Your search keyword '"high-voltage measuring equipment"' showing total 2 results

1. Semiconductor loss calculation of DC–DC modular multilevel converter for HVDC interconnections

Author

Shanshan Zhao, Yu Chen, and Li Peng

Subjects

voltage measurement, switching convertors, power control, HVDC power transmission, HVDC power convertors, frequency modulation, mathematical analysis, DC-DC power convertors, power transmission control, switching loss, semiconductor loss calculation, high-voltage DC interconnections, high-voltage measuring equipment, conduction loss, DC-DC modular multilevel converter, HVDC interconnections, voltage matching, galvanic isolation, flexible power control, system evaluation, parameter design, offline loss calculation method, DC–DC MMC, fundamental frequency modulation, instantaneous voltage calculation, instantaneous current calculation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Electricity, QC501-721

Abstract

DC–DC modular multilevel converter (DC–DC MMC) is an attractive candidate for high-voltage DC (HVDC) interconnections since it can provide the required voltage matching, galvanic isolation and flexible power control abilities. The semiconductor loss of such a DC–DC MMC is a major concern for both system evaluation and parameter design. However, it cannot be measured directly since it is out of the precision range of the high-voltage measuring equipment, and thus, mathematical analysis is considered as a feasible alternative. This paper proposes an accurate off-line loss calculation method for DC–DC MMC modulated by fundamental frequency modulation. Based on the characteristics of the modulation, the switching moments along with the instantaneous voltage and current can be calculated exactly, and the conduction loss and switching loss of each submodule can be expressed in a mathematical way. The calculation results are compared with the simulation results from a comprehensive switched model and show good accuracy performance within a relative error of ± 2% under different operating conditions.

Published

2018

2. Semiconductor loss calculation of DC–DC modular multilevel converter for HVDC interconnections

Author

Li Peng, Yu Chen, and Shanshan Zhao

Subjects

Computer science, 020209 energy, offline loss calculation method, lcsh:QC501-721, Energy Engineering and Power Technology, 02 engineering and technology, semiconductor loss calculation, HVDC power convertors, mathematical analysis, DC-DC modular multilevel converter, galvanic isolation, switching loss, parameter design, power transmission control, Approximation error, lcsh:Electricity, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, fundamental frequency modulation, DC–DC MMC, Electrical and Electronic Engineering, instantaneous current calculation, switching convertors, high-voltage DC interconnections, business.industry, 020208 electrical & electronic engineering, DC-DC power convertors, Fundamental frequency, HVDC power transmission, Modular design, HVDC interconnections, power control, high-voltage measuring equipment, frequency modulation, flexible power control, system evaluation, Modulation, voltage measurement, conduction loss, lcsh:Electrical engineering. Electronics. Nuclear engineering, voltage matching, business, Galvanic isolation, Frequency modulation, instantaneous voltage calculation, lcsh:TK1-9971, Voltage, Power control

Abstract

DC–DC modular multilevel converter (DC–DC MMC) is an attractive candidate for high-voltage DC (HVDC) interconnections since it can provide the required voltage matching, galvanic isolation and flexible power control abilities. The semiconductor loss of such a DC–DC MMC is a major concern for both system evaluation and parameter design. However, it cannot be measured directly since it is out of the precision range of the high-voltage measuring equipment, and thus, mathematical analysis is considered as a feasible alternative. This paper proposes an accurate off-line loss calculation method for DC–DC MMC modulated by fundamental frequency modulation. Based on the characteristics of the modulation, the switching moments along with the instantaneous voltage and current can be calculated exactly, and the conduction loss and switching loss of each submodule can be expressed in a mathematical way. The calculation results are compared with the simulation results from a comprehensive switched model and show good accuracy performance within a relative error of ± 2% under different operating conditions.

Published

2018