IRJET- Performance Evaluation of Micro Grid

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 06 Issue: 12 | Dec 2019 www.irjet.net p-ISSN: 2395-0072
© 2019, IRJET | Impact Factor value: 7.34 | ISO 9001:2008 Certified Journal | Page 859
PERFORMANCE EVALUATION OF MICRO GRID
Pappu Kumar1, Dr. Upendra prasad2
1PG Scholar, Department of Electrical Engineering, BIT Sindri, Dhanbad (Jharkhand), India
2Professor, Department of Electrical Engineering, BIT Sindri, Dhanbad (Jharkhand), India
---------------------------------------------------------------------***----------------------------------------------------------------------
Abstract - Micro grid is essentially a lowvoltageormedium
voltage conveyance which comprises of a bunch of micro-
sources for example, photo voltaic cluster, energy unit, wind
turbine and fuel cell. In this work, the dependability and
performance analysis of a typical micro grid, compiled with
Photovoltaic (PV) arrays and Proton Exchange Membrane
Fuel cell (PEMFC) is bestowed. The micro-grid system is
designed to operate either in an islanding/autonomous mode
to attain the load demand. The Voltage Source Converter
(VSC) Controller and Phase Locked Loop (PLL) are based on
DQ Transformation. This Transformation is applied to
effectually control the -grid voltage, current and frequency
and easy flow of power can be achieved from generation to
consumption. The voltage as well as the frequency of the
proposed micro-grid is consistent evenifthereisasuddenload
or power fluctuation. A dc-dc converter is used to connect the
PV and the PEMFC when the State of Charge (SOC) falls to its
minimal limit, the rated power can be attained by a backup
generator called PEMFC. The propounded PV-PEMFC micro-
grid is critically investigated to scrutinize its performance
improvisation by extensive simulation analysis to the dc grid.
Voltage Source Converter (VSC) helps to maintain the output
voltage and outputcurrentby enforcingtheimplementationof
Maximum Power Point Tracking (MPPT) techniques by P & O
algorithm. The system’s improvement in power quality can be
demonstrated with the help of results presented. A relative
analysis is carried out to study the proposed system with
Voltage source converter (VSC) controller. Using this
technique the total harmonic distortion (THD) at the Load
common coupling point is improved.
Key Words: PV Array, PEMFC, MPPT, Voltage Source
converter, Phase Locked Loop.
1. INTRODUCTION
Micro grid is a platform for supply –sidestorageanddemand
resources located in a local distribution grid. As energy age
and circulation organizations contend in the commercial
center, we have seen an expanding enthusiasm for
sustainable and elective energy sources. Not with standing
this opposition, organizations are looking for requests from
clients for higher quality and cleaner power. Additionally
considering the universes coal stocks are diminishing and
the making of enactment which is pushing for greener
energy arrangements. A Micro grid should be capable of
handling both normal state and emergency state operation.
PV modules are considered as the main source of alternate
power generation because of various factors like no
incurring of fuel cost, emission less power generation, long
life, less maintenance cost and ease of availability [1]. An
optimal configuration of PV arrays with an efficient
Maximum Power Point Technique (MPPT) coupled with
power electronic converter results in the extraction of
maximal power from PV modules. The implementation of
Perturb & Observe (P&O) algorithm in this work is because
of its simplicity and ease of execution [2]. As a Major energy
alternative, fuel cells can be used in DC micro grid and have
the following benefits like continuous availability, no
emission, better efficiency, less servicing cost and are well
matched for DG applications. Most widely used fuel cells in
the market are Proton Exchange Membrane Fuel Cell
(PEMFC).
The output of PV is normally dependsupontheatmospheric
conditions and cell temperature and also it is not available
during night. So it is an uncontrollable source. To overcome
the irrepressible nature of this source, a PEMFC backup
generator is used in the integrating. Fuel cell output power
can regulate the output power of a Micro grid system even
though Fuel cell works only at higher efficiency within a
specific range. The different combination of DG systems and
their operations in various modes are discussed in detail in
literature [4, 5]. The voltage source converter (VSC) is
controlled by typical regulators like phase locked loop
controller. The conventional techniques requires exact
scientific model of the systems and are very receptive to
alterations in parameters [6].
The classical techniques failed to define the response of the
system during immediate load variations and the
performance of power electronic system. In this paper
discussed along with methods for improvement of various
power quality issues such as harmonics produced by
nonlinear loads using power quality methods.. Micro grids
can cause some issues regarding Power quality, stability.
Also, there is a necessity to maintain a sophisticated control
over these networks to ensure protection and reliability.
Power Quality can be maintaining a near sinusoidal rated
voltage at rated frequency. The power quality of any system
can be quantified by means of power quality indices. In this
paper the most important power quality index Total
Harmonic Distortion is taken into consideration.

UG
FUELCELL
PGSYATEM
PVARRAY
PGSYSTEM
DC-DCCONVERTER
DC-DCCONVERTER
DC/ACCONVERTER
PCC
TR CB
ELECTRICAL
LOADS
Fig 1.1: Block diagram of M-G
2.1 PV MODULE
A photovoltaic system basically uses one or more solar
modules or panels in series or parallel connection according
to the desire of the user to convert solar energy to electrical
energy. The components required for a solar PV array are
solar panel, electrical connections and mostly MPPT
algorithms are used to find the maximum power point of the
produced solar power and the photovoltaic cell is the
building unit of a photovoltaic array.Thesecellsaremadeup
from semiconductor devices such as germanium, silicon etc.
These semiconductor devices are used as very thin wafers
who work on the principle of potential difference due to the
presence of holes and electrons. Due to the potential
difference across the wafer, voltage is produced. Electrons
attain energy when subjected to solar radiation and are free
to move around. If we connect an electrical circuit with the
wafer, we can harness electricity from the wafers. The
electricity is produced due to the movement of electrons
causing the flow of current .and for lowvoltagegenerationin
a PV cell (around 0.5V), several PV cells are connected in
series (for high voltage) and in parallel (for high current) to
form a PV module for desired output. In case of partial or
total shading, and at night there may be requirement of
separate diodes to avoid reverse currents The p-n junctions
of mono-crystalline silicon cells may have adequate reverse
current characteristics and these are not necessary. Thereis
wastage of power because of reverse currents which directs
to overheating of shaded cells. At higher temperatures solar
cells provide less efficiency and installers aim to offer good
ventilation behind solar panel. Usually there are of 36 or 72
cells in general PV modules. The modules consist of
transparent front side, encapsulated PV cell and back side.
The efficiency of a PV module is less than a PV cell. This is
because of some radiation is reflected by the glass coverand
frame shadowing. In any PV system a single PV cell is not
enough for generation of energy. The voltagerequiredismet
by series connection of these cells and parallel connection is
made as per current requirement based on panel ratings. In
this paper the data for the solar power plant is considered
from the 50KW grid connected solar power plant.
+ _
_
n p
+
_ +
_ +
_
+
_ +
_ +
Photon ≥ Eg
Fig 2.1: Representation of semiconductor
Table-1: Parameters of PV array
2.2 MAXIMUM POWER POINT TRACKING
The efficiency of a solar cell is very low and also when solar
cells are connected together to form a panel then its
efficiency is still not increased [8]. In order to increase the
efficiency (𝜂) of solar cell or solar panel we have to use
maximum power transfer theorem. The maximum power
transfer theorem says that the maximum power is transfer
when the output resistance of source matches with the load
resistance i.e. solar cell or solar panel impedance. So all
MPPT principles are based on maximum power transfer
theorem that always trying to matching the impedance of
load to source. There are so many methods proposed to find
that maximum point [2]. In this paper P&O method is
implemented. In this paper MPPT required to maintain 810
V DC voltages as constant. The effectivenessofMPPTisgiven
by following equation.
0
0
(t) dt
(t) dt
t
measured
MPPT t
actual
P
P
 



START
Read V(k) and I(k)
from panel and
Calculate
p(k)=V(k)*I(k)
Delay p(k) and V(k)
by (K-1) Instant
p(K-1), V(K-1)
p= p(k)- p(k-1)
V= V(k)-V(k-1)
P>0
V<0V<0
D=D- D D=D+ DD=D+ D D=D- D
RETURN
YES NO
YES NO YES NO
Fig 2.2.1: Flow chart of perturb and Observe Algorithm
Fig 2.2.2: Variation of I-V curve with solar radiation
Fig 2.2.3: Variation of P-V curve with solar radiation
3. FUEL CELL
A fuel cell is an electrochemical device thatproduceselectric
power in the form of direct current by converting chemical
energy present in the fuel (hydrogen). . Preferablyhydrogen
is used as a fuel and oxygen is used as an oxidant for Fuel
Cells. Although air can be used instead of oxygen but there is
decrease in the Fuel Cell efficiency for this kind of
arrangement. There are many types of Fuel cell line PEMFC,
MCFC, AFC, SOFC. But only PEMFCcanbeoperatedatnormal
air temperature. PEMFC is lightweight so it can be easily
transported, used for distribution power generation. There
are a number of fuel cells that can be chosen accordingtothe
power rating. 1kW FC has the output voltage range of about
25-50 V and 30 kW and above Fuel cells have output voltage
of about ( 200-400V).
Fig 3.1: Construction of fuel cell
Table -2: chemical reactions in different types of fuel cells
4. VSC CONTROLLER
The VSC controls have been extensively studied in the
literature, the most popular and mature control
methodology is call nested loop dq current control. This
classical control algorithm for VSC is based on the nested
loop dq control scheme, which normally includes a outer
control loop, either power control or dc voltage control, and
an inner current control loop demonstratestheconventional
dq control algorithm. In which, the outer loop controls the

active power and ac voltage while theinnerloopcontrolsthe
dq currents. A frame of reference transformationisrequired
for this control. The ac voltages and currents are first
transformed into dq quantities via Park’s transformation,
and the outer control loop generates the respective dq
current references depending on the control objectives. The
inner current control loop regulates the dq currents and
generates the appropriate switching pulses for converters.
Current references depending on the control objectives.The
inner current control loop regulates the dq currents and
generates the appropriate switching pulses for converters.
Fig 4.1: Simulation model of VSC controller
4 (a). Transformation from abc reference frame to
dq0.
In the conventional PLL, three-phase voltage vector is
translated from the abc natural reference frame to the αβ
stationary reference frame by usingClarke’stransformation,
and then translated to dq rotating frame by Park’s
transformation as shown in Fig. 4.2. The angular position of
this dq reference is controlled by a feedback loop which
makes the q-axis component equal to zero in steady state.
Therefore, under steady state condition, the d-axis
component will be the voltage vector amplitude.
Va
Vb
Vc
abc
αβ
VVα
Vβ
αβ
dq
Vq
Fig 4.2: Representation of Discrete transformation
This method utilizes two synchronous reference frames i.e.,
the voltage vector v is decomposed into positive sequence
pharos 𝑣+and negative sequence pharos 𝑣−, as shown in
Fig.4.2. In the general equation of 𝑉𝛼𝛽, α- and β-axis
components both contain the information of the positive
sequence and negative sequence which makes it difficult to
detect the positive sequence component.
5. PROPOSED METHODOLOG OF MICRO GRID
PV ARRAY
FUEL CELL
MPPT
BOOST
CONVERTER
VSC
CONTROLLER
VSC
CONTROLLER
LC FILTERS in
cascade
LC FILTERS in
cascade
LOCAL LOAD 1
LOCAL LOAD 2
UTILITY
GRID
6. SIMULATION RESULTS
6 (a). Results of fuel cell
Fig 6.1: V-I and P-I output characteristics of fuel cell
6(b). Results of PV array
Fig 6.2: I-V &P-V Characteristics of PV Array

6 (c). Three phase RMS voltage and RMS current
waveform outside of inverter.
6 (d). Output power generated in Micro grid
7. CONCLUSION
In recent years many research and developments have been
carried out in the field of Micro grid. In this paper many
issues related to Micro grid like effective control, power
quality and protection have been addressed. Combined
output of PV cell and Proton ExchangeMembranefuel cell i.e.
40 KW is connected to the conventional grid and changes in
Total Harmonic Distortion are studied. Total harmonic
distortion in voltage waveform and current was found to be
1.16 % and 2.55 % respectively at the Load common
coupling point. Calculated THD values in this project shows
better results. Also, a Micro grid of approximately 40 KW
capacities has been designed to operate both in islanded as
well as in grid connected mode. The designed system is
economical and feasible because it uses Voltage source
converter controller and combination of PV module and fuel
cell.
REFERENCES
[1] V. V. P and A. Singh, "A Comparative Analysis of PID and
Fuzzy Logic Controller in an Autonomous PV-FCMicrogrid,"
2018 International Conference on Control, Power,
Communication and Computing Technologies (ICCPCCT),
Kannur, pp. 381-385.
[2] S. Kauri and B. Dived, " Power quality issues and their
mitigation techniques in micro grid system-a review," 7th
India International Conference on Power Electronics (IICPE),
Patiala, 2016, pp. 1-4.
[3] P. B. Borase and S. M. Akolkar, "Energy management
system for micro grid with power quality improvement,"
2017 International conference on Microelectronic Devices,
Circuits and Systems (ICMDCS), Vellore, 2017, pp. 1-
[4] K. Tang, C. Sheen, W. Chen, B. Liu, Q. Yuen and Y. Sun,
"Micro grid modeling and simulation scenario design for
power quality analysis," IEEE PES Asia-Pacific Power and
Energy Engineering Conference (APPEEC), Brisbane, QLD,
2015, pp. 1-5.
[5] R. Diva, S. M. Nandukrishnan and M. G. Nair, "Hardware
implementation of power sharing and power quality
improvement for grid integration of micro grid,"
International Conference on Technological Advancements in
Power and Energy ( TAP Energy), Kollam, 2017, pp. 1-6
[7] G. Seritan, I. Triştiu, O. Ceaki and T. Boboc, " Power
quality assessment for microgrid scenarios," International
Conference and Exposition on Electrical and Power
Engineering (EPE), Iasi, 2016, pp. 723-7.
[8] Z. Wu, G. Hu, W. He, G. Hua and C. Cai, "Research on
Simulation Method for Typical Scenes of Microgrid (Group)
Access to Distribution Network," 2018 5th International
Conference on Information Science and Control Engineering
(ICISCE), Zhengzhou, 2018, pp. 491-495.

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