In an inductive battery charging system,for better power transfer capability and attaining required power level,compensation is necessary.This paper analyzes series/parallel(S/P)and dual side inductorcapacitor-capacit...In an inductive battery charging system,for better power transfer capability and attaining required power level,compensation is necessary.This paper analyzes series/parallel(S/P)and dual side inductorcapacitor-capacitor(LCC)compensation topologies for inductive power transfer of electric vehicle(EV)battery charging system.The design and modeling steps of inductive power transfer for electric vehicle battery charging system are presented.Besides,the equivalent electrical circuits are used to describe the circuit compensation topologies.The results convey that the efficiency of dual side LCC compensation is higher than that of S/P compensation at variable mutual inductance(misalignment).展开更多
文摘In an inductive battery charging system,for better power transfer capability and attaining required power level,compensation is necessary.This paper analyzes series/parallel(S/P)and dual side inductorcapacitor-capacitor(LCC)compensation topologies for inductive power transfer of electric vehicle(EV)battery charging system.The design and modeling steps of inductive power transfer for electric vehicle battery charging system are presented.Besides,the equivalent electrical circuits are used to describe the circuit compensation topologies.The results convey that the efficiency of dual side LCC compensation is higher than that of S/P compensation at variable mutual inductance(misalignment).
