increased Metals Recovery [Seite 363]
45 - 33 Experience with Digital Process Optimization of Zinc Roasting Plants [Seite 374]
46 - Part IX Zinc Leaching and Fe-Control I [Seite 386]
47 - 34 Smelting Jarosite and Sulphur Residue in a Plasma Furnace [Seite 387]
48 - 35 Simulation of an Alternative Direct Leaching Process for High Iron Content Zinc Concentrates [Seite 400]
49 - Part X PbZn Process Fundamentals II [Seite 411]
50 - 36 Lead and Zinc Extractive Metallurgy Research in the Kroll Institute for Extractive Metallurgy [Seite 412]
51 - 37 Electrochemical Extraction of Pb and Zn from Raw Mineral Materials Using Sulfurgraphite Electrode [Seite 421]
52 - 38 Characterization and Processing of Residues from Hydrometallurgical Zinc Smelters [Seite 428]
53 - 39 Leaching of Turkish Oxidized Pb-Zn Flotation Tailings by Inorganic and Organic Acids [Seite 437]
54 - 40 Numerical Simulation of Gas-Particle Two-Phase Chemical Reactions and Key Structure Optimization in the Lead Flash Smelting Furnace [Seite 459]
55 - 41 Effect of Alumina Ceramics Surface Condition on the Wetting of Liquid Lead [Seite 468]
56 - Part XI PbZn Sustainability [Seite 477]
57 - 42 Material Stewardship for Zinc [Seite 478]
58 - 43 Effect of Deposit Types, Mine Development and Industry Structure on Primary Lead and Zinc Economics in Australia, North America and Europe [Seite 493]
59 - Part XII By-Product Recovery I [Seite 503]
60 - 44 Hydrometallurgical Recovery of Tin from Harris Dross [Seite 504]
61 - 45 Pb and Other Impurities Recovery from Cu Smelting Residues in JX Nippon Mining & Metals [Seite 515]
62 - 46 Pyrometallurgical Recovery of Valuable Metals from Flue Dusts of Copper Smelter Through Lead Alloy [Seite 523]
63 - Part XIII Secondary Lead [Seite 532]
64 - 47 Operational Overview of RSR North America Corp. [Seite 533]
65 - 48 Refractory Solutions by Laboratory Tests and Fieldworks for Lead Recycling Applications [Seite 538]
66 - 49 Influence of Minor Elements in Waste Lead Battery Recycling [Seite 550]
67 - 50 The FAST Pb Process and Its Impact on Secondary Lead Production [Seite 562]
68 - 51 Recent Improvements at Hosokura Lead Smelter and Refinery [Seite 573]
69 - 52 Refractory Corrosion Comparison Through a Rotary Drum Furnace Slag Test for the Lead Industry [Seite 584]
70 - Part XIV Lead and Zinc Sustainability and Social License: Plenary Session [Seite 592]
71 - 53 Regional Changes in Refined Zinc Output and Demand [Seite 593]
72 - Part XV Mineral Processing [Seite 601]
73 - 54 A New Innovative Method of Flotation Separation for High Sulfur Lead-Zinc Sulfide Ore [Seite 602]
74 - 55 A Novel Collector 5-(Butylthio)-1,3,4-Thiadiazole-2-Thiol: Synthesis and Improved Flotation of Galena and Sphalerite from Pyrite [Seite 610]
75 - Part XVI By-Product Recovery II [Seite 627]
76 - 56 The Recovery of Pb and Zn in Antimony Smelting Slag [Seite 628]
77 - 57 Studies on the Formation of Intermetallic Compound Layers in Co(W)-Zn Diffusion Couples [Seite 636]
78 - 58 Effect of Oxidation of Zinc Powder on Purification of High-Cobalt and High-Germanium Zinc Sulfate Solutions [Seite 648]
79 - Part XVII Environmental and Safety Practices I [Seite 656]
80 - 59 ILTEC Technology-New Pathways Towards Safe and Effective Cooling [Seite 657]
81 - 60 Review of Waste Water Treatment Technologies Used in Lead Recycling [Seite 669]
82 - 61 Optimization of Arsenic Removal Process in Waste Acid from Zinc Smelting Plant Based on Orthogonal Experiment [Seite 680]
83 - Part XVIII Lead Refining [Seite 691]
84 - 62 Driving Innovation in Lead Batteries: The Focus of the Consortium of Battery Innovation [Seite 692]
85 - 63 New Technology for Copper Removal from Lead by Application of Aluminium: Practical Problems [Seite 699]
86 - 64 Processing of Polymetallic Materials Requires Flexible and Capable Downstream Refining Technology: Aurubis Lead Refinery as Economic, Modern, and Well Integrated Plant at the Site Hamburg [Seite 708]
87 - 65 Tin Treatment in Kosaka Lead Smelting [Seite 727]
88 - 66 True Traceability Enabled by In-Line Laser Marking of Lead and Zinc Ingots [Seite 735]
89 - 67 Advanced Technologies Reliant on the Properties of Lead [Seite 744]
90 - Part XIX Secondary Zinc II [Seite 749]
91 - 68 The EZINEX® Process for Secondary Zinc Bearing Materials [Seite 750]
92 - 69 Technologies for Treatment of Zinc-Containing Waste from Metallurgy in KCM AD [Seite 763]
93 - 70 Zinc Reduction/Vaporisation Behaviour from Metallurgical Wastes [Seite 774]
94 - 71 Recycling of Zinc from Galvanized Steel Scrap [Seite 783]
95 - Part XX Zinc Leaching and Fe-Control II [Seite 787]
96 - 72 A New Route for Treating Neutral Leaching Residue [Seite 788]
97 - 73 Study of a Novel Chloride Volatilization Process for the Treatment of Jarosite Residue [Seite 795]
98 - 74 Magnetic Separation of Iron Ion from Leaching Solution by Magnetic Seeding in Hydrometallurgy [Seite 806]
99 - 75 Experimental Study on Pressure Leaching of Zinc Sulfide Concentrate and Discussion on the Latest Relevant Progress [Seite 812]
100 - 76 Recent Operational Improvements of Hematite Plant at Akita Zinc Co., Ltd. [Seite 824]
101 - 77 The Analysis of Fe Behavior in Zinc Pressure Leaching [Seite 836]
102 - Part XXI Zinc Hydrometallurgy [Seite 842]
103 - 78 Development of the New Zinc-Separation Process for the Blast Furnace Dust [Seite 843]
104 - 79 Outotec Gypsum Removal Circuit and Outotec Cooling Tower Performance in Neutral Solution Cooling [Seite 849]
105 - 80 Purification and Comprehensive Recovery Metal Values from Zinc Hydrometallurgical Solution [Seite 857]
106 - 81 Refining of Zinc Chloride by the Combination of Cementation Reaction and Vacuum Distillation [Seite 862]
107 - 82 Advanced Concept "Poly Metallurgical Refinery" Developed by Cobre Las Cruces [Seite 870]
108 - Part XXII Environmental and Safety Practices II [Seite 880]
109 - 83 A New Lead Cementation Equipment and Lead Recovery Process in Chloride Media Developed by Cobre Las Cruces [Seite 881]
110 - 84 Performance and Mechanism of Chlorine Removal in Wastewater by Combination of CuSO4 and Zero-Valent Copper [Seite 890]
111 - 85 A Review on Recycling Technologies and Product Life Cycle Issues of Zinc and Lead [Seite 901]
112 - Part XXIII Poster Session [Seite 912]
113 - 86 Reaction Mechanism on a Novel Enhanced Smelting Technique for Lead-Acid Battery Paste Recycling [Seite 913]
114 - Author Index [Seite 922]
115 - Subject Index [Seite 926]
