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Revue des Energies Renouvelables SMEE’10 Bou Ismail Tipaza (2010) 347 – 358
347
Analysis and vector control of a cascaded doubly fed
induction generator in wind energy applications
Zoheir Tir
1*
, Hammoud Rajeai
1
and Rachid Abdessemed
2†
1
LAS, Research Laboratory, Department of Electrical Engineering, University of Setif, Algeria
2
LEB, Research Laboratory, Department of Electrical Engineering, University of Batna, Algeria
Abstract - This paper presents recent studies of the dynamic and steady state performance of the
cascaded doubly-fed induction generator for wind energy applications. The modeling
methodology based on dynamical equivalent circuits is given in this paper for the design of the
CDFIG controller, the CDFIG can be an attractive alternative to conventional double output
wound rotor induction generators. The system employs two cascaded induction machines to
eliminate the brushes and copper rings in the traditional DFIG. In this case, Cascaded induction
generators require lower maintenance. In CDFIG both stators of connected machines are
accessible. The control strategy for flexible power flow control is developed. The independent
control of the active and reactive power flows is achieved by means of a tow quadrant power
converter under the closed-loop stator flux oriented control scheme. The Matlab simulation
software is used for a preliminary investigation of CDFIG.
Keywords: Cascaded doubly fed Induction Generators - Variable speed generator, Vector control
- Closed loop speed Control - Active-power and reactive power adjust, Power flow diagrams -
Simulation.
1. INTRODUCTION
The expression doubly fed applies generally to machines where electrical power can
be fed or extracted from two accessible three-phase windings, [11]. Recent research [2-
8] has revealed that the brushless doubly-fed induction generator (CDFIG) or its
functionally identical twin, the CDFIG, is a possible alternative to the conventional
inverter-fed induction machine drive, especially in minimizing the overall drive cost for
limited speed range applications. Recently the doubly fed induction generators (DFIG)
became the popular configuration in variable speed wind energy applications [1]. The
development and use of the DFIG machines was dictated by the need for wide
operational range as well as the necessity to allow flexible power flow control, grid
integration as well as economic reasons [2-8]. The use of the DFIG machines, however,
increased the long term cost and complexity of the wind energy generation. The
disadvantage associated with the wound-rotor induction machines is that the slip rings
and carbon brushes have to be systematically maintained [6, 3]. Typical faults of slip
rings and brushes are: the increased surface roughness of the rings or the brush contact
face, break out of carbon material from the brushes and decreasing contact pressing
forces which lead to increased brush sparking and significant performance deterioration
[6]. Since wind turbines are installed in remote places, the maintenance costs for such
remote installations are significant, [6, 9]. The cost of maintenance for traditional DFIG
based wind generators increased the pressure to seek other alternative generator systems
*
zoheir_tir@yahoo.fr ; hradjeai@yahoo.fr
†
r.abdessemed@lycos.com
Z. Tir et al.
348
[3]. One of such alternatives is offered by the CDFIG as shown in Fig. 1. In this
configuration, the rotor energy is transferred by using a second fractional induction
machine (control machine), which is directly coupled to the main generator (power
machine) through the back-to-back connection of rotor circuit (or both cage) [3, 4]. A
number of studies have been conducted on the performance modeling of the CDFIG.
The results have been presented in simulation results only.
Fig. 1: CDFIG configuration for wind power generation
The objective of this research is to present a new brushless technique for the indirect
vector control of a CDFIG. This method is suitable for grid-connected variable speed
BDFIGs. This paper presents the analysis and the simulated results using Matlab /
SimPowerSystem / Simulink for control of the grid connected operation, where the
power flow is controlled into the grid.
2. ANALYSIS OF THE CDFIG
The CDFIG is based on two DFIMs, mechanically and electrically coupled, as it is
shown in Fig. 1. The two machines are inverse coupling sequences [12], and a rigorous
analysis (using ideal models of DFIMs). This is the aim of Section II, and it allows one
to describe the power flow through the two machines in order to evaluate qualitatively
the generator efficiency. Then, it will also be possible to discuss on complementary
constraints related to the CDFIG design for an integration of the two machines into a
single frame [12].
Thereafter, modeling (Section III) is oriented by these preliminary results, more
particularly concerning coupling sequence between rotor windings. A model of a
realistic generator is established using a graphical representation of the system, adapted
to the end-user point of view: an electrical scheme. The representation proposed in this
paper (dynamical-equivalent circuit representation) is not limited to the classical case of
sinusoidal steady-state operation but it can be applied to a transient description of the
system. Then, this model is used for the design of the CDFIG controller will be detailed
in Section IV [12].
If the DFIM is conserved, rotor windings must be supplied by another three-phase ac
machine: Another DFIM is introduced, as shown in Fig. 3. It is shown that these two
DFIMs can be directly connected and finally integrated, giving us a complete brushless
solution called cascaded DFIM-CDFIM (more precisely, in this paper, generator-
CDFIG). Notice that the global structure of the generator based on a single DFIG can be
conserved with the CDFIG: The stator windings of the DFIM N°1 are connected to a
SMEE’2010: Analysis and vector control of a cascaded doubly fed induction…
349
voltage source inverter, and this inverter is supplied by a Pulse Width Modulated
(PWM) rectifier connected to a grid [12].
Moreover, in this paper, machine design is not treated, and this part of the problem
introduces supplementary constraints. If a compact solution is required as for wind
energy equipment, a single-frame CDFIG (SF-CDFIG) can be designed, introducing
additional constraints for the numbers of pole pairs in order to avoid direct magnetic
coupling between stator windings of the two machines, as shown in Fig. 2, with
2N
p
=
and
1N
c
= , [11].
Fig. 2: Example of SF-CDFIG or BDFIG [11]
The study presented in the following section is focused on the CDFIG. Indeed, it is
necessary to analyze the behavior of this structure with inverse coupling sequence.
This paper is based on a simplified model of the DFIM where copper/iron losses and
magnetic leakages are neglected as shown in Fig. 3. Thus, a DFIM is characterized by
the following:
Ω
+ω=ω p
rs
(1)
sr
PSP ×−= (2)
mrs
PPP =+ (3)
s
ps
s
r
N
SorS
ω
Ω
−
ω
=
ω
ω
∆ (4)
Fig. 3: DFIM in supersynchronous motor/generator convention
Z. Tir et al.
350
Fig. 4: CDFIG power flow convention
According to Fig. 4, neglecting losses, the mechanical power
mc
P and
mp
P , the
rotor power
rc
P and
rp
P
for either machine, as well as the grid power
g
P
, may be
expressed as functions of machine
c
M and
p
M
stator power
c
P and
p
P
and the rotor
power
rc
P and
rp
P and the supply stator voltage frequencies
c
ω
,
2
ω
(
gp
ω
=
ω
) and
the rotor frequency
r
ω
.
c
rc
c
S
ω
ω
=
,
p
rp
p
S
ω
ω
= ,
c
p
S
ω
ω
∆ (5)
(
)
pmcpc
NN ω−Ω×+=ω
,
pp
f2 ×π=ω
(6)
mpprp
N
Ω
×
−ω=ω ,
pmcrc
N
ω
−
Ω
×
=
ω
(7)
()
p
p
pccmc
N
PPS1P
ω
Ω
−=−= (8)
()
p
p
pppmp
N
PPS1P
ω
Ω
−=−=
(9)
c
rc
cccrc
PPSP
ω
ω
−=−=
(10)
p
rp
ppprp
PPSP
ω
ω
−=−= (11)
pcg
PPP +=
(12)
The rotor power has the same value for both machines, but with opposite polarity, so
that
rrprc
PPP =−=
. Thus, from {Eq. (10)} and {Eq. (11)}, the stator power to the
machines may be expressed as a function of the frequencies
c
ω
and
p
ω
.
p
c
pc
PP
ω
ω
−= (13)
SMEE’2010: Analysis and vector control of a cascaded doubly fed induction…
351
From {Eq. (12)} and {Eq. (13)}, the stator power of power machine may be
expressed as a function of the grid power
g
P
and the supply frequencies
p
ω
.
pc
c
gc
PP
ω−ω
ω
= (14)
pc
p
gp
PP
ω−ω
ω
−= (15)
From {Eq. (10)} and {Eq. (14)}, the stator power for control machine, may be
expressed as a function of the grid power
g
P
and the frequencies
c
ω
.
pc
rc
gmc
PP
ω−ω
ω−ω
−= (16)
pc
pr
gmp
PP
ω−ω
ω
−
ω
−= (17)
(
)
mpmcg
PPP
+
−=
(18)
Power flow diagrams of the CDFIG are shown in Figs. 5a- and 5b-, respectively.
Fig. 5: Power flow diagrams: a- typical for ‘supersynchronous’ speeds
b- typical for ‘hypersynchronous’ speeds
Fig. 6 shows an illustration of the transfers of powers of the CDFIG with variation
speed.
For drawing the steady state per phase circuit the slips of two machines should be
defined:
p
mpp
p
P
S
ω
ω
−ω
=
,
c
mcc
c
P
S
ω
ω−ω
=
(19)
Z. Tir et al.
352
Fig. 6:
m
P ,
mp
P ,
cmp
PandP as functions of speed
m
Ω
The steady state CDFIG per-phase equivalent circuit is shown in Fig. 7. Because the
two considered machines are assumed identical the sum of rotor resistances and the sum
of rotor leakage inductances are modeled in the rotor circuit.
Fig. 7: Steady state per-phase equivalent circuit of the
CDFIG in voltage controlled mod,
[13, 14]
The CDFIG steady-state performance equations on a per-phase basis are as follows:
⎥
⎥
⎥
⎦
⎤
⎢
⎢
⎢
⎣
⎡
×
⎥
⎥
⎥
⎥
⎥
⎦
⎤
⎢
⎢
⎢
⎢
⎢
⎣
⎡
ω+ω−
ω−ω+ω
ωω+
=
⎥
⎥
⎥
⎦
⎤
⎢
⎢
⎢
⎣
⎡
sc
r
sp
scpsmcp
mcprp
p
s
mpp
mppspps
sc
sp
I
I
I
LjRLsj0
LjLj
S
R
Lj
0LjLjR
V
0
V
(20)
Fig. 8 shows the frequencies of the cascade according to speed.
Fig. 8: Frequencies for the 2/2 pole pair CDFIG
Fig. 9 shows the tensions
c
V may vary proportionally to machine
p
M
Mp supplied
frequency
c
f , in order to maintain a constant
cc
fV ratio.
SMEE’2010: Analysis and vector control of a cascaded doubly fed induction…
353
Fig. 9: Tensions
p
V and
c
V versus speed in the CDFIG [13-15]
3. DYNAMICAL MODEL OF THE CASCADED
DOUBLY FED INDUCTION GENERATOR
The behavior of each individual machine (PM and CM) is described by the
following:
(
)
(
)
(
)
()
()
()
⎩
⎨
⎧
ω++ω++=
ω++ω++=
sprmprprrprprp
rppmpsppspspsp
ijSLijSLRv
ijSLijSLRv
(21)
(
)()
(
)
()()()
⎩
⎨
⎧
ω++ω++=
ω++ω++=
scrmcrcrrcrcrc
rccmcsccscscsc
ijSLijSLRv
ijSLijSLRv
(22)
{Eq. (21)} and {Eq. (22)} refer to the power and control machines, respectively.
Due to the pole pair difference between the two stators, there exists such relations
between the electrical speeds of the rotor and stators for the 50 Hz system, which are
given in
502
p
π=ω (23)
pmpr
P
ω
−ω=ω
(24)
(
)
cpmpc
PP +ω−ω=ω
(25)
The behavior of the CDFIG can be described in (4) by the combination of {Eq. (21)}
and {Eq. (22)} and noting that
rcrp
ii −=
and
rcrp
υ=υ
due to the back-to back
connection of rotors.
(
)
(
)
(
)
()()()
()()()
()
()
()
rprmprprrprp
rprmcrcrrcrc
rccmcsccscscsc
rppmpsppspspsp
ijSLijSLR
ijSLijSLR
ijSLijSLRv
ijSLijSLRv
ω++ω+++
ω++ω++=θ
ω++ω++=
ω
+
+
ω
+
+
=
(26)
It is assumed that the stator has two sinusoidally distributed windings with number
of poles (
cp
PP =
).
There are three initial reference frames (shown in Fig. 10):
Z. Tir et al.
354
a- PW reference
p
s
d ,
p
s
q related to a
p
P
pole-pair-type distribution, which is used
as the overall reference frame.
b- CW reference
c
s
d ,
c
s
q related to a
c
P pole-pair-type distribution and located at a
mechanical angular position of
c
θ
radians from
p
s
d ,
p
s
q .
c- Rotor references
p
r
d ,
p
r
q and
c
r
d ,
c
r
q related, respectively, to a
p
P
and
c
P pole-
pair-type distributions which are located at a mechanical angular position of
r
θ
C from
p
s
d ,
p
s
q .
Fig. 10: Three-phase. CDFIG model in d-q reference frame, [13, 14]
In a standard practice, the dynamic equation in {Eq. (26)} is usually represented in
the selected d-q reference frame. With the assumption of a stiff grid connection, the
synchronous reference frame is selected. The stator frame rotates at the speed
e
ω
which
is shown in Fig. 2. Moreover, Fig. 10 also shows the angle relationship of power
machine stator, power and control machine rotors and control machine stator to the
selected reference frame. The complete CDFIG dynamic model in d-q reference frame
can be given in:
c
q
sc
d
sc
d
scsc
d
sc
c
d
sc
q
sc
q
scsc
q
sc
r
q
r
d
r
d
rr
d
r
r
d
r
q
r
q
rr
q
r
p
q
sp
d
sp
d
spsp
d
sp
p
d
sp
q
sp
q
spsp
q
sp
td
d
iR
td
d
iR
td
d
iR
td
d
iR
td
d
iR
td
d
iR
ωΨ−
Ψ
+=υ
ωΨ+
Ψ
+=υ
ωΨ−
Ψ
+=θ
ωΨ+
Ψ
+=θ
ωΨ−
Ψ
+=υ
ωΨ+
Ψ
+=υ
(27)
SMEE’2010: Analysis and vector control of a cascaded doubly fed induction…
355
Flux linkages are defined by:
d
rmc
d
scsc
d
sc
q
rmc
q
scsc
q
sc
q
scmc
d
rr
d
spmp
d
r
q
scmc
q
rr
q
spmp
q
r
d
rmp
d
spsp
q
sp
q
rmp
q
spsp
q
sp
iLiL
iLiL
iLiLiL
iLiLiL
iLiL
iLiL
+=Ψ
+=Ψ
−+=Ψ
−+=Ψ
+=Ψ
+=Ψ
(28)
The total electric
e
T for BDFIG is the sum of both machines:
(
)
(
)()
q
sc
d
sc
d
sc
q
scp
q
sp
d
sp
d
sp
q
sppe
iiPiiP
2
3
T Ψ−Ψ+Ψ−Ψ−= (29)
The electric torque equation is defined by the friction and total inertia of the power
and control machines:
(
)
(
)
td
d
JJFFTT
m
cpm
c
F
p
F
Le
ω
+−ω+−=
(30)
The complete CDFIG system defined by {Eq. (27)} – {Eq. (30)} presents an
accurate dynamic model of the generator the model can precisely describe the machine
dynamic behavior under stiff grid connection.
4. CDFIG CONTROLLER DESIGN
The situation becomes more demanding when a wind turbine is required to produce
constant voltage and constant frequency power in a weak grid or non-grid connected,
stand alone situation. Special control strategies have to be devised to attain such
objectives. Vector control, introduced by Blaschke in 1972, [10].
The developed control strategy is based on a loops control as shown in Fig. 11. Two
regulation paths are implemented as in the classical vector control schemes: one control
path regulates the d magnetizing currents and the other one is dedicated to control the q
active currents. In order to obtain a good decoupled control, the PW flux orientation has
been selected (
sp
d
sp
Ψ=Ψ and 0
q
sp
=Ψ ). The obtained control strategy for the
BDFM is similar to the well-known stator field orientation control used in the DFIM.
[11, 13, 14].
5. SIMULATION RESULTS
The CDFIG is first placed in ideal conditions and is driven to 735 rpm. We impose
an active power step of – 4 kW at t = 3 s and we observe the response obtained with the
PI controller. Also we impose a reactive power step of 2 kW at t = 2 s and we observe
the response obtained with the PI controller.
Results are presented on figures 12, 13, 14 and 15.
We can notice that the response times are equivalent (about 35 ms). The effect of the
active power step on the reactive power shows that the cross-coupling terms. The
impact of the active power change on reactive power and on the contrary in the DFTSIG
is demonstrated in Fig. 8, where they can be seen that there only exists a transient
Z. Tir et al.
356
disturbance in the reactive et active component (at times 2 an 3 s) while the steady state
operation are unaffected. Fig. 9 shows the Power machine stator current.
Fig. 11: CDFIG Controller Structure
Fig. 12: Reactive and active power decoupling
Fig. 13: Power stator current
SMEE’2010: Analysis and vector control of a cascaded doubly fed induction…
357
Fig. 14: Rotor current
Fig. 15: Control stator current
6. CONCLUSIONS
Owing to its great reliability, CDFIM is an interesting solution for wind energy
applications. It has been also shown in this paper that using an appropriate modeling
approach based on dynamical equivalent circuit representation; a theoretical and
simulation study of the CDFIG dynamic performance in closed loop control of the
generator active and reactive powers has been presented. The control system is based on
the field orientation principle and the orientation of the power machine stator flux with
two PI controllers placed in the power stator field coordinates, where a back-to-back
voltage source converter was employed. Moreover, the proposed modeling approach
allows the study of power flow. The proposed configuration can be easily implemented
with fractional control machine and further with common squirrel cage rotor and dual
stator windings.
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