Optimal LLC Converter Design With Topology Morphing Control for Wide Voltage Range Battery Charging Applications

IF 5 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE open journal of power electronics Pub Date : 2024-08-16 DOI:10.1109/OJPEL.2024.3444775
Guvanthi Abeysinghe Mudiyanselage;Kyle Kozielski;Ali Emadi
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Abstract

LLC converters benefit from soft switching and sinusoidal currents over dual active bridge (DAB) converters. The design process of an LLC converter involves the selection of resonant tank inductor, capacitor, magnetizing inductance, resonant frequency, and transformer turns ratio for proper operation within the desired range of voltages and power. However, the design and control of frequency-modulated LLC converters in wide voltage range applications is challenging due to the wide range of switching frequencies. Topology morphing control is an established technique utilized for countering the challenges of wide voltage range LLC operation. This work provides a design framework for an LLC converter with topology morphing for wide voltage range applications. The proposed design framework uses time domain analysis and a power loss model to evaluate the optimal converter parameters for efficiency maximization over the entire voltage range. Methodology of implementing online topology morphing with closed-loop control in a digital signal processor (DSP) considering an on-board battery charger (OBC) application is also provided. The design optimization process and control methodology are validated through a 300–700 V input, 250–450 V output, 3.3 kW hardware demonstrator. An experimental peak efficiency of 97.72% is achieved compared to a calculated 97.63% efficiency, proving the accuracy of the analytical model. Time weighted averaged efficiency above 96.7% is observed over the entire voltage range.
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针对宽电压范围电池充电应用的拓扑变形控制优化 LLC 转换器设计
与双有源桥(DAB)转换器相比,LLC 转换器具有软开关和正弦电流的优点。LLC 转换器的设计过程包括选择谐振槽电感器、电容器、磁化电感、谐振频率和变压器匝数比,以便在所需电压和功率范围内正常运行。然而,由于开关频率范围较宽,在宽电压范围应用中设计和控制频率调制 LLC 转换器极具挑战性。拓扑变形控制是应对宽电压范围 LLC 运行挑战的一种成熟技术。本研究为宽电压范围应用中具有拓扑变形功能的 LLC 转换器提供了一个设计框架。所提出的设计框架采用时域分析和功率损耗模型来评估最佳转换器参数,从而在整个电压范围内实现效率最大化。考虑到车载电池充电器(OBC)的应用,还提供了在数字信号处理器(DSP)中实现在线拓扑变形和闭环控制的方法。通过一个输入电压为 300-700 V、输出电压为 250-450 V、功率为 3.3 kW 的硬件演示器,验证了设计优化过程和控制方法。实验峰值效率为 97.72%,而计算效率为 97.63%,证明了分析模型的准确性。在整个电压范围内观察到的时间加权平均效率高于 96.7%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
8.60
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0.00%
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审稿时长
8 weeks
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