Efficient Design for Implantable Device Constant Current Induction Doubly Fed Generating Incorporating Grid Connectivity

Abstract

This research presents an innovative approach to the efficient design of implantable devices, focusing on the development and modeling of a constant current induction doubly fed generator (DFIG) system that incorporates grid connectivity under both sub and hyper synchronization conditions. The core of this study is to establish a physical equation for a power station and a DFIG using a combination of power management and voltage estimation techniques in the context of circuit power. The induction generator (IG) blade in the system is designed to rotate synchronously with the photovoltaic (PV) system frequency. The DFIG is connected to a distribution substation, with synchronization between the active power filter and the grid depot achieved through the use of dual converters: a machine side converter (MSC) on the grid side and a grid side converter (GSC) on the power system. Within the circuits, two applications are implemented to recover the parameter spectrum, aiming to maximize the thermodynamic efficiency delivered to the DFIG rotor.