Performance analysis of various parameters by comparison of conventional pitch angle controller with fuzzy logic controller

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 03 Issue: 03 | Mar-2014, Available @ http://www.ijret.org 177
PERFORMANCE ANALYSIS OF VARIOUS PARAMETERS BY
COMPARISON OF CONVENTIONAL PITCH ANGLE CONTROLLER
WITH FUZZY LOGIC CONTROLLER
Jay Verma1
, Yogesh Tiwari2
, Anup Mishra3
, Pawan Tapre4
1
Assistant professor, Electrical Department, SSIET, C.G, India
2
Associate Professor, Electrical Department, SSCET, C.G, India
3
Professor, Electrical Department, BIT, C.G, India
4
Associate Professor, Electrical Department, SSCET, C.G, India
Abstract
This paper deals with a variable speed wind turbine coupled with a permanent magnet synchronous generator connected through a
two mass drive train. This drive train is connected to synchronous generator and after the conversion process finally connected to
grid and the idea of transmission over a long distance makes the use of converter necessary and at the receiving end. The inverter is
used to convert it back and the inverter is designed with a proper gate signal to get the best output three phase voltages. The fuzzy
logic controller is used to track generator speed with varying wind speed to optimize turbine aerodynamic efficiency in the outer
speed loop. Pitch angle control of wind turbine has been used widely to reduce torque and output power variation in high rated wind
speed areas .The machine side converter is designed to extract maximum power from the wind. In this work a WECS connected with
grid is designed in Matlab and a Fuzzy controller is designed to improve the output and we can see the major difference in DC link
voltage and reactive power in transmission line. From the outputs we can also go through the reactive power issue which system is
best for inductive load or capacitive load. The simple PI system is good for capacitive load and the fuzzy system is better option for
the inductive load. The results of both the system of normal controller and fuzzy controller is compared and analyzed.
Key Words: Fuzzy logic controller (FLC), permanent magnet synchronous generator (PMSG), insulated gate bipolar
transistor (IGBT) , Pulse width modulation (PWM), Wind energy conversion system, DC link capacitor. FACTS Flexible
A.C Transmission system, PI proportional integral
-----------------------------------------------------------------------***-----------------------------------------------------------------------
1. INTRODUCTION
Now days the use of electricity is the basic needs of any firm it
may be for industrial purpose or for simple household the first
and foremost requirement of all is the electric energy for 24 x
7.
To fulfill this requirement all the nations rather it is developed
country or developing country trying to provide it is as well as
possible. In this race of production of electric energy the coal
and fuel based plants are the best options since their efficiency
is well good as compared to other generating systems. But as
we all know the fossil fuels are non renewable so we have to
take care of that portion also and the main thing is the adverse
effects of these generating stations .As so much harmful gases
are exhausted in environment which will effect environment
and also become a reason of increased global warming.
To overcome all these effects a step has been taken of
producing electric energy by using non renewable energy
resources such as solar power and wind power. In these
systems the electric energy generated is clean and pollution
free. The installation of wind turbines in power systems has
developed rapidly in the last 20 years and the national and
international growth rates and policies indicate that this
development will continue. During 1999, 3920MWof wind
turbine capacity was installed in the world, making up a total
accumulated installation of 13 932 MW of wind power at the
end of 1999 [2].
For the installation of wind energy MNRE scheme (The
Ministry of New & Renewable energy) has introduced to
aware more and more people about this technology,
government also gives incentives in order to promote wind
energy. Wind is air in motion; this is actually derived from
solar energy. About 2% of total solar flux that reaches the
earth’s surface is transformed into wind energy due to uneven
heating of atmosphere. This kinetic energy of wind is used to
gain the rotational motion of wind turbine which is coupled
with an electrical generator to supply over a region acting as
stand alone or supplying power to a grid. An actual WECS

__________________________________________________________________________________________
(Wind energy conversion system) be considered as follow [3]
which can be used in two different ways
(A) Isolated stand alone system
(B) Grid connected system
In wind energy application variable speed wind turbines are
much better performance due to its maximum power point
tracking algorithm (MPPT) .Now a days Doubly fed Induction
generator are widely used in a variable speed wind turbine but
te main drawback is the requirement of gear box to match
turbine and rotor speed. The gearbox many times suffers and
requires regular maintenance making the system unreliable
[3]. The reliability of variable speed wind turbine can be
improved significantly using a direct drive based permanent
magnet synchronous generator (PMSG).
For obtaining maximum output a control strategy has been
developed and the generator side switch mode rectifier has
been controlled to achieve maximum power from the wind.
This method requires one switching device (IGBT) which is
used to control generator torque to extract maximum power.
1.1 Wind Turbine Characteristics
Wind turbine modeling: In our proposed work a variable speed
wind turbine is connected to a two mass drive train and the
output of this drive train is connected to a permanent magnet
synchronous generator and then a measurement block is added
and the three phase is converted to DC by using simple
universal bridge so that we can supply it over a long distance
as losses will be less in DC supply and a DC link capacitor is
connected so as to maintain a constant DC link voltage over
the transmission line it should remain constant over the line
since it is necessary for conversion it again in ac voltage by
the use of inverter. In this inverter we use IGBT type six pulse
so that switching will be very fast and a suitable control
system is designed so that maximum torque can be extracted.
The output is then given to a variable load and again it is
passed through an LC filter and the output of filter is then
applied to the grid which is controllable voltage source in our
work. All the design is done in matlab.
Fig-1: Overall Wind Energy Conversion System
This block implements a variable pitch wind turbine model.
The performance coefficient Cp of the turbine is the
mechanical output power of the turbine divided by wind
power and a function of wind speed, rotational speed, and
pitch angle (beta). Cp reaches its maximum value at zero beta.
According to the Aerodynamics, the aerodynamic power of
the wind turbine can be expressed as
………… (1)
When the rotor speed is adjusted to maintain its optimal value,
the maximum power can be gained as
…………… (2)
Where is decided by
……… (3)
The mechanical rotor power generated by the turbine as a
function of the rotor speed for different wind speed is shown
in Fig. 2
Fig-2: Characteristics of Input power versus speed
1.2 Two Mass Drive Train
Here WECS is represented with the two-mass drive train
model. The differential equations governing its mechanical
dynamics are presented as follows [4]
Fig-3 Two mass drive train model

__________________________________________________________________________________________
Where is the inertia constant of the turbine, is the
inertia Constant of the PMSG, is the shaft twist angle, wt
is the Angular speed of the wind turbine in p.u., is the rotor
speed of the PMSG in p.u., is the electrical base speed,
and the Shaft torque is
Where is the shaft stiffness and is the damping
coefficient
2. CONTROL OF PROPOSED SYSTEM
In this proposed wind energy system the output ac voltage is
controlled through amplitude and frequency. Power from
PMSG based wind turbine is fed to ac-dc-ac converters to
maintain the output voltage at desired amplitude and
frequency. The reactive power and an active power exchange
with the grid are function of phase and amplitude of terminal
voltage at AC terminals of a GSC. The objective of controlling
a GSC is to keep constant DC link voltage under change in
generated active power while keeping sinusoidal currents of
PMSG as shown in figure 4.
Fig-4: Subsystem of control system of inverter
Due to unbalanced load connected to an inverter the currents
will not same in all the phases and hence LC filters will cause
unequal voltage drops. Hence it is necessary to compensate
voltage imbalance .To achieve this goal the rms value of phase
voltages and the reference phase voltage is given to a PI
controller. The output of PI controller is multiplied with a unit
sine wave generator to get the reference phase voltages. By
using these reference voltages PWM pulses are generated to
switch the load side inverter. The schematic of this control
arrangement is shown in below figure 5. [6]
Fig-5: Gate pulse generation of inverter
3. FUZZY CONTROL SYSTEM
A fuzzy logic controller may consist of three basic blocks,
namely, Fuzzification, Inference system and Defuzification [7]
Fig-5: Fuzzy control arrangement
3.1 Fuzzification
Fuzzification is the procedures to process the input variables
with membership functions and determine the degree to which
the input variables are belong to each of the appropriate fuzzy
sets via membership functions. Membership functions (MF)
are used to convert each value of input variables into a
membership value between 0 and 1. Membership functions
may take any Arbitrary shape or form, such as Gaussian
distribution curves, Sigmoid curves, bell shape curves,
triangular functions or tables . The selection of membership
functions is very important as it means a kind of controller
tuning. Once the membership function shape has been chosen,
the values they are centered about and the width of the
functions have to be set. Overlapping of membership functions
is required as it means that more than one rule is fired at any
time, which is a key feature of fuzzy systems.

__________________________________________________________________________________________
Triangular membership function are used as they are easier to
implement and quicker to process. In the proposed fuzzy
system, seven fuzzy sets have been considered for each input:
negative very big (NVB), negative big (NB), negative medium
(NM), negative small (NS) zero (ZE), positive small (PS),
positive medium (PM) and positive big (PB), positive very big
(PVB). Before fuzzification, the input variables are
normalized using base values.
3.2 Fuzzy Inference System
The fuzzy inference includes the process of fuzzy logic
operation, fizzy rule implication and aggregation. In the fuzzy
inference system, the fuzzified input variables are processed
with fuzzy operators and the IF-THEN rule implementation.
The output fuzzy sets for each rule are then aggregated into a
single output fuzzy set. Aggregation is the process by which
the fuzzy sets that represent the outputs of each rule are
combined into a single fuzzy set. The input of the aggregation
process is the list of output fuzzy sets and the output of the
aggregation process is one fuzzy set for each output variable.
3.3 Defuzzification
The input for the defuzzification process is a fuzzy set (the
aggregate output fuzzy set) and the output is a single value.
The centroid method is used for defuzzification; it returns the
centre of the area under the curve representing the aggregated
output fuzzy set.
Fig-6: Membership function
Fig-7: Membership function
Fig-8: Output membership function
Fig-9: Rule view of the next fuzzy control system
Fig-10 surface view of the next fuzzy control system
4. OVERALL DESIGN OF PROPOSED WIND
ENERGY CONVERSION SYSTEM
Fig-11: Proposed wind energy conversion system in Matlab
Table-1: Parameters of turbine generator system
Wind Turbine Parameters Values
Density of air 1.225 Kg/m3
Area swept by blades , A 1.06m2
Base wind speed 12 m/s

__________________________________________________________________________________________
Table-2: Permanent magnet synchronous generator
PMSG Values
No of poles 10
Rated speed 153 rad/s
Rated current 12 amp
Armature resistance 0.425Ὡ
Magnetic flux linkage 0.433 wb
Stator inductance 4 mH
Rated torque 40 Nm
5. RESULTS
Fig-12: Voltage and current waveform at grid
Fig-13: DC link voltage
Fig-14: (a) phase voltage (b) line current (c) rms phase
voltage (d) rms line current (e) active power (f) rotor speed
Fig-15: Rms value of active and reactive power
5.1 Fuzzy Control System Output
Fig-16: output voltage and current
Fig-17: DC link voltage
Fig-18: (a) phase voltage (b) line current (c) rms phase
voltage (d) rms line current (e) active power (f) rotor speed

__________________________________________________________________________________________
Fig-19: Rms value of active and reactive power
6. CONCLUSIONS
After modeling of WECS has been done the outputs has been
recorded and shown in the figures above and we can see that
we are much closer to the desired output and the main aim is
to maintain a DC link voltage constant is also been done with
the help of inverter control system and so that the inverter can
convert this voltage into three phase voltage.
In the next stage of our work we have developed a control
system based on fuzzy system of Mamdani type. In this
control system we use different parameters as input like
generated power and compare it with reference power and the
actual wind speed and reference wind speed is proceeded in
this fuzzy control system and the rules are designed on the
basis of if – then rules which is shown in above figure. After
developing rules and implementing it to the model we can run
this model and analyze the results.
We conclude that the DC link voltages are more constant from
the fuzzy control system and active and reactive power rms
values are also much better shape so that the reactive power
compensation is not very big issue in the fuzzy based control
system.
The active and reactive power waveforms shows that inn
simple pitch control system the reactive power is slightly
lower as compared to fuzzy logic controller .We can say that
the use of systems depends upon the type of load .The pitch
control arrangement using PI controller is much better for
capacitive load as well as our next system by the use of fuzzy
controller is well good for inductive load since we don’t need
the reactive power generation .As in many system several
FACTS devices are used for the generation or compensation
of reactive power.
ACKNOWLEDGEMENTS
The authors are grateful to Shri I .P .Mishra, President, Shri
Shankaracharya group of institution SSGI Dr Deepak Sharma,
Director ,Shri shankaracharya institute of engineering and
technology SSIET, for their valuable support in our research
work.
REFERENCES
[1]. Staffan Jacobsson IMIT and Department of Industrial
Dynamics, Chalmers University of Technology, Gothenburg,
Sweden Anna Bergek IMIT and Department of Management
and Economics, Linköping University, Linköping, Sweden
―International wind energy development—World market
update 1999,‖ BTM Consults Aps., Ringkobing, Denmark,
2000.
[2]. Suman Nath, Somnath Rana The Modeling and
Simulation of Wind Energy Based Power System using
MATLAB. International journal of power system Operation
and Energy Management, ISSN (PRINT): 2231-4407, Volume
-1, Issue-2, 2011.
[3]. H.Polinder, F .F .A. van der pijl, G.J. de Vilder, and P.J.
Tavner, ―Comparison of Direct Drive and geared generator
concepts for wind turbines,‖IEEE Trans.Energy Convers.,
vol.21, no3, pp.725- 733,sep 2006.
[4]. Kenneth.E.Okedu ― Effects of drive train model
parameters on a variable speed wind turbine.‖ International
journal of renewable energy research , vol 2 , no 2 ,2012.
[5]. Jay Verma, Yogesh Tiwari, Anup Mishra, Nirbhay Singh
International Journal of Recent Technology and Engineering
(IJRTE) ISSN: 2277-3878, Volume-2, Issue-6, January 2014
33 Published By: Blue Eyes Intelligence Engineering &
Sciences Publication Pvt. Ltd. Performance, Analysis and
Simulation of Wind Energy Conversion System Connected
With Grid.
[6]. C. N. Bhende, S. Mishra, Senior Member, IEEE, and Siva
Ganesh Malla ―Permanent Magnet Synchronous Generator-
Based Standalone Wind Energy Supply System ―IEEE
TRANSACTIONS ON SUSTAINABLE ENERGY, VOL. 2,
NO. 4, OCTOBER 2011
[7]. Ms. Epsita Pal, Mr. Yogesh Tiwari, Dr. Anup Mishra
Variable Speed Wind Power Generation System Based on
Fuzzy Logic Control for Maximum Output Power Tracking
International Journal of Engineering Research & Technology
(IJERT) Vol. 3 Issue 1, January – 2014 ISSN: 2278-0181
BIOGRAPHIES
Jay Verma currently pursuing Master of
engineering in power system engineering from
SSCET.Research interest are in power system
and renewable sources of energy. At present
working as a Assistant professor in shri
shankaracharya institute of engineering and
technology, Durg.
Yogesh Tiwari is currently working as an
Asso. Prof. in EEE Department of SSCET
Bhilai. He has over 4 year industrial & 10
year teaching experience. He has published
near 15 research papers in national &
international conferences & journals.

__________________________________________________________________________________________
Dr. Anup mishra received his Ph.D degree in
2010 from BUIT, Bhopal , teaching and
research experience of more than 13 years. He
has published more than 10 Research papers
in reputed International Journals &
Conferences .At present, he is working as
professor and H.O.D. in Electrical and Electronics Department
of BIT, (Durg)
Pawan Tapre is currently working as senior
associate professor in EEE department of
SSCET. He has teaching experience of 9 years
and 4 years industrial experience. He has
published more than 10 research papers in
reputed international journals and
conferences.

Performance analysis of various parameters by comparison of conventional pitch angle controller with fuzzy logic controller

More Related Content

What's hot (20)

Viewers also liked (20)

Similar to Performance analysis of various parameters by comparison of conventional pitch angle controller with fuzzy logic controller (20)

More from eSAT Publishing House (20)

Recently uploaded (20)

Performance analysis of various parameters by comparison of conventional pitch angle controller with fuzzy logic controller