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

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

doi:10.1109/OJPEL.2024.3414151

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

Z. Li, R. Mirzadarani, M. Ghaffarian Niasar, M. Itraj, L. van Lieshout, P. Bauer, Z. Qin^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

56 Downloads (Pure)

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.

Original language	English
Pages (from-to)	936 - 955
Number of pages	20
Journal	IEEE Open Journal of Power Electronics
Volume	5
DOIs	https://doi.org/10.1109/OJPEL.2024.3414151
Publication status	Published - 2024

Keywords

Bridge circuits
Frequency conversion
Hydrogen Electrolyzer
Input-Series-Output-Parallel
Insulation
Medium voltage
Modular Multi-level Converter
Power transformer insulation
Rectifiers
Solid-State Transformer
Topology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1109/OJPEL.2024.3414151

Medium-Voltage_Solid-State_Transformer_Design_for_Large-Scale_H2_ElectrolyzersFinal published version, 6.36 MBLicence: CC BY

Cite this

@article{f430f549c3db454f99b79ec72d7ad918,

title = "Medium-Voltage Solid-State Transformer Design for Large-Scale H2 Electrolyzers",

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.",

keywords = "Bridge circuits, Frequency conversion, Hydrogen Electrolyzer, Input-Series-Output-Parallel, Insulation, Medium voltage, Modular Multi-level Converter, Power transformer insulation, Rectifiers, Solid-State Transformer, Topology",

author = "Z. Li and R. Mirzadarani and Niasar, {M. Ghaffarian} and M. Itraj and {van Lieshout}, L. and P. Bauer and Z. Qin",

year = "2024",

doi = "10.1109/OJPEL.2024.3414151",

language = "English",

volume = "5",

pages = "936 -- 955",

journal = "IEEE Open Journal of Power Electronics",

issn = "2644-1314",

publisher = "IEEE",

}

TY - JOUR

T1 - Medium-Voltage Solid-State Transformer Design for Large-Scale H2 Electrolyzers

AU - Li, Z.

AU - Mirzadarani, R.

AU - Niasar, M. Ghaffarian

AU - Itraj, M.

AU - van Lieshout, L.

AU - Bauer, P.

AU - Qin, Z.

PY - 2024

Y1 - 2024

N2 - 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.

AB - 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.

KW - Bridge circuits

KW - Frequency conversion

KW - Hydrogen Electrolyzer

KW - Input-Series-Output-Parallel

KW - Insulation

KW - Medium voltage

KW - Modular Multi-level Converter

KW - Power transformer insulation

KW - Rectifiers

KW - Solid-State Transformer

KW - Topology

UR - http://www.scopus.com/inward/record.url?scp=85196074661&partnerID=8YFLogxK

U2 - 10.1109/OJPEL.2024.3414151

DO - 10.1109/OJPEL.2024.3414151

M3 - Article

AN - SCOPUS:85196074661

SN - 2644-1314

VL - 5

SP - 936

EP - 955

JO - IEEE Open Journal of Power Electronics

JF - IEEE Open Journal of Power Electronics

ER -

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

Abstract

Keywords

UN SDGs

Access to Document

Other files and links

Fingerprint

Flexible Offshore Wind Hydrogen Power Plant Module

Cite this

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

Abstract

Keywords

UN SDGs

Access to Document

Other files and links

Fingerprint

Projects

Flexible Offshore Wind Hydrogen Power Plant Module

Cite this

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