Comparative Evaluation of MVAC-LVDC SST and Hybrid Transformer Concepts for Future Datacenters

2022 International Power Electronics Conference (IPEC-Himeji 2022- ECCE Asia) Pub Date : 2022-05-15 DOI:10.23919/IPEC-Himeji2022-ECCE53331.2022.9807028

J. Huber, P. Wallmeier, Ralf Pieper, F. Schafmeister, J. Kolar

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引用次数: 10

Abstract

A transition from state-of-the-art 400 V AC to 690 V AC or 800 V DC (±400 V DC) distribution improves the overall power conversion efficiency of datacenter power supply systems. The latter requires megawatt-level isolated medium-voltage (MV) AC to low-voltage (LV) DC conversion stages that operate with an efficiency of at least 98 %. Whereas today's most advanced industrial MVAC-LVDC solid-state transformer (SST) prototypes do achieve this, they are highly complex and do not show any clear advantages in terms of efficiency and power density over alternative approaches that retain the low-frequency transformer (LFT) to provide isolation and decoupling from harsh MV grid realities. We thus comparatively evaluate MVAC-LVDC SSTs against such alternative concepts, i.e., LFTs with LV-side SiC PFC rectifiers, or 12-pulse rectifier systems hybridized with active filters that just provide sufficient power processing capability to achieve unity power factor operation.

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未来数据中心MVAC-LVDC SST和混合变压器概念的比较评估

从最先进的400v AC配电过渡到690v AC或800v DC(±400v DC)配电，提高数据中心供电系统的整体功率转换效率。后者需要兆瓦级隔离的中压(MV)交流到低压(LV)直流转换阶段，其工作效率至少为98%。尽管当今最先进的工业MVAC-LVDC固态变压器(SST)原型确实实现了这一点，但它们非常复杂，在效率和功率密度方面，与保留低频变压器(LFT)的替代方法相比，没有显示出任何明显的优势，以提供与恶劣中压电网现实的隔离和解耦。因此，我们将MVAC-LVDC SSTs与这些替代概念进行了比较评估，即LFTs与lv侧SiC PFC整流器，或12脉冲整流器系统与有源滤波器混合，仅提供足够的功率处理能力以实现统一功率因数运行。

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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来源期刊

2022 International Power Electronics Conference (IPEC-Himeji 2022- ECCE Asia)

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