- Open Access
- Total Downloads : 577
- Authors : N.Sambasivarao
- Paper ID : IJERTV2IS90578
- Volume & Issue : Volume 02, Issue 09 (September 2013)
- Published (First Online): 21-09-2013
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Mitigation of Active, Reactive power loss and Overloading in a Restructured Powersystem using Series facts Device
N.Sambasivarao
Associate Professor and Head Department of EEE NRI institute of Technology,agiripalli
Abstract This paper presents a new method to mitigate Active,Reactive Power loss and Overloading in a Restructured Powersystem.The Increased power demand has forced the power system to operate very closer to its stability limits.So Transmission Overloading,Voltage instability and power loss problems are arise in the power system. These are very serious problems which cause damage to the power system.Overloading is a tough task in Deregulated power system.The above mentioned problems are reduced by incorporating Series Facts device in optimal location by Sensitivity analysis.The Simulation results were successfully tested on modified IEEE 5 bus system using Power world simulator 11.0.
Index Terms Deregulated powersystem, Thyristor Controlled Series Capacitor (TCSC), Mitigation, Overloading, Total VAR Powerloss, Active ,Reactive power loss.
1 INTRODUCTION
In the recent year with the deregulation of the electricity market the traditional concepts and practice of the power sys- tem are changed.In this process the existing transmission lines are over loaded and lead to unstable system.Overloading may also due to transfer of cheap power from generator bus to load bus,this lead to the inroduction of flexible ac transmission sys- tem(FACTS) such as Thyristor controlled series compensa- tion(TCSC).This device control the power flow in the network And reduce the flow heavily loaded line there by resulting in an increase load ability low system losses improved stability of the network and reduced active, reactive power loss.
Because of the Economic considerations, Instalation of facts Controllers in all the buses or lines is impossible and Unnecessary.There are Several methods for finding the op- timal location of FACTS devices in a power system.In [1],sencitivity approach is used to find the optimal location for placement of TCSC[6].The reduction of total system reactive Power loss method is one used to find optimal loation for placement of series FACTS device. Power flow index is used to find optimal location of FACTS device mitigation of over- loading.The method firstly put all the busses in the orderby voltage reactive power sensitivity then choose the optimal location and appropriate capability of Thyristor controlled series capacitor (TCSC).
The issue of transmission overloading is more pronounced in deregulated and competitive markets and needs a special treatment.In this environment, independent system opera- tor(ISO) has to relieve the overloading,so that the system is maintained in secure state. To mitigate overloading ISO can use mainly two types of techniques which are as follows:
-
Cost free means : using sreies FACTS devices
-
Re-dispatching the generation amounts
Among the above two methods cost free means do have advantage such as not touching economical matters, So GENCO and DISCO will not involved. FACTS devic- es,especially series FACTS devices like TCSC are considered one such technology that reduced the transmission overload- ing,powerloss (active,reactive) and allows better utilization of existing grid infrastructure,along with many benfits.
-
Thyristor Controlled Series Capacitor
The basic Thyristor Controlled Series Capacitor scheme, proposed in 1986 by Vithayathil is shown in figure 1. It con- sists of the series compensating capacitor shunted by a Thy- ristor-controlled Reactor. In a practical TCSC implementation, Several such basic compensators may be connected in series to obtain the desired voltage rating and operating characteristics.
N.Sambasiva Rao received M. Tech in Electrical Power Engineering and B.Tech degree in Electrical & Electronics Engineering from JNTU Hydera- bad, India.. He is perusing his Ph.D from JNTU, Hyderabad, India.
Fig 1. Equivalent circuit of TCSC
The power loss sensitivity index with respect to this control variable can be formulated as
aij
QL
X
Loss sensitivity with respect to TCSC
ij
L
L
v2 v2 2v v
v2 v2 2v v
Q
R2 X 2
cos
cos
ij
ij
ij
ij
X i j i j
i j R2 X 2 2
ij
n n
ij ij
Q
L
ij P Pj Q Q j
Q P
j
-
P Q
j
i 1 j 1 i
i ij i
i
2.1 Transmission line modeling with TCSC
Where , , and are loss coefficients computed from the elements of the bus impedance matrix and the bus voltage defined as :
The series impedance of a high voltage transmission line is usually inductive,with only 5 to 10 percentage of resitance This provides convenient condtion to control the steady state impedance of transmission line by adding both a Thyrister
ij
ij
ViV j
cosi j
Controlled Series Capacitor(TCSC) and a Thyristor Controlled Series Reactor
ij
ij sin
V V i j
V V i j
i j
c
c
Pc Q
ij
ij
Pc Q P Q P Q
ji
ji
ic
ic
jc
ji
ji
ic
ic
jc
Determined from [7] Method.
ij
X ij ViV j
cosi j
ij
ji
ic
jc
ij
ji
ic
jc
c
c
A General equivalent circuit of TCSC injected in transmis- sion line is shown in fig2.
Fig 2. Injection Model of TCSC
-
-
DEVICE PLACEMENT USING LOSS SENSITIVITY INDEX METHOD
The objective of the device placement may be reduction in the real power loss of a particular line,reduction in the total sys- tem real power loss,reduction in the total reactive power loss and reduction in the overloading of the system.Loss sensitivity index is method based on the sensitivity of total system active and reactive power loss with respect to control variable of the FACT device.
ij ViV j cosi j
X ij
X ij
-
Criteria for Optimal placement for TCSC
The FACTS device should be placed on the most sensitivity bus or line. For the TCSC the location is the line with most positive sesetivity index. The TCSC should be placed on the line having most positive loss sensitivity index.
-
Simulation results for modified IEEE 5-bus system.
Test results are optained by considering practical IEEE 5 bus system.OPF soluction is obtained on the system to determine the optimum genatation schedule than satisfied the objective of minimizing the losses from the desire transations and con- troling of voltage magnitude. Here the sensitive index for TCSC has been calculated for the placement of FACTS device. The FACTS device placement method known as sensitivity index has been tested on IEEE 5- bus system.
Figure.3 Shows the single line diagram of IEEE 5-bus system
The sensitivity of 5-bus system with out TCSC is given in the table below.
Table 1: sensitivity Index
Lines |
From bus |
To bus |
Sensitivity Index |
1 |
1 |
2 |
-7.759671 |
2 |
1 |
3 |
-0.120364 |
3 |
2 |
3 |
-0.303177 |
4 |
2 |
4 |
-1.145739 |
5 |
2 |
5 |
-1.69700 |
6 |
3 |
4 |
-32.19711 |
7 |
4 |
5 |
-0.026715 |
From the above table 1, the lines 1-3 and 4-5 have the most positive sensitivity factors. So these are the best locations for placement of TCSC to reduce over loading in the network. By placing TCSC in the line 1-3, the overloading can be miti- gated[1].These location offer best results in terms of increase
in active power generation with mitigation of active and reac- tive powerloss and improvement of voltage profile.
Fig 4 Shows the modified IEEE 5- bus system with out TCSC
Fig .4 Shows the transmition line flows without TCSC . It is observed that the lines 1-2, 2-4 and 2-5 are over loaded compared to other lines.
The percentage lodability values for modified IEEE 5-bus System is tabulated below.
Table2: Optimum power flow result with out TCSC
LINES |
FROM BUS |
TO BUS |
LODABILITY [%] |
1 |
1 |
2 |
96.9 |
2 |
1 |
3 |
37.6 |
3 |
2 |
3 |
22.4 |
4 |
2 |
4 |
86 |
5 |
2 |
5 |
82.9 |
6 |
3 |
4 |
11.8 |
7 |
4 |
5 |
4.1 |
From the above table 2, the maximum lodable lines are 1-2, 2-4and 2-5. Due the Increased loading these lines are over- loaded. So by using TCSC, overloading is going to be re- duced.
Table 3: Optimum power flow solution on 5-bus system with out TCSC
Quantity |
Values without TCSC |
Active power loss |
9.086 |
Reactive Power loss |
36.99 |
Table 4: Voltage profile without TCSC
Bus no |
Voltage Magnitude Without TCSC |
1 |
1.06 |
2 |
1 |
3 |
1.0061 |
4 |
0.9879 |
5 |
0.9815 |
Fig 5.Voltage profile without TCSC
Table 3 shows result obtained on 5-bus system for Active and Reactive power loss without TCSC.
Table 4 shows voltage maginitudes at each bus with out placement of TCSC.The results obtained on 5-bus system indi- cate that in order to maintain the voltage magnitude at main at 1.1p.u.
5.1 Simulation results on IEEE 5-bus system with TCSC
From the table 1 , the maximum Loadable lines are 1-2,2-4 and 2-5. From table 2 , the lines 1-3 and 4-5 have the most positive sensitivity factors. From the above anolosis these are the best location for placement of TCSC . By placing the TCSC in the line 1-3, the overloading in the system is mitigated which is shown in fig 6
Fig 6 Shows the modified IEEE 5- bus system With TCSC (Overloading mitigation by TCSC)
It is observed that after placing TCSC the over loading in the line is reduced.
The objective is to mitigate power loss ,overloading and im- poving voltage profile.TCSC is modeled as an adjustable series reactance which is a function of TCSC.By incorporating TCSC not only reduce the powerloss also improves the voltage pro- file shown in table:7.It is observed that optimal power flow solution changes little compared with the base optimal power flow shown in table:6 when TCSC is used.The Table6 shows Loadability of each line when TCSC is placed in the line 1-3 .
Table5: Optimum power flow result with TCSC
(65% Comp)
Lines |
From Bus |
To Bus |
Lodability [%] |
1 |
1 |
2 |
74.42 |
2 |
1 |
3 |
56.12 |
3 |
2 |
3 |
9.03 |
4 |
2 |
4 |
28.74 |
5 |
2 |
5 |
55.45 |
6 |
3 |
4 |
17.35 |
7 |
4 |
5 |
5.86 |
From the above table 4 , by incorporating TCSC in the Line 1-3, then overloading is mitigated.
Table 6: Optimum power flow solution on 5-bus system with TCSC
Quantity |
Values with TCSC |
Active power loss |
8.963 |
Reactive Power loss |
36.99 |
Fig 7.Voltage profile with TCSC
Bus no |
Voltage Magnitude With TCSC |
1 |
1.0600 |
2 |
1.0000 |
3 |
1.0197 |
4 |
1.0022 |
5 |
0.9647 |
Fig 7.Voltage profile with TCSC
The comprision of power flows with and without TCSC is shown as
100
80
60
40
20
0
base case
power flow
65%
compensation
100
80
60
40
20
0
base case
power flow
65%
compensation
1 2 3 4 5 6 7
1 2 3 4 5 6 7
Chart1:comprision of power flows(MW) with and without TCSC
6 Conclusions:
Mitigation of overloading, power loss is an important issue in deregulated power system. FACTS devices such as TCSC by controlling the power flow in the network can help to reduce flows in overloaded lines. Because of the considerable costs of FACTS devices, It is important to obtain optimal location for placement of these devices. The results presented in this paper show that sensitivity index along with TCSC. The effect of TCSC on line outage in order to mitigate overloading has also been studied. It can be observed from the setting the installed TCSC.
ACKNOWLEDGEMENTS
We, the authors are very grateful to the Chairman of NRI group of InstitutionsDr. R. Venkat Rao and Principal of NRI Institute of Technology Dr. C. Naga Bhaskar. Without their assistantship the work could not be completed.
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Author Biography
N.Sambasiva Rao received the B.Tech degree in Elec- trical & Electronics Engineering and M. Tech in Elec- trical Power Engineering from JNTU Hyderabad, India. He has 12 years experience in teaching. He is perusing his Ph.D from JNTU, Hyderabad, India. He published a 7 research papers in various International Journals and 2 research papers in National Conferences. He is the Member of International Association of Engineers
(IAENG) and Life member of ISTE.
He is currently working as Associate Professor and Head of the department in Electrical & Electronics Engineering at NRI Institute of Technology, Agiripalli, India. He got Best Achiever award of Andhra Pradesh By NCERT, New Del- hi, India. His Areas of interest include Electrical Machines, control Systems and power System Protection.