dynamic modelling of doubly-fed induction machine wind generators
TRANSCRIPT
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Technical Documentat ion
Dynamic Modelling of Doubly-Fed
Induction Machine Wind-Generators
G m b H
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D y n a m i c M o d e l l i n g o f D o u b l y - F e d I n d u c t i o n M a c h i n e W i n d - G e n e r a t o r s 1
DIgSILENT GmbHHeinrich-Hertz-Strasse 9D-72810 GomaringenTel.: +49 7072 9168 – 0Fax: +49 7072 9168- 88http://www.digsilent.de-mail: [email protected]
Dynamic Modelling ofDoubly-Fed InductionMachine Wind-Generators
Published byDIgSILENT GmbH, Germany
Copyright 2003. All rightsreserved. Unauthorised copyingor publishing of this or any partof this document is prohibited.
doc.TechRef, 14 August 2003
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1 I n t r o d u c t i o n
D y n a m i c M o d e l l i n g o f D o u b l y - F e d I n d u c t i o n M a c h i n e W i n d - G e n e r a t o r s 2
1 Introduction
The electrical systems of several European countries contain large amounts of embedded wind generation and similar scenarios
are foreseen in other parts of the world. This aspect, together with the significant size of new wind farm projects, requires
realistic modelling capabilities of wind generators for proper assessment of power system planning and impact analysis of future
wind generation.
As a result of research and consulting activities of DIgSILENT, generic dynamic models of different types of wind power
generation were developed. These models are now available in the standard Wind-Power library of PowerFactory .
This document describes a doubly-fed induction generator wind turbine model including all relevant components. At the same
time, this document is a reference to all DFIG-related models of the Wind-Power library.
The presented models are mainly intended for stability analysis of large power systems. The proper response of the models to
network faults was in the centre of interest, but the models can also be used for simulating the impact of wind fluctuations to
power systems.
There is no wind model included in this description. However, any type of stochastic or deterministic wind model, or measured
wind speeds can be connected to the wind speed input of the presented model.
The models are intended for balanced and unbalanced RMS calculations typically applied in stability studies. However, it is also
possible to perform electromagnetic transient simulations with these models.
The basic structure of the model is briefly described in this section and more thoroughly analyzed in the following sections.
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2 The Doubly-Fed Induction Machine Concept
DFIG
External Grid
Prime
Mover
Grid Side
Converter
Rotor Side
Converter
Protection
Control Control
Figure 1: Doubly-Fed Induction Generator Concept
The general concept of a Doubly-Fed Induction Generator (DFIG) is shown in Figure 1.
The prime mover, consisting of a pitch-angle controlled wind turbine, the shaft and the gear-box drives a slip-ring induction
generator. The stator of the DFIG is directly connected to the grid, the slip-rings of the rotor are fed by self-commutated
converters. These converters allow controlling the rotor voltage in magnitude and phase angle and can therefore be used for
active- and reactive power control.
In the presented model, the converters and controllers are represented to the necessary extent. Both the rotor- and the grid-
side controllers are modelled in full detail, including fast current control loops. However, for many applications the fast control
loops of the grid side converter can be approximated by steady state models.
With the rotor side converter, the situation is different due to protective practices in DFIG. For protecting the rotor-side
converter against over-currents, it is usual practice to bypass the rotor-side converter during system faults. Whether the DFIG is
totally disconnected from the system or not, depends on the actual deepness of the voltage sag and on the applied protectionphilosophy. The correct modelling of the rotor bypass, usually called “crow bar protection”, is essential to assess voltage
stability of large farms during faults in the transmission- or distribution network. For this reason, it is necessary to model even
the fast current controls of the rotor side converter to effectively determine the operation of the crow bar. Other protection
functions also found in DFIG such as over/under-speed and over/under-voltage are considered in the proposed model as wel
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3 The DFIG Wind-Generator Model
3.1 Overview
Prime Mover
(To Protection System)
(From Protection System)
omega..
pt
Pwind
beta
u
bypass
P;Q
c o s p h . .
Ifq_ref;Ifd_ref
Pref
iq;id
Pfq;Pfd
psis_..
speed
Pmq ; Pmd
Irot
I f q ; I . .
Shaft*
Pitch Control*
Transformatio..*
Current Measurement*
V meas.StaVmea*
ProtectionElmPro*
Turbine*
vw
MPTElmMpt*
PQ ControlElmGen*
Qref
Current Control*
DFIGElmAsm*
Power MeasurementStaPqmea
DFIG: D I g S I L E N T
Figure 2: Complete Scheme of the Doubly-Fed Induction Machine Wind Generator
The complete scheme of a doubly-fed induction machine wind generator is shown in Figure 2. The main components are:
• The prime mover consisting of the pitch angle controller, the wind turbine and the shaft (Pitch-Control, Turbine,
Shaft)
• Doubly-Fed induction generator (DFIG)
• The control-system regulating active and reactive power of the DFIG through the rotor-side converter applying a
maximum power tracking strategy (MPT, Power Measurement, PQ Control, Current Control, Current Measurement)
• Protection-system (V meas., Protection)
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The models of all major components are described in the following sections. It is important to point out that these models can
be used in combinations that differ from Figure 2, e.g. realizing power-dependent speed control instead of the speed-dependent
power control.
Additionally, the model can be extended by stochastic or deterministic wind-speed models, more sophisticated voltage and
frequency control.
3.2 Prime Mover and Controller
The prime mover of a wind generator model represents the conversion of kinetic energy stored in the air flowing through the
blades into rotational energy at the generator shaft.
The prime-mover model is subdivided into three sub-models, which are
• The turbine that transforms the wind energy into rotational energy at the turbine shaft.
• Blade angle controller.
• Shaft coupling turbine and generator including the gear-box.
3.2.1 Wind Turbine
In this section all aspects related to the power conversion from kinetic wind energy to rotational energy that are of relevance
for the stability model are explained.
The kinetic energy of a mass of air m having the speed vw is given by:
2
2 wk v
m E ⋅= (1)
The power associated to this moving air mass is the derivative of the kinetic energy with respect to time.
22
02
1
2
1ww
k vqvt
m
t
E P ⋅⋅=⋅
∂
∂⋅=
∂
∂= (2)
where q represents the mass flow given by the expression:
Avq w ⋅⋅= ρ (3)
ρ is the air density and A the cross section of the air mass flow.
Only a fraction of the total kinetic power can be extracted by a wind turbine and converted into rotational power at the shaft.
This fraction of power (PWIND) depends on the wind speed, rotor speed and blade position (for pitch and active stall control
turbines) and on the turbine design. It is usually denominated aerodynamic efficiency Cp :
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Figure 3: Typical Cp(β , λ) Characteristic
0 P P Cp Wind = (4)
For a specific turbine design, the values of Cp are usually presented as a function of the pitch angle (β) and the tip speed ratio
(λ). The tip speed ratio is given by:
w
TUR
v
R⋅= ω
λ (5)
R is the radius of the turbine blades and ωTUR is the turbine speed.
PowerFactory allows the input of a two-dimensional lookup characteristic (for different values of β and λ) to define Cp. A two-
dimensional, cubic spline-interpolation method is used for calculating points between actually entered values. The high accuracy
of the interpolation method avoids the need of entering a large number of points (see also Figure 3).
Alternatively, analytical approaches for approximating the Cp -characteristic could be used but since these data are usually
available in tabular formats, no such model was included into the PowerFactory standard Wind-Power-Library.
Finally, the mechanical power extracted from the wind is calculated using:
( ) 32 ,2
wmech vCp R P ⋅⋅⋅⋅= β λ π ρ
(6)
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The Cp -characteristic can be calculated using special software for aerodynamic designs that is usually based on blade-iteration
techniques or it can be obtained from actual measurements.
It has to be pointed out that the presented turbine model is based on a steady state approach and is not able to represent stall
dynamics.
The input/output diagram of the turbine model is depicted in Figure 4 and the input-, output- and parameter definitions are
presented in Table 1 to
Table 3.
Figure 4: Input/Output Definition of Wind-Turbine
Table 1:Input Definition of Wind-Turbine
Input Symbol Description Unit
beta β (6) Blade pitch angle degrees
vw vw (5,6) Wind Speed m/sec
omega_tur ωTUR (5) Turbine Angular Velocity rad/sec
Table 2: Output Definition of Wind-Turbine
Output Symbol Description Unit
Pwind Pmech (6) Generated, Mechanical Power MW
Table 3: Parameter-Definition of Wind-Turbine
Output Symbol Description Unit
R R (5,6) Rotor Blade Radius m
rho ρ (6) Air Densitiy kg/m3
Cp Cp(β,λ) (6) Cp-Characteristic (2-dim. Lookup-table)
beta
Wind-Turbine
vw
omega_tur
Pwind
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3.2.2 Blade Angle Control
SERVOBLADE ANGLE CONTROLLER
speedbeta_ref beta
ref
Time ConstT-
-PI controller
Ka,Tr,Ta
Vrmin
Vrmax
{1/s}
Ymin
Ymax
Limiter
rate_cl
rate_op
Blade Angle Control: D I g S I L E N T
Figure 5: Block Diagram of Blade Angle Controller
Adjusting the blade angle allows varying the power coefficient Cp, and hence controlling the power generated by a wind turbine
(see also Figure 3).
The two common concepts are pitch-control and active-stall control. In a pitch-controlled wind turbine, the blades are turned
into the wind for reducing the lift forces at the blades which lowers the power coefficient.
Active-stall controlled wind turbines turn the blades out of the wind flow for disturbing the laminar air flow at the blades and
hence reducing the generated power.
The model presented here is generic and captures the main characteristics of pitch angle controls of existing wind generation
technologies. Controller and servomechanism are depicted in Figure 5. The controller has a feedback of the generator speed.
Its speed-reference is set to the maximum speed (usually above 20% nominal). The blade angle is at the minimum limit of the
controller for all operating conditions below rated rotor speed. This minimum limit corresponds to the optimum blade angle1.
The servomechanism model accounts for the associated time constant, rate-of-change limits and blade angle limitations.
1 Blade-Angle optimization can be realized using a variable minimum blade angle limit
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Figure 6: Input/Output Definition of Blade Angle Controller
Table 4: Input Definition of Blade Angle Controller
Input Description Unit
speed Speed Input (from Generator) p.u.
Table 5: Output Definition of Blade Angle Controller
Output Description Unit
beta Blade Angle (Pitch-Angle) deg
Table 6: Parameter Definition of Blade Angle Controller
Parameter Description Unit
Ka Blade Angle Controller Gain deg/p.u.
Ta Blade Angle Controller Time Constant s
Tr Lead Time Constant s
T Servo Time Constant s
rate_op Opening Rate of Change Limit deg/s
rate_cl Closing Rate of Change Limit deg/s
beta_max Max. Blade Angle deg
beta_min Min. Blade Angle deg
ref_speed Speed Reference p.u.
Blade Angle Controllerspeed beta
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3.2.3 Shaft
Figure 7: Spring-Mass Model of Second Order
pt
Pwind
speed_gen omega_gen
TmecTwind
tdif omega_tur -
Gear BoxRPMnom
RatePtPbase
0
1
SpringK,D_shaft
0
1
Mass_1TorqueD_turb,J
Torque
0
1
Shaft Model:
0
1
0
1
D I g S I L E N T
Figure 8: Block Diagram of Shaft
DgDt
ωgJg
Jtωt
K tg
Dtg
ω’ g
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Under normal operating conditions, variable speed generators are “decoupled” from the grid; that is, with appropriate controls,
torsional shaft oscillations are filtered by the converters and almost not noticeable as harmonics of the generated power.
However, during heavy faults, e.g. short circuits in the network, generator and turbine acceleration can only be simulated with
sufficient accuracy if shaft oscillations are included in the model.
Shaft characteristics of wind generators are quite different from other types of generation due to the relatively low st iffness of
the turbine shaft. This results in torsional resonance frequencies in a range of about 0.5 to 2 Hz.
The proposed model approximates the shaft by a two-mass model, represented by turbine- and generator inertia (see Figure
7). The model according to Figure 7 and Figure 8 represents the turbine inertia and the coupling between turbine- and
generator. The generator inertia however, is modelled inside the built-in induction machine model. The generator inertia is
specified in the form of an acceleration time constant in the induction generator type. The inertia of the gear-box is not
modelled separately but shall be included in the generator inertia.
The spring-constant K and the corresponding damping coefficient D are related to the turbine-side.
Shaft-models of higher order can easily be implemented by expanding the second order model. For stability analysis however, a
second order model provides sufficient accuracy.
Figure 9: Input/Output Definition of Shaft
Table 7: Input Definition of Shaft
Input Description Unit
Pwind Turbine Power MW
speed_gen Generator Speed p.u.
Table 8: Output Definition of Shaft
Output Description Unit
omega_tur Turbine Speed (Angular Velocity) rad/s
pt Mechanical Power at Generator Inertia p.u.
Shaft
Pwind
speed_gen
omega_tur
pt
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Table 9: Parameter Definition of Shaft
Parameter Description Unit
Pbase Rated Power of Generator MW.
D_turb Turbine Damping Nms/rad
J_shaft Turbine Inertia kgm2
K_shaft Shaft-Stiffness Nm/rad
D_shaft Torsional Damping Nms/rad
RPMnom Nominal Rotor Speed rpm
3.3
Generator Rotor-Side Converter and Controls
The electrical characteristics and hence the modelling requirements vary considerably with the different types of generators. In
this section the available models for doubly-fed induction machines are presented.
Obviously, the equipment characteristics depend on the manufacturer. The models presented here reflect typical equipment and
control structures.
This section starts with a description of the DFIG including the rotor-side converter. The grid-side converter with controls is
described in section 0, followed by a presentation of DFIG protections.
3.3.1
Asynchronous machine and Rotor Side Converter
The doubly-fed induction machine model extends the usual induction machine by a PWM converter in series to the rotor
impedance as shown in Figure 10. In this figure, Rs and Xs are the resistance and leakage reactance of the stator winding; Xm
is the magnetizing reactance and Zrot is the rotor impedance.
Rs Xs
Xm
Zrot
U Ur t j r e
ω −Ur Ur'= UDCUAC
Figure 10: Equivalent Circuit of the Doubly-Fed Induction Machine with Rotor-Side Converter
The PWM converter inserted in the rotor circuit allows for a flexible and fast control of the machine by modifying magnitude and
phase angle of the rotor voltage.
It is assumed that a standard bridge consisting of six transistors builds the converter and that sinusoidal pulse width modulation
is applied.
In contrast to the normal induction machine model, in which the rotor is short-circuited, the winding ratio between rotor and
stator is important for calculating actual DC voltages. The nominal rotor voltage that can be measured at the slip rings under
open rotor conditions defines this winding ratio.
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For load flow calculations and transients initialization, only active power (AC-side), reactive power and the slip have to be
specified. Internally, the corresponding modulation factors of the converter (Pmd, Pmq) are calculated and together with the
power balance between the AC and DC side of the converter, DC voltage and DC current are obtained.
During time domain simulations the converter is controlled through the pulse width modulation indices Pmd and Pmq which
define the ratio between DC voltage and the AC-voltage at the slip rings. The modulation indices Pmd and Pmq are defined in a
rotor-oriented reference frame.
For more details about the built-in DFIG model, please refer to the corresponding Model Description of the Technical Reference
Manual .
3.3.2 Rotor-Side Converter Controller
(To Protection System)
(From Protection System)
Irot
bypass
P;Q
phim
Ifq_ref;Ifd_ref
Pref
Ifq;Ifd
Pfq;Pfd
psis_r;psis_i
iq;id
Pmq ; Pmd
Transformatio..*
Current Measurement*
PQ ControlElmGen*
Qref
Current Control*
Figure 11: Main Components of the Rotor-Side Converter Controller (Composite Model Frame)
The basic diagram (Frame) of the rotor-side converter controllers is shown in Figure 11.
The rotor-side converter is controlled by a two stage controller. The first stage consists of very fast current controllers
regulating the machine’s rotor currents to reference values that are specified by a slower power-controller (second stage).
The rotor-side current-controller operates in a stator-flux oriented reference frame. Hence, rotor currents must first be
transformed into a stator-flux oriented reference frame (psis_r, psis_i, see Figure 11).
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3.3.2.1
Rotor-Current Controller
The block Current Measurement transforms rotor currents from the original, rotor-oriented reference frame to stator-flux
orientation. Additionally, the magnitude (in kA) of the rotor-current phasor is calculated and sent to the rotor current protectionmodel. For considering flux-measurement delays (or flux-observer delays), a delay time constant can be entered.
This transformation decomposes the rotor currents into a component that is in-phase with stator flux (d-component) and a
component that is orthogonal to stator flux (q-component). The q-component of the rotor current directly influences the torque,
why the q-axis can be used for torque- or active power control. The d-axis component is a reactive current component and can
be used for reactive power- or voltage control.
x3
Rotor-Side Converter
Current Control
x4
Pmd
Pmq
u d
u q
yi1
yi
bypass
o 1 6
Ird
Ird_ref
Irq_ref
Irqmodule limiter
Max
0
1
0
1
non-windup PIKq,Tq
MinPmq
MaxPmq
0
1
(1/(1+sT))Tr
(1/(1+sT))Tr
-
-
non-windup PIKd,Td
MinPmd
MaxPmd
0
1
Current Control:
2
1
3
4
0
0
1
D I g S I L E N T
Figure 12: Block Diagram of Rotor-Current Controller
The block-diagram depicted in Figure 12 is the implementation of the rotor-current controller. There are two independent
proportional-integral-(P-I-) controllers, one for the d-axis component, one for the q-axis component. The output of the current
controller defines the pulse-width modulation indices in stator-flux orientation.
For limiting harmonics, the magnitude of the pulse-width modulation index is limited to the parameter Max. Both P-I-controllers
are equipped with non-windup limiters.
By activating the additional input signal bypass, the pulse-width modulation indices are immediately set equal to zero, which is
equivalent to blocking and bypassing the rotor-side converter (“Crow-Bar protection”, see section 3.5).
Because the modulation index of the doubly-fed induction machine must be defined in a rotor-oriented reference frame, the
outputs of the rotor-current controller have to be transformed back from stator-flux-orientation to rotor-orientation. This
transformation is realized by the block Transformation .
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Figure 13: Input/Output Definition of Rotor-Current Measurement
Table 10: Input Definition of Rotor-Current Measurement
Input Description Unit
cosphim Cosine of rotor angle
sinphim Sine of rotor angle
id Rotor-Current (d-axis, in rotor-oriented reference frame) p.u.
iq Rotor-Current (q-axis, in rotor-oriented reference frame) p.u.
psis_r Stator Flux, real part p.u.
psis_i Stator Flux, imaginary part p.u.
Table 11: Output Definition of Rotor-Current Measurement
Output Description Unit
ifd Rotor-Current (d-axis, Stator-Flux Orientation) p.u.
ifq Rotor-Current (q-axis, Stator-Flux Orientation)
Irot Rotor-Current (Magnitude of current-phasor) kA
Table 12: Parameters of Rotor-Current Measurement
Parameter Description Unit
Tm Measurement Delay Time s
Urrated Rated Rotor Voltage kV
Srated Rated Power of DFIG MVA
Rotor-CurrentMeasurement
cosphim
sinphim
id
iq
psis_r
psis_i
ifd
ifq
Irot
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Figure 14: Input/Output Definition of Rotor- Current Controller
Table 13: Input-Definition of Rotor- Current Controller
Input Description Unit
bypass Bypass-Signal
Iq_ref q-Axis Current Reference p.u.
Ifq q-Axis Current p.u.
Id_ref d-Axis Current Reference p.u.
Id d-Axis Current p.u.
Table 14: Output-Definition of Rotor-Current Controller
Output Description Unit
Pmq q-Axis Pulse Width Modulation Index
Pmd d-Axis Pulse Width Modulation Index
Table 15: Parameter-Definition of Rotor- Current Controller
Parameter Description Unit
Tr Current Measurement Time Constant sec
Kq q-Axis Gain p.u
Tq q-Axis Time Constant sec
Kd d-Axis Gain p.u
Td d-Axis Time Constant sec
MinPmq Min. q-Axis Pulse-Width Modulation Index p.u
MinPmd Min. d-Axis Pulse-Width Modulation Index p.u
MaxPmq Max. q-Axis Pulse-Width Modulation Index p.u
MaxPmd Max. d-Axis Pulse-Width Modulation Index t p.u
Max Max. Magnitude of Pulse-Width Modulation Index p.u
Rotor-CurrentController
bypass
Ifq_ref
Ifq
Ifd_ref
Ifd
Pmq
Pmd
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Figure 15: Input/Output Definition of Rotor-dq-Transformation
Table 16: Input Definition of Rotor-dq-Transformation
Input Description Unit
cosphim Cosine of Rotor-Angle
sinphim Sine of Rotor-Angle
Pfd d-Axis Modulation Index (Stator-Flux Orienation)
Pfq q-Axis Modulation Index (Stator-Flux Orientatin)
psis_r Stator-Flux, Real Part p.u.
psis_i Stator-Flux, Imaginary Part p.u.
Table 17: Output Definition of Rotor-dq-Transformation
Output Description Unit
Pmd d-Axis Modulation Index (Rotor-Orientation)
Pmq q-Axis Modulation Index (Rotor-Orientation)
Rotor-dq-Transformation
cosphim
sinphim
Pfd
Pfq
psis_r
psis_i
Pmdd
Pmq
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3.3.2.2
Power-Controller
xQ
x2
xP
Reactive Power Control
Active Power Control
Active and Reactive Power Control
Rotor Side Converter
x1
Ifd_ref
Ifq_ref
bypas..
Q
Qref
P
Pref
module limiter
Max
0
1
0
1
non-windup PIKp,Tp
MinIfq
MaxIfq
0
1
(1/(1+sT)Ttr
-
-
non-windup PIKq,Tq
MinIfd
MaxIfd
0
1
(1/(1+sT)Ttr
PQ Control:
1
2
3
4
0
1
0
D I g S I L E N T
Figure 16: Block-Diagram of PQ-Controller
D-axis and q-axis component of the rotor current are controlled to reference values specified by active- and reactive power
controllers according to Figure 16. Similar to the rotor-current controller, the power controller regulates active- and reactive
power by independent P-I-controllers. The P-I-controllers are equipped with non-windup limiters. The output limits the
magnitude of the rotor-current reference. In contrast to the output-limiter in Figure 12, the q-axis-component (active current
component) is prioritized.
Voltage control can either be realized by connecting a voltage controller behind the reactive power reference or by replacing the
reactive power controller by a voltage controller defining the d-axis current reference.
Figure 17: Input/Output Definition of PQ-Controller
PQ-Controller
bypass
Pref
P
Qref
Q
Ifd_ref
Ifq_ref
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Table 18: Input Definition of PQ-Controller
Input Description Unitbypass Bypass-Signal
Pref Active Power Reference p.u.
P q-Axis Current p.u.
Qref d-Axis Current Reference p.u.
Q d-Axis Current p.u.
Table 19: Output-Definition of PQ-Controller
Output Description Unit
Ifq_ref q-Axis Current Reference p.u.
Ifd_ref d-Axis Current Reference p.u.
Table 20: Parameter Definition of PQ-Controller
Parameter Description Units
Ttr Measuring time constant sec
Kp Active Power Control Gain p.u
Tp Active Power Control Time Constant sec
Kq Reactive Power Control Gain p.u
Tq Reactive Power Control Time Constant sec
MinIfq Min. q-axis current reference p.u
MinIfd Min. d-axis current reference p.u
MaxIfq Max. q-axis current reference p.u
MaxIfd Max. d-axis current reference p.u
Max Max. current magnitude reference p.u
3.3.3 Maximum Power Tracking
According to the classical control strategy the active power dispatch of wind-turbines is permanently optimized. Hence, the wind
turbine operates with maximum possible active power output, depending on actual wind speed.
As shown in Figure 3 there is, for every wind speed, an optimum mechanical speed (optimum λ). Assuming that the wind
turbine always operates at this optimum point, the actual wind speed and hence the maximum possible active power can be
calculated from the mechanical speed, without the necessity of wind-speed measurements.
Calculating the table of max. power versus mechanical speed and applying the maximum power as active power reference to
the PQ-controller drives the wind turbine into the optimum point. In the PowerFactory model, the power vs. speed characteristic
(or MPT-characteristic) is defined using a linearly interpolated table.
Alternatively, many doubly-fed induction machines are operated using a slightly different control-scheme, in which active power
is measured and mechanical speed is calculated by the inverse MPT-characteristic. In this case, the calculated speed is sent as
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speed-reference to a speed-controller. Replacing the active power controller according to Figure 16 by a speed-controller and
connecting an inverse MPT table to the speed-reference point realizes this alternative control scheme.
Figure 18; Input/Output Definition of MPT-Characteristic
Table 21: Input Definition of MPT-Characteristic
Input Description Unit
speed Mechanical Speed p.u.
Table 22: Output Definition of MPT-Characteristic
Output Description Unit
Pref Active Power Reference p.u.
Table 23: Parameter Definition of MPT-Characteristic
Parameter Description Unit
array_MPT Array of Power Reference Points p.u.
speed MPT-Characteristic Pref
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3.4 Grid-Side-Converter with Controls
L 1
C 1
PWM U1
Figure 19: Grid-Side Converter
The grid-side converter consists of a 6-pulse bridge (PWM U1 in Figure 19), the AC-inductance (L1) and the DC-capacitance
(C1).
Like the rotor-side converter, the grid-side PWM converter is modelled using a fundamental frequency approach. The input
variables Pmr and Pmi, together with the DC-voltage, define magnitude and phase angle of the AC-voltage at the PWM-
converter’s AC-terminal. The pulse-width modulation indices Pmr and Pmi are referred to the so-called global reference frame ,
which is in EMT-simulations a steady state reference frame and which rotates with reference frequency (mechanical speed of
the reference machine) in case of an RMS simulation. However, the reference frame has no influence to the system’s
performance, as long as all quantities are given in the correct reference frames.
More information about the PWM-controller, the AC-inductance and the DC-capacitance can be found in the corresponding
Model Descriptions .
The basic diagram of the grid-side controller is shown in Figure 20.
The modulation indices of the Converter are imposed from a Current Control through a reference frame transformation ( ph-
transf ). The Current Control operates in an AC-voltage oriented reference frame. It contains two current control loops: direct
(active-) and quadrature (reactive-) axis current components (id and iq ). The reference of the direct axis current component
(id_ref ) is set by DC voltage control . The reference of the quadrature axis current component (id_ref ) is, kept constant (const.
reactive power) in this case.
For defining the AC-voltage oriented reference frame, a PLL (phase-locked-loop) is required measuring the voltage angle. The
PLL-output is used for transforming the current measurement into the voltage-oriented reference frame (dq- transf) and for
transforming the controller outputs (pulse-width modulation indices) back to the global reference frame ( ph-transf ).
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The grid-side controller (Figure 21) is very similar to the rotor-side current controller (Figure 12). However, since it operates in
a voltage-oriented reference frame and not in a flux-oriented reference frame the role of d- and q-axis is inverted: the d-axis
component defines active-current and the q-axis component defines reactive current.
Figure 22: Input/Output Definition of Grid-Side Current Controller
Table 24: Input Definition of Grid-Side Current Controller
Input Description Unit
Id_ref d-Axis Current Reference p.u.
Id d-Axis Current p.u.
Iq_ref q-Axis Current Reference p.u.
Iq q-Axis Current p.u.
Table 25: Output Definition of Grid-Side Current Controller
Output Description Unit
Pmd d-Axis Pulse Width Modulation Index
Pmq q-Axis Pulse Width Modulation Index
Table 26: Parameter Definition of Grid-Side Current Controller
Parameter Description Units
Kd d-axis proportional gain p.u.
Td d-axis integral time constant Sec
Kq q-axis proportional gain p.u
Tq q-axis integral time constant Sec
Tr Current measurement time constant Sec
Min_Pmd Min. d-axis modulation factor p.u.
Min_Pmq Min. q-axis modulation factor p.u.
Max_Pmd Max. d-axis modulation factor p.u.
Max_Pmq Max. q-axis modulation factor p.u.
Grid-Side CurrentController
Id_ref
Id
Iq_ref
Iq
Pmd
Pmq
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Fmeas
cosphi
sinphi
y i
om
o m_
n o m
dom
K p p h i
K i p h i
dphi
ii
rr
vi
vr
1/(2pi)
cos(x)
sin(x)
1/s
K/s_limK
dommin
dommax
KKp
PLL:
0
1
0
1
2
D I g S I L E N T
Figure 23: Block-Diagram of PLL
Figure 24: Basic-Data-Page of PLL Showing Node-Reference
The reference angle of the current controller is provided by a PLL (phase locked loop). The PLL is a PowerFactory built-in model
that refers directly to a bus-bar or terminal. The block-diagram is shown in Figure 23, however, the input voltage is not defined
by a composite model but directly by a node-reference in the input-dialogue box of the PLL, as shown in Figure 24.
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Figure 25: Input/Output Definition of PLL (Built-In Model)
Table 27: Output Definition of PLL
Output Description Unit
Fmeas Measured Frequency Hz
sinphi Sine of Voltage Angle
cosphi Cosine of Voltage Angle
Table 28: Parameter Definition of PLL
Parameter Description Unit
Kp Controller Gain
Ki Integration Gain 1/a
ommax Upper Frequency Limit p.u.
ommin Lower Frequency Limit p.u.
The input/output definition of the transformation blocks carrying out the transformation from the global reference system to the
AC-voltage oriented reference system and back are shown in Figure 26.
Figure 26: Input/Output Definition of Grid-dq-Transformation
Grid-dq-Transformation
iq
idir
ii
sinphi
cosphi
PLL
cosphi
sinphi
Fmeas
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Table 29: Input Definition of Grid-dq-Transformation
Input Description Unitir Real Part of Input Signal in Global Reference System p.u.
ii Im. Part of Input Signal in Global Reference System p.u.
sinphi Cosine of Reference Angle
cosphi Cosine of Reference Angle
Table 30: Output Definition of Grid-dq-Transformation
Output Description Unit
id d-Axis Current p.u.
iq q-Axis Current p.u.
Figure 27: Input/Output Definition of Phase-Transformation
Table 31: Input Definition of Phase-Transformation
Input Description Unit
id d-Axis Component of Input Signal p.u.
iq q-Axis Component of Input Signal p.u.
sinphi Cosine of Reference Angle
cosphi Cosine of Reference Angle
Table 32: Output Definition of Phase-Transformation
Output Description Unit
ir Real Part of Output Signal p.u.
ii Im. Part of Output Signal p.u.
Phase-Transformation
ii
irid
iq
sinphi
cosphi
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3.4.1.2
DC-Voltage Controller
xidref
id_ref udc
udc_ref
dudc{K (1+1/sT)}Kudc,Tudc
Min_idref
Max_idref
-
DC Voltage Control:
0
1
D I g S I L E N T
Figure 28: DC-Voltage Controller
The P-I-controller shown in Figure 28 controls the DC-voltage and sets the d-axis current reference. Time constant and gain of the controller must be set in accordance with the DC-capacitance (see Figure 19).
Figure 29: Input/Output Definition of DC-Voltage Controller
Table 33: Input Definition of DC-Voltage Controller
Input Description Units
udc_ref DC-Voltage, Reference Value p.u.
udc DC-Voltage sec
DC-VoltageController
id_ref
udc_ref
udc
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Table 34: Output Definition of DC-Voltage Controller
Ouput Description Units
id_ref d-Axis Current Reference p.u.
Table 35: Parameter Definition of DC-Voltage Controller
Parameter Description Units
Kudc Proportional Gain p.u.
Tudc Integral Time Constant sec
Min_idref Min. d-axis current reference p.u.
Max_idref Max. d-axis current reference p.u
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3.5 Protection
CrowBar
u
speed
Irot
bypass
TripVoltage
TripSpeed
Rotor BypassMaxIrotor, tbypass
Max
0
1
2
VoltageProtMaxVoltage1,ttripMaxV1, ..
SpeedProtMaxSpeed1,ttripMaxS1, Ma..
Protection:
0
1
2
D I g S I L E N T
Figure 30: Block Diagram of DFIG-Protection
The following protective functions are implemented in the block diagram according to Figure 30:
1. Under-/Over-Voltage
2. Under-/Over-Speed
3. Rotor-Over-Current (“Crow-Bar Protection”)
The Under/Over-Voltage unit supervises the voltage at the HV side of the transformer and has four voltage levels, two for
under-voltage and two for over-voltage. If this protective unit triggers the machine breaker is opened.
The Under/Over-speed protection unit supervises the generator speed and consists of four levels, two for under-speed and twofor over-speed. If this protective unit triggers the machine breaker is opened.
Rs Xs
Xm
Zrot
U Ur t j r e
ω −Ur Ur'=
AdditionalImpedance
Figure 31: Equivalent Circuit Diagram of DFIG During Crow-Bar Protection
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The Crow-Bar protection is specific to doubly-fed induction generators and protects the rotor-side converter against over-
currents. When the rotor current exceeds a threshold value, the converter is blocked and bypassed through an additional
impedance (see Figure 31). This additional impedance reduces the amount of reactive power absorbed by the machine and
improves the torque characteristic during voltage sags. While the Crow-Bar is inserted, the integral actions of the rotor-side
controllers are set to zero (see Figure 12 and Figure 16) for minimizing discontinuities in the rotor current when the Crow-Bar is
removed. Those discontinuities would eventually lead to subsequent operations of the Crow-Bar protection. When the Crow-Bar
is released, the rotor side converter is unblocked. For simulating cases, in which doubly-fed induction generators remain in the
system during faults, as recommended by the latest E.ON. guidelines, the operation of the Crow-Bar protection does not open
the machine breaker. For simulating synchronous operation of Crow-Bar protection and machine breaker, the model can easily
be modified.
Figure 32: Input/Output Definition of DFIG-Protection
Table 36: Input Definition of DFIG-Protection
Input Description Units
Irot Rotor Current Magnitude kA
speed Generator Speed sec
u Bus-Bar Voltage p.u
Table 37: Output Definition of DFIG-Protection
Output Description Units
bypass Bypass-Signal (for Crow-Bar Insertion)
DFIG-Protectionbypass
Irot
speed
u
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Table 38: Parameter Definition of DFIG-Protection
Parameter Description Units
MaxIrotor Rotor Current for Crow Bar Insertion kA
tbypass Crow Bar Insertion Time sec
MaxSpeed1 Overspeed Setting step 1 p.u
ttripMaxS1 Overspeed Time Setting step 1 sec
MaxSpeed2 Overspeed Setting step 2 p.u
ttripMaxS2 Overspeed Time Setting step 2 sec
MinSpeed1 Underspeed Setting step 1 p.u
ttripMinS1 Underspeed Time Setting step 1 sec
MinSpeed2 Underspeed Setting step 2 p.u
ttripMinS2 Underspeed Time Setting step 2 sec
MaxVoltage1 Overvoltage Setting step 1 p.u
ttripMaxV1 Overvoltage Time Setting step 1 sec
MaxVoltage2 Overvoltage Setting step 2 p.u
ttripMaxV2 Overvoltage Time Setting step 2 sec
MinVoltage1 Undervoltage Setting step 1 p.u
ttripMinV1 Undervoltage Time Setting step 1 sec
MinVoltage2 Undervoltage Setting step 2 p.u
ttripMinV2 Undervoltage Time Setting step 2 sec
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4 Simulation Examples
In this section the behaviour of the proposed DFIG model under different types of system faults is presented.
4.1 Three-Phase Fault Far from Wind Generation
In this case, a three phase fault cleared after 200 ms causing a voltage depression of about 25% is simulated. The results are
presented in Figure 33 to Figure 35.
4.0003.0002.0001.0000.00 ..
1.200
0.80
0.40
0.00
-0.400
-0.800
PQ Control: Total Active Power (P)
4.0003.0002.0001.0000.00 ..
1.000
0.00
-1.000
-2.000
-3.000
PQ Control: Total Reactive Power (Q)
4.0003.0002.0001.0000.00 ..
1.200
1.00
0.80
0.60
0.40
0.20
0.00
T3WT1: AC Voltage at HV side (u)
DIgSILENTDoubly-fed Induction Generator - Example Plot-1
Date: 5/26/2003
Annex: /1
D I g S I L E N T
Figure 33: Three-Phase Fault Far from Wind Generation, Connection Point
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4.0003.0002.0001.0000.00 ..
7.500
5.000
2.500
0.00
-2.500
-5.000
-7.500
G1d: Stator Reactive Power
4.0003.0002.0001.0000.00 ..
5.500
5.000
4.500
4.000
3.500
3.000
G1d: Stator Active Power
4.0003.0002.0001.0000.00 ..
0.50
0.25
0.00
-0.250
-0.500
-0.750
PWM U1: Grid Side Converter Active Power
4.0003.0002.0001.0000.00 ..
0.00
-0.100
-0.200
-0.300
-0.400
PWM U1: Grid Side Converter Reactive Power
DIgSILENTDoubly-fed Induction Generator - Example Plot-2
Date: 5/26/2003
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D I g S I L E N T
Figure 34: Three-Phase Fault Far from Wind Generation, Stator- and Grid-Side Results
4.0003.0002.0001.0000.00 ..
4.500
4.400
4.300
4.200
4.100
4.000
Prime Mover: Wind Power
4.0003.0002.0001.0000.00 ..
3.000
2.000
1.000
0.00
-1.000
Prime Mover: Blade pitch Angle
4.0003.0002.0001.0000.00 ..
1.000
0.99
0.98
0.97
0.96
0.95
0.94
G1d: Generator Speed
DIgSILENTDoubly-fed Induction Generator - Example Plot-3
Date: 5/26/2003
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D I g S I L E N T
Figure 35: Three-Phase Fault Far from Wind Generation, Mechanical Variables
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Figure 33 shows that the total active and reactive power at the connection point is quickly restored. The active power of the
stator has an oscillatory component due to torsional oscillations that is almost perfectly damped by the active power controller
of the grid-side converter (Figure 34). The speed deviations are not large enough to cause a variation of the blade angles the
pitch control.
4.2 Three Phase Fault Close to Wind Generation
In this case, a three phase fault cleared after 400 ms causing a voltage depression of about 85% is simulated assuming that the
under-voltage protection is set to avoid the disconnection from the grid under these circumstances. The results are presented
in Figure 36 to Figure 38.
In this case, it takes longer to restore total active and reactive power than in the previous case, due to the operation of the
crow bar (Figure 36). The total reactive power is almost zero during the fault and is negative during the time between clearing
the fault and removing the crow bar protection at t=0.5s. In this case, the speed deviation is larger than in the previous case
and the blade angle is increased to reduce the power extracted from the wind.
The reactive power absorbed by the generator during the time that the crow bar is inserted may have a negative impact on the
voltage stability of the system when a significant number of units are connected. The modelling of the operation of this
protective function should be particularly considered in the design of transmission systems connecting large wind farms to utility
grids.
4.0003.0002.0001.0000.00 ..
1.200
0.80
0.40
0.00
-0.400
-0.800
PQ Control: Total Active Power (P)
4.0003.0002.0001.0000.00 ..
1.000
0.00
-1.000
-2.000
-3.000
PQ Control: Total Reactive Power (Q)
4.0003.0002.0001.0000.00 ..
1.200
1.00
0.80
0.60
0.40
0.20
0.00
T3WT1: AC Voltage at HV side (u)
DIgSILENTDoubly-fed Induction Generator - Example Plot-1
Date: 5/26/2003
Annex: /1
D I g S I L E N T
Figure 36: Three-Phase Fault Close to Wind Generation, Connection Point
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4.0003.0002.0001.0000.00 ..
8.000
4.000
0.00
-4.000
-8.000
-12.00
G1d: Stator Reactive Power
4.0003.0002.0001.0000.00 ..
6.000
4.000
2.000
0.00
-2.000
-4.000
G1d: Stator Active Power
4.0003.0002.0001.0000.00 ..
1.200
0.80
0.40
0.00
-0.400
-0.800
-1.200
PWM U1: Grid Side Converter Active Power
4.0003.0002.0001.0000.00 ..
4.000
3.000
2.000
1.000
0.00
-1.000
PWM U1: Grid Side Converter Reactive Power
DIgSILENTDoubly-fed Induction Generator - Example Plot-2
Date: 5/26/2003
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D I g S I L E N T
Figure 37: Three-Phase Fault Close to Wind Generation, Stator- and Grid-Side Results
4.0003.0002.0001.0000.00 ..
4.400
4.300
4.200
4.100
4.000
3.900
Prime Mover: Wind Power
4.0003.0002.0001.0000.00 ..
0.30
0.20
0.10
0.00
-0.100
Prime Mover: Blade pitch Angle
4.0003.0002.0001.0000.00 ..
1.140
1.100
1.060
1.020
0.98
0.94
G1d: Generator Speed
DIgSILENTDoubly-fed Induction Generator - Example Plot-3
Date: 5/26/2003
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D
I g S I L E N T
Figure 38: Three-Phase Fault Close to Wind Generation, Mechanical Variables
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4 S i m u l a t i o n E x a m p l e s
D y n a m i c M o d e l l i n g o f D o u b l y - F e d I n d u c t i o n M a c h i n e W i n d - G e n e r a t o r s 3 6
4.3 Single Phase Fault Close to Wind Generation
In this case, a single phase fault cleared after 400 ms causing a total voltage depression in phase A at the HV side of the
machine transformer is simulated assuming that the under-voltage protection is set to avoid the disconnection from the grid
under this circumstances. The results are presented in Figure 39 to Figure 41.
In this case, the total active power does not decrease during the fault as in the previous case due to the fault type. However,
the increasing rotor current causes the Crow-Bar protection to trip. Consequently, the total reactive power absorption
significantly increases until the crow bar protection is removed at t=0.5s. The speed deviation is less than in the previous case
and the blade angle is kept constant.
In contrast to the previous cases, this case was simulated using an instantaneous-value representation of the AC-system (EMT-
simulation). This more accurate model uses fifth-order generator models, including stator transients and differential equations
for all network components.
1.000.750.500.25-0.00 [s]
2.00
1.00
-0.00
-1.00
PQ Control: Total Active Power (P)
1.000.750.500.25-0.00 [s]
2.00
1.00
-0.00
-1.00
-2.00
PQ Control: Total Reactive Power (Q)
1.000.750.500.25-0.00 [s]
2.00
1.00
-0.00
-1.00
-2.00
T3WT1: Phasenspannung L1/OS-Seite in p.u.
DIgSILENTDoubly-fed Induction Generator - Example Results at Connection Point
Date: 8/11/2003
Annex: 1 /1
D I g S I L E N T
Figure 39: Single-Phase Fault Close to Wind Generation, Connection Point
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8/9/2019 Dynamic Modelling of Doubly-Fed Induction Machine Wind Generators
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4 S i m u l a t i o n E x a m p l e s
D y n a m i c M o d e l l i n g o f D o u b l y - F e d I n d u c t i o n M a c h i n e W i n d - G e n e r a t o r s 3 7
1.000.750.500.25-0.00 [s]
9.00
6.00
3.00
0.00
-3.00
-6.00
G1d: Stator Reactive Power
1.000.750.500.25-0.00 [s]
7.50
5.00
2.50
0.00
-2.50
-5.00
G1d: Stator Active Power
1.000.750.500.25-0.00 [s]
3.00
2.00
1.00
0.00
-1.00
PWM U1: Grid Side Converter Active Power
1.000.750.500.25-0.00 [s]
3.00
2.00
1.00
0.00
-1.00
PWM U1: Grid Side Converter Reactive Power
DIgSILENTDoubly-fed Induction Generator - Example Active/Reactive Power
Date: 8/11/2003
Annex: 1 /2
D I g S I L E N T
Figure 40: Single Phase Fault Close to Wind Generation, Stator- and Grid-Side Results
1.000.750.500.25-0.00 [s]
4.40
4.30
4.20
4.10
4.00
3.90
Turbine: Wind Power
1.000.750.500.25-0.00 [s]
0.15
0.10
0.05
0.00
-0.05
-0.10
-0.15
Pitch Control: Blade pitch Angle
1.000.750.500.25-0.00 [s]
1.14
1.10
1.06
1.02
0.98
0.94
G1d: Generator Speed
DIgSILENTDoubly-fed Induction Generator - Example Mechanical Results
Date: 8/11/2003
Annex: 1 /3
D I g S I L E N T
Figure 41: Single-Phase Fault Close to Wind Generation, Mechanical Variables
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8/9/2019 Dynamic Modelling of Doubly-Fed Induction Machine Wind Generators
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5 C o n c l u s i o n s
5 Conclusions
The PowerFactory standard library of generic models for simulating DFIG-based wind power plants was described using a
typical DFIG-example. The models include the conversion from wind- to mechanical energy, pitch control, maximum power
tracking and controllers for the rotor-side- and grid-side converters.
The described models can easily be extended for different reactive and active power control schemes.
All block diagrams, equations and input/output definitions were presented in this document allowing to use the PowerFactory
standard library efficiently.
Simulation examples showing the dynamic response of the described models illustrate the validity and accuracy of the
presented approach