Synchronous modulation strategy for multi-objective optimization of traction converters under five-division frequency operation conditions

JIN Miaoxin; DU Jingrun; FAN Ziyin; XIANG Chaoqun

doi:10.13890/j.issn.1000-128X.2024.02.006

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Synchronous modulation strategy for multi-objective optimization of traction converters under five-division frequency operation conditions

Converting and Control | 更新时间：2024-08-02

- Synchronous modulation strategy for multi-objective optimization of traction converters under five-division frequency operation conditions
- Electric Drive for Locomotives Issue 2, Pages: 51-58(2024)
- 作者机构：
  
  1.重载快捷大功率电力机车全国重点实验室，湖南株洲 412001
  2.中车株洲电力机车有限公司，湖南株洲 412001
  3.中南大学交通运输工程学院，湖南长沙 410075
- 作者简介：
- 基金信息：
- DOI：10.13890/j.issn.1000-128X.2024.02.006
  CLC： U264.3⁺7
- Published：10 March 2024，
  
  Received：07 December 2023，
- 稿件说明：
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金淼鑫, 杜京润, 范子寅, 等. 牵引变流器五分频多目标优化同步调制策略[J]. 机车电传动, 2024(2): 51-58.

JIN Miaoxin, DU Jingrun, FAN Ziyin, et al. Synchronous modulation strategy for multi-objective optimization of traction converters under five-division frequency operation conditions[J]. Electric drive for locomotives,2024(2): 51-58.
金淼鑫, 杜京润, 范子寅, 等. 牵引变流器五分频多目标优化同步调制策略[J]. 机车电传动, 2024(2): 51-58. DOI：10.13890/j.issn.1000-128X.2024.02.006.

JIN Miaoxin, DU Jingrun, FAN Ziyin, et al. Synchronous modulation strategy for multi-objective optimization of traction converters under five-division frequency operation conditions[J]. Electric drive for locomotives,2024(2): 51-58. DOI：10.13890/j.issn.1000-128X.2024.02.006.

摘要

受限于散热条件，为了防止功率器件产生过大的开关损耗，进而减少服役寿命，轨道交通牵引逆变器开关频率通常低于1 kHz。逆变器运行至中、高频区域时，载波比下降导致其输出谐波增加，造成输出性能下降的同时导致电流峰值增大，使得绝缘栅双极晶体管（Insulated-gate Bipolar Transistor，IGBT）产生较大功率损耗，影响行车安全。针对现有低载波比的调制策略较多考虑输出性能的优化，而对IGBT功率损耗抑制考量较少的问题，文章提出一种针对牵引逆变器在五分频下的多目标优化调制策略，保证逆变器输出加权总谐波畸变较小的同时，降低总功率损耗。首先，根据逆变器负载模型建立输出电压与电流的数值与相位关系，根据器件厂商所提供的数据手册，从功率损耗产生机理出发，建立精确的IGBT功率损耗离散计算模型；其次，以逆变器输出电流谐波和功率损耗为优化目标，保证逆变器输出电压基波幅值与参考一致的前提下对开关角进行求解，实现逆变器多目标优化调制的目的。仿真结果表明，在工作区间内，与传统策略相比，所提优化调制策略显著降低了IGBT的功率损耗并保证了较优的输出性能。

Abstract

Restricted by heat dissipation conditions

the switching frequency of the traction inverters for rail transit typically remains below 1 kHz

to prevent potential shortening of their service lifetime due to excessive switching losses in power devices. Inverter operation in the middle and high-frequency ranges results in a decrease in carrier ratio

leading to amplified output harmonics. This not only lowers output performance but also elevates peak current levels

intensifying power losses within the insulated-gate bipolar transistor (IGBT) and consequently undermining driving safety. Unlike existing modulation strategies to address low carrier ratios

which mostly focus on optimizing output performance while overlooking the suppression of IGBT power losses

this paper presents a multi-objective optimization modulation strategy for traction inverters under five-division frequency. This strategy aims to maintain a low weighted total harmonic distortion (WTHD) in the inverter output while reducing total power losses. Firstly

numerical and phase relationships between the output voltage and current were established based on the inverter load model. A precise discrete calculation model for IGBT power losses was developed based on the data manual provided by the device manufacturer

leveraging the power loss generation mechanism. Subsequently

the switching angles were solved under the premise of ensuring the fundamental amplitude of inverter output voltages aligned with the reference level

to enable multi-objective optimization modulation for inverters

including both inverter output current harmonics and power losses as optimization objectives. Simulation results indicate that within the operating range

the proposed optimization modulation strategy significantly reduced IGBT power losses and remained superior output performance compared to traditional strategies.

关键词

变流器功率损耗五分频多目标优化调制加权总谐波畸变开关角

Keywords

converterpower lossfive-division frequencymulti-objective optimization modulationweighted total harmonic distortionswitching angle

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