INJECTION PHENOMENA AND HEAT TRANSFER IN COPPER CONVERTERS by ALEJANDRO ALBERTO BUSTOS Mining Eng., Universidad de Chile, 1972 M.Sc, Universidad de Chile, 1975 A THESIS SUBMITTED IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY in THE FACULTY OF GRADUATE STUDIES (Department of Metallurgical Engineering) We accept this thesis as conforming to the_j^-quired standard THE UNIVERSITY OF BRITISH COLUMBIA December 1984 0 Alejandro Alberto Bustos, 1984 In presenting this thesis in partial fulfilment of the requirements for an advanced degree at the University of British Columbia, I agree that the Library shall make it freely available for reference and study. I further agree that permission for extensive copying of this thesis for scholarly purposes may be granted by the head of my department or by his or her representatives. It is understood that copying or publication of this thesis for financial gain shall not be allowed without my written permission. Department of Metallurgical Engineering The University of British Columbia 1956 Main Mall Vancouver, Canada V6T 1Y3 Date February 18, 1985 ii ABSTRACT The injection dynamics and related accretion build up, as well as bath motion and heat losses in copper converters, have been investigated. The studies involved physical and mathematical models coupled with plant trials at four copper smelters to examine gas discharge phenomena, bath slopping and heat transfer within the converter. th The laboratory work, performed on a 1|4 scale model of a converter, indicated significant tuyere interaction. Air discontinuously discharges into the bath with a frequency which increases with gas flow rate and is affected by the bath circulation velocity in the tuyere region. Measurements have delineated slopping behaviour in terms of tuyere sub mergence and the buoyancy power input to the bath. The industrial trials were conducted in Peirce-Smith, Hoboken and Inspiration converters under normal conditions. A tuyerescope attached to the back of a tuyere permitted the direct observation of accretion growth and the sampling of accretions during blowing. The tests indicated that the copper converter operates under bubbling conditions. Pressure pulses from the tuyeres revealed that in non-ferrous submerged in jection processes three regimes of gas-liquid interaction can be identified: bubbling, unstable envelope and channelling. i ii The relative dominance of each regime is affected by tuyere line erosion, viscosity of the bath and tuyere submergence. Analysis of the accretion samples revealed that accretions in the copper converter form mainly by the solidification of bath at the tuyere tip. Oxygen enriched air does not prevent accretion formation, but seems to produce a softer, easy-to- punch accretion. The type of puncher as well as punching frequency affect conditions inside the tuyere pipe and this could have an influence on accretion formation. The mathematical heat transfer model indicated that when the converter is out of the stack, heat losses through the mouth of the converter cause the internal surface to cool rapidly which may lead to freezing at the tuyere line and tuyere blockage when blowing is resumed. The temperature gradient, localized to within 60-80 mm of the refractory inside wall, changes markedly within the first minutes of the converter being out of stack. This may generate thermal stresses in the converter wall and contribute to refractory erosion at the tuyere line. Covering the converter mouth during out-of-stack periods significantly reduces the change in temperature gradient at the inside wall as well as heat losses from the converter. iv TABLE OF CONTENTS Page ii ABSTRACT TABLE OF CONTENTS iv LIST OF TABLES viii LIST OF FIGURES x TABLE OF NOMENCLATURE xvii ACKNOWLEDGEMENTS xx CHAPTER I INTRODUCTION: THE COPPER CONVERTING PROCESS 1 1.1 History of Copper Converting 2 1.2 Current Converting Practice 5 1.3 Problems in Copper Converting 9 CHAPTER II LITERATURE REVIEW: STUDIES IN GAS INJECTION 13 2.1 Studies in Side-Blown Injection 14 2.2 Bubble Formation During Submerged Injection 20 2.2.1 Bubble Formation in Low-Density, Inviscid Liquids 22 2.2.2 Bubble Formation in Liquid Metals 28 2.3 Pressure Fluctuations at the Tuyere .... 33 2.4 The Bubbling-Jetting Transition 44 2.5 Accretion Formation and Tuyere Blockage . 47 2.6 Bath Surface Movement. Splashing and Slopping 53 2.7 Summary 63 V CHAPTER III OBJECTIVES 66 CHAPTER IV EXPERIMENTAL TECHNIQUES 69 4.1 Laboratory Experimental Work 69 4.1.1 The isothermal Model ^ 4.1.2 Experimental Apparatus 77 4.1.2.1 Converter-Shaped Vessel 79 4.1.2.2 Tuyeres 82 4.1.2.3 Gas-Delivery System 85 4.1.2.4 Pressure Measurements 86 4.1.2.5 High-Speed Cinematography 86 4.1.3 Conditions for the Tests and General Procedure 88 4.2 Industrial Work 91 4.2.1 Smelters Selected for the Tests 92 4.2.2 Scope of the Industrial Tests 96 4.2.3 Equipment and Procedure 97 CHAPTER V EXPERIMENTAL RESULTS 103 5.1 Laboratory Results 103 5.1.1 Dynamic Pressure Measurements 103 5.1.1.1 Effect of the Air Flow Rate 104 5.1.1.2 Effect of Tuyere Spacing 110 5.1.1.3 Tuyere Interaction 113 5.1.1.4 Effect of Tuyere Submergence 115 5.1.2 High-Speed Cinematography 117 5.1.2.1 Observations at the Tuyere Line 117 5.1.2.2 Slopping Observations 120 5.1.3 Slopping Measurements 121 vi 5.2 Industrial Results 128 5.2.1 Dynamic Pressure in the Tuyeres 128 5.2.1.1 Effect of the State of the Refractory at the Tuyere Region 129 5.2.1.2 Effect of the Tuyere Submergence 132 5.2.1.3 Effect of Tuyere Blockage 132 5.2.2 Accretion Growth at the Tuyere Tip 136 5.2.2.1 Dynamics of Accretion Growth 136 5.2.2.2 Effect of Oxygen Enrichment of the Blast 138 5.2.2.3 Analysis of Accretion Samples 142 5.2.2.4 Influence of the 4B5 Punching System 144 5.2.2.5 Tuyere Pipes. Metallographic Work 148 5.2.3 Bath Surface Movement and Splashing 151 CHAPTER VI HEAT LOSSES FROM COPPER CONVERTERS. A MATHEMATICAL MODEL 154 6.1 Scope of the Heat Transfer Model 154 6.2 The Mathematical Model 155 6.2.1 Radiation Heat Transfer in Copper Converters 158 6.2.2 Transient Conduction in the Elements in the Model 162 6.2.3 Computer Program 166 6.2.4 Range of Variables Studied in the Model 168 6.3 Accuracy of the Heat Transfer Model 169 6.4 Influence of the Refractory Emissivity 171 6.5 Model Predictions 175 6.5.1 Effect of the Converter Mouth Position 175 6.5.2 Thermally Active Zone in the Refractory .... 179 6.5.3 Effect of the Converter Diameter 182 6.5.4 Effect of the Area of the Converter Mouth .. 184 6.5.5 Influence of the Coverage of the Mouth 187 vii CHAPTER VII DISCUSSION 195 7.1 Injection Dynamics at the Tuyere Tip 195 7.2 Bath Movement and Slopping 209 7.3 Accretion Formation and Tuyere Blockage 213 7.4 Heat Losses from the Converter 218 CHAPTER VIII SUMMARY AND CONCLUSIONS 221 8.1 Summary 221 8.2 Suggestions for further Work 225 REFERENCES 228 APPENDIX I THE PLATE ORIFICE 240 APPENDIX II PRESSURE TRACES FOR DIFFERENT CHARGES OF THE COPPER CONVERTER 251 APPENDIX II RADIATION SHAPE FACTORS IN THE HEAT TRANSFER MODEL 253 APPENDIX IV THERMAL CONDUCTANCES FOR THE DIFFERENT NODES IN THE MODEL 257 APPENDIX V HEAT TRANSFER COEFFICIENT FOR THE EXTERNAL SURFACE OF THE CONVERTER 261 APPENDIX VI TEMPERATURE PROFILES IN THE CONVERTER WALL WITH VARIABLE THERMAL CONDUCTIVITY.. 267 APPENDIX VII HEAT TRANSFER MODEL PROGRAM 269 viii LIST OF TABLES Table 4.1 Physical Properties of Some Fluids 72 Table 4.1 Details of Copper Converter Practice in North America 80 Table 4.3 Characteristics of the Average 13 x 30 Converter and Three Other Plants 81 Table 4.4 Scaled-Down Characteristics for Different Models 89 Table 4.5 Range of Variables 90 Table 4.6 Conditions for the Industrial Trials 95 Table 6.1 Parameters in the Heat Transfer Model 170 Table 1.1 Characteristic Dimensions of Orifice and Comparison with Recommended Design Variables 241 Table 1.2 Values for Use in Equation (1.2) to Obtain Discharge Coefficients for 2-inch Plate Orifices 245 Table 1.3 Calibration of the Plate Orifice with a Diameter Ratio of 0.4 246 Table 1.4 Calibration of the Plate Orifice with a Diameter Ratio of 0.6 247 ix Table V.l Properties of Dry Air at Atmospheric Pressure 264 Table V.2 Heat Transfer Coefficient for Different Converter Diameters 265 Table V.3 Heat Losses by Convection and Radiation as Compared with Conductive Heat Flow Inside the Wall 266
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