IRJET- Modeling, Simulation and Control of a Photovoltaic Energy System with a Fuel-Cell Backup

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 06 Issue: 08 | Aug 2019 www.irjet.net p-ISSN: 2395-0072
© 2018, IRJET | Impact Factor value: 7.34 | ISO 9001:2008 Certified Journal | Page 1392
Modeling, Simulation and Control of a Photovoltaic Energy System with
a Fuel-Cell Backup
Samia Abdelfatah1, Elwy El-Kholy2, Hossam Youssef3 andHilmy Awad4
1Researcher at Electrical Technology Department, Faculty of Industrial Education, Helwan University, Cairo, Egypt
2Professor of Power Electronics, Faculty of Engineering Shebin El Kom, Menoufia University, Menoufia, Egypt
3Professor Emeritus at Electrical Technology Dept, Faculty of Industrial Education, Helwan University,
Cairo, Egypt
4Assistant Professor, Electrical Technology Dept, Faculty of Industrial Education, Helwan University, Cairo, Egypt
---------------------------------------------------------------------***----------------------------------------------------------------------
Abstract – Although the photovoltaic (PV) energy
systems provide a valuable solution to the energy crises,
their intermittent nature necessitates the existence of
backup systems for the continuous operation of the
connected loads. This paper presents a PV system with a
fuel-cell as a backup system for the continuous operation.
Normally, the connected loads are energized by the PV
within the nominal range of the irradiance. If the
irradiance falls below a threshold value, the loads will be fed
by the fuel cell. The proposed energy system contains a PV
array, fuel cells, as well as the necessary power electronics
devices and Analysis of operating conditions for each of the
solar cells and fuel cells. The simulation results the proposed
system can efficiently solve the intermittent nature of the PV
energy systems.
Key Words: Photovoltaic, Fuel cell, style, MPPT.
1. INTRODUCTION
It is well-known that electrical networks are very
necessary for human life. However, increased demand for
energy has led to global environmental concerns where
that environmental pollution has led to many
organizations and association to establish protocols and
directives in order to regulate the generation of CO2 and
other pollutants such as Kyoto Protocol and European
Directive on renewable energy sources. This fact justifies
the increased world’s interest in renewable energy (RE)
sources as they are the most environmentally-friendly
sources [1-2].
Many researchers presented different proposed solution
to enhance the quantity of electricity generated from
clean and renewable sources of energy and related
technologies are being sought, developed and
implemented worldwide. These alternative sources of
energy include wind, solar, geothermal, biofuels, tidal and
waves. The renewable energy sources have its own
drawbacks. For instance, solar panel has low efficiency
and its power output depends on climatic conditions like
insulation and temperature [3-7]. An attribute of optical
arrays where the current changes almost linearly with
solar radiation that negatively affects the performance of
a DC motor driving a centrifugal pump and also the motor
efficiency degradation was noticed under weak solar
insulation [8-9].
The hybrid power systems exhibit higher reliability of
generation than those that use individual system. So,
hybrid system is the most desired solution in Renewable
Energy system [10-11]. A hybrid PV/wind system
(HPWS) is presented in [12-13] where, the wind energy
has a disadvantage of that the wind isn’t always blowing.
This can cause serious problems for wind turbine
developers who will often spend significant time, money
check whether or not a special site is suitable and the
generation of wind power that it is not a continuous
energy source. The Fuel cells have some advantages
compared to conventional power sources and other
renewable energy sources. It has higher efficiency, noise
free operation (since there are no moving parts). It has
also pollution free completely since water is the result
instead of CO2 emission from the fuel cell. In addition to
that it has lesser maintenance and the fuel cell is
economical to operate because it does not need any fossil
fuel [14].
The proposed hybrid PV-FC generation system employs
to operate the solar panel at its maximum power point,
perturb and observe (P&O) algorithm. The proposed
controllers extract the required load power either from
the PV or the FC. In case of high irradiance, the normally
and the connected loads are energized by the PV within
the nominal range of the irradiance. When the insulation
level decreases (shading) such that PV power is not
enough to feed the load; there should be a switch in order
to alternate between the PV and FC.
2. Description and Modeling of PV-FC Hybrid
System.
A. Design of the System
The proposed hybrid system shown in Figure 1 relies
mainly on PV power. In case of normal insulation levels,
the PV panels feed the load via AC/DC boost converter
employing the (P&O) algorithm for maximum power point
tracking. The load here is represented by 3-phase
induction motor where their speed is controlled by the V/F

control method. When the insulation level decreases such
that PV power is not enough to feed the load, the fuel cell is
operated to compensate the load via AC/DC Converter.
There should be a switch in order to alternate between the
PV and FC as shown in Figure 1.
Fig – 1: PV - FC hybrid system.
B. Photo voltaic System
A solar cell is modeled by a current source and a
parallel diode, shunt resistance RSh and series resistance RS
are added to the model as shown in Figure 2. RS whose
value is very small, Rsh is whose value is very high [15-19].
Where,
I is the solar cell current in Amp.
IL is the light generated current in Amp.
ID is the diode saturation current in Amp.
T is the array temperature in °K.
Fig – 2: Model for a solar cell.
Where
ID = IO [exp (q (V + I RS)/KT)) – 1]
C. 0
D. Maximum Power Point Tracking (MPPT)
There are different techniques available in literature for
tracking maximum power from PV panels examples are
the (P&O) methods, the Incremental Conductance (IC)
methods, the Neural Network method and the Fuzzy Logic
method, [20-21]. Table 1 shows the characteristics of
different Maximum Power Point Tracking (MPPT)
techniques as perturb and observe (P&O) algorithm is
adopted due its simplicity [22]. The solar PV system is
connected to the inverter through a AC/DC converter. A
boost converter is used to implement MPPT algorithm.
Output voltage of the boost converter is equal to
VO = (1/ (1-D) Vs.
where
Vs is the input voltage and D is the duty ratio.
Perturb and Observe (P&O) MPPT technique is shown in
Figure 3. Voltage Vcell and current Icell_are measured from
solar array to calculate power (Po). Block dv/dt compares
the present value of power with previous value. If
increment in power is positive then perturbation variable
voltage is incremented by predefined step size. Output
voltage of solar panel is compared with this varied voltage
value and steady state error obtained is eliminated by PI
controller. To avoid over saturation, a limiter should be
placed at the output of PI controller which is compared
with carrier wave to generate pulse for controlled switch
IGBT of AC/DC boost converter [23].
Table -1: Characteristics of different MPPT techniques
[23].

Fig – 3: Flowchart of P&O MPPT Technique.
E. Proton Exchange Membrane Fuel Cells (PEM
FC)
A Proton Exchange Membrane (PEM) fuel cell consists of a
polymer electrolyte membrane sandwiched between two
electrodes (anode and cathode). In the electrolyte, only
ions allowed passing through and the electrons are not
allowed [24-25]. So, the flow of electrons an external
circuit from anode to cathode to produce electricity due to
the potential difference between the anode and cathode.
The theory of the basic operation of the PEM fuel cell is
fully explained in Figure 4. However; the overall
electrochemical reactions for a PEM fuel cell is presented
as follows:
Anode:
Cathode:
Overall:
The characteristics of PEMFC are given as shown clearly in
Table 2.
Fig – 4: Operation of a PEM fuel cell.
Table -2: Characteristics of the PEMFC
Fuel Cell
Type
Operating
Temperature
Typical
Stack
Size
Application Efficiency
Polymer
Electroly
te
Membra
ne Fuel
Cell
Model
60-100°C
Typically
80°C
<1KW-
100KW
Backup
power,
portable
Power.
Distributed
Generation.
Transportati
on Specialty
Vehicles.
60%
Transport
ation
In this paper A MATLAB-Simulink Generic Model of PEM
fuel cell stack is analyzed. By analysis of this model it is
found that it is a concise model of PEM fuel cell. In this
model a PEM fuel cell is broadly analyzed by keeping
under consideration almost all the parameters which
affect the performance of PEM fuel cell such as Flow rate,
utilization of fuel and air, Partial pressure of fuel and air,
Humidity and Temperature of stack and also stack
consumption of air and fuel [26-27]. Further, the
operation of PEM Fuel cell stack is performed under two
conditions of absolute and Nominal values of fuel and air
utilization.
4. RESULTS AND DISCUSSIONS
Induction motor, 3-phase squirrel-cage rated, 6 HP, 220 V,
60 Hz, and 1725 rpm is fed by a 3-phase MOSFET inverter
connected to a DC voltage source of 325 V through hybrid
PV-Fuel cell. The applied load torque to the machine's
shaft is hold at constant nominal value, of 12 N.m. Speed
control of the motor by using the Constant V/Hz. At the
start of the operation, the load is fed through the solar
cells in the form of current. If it starts to draw a high
current until it reaches the nominal current, the load is
stabilized at work until the value of the solar radiation
decreases. A change in the voltage value occurs and
therefore a change in the voltage-frequency ratio occurs.
Separate solar cells and run fuel cells, as the solar
radiation shown clearly in Figure 5. DC voltage source
(hybrid PV-Fuel cell) shown in Figure 6, however,
Ia_Stator (A) is shown in Figure 7. The simulation should
start in steady-state and the initial motor speed should be
at 1720 RPM which is clearly shown in Figure 8 where the
rms value of the stator voltages should be at 220V as
shown in Figure 9 however, the frequency of 60Hz is
shown in Figure 10.

Fig – 5: Solar irradiance.
Fig – 6: DC voltage source (hybrid PV-Fuel cell).
Fig – 7: Ia _ Stator (A).
At 0.6 second, it is shown that the speed is changed from
1725 to 1300 RPM. When the motor reaches a constant
speed of 1275 RPM, the stator voltage (rms) value is
decreased to 165.8V and the frequency to 45.2 Hz. At 1.8
seconds the voltage decreases and the current is also due
to the decrease of solar radiation and shadows, which
causes the instability of the ratio between voltage and
frequency and thus changes the value of the speed than
the required value. And at 2.3 second Solar cells are
separated and fuel cells are turned on to feed the load.
Fig – 8: Speed of induction motor (RPM).
Fig – 9: Stator voltages (rms).
Fig – 10: Frequency (HZ).
Renewable energy (RE) sources are attracting more
attention as alternative energy sources to conventional
fossil fuel energy sources in spite of its own disadvantages.
Solar panel has low efficiency and its power output
depends on geographical and meteorological conditions
such as insulation and temperature. The solar cells may
not meet the energy demanding however, the hybrid
system of PV with a fuel-cell meet this demands. The fuel-
cell system is mainly exploited as a backup and extracts
the maximum power from each hybrid power system
component, Photovoltaic (PV) generator and Fuel Cell (FC)
source. The results show the effectiveness of the system.
6. CONCLUSION

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BIOGRAPHIES
Samia Abdalfatah was born in Sharkia
Governorate, Egypt, in 1985. She
received the B.Sc. in Industrial
Education from Helwan University in
2007 and M.Sc. in Industrial Education
from Suez University Egypt, in 2015.
She is currently working as an Assistant
lecturer in the Faculty of Industrial
Education, Department of Electrical
Technology, Helwan University.
Elwy E. El-Kholy was born in Menoufia,
Egypt, in 1963. He is a Professor of
power electronics, Faculty of
Engineering Shebin El Kom , Menoufia
University, Menoufia, Egypt He received
the B.Sc., M.Sc., and Ph.D. degrees in
electrical engineering from Menoufia
University, Shebin El-Kom, Egypt, in
1986, 1992, and 1996, respectively., He
is the Dean Faculty of Engineering,
Menoufia University.
Hossam Youssef, was born in El
Fayoum, Egypt in 1959. He obtained
his Ph.D. from Polytechnic Institute
(Leningrad) USSR – 1990. He is
currently working as an Associate
Professor at Department of Electrical
Technology, Faculty of Industrial
Education, Helwan university. He is
the head of Electrical Technology
Department. He worked as an
Associate Professor of Electronic
Department (College of Electronic &
Communications, Jeddah, KSA
between 2003 and 2013. He gained a
Post Doctor Scholarship in Queen's
university of UK (2001-2002).
Hilmy Awad received the B.Sc. degree
in electrical power and machines from
Zagazig University, Zagazig, Egypt, in
1993 and the M.Sc. in electrical
engineering from Eindhoven
University of Technology, Eindhoven,
The Netherlands, in 1999. He obtained
his Ph.D. degree at the Department of
Electric Power Engineering, Chalmers
University of Technology, Gothenburg,
Sweden on 2004. He is currently
working as an assistant professor at
the faculty of Industrial Education,
Cairo, Egypt. His research interests
include power electronics
applications, renewable energy
systems, and power quality problems.

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