IRJET- Enhancement of Power Flow Capability in Power System using UPFC- A RevieW

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 06 Issue: 05 | May 2019 www.irjet.net p-ISSN: 2395-0072
© 2019, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 1146
Enhancement of Power Flow Capability in Power System using
UPFC- A Review
Shradha N. Waghade1, Chandrakala Gowder2
1PG Scholar, Dept. of Electrical Engineering, Shri Sai Collage of Engineering and Technology, Bhadrawati,
Maharashtra, India
2Assistant Professor, Dept. of Electrical Engineering, Shri Sai Collage of Engineering and Technology, Bhadrawati,
Maharashtra, India
---------------------------------------------------------------------***----------------------------------------------------------------------
Abstract – Flexible Alternating Current Transmission
Systems (FACTS) technology opens up new opportunities for
controlling power and enhancing the usable capacity of
present as well as new and upgraded lines. The focus of this
paper is a FACTS device known as the Unified Power Flow
Controller (UPFC). With its unique capability to control
simultaneously real and reactive power flows on a
transmission line as well as to regulate voltage at the bus
where it is connected, this device creates a tremendous
quality impact on power system stability. These features
turn out to be even more significant because UPFC can allow
loading of the transmission lines close to their thermal
limits, forcing the power to flow through the desired paths.
This provides the power system operators much needed
flexibility in order to satisfy the demands. The IEEE 5 bus
network is a benchmark system taken in this paper in order
to check the response of UPFC on the power flow
enhancement. UPFC is modeled in different ways to analyze
power flow and voltage improvement at each bus. In this
paper UPFC is modeled as a Voltage Source Model (VSM)
and that will generate reference bus voltage and phase
angle at different load conditions on the receiving end of
UPFC. The variation between the voltage generated by VSM
and actual voltage profile in the bus is injected in the line
through an injection transformer.
Key Words: FACTS, real and reactive power flow, IEEE 5
bus system, IGBT, UPFC.
1. INTRODUCTION
The continuing rapid development of high-power
semiconductor technology now makes it possible to
control electrical power systems by means of power
electronic devices. These devices constitute an emerging
technology called FACTS (flexible alternating current
transmission systems). Its first concept was introduced by
N.G Hingorani, in 1988 (FACTS) is very popular and
essential device in power systems [1]. FACTS technology
has a number of benefits, such as greater power flow
control, increased secure loading of existing transmission
circuits, damping of power system oscillations, less
environmental impact and, potentially, less cost than most
alternative techniques of transmission system
reinforcement.
In order to have a better use of the transmission
capabilities of the transmission lines, different types of
FACTS devices have been studied: Static VAR Compensator
(SVC), Thyristor controlled series capacitor (TCSC),Static
synchronous compensator (STATOM), Static series
compensator (SSSC), Unified Power Flow Controllers
(UPFCs), thyristor switched capacitor (TSC) thyristor
controlled reactor (TCR) [2-10]. Several FACTS-devices
have been introduced for various applications in power
system.
The UPFC is the most versatile of the FACTS devices. It
cannot only perform the functions of the static
synchronous compensator (STATCOM), thyristor switched
capacitor (TSC) thyristor controlled reactor (TCR), and the
phase angle regulator but also provides additional
flexibility by combining some of the functions of the above
controllers. The main function of the UPFC is to control the
flow of real and reactive power by injection of a voltage in
series with the transmission line. Both the magnitude and
the phase angle of the voltage can be varied
independently. Real and reactive power flow control can
allow for power flow in prescribed routes, loading of
transmission lines closer to their thermal limits and can be
utilized for improving transient and small signal stability
of the power system.
This device combination of two other FACTS devices: the
Static Synchronous Compensator (STATCOM) and the
Static Synchronous Series Compensator (SSSC).
Practically, these two devices are two Voltage Source
Inverters (VSI’s) connected respectively in shunt with the
transmission line through a shunt transformer and in
series with the transmission line through a series
transformer. These are connected to each other by a
common DC link, which is a typical storage capacitor [5-
10].
2. LITERATURE REVIEW
In (2013) Hakim Elahi Tooraji and Nekoubin Abdolamir
designed and simulated a Unified Power Flow Controller is
in multi-machine power system. The on-line designed
process is based on PWM method which all the power
quality parameters representing as voltage sag and sweel
can be improved. In the proposed control method, the

harmonic distortion of the system is decreased and the
voltage oscillations of the DC capacitor will be improved.
Simulations that are done by the PSCAD/EMTDC software
show the effectiveness and precision of this designing
[11].
In (2013) Kumar Gaurav and Nitin Saxena investigate the
enhancement in voltage stability margin as well as the
improvement in the power transfer capability in a power
system with the incorporation of UPFC. A simple
transmission line system is modeled in Matlab/Simulink
environment. The load flow results are first obtained for
an uncompensated system, and the voltage and power
profiles are studied. The results so obtained are compared
with the result obtained after compensating the system
using UPFC to show the voltage stability margin
enhancement [12].
In (2013) Vaibhav S Kale et, al. proposed the real, reactive
power and voltage control through a transmission line by
placing UPFC at the sending end using computer
simulation. The control scheme has the fast dynamic
response and hence is adequate for improving transient
behavior of power system after transient conditions [13].
In (2015) Koganti et, al. studied Power quality and
stability improvement of HVDC transmission System using
UPFC for Different uncertainty conditions, they concluded
that UPFC improves the system performance. It can
control the power flow in the transmission line, effectively.
With the addition of UPFC, the magnitude of fault current
reduces and oscillations of excitation voltage also reduce.
The total harmonic distortion (THD) is also reduced well
below the IEC standards. It is more economical for the
HVDC transmission system to transfer more power [14].
In (2015) Shantha Soruban et, al. proposed an ANN based
control scheme for a UPFC to be used as an active power
filter. The objective is to guarantee power to the load at
the required power quality. The ANN control unit
monitors the voltage at the point of common coupling.
UPFC enables improved power quality by maintaining
power factor nearer to unity rapid response time, the
ability to provide reactive power at low voltage and to
provide voltage compensation can be obtained. For
unbalanced voltage compensation, two unbalanced
controllers using the phase voltage amplitude and
negative sequence component are proposed [15].
3. UNIFIED POWER FLOW CONTROLLER
UPFC is the most flexible multi-functional FACTs device
which is a new generation of FACTS devices. The UPFC is
one of the most versatile devices. In UPFC, the transmitted
power can be controlled by changing three parameters of
power transmission line namely transmission magnitude
voltage, impedance and phase angle.
3.1 Basic principle of UPFC
The UPFC consists of two voltage source converters; series
and shunt converter, which are connected to each other
with a common dc link. Shunt converter (converter 1)or
Static Synchronous Compensator (STATCOM) is used to
provide reactive power to the ac system, besides that, it
will provide the dc power required for both inverters,
while series converter (converter 2)or Static Synchronous
Series Compensator (SSSC) is used to add controlled
voltage magnitude line as shown in fig. 1. Each of the
branches consists of a transformer and power electronic
converter. These two voltage source converters shared a
common dc capacitor. The real power can freely flow in
either direction between the ac terminals of the two
converters. In this respect, converter 2 provides the main
function by injecting an AC voltage Vse, at system
frequency with variable magnitude |Vse|, (|Vse| ≤ 0 ≤ |Vse|
max) and phase angle (0 ≤ γ ≤ 2π) in series with the line.
On the other hand, converter1 is used primarily to provide
the real power demanded by converter2 at the common dc
link [2].
The energy storing capacity of this dc capacitor is
generally small. The reactive power in the shunt or series
converter can be chosen independently, giving greater
flexibility to the power flow control.
Fig -1: schematic diagram of the UPFC
Fig.2 shows Single line diagram of UPFC and Phasor of
voltage and current to V [7]. This gives a new line voltage
V2 with different magnitude and phase shift.
As the angle φ varies, the phase shift δ between V2 and V3
also varies. Voltage and current with the presence of the
two converters, UPFC not only can supply reactive power
but also active power. The equation for the active and
reactive power is given as follows,

Fig – 2: Single line diagram of UPFC and Phasor of
Voltage and current
3.2 Voltage Source Converters Used in UPFC
3.2.1 STATCOM
A static synchronous generator operated as a shunt –
connected static var compensator whose capacitive or
inductive output current can be controlled independent of
the ac system voltage. For the voltage-sourced converter,
its ac output voltage is controlled such that it is just right
for the required reactive current flow for any ac bus
voltage dc capacitor voltage is automatically adjusted as
require serving as a voltage source for the converter.
STATCOM also designed to act as an active filter to absorb
system harmonics. Fig-4 shows the schematic diagram of
STATCOM without energy storage system.
Fig – 4: schematic diagram of STATCOM without energy
storage system
3.2.2 SSSC
A Static synchronous series generator operated without an
external electric energy source as a series compensator
whose output voltage is in quadrature with and controlled
independently of the line current for the purpose of
increasing or decreasing overall reactive voltage drop
across the line and thereby controlling the transmitted
electric power. The SSSC may include transiently rated
energy storage or energy absorbing devices to enhance the
dynamic behavior of the power system by additional
temporary real power compensation to increase or
decrease momentarily the overall real voltage drop across
the line.
Fig – 4: Schematic of SSSC
4. Control of UPFC OPERATING MODES OF UPFC
As the UPFC consists of two converters that are coupled on
the DC side, the control of each converter is explained
below:
4.1 Control of the Shunt Converter:
The block diagram of shunt converter is shown in fig 5.The
shunt converter draws a controlled current from the
system. One component of this current is Ip which is
automatically determined by the requirement to balance
the real power supplied to the series converter through
the DC link. This power balance is enforced by regulating
the DC capacitor voltage by feedback control.
Fig – 5: block diagram of shunt controller
The other component of the shunt converter current is the
reactive current, Ir which can be controlled in a similar

fashion as in a STATCOM. There are two operating
(control) modes for a STATCOM or the shunt converter
[17]. These are,
1. VAR control mode where the reactive current reference
is determined by the inductive or capacitive VAR
command. The feedback signals are obtained from current
transformers (CT) typically located on the bushings of the
coupling (step down) transformer.
2. Automatic voltage control mode where the reactive
current reference is determined by the output of the
feedback voltage controller which incorporates a droop
characteristic (as in the case of a SVC or a STATCOM). The
voltage feedback signals are obtained from potential
transformers (PT) measuring the voltage V1 at the
substation feeding the coupling transformer.
4.2 Control of the series converter:
The block diagram of series converter is shown in fig-6.In
this control mode, the series injected voltage is
determined by a vector control system to ensure the flow
of the desired current (phasor) which is maintained even
during system disturbances (unless the system control
dictates the modulation of the power and reactive power).
Although the normal conditions dictate the regulation of
the complex power flow in the line, the contingency
conditions require the controller to contribute to system
stability by damping power oscillations.
Fig – 6: block diagram of series controller
The different control modes for the series voltage are
given:
1. Direct voltage injection mode where the converter
simply generates a voltage phasor in response to the
reference input. A special case is when the desired voltage
is a reactive voltage in quadrature with the line current.
2. Phase Angle Shifter Emulation mode where the injected
voltage is phase shifted relative to the voltage by an angle
specified by the reference input.
3. Line impedance emulation mode where the series
injected voltage is controlled in proportion to the line
current.
4. Automatic power flow control mode where the
reference inputs determine the required real power (P)
and the reactive power (Q) at a specified location in the
line.
3. CONCLUSIONS
In this study, a brief review of UPFC (FACTS), the essential
features of UPFC controller and mathematical model was
discussed. The potential to enhancement of power system
stability was explained. In power system transmission, it is
required to maintain the voltage magnitude, phase angle
and line impedance. Consequently, to control power flow
over designated transmission line and enhancement of
power system stability FACTS devices are used in modern
power system network. The Comparisons of Facts
Controller on different aspects are given in Table 1
In this paper the role of UPFC device in power system and
current status of electric power system network are
addressed. Therefore, following results are found power
flow control is achieved by using FACTS (UPFC) devices.
Transient stability is improved and faster steady state is
achieved. Hence congestion is less by improving transient
stability.
Table -1: Comparisons of Facts Controller
Facts
devices
Power
System
Stability
Enhance
ment
Load
flow
Voltage
Control
Trans
ient
Stabil
ity
Dynamic
Stability
UPFC Yes High High Mediu
m
Medium
TCSC
Yes Mediu
m
Low High Medium
SVC
Yes Low
High
Low Medium
SSSC
Yes Low
High
Medi
um
Medium
REFERENCES
[1] N. G. Hingorani and L. Gyugyi, “Understanding FACTS,
Concepts, and Technology of Flexible AC Transmission
Systems”, Piscataway, N IEEE Press, 2000.
[2] Mithu Sarkar, “Effect Of UPFC Allocation on
Transmission System Power Loss”, Int.Conf. On
Energy Efficient Technologies for System
Sustainability (ICEETS-2013), IEEE, Tamilnadu, 10th –
12th April 2013.
[3] Gyugyi, L., Schauder, C.D., Williams, S.L., Reitman, T.R.,
Torgerson, D.R. and Edris, A. “The unified power flow
controller: A new approach to power transmission
control”, IEEE Transaction Power Delivery, Vol. 10, pp.
1085-1097,1995.

[4] AmlanBarik, SidharthSabyasachi, “Control Design and
Comparison of Unified Power Flow Controller for
Various Control Strategies” International Journal of
Recent Technology and Engineering (IJRTE) ISSN:
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[5] Roopa. R, K.ShanmukhaSundar, “Enhancement Of
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Conference, 05th July-2014, Bengaluru, India, Isbn:
978-93-84209-33-9.
[6] Tanushree Kaul, Pawan Rana, “Modeling, Analysis and
Optimal Location of UPFC for Real Power Loss
Minimization”, International journal application, 7 July
2013.
[7] Sandeep Sharma and Shelly Vadhera, “Enhancement of
Power Transfer Capability of Interconnected Power
System Using Unified Power Flow Controller (UPFC)”,
International Journal of Electronics and Electrical
Engineering Vol. 4, No. 3, June 2016.
[8] A. Rajabi-Ghahnavieh, M. Fotuhi-Firuzabad, “UPFC for
Enhancing Power System Reliability”, IEEE-2010.
[9] Kunal Gupta, Baseem Khan, “Available Transfer
Capability Enhancement by Unified Power Flow
Controller”, IEEE - 2015.
[10] Sadjad Galvani, MehrdadTarafdar Hagh, “Unified
power flow controller impact on power system
predictability”, IEEE-2014.
[11] H. E. Tooraji and N. Abdolamir, “Improving Power
Quality Parameters in AC Transmission Systems Using
Unified Power Flow Controller,” Research Journal of
Recent Sciences, Vol.2, No.4, pp.84-90, Apr. 2013.
[12] K. Gaurav and N. Saxena, “Power Quality improvement
using UPFC,” International Journal of Electrical,
Electronics and Computer Engineering, Vol.2, No.2,
pp.30- 33, 2013.
[13] S. Vaibhav Kale, R. P.Prashant and R. Khatri, “Unified
Power Flow Controller for Power Quality
Improvement,” International Journal of Emerging
Science and Engineering (IJESE), Vol.1, No. 10, pp. 1-4,
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[14] K. S. Lakshmi, G. Sravanthi, L. Ramadevi, and K. H.
Chowdary, “Power quality and stability improvement
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uncertainty conditions,” International Journal of
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795-801, Feb. 2015.
[15] M. S. Soruban, J D. Sathyaraj, and J. J. Gnana Chandran,
“Power Quality Enhancement Using UPFC as an Active
Power Filter for Renewable Power Generation,”
International Journal of Advanced Research in
Electrical, Electronics and Instrumentation
Engineering Vol. 4, No. 3, pp. 1712-1718, March. 2015.

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