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200 12$aA review of the lower Mississippi River Potamology Program /$fDavid S. Biedenharn, Wayne A. Stroupe, and John H. Brooks
210  1$a[Vicksburg, Miss.] :$cUS Army Corps of Engineers, Mississippi Valley Division,$d2014.
215   $a1 online resource (viii, 37 pages) $cillustrations
225 1 $aMRG & P Report ;$vNo. 1
300   $a"Report prepared for the Mississippi River Commission"--Cover.
300   $a"March 2014."
320   $aIncludes bibliographical references.
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606   $aGeomorphology$zMississippi River
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200 10$aFurnace Tapping 2022 /$fedited by Joalet D. Steenkamp, Dean Gregurek, Quinn G. Reynolds, Gerardo Alvear Flores, Hugo Joubert, Phillip J. Mackey
205   $a1st ed. 2022.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2022.
215   $a1 online resource (391 pages)
225 1 $aThe Minerals, Metals & Materials Series,$x2367-1696
311 08$aPrint version: Steenkamp, Joalet D. Furnace Tapping 2022 Cham : Springer International Publishing AG,c2022 9783030925437 
327   $aIntro -- Preface -- Contents -- About the Editors -- Part I  Session I -- 1  Controlled Tapping-The Research Project -- 2  MIRS Robotic Tapping and Plugging of Non-ferrous Smelting Furnaces -- 3  Theoretical Framework and Practical Recommendations for Proper Thermal Lance Use and Selection -- 4  Data Analysis to Assess Carry-Over Slag -- 5  An Overview of Submerged Arc Furnaces Tapping Operations and Tap-Hole Management at Assmang Manganese Cato Ridge Works -- 6  Aluminium Tapping and Molten Metal Handling in Primary Smelters -- Part II  Session II -- 8  Furnace Tapping 101 -- 9  CFD Study on Continuous Tapping of Silicon -- 10  Reduced-Order Models of Furnace Tapping Systems-A Case Study from a Submerged Arc Furnace Producing Silicomanganese -- 11  Tapped Alloy Mass Prediction Using Data-Driven Models with an Application to Silicomanganese Production -- 12  Slag Reduction and Viscosities Interaction in Ferromanganese Process -- 13  Lab-Scale Physical Model Experiments to Understand the Effect of Particle Bed on Tapping Flow Rates -- 14  The Interaction of Slag and Carbon on the Electrical Properties -- 15  Electrical Resistivity of Transformed Carbon Materials in the Silicon Furnace -- Part III  Session III -- 16  PGM, Nickel, and Copper Tapping: An Updated Industry Survey -- 17  Kansanshi Copper Smelter ISACONVERT? Furnace Tapping System Design, Operation, and Improvements -- 18  Successful Development and Optimisation of Lead ISASMELT? Furnace Slag Tapping System at Kazzinc Ltd. -- 19  Simulation-Based Approaches for Optimized Tap-Hole Design -- Part IV  Session IV -- 20  Tap-Hole Refractory Issues and Remedies -- 21  Sensor Technologies for Optimized Tapping Procedures -- 22  The Evaluation of Chemical Wear of Carbon-Based Tap-Hole Refractories in Ferrochrome Production.
327   $a23  Investigation of Melting Behavior and Viscosity of Slags from Secondary Ferromanganese Production -- 24  Metal and Slag Extraction from Different Zones of a Submerged Arc Furnace with Non-uniform Porous Bed Using CFD -- 25  Tapblock Refractory Wear Monitoring and Hearth Refractory Design Optimization in Metallurgical Furnaces -- 26  Slide Gate Technology for Slag Tapping -- 27  Tap-Hole Clay Technologies for Ferroalloy Reduction Furnaces -- 28  Health-Friendly Plugging Repair Pastes -- Author Index -- Subject Index.
330   $aNo pyrometallurgical smelter can operate without some form of tapping system. It is the one thing all smelters have in common. This collection discusses this meeting point of the science, technology, and skill involved in this process. The tap-hole design process includes a set of design criteria, which need to be revised as the results of laboratory, computational fluid dynamics (CFD), and time-and-motion studies become available. The tap-hole life cycle is considered in this volume, with authors addressing the requirements for installation and operability as well as for maintenance. Matters such as online monitoring of the tap-hole wear, handling of liquid products, and extraction of fumes are all discussed. Although much has been done to make the tapping process as automatic as possible, tapping of smelters cannot be done without labor. Tap floor operators work in harsh environments where safety is of utmost importance. Selection of suitable personnel and intensive training is required and is discussed in this collection.
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606   $aMaterials science
606   $aIndustrial and Production Engineering
606   $aEngineering Fluid Dynamics
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606   $aProcess Engineering
606   $aMaterials Science
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