控制电缆烧损事故之分析改善与预防对策PPT课件

1、1,Chapter 4 Modeling of Nonlinear Load,Organized by Task Force on Harmonics Modeling & Simulation Adapted and Presented by Paulo F Ribeiro AMSC May 28-29, 2008,Contributors: S. Tsai, Y. Liu, and G. W. Chang,2,Chapter outline,Introduction Nonlinear magnetic core sources Arc furnace 3-phase line commu

2、ted converters Static var compensator Cycloconverter,3,Introduction,The purpose of harmonic studies is to quantify the distortion in voltage and/or current waveforms at various locations in a power system. One important step in harmonic studies is to characterize and to model harmonic-generating sou

3、rces. Causes of power system harmonics Nonlinear voltage-current characteristics Non-sinusoidal winding distribution Periodic or aperiodic switching devices Combinations of above,4,Introduction (cont.),In the following, we will present the harmonics for each devices in the following sequence: Harmon

4、ic characteristics Harmonic models and assumptions Discussion of each model,5,Chapter outline,Introduction Nonlinear magnetic core sources Arc furnace 3-phase line commuted converters Static var compensator Cycloconverter,6,Nonlinear Magnetic Core Sources,Harmonics characteristics Harmonics model fo

5、r transformers Harmonics model for rotating machines,7,Harmonics characteristics of iron-core reactors and transformers,Causes of harmonics generation Saturation effects Over-excitation temporary over-voltage caused by reactive power unbalance unbalanced transformer load asymmetric saturation caused

6、 by low frequency magnetizing current transformer energization Symmetric core saturation generates odd harmonics Asymmetric core saturation generates both odd and even harmonics The overall amount of harmonics generated depends on the saturation level of the magnetic core the structure and configura

7、tion of the transformer,8,Harmonic models for transformers,Harmonic models for a transformer: equivalent circuit model differential equation model duality-based model GIC (geomagnetically induced currents) saturation model,9,Equivalent circuit model (transformer),In time domain, a single phase trans

8、former can be represented by an equivalent circuit referring all impedances to one side of the transformer The core saturation is modeled using a piecewise linear approximation of saturation This model is increasingly available in time domain circuit simulation packages.,10,Differential equation mod

9、el (transformer),The differential equations describe the relationships between winding voltages winding currents winding resistance winding turns magneto-motive forces mutual fluxes leakage fluxes reluctances Saturation, hysteresis, and eddy current effects can be well modeled. The models are suitab

10、le for transient studies. They may also be used to simulate the harmonic generation behavior of power transformers.,11,Duality-based model (transformer),Duality-based models are necessary to represent multi-legged transformers Its parameters may be derived from experiment data and a nonlinear induct

11、ance may be used to model the core saturation Duality-based models are suitable for simulation of power system low-frequency transients. They can also be used to study the harmonic generation behaviors,12,GIC saturation model (transformer),Geomagnetically induced currents GIC bias can cause heavy ha

12、lf cycle saturation the flux paths in and between core, tank and air gaps should be accounted A detailed model based on 3D finite element calculation may be necessary. Simplified equivalent magnetic circuit model of a single-phase shell-type transformer is shown. An iterative program can be used to

13、solve the circuitry so that nonlinearity of the circuitry components is considered.,13,Rotating machines,Harmonic models for synchronous machine Harmonic models for Induction machine,14,Synchronous machines,Harmonics origins: Non-sinusoidal flux distribution The resulting voltage harmonics are odd a

14、nd usually minimized in the machines design stage and can be negligible. Frequency conversion process Caused under unbalanced conditions Saturation Saturation occurs in the stator and rotor core, and in the stator and rotor teeth. In large generator, this can be neglected. Harmonic models under bala

15、nced condition, a single-phase inductance is sufficient under unbalanced conditions, a impedance matrix is necessary,15,Balanced harmonic analysis,For balanced (single phase) harmonic analysis, a synchronous machine was often represented by a single approximation of inductance h: harmonic order : di

16、rect sub-transient inductance : quadrature sub-transient inductance A more complex model a: 0.5-1.5 (accounting for skin effect and eddy current losses) Rneg and Xneg are the negative sequence resistance and reactance at fundamental frequency,16,Unbalanced harmonic analysis,The balanced three-phase

17、coupled matrix model can be used for unbalanced network analysis Zs=(Zo+2Zneg)/3 Zm=(ZoZneg)/3 Zo and Zneg are zero and negative sequence impedance at hth harmonic order If the synchronous machine stator is not precisely balanced, the self and/or mutual impedance will be unequal.,17,Induction motors

18、,Harmonics can be generated from Non-sinusoidal stator winding distribution Can be minimized during the design stage Transients Harmonics are induced during cold-start or load changing The above-mentioned phenomenon can generally be neglected The primary contribution of induction motors is to act as

19、 impedances to harmonic excitation The motor can be modeled as impedance for balanced systems, or a three-phase coupled matrix for unbalanced systems,18,Harmonic models for induction motor,Balanced Condition Generalized Double Cage Model Equivalent T Model Unbalanced Condition,19,Generalized Double

20、Cage Model for Induction Motor,Stator,Excitation branch,At the h-th harmonic order, the equivalent circuit can be obtained by multiplying h with each of the reactance.,mutual reactance of the 2 rotor cages,2 rotor cages,20,Equivalent T model for Induction Motor,s is the full load slip at fundamental

21、 frequency, and h is the harmonic order - is taken for positive sequence models + is taken for negative sequence models.,21,Unbalanced model for Induction Motor,The balanced three-phase coupled matrix model can be used for unbalanced network analysis Zs=(Zo+2Zpos)/3 Zm=(ZoZpos)/3 Zo and Zpos are zer

22、o and positive sequence impedance at hth harmonic order Z0 can be determined from,22,Chapter outline,Introduction Nonlinear magnetic core sources Arc furnace 3-phase line commuted converters Static var compensator Cycloconverter,23,Arc furnace harmonic sources,Types: AC furnace DC furnace DC arc fur

23、nace are mostly determined by its AC/DC converter and the characteristic is more predictable, here we only focus on AC arc furnaces,24,Characteristics of Harmonics Generated by Arc Furnaces,The nature of the steel melting process is uncontrollable, current harmonics generated by arc furnaces are unp

24、redictable and random. Current chopping and igniting in each half cycle of the supply voltage, arc furnaces generate a wide range of harmonic frequencies,25,Harmonics Models for Arc Furnace,Nonlinear resistance model Current source model Voltage source model Nonlinear time varying voltage source mod

25、el Nonlinear time varying resistance models Frequency domain models Power balance model,26,Nonlinear resistance model,simplified to,R1 is a positive resistor R2 is a negative resistor AC clamper is a current-controlled switch It is a primitive model and does not consider the time-varying characteris

26、tic of arc furnaces.,modeled as,27,Current source model,Typically, an EAF is modeled as a current source for harmonic studies. The source current can be represented by its Fourier series an and bn can be selected as a function of measurement probability distributions proportion of the reactive power

27、 fluctuations to the active power fluctuations. This model can be used to size filter components and evaluate the voltage distortions resulting from the harmonic current injected into the system.,28,Voltage source model,The voltage source model for arc furnaces is a Thevenin equivalent circuit. The

28、equivalent impedance is the furnace load impedance (including the electrodes) The voltage source is modeled in different ways: form it by major harmonic components that are known empirically account for stochastic characteristics of the arc furnace and model the voltage source as square waves with m

29、odulated amplitude. A new value for the voltage amplitude is generated after every zero-crossings of the arc current when the arc reignites,29,Nonlinear time varying voltage source model,This model is actually a voltage source model The arc voltage is defined as a function of the arc length Vao :arc

30、 voltage corresponding to the reference arc length lo, k(t): arc length time variations The time variation of the arc length is modeled with deterministic or stochastic laws. Deterministic: Stochastic:,30,Nonlinear time varying resistance models,During normal operation, the arc resistance can be mod

31、eled to follow an approximate Gaussian distribution is the variance which is determined by short-term perceptibility flicker index Pst Another time varying resistance model: R1: arc furnace positive resistance and R2 negative resistance P: short-term power consumed by the arc furnace Vig and Vex are

32、 arc ignition and extinction voltages,31,Power balance model,r is the arc radius exponent n is selected according to the arc cooling environment, n=0, 1, or 2 recommended values for exponent m are 0, 1 and 2 K1, K2 and K3 are constants,32,Chapter outline,Introduction Nonlinear magnetic core sources

33、Arc furnace 3-phase line commuted converters Static var compensator Cycloconverter,33,Three-phase line commuted converters,Line-commutated converter is mostly usual operated as a six-pulse converter or configured in parallel arrangements for high-pulse operations Typical applications of converters c

34、an be found in AC motor drive, DC motor drive and HVDC link,34,Harmonics Characteristics,Under balanced condition with constant output current and assuming zero firing angle and no commutation overlap, phase a current is h = 1, 5, 7, 11, 13, . Characteristic harmonics generated by converters of any

35、pulse number are in the order of n = 1, 2, and p is the pulse number of the converter For non-zero firing angle and non-zero commutation overlap, rms value of each characteristic harmonic current can be determined by F(,) is an overlap function,35,Harmonic Models for the Three-Phase Line-Commutated

36、Converter,Harmonic models can be categorized as frequency-domain based models current source model transfer function model Norton-equivalent circuit model harmonic-domain model three-pulse model time-domain based models models by differential equations state-space model,36,Current source model,The m

37、ost commonly used model for converter is to treat it as known sources of harmonic currents with or without phase angle information Magnitudes of current harmonics injected into a bus are determined from the typical measured spectrum and rated load current for the harmonic source (Irated) Harmonic ph

38、ase angles need to be included when multiple sources are considered simultaneously for taking the harmonic cancellation effect into account. h, and a conventional load flow solution is needed for providing the fundamental frequency phase angle, 1,37,Transfer Function Model,The simplified schematic c

39、ircuit can be used to describe the transfer function model of a converter G: the ideal transfer function without considering firing angle variation and commutation overlap G,dc and G,ac, relate the dc and ac sides of the converter Transfer functions can include the deviation terms of the firing angl

40、e and commutation overlap The effects of converter input voltage distortion or unbalance and harmonic contents in the output dc current can be modeled as well,38,Norton-Equivalent Circuit Model,The nonlinear relationship between converter input currents and its terminal voltages is I & V are harmoni

41、c vectors If the harmonic contents are small, one may linearize the dynamic relations about the base operating point and obtain: I = YJV + IN YJ is the Norton admittance matrix representing the linearization. It also represents an approximation of the converter response to variations in its terminal

42、 voltage harmonics or unbalance IN = Ib - YJVb (Norton equivalent),39,Harmonic-Domain Model,Under normal operation, the overall state of the converter is specified by the angles of the state transition These angles are the switching instants corresponding to the 6 firing angles and the 6 ends of com

43、mutation angles The converter response to an applied terminal voltage is characterized via convolutions in the harmonic domain The overall dc voltage Vk,p: 12 voltage samples p: square pulse sampling functions H: the highest harmonic order under consideration The converter input currents are obtaine

44、d in the same manner using the same sampling functions.,40,Chapter outline,Introduction Nonlinear magnetic core sources Arc furnace 3-phase line commuted converters Static var compensator Cycloconverter,41,Harmonics characteristics of TCR,Harmonic currents are generated for any conduction intervals

45、within the two firing angles With the ideal supply voltage, the generated rms harmonic currents h = 3, 5, 7, , is the conduction angle, and LR is the inductance of the reactor,42,Harmonics characteristics of TCR (cont.),Three single-phase TCRs are usually in delta connection, the triplen currents ci

46、rculate within the delta circuit and do not enter the power system that supplies the TCRs. When the single-phase TCR is supplied by a non-sinusoidal input voltage the current through the compensator is proved to be the discontinuous current,43,Harmonic models for TCR,Harmonic models for TCR can be categorized as frequency-domain based models current source model transfer function model Norton-equivalent circuit model time-domain based models models by differential equations state-space model,44,Current Source Model,by discrete Fourier