Matlab simulink based digital protection of transformer
1 like420 views
The document discusses the simulation of a differential relay for transformer protection using MATLAB Simulink. It presents the behavior of the relay under various operating conditions such as normal operation, internal faults, and abnormal conditions like magnetizing inrush and over fluxing. The findings highlight the effectiveness of this simulation method in modeling and testing new algorithms to enhance transformer protection strategies.
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 484
MATLAB SIMULINK BASED DIGITAL PROTECTION OF
TRANSFORMER
P.B.Thote1
, M.B. Daigavane2
, N.G. Bawane3
1
Research Scholar, G.H.R.C.E, Nagpur (RTMNU, Nagpur), India
2
Principal, V.I.T, Nagpur (RTMNU, Nagpur), India
3
Principal, S.B.J.I.T.M.R, Nagpur (RTMNU, Nagpur), India
Abstract
Power transformer is one of the most important equipment in a power transmission and distribution system. This paper presents a
technology to simulate differential relay in Matlab Simulink based environment for determining its behavior during various operating
conditions. The results show that this simulation method can work properly and this will allow rapid modeling and testing of new
algorithm in view to improve protection of transformer.
Keywords: differntial protection, magnetising inrush current, internal faults, over fluxing,trip signal
-----------------------------------------------------------------------***----------------------------------------------------------------------
1. INTRODUCTION
Transformer is a vital and expensive component of electrical
power system. The unplanned outage of a power transformer is
costly for utilities and hence need adequate protection [1]. It is
necessary to study the various operating conditions of
transformer to explore new protection algorithm [2].The aim of
this paper is to simulate various conditions of a transformer like
load condition, internal faults, abnormal conditions like
magnetizing inrush current, over fluxing, etc. In this paper, the
physical model of a two winding 230 V/230 V is simulated in
MATLAB-SIMULINK. The block parameters of transformer
are obtained using experiment conducted on laboratory
transformer. All the mentioned operating conditions are applied
in this model one by one and are analyzed from differential
protection point of view. An example presented in this paper
demonstrates the capabilities and underline the advantages of
Matlab-Simulink environment to study differential current
pattern for various conditions which can be subsequently used
for designing suitable digital relay. This data can be used to
improve transformer protection using intelligent techniques.
2. DEVELOPMENT OF DIGITAL DIFFERENTIAL
RELAY
2.1 Main Simulink Model
The main simulink model used for obtaining differential current
data is shown in Figure 1
Fig 1 Simulink model for differential protection of Transformer
2.2 Results of Laboratory Experiment
To obtain the block parameters of transformer, open circuit and
short circuit test is performed. Figure 2 shows the experimental
set-up to obtain block parameters of transformer.](https://image.slidesharecdn.com/matlabsimulinkbaseddigitalprotectionoftransformer-160812140759/85/Matlab-simulink-based-digital-protection-of-transformer-1-320.jpg)
![IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 487
During this condition the relay mal-operates. Conventionally,
second harmonic blocking scheme is used for discrimination
between inrush current and fault current. But today’s new low
loss core material decreases the second harmonic component of
inrush current [3]. Therefore, researchers are using new
techniques like wave shape recognition, Digital Signal
Processing based techniques for accurate and rapid
discrimination between abnormal and fault conditions [4, 5].
For the past few years, inrush current became an interesting
topic and many researchers have focused their studies in this
matter [6].
3.4 Over Fluxing Condition
Increase in input voltage causes increase in working flux level.
The reduction in supply frequency also increases the core flux.
The generator transformers are more prone for over fluxing as
this may be subjected to an uncomfortable combination of over
voltage and under frequency during start-up. The ratio of V/f is
an index of over fluxing. Fig.11 shows differential current data
for the over fluxing condition when input voltage = 282 V and
input frequency = 47Hz which results in mal operation of relay.
Fig 11 Differential current and Trip signal for overfluxing
condition
CONCLUSIONS
The results presented in this paper are in line agreement with
the theoretical calculations. From the work presented in this
paper, it is possible to obtain differential current data for
various operating conditions which can be used for improving
the protection function of transformer, mainly to discriminate
between transformer internal faults and transients like inrush,
over fluxing conditions.
REFERENCES
[1] S.V.Kulkarni,S.A.Khaparde, Transformer Engineering.
Design and Practice, Marcel Dekker Inc., New York,
Basel, 2004.
[2] Haihui Song, Fangming Zhao, Di He, “Simulation study
on internal fault of Transformer ” Elsevier, sciverse
science direct, 2012 international conference on solid
state devices and material science, Physics Procedia 25
(2012) pp 459-464
[3] J.P Patra, “A discussion on power transformer
magnetizing inrush, remedy, fault detection in Matlab-
simulink environment”, International Journal of
Electrical Engineering, ISSN 0974-2158 vol.4, number 1
(2011), pp 83-102
[4] R. Bouderbala, H. Bentarzi and A. Ouadi, “Digital
Differential Relay Reliability Enhancement of Power
Transformer”, International Journal of Circuits, System
And Signal Processing
[5] M.S. El-Bages, “Improvement of Digital Differential
Relay Sensitivity For Internal Ground Faults In
Powertransformers ”, IJPTE Journal, ISSN 2077-3528,
pp 1-5
[6] P.L,Mao and R.K.Aggarwal, "A wavelet transform
based decision making logic method for discrimination
between internal faults and inrush currents in power
transformers", International journal of Electric power
and Energy systems, Vol. 22, no 6 ,pp-389-395 2000
[7] A.I.Megahed, A.Ramadan, W.El.Mahdy, "Power
transformer differential relay using wavelet transform
energies", in:Power and Energy Society General
Meeting, IEEE, 20-24,1-6,2008
REFERENCES:
Pankaj B. Thote has born in Nagpur
(Maharashtra)in 1975. He received the
B.E. degree in Electrical Engineering in
1997 and M.E. degree in Electrical Power
System in 2010 from Sant Gadge Baba
Amravati University, India. He is
currently working as a Assistant Professor
& Head in Electrical Engineering
Department of Shri Shantilalji Badjate Institute of Technology,
Managment and Research, Nagpur. His research interests
include network analysis and protection. He is a Life Member
of the Indian Society for technical Education. He is pursuing his
Ph.D degree from Rashtrasanth Tukdoji Maharaj Nagpur
University.
Dr. Manoj B. Daigavane obtained the
B.E. Degree in Power Electronics
Engineering from Nagpur University,
India in 1988. He received the M.S.
Degree in Electronics and Control
Engineering from Birla Institute of
Technology and Science, Pilani (Raj) India in 1994. He also
obtained the M.E. Degree in Power Electronics Engineering
from Rajeev Gandhi University of Technology, Bhopal (M.P),
India in 2001. He received Ph D Degree in Electrical
Engineering from R.T.M. Nagpur University, India in 2009.
Since Sept.1988- June 2007, he had been with the Department
of Electronics and Power Electronics Engineering, B. D.
College of Engineering, Sewagram (Wardha), affiliated to the](https://image.slidesharecdn.com/matlabsimulinkbaseddigitalprotectionoftransformer-160812140759/85/Matlab-simulink-based-digital-protection-of-transformer-4-320.jpg)
Matlab simulink based digital protection of transformer
- 1. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 _______________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 484 MATLAB SIMULINK BASED DIGITAL PROTECTION OF TRANSFORMER P.B.Thote1 , M.B. Daigavane2 , N.G. Bawane3 1 Research Scholar, G.H.R.C.E, Nagpur (RTMNU, Nagpur), India 2 Principal, V.I.T, Nagpur (RTMNU, Nagpur), India 3 Principal, S.B.J.I.T.M.R, Nagpur (RTMNU, Nagpur), India Abstract Power transformer is one of the most important equipment in a power transmission and distribution system. This paper presents a technology to simulate differential relay in Matlab Simulink based environment for determining its behavior during various operating conditions. The results show that this simulation method can work properly and this will allow rapid modeling and testing of new algorithm in view to improve protection of transformer. Keywords: differntial protection, magnetising inrush current, internal faults, over fluxing,trip signal -----------------------------------------------------------------------***---------------------------------------------------------------------- 1. INTRODUCTION Transformer is a vital and expensive component of electrical power system. The unplanned outage of a power transformer is costly for utilities and hence need adequate protection [1]. It is necessary to study the various operating conditions of transformer to explore new protection algorithm [2].The aim of this paper is to simulate various conditions of a transformer like load condition, internal faults, abnormal conditions like magnetizing inrush current, over fluxing, etc. In this paper, the physical model of a two winding 230 V/230 V is simulated in MATLAB-SIMULINK. The block parameters of transformer are obtained using experiment conducted on laboratory transformer. All the mentioned operating conditions are applied in this model one by one and are analyzed from differential protection point of view. An example presented in this paper demonstrates the capabilities and underline the advantages of Matlab-Simulink environment to study differential current pattern for various conditions which can be subsequently used for designing suitable digital relay. This data can be used to improve transformer protection using intelligent techniques. 2. DEVELOPMENT OF DIGITAL DIFFERENTIAL RELAY 2.1 Main Simulink Model The main simulink model used for obtaining differential current data is shown in Figure 1 Fig 1 Simulink model for differential protection of Transformer 2.2 Results of Laboratory Experiment To obtain the block parameters of transformer, open circuit and short circuit test is performed. Figure 2 shows the experimental set-up to obtain block parameters of transformer.
- 2. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 _______________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 485 Fig2. Experimental set-up Figure 3 shows data entry window for two winding transformer. Fig3. Data entry window for two winding Transformer 2.3 Validation of Simulink Model For load of P= 1000 W and Q= 800 VAr, S= 1280.62 VA, I1=I2 =5.56 A and I1peak =I2peak = 7.87 A The waveforms obtained by this simulink model are in line with the actual calculations as shown in figure 4. Fig 4 Winding currents on two sides of a Transformer This confirms the correctness of the simulink model and hence data of differential current for various operating conditions obtained from this model can be used for further analysis. The pickup value of differential current is set equal to 0.35 A. 2.4 Subsystems used in Main Simulink Model Figure 5 illustrates the components of subsystem 1 used in main simulink model where differential current is input and Trip signal is the output. Fig 5 Sub-system 1 used in main simulink model Figure 6 shows the components of subsystem 2. Fig 6 Sub-system 2 used in main simulink model
- 3. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 _______________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 486 The relational operator determines whether the differential current is more than the peak up value of current. Fundamental and second harmonic block calculates the fundamental and second harmonic contents of differential current. Divide block calculates the ratio of second harmonic to fundamental component. Relational operator 1 block determines whether the ratio is more than the set limit of ratio. Not block and And block realizes harmonic restrain scheme. 3. RESULTS AND DISCUSSION The results are given for following conditions of energisation and faults. 3.1 Normal Operation When the transformer is operating normally, the differential current is well below the peak up value and the relay does not issue any trip signal as shown in Figure 7.It is the correct operation of relay. Fig 7 Differential current and Trip signal for normal condition 3.2 Internal Fault When few turns of the windings are shorted, the differential current exceeds the peak up value and the relay issues trip signal as shown in figure 8.It is again the correct operation of ralay.Various internal faults on winding 1 and 2 of transformer are simulated by changing number of turns. The fault occurs at 0.02sec. Fig 8 Differential current and Trip signal for internal fault condition In this case, the differential current is more than pick-up value and relay will operate. It is the correct operation of relay. 3.3 Magnetizing Inrush Current The transient magnetizing current of a transformer flowing after connecting the transformer with AC source is called inrush current. Inrush current is highly asymmetric. It results from saturation of core of transformer caused by excessive growth of magnetic flux in one direction only. The first peak of an inrush current may exceed many times the value of transformer nominal current. Fig.9 shows the waveform of a magnetizing inrush current with transformer energized at instant zero on the input voltage wave. Fig 9 Magnetizing inrush current It is possible to analyze the various factors which affect the first peak of the inrush current like saturation characteristics of the core, instant on input voltage wave where transformer is energized, residual magnetic flux, etc in the simulation presented in this paper. Since the differential current is above the pickup value of current, the relay issues trip signal as shown in fig 10. Fig 10 Differential current and Trip signal for Magnetizing inrush condition
- 4. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 _______________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 487 During this condition the relay mal-operates. Conventionally, second harmonic blocking scheme is used for discrimination between inrush current and fault current. But today’s new low loss core material decreases the second harmonic component of inrush current [3]. Therefore, researchers are using new techniques like wave shape recognition, Digital Signal Processing based techniques for accurate and rapid discrimination between abnormal and fault conditions [4, 5]. For the past few years, inrush current became an interesting topic and many researchers have focused their studies in this matter [6]. 3.4 Over Fluxing Condition Increase in input voltage causes increase in working flux level. The reduction in supply frequency also increases the core flux. The generator transformers are more prone for over fluxing as this may be subjected to an uncomfortable combination of over voltage and under frequency during start-up. The ratio of V/f is an index of over fluxing. Fig.11 shows differential current data for the over fluxing condition when input voltage = 282 V and input frequency = 47Hz which results in mal operation of relay. Fig 11 Differential current and Trip signal for overfluxing condition CONCLUSIONS The results presented in this paper are in line agreement with the theoretical calculations. From the work presented in this paper, it is possible to obtain differential current data for various operating conditions which can be used for improving the protection function of transformer, mainly to discriminate between transformer internal faults and transients like inrush, over fluxing conditions. REFERENCES [1] S.V.Kulkarni,S.A.Khaparde, Transformer Engineering. Design and Practice, Marcel Dekker Inc., New York, Basel, 2004. [2] Haihui Song, Fangming Zhao, Di He, “Simulation study on internal fault of Transformer ” Elsevier, sciverse science direct, 2012 international conference on solid state devices and material science, Physics Procedia 25 (2012) pp 459-464 [3] J.P Patra, “A discussion on power transformer magnetizing inrush, remedy, fault detection in Matlab- simulink environment”, International Journal of Electrical Engineering, ISSN 0974-2158 vol.4, number 1 (2011), pp 83-102 [4] R. Bouderbala, H. Bentarzi and A. Ouadi, “Digital Differential Relay Reliability Enhancement of Power Transformer”, International Journal of Circuits, System And Signal Processing [5] M.S. El-Bages, “Improvement of Digital Differential Relay Sensitivity For Internal Ground Faults In Powertransformers ”, IJPTE Journal, ISSN 2077-3528, pp 1-5 [6] P.L,Mao and R.K.Aggarwal, "A wavelet transform based decision making logic method for discrimination between internal faults and inrush currents in power transformers", International journal of Electric power and Energy systems, Vol. 22, no 6 ,pp-389-395 2000 [7] A.I.Megahed, A.Ramadan, W.El.Mahdy, "Power transformer differential relay using wavelet transform energies", in:Power and Energy Society General Meeting, IEEE, 20-24,1-6,2008 REFERENCES: Pankaj B. Thote has born in Nagpur (Maharashtra)in 1975. He received the B.E. degree in Electrical Engineering in 1997 and M.E. degree in Electrical Power System in 2010 from Sant Gadge Baba Amravati University, India. He is currently working as a Assistant Professor & Head in Electrical Engineering Department of Shri Shantilalji Badjate Institute of Technology, Managment and Research, Nagpur. His research interests include network analysis and protection. He is a Life Member of the Indian Society for technical Education. He is pursuing his Ph.D degree from Rashtrasanth Tukdoji Maharaj Nagpur University. Dr. Manoj B. Daigavane obtained the B.E. Degree in Power Electronics Engineering from Nagpur University, India in 1988. He received the M.S. Degree in Electronics and Control Engineering from Birla Institute of Technology and Science, Pilani (Raj) India in 1994. He also obtained the M.E. Degree in Power Electronics Engineering from Rajeev Gandhi University of Technology, Bhopal (M.P), India in 2001. He received Ph D Degree in Electrical Engineering from R.T.M. Nagpur University, India in 2009. Since Sept.1988- June 2007, he had been with the Department of Electronics and Power Electronics Engineering, B. D. College of Engineering, Sewagram (Wardha), affiliated to the
- 5. IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308 _______________________________________________________________________________________ Volume: 03 Issue: 02 | Feb-2014, Available @ http://www.ijret.org 488 Nagpur University, India. Since July 1, 2007 to Apr 30, 2009, he was Professor & Head of Electrical and Electronics Engineering, Disha Institute of Mgmt. and Tech., Raipur (C.G.) where he is engaged in teaching & research. Earlier, he was Principal at S. D. College of Engineering, Wardha. Presently, he is Principal of V.I.T College of Engineering, Nagpur – Maharashtra (India). His main areas of interest are resonant converters, Power quality issues, DSP applications and Power electronics for motor drives. He has been responsible for the development of Electrical Machines and Power Electronics Laboratories He is a Member of the Institution of Engineers (India) and a Life Member of the Indian Society for technical Education. Dr. Narendra G. Bawane is a Professor & Principal of S. B. Jain Institute of Technology, Management & Research, Nagpur. Prior to this assignment, he was Head of Computer Science and Engineering department at G. H. Raisoni college of Engineering, Nagpur. He has also worked with B.D. College of engineering sewagram and Govt. Polytechnic, Nagpur for several years. He is having total teaching experience of more than 24 years to his credit. He has completed his B.E. from Nagpur University in 1987 and M. Tech. in 1992 from IIT, New Delhi. He completed his Ph. D. in 2006 at VNIT, Nagpur. His areas of interest are ANN,Fuzzy,Embeded Systems etc.