signals for brushless DC motor/machine in...Figure E10.25.3 Top plot: motor (stator) current iMA(t) = I(R1) and applied ...Figure E10.25.4 Top plot: reverse conducting current of diode iDau(t) = I(Da...Figure E10.26.1 Full‐wave, three‐phase current‐controlled voltage source inv...Figure E10.26.2 Battery voltage Vbat = V(2) − V(0) and battery current or in...Figure E10.26.3 Reference currents of inverter vref1(t) = V(12) − V(0), vref...Figure E10.26.4 Power system phase voltages van(t) = V(19) − V(123), vbn(t) ...Figure E10.27.1 Equivalent circuit of a solar cell.Figure E10.27.2 Nonlinear convex (Vc − Ic) characteristic of a solar cell.Figure E10.27.3 Equivalent circuit of a solar PV array or panel with bypass ...Figure E10.27.4 Battery voltage Vbat = V(2) − V(0) and battery current or in...Figure E10.27.5 Reference currents of inverter vref1(t) = V(12) − V(0), vref...Figure E10.27.6 Power system phase voltages van(t) = V(19) − V(123), vbn(t) ...Figure E10.28.1 Block diagram of direct‐drive, variable‐speed wind power pla...Figure E10.28.2 Direct‐drive (without mechanical gear), variable‐speed three...Figure E10.28.3 Three‐phase ∆/(ungrounded Y) step‐up transformer supplying t...Figure E10.28.4 Three‐phase current‐controlled voltage source inverter suppl...Figure E10.28.5 Top plot: steady‐state line‐to‐neutral voltages van(t) = V(1...Figure E10.28.6 Top plot: required (given) rectifier output unipolar voltage...Figure E10.28.7 Reference line currents vref1(t) = V(12) − V(0), vref2(t) = Figure E10.28.8 Top plot: required (given) rectifier output unipolar voltage...Figure E10.28.9 Top plot: secondary phase transformer currents iaph(t) = I(LFigure E10.28.10 Top plot: primary line transformer currents igenA(t) = I(Rg...Figure E10.28.11 Design dimensions of tower of wind power plant.Figure 10.3 Voltage–current (v‐i) diagram of motoring and regeneration modes...Figure 10.4 Block diagram of motoring mode converting electric energy of con...Figure 10.5 Block diagram of regeneration mode converting mechanical braking...Figure E10.29.1 Input transformer (N1 : N2) with diode bridge PWM MOSFET swi...Figure E10.29.2 Current‐controlled PWM voltage source inverter [7, 8, 17] fe...Figure E10.29.3 Top plot: input DC voltage to inverter vout(t) = Vbat(t) ≈ VFigure E10.29.4 Harmonic current through DC input source of inverter ibat(t)...Figure E10.29.5 Top plot: induced voltages of induction machine ea(t) = vout...Figure E10.29.6 Comparison of reference currents vref1(t) = V(12) − V(0), vr...Figure E10.29.7 Input AC voltage to primary of step‐up transformer vsyst(t) ...Figure E10.29.8 Secondary transformer voltage vsec(t) = V(10) − V(11) and cu...Figure E10.29.9 Top plot: unipolar output voltage of diode bridge vCbridge(tFigure E10.29.10 Current through MOSFET switch iDMosfet(t) = ID(mosfet) oper...Figure E10.29.11 Top plot: unipolar (or DC) output voltage vout(t) ≈ Vbat = 12 Chapter 11Figure 11.1 Assembled DC machine [1].Figure 11.2 Disassembled DC machine [1] of Figure 11.1.Figure 11.3 Rotor lamination with rectangular slots to house the rotor windi...Figure 11.4 Types of rotor slots housing different winding coils: (a) single...Figure 11.5 Double‐layer lap winding with p = 4 poles and N = 24 full‐pitch ...Figure 11.6 Developed (straightened out) four‐pole rotor/armature winding of...Figure 11.7a Two‐pole direct‐current (DC) machine with slip rings consists o...Figure 11.7b Instantaneous magnetomotive forces (mmfs) Fs and Fr; flux densi...Figure 11.8a Two‐pole DC machine consisting of stationary stator (s) with an...Figure 11.8b Instantaneous magnetomotive forces (mmfs) Ff and Fa; flux densi...Figure 11.8c Application of the right‐hand‐side rule producing the mechanica...Figure 11.9a Schematic cross section of one pole pitch (half a period) of a ...Figure 11.9b Two‐dimensional magnetic field distribution of one pole pitch o...Figure 11.9c Air‐gap flux density of Figure 11.9, expanded rotor position 1 ...Figure 11.10 (a) Ward Leonard system [30] or generator/motor set applied to ...Figure 11.11 (a) Separately excited DC motor with armature reaction compensa...Figure 11.12 (a) Separately excited generator with cumulatively/differential...Figure 11.13 Self‐excited generator used when no independent voltage source ...Figure 11.14 (a) Series excited motor with one independent voltage source VaFigure E11.1.1 Equivalent circuit of a separately excited DC motor. For stea...Figure E11.2.1 Equivalent circuit of DC machine with (cumulative) flux addit...Figure E11.2.2 Applied terminal armature voltage Va(t) as a function of time...Figure E11.2.3 Applied mechanical shaft torque Tm(t) as a function of time....Figure E11.2.4 Calculated armature current Ia(t) as a function of time.Figure E11.2.5 Calculated angular velocity ωm(t) as a function of time....Figure E11.2.6 Calculated electrical torque Te(t) as a function of time.Figure E11.2.7 Calculated output power P(t) as a function of time.Figure E11.2.8 Calculated armature current Ia(t) as a function of time.Figure E11.2.9 Calculated angular velocity ωm(t) as a function of time....Figure E11.2.10 Calculated electrical torque Te(t) as a function of time.Figure E11.2.11 Calculated output power P(t) as a function of time.Figure E11.2.12 Calculated armature current Ia(t) as a function of time.Figure E11.2.13 Calculated angular velocity ωm(t) as a function of time...Figure E11.2.14 Calculated electrical torque Te(t) as a function of time.Figure E11.2.15 Calculated output power P(t) as a function of time.Figure P11.1.1 Circuit [39] for measuring the armature resistance Ra.Figure P11.1.2 Starting circuit [39] of separately excited DC motor includin...Figure P11.1.3 Separately excited DC motor with automatic starting box consi...Figure P11.1.4 Transient armature current ia(t) in ampere (A) and transient ...Figure P11.3.1 Equivalent circuit of separately excited DC generator supplyi...Figure 11.A.1 Vector equipotential lines (specified by potential ϕi) fo...Figure 11.A.2a Vectors used for flux calculation [3]. The potential Ao is a ...Figure 11.A.2b Vectors used for flux calculation based on triangular first‐o...Figure 11.A.2c Equidistant vector potential (Aℓ) solution [2] for a si...Figure 11.A.3 Relations used for flux calculation [2] based on rectangular (...Figure 11.A.3d Equidistant vector potential (Ao) solution [2] for a simple o...Figure 11.A.4a Definition of vertex coordinates used for flux calculation ba...Figure 11.A.4b Equidistant vector potential (Aℓ) solution [2] for a si...Figure 11.B.1 Grid or node system for the numerical analysis of a 16‐pole DC...Figure 11.B.2 Magnetic field or vector potential distribution based on numer...
13 Chapter 12Figure 12.1 Two‐phase, two‐pole stator winding consisting of concentrated wi...Figure 12.2 Radial fundamental cosinusoidal magnetic field intensity Hg of c...Figure 12.3a Instantaneous magnetic field intensity Hg(ωt = 0) or F1(ωt...Figure 12.3b Instantaneous magnetic field intensity Hg(ωt = π/2) or F2(Figure 12.3c Instantaneous magnetic field intensity Hg(ωt = π) or F3(ωt...Figure 12.4a Three‐phase stator winding and rotating DC winding on rotor. Th...Figure 12.4b Three‐phase stator winding and rotating DC winding on rotor. Th...Figure 12.5 Four‐pole configuration with concentrated two-phase windings. Th...Figure 12.6 Magnetic field intensity Hg in the air gap around the circumfere...Figure 12.7 Magnetic field intensity Hg in the air gap around the circumfere...Figure 12.8 Three‐phase, two‐pole distributed winding located in 18 stator s...Figure 12.9 Three‐phase, four‐pole distributed winding located in 24 stator ...Figure 12.10 Various permanent‐magnet material characteristics [8], where Ne...Figure 12.11 Typical demagnetization curves and temperature dependency of Nd...Figure 12.12 Load line 1: load line for small air‐gap and large flux density...Figure 12.13a Partial cross section of a 12‐pole
