Oscillations of a Wind Power Plant with Several Moving Masses Using the Galloping Effect

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Abstract

We consider a chain of several bodies that can move translationally along a horizontal line. The neighboring bodies are connected to each other by springs. One end of the chain is fixed, and on the other there is a body, which is a rectangular parallelepiped of a square section. The system is placed in a horizontal stationary medium flow perpendicular to the specified straight line. Under the assumption that the flow affects only the parallelepiped, the dynamics of this system are studied as a potential working element of an oscillatory wind power plant using the galloping effect. For a different number of bodies in a chain, different values of flow velocity and external load, periodic regimes in the system are studied. It is shown, in particular, that an increase in the number of bodies in a chain makes it possible to increase the maximum power that can be obtained using the device and to reduce the critical speed at which oscillations occur. A scheme for regulating the load resistance is proposed, aimed at ensuring the transition to an oscillatory mode with maximum power.

About the authors

B. Ya. Lokshin

Institute of Mechanics, Lomonosov Moscow State University, Moscow, Russia

Email: seliutski@imec.msu.ru
Россия, Москва

Yu. D. Selyutskiy

Institute of Mechanics, Lomonosov Moscow State University, Moscow, Russia

Author for correspondence.
Email: seliutski@imec.msu.ru
Россия, Москва

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