A High-Frequency PCB-Winding Transformer Design with Medium Voltage Insulation for Solid-State Transformer

2023 IEEE Applied Power Electronics Conference and Exposition (APEC) Pub Date : 2023-03-19 DOI:10.1109/APEC43580.2023.10131159

Zheqing Li, Feng Jin, Yi-Hsun Hsieh, Qiang Li

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引用次数: 1

Abstract

A Solid-state transformer directly reduces medium voltage to low voltage (e.g. 400 V) with minimized power conversion stages. Insulation structure is the bottleneck of DC-DC module in SST from insulation effectiveness, manufacturing process, thermal management, and power density point of view. In this paper, a compact PCB-winding transformer structure is proposed to handle the medium voltage insulation by FR4 in PCB-winding. The primary side winding is built in PCB-winding and secondary side winding is still Litz wire for a lower loss. With semi-conductive shielding and stress grading layer design, the E-field can be restrained in the primary side PCB for a partial discharge free insulation. An arc section winding structure is proposed to reduce the high E-field inside the insulation layer to improve insulation performance. The layer-to-layer winding resistance and overall loss/footprint trade-off is analyzed for a low loss design. Finally, the design is demonstrated on an 800/400V, 15-kW, 200-kHz CLLC converter with 98.8% peak efficiency and 130W/in3 power density, whose transformer achieves partial discharge free up to 14.6kV.

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固态变压器中压绝缘高频pcb绕组变压器设计

固态变压器以最小的功率转换阶段直接将中压降低到低电压(例如400 V)。从绝缘效能、制造工艺、热管理和功率密度等方面来看，绝缘结构是SST中DC-DC模块的瓶颈。本文提出了一种紧凑的pcb绕组变压器结构，以解决pcb绕组中FR4的中压绝缘问题。初级侧绕组采用pcb绕组，次级侧绕组仍采用Litz线，损耗较低。采用半导电屏蔽和应力分级层设计，可以抑制初级侧PCB中的e场，实现部分无放电绝缘。为了降低绝缘层内部的高电场，提出了电弧分段绕组结构，以提高绝缘层的绝缘性能。为了实现低损耗设计，分析了层与层之间的绕组电阻和总体损耗/占位权衡。最后，在一个800/400V、15 kw、200 khz、峰值效率98.8%、功率密度130W/in3的CLLC变换器上进行了设计验证，该变换器的变压器在14.6kV下实现了无局部放电。

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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2023 IEEE Applied Power Electronics Conference and Exposition (APEC)

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