The Irremovable Properties Proof of Decaying DC Component for Dynamic Phasor Measurement

Hai Bao; Jin Si Han; Shu De Zhang; Yu Long Chen

doi:10.4028/www.scientific.net/AMR.986-987.1611

Paper Titles

Study on a New Test and Diagnosis Method for Complex Integrated Circuit
p.1591

Synchronization Optimization Simulation of Optical Fiber Network Fault Features and Model Parameters
p.1596

The Analysis of Device Model in CMOS Integrated Temperature Sensor
p.1600

The Design and Analysis of Substation Equipment Temperature Wireless Monitoring System
p.1606

The Irremovable Properties Proof of Decaying DC Component for Dynamic Phasor Measurement
p.1611

The Research and Simulation of Intelligent Electric Leakage Detection Model for Mining Machinery
p.1616

The Research on the Factory Accept Test Technology of Subsea PLET
p.1619

The Research on the Integrational Measurement Device of Grounding Resistance
p.1624

Videogrammetric Techniques for Wind Tunnel Testing and Applications
p.1629

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 986-987The Irremovable Properties Proof of Decaying DC...

The Irremovable Properties Proof of Decaying DC Component for Dynamic Phasor Measurement

Abstract:

Dynamic voltage can be described by two parts in time domain, sinusoidal steady state component and dynamic state component. The latter reflects the effect of the system’s characteristic root, and is also called decaying DC component. Decaying exponential signal has continuous spectrum, and this characteristic has a bad effect on the accuracy of phase angle’s measurement, therefore the idea of filtering the decaying exponential signal was proposed. To verify the possibility of this proposal, this paper analyzes the frequency formation of dynamic voltage signal mathematically, and points out that at the frequency of the sinusoidal component, measured voltage signal’s time domain description is the superposition of two sinusoidal signals with the same frequency, different phase angles and different amplitudes. This is the reason for the deviation between the measured voltage angle and the theoretical phase angle. The deviation angle not only shows the combined action of steady component and dynamic component, but also illustrates that the decaying exponential signal cannot be filtered out.

You might also be interested in these eBooks

Energy Research and Power Engineering 2014

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 986-987)

Pages:

1611-1615

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.986-987.1611

Citation:

Cite this paper

Online since:

July 2014

Authors:

Hai Bao*, Jin Si Han, Shu De Zhang, Yu Long Chen

Keywords:

Dynamic Grid, Frequency Characteristic, Phasor Measurement, Proof, Wide-Area Measurement System (WAMS)

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Phadke, J. Thorp. Synchronized phasor measurements and their applications [M]. NY. USA: Springer. (2008).

Google Scholar

[2] He Zhiqin, Zhang Zhe, Yin Xianggen, Wang Hua. A novel wide area backup protection algorithm based on fault voltage comparison [J]. TRANSACTIONS OF CHINA ELECTROTECHNICAL SOCIETY, 2012 27 (7) 274-283.

DOI: 10.1109/tpwrd.2013.2247638

Google Scholar

[3] DUAN Jun-dong, GUO Zhi-zhong. On-line assessment of voltage stability of power system based on wide-area measurement system [J]. Relay, 2006 34 (15) 24-28.

Google Scholar

[4] Gu Wei, Wan Qiulan. Linearized voltage stability index for wide-area voltage monitoring and control [J]. TRANSACTIONS OF CHINA ELECTROTECHNICAL SOCIETY, 2010 25 (6) 110-115.

Google Scholar

[5] Li Zhenxing, Yin Xianggen, Zhang Zhe, He Zhiqing. A study of wide-area protection algorithm based on integrated impedance comparison [J]. TRANSACTIONS OF CHINA ELECTROTE- -CHNICAL SOCIETY, 2012 27 (8) 179-186.

DOI: 10.1109/tpwrd.2013.2247638

Google Scholar

[6] Gan Lei, Kang Hewen, He Min. The dynamic monitoring of voltage stability based on wide-area measurement system [J]. Power System Protection and Control, 2010 38 (21) 152-161.

Google Scholar

[7] Hou Wang-bin, Liu Tian-qi, Li Xing-yuan. Under-frequency load shedding based on comprehensive weight and wide area measurement system [J]. Power System Protection and Control, 2011 39 (21) 70-75.

Google Scholar

[8] Yang Guiyu, Jiang Daozhuo, Qiu Jiaju. Synchronous measurement precision of phasor measurement unit [J]. Automation of Electric Power Systems, 2003 27 (14) 57-61.

Google Scholar

[9] Jiang Daozhuo, Ma Jin, Zhang Xinjie. The application of phase locked loop in the data acquisition and control apparatus of power system [J]. Relay, 2000 28 (8) 43-45.

Google Scholar

[10] Wang Mao-hai, Bao Jie, Qi Xia, Xu Zheng-shan, Guo Zi-ming. Online assessment of phasor measurement unit's performance based on sample data [J]. Power System Protection and Control, 2009 37 (10) 48-52.

Google Scholar

[11] IEEE working group reports. Synchronized Sampling and Phasor measurements for relaying and control [R]. IEEE Trans. On PWRD. 1994 9 (1) 442-449.

Google Scholar

[12] Burnett Jr R O, Butts M M, Cease T W, et al. Synchronized Phasor Measurement of a power system event [J]. IEEE Trans. On PWRD 1994 9 (3) 1643-1649.

DOI: 10.1109/59.336093

Google Scholar

[13] Mai Ruikun, He Wen, He Zhengyou, Bo Zhiqian, Qian Qingquan. Dynamic phasor estimator with removing decaying DC component [J]. Proceedings of the CSEE, 2010, 30(31): 123-128.

Google Scholar