Current Sensorless ZPA Frequency Tracking Control of IPT System with LCCL-S Topology

机译：具有LCCL-S拓扑的IPT系统的无电流ZPA频率跟踪控制

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Inductive power transfer (IPT) systems for electric vehicles (EVs) should apply zero-phase angle (ZPA) frequency control methods for achieving low VA rating and high efficiency. In order to apply ZPA frequency control, current sensors are needed in previous studies. However, these sensors have several problems using for ZPA frequency control such as switching noise, degrading control performance, control complexity, and so on. Therefore, this paper proposes the simpler control method without current sensor for ZPA frequency tracking with LCCL-S topology of IPT systems. The optimal design point is also deducted to apply the proposed control. A simulation and an experiment of 3.3-kW IPT system are performed to verify the proposed control.

机译：电动汽车（EV）的感应功率传输（IPT）系统应采用零相角（ZPA）频率控制方法，以实现低VA额定值和高效率。为了应用ZPA频率控制，以前的研究中需要电流传感器。但是，这些传感器在用于ZPA频率控制时会遇到一些问题，例如开关噪声，控制性能下降，控制复杂性等。因此，本文针对IPT系统的LCCL-S拓扑，提出了一种无需电流传感器的简单控制方法，即可进行ZPA频率跟踪。最佳设计点也被扣除以应用建议的控制。进行了3.3 kW IPT系统的仿真和实验，以验证所提出的控制。

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来源
《2019 10th International Conference on Power Electronics and ECCE Asia》|2019年|1-6|共6页
会议地点 Busan(KR)
作者
Jongeun Byun; Won-Jin Son; Jae Han Lee; Sangjoon Ann; Byoung Kuk Lee;
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作者单位

Sungkyunkwan University, Suwon, South Korea;

Sungkyunkwan University, Suwon, South Korea;

Sungkyunkwan University, Suwon, South Korea;

Sungkyunkwan University, Suwon, South Korea;

Sungkyunkwan University, Suwon, South Korea;

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原文格式 PDF
正文语种 eng
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关键词
inductive power transfer system; current sensorless; frequency tracking control; zero phase angle;

机译：感应功率传输系统;无电流传感器;频率跟踪控制;零相位角;;

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Current Sensorless ZPA Frequency Tracking Control of IPT System with LCCL-S Topology

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