A Dual-Active-Bridge With Half-Bridge Submodules DC Solid-State Transformer for DC Distribution Networks

High-frequency dc solid-state transformer (DCSST) plays an important role in DC bus connection, voltage conversion, electrical isolation, and bidirectional power transmission in dc distribution networks. In various DSSCT topologies, the dual-active-bridge (DAB) scheme becomes a typical solution for DCSST due to its various advantages. However, the DAB scheme still has drawbacks during practical applications. In this article, a DAB with half-bridge submodules (HSDAB) is proposed. By replacing the switches in front bridge arm with half-bridge submodules (SMs), the proposed HSDAB scheme maintains the advantages of conventional DAB and obtains bidirectional dc fault-handling capability, reducing the application of large dc capacitors and dc circuit breaker; therefore, the volume and construction cost of DCSST can be effectively reduced. Besides, a high-frequency-link (HFL) voltage regulation strategy for HSDAB is also proposed in this article. The HFL voltages can be adjusted to match the HFL transformer voltage ratio during the whole operating range, reducing the current stress, HFL reactive power, and power loss of DCSST. Moreover, the proposed HSDAB scheme can also be applied as a basic circuit to establish multiple modular architecture DCSST, flexibly connecting low-voltage dc, medium-voltage dc, and high-voltage dc buses in the dc distribution network. The topology, operation principle, control structure, corresponding bidirectional dc fault handling, and HFL voltage regulation strategy of the proposed HSDAB scheme are investigated. The experimental results verify the correctness and effectiveness of the analysis and proposed scheme.

Automated summary

This article proposes a DAB with half-bridge submodules (HSDAB) to reduce the volume and construction cost of DCSST, and to provide bidirectional dc fault-handling capability. Additionally, a high-frequency-link (HFL) voltage regulation strategy for HSDAB is introduced to reduce the current stress, HFL reactive power, and power loss of DCSST.