ELE 361 Electric Machines I http://www.ee.hacettepe.edu.tr/~usezen/ele361/ 1 Textbooks • A.E. Fitzgerald, C. Kingsley, S.D. Umans, Electric Machinery, McGraw-Hill, 6th Ed., 2003, (5th Ed. 1991) • S.J. Chapman, Electric Machinery Fundamentals, McGrawHill, 2nd Ed., 1991 (3rd Ed., 1993) • G.R. Slemon, A. Straughen, Electric Machines, Addison Wesley, 1980. • P.C. Sen, Principles of Electrical Machinery and Power Electronics, J. Wiley, 1989 • S.A. Nasar, L.E. Unnewehr, Electromechanics and Electric Machines, J. Wiley, 2nd Ed., 1983. 2 Contents • Basic concepts of magnetic circuits (Ch.1, Text 1) – magnetization, energy storage, hysteresis and eddy-current losses • Single-phase transformers (Ch.2, Text 1) – equivalent circuit, open-and short circuit tests, regulation, efficiency • Electromechanical energy conversion (Ch.3, Text 1) – field energy, co-energy, force, torque, singly and doubly-excited systems • Principles of rotating machines (Ch.4, Text 1) – Construction and types of rotating machines, induced emf, armature mmf, torque production • Direct-current machines (Ch.7, Text 1) – emf and torque production, magnetization characteristic, methods of excitation, DC generator and motor analysis, ratings and efficiency • Single-phase induction motors (Ch.9, Text 1) – equivalent-circuit, s/s operation, starting. linear induction motor, splitphase, capacitor type, shaded pole motors 3 I. Basic concepts of Magnetic Circuits (M.C.) 4 1. Basic principles • Electromechanical energy conversion device (E.M.D) – links electrical & mechanical systems • or Electromechanical transducer (E.M.T) – converts electrical energy to mechanical energy and vice versa Electric Motors Electrical energy Mechanical energy Generators • The energy conversion is reversible 5 • Most energy forms are converted to electrical energy, since it can be – transmitted & distributed easily – controlled efficiently and reliably in a simple manner Primary sources of energy Electrical Energy hydropower, fossile fuel, natural gas wind, nuclear power etc. mechanical energy Turbine primary source mechanical , heat, chemical, light etc. electrical energy G Ultimately desired Output electrical energy process EMT mechanical energy M Pumps, fans etc output 6 • Coupling between electrical systems and mechanical systems is through the medium of fields of electric currents or charges. – MAGNETIC FIELDS • Electromagnetic machine – ELECTROSTATIC FIELDS • Electrostatic machine (not used in practice due to low power densities, resulting in large m/c sizes) 7 Principle phenomena in Electromechanical Energy Conversion (E.M.C) 1. Force on a conductor 2. Force on ferromagnetic materials (e.g. iron) 3. Generation of voltage 8 Force on a conductor • A mechanical force is exerted on current carrying conductor in a magnetic field (MF) and also between current carrying conductors by means of their MF – Reversibly voltage is induced in a circuit undergoing motion in a MF F l i B NB. In left-hand rule, B and i exchange fingers Right-hand rule 9 Ex1. Ex3. Ex4. Ex2. Induced voltage e d dt (t ) flux linkage 10 Force on a ferromagnetic materials • A mechanical force is exerted on a ferromagnetic material tending to align it with the position of the densest part of MF. 11 Generation of voltage • A voltage is induced in a coil when there is a change in the flux linking the coil eN d d dt dt e2 N 2 d dt 'iron 'air 12 • The change in flux linkage is either due to changing flux linking the coil (i.e. transformer voltage) or by relative motion of coil and MF with respect each other Single-coil rotor Flux linkage of the coil (i.e. flux captured by the coil) NB0 A cos , t 13 Classification of E.M.D. E.M.D. Continuous energy conversion devices electric motors, generators Force producing devices Devices used for measurement and control Relays, solenoids, electromagnets Electromechanical transducers 14 An E.M.D involves energy in 4 forms: • Motoring action Energy input from electrical sources • = Mechanical energy output + Energy converted into heat due to losses + Increase in energy stored in magnetic field – Energy converted into heat due to losses – Increase in energy stored in magnetic field Generating action Electrical energy output = Mechanical energy input Irreversible conversion to heat occurs due to – heat in i2R losses (copper losses) – magnetic losses (core losses) – mechanical losses (friction & windage losses) 15 Rewriting the energy balance equation (motoring convention): Electrical energy input – Copper losses = Net electrical energy input Mechanical energy output + + Friction & windage losses Increasing energy stored in M.F. + Core losses Gross mechanical energy output 16 2. Analysis of Magnetic Circuits (M.C.) g c c air 0 0 4 10 7 H/m c r 0 2000 r 80000 Magnetomotive force (F): F Ni Core flux density (Bc): Bc Airgap flux density (Bg): Bg Ac Ag [ Ampere-turns (AT) ] [ Wb/m2 or Tesla (T) ] [ Wb/m2 or Tesla (T) ] where represents the magnetic flux 17 Fringing effects: Due to fringing effects Ag > Ac Normally, we ignore fringing effects, so Ag Ac Since Ag Ac Bg Bc 18 Magnetomotive Force F C H d For the M.C. on the right F H H c c H g g Ni where H represents the magnetic field intensity 19 Relationship between Bc and Hc In the linear region Bc c H c linear region Bc , H c F linear region 20 F H c c H g g Assuming operating in the linear region, we can rewrite the above equation as : F Bc c c Bg 0 g 21 Magnetomotive Force - 2 F Bc c c Bg 0 g Noting that B = /A, we can rewrite the above equation as F c Ac c 0 Ag g c g F c Ac 0 Ag We can further simplify the notation F Rc Rg where R represents the magnetic resistance of the medium against flux, called reluctance 22 Reluctance F Rc Rg where: Rc c c Ac and Rg g 0 Ag [ AT/Wb ] Magnetic resistance of a medium against magnetic flux is called RELUCTANCE Note the analogy between the electrical circuits F Rc Rg V i R1 R2 23 Analogy between electric and magnetic circuits Correspondence of conductance in magnetic circuits is called permeance: P 1 R 24 Simplifications: F Rc Rg Rc c c Ac Rg g 0 Ag Noting that c = r 0 and 2000 < r < 80000 Rc << Rg in the linear region of Bc-Hc curve, i.e. in linear M.C.s so F Rg Ni Ni 0 Ac F R g Rg g Nearly all magnetomotive force (F ) is used to overcome the airgap portion of the MC 25 3. Flux Linkage and Inductance Flux linkage N For linear magnetic circuits and induced voltage e is given by e d dt Li where L indicates the self-inductance of coil 26 Self inductance of the N-turn coil: N Li L N NBc Ac i i For non-linear magnetic circuits or N N F N 2 L i i Rc Rc L d d N di di L N 2 Pc 27 Ex1. Find: a) the inductance of the winding b) flux density in gap g1 (B1) Equivalent magnetic circuit: 28 Ex2. plastic = 0 N = 200 turns i = 50A Consider the plastic ring above and assuming rectangular cross section area a) Find B at the mean diameter of coil b) Find inductance of coil, assuming flux density inside ring is uniform 29 Self and Mutual Inductances 1 N 1 F1 N 1 i1 2 N 2 F2 N 2 i2 F1 F2 F F 1 2 Rg Rc Rg Assumption: c air 0 1 1 N 1 N 1i1 Rg N 12 0 Ag g L11 Self-inductance of coil N 1 N 2 i2 Rg i1 N 1 N 2 0 Ag g i2 L12 Mutual-inductance between coils 1 & 2 30 Self and Mutual Inductances - 2 1 L11i1 L12 i2 2 L21i1 L22 i2 L11 N 12 Pg L22 N 22 Pg L12 L21 N 1 N 2 Pg where Pg 1 Rg 0 Ag g 31 Leakage Flux core flux m Leakage flux: Magnetizing flux: (core flux) l m leakage flux Not all the flux closes its path from the magnetic core, but some portion closes its path through air. This is called the leakage flux, l . 32 4. Magnetic Stored Energy • Stored energy in a magnetic circuit in a time interval between t1 and t2 : W tt12 p dt t t 12 e t t 12 i dt pei eN d d dt dt d i dt dt W 12 i d 33 W 12 i d For a linear magnetic circuit: Li i L W 1 2 d L 1 W 1 2 2 12 2L 34 Similarly L i d L di W 12 i d i Li12 i di 1 Li22 i12 2 With i1= 0, i2= i or 1= 0, 2= 1 W Li 2 2 or W 1 2 2L 35 W 12 i d F Ni i F N N d N d W 12 F d B H F 36 4. Magnetic Materials • Magnetic – Ferrimagnetic (2000 < r < 10000) • e.g. Mn-Zn alloy – Ferromagnetic (r around 80000) • Hard (permanent magnet) – e.g. Alnico, Neodimium-Iron-Boron, etc. (rare-earth magnets) • Soft (electrical steel) – e.g. FeSi, FeNi and FeCo alloys • Non-magnetic – Paramagnetic (r slightly > 1) • e.g. aluminum, platinum and magnesium – Diamagnetic (r slightly < 1) • e.g. copper and zinc 37 Properties of Magnetic Materials: • Become magnetized in the same direction of the applied magnetic field • B varies nonlinearly with H (doublevalued relationship between B and H ) • Exhibit saturation and hysteresis • Dissipate power under time-varying magnetic fields 38 Terminology: • Magnetization curve • Magnetic hysteresis • Residual flux density, Br and coercive field intensity, Hc • Cyclic state 39 S S N N Magnetic Hysteresis 40 Normal (DC) magnetization curve (n.m.c) for a ferromagnetic core: The curve used to describe a magnetic material is called the B-H curve, or the hysteresis loop: 41 Hysteresis Loop: Br : residual flux density Hc : coercive field intensity 42 Hysteresis Loop Magnetic performance of magnetic material depends on their previous history During measurements, the material should be put to a definite magnetic cycle: H is varied in a cyclic manner { +Hm 0 –Hm 0 +Hm} 2. 3. 4. From a demagnetized state (B = 0) while mmf F or field intensity H is gradually increased, B moves on n.m.c. from a b : [ H = 0 Hm B = 0 Bm] B moves from b c : [ H = Hm 0 B = Bm Br ] B moves from c d : [ H = 0 –Hc B = Br 0 ] B moves from d e : [ H = –Hc –Hm B = 0 –Bm ] 5. B moves from e f : [ H = –Hm 0 B = –Bm –Br ] 6. 7. B moves from f g : [ H = 0 Hc B moves from g b : [ H = Hc Hm B = –Br 0] B = 0 Bm] 1. 43 Ex: r 70000 Find: a. b. c. d. e. f. g. The exciting current ie for Bc = 1.0 T. The flux and flux linkage (ignore leakage fluxes). The reluctance of the airgap Rg and magnetic core Rc. The induced emf e for a 60 Hz core flux of Bc = 1.0 sin 377 t, Tesla The inductance L of the winding (neglect fringing fluxes) The magnetic stored energy W at Bc = 1.0T Assuming that core material has a DC magnetization curve, find the exciting current i for Bc = 1.0 T 44 Ex: r 70000 Magnetization curve of the core 45 6. AC Excitation and Losses a) Relation between periodic exciting current ie and flux in a magnetic circuit v t e t N d dt v t Vm cos t where ω 2πf ( t ) m sin t e t N d N m cos t E m cos t dt E m 2fN m E rms 2 fN m 2 E rms 4.44 fN m 46 Due to non-linear B-H characteristic (or - F ch.) of a magnetic material, the exciting current ie (or i ) is a distorted sine wave although flux is sinusoidal. 47 Distorted sine wave exciting current waveform 48 Expanding ie using Fourier series ie ( t ) I c1 cos t I m 1 sin t I c 3 cos 3t I m 3 sin 3t I c 5 cos 5t I m 5 sin 5t Neglecting high order harmonics: ie ( t ) I c1 cos t I m1 sin t ie ( t ) I c cos t I m sin t rc: core loss resistance xm: magnetizing reactance Steady-state equivalent circuit model of the exciting branch 49 b) Energy (power) losses in magnetic circuits Power loss in M.C. is due to: • Hysteresis loss • Eddy current losses 50 Hysteresis Loss W 12 F d F H c lc Bc Ac B W Ac lc B12 H dB B W Vc B12 H dB Vc: Volume of the magnetic core 51 For one cycle of ac excitation: Wab Vc BBm HdB 0 W bc Vc BBc HdB 0 a m Wcd Vc B Bm HdB 0 c Wda Vc BBa HdB 0 m Hysteresis loss per cycle of ac excitation: Wh Wab Wbc Wcd Wda Ph Wh f Empirical eqn: Ph Vc Bm f : constant depending on material type 1.5 x 2.5 x 52 Eddy Current Loss In general, M.C. have - very high magnetic permeability, c air 0 - high electrical conductivity (low resistivity), which causes extra I2R losses (Pe) within the magnetic materials when they are subject to time-varying MF. Eddy current loss: Pe K eVc d 2 Bm2 f 2 53 Eddy Current Loss Pe K eVc d 2 Bm2 f 2 d: thickness of lamination Ke: constant depending on material resistivity Core loss: Pcore Ph Pe Stacking factor Fs in a laminated material Ac (effective) Fs Ac (actual) 0.95 < Fs < 1 54 Core Loss Pcore Ph Pe Core Loss is given in manufacturer’s data sheets for each specific core material as Pcore vs Bm curves in log. scale, with operating frequency as a parameter: Core loss increases with increasing frequency 55