Traveling Wave Differential Relaying Presented by Jinqian Yu.
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Transcript of Traveling Wave Differential Relaying Presented by Jinqian Yu.
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Traveling Wave Differential Relaying
Presented by Jinqian Yu
![Page 2: Traveling Wave Differential Relaying Presented by Jinqian Yu.](https://reader036.fdocuments.us/reader036/viewer/2022062317/5a4d1b287f8b9ab059998315/html5/thumbnails/2.jpg)
Table of Contents
1. Introduction
2. Line model for traveling waves
3. Traveling waves’ propagation & measurement
4. Differential algorithm based on traveling waves
5. Feasibility of implementation
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Introduction
Basic idea The occurrence of a fault can trigger a series of traveling
waves which contain the earliest available evidence to a relay that the fault has taken place. It is possible to design a differential relay scheme based on traveling waves.
Advantages • Ultra-high speed • Less susceptible by system transient phenomenon
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Line model for traveling waves
Distributed parameter model
→
Solution
u iri lx ti ugu cx t
u ilx ti ucx t
(lossless line)
( ) ( )
1 [ ( ) ( )]
x xu F t f tv vx xi F t f t
z v v
Where v is surge velocity
z is surge impedance
1vlc
lzc
l
c
l
c
ui
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Traveling waves propagation & measurement
2 1
2 1
f s r
r r f
e k e
e k e
k is reflection coefficients, such that
Fer ef
ir if
er1
ef2
er3
ef4
ef1
er2
ef3
x
t
T
3T
5T
S R
The reflection coefficient at fault location is -1
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Measurement
Sending end
→
Receiving end
→
( ) ( )
1( ) [ ( ) ( )]
s
s
u t F vt f vt
i t F vt f vtz
2 ( ) ( ) ( )2 ( ) ( ) ( )
s s
s s
F vt u t zi tf vt u t zi t
( ) ( ) ( )1( ) [ ( ) ( )]
r
r
u t F d vt f d vt
i t F d vt f d vtz
2 ( ) ( ) ( )2 ( ) ( ) ( )
r r
r r
F d vt u t zi tf d vt u t zi t
F and f denote forward wave and backward wave respectively
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Differential algorithm based on traveling waves
S RFs
fs
fr
Frus(t) ur(t)
( ) ( ) ( )( ) ( ) ( )( ) ( ) ( )( ) ( ) ( )
s s s
r r r
sr s s
rs r r
u t F t f tu t F t f tzi t F t f tzi t F t f t
→( ) ( ) 2 ( )( ) ( ) 2 ( )( ) ( ) 2 ( )( ) ( ) 2 ( )
s sr s
r rs r
s sr s
r rs r
u t zi t F tu t zi t F tu t zi t f tu t zi t f t
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Derive the Bergeron’s equations
In a healthy line, it takes time T= d/v that a forward wave from terminal S travel to terminal R where the wave is regarded as backward wave.
Use these equations and take t = t – T in equations in last slide, we get the Bergeron’s equation:
( ) ( )( ) ( )
r s
s r
f t F t Tf t F t T
( ) ( ) ( ) ( )( ) ( ) ( ) ( )
s sr r rs
r rs s sr
u t zi t u t T zi t Tu t zi t u t T zi t T
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Feasibility issuesThough Bergeron’s equations always hold if there is no internal fault
between two terminals of a line and this differential relaying scheme seems foolproof, some problems still remain unsolved.
1. The relay has to rely on a narrow window of available data to make a decision.
2. It is difficult to recognize and capture the data carried by wavefront as it travels at such a high speed.
3. Data acquisition system must be high bandwidth to obtain the high-frequency content of traveling waves.
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Conclusion
• Differential relaying based only traveling waves is just one of those relatively new scheme using traveling waves. In theory, it has demonstrated the possibility of ultra-high speed for a relay. However, some technical issues need to be solved before implementation. Traveling wave differential relaying is still an interesting technique and worth our attention.
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Reference[1] Tagaki, T., Baba, J.I., Uemura, K. and Sakaguchi, T. Fault protection based on
traveling wave theory, Part 1–Theory. Electrical Engineering in Japan, Vol. 98, No. 1, 1978.
[2] Tagaki, T., Baba, J.I., Uemura, K. and Sakaguchi, T. Fault protection based on traveling wave theory, Part 2–Sensitivity analysis and laboratory test, IEEE paper No. A 78, pp. 220-226, 1978.
[3] Dommel, H.W. and Michels, J.M., High speed relaying using traveling waves transient analysis, IEEE paper No. A78, pp 214-219, 1978.
[4] Bewley, L.V., Traveling Waves on Transmission Systems, John Wiley & Sons, Inc. New York, 1963.
[5] Chamia, M. and Liberman, S. Ultra high speed relay for EHV/UHV transmission lines – development, design and application, IEEE Trans, on PAS, vol. PAS-97, No. 6, pp. 2104-2116, 1978.
[6] Mansour, M.M and Swift, G.W., A multi-microprocessor based traveling wave relay – Theory and realization, IEEE Trans. Vol. PWRD-1, No. 1, 1986.
[7] Bollen, M.H.J. and Kerston, W.F.J., Traveling-wave-based protection: directional, differential or distance? Proc 10th Power Systems Computation Conf., 1990.
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[8] Bollen, M.H.J. Traveling-wave-based protection of double-circuit lines. IEE Proceedings-C, Vol. 140, No. 1, 1993.
[9] Arun G. Phadke, James S. Thorp. Computer relaying for power systems, John Wiley & Sons, Inc, New York, pp 254-280, 2009.
[10] Zecun Zhou. High voltage technology, China electric power press, pp. 141-166. 2003.
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Thank you!
Q&A