Power system analysis / (Record no. 62205)
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| 000 -CABECERA | |
|---|---|
| Campo de control de longitud fija | 09868nam a2200349 a 4500 |
| 003 - IDENTIFICADOR DEL NÚMERO DE CONTROL | |
| Identificador del número de control | AR-sfUTN |
| 008 - DATOS DE LONGITUD FIJA--INFORMACIÓN GENERAL | |
| Códigos de información de longitud fija | 170717b ||||| |||| 00| 0 d |
| 020 ## - NÚMERO INTERNACIONAL ESTÁNDAR DEL LIBRO | |
| ISBN | 9780072847963 |
| 040 ## - FUENTE DE LA CATALOGACIÓN | |
| Centro transcriptor | AR-sfUTN |
| 041 ## - CÓDIGO DE LENGUA | |
| Código de lengua del texto | eng |
| 080 ## - NÚMERO DE LA CLASIFICACIÓN DECIMAL UNIVERSAL | |
| Clasificación Decimal Universal | 621.316.11 SA12 |
| Edición de la CDU | 2000 |
| 100 1# - ENTRADA PRINCIPAL--NOMBRE DE PERSONA | |
| Nombre personal | Saadat, Hadi |
| 245 10 - MENCIÓN DE TÍTULO | |
| Título | Power system analysis / |
| Mención de responsabilidad | Hadi Saadat. |
| 250 ## - MENCIÓN DE EDICIÓN | |
| Mención de edición | 2nd |
| 260 ## - PUBLICACIÓN, DISTRIBUCIÓN, ETC. | |
| Lugar de publicación, distribución, etc. | Boston: |
| Nombre del editor, distribuidor, etc. | McGraw-Hill, |
| Fecha de publicación, distribución, etc. | 2002 |
| 300 ## - DESCRIPCIÓN FÍSICA | |
| Extensión | 712 p. |
| 336 ## - TIPO DE CONTENIDO | |
| Fuente | rdacontent |
| Término de tipo de contenido | texto |
| Código de tipo de contenido | txt |
| 337 ## - TIPO DE MEDIO | |
| Fuente | rdamedia |
| Nombre del tipo de medio | sin mediación |
| Código del tipo de medio | n |
| 338 ## - TIPO DE SOPORTE | |
| Fuente | rdacarrier |
| Nombre del tipo de soporte | volumen |
| Código del tipo de soporte | nc |
| 500 ## - NOTA GENERAL | |
| Nota general | Incluye CD-ROM, NºI RE0328 |
| 505 80 - NOTA DE CONTENIDO CON FORMATO | |
| Nota de contenido con formato | CONTENIDO<br/>PREFACE xv<br/>1 THE POWER SYSTEM: AN OVERVIEW 1<br/>1.1 INTRODUCTION 1<br/>1.2 ELECTRIC INDUSTRY STRUCTURE 2<br/>1.3 MODERN POWER SYSTEM 4<br/>1.3.1 GENERATION 4<br/>1.3.2 TRANSMISSION AND SUBTRANSMISSION 6<br/>1.3.3 DISTRIBUTION 6<br/>1.3.4 LOADS 8<br/>1.4 SYSTEM PROTECTION 11<br/>1.5 ENERGY CONTROL CENTER 11<br/>1.6 COMPUTER ANALYSIS 11<br/>2 BASIC PRINCIPLES 14<br/>2.1 INTRODUCTION 14<br/>2.2 POWER IN SINGLE-PHASE AC CIRCUITS 15<br/>2.3 COMPLEX POWER 19<br/>2.4 THE COMPLEX POWER BALANCE 21<br/>2.5 POWER FACTOR CORRECTION 23<br/>2.6 COMPLEX POWER FLOW 26<br/>2.7 BALANCED THREE-PHASE CIRCUITS 30<br/>2.8 Y-CONNECTED LOADS 32<br/>2.9 DELTA-CONNECTED LOADS 34<br/>2.10 DELTA-Y TRANSFORMATION 35<br/>2.11 PER-PHASE ANALYSIS 36<br/>2.12 BALANCED THREE-PHASE POWER 37<br/>3 GENERATOR AND TRANSFORMER MODELS; THE PER-UNIT SYSTEM 48<br/>3.1 INTRODUCTION 48<br/>3.2 SYNCHRONOUS GENERATORS 49<br/>3.2.1 GENERATOR MODEL 49<br/>3.3 STEADY-STATE CHARACTERISTICS CYLINDRICAL ROTOR 56<br/>3.3.1 POWER FACTOR CONTROL 56<br/>3.3.2 POWER ANGLE CHARACTERISTICS 57<br/>3.4 SALIENT-POLE SYNCHRONOUS GENERATORS 62<br/>3.5 POWER TRANSFORMER 64<br/>3.6 EQUIVALENT CIRCUIT OF A TRANSFORMER 64<br/>3.7 DETERMINATION OF EQUIVALENT CIRCUIT PARAMETERS 68<br/>3.8 TRANSFORMER PERFORMANCE 70<br/>3.9 THREE-PHASE TRANSFORMER CONNECTIONS 74<br/>3.9.1 THE PER-PHASE MODEL OF A THREE-PHASE TRANSFORMER 76<br/>3.10 AUTOTRANSFORMERS 77<br/>3.10.1 AUTOTRANSFORMER MODEL 81<br/>3.11 THREE-WINDING TRANSFORMERS 81<br/>3.11.1 THREE-WINDING TRANSFORMER MODEL 82<br/>3.12 VOLTAGE CONTROL OF TRANSFORMERS 83<br/>3.12.1 TAP CHANGING TRANSFORMERS 83<br/>3.12.2 REGULATING TRANSFORMERS OR BOOSTERS 86<br/>3.13 THE PER-UNIT SYSTEM 88<br/>3.14 CHANGE OF BASE 90<br/>4 TRANSMISSION LINE PARAMETERS 102<br/>4.1 INTRODUCTION 102<br/>4.2 OVERHEAD TRANSMISSION LINES 103<br/>4.3 LINE RESISTANCE 105<br/>4.4 INDUCTANCE OF A SINGLE CONDUCTOR 106<br/>4.4.1 INTERNAL INDUCTANCE 107<br/>4.4.2 INDUCTANCE DUE TO EXTERNAL FLUX LINKAGE 108<br/>4.5 INDUCTANCE OF SINGLE-PHASE UNES 109<br/>4.6 FLUX LINKAGE IN TERMS OF SELF- AND MUTUAL INDUCTANCES 110<br/>4.7 INDUCTANCE OF THREE-PHASE TRANSMISSION LINES 112<br/>4.7.1 SYMMETRICAL SPACING 112<br/>4.7.2 ASYMMETRICAL SPACING 113<br/>4.7.3 TRANSPOSE LINE 114<br/>4.8 INDUCTANCE OF COMPOSITE CONDUCTORS 115<br/>4.8.1 GMR OF BUNDLED CONDUCTORS 118<br/>4.9 INDUCTANCE OF THREE-PHASE DOUBLE-CIRCUIT LINES 119<br/>4.10 LINE CAPACITANCE 120<br/>4.11 CAPACITANCE OF SINGLE-PHASE LINES 121<br/>4.12 POTENTIAL DIFFERENCE IN A MULTICONDUCTOR CONFIGURATION 123<br/>4.13 CAPACITANCE OF THREE-PHASE LINES 124<br/>4.14 EFFECT OF BUNDLING 126<br/>4.15 CAPACITANCE OF THREE-PHASE DOUBLE-CIRCUIT LINES 126<br/>4.16 EFFECT OF EARTH ON THE CAPACITANCE 127<br/>4.17 MAGNETIC FIELD INDUCTION 133<br/>4.18 ELECTROSTATIC INDUCTION 135<br/>4.19 CORONA 135<br/>5 LINE MODEL AND PERFORMANCE 142<br/>5.1 INTRODUCTION 142<br/>5.2 SHORT LINE MODEL 143<br/>5.3 MEDIUM LINE MODEL 147<br/>5.4 LONG LINE MODEL 151<br/>5.5 VOLTAGE AND CURRENT WAVES 156<br/>5.6 SURGE IMPEDANCE LOADING 159<br/>5.7 COMPLEX POWER FLOW THROUGH TRANSMISSION LINES 161<br/>5.8 POWER TRANSMISSION CAPABILITY 163<br/>5.9 LINE COMPENSATION 165<br/>5.9.1 SHUNT REACTORS 165<br/>5.9.2 SHUNT CAPACITOR COMPENSATION 168<br/>5.9.3 SERIES CAPACITOR COMPENSATION 168<br/>5.10 LINE PERFORMANCE PROGRAM 171<br/>6 POWER FLOW ANALYSIS 189<br/>6.1 INTRODUCTION 189<br/>6.2 BUS ADMITTANCE MATRIX 190<br/>6.3 SOLUTION OF NONLINEAR ALGEBRAIC EQUATIONS 195<br/>6.3.1 GAUSS-SEIDEL METHOD 195<br/>6.3.2 NEWTON-RAPHSON METHOD 200<br/>6.4 POWER FLOW SOLUTION 208<br/>6.4.1 POWER FLOW EQUATION 208<br/>6.5 GAUSS-SEIDEL POWER FLOW SOLUTION 209<br/>6.6 LINE FLOWS AND LOSSES 212<br/>6.7 TAP CHANGING TRANSFORMERS 220<br/>6.8 POWER FLOW PROGRAMS 222<br/>6.9 DATA PREPARATION 223<br/>6.10 NEWTON-RAPHSON POWER FLOW SOLUTION 232<br/>6.11 FAST DECOUPLED POWER FLOW SOLUTION 240<br/>7 OPTIMAL DISPATCH OF GENERATION 257<br/>7.1 INTRODUCTION 257<br/>7.2 NONLINEAR FUNCTION OPTIMIZATION 258<br/>7.2.1 CONSTRAINED PARAMETER OPTIMIZATION: EQUALITY CONSTRAINTS 260<br/>7.2.2 CONSTRAINT PARAMETER OPTIMIZATION: INEQUALITY CONSTRAINTS 264<br/>7.3 OPERATING COST OF A THERMAL PLANT 267<br/>7.4 ECONOMIC DISPATCH NEGLECTING LOSSES AND NO GENERATOR LIMITS 268<br/>7.5 ECONOMIC DISPATCH NEGLECTING LOSSES AND INCLUDING GENERATOR LIMITS 276<br/>7.6 ECONOMIC DISPATCH INCLUDING LOSSES 279<br/>7.7 DERIVATION OF LOSS FORMULA 289<br/>8 SYNCHRONOUS MACHINE TRANSIENT ANALYSIS 314<br/>8.1 INTRODUCTION 314<br/>8.2 TRANSIENT PHENOMENA 315<br/>8.3 SYNCHRONOUS MACHINE TRANSIENTS 318<br/>8.3.1 INDUCTANCES OF SALIENT-POLE MACHINES 320<br/>8.4 THE PARK TRANSFORMATION 321<br/>8.5 BALANCED THREE-PHASE SHORT CIRCUIT 325<br/>8.6 UNBALANCED SHORT CIRCUITS 330<br/>8.6.1 LINE-TO-LINE SHORT CIRCUIT 330<br/>8.6.2 LINE-TO-GROUND SHORT CIRCUIT 333<br/>8.7 SIMPLIFIED MODELS OF SYNCHRONOUS MACHINES FOR TRANSIENT ANALYSES 335<br/>8.8 DC COMPONENTS OF STATOR CURRENTS 340<br/>8.9 DETERMINATION OF TRANSIENT CONSTANTS 342<br/>8.10 EFFECT OF LOAD CURRENT 347<br/>9 BALANCED FAULT 353<br/>9.1 INTRODUCTION 353<br/>9.2 BALANCED THREE-PHASE FAULT 354<br/>9.3 SHORT-CIRCUIT CAPACITY (SCC) 362<br/>9.4 SYSTEMATIC FAULT ANALYSIS USING BUS IMPEDANCE MATRIX 363<br/>9.5 ALGORITHM FOR FORMATION OF THE BUS IMPEDANCE MATRIX 369<br/>9.6 ZBUILD AND SYMFAULT PROGRAMS 381<br/>10 SYMMETRICAL COMPONENTS AND UNBALANCED FAULT 399<br/>10.1 INTRODUCTION 399<br/>10.2 FUNDAMENTALS OF SYMMETRICAL COMPONENTS 400<br/>10.3 SEQUENCE IMPEDANCES 406<br/>10.3.1 SEQUENCE IMPEDANCES OF Y-CONNECTED LOADS 407<br/>10.3.2 SEQUENCE IMPEDANCES OF TRANSMISSION LINES 409<br/>10.3.3 SEQUENCE IMPEDANCES OF SYNCHRONOUS MACHINE 410<br/>10.3.4 SEQUENCE IMPEDANCES OF TRANSFORMER 411<br/>10.4 SEQUENCE NETWORKS OF A LOADED GENERATOR 418<br/>10.5 SINGLE LINE-TO-GROUND FAULT 421<br/>10.6 LINE-TO-LINE FAULT 423<br/>10.7 DOUBLE LINE-TO-GROUND FAULT 425<br/>10.8 UNBALANCED FAULT ANALYSIS USING BUS IMPEDANCE MATRIX 432<br/>10.8.1 SINGLE LINE-TO-GROUND FAULT USING Zbus 432<br/>10.8.2 LINE-TO-LINE FAULT USING Zbus 433<br/>10.8.3 DOUBLE LINE-TO-GROUND FAULT USING Zbus 434<br/>10.8.4 BUS VOLTAGES AND LINE CURRENTS DURING FAULT 434<br/>10.9 UNBALANCED FAULT PROGRAMS 442<br/>11 STABILITY 460<br/>11.1 INTRODUCTION 460<br/>11.2 SWING EQUATION 461<br/>11.3 SYNCHRONOUS MACHINE MODELS FOR STABILITY STUDIES 464<br/>11.3.1 SYNCHRONOUS MACHINE MODEL INCLUDING SALIENCY 467<br/>11.4 STEADY-STATE STABILITY SMALL DISTURBANCES 471<br/>11.5 TRANSIENT STABILITY EQUAL-AREA CRITERION 486<br/>11.5.1 APPLICATION TO SUDDEN INCREASE IN POWER INPUT 488<br/>11.6 APPLICATION TO THREE-PHASE FAULT 492<br/>11.7 NUMERICAL SOLUTION OF NONLINEAR EQUATION 501<br/>11.8 NUMERICAL SOLUTION OF THE SWING EQUATION 504<br/>11.9 MULTIMACHINE SYSTEMS 511<br/>11.10 MULTIMACHINE TRANSIENT STABILITY 514<br/>12 POWER SYSTEM CONTROL 527<br/>12.1 INTRODUCTION 527<br/>12.2 BASIC GENERATOR CONTROL LOOPS 528<br/>12.3 LOAD FREQUENCY CONTROL 528<br/>12.3.1 GENERATOR MODEL 529<br/>12.3.2 LOAD MODEL 530<br/>12.3.3 PRIME MOVER MODEL 530<br/>12.3.4 GOVERNOR MODEL 531<br/>12.4 AUTOMATIC GENERATION CONTROL 542<br/>12.4.1 AGC IN A SINGLE AREA SYSTEM 542<br/>12.4.2 AGC IN THE MULTIAREA SYSTEM 545<br/>12.4.3 TIE-LINE BIAS CONTROL 549<br/>12.5 AGC WITH OPTIMAL DISPATCH OF GENERATION 554<br/>12.6 REACTIVE POWER AND VOLTAGE CONTROL 555<br/>12.6.1 AMPLIFIER MODEL 555<br/>12.6.2 EXCITER MODEL 556<br/>12.6.3 GENERATOR MODEL 557<br/>12.6.4 SENSOR MODEL 557<br/>12.6.5 EXCITATION SYSTEM STABILIZER - RATE FEEDBACK 562<br/>12.6.6 EXCITATION SYSTEM STABILIZER - PID CONTROLLER 564<br/>12.7 AGC INCLUDING EXCITATION SYSTEM 566<br/>12.8 INTRODUCTORY MODERN CONTROL APPLICATION 567<br/>12.8.1 POLE-PLACEMENT DESIGN 569<br/>12.8.2 OPTIMAL CONTROL DESIGN 576<br/>APPENDIXES<br/>A INTRODUCTION TO MATLAB 586<br/>A.1 INSTALLING THE TEXT TOOLBOX 587<br/>A.2 RUNNING MATLAB 587<br/>A.3 VARIABLES 589<br/>A.4 OUTPUT FORMAT 590<br/>A.5 CHARACTER STRING 592<br/>A.6 VECTOR OPERATIONS 593<br/>A.7 ELEMENTARY MATRIX OPERATIONS 596<br/>A.7.1 UTILITY MATRICES 599<br/>A.7.2 EIGENVALUES 599<br/>A.8 COMPLEX NUMBERS 599<br/>A.9 POLYNOMIAL ROOTS AND CHARACTERISTIC POLYNOMIAL 601<br/>A.9.1 PRODUCT AND DIVISION OF POLYNOMIALS 603<br/>A.9.2 POLYNOMIAL CURVE FITTING 604<br/>A.9.3 POLYNOMIAL EVALUATION 604<br/>A.9.4 PARTIAL-FRACTION EXPANSION 605<br/>A.10 GRAPHICS 606<br/>A.11 GRAPHICS HARD COPY 608<br/>A.12 THREE-DIMENSIONAL PLOTS 615<br/>A.13 HANDLE GRAPHICS 616<br/>A.14 LOOPS AND LOGICAL STATEMENTS 619<br/>A.15 SOLUTION OF DIFFERENTIAL EQUATIONS 626<br/>A.16 NONLINEAR SYSTEMS 629<br/>A.17 SIMULATION DIAGRAM 631<br/>A.18 INTRODUCTION TO SIMULINK 634<br/>A.18.1 SIMULATION PARAMETERS AND SOLVER 635<br/>A.18.2 THE SIMULATION PARAMETERS DIALOG BOX 636<br/>A.18.3 BLOCK DIAGRAM CONSTRUCTION 637<br/>A.18.4 USING THE TO WORKSPACE BLOCK 643<br/>A.18.5 LINEAR STATE-SPACE MODEL FROM SIMULINK DIAGRAM 644<br/>A.18.6 SUBSYSTEMS AND MASKING 646<br/>B REVIEW OF FEEDBACK CONTROL SYSTEMS 648<br/>B.1 THE CONTROL PROBLEM 648<br/>B.2 STABILITY 649<br/>B.2.1 THE ROUTH-HURWITZ STABILITY CRITERION 650<br/>B.2.2 ROOT-LOCUS METHOD 651<br/>B.3 STEADY-STATE ERROR 652<br/>B.4 STEP RESPONSE 654<br/>B.5 ROOT-LOCUS DESIGN 655<br/>B.5.1 GAIN FACTOR COMPENSATION OR P CONTROLLER 656<br/>B.5.2 PHASE-LEAD DESIGN 657<br/>B.5.3 PHASE-LAG DESIGN 658<br/>B.5.4 PID DESIGN 659<br/>B.5.5 PD CONTROLLER 659<br/>B.5.6 PI CONTROLLER 660<br/>B.5.7 PID CONTROLLER 660<br/>B.6 FREQUENCY RESPONSE 667<br/>B.6.1 BODE PLOT 667<br/>B.6.2 POLAR PLOT 668<br/>B.6.3 RELATIVE STABILITY 668<br/>B.6.4 GAIN AND PHASE MARGINS 669<br/>B.6.5 NYQUIST STABILITY CRITERION 670<br/>B.6.6 SIMPLIFIED NYQUIST CRITERION 670<br/>B.6.7 CLOSED-LOOP FREQUENCY RESPONSE 671<br/>B.6.8 FREQUENCY RESPONSE DESIGN 672<br/>B.7 Control System Toolbox LTI Models and LTI Viewer 675<br/>B.7.1 LTI Models 675<br/>B.7.2 The LTI Viewer 675<br/>C POWER SYSTEM TOOLBOX 679<br/>BIBLIOGRAPHY 686<br/>ANSWERS TO PROBLEMS 693 |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | POWER SYSTEM ANALYSIS |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | TRANSMISSION LINE |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | POWER FLOW ANALYSIS |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | SYNCHONOUS MACHINE |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | SYMMETRICAL COMPONENTS |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | UNBALANCED FAULT |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | POWER SYSTEMS CONTROL |
| 650 ## - PUNTO DE ACCESO ADICIONAL DE MATERIA--TÉRMINO DE MATERIA | |
| Término de materia | MATLAB |
| 942 ## - ELEMENTOS DE PUNTO DE ACCESO ADICIONAL (KOHA) | |
| Tipo de ítem Koha | Libros |
| Esquema de clasificación | Clasificación Decimal Universal |
| 999 ## - NÚMEROS DE CONTROL DE SISTEMA (KOHA) | |
| -- | 62205 |
| -- | 62205 |
| Estado | Estado perdido | Tipo de préstamo | Localización permanente | Ubicación/localización actual | Fecha de adquisición | Número de inventario | Total Checkouts | Total Renewals | ST completa de Koha | Código de barras | Date last seen | Date last checked out | Número de copias | Tipo de ítem Koha |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Facultad Regional Santa Fe | Facultad Regional Santa Fe | 02/02/2018 | 9607 | 10 | 4 | 621.316.11 SA12 | 9607 | 29/02/2024 | 03/05/2023 | 02/02/2018 | Libros |