A Smart Substation Field Secondary Device Testing Technique Based on Recurrence Principle

Abstract

According to the demand of substation secondary device dynamic performance testing, a smart substation field testing technique based on recurrence principle is proposed in the paper, and the characteristics of smart substation secondary device digitization and information sharing are used by the technique. The principle of testing technique is as follow: the digital simulation model is constructed on the basis of the substation’s actual construction, then the simulating data highly similar to substation’s actual electric quantity transient process is generated, at last, the substation digital secondary device can be tested by using data “recurrence” technique. The testing technique is verified and applied by constructing testing system, the application results show that the technique can effectively perform field test on the dynamic performance of digital secondary device, and the technique has good engineering implementation and application value.

Share and Cite:

Zhang, K. , Chen, L. , Xia, Y. , Lei, Y. , Shu, X. , Li, H. , Wang, T. and Du, Z. (2014) A Smart Substation Field Secondary Device Testing Technique Based on Recurrence Principle. Journal of Power and Energy Engineering, 2, 244-251. doi: 10.4236/jpee.2014.24035.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Ye, Y.B. and Chen, S. (2010) Analysis of Successive Trips of Transformer Differential Relay and Bus Differential Relay. Electric Power Automation Equipment, 30, 146-148.
[2] Overman T M, Sackman R W. (2010) High Assurance Smart Grid: Smart Grid Control Systems Communications Architecture. Smart Grid Communications, IEEE International Conference, 19-24.
[3] Mao, P., Duan, Y.Q., Xu, Y., et al. (2006) Realization of Dynamic Detecting Relay in High Voltage Line Protection Devices. Automation of Electric Power Systems, 30, 86-89.
[4] Kuffel, R., Winnipeg, B.C., Giesbrecht, J., Maguire, T. and Wierckx, R.P. (1996) A Fully Digital Power System Simulator Operating in Real Time. Electrical and Computer Engineering, 733-736.
[5] Liang, Z.C., Ma, X.D., Wang, H.X., et al. (1999) Small-Sized Real-Time Digital Simulator for the Test of Protective relay. Automation of Electric Power Systems, 23, 27-30.
[6] Wang, Z., Zhang, M., Sun, L.S., et al. (2001) Research on DSP-Based Digital Test Equipment for Protection Relay by Dynamic Simulation. Electric Power Automation Equipment, 21, 8-10.
[7] Reddy, M.H., Kishor, G., Satheesh, G. and Reddy, T.B. (2012) Digital Simulation of Hybrid PWM Inverter Fed Induction Motor Using Two Inductor Boost Converter. Advances in Engineering, Science and Management (ICAESM), 361-366.
[8] Minami, Y., Yamanaka, N., Imahori, T. and Tanaka, T. (2004) Substation Architecture with Protective Relays Using Digital Instrument Transformers and Digital Interface Technology. Developments in Power System Protection, 810-813.
[9] Feng, J. (2011) Smart Subatation Principle and Testing Technique. China Electric Power Press, Beijing.
[10] Q/GDW 441-2010 (2012) Technical Specifications of Protection for Smart Substation. State Grid Corporation of China, Beijing.
[11] Yue, C.Y., Tian, F., Zhou, X.X., et al. (2006) Principle of Interfaces for Hybrid Simulation of Power System Electromagnetic-Electromechanical Transient Process. Power System Technology, 30, 23-27.
[12] Dube, B., Varennes, Q., Lefebvre, S., Perocheau, A. and Nakra, H.L. (1988) Comparative Hybrid and Digital Simulation Studies of the Behaviour of a Wind Generator Equipped with a Static Frequency Converter. Electrical Engineering Journal, 39-44.
[13] Zhu, X.K., Zhou, X.X., Tian, F., et al. (2011) Hybrid Electromechanical-Electromagnetic Simulation to Transient Process of Large-Scale Power Grid on the Basis of ADPSS. Power System Technology, 35, 26-31.
[14] Zhao, W.G. and Ren, X.Y. (2010) Time Synchronization with IRIG-B Code in Smart Electronic Devices. Automation of Electric Power Systems, 34, 113-115.
[15] Shi, X.H., Gao, H.L., Xiang, M.J., et al. (2011) Application of IEEE1588 Time Synchronization Protocol in Digital Substation. Electric Power Automation Equipment, 31, 132-135.

Copyright © 2021 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.