DocumentCode
902366
Title
Voltage sag detection technique for a dynamic voltage restorer
Author
Fitzer, Chris ; Barnes, Mike ; Green, Peter
Author_Institution
Dept. of Electr. Eng. & Electron., Univ. of Manchester Inst. of Sci. & Technol., UK
Volume
40
Issue
1
fYear
2004
Firstpage
203
Lastpage
212
Abstract
Dynamic voltage restorers (DVRs) are used to protect sensitive loads from the effects of voltage sags on the distribution feeder. This paper presents and verifies a novel voltage sag detection technique for use in conjunction with the main control system of a DVR. In all cases it is necessary for the DVR control system to not only detect the start and end of a voltage sag but also to determine the sag depth and any associated phase shift. The DVR, which is placed in series with a sensitive load, must be able to respond quickly to a voltage sag if end users of sensitive equipment are to experience no voltage sags. A problem arises when fast evaluation of the sag depth and phase shift is required, as this information is normally embedded within the core of a main DVR control scheme and is not readily available to either users monitoring the state of the grid or parallel controllers. Previous research presented an additional controller, which required phase and sag depth information to manipulate the injection voltage vector returned by the main controller in order to prevent the DVR injection transformers from saturating. Typical standard information tracking or detection methods such as the Fourier transform or phase-locked loop (PLL) are too slow in returning this information, when either applied to the injection voltage vector, or to the supply voltages directly. As a result of this the voltage sag detection method in this paper proposes a new matrix method, which is able to compute the phase shift and voltage reduction of the supply voltage much quicker than the Fourier transform or a PLL. The paper also illustrates that the matrix method returns results that can be directly interpreted, whereas other methods such as the wavelet transform return results that can be difficult to interpret.
Keywords
electric potential; matrix algebra; voltage control; voltage regulators; distribution feeder; dynamic voltage restorer; injection transformer; injection voltage sector; numerical matrix method; parallel controllers; phase shift; sag depth; voltage sag detection; wavelet transform; Control systems; Fourier transforms; Monitoring; Phase detection; Phase locked loops; Power quality; Protection; Transformers; Voltage control; Voltage fluctuations;
fLanguage
English
Journal_Title
Industry Applications, IEEE Transactions on
Publisher
ieee
ISSN
0093-9994
Type
jour
DOI
10.1109/TIA.2003.821801
Filename
1268198
Link To Document