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Static and dynamic neutronic analysis of the uranium tetra-fluoride, ultrahigh temperature, vapor core reactor system PDF

396 Pages·1991·8.2 MB·English
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STATIC AND DYNAMIC NEUTRONIC ANALYSIS OF THE URANIUM TETRA-FLUORIDE, ULTRAHIGH TEMPERATURE, VAPOR CORE REACTOR SYSTEM By SAMER DAKHLALLAH KAHOOK A DISSERTATION PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY UNIVERSITY OF FLORIDA 1991 ^^ '.A it. Aj » !• - , <) '.01. ^ .. Dedicated to my parents, Mr. and Mrs. Dakh1a1lah Kahook, asking A11ah to reward them, have mercy on them, and grant them paradise as they raised and cherished me in my childhood. ,: i ACKNOWLEDGEMENTS The author would like to express his appreciation and sincere thanks to the members of his supervisory committee, Dr. Edward T. Dugan, Dr. Nils J. Diaz, Dr. Alan M. Jacobs, Dr. Samim Anghaie, Dr. William E. Lear, Jr., and Dr. Willis B. Person for their guidance and assistance during the course of this research. Special thanks are extended to Dr. Dugan, chairman of the author's supervisory committee for his patience and enduring support. The author recognizes that much of his knowledge in reactor physics and computer programming was realized while researching under the guidance and direction of Dr. Dugan. Support for this research has been provided, in part, by the Air Force Wright Aeronautical Laboratories (AFWAL), the Frederick Hauck Fund, and the University of Florida. The AFWAL work was performed for the Innovative Science and Technology Directorate of the Strategic Defense Initiative within the Innovative Nuclear Space Power Institute (INSPI). This support is greatly appreciated. Funding for the computer analysis was provided for by the National Science Foundation at the San Diego Supercomputer Center and the University of Florida and the International Business Machines (IBM) Corporation through their Research Computing Initiative at the North East Regional Data Center. The author is grateful for these funds. iii Thanks are also due to the fellow students whose friendships, comments, and encouragements have also facilitated in this research. The author would like to express his love and respect to his parents Mr. and Mrs. Dakhlallah Kahook, to his brothers Nofal and Mohammed, and to his sisters for their love, understanding, and patience throughout the author's stay at the University of Florida. The financial support provided to the author by his family is gratefully acknowledged. Finally, the author would like to express his love and deepest appreciation to his wife, Layali, whose understanding, patience, and support provided the motivation needed to finish this research. y -h .¥" ^ ' ; r V. " ' '- i ' I '• 'i. y ' X- '.,. ^' ^ ': ' I?- - --l t' -^-.: ' " ' ' ' -<*' 5 .1 .' iv TABLE OF CONTENTS Page i ACKNOWLEDGEMENTS i i i LIST OF TABLES x LIST OF FIGURES xiv ABSTRACT xvi i i CHAPTER INTRODUCTION I 1 Introduction 1 Description of the Ultrahigh Temperature Vapor Core Reactor 2 Dissertation Objectives 6 Dissertation Organization 7 II PREVIOUS RESEARCH ON RELATED CONCEPTS 11 Introduction 11 Previous Research on Gas Core Reactors 12 Previous Research on Coupled Core Reactors 13 Previous Research on Circulating Fuel Reactors 14 Remarks 18 III DESIGN OF THE URANIUM TETRA-FLUORIDE, ULTRAHIGH TEMPERATURE VAPOR CORE REACTOR 19 Introduction 19 Prel iminary Design Considerations 20 Choice of Materials 21 The Moderator-Reflector Material 21 The Fissioning Fuel Material 24 The Working Fluid Material 29 Description of a Uranium Tetra-Fluoride, UTVR/Disk MHD-Rankine Power Cycle 29 Neutronic Analysis of the Ultrahigh Temperature Vapor Core Reactor 37 Static Neutronic Calculations 37 Dynamic Neutronic Calculations 39 CHAPTER Piae IV STATIC, ONE-DIMENSIONAL, UTVR NUCLEAR CHARACTERIZATION AND CONFIGURATION OPTIMIZATION 40 Introduction 40 Scoping Calculations 43 Geometric Variations 43 UTVC radius 43 Inner BeO moderator-reflector region thickness 50 Outer BeO moderator-reflector region thickness 55 UF^ boiler region thickness 57 UF? boiler core volume 59 Fuel Density Variations 61 UF^ partial pressure and mole fraction (UF^rNaF) Jlin the UTVC 61 U"5 enrichment in UF« 62 u""* as the fissile isotope 62 Average density of the UF^ in the boiler region 66 Material Variations 68 Choice of metal fluoride in UTVC 68 Wall cooling region 70 Other metal fluoride working fluids 70 NaF mass flow rate to the boiler region 73 UF^/NaF inlet velocity to the boiler 76 Addition of Li F poison to the boiler 76 BeO in the annular boiler region 79 Reactivity effects of liner materials 81 One-Dimensional Results 84 The Neutron Multiplication Factor 86 Power Sharing Factor 87 Spherical "Mock-up" Comments 90 V STATIC, TWO-DIMENSIONAL, UTVR NUCLEAR CHARACTERIZATION AND CONFIGURATION OPTIMIZATION 94 Introduction 94 Scoping Calculations in R-^ Geometry 96 Geometric Variations 98 UTVC radius variations 98 Inner BeO moderator-reflector region thickness variations 104 Variation in the area of the boiler columns 107 Variation in the number of boiler columns 109 Fuel/Working-Fluid Density Variations 110 UF4 partial pressure in the UTVC 112 Average UF^ density in the boiler columns 115 Varying the UF^ average density in the UTVC as a function of the radial distance from the center ine 116 1 Scoping Calculations in R-Z Geometry 121 Geometric Variations 124 vi CHAPTER Page V MBEO region height 124 (cont.) TBEO region height 129 First OBEO region height 131 Boiler: subcooled and saturated liquid region height 134 Material Variation 135 Poisoning the boiler feedline walls 136 Comments on Power Sharing 140 Two-Dimensional Results 144 The Neutron Multiplication Factor 144 The Power Sharing Factor 146 Remarks 148 VI STATIC, THREE-DIMENSIONAL NEUTRONIC ANALYSIS OF THE UTVR.... 151 Introduction 151 Description of the UTVR Geometry in MCNP 152 Description of the Boiler Column 156 Reactivity Worths of the Boiler Feedlines, UTVC Inlet PIenums and the MHD Duct Regions 158 , Reducing the Uncertainty in Parameters Associated with the Boiler Columns in MCNP Calculations 161 Performance of Variance-Reduction Techniques 165 Nuclear and Physical Characteristics of the UTVR 166 , ' r V Energy Cutoff 168 ' * Implicit Capture and Weight Cutoff 168 Weight Windows 173 BB0o1illeerr--ttoo--UuTiVvCt Ssyymmmmeettrryy 178 Neuittrroonn TTrraannssppoorrtt CCoouupp!liinngg CCooeeffffiicciieents 185 ir. Obtained Directly from MCNP. 187 €1*'^ Obtained Indirectly from MMCC^NP 189 Isolation of secondary coupling effects 190 , Neutron Multiplication Factor.of the j Core, k^ff... 197 Reactivity of the j^" Core, p^..., :I1... 198 Prompt Neutron Generation Time, A'^(t) 198 Results of Density Variations in the UTVC and Boiler Col umns 199 VII KINETIC EQUATIONS OF A FOUR-BOILER COLUMN UTVR SYSTEM 209 Introduction 209 The Four-Boiler Column UTVR System Coupled Core Point Reactor Kinetics Equations 209 Core-to-Core Fuel -Flow Coupling 211 Core-to-Core Neutron Transport Coupling 214 Steady-State Solution 218 . The Linearized UTVR CC-PRK Equations 221 Inherent Reactivity Feedbacks of the UTVR « 229 Reactivity Feedback of the Boiler Columns, Sp {t) 233 Reactivity Feedback of the UTVC, 8p^{t) 251 vii CHAPTER r^ :-. ^aae VIII DYNAMIC ANALYSIS OF THE UTVR 264 Introduction 264 The Unperturbed UTVR Configuration 265 Results of the Dynamic Analysis 269 Boiler Column Reactivity Perturbation 269 UTVC Reactivity Perturbation 276 Variations in Core-to-Core Direct Neutron Transport Delay Times 283 Variations in the Coupling Coefficients 287 Variations in the UTVC Fuel Mass Reactivity Feedback Coefficient 291 Concluding Remark 296 IX SUMMARY OF RESULTS, CONCLUSIONS, AND RECOMMENDATIONS FOR FURTHER RESEARCH 300 Introduction 300 Summary of Results 300 Results from the Static Neutronic Analysis 300 Results from the Dynamic Neutronic Analysis 302 Comments and Conclusions 303 - Recommendations for Further Research 305 Static Neutronic Analysis 305 ' Dynamic Neutronic Analysis 307 APPENDICES .. J ' ; . 4 '< ' ^* :^w, A DESCRIPTION OF THE COMPUTER CODES 309 Introduction 309 Description of Nuclear Codes 309 AMPX: A Modular Code System for Generating Coupled Multigroup Neutron-Gamma Libraries from ENDF/B 309 The AMPX-DRIVER module 311 The XLACS module 311 The NITAWL module 312 The XSDRNPM module 312 DOT-4: A One- and Two-Dimensional Neutron/Photon Transport Code 315 GIP 316 MCNP-A General Monte Carlo Code for Neutron and Photon Transport 317 Description of the EASY5 Engineering Analysis Program 318 B BENCHMARK CALCULATIONS OF XSDRNPM AND DOT-4 WITH MCNP 320 Comparison of XSDRNPM with MCNP 320 Comparison of DOT-4 with MCNP 324 Conclusion 329 Vl•l•l• APPENDICES Page C DESCRIPTION OF THE ISOLATOR OF SECONDARY COUPLING EFFECTS CODE 331 Introduction 331 Description of the ISCE Code 331 The MAIN Module 331 The REED Module 332 The ERIN Module 332 The NOUT Module 333 The ESTM Module 333 The RITE Module 337 Input Data Format 337 Input Data File 337 List of Input Data Files 339 Comparison of Results Obtained from ISCE with Results Obtained Directly from MCNP 340 D CIRCULATING-FUEL, COUPLED CORE POINT REACTOR KINETICS EQUATIONS 345 Description and Definition of Symbols, Parameters, and Terms used in the Circulating-Fuel, Coupled Core Point Reactor Kinetics Equations 350 Definition of Superscripts and Subscripts 350 Definition of Integral Parameters 351 Neutron population, N"^{t) 351 Reactivity, /)J(t) 354 Effective delayed neutron fraction, ^(t) 354 Prompt neutron generation time, A'^{t) 358 Effective delayed neutron precursor concentration for the delayed neutron grouo, tj{t) 358 i Effective coupling coefficient, c:3 (t) 359 Interpretation of Equations (D-l) and (D-4) 361 Equation (D-l) 361 Equation (D-4) 365 LIST OF REFERENCES 366 BIOGRAPHICAL SKETCH 371 ix

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