Medium-Voltage Solid-State Transformer Design for Large-Scale H2 Electrolyzers

IF 5 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of power electronics Pub Date : 2024-06-13 DOI:10.1109/OJPEL.2024.3414151

Z. Li;R. Mirzadarani;M. Ghaffarian Niasar;M. Itraj;L. van Lieshout;P. Bauer;Z. Qin

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Abstract

In the production of green hydrogen, electrolyzers draw power from renewable energy sources. In this paper, the design of Solid State Transformer (SST) for large-scale H ₂ electrolyzers is benchmarked. The three most promising topologies are chosen for design and comparison, including Modular Multi-level Converter (MMC) based SST, Modular Multi-level Resonant (MMR) based SST, and Input-Series-Output-Parallel (ISOP) based SST. The distance between converter towers for insulation and maintenance, the insulation system of the transformer, and the cooling system are designed with practical considerations in order to have an accurate estimation of the volume and weight of the SST. Losses in the switches are calculated based on equations, and losses in passive components are calculated based on FEM simulation. The operating frequency for each topology is optimized to minimize loss, weight, and volume. The best of each topology is then compared with each other to identify the most suitable one for large-scale H ₂ electrolyzers.

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用于大型 H2 电解槽的中压固态变压器设计

在生产绿色氢气的过程中，电解槽从可再生能源中获取电能。本文对用于大规模氢气电解槽的固态变压器（SST）的设计进行了基准测试。本文选择了三种最有前途的拓扑结构进行设计和比较，包括基于模块化多电平转换器（MMC）的 SST、基于模块化多电平谐振（MMR）的 SST 和基于输入-串联-输出-并联（ISOP）的 SST。为了准确估算 SST 的体积和重量，我们在设计时实际考虑了用于绝缘和维护的变流器塔之间的距离、变压器的绝缘系统和冷却系统。开关的损耗根据方程式计算，无源元件的损耗根据有限元模拟计算。对每种拓扑结构的工作频率进行优化，以尽量减少损耗、重量和体积。然后对每种拓扑结构的最佳结果进行比较，以确定最适合大规模 H2 电解槽的拓扑结构。

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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