Abstract
This paper includes the study of the various voltage instability problems which occurs due to various reasons which can lead to the system collapse. Voltage stability is the phenomenon which shows the ability of the system to regain its original properties of voltage control after a small disturbance. To maximise wind penetration and the wind energy output, it is necessary to minimise these instability problems. There are various methods to test the voltage instability and correct it, but in this paper, P and Q power of isolated wind turbine farm and wind integrated grid system will be calculated. Most of the wind farm consists of the PMSG which does not provide uniform wind speed so that DFIG is used in this paper to attain the uniform speed and efficient use of the wind speed. The maximum wind power penetration is very crucial to increase the power quality as well as to increase the voltage stability and it is always desirable that the voltage profile is maintained within acceptable levels to ensure stability and reliability of the system and instability issue is solved by placing wind farms by installing various SVCs. The wind farm has been modelled by including a 14 BUS system which can be used to test the system.
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Sharma, T., Singh, O. (2020). Voltage Stability Analysis of Wind Integrated Grid. In: Singh Tomar, G., Chaudhari, N.S., Barbosa, J.L.V., Aghwariya, M.K. (eds) International Conference on Intelligent Computing and Smart Communication 2019. Algorithms for Intelligent Systems. Springer, Singapore. https://doi.org/10.1007/978-981-15-0633-8_89
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DOI: https://doi.org/10.1007/978-981-15-0633-8_89
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