Technique for Voltage Control in Distribution System
This paper presents the techniques for voltage control in distribution system. It is integrated in the distribution management system. Voltage is an important parameter for the control of electrical power systems. The distribution network operators have the responsibility to regulate the voltage supplied to consumer within statutory limits. Traditionally, the On-Load Tap Changer (OLTC) transformer equipped with automatic voltage control (AVC) relays is the most popular and effective voltage control device. A static synchronous compensator (STATCOM) may be equipped with several controllers to perform multiple control functions. Static Var Compensation (SVC) is regulation slopes and available margins for var dispatch. The voltage control in distribution networks is established as a centralized analytical function in this paper.
[1] C. Gao, and M. A. Redfern. “A review of voltage control techniques of
network with distributed generations using on-load tab changer
transformers, 45th Universities Power Engineering Conference (UPEC),
2010.
[2] P. M. S. Carvalho, pedro F. P. Correia, and L. A. F. Ferreira,
“Distributed reactive power generation control for voltage rise
mitigation in distribution networks,” IEEE Transaction on Power
System, vol. 23, no. 2, May. 2008.
[3] Z. Dong, et al., “Capacitor switching and network reconfiguration for
loss reduction in distribution system,” in Proc Power Engineering
Society General Meeting Conf., pp. 1-6, 2006.
[4] C. T. Su, and C. S. Lee, “Modified differential evolution method for
capacitor placement of distribution systems,” in Proc. Transmissions and
Distribution Conf., pp. 208-213, 2002.
[5] Yuan-Yin Hsu, and Wah-Chun Chan, “Coordinate frequency and
voltage control of synchronous generation,” IEEE Transaction on
aerospace and Electronic System, vol. 23, no. 1, Jan. 1987.
[6] A. R. Hason, T. S. Martis, and A. H. M. Sadrul, “Design and
implementation of fuzzy controller based automatic voltage regulator for
a synchronous generation,” IEEE Transaction on Energy Conversion,
vol. 9, no. 3, Sept. 1994.
[7] P. Chiradeja, R. Ramakumar, “An approach to quantify the technical
benefits of distributed generation,” IEEE Trans Energy Conversion, vol.
19, no. 4, pp. 764-773, 2004.
[8] H. A. Gil and G. Joos, “Models for quantifying the economic benefits of
distributed generation,” IEEE Transaction on Power Systems, vol. 23,
no. 2, pp. 327-335, May. 2008.
[9] M. P. Lalitha, et al., “Optimal DG placement for minimum real power
loss in radial distribution systems using PSO,” Journal of Theoretical
and Applied Information Technology, pp. 107-116, 2010.
[10] K. Tanaka, M. oshiro, S. Toma, A. Yona, and C. H. Kim, “Decentralised
control of voltage in distribution systems by distributed generation,” IET
Gener. Transm. Distrib., vol. 4, no. 11, pp. 1251-1260, 2010.
[11] A. Hajizadeh, and M. A. Golkar, “Intelligent robust control of hybrid
distributed generation system under voltage sag,” Expert systems with
applications, vol. 37, issue 12, pp. 7627-7638, Dec. 2010. [12] H. F. Wang. “Interaction and multivariable design of STATCOM AC
and DC voltage control.” Electrical power energy system, vol. 25, no. 5,
pp. 387–394, Jan. 2003.
[13] L. Shenghu, M. Ding, J. Wang, and W. Zhang, “Voltage control
capability of SVC with var dispatch and slopesetting,” Electrical power
energy system, vol. 79, issue 5, pp. 818–825, May. 2009.
[14] S. K. Tso, J. Liang, and X. X. Zhou, “Coodinate of TCSC and SVC for
improvement of power system performance with NN-base parameter
adaptation,” International Journal of electrical power and energy
systems, vol. 21, issue 4, pp. 235 – 244, May 1999.
[15] P. C. Srivastava, A. Ghosh, and S. V. J. Kumar, “Model - base control
design of a TCSC-compensate pwer system,” International Journal of
electrical power and energy systems, vol. 21, no. 4, pp. 299 – 307, May
1999.
[1] C. Gao, and M. A. Redfern. “A review of voltage control techniques of
network with distributed generations using on-load tab changer
transformers, 45th Universities Power Engineering Conference (UPEC),
2010.
[2] P. M. S. Carvalho, pedro F. P. Correia, and L. A. F. Ferreira,
“Distributed reactive power generation control for voltage rise
mitigation in distribution networks,” IEEE Transaction on Power
System, vol. 23, no. 2, May. 2008.
[3] Z. Dong, et al., “Capacitor switching and network reconfiguration for
loss reduction in distribution system,” in Proc Power Engineering
Society General Meeting Conf., pp. 1-6, 2006.
[4] C. T. Su, and C. S. Lee, “Modified differential evolution method for
capacitor placement of distribution systems,” in Proc. Transmissions and
Distribution Conf., pp. 208-213, 2002.
[5] Yuan-Yin Hsu, and Wah-Chun Chan, “Coordinate frequency and
voltage control of synchronous generation,” IEEE Transaction on
aerospace and Electronic System, vol. 23, no. 1, Jan. 1987.
[6] A. R. Hason, T. S. Martis, and A. H. M. Sadrul, “Design and
implementation of fuzzy controller based automatic voltage regulator for
a synchronous generation,” IEEE Transaction on Energy Conversion,
vol. 9, no. 3, Sept. 1994.
[7] P. Chiradeja, R. Ramakumar, “An approach to quantify the technical
benefits of distributed generation,” IEEE Trans Energy Conversion, vol.
19, no. 4, pp. 764-773, 2004.
[8] H. A. Gil and G. Joos, “Models for quantifying the economic benefits of
distributed generation,” IEEE Transaction on Power Systems, vol. 23,
no. 2, pp. 327-335, May. 2008.
[9] M. P. Lalitha, et al., “Optimal DG placement for minimum real power
loss in radial distribution systems using PSO,” Journal of Theoretical
and Applied Information Technology, pp. 107-116, 2010.
[10] K. Tanaka, M. oshiro, S. Toma, A. Yona, and C. H. Kim, “Decentralised
control of voltage in distribution systems by distributed generation,” IET
Gener. Transm. Distrib., vol. 4, no. 11, pp. 1251-1260, 2010.
[11] A. Hajizadeh, and M. A. Golkar, “Intelligent robust control of hybrid
distributed generation system under voltage sag,” Expert systems with
applications, vol. 37, issue 12, pp. 7627-7638, Dec. 2010. [12] H. F. Wang. “Interaction and multivariable design of STATCOM AC
and DC voltage control.” Electrical power energy system, vol. 25, no. 5,
pp. 387–394, Jan. 2003.
[13] L. Shenghu, M. Ding, J. Wang, and W. Zhang, “Voltage control
capability of SVC with var dispatch and slopesetting,” Electrical power
energy system, vol. 79, issue 5, pp. 818–825, May. 2009.
[14] S. K. Tso, J. Liang, and X. X. Zhou, “Coodinate of TCSC and SVC for
improvement of power system performance with NN-base parameter
adaptation,” International Journal of electrical power and energy
systems, vol. 21, issue 4, pp. 235 – 244, May 1999.
[15] P. C. Srivastava, A. Ghosh, and S. V. J. Kumar, “Model - base control
design of a TCSC-compensate pwer system,” International Journal of
electrical power and energy systems, vol. 21, no. 4, pp. 299 – 307, May
1999.
@article{"International Journal of Electrical, Electronic and Communication Sciences:65382", author = "S. Thongkeaw and M. Boonthienthong", title = "Technique for Voltage Control in Distribution System", abstract = "This paper presents the techniques for voltage control in distribution system. It is integrated in the distribution management system. Voltage is an important parameter for the control of electrical power systems. The distribution network operators have the responsibility to regulate the voltage supplied to consumer within statutory limits. Traditionally, the On-Load Tap Changer (OLTC) transformer equipped with automatic voltage control (AVC) relays is the most popular and effective voltage control device. A static synchronous compensator (STATCOM) may be equipped with several controllers to perform multiple control functions. Static Var Compensation (SVC) is regulation slopes and available margins for var dispatch. The voltage control in distribution networks is established as a centralized analytical function in this paper.
", keywords = "Voltage Control, Reactive Power, Distribution System.", volume = "7", number = "10", pages = "1333-4", }
