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200 10$aModeling, sensing and control of gas metal arc welding /$fDesineni Subbaram Naidu, Selahattin Ozcelik, Kevin L. Moore
210   $aOxford $cElsvier$d2003
215   $a1 online resource (373 p.)
300   $aDescription based upon print version of record.
311   $a0-08-044066-5 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Modeling, Sensing and Control of Gas Metal Arc Welding; Copyright Page; Contents; Dedication; Preface; Acknowledgments; List of Figures; Chapter 1. Introduction; 1.1 Introduction; 1.2 The Survey; References List for Chapter 1; Chapter 2. Gas Metal Arc Welding: Modeling; 2.1 Gas Metal Arc Welding; 2.2 Physics of Welding; 2.3 Melting Rate; 2.4 Metal Transfer Characteristics; 2.5 Weld Pool; 2.6 Process Voltages; 2.7 Heat and Mass Transfer; 2.8 Process Variables; 2.9 INEEL/ISU Model; 2.10 Empirical and Statistical Models; 2.11 Modeling by System Identification and Estimation
327   $a2.12 Intelligent Modeling2.13 Other Issues on Modeling; 2.14 Power Supplies; 2.15 Other Issues on Power Supplies; 2.16 Classification of References by Section; References List for Chapter 2; Chapter 3. Gas Metal Arc Welding: Sensing; 3.1 Classification of Sensors; 3.2 Conventional Method; 3.3 Computer-Based Measurements; 3.4 Welding Parameters Monitoring; 3.5 Sensors for Line Following/Seam Tracking; 3.6 Arc Length Sensors; 3.7 Sensors for Weld Penetration Control; 3.8 Sensors for Weld Pool Geometry; 3.9 Optical Sensors; 3.10 Sensors for Quality Control; 3.11 Intelligent Sensing
327   $a3.12 Other Issues on Sensing3.13 Classification of References by Section; References List for Chapter 3; Chapter 4. GMAW: Automatic Control; 4.1 Automatic Welding; 4.2 Control of Process Variables; 4.3 Classical Control: PI, PID and Others; 4.4 Multivariable Control; 4.5 Optimization and Optimal Control; 4.6 Adaptive Control; 4.7 Intelligent Control; 4.8 Statistical Process Control and Quality Control; 4.9 Other Control Methodologies and Issues; 4.10 Safety and Environmental Issues; 4.11 Classification of References by Section; References List for Chapter 4
327   $aChapter 5. Control of GMAW: A Case Study5.1 Introduction; 5.2 Empirical Modeling of a GMAW Process; 5.3 SISO Current Control Using PI Controller; 5.4 Multi-Loop Control of the GMAW Process; 5.5 Adaptive Control of GMAW Process; 5.6 Control Strategy; 5.7 Summary; 5.8 Classification of References by Section; References List for Chapter 5; Chapter 6. Conclusions; 6.1 Control Technology and Automation in Welding; 6.2 Main Issues and Outlook; 6.3 Classification of References by Section; References List for Chapter 6; Bibliography; Index
330   $aArc welding is one of the key processes in industrial manufacturing, with welders using two types of processes - gas metal arc welding (GMAW) and gas tungsten arc welding (GTAW).   This new book provides a survey-oriented account of the modeling, sensing, and automatic control of the GMAW process.Researchers are presented with the most recent information in the areas of modeling, sensing and automatic control of the GMAW process, collecting a number of original research results on the topic from the authors and colleagues. Providing an overview of a variety of topics, this boo
606   $aGas metal arc welding
606   $aElectric welding
615  0$aGas metal arc welding.
615  0$aElectric welding.
676   $a671.5/212 22
676   $a671.5212
676   $a671.5212
700   $aNaidu$b D. S$g(Desineni S.),$f1940-$057406
701   $aOzcelik$b Selahattin$f1965-$0738992
701   $aMoore$b Kevin L.$f1960-$01822934
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996   $aModeling, sensing and control of gas metal arc welding$94389389
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200 00$aHeat Treatment of Steels
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (213 p.)
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330   $aSteels represent a quite interesting material family, both from scientific and commercial points of view, following many applications they can be devoted to. Following this, it is therefore essential to deeply understand the relations between properties and microstructure and how to drive them via a specific process. Despite their diffusion as a consolidated material, many research fields are active regarding new applications. In this framework, in particular, the role of heat treatments in obtaining complex microstructures is still quite an open matter, which is also thanks to the design of innovative heat treatments.This Special Issue embraces interdisciplinary work covering physical metallurgy and processes, reporting on experimental and theoretical progress concerning microstructural evolution during the heat treatment of steels.
606   $aTechnology: general issues$2bicssc
610   $aAlN precipitate
610   $aannealing
610   $aaustempering
610   $aaustenite grain size
610   $aauto-tempering
610   $aboiling and quenching heat transfer
610   $aboiling curve
610   $acarburization
610   $acompound layer
610   $acreep
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610   $aelongation to failure
610   $aFeCMnAl
610   $aflash heating
610   $aforged steels
610   $aforging
610   $agear steel
610   $ahigh silicon steel
610   $ahigh speed steel
610   $ahigh-Cr steel
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610   $amaterials design
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610   $ametal quenching heat flow
610   $amicrostructure
610   $an/a
610   $anitriding
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610   $apearlitic steel wire
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610   $aprecipitation criterion
610   $aprocess design
610   $aQP
610   $aquenching severity
610   $areduction of area
610   $aresidual stress
610   $aretained austenite
610   $asteel
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610   $astress relief
610   $atempering
610   $athermo-cycling annealing
610   $atorsion
610   $atwo-stage treatment
610   $aultra-high strength steel
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610   $avacuum heat treatment
610   $awelded rotor
610   $awhite layer
610   $aZener pinning
610   $a?-carbide
615  7$aTechnology: general issues
700   $aDi Schino$b Andrea$4edt$01289225
702   $aTestani$b Claudio$4edt
702   $aDi Schino$b Andrea$4oth
702   $aTestani$b Claudio$4oth
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996   $aHeat Treatment of Steels$93021108
997   $aUNINA