Your search keyword '"Chenxiang Gao"' showing total 4 results

1. Hierarchical Modeling Scheme for High-Speed Electromagnetic Transient Simulations of Power Electronic Transformers

Author

Chengyong Zhao, Ding Jiangping, Hui Ding, Chenxiang Gao, Jianzhong Xu, and Feng Moke

Subjects

Admittance, Computer science, 020208 electrical & electronic engineering, 02 engineering and technology, Admittance parameters, law.invention, Electric power system, Electromagnetic coil, law, Power electronics, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Transient (oscillation), Electrical and Electronic Engineering, Transformer

Abstract

The extensive application of the power electronic transformers (PETs) in power systems poses a challenge as the accurate and high-speed electromagnetic transient (EMT) simulation of PET has been a critical issue. The computational time of the detailed EMT simulation of PET on EMT programs is unacceptable due to the large electrical node count, microsecond-range simulation steps, and high switching frequency of the devices and transformers. This article proposes a hierarchical modeling scheme for PET. Unlike the existing modeling methods, the proposed technique recursively decreases the dimension order of the admittance matrix to obtain the generalized Norton equivalent of each phase leg. The final admittance matrix overlaid onto the external system admittance matrix has a dimension order of magnitude remarkably smaller than that of the unreduced structure. By comparison with a detailed EMT model of a medium-voltage dc system, the performance of the proposed scheme has been assessed in PSCAD/EMTDC under various working conditions. With negligible loss of accuracy, approximately one to two orders of magnitude speedup over a straightforward EMT program is achieved.

Published

2021

2. Accelerated electromagnetic transient (EMT) equivalent model of solid-state transformer

Author

Chengyong Zhao, Ding Jiangping, Gen Li, Hang Zhang, Zixin Li, Chenxiang Gao, Jianzhong Xu, and Feng Moke

Subjects

Admittance, Computer science, business.industry, Energy Engineering and Power Technology, Topology (electrical circuits), Modular design, Admittance parameters, law.invention, Control theory, law, Transient (oscillation), Electrical and Electronic Engineering, business, Transformer, Equivalence (measure theory), Order of magnitude

Abstract

Accurate and efficient electromagnetic transient (EMT) simulation of various types of solid-state transformers (SST) is extremely time-consuming due to the complex module structure, flexible topology connections, large number of electrical nodes and simulation time-steps limited in the range of micro-seconds. Therefore, it is urgent to develop the EMT equivalent modelling and fast simulation of SSTs for system level studies. Taking the modular multilevel converter (MMC) based SST as an example, this paper proposes an accelerated EMT model which focuses on the equivalence of the dual active bridge (DAB) based high-frequency link (HFL) in the SST. Compared with the existing algorithms, two critical factors of the proposed method that contribute the most to the efficiency improvement are the preprocessing of the nodal admittance equation and the conversion of the short-circuit admittance parameters. The proposed model is verified in PSCAD/EMTDC by comparing it with the detailed EMT model. The results show that the accelerated model is one to two orders of magnitude faster than the detailed model without sacrificing the accuracy. The experiment validation also confirms the validity of the proposed model.

Published

2021

3. High-Speed Modeling Architecture for Fast EMT Simulation of Power Electronic Transformers

Author

Jianzhong Xu, Chengyong Zhao, Chenxiang Gao, Feng Moke, and Ding Jiangping

Subjects

Admittance, Speedup, Computer science, law, Orders of magnitude (temperature), Norton's theorem, Transient (oscillation), Transformer, Topology, Power (physics), law.invention, Admittance parameters

Abstract

This paper proposes a high-speed modeling architecture for fast electromagnetic transient (EMT) simulation of PETs. Unlike the existing modeling methods, the proposed technique recursively decreases the dimension order of the admittance matrix to obtain the generalized Norton equivalent of each phase leg. The final admittance matrix overlaid onto the external system admittance matrix has a dimension orders of magnitude remarkably smaller than that of the unreduced structure. By comparison with a detailed EMT model of a medium-voltage dc (MVDC) grid, the performance of the proposed scheme has been assessed in PSCAD/EMTDC under various working conditions. With negligible loss of accuracy, approximately one to two orders of magnitude speedup over a straightforward EMT program is achieved.

Published

2020

4. Enhanced Equivalent Model of MMC-Based Power Electronic Transformer

Author

Jianzhong Xu, Ding Jiangping, Feng Moke, Chenxiang Gao, and Chengyong Zhao

Subjects

Electric power system, Admittance, Computer science, law, Power electronics, Electronic engineering, Equivalent circuit, Topology (electrical circuits), Transient (oscillation), Transformer, Admittance parameters, law.invention

Abstract

Accurate and efficient electromagnetic transient (EMT) simulation of various types of power electronic transformers (PET) is extremely time consuming due to the complex module structure, flexible topology connections, large electrical node count and microsecond-range simulation time-steps. Therefore, the EMT equivalent modelling and fast simulation of PET topologies face very urgent needs for research and practical development. Taking the modular multilevel converter (MMC) based PET as an example, this paper proposes an enhanced EMT model which focuses on the equivalence of the dual active bridge (DAB) based DC/DC converter in the PET. Two critical factors of the proposed method that contribute the most to the efficiency improvement are the preprocessing of nodal admittance equation and the conversion of the short-circuit admittance parameters. The proposed model is verified in PSCAD/EMTDC by comparing with the detailed EMT model. The results show that the accelerated model is one to two orders of magnitude faster than the detailed model with negligible loss of accuracy.

Published

2020