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A Voltage Stability-Based Approach to Determining the Maximum Size of Wind Farms in Power Systems
Author(s) -
Giulio Lorenzini,
Mehrdad Ahmadi Kamarposhti,
Ahmed A. A. Solyman
Publication year - 2021
Publication title -
international journal of design and nature and ecodynamics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.193
H-Index - 13
eISSN - 1755-7445
pISSN - 1755-7437
DOI - 10.18280/ijdne.160301
Subject(s) - wind power , installation , electric power system , wind speed , voltage , power optimizer , power (physics) , electrical engineering , engineering , control theory (sociology) , automotive engineering , environmental science , marine engineering , computer science , meteorology , maximum power point tracking , geography , mechanical engineering , physics , control (management) , quantum mechanics , inverter , artificial intelligence
Current methods to determine the wind farms maximum size do not consider the effect of new wind generation on the Voltage Stability Margins (VSMs). Installing wind power in one area may affect VSMs in other areas of the power system. Buses with high VSMs before wind power injection may be converted into weak buses after wind power injections in other parts of power systems, which may lead to limited future wind farms expansion in other areas. In this paper, two methods are proposed to determine two new wind farms maximum size in order to maximize wind power penetration level. In both methods, the size of any new wind farm is determined using an iterative process which is increased by a constant value. Proposed methods were used in the IEEE 14-bus power system. The results of applying these new methods indicate that the second method results in higher maximum sizes than the first method.