Record ID | marc_columbia/Columbia-extract-20221130-031.mrc:10266595:8427 |
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LEADER: 08427cam a22007334a 4500
001 15062847
005 20220703231214.0
006 m o d
007 cr cn|---ancau
008 010717s2002 flua obf 001 0 eng c
010 $z 2001043027
035 $a(OCoLC)ocm49563891
035 $a(NNC)15062847
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020 $a0849300045$q(alk. paper)
020 $a9780849300042$q(alk. paper)
020 $a1420042653$q(electronic bk.)
020 $a9781420042658$q(electronic bk.)
020 $a128051857X
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024 7 $a10.1201/9781420042658$2doi
035 $a(OCoLC)49563891$z(OCoLC)71850184$z(OCoLC)144218135$z(OCoLC)232612336$z(OCoLC)276797217$z(OCoLC)506244031$z(OCoLC)647589881$z(OCoLC)779920249$z(OCoLC)987674672$z(OCoLC)992094798$z(OCoLC)994922814$z(OCoLC)1031046754$z(OCoLC)1058549494$z(OCoLC)1062891532$z(OCoLC)1063631264$z(OCoLC)1069726413$z(OCoLC)1086908530
037 $aTANDF_187558$bIngram Content Group
042 $apcc
050 4 $aTK2711$b.B65 2002
072 7 $aTEC$x007000$2bisacsh
082 04 $a621.31/042$221
049 $aZCUA
100 1 $aBoldea, I.
245 14 $aThe induction machine handbook /$cIon Boldea, Syed A. Nasar.
260 $aBoca Raton :$bCRC Press,$c2002.
300 $a1 online resource (950 pages) :$billustrations.
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
347 $adata file$2rda
490 1 $aElectric power engineering series
504 $aIncludes bibliographical references and index.
505 0 $aINDUCTION MACHINES IN INDUSTRY; Electric Energy and Induction Motors; Historical Development; Induction Machines in Applications; CONSTRUCTION ASPECTS AND OPERATION PRINCIPLES OF INDUCTION MACHINES; Construction Aspects of Rotary IMS; Construction Aspects of Linear Induction Motors; Operation Principles of Induction Machines; MATERIALS AND LOSSES; Magnetic Materials and Losses; Operating Flux Densities; Frequency Effects; Electric Materials and Losses; Skin Effect; Frequency Effects; Insulation Materials and Losses; Skin Effect; Frequency Effects; WINDINGS AND THEIR MMFS; Single-Layer and Double-Layer Windings; Integral and Fractional Slot Windings; Wave and Lap Windings; Pole-Changing Windings; Cage Windings; Current-Sheet Approach; MAGNETIZATION CURVE AND INDUCTANCE; Equivalent Airgap to Account for Slotting; Basic Magnetization Curve; An Analytical Iterative Saturation Model(AIM); Emf of an AC Winding; Magnetization
505 0 $aInductance; LEAKAGE INDUCTANCES AND RESISTANCES; Differential Leakage Inductances; Slot Leakage Inductances-Single and Double Layer, Rectangular and Rounded; End Connection Leakage Inductance; Rotor Bar and Ring Leakage Inductances; Stator and Rotor Leakage Inductances; Stator and Rotor Resistances; Rotor Quantities Referred to the Stator; STEADY-STATE PERFORMANCE CALCULATIONS; The Basic Equivalent Circuit; The Complete Equivalent Circuit; Modes of Operation: Motoring, Generating,
505 0 $aBraking; Torque/Speed Characteristics; Efficiency and Power Factor; Peak and Starting Torque Specifications; Standard and New Equivalent Circuits for Variable Speed; Nonsymmetric Operation Modes; STARTING AND SPEED CONTROL METHODS; ON-LOAD SATURATION AND FREQUENCY EFFECTS ON CIRCUIT PARAMETERS; Skin Effect Modelling-Single and Multiple Conductors in Slot; The Multilayer Approach to Skin Effect; Multi-Rotor Circuit Modeling; Leakage Saturation and Skin Effect via a Comprehensive Analytical Field Model; The Skewing mmf Concept; The FEM Approach; SPACE HARMONICS, PARASITIC TORQUES, RADIAL FORCES,
505 0 $aAND NOISE; mmf Space Harmonics; Airgap Magnetic Conductance Harmonics; Saturation Induced Airgap Flux Harmonics; Parasitic Torque; Radial Forces and Noise; CORE AND WINDING FUNDAMENTAL AND HARMONIC LOSSES; Core Loss Basic Models; Core Loss Advanced Models; Winding Fundamental and Harmonic Losses; Stray-Load Losses for Sinusoidal and Non-Sinusoidal Voltage Supply; THERMAL MODELING; Basic One-Dimensional Models; Realistic One-Dimensional Models; Models from Finite Element Analysis; INDUCTION MACHINE TRANSIENTS; The Phase Coordinate Model; The Complex Variable(Space Phasor) Model for Single Rotor Circuit; Space Phasor Equations and Diagrams; Steady-State Analysis with Space Phasors; Transient Analysis with Space Phasors; Multi-Rotor Circuit; Core loss and saturation consideration; Reduced Order Models; The Sudden Short Circuit; Most Severe Tansients So Far; The abc-dq Model; Multimachine Transients; Subsynchronous Resonance
505 0 $a; Torsional Torque Transients in Large Ims; Rotor Bar Current Models; Transients under Constant Flux Operation; DESIGN SPECIFICATIONS AND PRINCIPLES; Typical Load Curves; Derating; Voltage and Frequency Variation; Specifications for Constnat Voltage and Frequency Operation; Design Factors and Features; Output Coefficient Design Concept; Tangential Stress Coefficient design concept; IM DESIGN BELOW 100 KW AT CONSTANT V&F WITH CASE STUDY; IM DESIGN ABOVE 100KW AT CONSTANT V&F WITH CASE STUDY; IM DESIGN FOR VARIABLE SPEED WITH CASE STUDY; DESIGN OPTIMIZATION METHODS; Initial Data, Variables, Constraints, and Objective Functions; Induction Machine Models for Design; Design Optimization Techniques: Deterministic,
505 0 $aStochastic; Design of Large Induction Machines; Comparison Between Deterministic and Stochastic Methods; THREE PHASE INDUCTION GENERATORS; Induction Generators for Direct Grid Connection; Induction Generators for Autonomous Loads; Doubly Fed Induction Generators; LINEAR INDUCTION MOTORS; Topologies; Analysis of Fields and Forces; Equivalent Circuits; Longitudinal End Effects; Transverse Edge Effects; Design Procedure and Case Study; ULTRA-HIGH FREQUENCY MDELLING AND BEHAVIOR OF IMs; Practical Lumped RLC Modeling; Shaft Voltages and Bearing Currents; Micro-Second Voltage Pulse Distribution Along the Motor Windings; Long Cable Effects; Practical circuit models; TESTING OF THREE PHASE INDUCTION MACHINES; The IEEE-112B Standards and Results; Parameter Estimation from Pulse and Frequency Tests at Standstill; On-Line Parameter Estimation; Tests with Power Electronics; SINGLE PHASE INDUCTION MOTORS: THE BASICS; Classifications; Basic
505 0 $aEquivalent circuits; SINGLE-PHASE INDUCTION MOTORS: STEADY STATE; With Open Auxiliary Winding; Capacitor Motor; Symmetrization Conditions; Characteristic Curves; Nonorthogonal Winding Models; Space and Voltage Harmonic Effects; Doubly Tapped Winding Modelling and Performance; SINGLE PHASE INDUCTION MOTOR DESIGN & CASE STUDY; SINGLE PHASE INDUCTION GENERATORS; SINGLE PHASE INDUCTION MOTOR TRANSIENTS; TESTING OF SINGLE PHASE INDUCTION MOTORS
520 $aReviews many of the complex issues involved in the design and analysis of both single phase and three phase induction machines. The handbook begins with discussions of construction and operation principles, materials, windings, the magnetization curve, leakage inductances, and steady state equivale.
546 $aEnglish.
650 0 $aElectric machinery, Induction$vHandbooks, manuals, etc.
650 6 $aMachines à induction$vGuides, manuels, etc.
650 7 $aTECHNOLOGY & ENGINEERING$xElectrical.$2bisacsh
650 7 $aElectric machinery, Induction.$2fast$0(OCoLC)fst00905219
655 0 $aElectronic books.
655 4 $aElectronic books.
655 7 $aHandbooks and manuals.$2fast$0(OCoLC)fst01423877
700 1 $aNasar, S. A.
776 08 $iPrint version:$aBoldea, I.$tInduction machine handbook.$dBoca Raton : CRC Press, 2002$z0849300045$w(DLC) 2001043027$w(OCoLC)47625370
830 0 $aElectric power engineering series.
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio15062847$zTaylor & Francis eBooks
852 8 $blweb$hEBOOKS