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Fundamental Design of Steelmaking Refractories
Buch von Debasish Sarkar
Sprache: Englisch

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Fundamental Design of Steelmaking Refractories

Comprehensive up-to-date resource organizing fundamental aspects for the design and performance of steelmaking refractories

Fundamental Design of Steelmaking Refractories provides a fundamental understanding in the design of steelmaking refractories, in detail and all in one source, enabling readers to understand various issues including how heat and mass transfer occurs throughout the refractory, how matrix impurity or their contact affects the phases, and how invisible defects form during refractory manufacturing that eventually facilitates to analyze wear, corrosion, and performance of different refractory linings for primary and secondary steelmaking vessels, tundish, and continuous casting refractories.

Other specific sample topics covered in Fundamental Design of Steelmaking Refractories include:
* Phase formations and correlation with impurity effects and refractory processing shortcomings
* Stress, wear, and corrosion to design refractories and performance statistics of steelmaking refractories
* Equilibrium and non-equilibrium phases, packing, stress and defects in compaction, and degree of ceramic bonding
* Thermal and mechanical behavior, flow control mechanisms, continuous casting refractories, and premature refractory damage
* Precast and purging system, consistent supply and time management, and preventive maintenance in operation

With its complete coverage of the subject, Fundamental Design of Steelmaking Refractories fulfills the academic demand of undergraduate, postgraduate, and research scholars of ceramic engineering; metallurgical engineers and mechanical engineering outlets that want to nurture in the refractory and steel sectors will also find value in the text.
Fundamental Design of Steelmaking Refractories

Comprehensive up-to-date resource organizing fundamental aspects for the design and performance of steelmaking refractories

Fundamental Design of Steelmaking Refractories provides a fundamental understanding in the design of steelmaking refractories, in detail and all in one source, enabling readers to understand various issues including how heat and mass transfer occurs throughout the refractory, how matrix impurity or their contact affects the phases, and how invisible defects form during refractory manufacturing that eventually facilitates to analyze wear, corrosion, and performance of different refractory linings for primary and secondary steelmaking vessels, tundish, and continuous casting refractories.

Other specific sample topics covered in Fundamental Design of Steelmaking Refractories include:
* Phase formations and correlation with impurity effects and refractory processing shortcomings
* Stress, wear, and corrosion to design refractories and performance statistics of steelmaking refractories
* Equilibrium and non-equilibrium phases, packing, stress and defects in compaction, and degree of ceramic bonding
* Thermal and mechanical behavior, flow control mechanisms, continuous casting refractories, and premature refractory damage
* Precast and purging system, consistent supply and time management, and preventive maintenance in operation

With its complete coverage of the subject, Fundamental Design of Steelmaking Refractories fulfills the academic demand of undergraduate, postgraduate, and research scholars of ceramic engineering; metallurgical engineers and mechanical engineering outlets that want to nurture in the refractory and steel sectors will also find value in the text.
Über den Autor

Debasish Sarkar, PhD, is currently Professor of the Department of Ceramic Engineering, National Institute of Technology, Rourkela, India. Prof. Sarkar has been working in the subject area of nanostructured ceramics, ceramic processing, iron and steel making refractories. process optimization and finite element analysis of structural ceramics for 26 years. He has published numerous peer-review articles, national and international patents, prototype developments, and books on the projected topics.

Inhaltsverzeichnis

Preface xv

Acknowledgment xvii

About Author xix

1 Heat and Mass Transfer 1

1.1 Introduction 1

1.2 Energy Conservation 2

1.3 Conduction 6

1.3.1 Basic Concept and Properties 6

1.3.2 One-Dimensional Steady-state Conduction 9

1.3.3 Two-Dimensional Steady-state Conduction 14

1.4 Convection 16

1.4.1 Boundary Layers 18

1.4.2 Laminar and Turbulent Flow 21

1.4.3 Free and Forced Convection 23

1.4.4 Flow in Confined Region 24

1.5 Radiation 29

1.5.1 Basic Concepts 29

1.5.2 Emission from Real Surfaces 29

1.5.3 Absorption, Reflection, and Transmission by Real Surfaces 31

1.5.4 Exchange Radiation 32

1.6 Mass Transfer 34

1.6.1 Convection Mass Transfer 35

1.6.2 Multiphase Mass Transfer 35

1.6.3 Analogy-Heat, Mass, and Momentum Transfer 37

1.7 Heat Transfer in Refractory Lining 39

1.7.1 Tunnel Kiln 39

1.7.2 Ladle Lining 40

References 43

2 Equilibrium and Nonequilibrium Phases 45

2.1 Introduction 45

2.2 Basics of Phase Diagram 45

2.2.1 Gibb's Phase Rule 45

2.2.2 Binary Phase Diagram and Crystallization 47

2.2.3 Ternary Phase Diagram and Crystallization 55

2.2.4 Alkemade Lines 60

2.3 One-Component Phase Diagrams 62

2.3.1 Water 62

2.3.2 Quartz 63

2.4 Two-Component Phase Diagrams 64

2.4.1 Fe-C 64

2.4.2 Two Oxides Phase Diagrams 66

2.5 Three-Component Phase Diagrams 72

2.5.1 Three Oxides Phase Diagrams 72

2.5.2 FeO-SiO2 -C 78

2.6 Nucleation and Crystal Growth 79

2.6.1 Homogenous and Heterogeneous Nucleation 79

2.6.2 Crystal Growth Process 82

2.7 Nonequilibrium Phases 83

References 85

3 Packing, Stress, and Defects in Compaction 87

3.1 Introduction 87

3.2 Refractory Grading and Packing 88

3.2.1 Binary and Ternary System 89

3.2.2 Particle Morphology and Mechanical Response 91

3.2.3 Nanoscale Particles and Mechanical Response 93

3.2.4 Binder and Mixing on Packing 95

3.3 Stress-Strain during Compaction 98

3.4 Agglomeration and Compaction 99

3.5 Uniaxial Pressing 102

3.6 Cold Isostatic Pressing 104

3.7 Defects in Shaped Refractories 107

References 111

4 Degree of Ceramic Bonding 113

4.1 Introduction 113

4.2 Importance of Heating Compartment 114

4.2.1 Loading and Heating 114

4.2.2 Heat Distribution 116

4.2.3 Temperature Conformity 116

4.3 Initial Stage Sintering 118

4.3.1 Sintering Mechanisms of Two-particle Model 118

4.3.2 Atomic Diffusion 120

4.3.3 Sintering Kinetics 121

4.3.4 Sintering Variables 125

4.3.5 Limitations of Initial Stage of Sintering 126

4.4 Intermediate and Final Stage Sintering 126

4.4.1 Intermediate Stage Model 126

4.4.2 Final Stage Model 128

4.4.3 Influence of Entrapped Gases 129

4.5 Microstructure Alteration 130

4.5.1 Recrystallization and Grain Growth 130

4.5.2 Grain Growth: Normal and Abnormal 131

4.5.3 Pores and Secondary Crystallization 135

4.6 Sintering with Low Melting Constituents 137

4.7 Bonding Below 1000°C 138

4.7.1 Organic Binder 139

4.7.2 Inorganic Binder 140

4.7.3 Carbonaceous Binder 141

References 142

5 Thermal and Mechanical Behavior 143

5.1 Introduction 143

5.2 Mechanical Properties 144

5.2.1 Elastic Modulus 144

5.2.2 Hardness 146

5.2.3 Fracture Toughness 147

5.2.4 Strength 149

5.2.5 Fatigue 154

5.3 Cracking 154

5.3.1 Theory of Brittle Fracture 156

5.3.2 Physics of Fracture 158

5.3.3 Spontaneous Microcracking 159

5.4 Thermal Properties 160

5.4.1 Stress Anisotropy and Magnitude 160

5.4.2 Thermal Conductivity 162

5.4.3 Thermal Expansion 164

5.4.4 Thermal Shock 166

5.4.5 Thermal Stress Distribution 166

5.5 Thermomechanical Response 168

5.5.1 Refractoriness under Load 169

5.5.2 Creep in Compression (CIC) 171

5.5.3 Hot Modulus of Rupture 174

5.6 Wear 176

5.6.1 System-dependent Phenomena 176

5.6.2 Adhesive 178

5.6.3 Abrasive 179

5.6.4 Erosive 180

5.6.5 Oxidative 181

References 182

6 High Temperature Refractory Corrosion 183

6.1 Introduction 183

6.2 Thermodynamic Perceptions 184

6.3 Effect of Temperature and Water Vapor 187

6.4 Slag-Refractory Interactions 191

6.4.1 Diffusion in Solids 193

6.4.2 Oxidation 195

6.4.3 Infiltration 198

6.4.4 Dissolution 201

6.4.5 Crystallite Alteration 204

6.4.6 Endell, Fehling, and Kley Model 205

6.5 Phenomenological Approach and Slag Design 206

6.5.1 Refractory Solubility 209

6.5.2 Slag Composition and Volume Optimization 210

References 215

7 Operation and Refractories for Primary Steel 217

7.1 Introduction 217

7.2 Operational Features in BOF 221

7.2.1 Charging and Blowing 222

7.2.2 Mode of Blowing 223

7.2.3 Physicochemical Change in BOF 227

7.2.4 Tapping 230

7.2.5 Slag Formation 231

7.3 Operational Features in EAF 232

7.4 Refractory Designing and Lining 236

7.4.1 Steel Chemistry and Slag Composition 236

7.4.2 Thermal and Mechanical Stress 239

7.4.3 Refractory Lining and Corrosive Wear 243

7.4.4 Refractory Composition and Properties 249

7.5 Refractory Maintenance Practice 252

7.6 Philosophy to Consider Raw Materials 254

7.7 Microstructure-dependent Properties of Refractories 257

7.7.1 Microstructure Deterioration Inhibition to Improve Slag Corrosion Resistance 257

7.7.2 Slag Coating to Protect the Working Surface 258

7.7.3 Microstructure Reinforcement by Evaporation-Condensation of Pitch 259

7.7.4 Whisker Insertion to Reinforce Microstructure 259

7.7.5 Fracture Toughness Enhancement and Crack Propagation Inhibition 259

References 260

8 Operation and Refractories for Secondary Steelmaking 263

8.1 Introduction 263

8.2 Steel Diversity, Nomenclature, and Use 267

8.3 Vessels for Different Grades of Steel 270

8.4 Operational Features of Vessels 272

8.4.1 Ladle Furnace (LF) 273

8.4.2 Argon Oxygen Decarburization (AOD) 278

8.4.3 Vacuum Ladle Degassing Process 279

8.4.4 Stirring and Refining Process in Degassing 285

8.4.5 Composition Adjustment by Sealed Ar Bubbling with Oxygen Blowing (CAS-OB) 288

8.4.6 RH Snorkel 289

8.5 Designing Aspects of Refractories 291

8.6 Refractories for Working Lining 303

8.6.1 Magnesia-Carbon Refractories 303

8.6.2 Alumina-Magnesia-Carbon Refractories 306

8.6.3 Dolo-Carbon Refractories 310

8.6.4 Magnesia-chrome (MgO-Cr2O3) 313

8.6.5 Spinel Bricks 314

References 315

9 Precast and Purging System 319

9.1 Introduction 319

9.2 Composition Design of Castables 320

9.2.1 Choice of Raw Materials and Properties 322

9.2.2 Choice of Binders 329

9.2.3 Aggregates Grading 333

9.2.4 On-site Castable Casting 335

9.3 Precast-Shape Design and Manufacturing 337

9.4 Precast Shapes and Casting 337

9.5 Purging Plugs 341

9.5.1 Plug Design and Refractory 341

9.5.2 Gas Purging 344

9.5.3 Installation and Maintenance 346

9.5.4 Clogging and Corrosion 348

References 350

10 Refractories for Flow Control 353

10.1 Introduction 353

10.2 First-Second-Third Generation Slide Gate 355

10.3 New Generation Ladle Slide Gate System 359

10.4 Ladle Slide Gate Plate 360

10.4.1 Critical Design Parameters 362

10.4.2 Selection of Slide Plate and Fixing 366

10.4.3 Materials and Fabrication of SGP 369

10.4.4 Mode of Failures 374

10.4.5 FEA for Stress and Cracking 378

10.5 Tundish Slide Gate and Plate 380

10.5.1 Modern Slide Gate and Refractory Assembly 381

10.5.2 Materials and Fabrication 381

10.5.3 Cracking and Corrosion Phenomena 383

10.6 Short Nozzles for Ladle and Tundish 389

10.7 Nozzle Diameter and Gate Opening in Flow 390

References 393

11 Refractories for Continuous Casting 395

11.1 Introduction 395

11.2 Importance of Long Nozzles in Steel Transfer 397

11.2.1 Furnace to Ladle Transfer 397

11.2.2 Ladle to Tundish Transfer 398

11.2.3 Tundish to Mold Transfer 399

11.3 Tundish Lining 400

11.3.1 Lining and Failure 400

11.3.2 Lining Improvement and Maintenance 407

11.4 Ladle Shroud (LS) 409

11.4.1 Design and Geometry 409

11.4.2 Failures, Materials and Processing 418

11.4.3 Operational Practice 424

11.4.4 Flow Pattern 425

11.5 Mono Block Stopper 427

11.5.1 Preheating Schedule 427

11.5.2 Installation 428

11.5.3 Failures 429

11.5.4 Glazing 430

11.6 Submerged-Entry Nozzle 430

11.6.1 Installation and Failures 431

11.6.2 SEN Fixing for Thin Slab Caster 432

11.6.3 SES Installation and Failures 432

11.6.4 Corrosion and Clogging 435

References 444

12 Premature Refractory Life by Other Parameters 445

12.1 Introduction 445

12.2 Refractory Manufacturing Defects 446

12.2.1 Consistence Raw Material 447

12.2.2 Processing Parameters 449

12.2.3 Pressing and Firing 451

12.3 Packing and Transport 453

12.3.1 Packaging and Packing Material 453

12.3.2 Vibration-free Packaging 454

12.3.3...

Details
Erscheinungsjahr: 2023
Fachbereich: Fertigungstechnik
Genre: Technik
Rubrik: Naturwissenschaften & Technik
Medium: Buch
Inhalt: 528 S.
ISBN-13: 9781119790730
ISBN-10: 1119790735
Sprache: Englisch
Einband: Gebunden
Autor: Sarkar, Debasish
Hersteller: John Wiley & Sons Inc
Maße: 160 x 238 x 36 mm
Von/Mit: Debasish Sarkar
Erscheinungsdatum: 19.05.2023
Gewicht: 0,886 kg
Artikel-ID: 123503087
Über den Autor

Debasish Sarkar, PhD, is currently Professor of the Department of Ceramic Engineering, National Institute of Technology, Rourkela, India. Prof. Sarkar has been working in the subject area of nanostructured ceramics, ceramic processing, iron and steel making refractories. process optimization and finite element analysis of structural ceramics for 26 years. He has published numerous peer-review articles, national and international patents, prototype developments, and books on the projected topics.

Inhaltsverzeichnis

Preface xv

Acknowledgment xvii

About Author xix

1 Heat and Mass Transfer 1

1.1 Introduction 1

1.2 Energy Conservation 2

1.3 Conduction 6

1.3.1 Basic Concept and Properties 6

1.3.2 One-Dimensional Steady-state Conduction 9

1.3.3 Two-Dimensional Steady-state Conduction 14

1.4 Convection 16

1.4.1 Boundary Layers 18

1.4.2 Laminar and Turbulent Flow 21

1.4.3 Free and Forced Convection 23

1.4.4 Flow in Confined Region 24

1.5 Radiation 29

1.5.1 Basic Concepts 29

1.5.2 Emission from Real Surfaces 29

1.5.3 Absorption, Reflection, and Transmission by Real Surfaces 31

1.5.4 Exchange Radiation 32

1.6 Mass Transfer 34

1.6.1 Convection Mass Transfer 35

1.6.2 Multiphase Mass Transfer 35

1.6.3 Analogy-Heat, Mass, and Momentum Transfer 37

1.7 Heat Transfer in Refractory Lining 39

1.7.1 Tunnel Kiln 39

1.7.2 Ladle Lining 40

References 43

2 Equilibrium and Nonequilibrium Phases 45

2.1 Introduction 45

2.2 Basics of Phase Diagram 45

2.2.1 Gibb's Phase Rule 45

2.2.2 Binary Phase Diagram and Crystallization 47

2.2.3 Ternary Phase Diagram and Crystallization 55

2.2.4 Alkemade Lines 60

2.3 One-Component Phase Diagrams 62

2.3.1 Water 62

2.3.2 Quartz 63

2.4 Two-Component Phase Diagrams 64

2.4.1 Fe-C 64

2.4.2 Two Oxides Phase Diagrams 66

2.5 Three-Component Phase Diagrams 72

2.5.1 Three Oxides Phase Diagrams 72

2.5.2 FeO-SiO2 -C 78

2.6 Nucleation and Crystal Growth 79

2.6.1 Homogenous and Heterogeneous Nucleation 79

2.6.2 Crystal Growth Process 82

2.7 Nonequilibrium Phases 83

References 85

3 Packing, Stress, and Defects in Compaction 87

3.1 Introduction 87

3.2 Refractory Grading and Packing 88

3.2.1 Binary and Ternary System 89

3.2.2 Particle Morphology and Mechanical Response 91

3.2.3 Nanoscale Particles and Mechanical Response 93

3.2.4 Binder and Mixing on Packing 95

3.3 Stress-Strain during Compaction 98

3.4 Agglomeration and Compaction 99

3.5 Uniaxial Pressing 102

3.6 Cold Isostatic Pressing 104

3.7 Defects in Shaped Refractories 107

References 111

4 Degree of Ceramic Bonding 113

4.1 Introduction 113

4.2 Importance of Heating Compartment 114

4.2.1 Loading and Heating 114

4.2.2 Heat Distribution 116

4.2.3 Temperature Conformity 116

4.3 Initial Stage Sintering 118

4.3.1 Sintering Mechanisms of Two-particle Model 118

4.3.2 Atomic Diffusion 120

4.3.3 Sintering Kinetics 121

4.3.4 Sintering Variables 125

4.3.5 Limitations of Initial Stage of Sintering 126

4.4 Intermediate and Final Stage Sintering 126

4.4.1 Intermediate Stage Model 126

4.4.2 Final Stage Model 128

4.4.3 Influence of Entrapped Gases 129

4.5 Microstructure Alteration 130

4.5.1 Recrystallization and Grain Growth 130

4.5.2 Grain Growth: Normal and Abnormal 131

4.5.3 Pores and Secondary Crystallization 135

4.6 Sintering with Low Melting Constituents 137

4.7 Bonding Below 1000°C 138

4.7.1 Organic Binder 139

4.7.2 Inorganic Binder 140

4.7.3 Carbonaceous Binder 141

References 142

5 Thermal and Mechanical Behavior 143

5.1 Introduction 143

5.2 Mechanical Properties 144

5.2.1 Elastic Modulus 144

5.2.2 Hardness 146

5.2.3 Fracture Toughness 147

5.2.4 Strength 149

5.2.5 Fatigue 154

5.3 Cracking 154

5.3.1 Theory of Brittle Fracture 156

5.3.2 Physics of Fracture 158

5.3.3 Spontaneous Microcracking 159

5.4 Thermal Properties 160

5.4.1 Stress Anisotropy and Magnitude 160

5.4.2 Thermal Conductivity 162

5.4.3 Thermal Expansion 164

5.4.4 Thermal Shock 166

5.4.5 Thermal Stress Distribution 166

5.5 Thermomechanical Response 168

5.5.1 Refractoriness under Load 169

5.5.2 Creep in Compression (CIC) 171

5.5.3 Hot Modulus of Rupture 174

5.6 Wear 176

5.6.1 System-dependent Phenomena 176

5.6.2 Adhesive 178

5.6.3 Abrasive 179

5.6.4 Erosive 180

5.6.5 Oxidative 181

References 182

6 High Temperature Refractory Corrosion 183

6.1 Introduction 183

6.2 Thermodynamic Perceptions 184

6.3 Effect of Temperature and Water Vapor 187

6.4 Slag-Refractory Interactions 191

6.4.1 Diffusion in Solids 193

6.4.2 Oxidation 195

6.4.3 Infiltration 198

6.4.4 Dissolution 201

6.4.5 Crystallite Alteration 204

6.4.6 Endell, Fehling, and Kley Model 205

6.5 Phenomenological Approach and Slag Design 206

6.5.1 Refractory Solubility 209

6.5.2 Slag Composition and Volume Optimization 210

References 215

7 Operation and Refractories for Primary Steel 217

7.1 Introduction 217

7.2 Operational Features in BOF 221

7.2.1 Charging and Blowing 222

7.2.2 Mode of Blowing 223

7.2.3 Physicochemical Change in BOF 227

7.2.4 Tapping 230

7.2.5 Slag Formation 231

7.3 Operational Features in EAF 232

7.4 Refractory Designing and Lining 236

7.4.1 Steel Chemistry and Slag Composition 236

7.4.2 Thermal and Mechanical Stress 239

7.4.3 Refractory Lining and Corrosive Wear 243

7.4.4 Refractory Composition and Properties 249

7.5 Refractory Maintenance Practice 252

7.6 Philosophy to Consider Raw Materials 254

7.7 Microstructure-dependent Properties of Refractories 257

7.7.1 Microstructure Deterioration Inhibition to Improve Slag Corrosion Resistance 257

7.7.2 Slag Coating to Protect the Working Surface 258

7.7.3 Microstructure Reinforcement by Evaporation-Condensation of Pitch 259

7.7.4 Whisker Insertion to Reinforce Microstructure 259

7.7.5 Fracture Toughness Enhancement and Crack Propagation Inhibition 259

References 260

8 Operation and Refractories for Secondary Steelmaking 263

8.1 Introduction 263

8.2 Steel Diversity, Nomenclature, and Use 267

8.3 Vessels for Different Grades of Steel 270

8.4 Operational Features of Vessels 272

8.4.1 Ladle Furnace (LF) 273

8.4.2 Argon Oxygen Decarburization (AOD) 278

8.4.3 Vacuum Ladle Degassing Process 279

8.4.4 Stirring and Refining Process in Degassing 285

8.4.5 Composition Adjustment by Sealed Ar Bubbling with Oxygen Blowing (CAS-OB) 288

8.4.6 RH Snorkel 289

8.5 Designing Aspects of Refractories 291

8.6 Refractories for Working Lining 303

8.6.1 Magnesia-Carbon Refractories 303

8.6.2 Alumina-Magnesia-Carbon Refractories 306

8.6.3 Dolo-Carbon Refractories 310

8.6.4 Magnesia-chrome (MgO-Cr2O3) 313

8.6.5 Spinel Bricks 314

References 315

9 Precast and Purging System 319

9.1 Introduction 319

9.2 Composition Design of Castables 320

9.2.1 Choice of Raw Materials and Properties 322

9.2.2 Choice of Binders 329

9.2.3 Aggregates Grading 333

9.2.4 On-site Castable Casting 335

9.3 Precast-Shape Design and Manufacturing 337

9.4 Precast Shapes and Casting 337

9.5 Purging Plugs 341

9.5.1 Plug Design and Refractory 341

9.5.2 Gas Purging 344

9.5.3 Installation and Maintenance 346

9.5.4 Clogging and Corrosion 348

References 350

10 Refractories for Flow Control 353

10.1 Introduction 353

10.2 First-Second-Third Generation Slide Gate 355

10.3 New Generation Ladle Slide Gate System 359

10.4 Ladle Slide Gate Plate 360

10.4.1 Critical Design Parameters 362

10.4.2 Selection of Slide Plate and Fixing 366

10.4.3 Materials and Fabrication of SGP 369

10.4.4 Mode of Failures 374

10.4.5 FEA for Stress and Cracking 378

10.5 Tundish Slide Gate and Plate 380

10.5.1 Modern Slide Gate and Refractory Assembly 381

10.5.2 Materials and Fabrication 381

10.5.3 Cracking and Corrosion Phenomena 383

10.6 Short Nozzles for Ladle and Tundish 389

10.7 Nozzle Diameter and Gate Opening in Flow 390

References 393

11 Refractories for Continuous Casting 395

11.1 Introduction 395

11.2 Importance of Long Nozzles in Steel Transfer 397

11.2.1 Furnace to Ladle Transfer 397

11.2.2 Ladle to Tundish Transfer 398

11.2.3 Tundish to Mold Transfer 399

11.3 Tundish Lining 400

11.3.1 Lining and Failure 400

11.3.2 Lining Improvement and Maintenance 407

11.4 Ladle Shroud (LS) 409

11.4.1 Design and Geometry 409

11.4.2 Failures, Materials and Processing 418

11.4.3 Operational Practice 424

11.4.4 Flow Pattern 425

11.5 Mono Block Stopper 427

11.5.1 Preheating Schedule 427

11.5.2 Installation 428

11.5.3 Failures 429

11.5.4 Glazing 430

11.6 Submerged-Entry Nozzle 430

11.6.1 Installation and Failures 431

11.6.2 SEN Fixing for Thin Slab Caster 432

11.6.3 SES Installation and Failures 432

11.6.4 Corrosion and Clogging 435

References 444

12 Premature Refractory Life by Other Parameters 445

12.1 Introduction 445

12.2 Refractory Manufacturing Defects 446

12.2.1 Consistence Raw Material 447

12.2.2 Processing Parameters 449

12.2.3 Pressing and Firing 451

12.3 Packing and Transport 453

12.3.1 Packaging and Packing Material 453

12.3.2 Vibration-free Packaging 454

12.3.3...

Details
Erscheinungsjahr: 2023
Fachbereich: Fertigungstechnik
Genre: Technik
Rubrik: Naturwissenschaften & Technik
Medium: Buch
Inhalt: 528 S.
ISBN-13: 9781119790730
ISBN-10: 1119790735
Sprache: Englisch
Einband: Gebunden
Autor: Sarkar, Debasish
Hersteller: John Wiley & Sons Inc
Maße: 160 x 238 x 36 mm
Von/Mit: Debasish Sarkar
Erscheinungsdatum: 19.05.2023
Gewicht: 0,886 kg
Artikel-ID: 123503087
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