A Shunt DC Electric Spring Control Strategy for MVDC Bus Voltage Stability Onboard AES

IF 0.6 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC
Remna Radhakrishnan, Mariamma Chacko
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Abstract

Background: The recent trend in the all-electric ship (AES) electrical systems, especially in military vessels, is to move towards medium voltage direct current (MVDC) distribution. Bus voltage instability is a major issue in direct current (DC) distribution systems. Nowadays, direct current electric springs (DCES) are extensively used in low-voltage direct current (LVDC) microgrids to address voltage instability issues. This paper extends the use of a shunt DCES to stabilize the bus voltage in an MVDC grid. The work proposes an addition to the MVDC onboard ship distribution system architecture, described in IEEE 1709, by integrating a shunt DCES with a novel control strategy to stabilize the bus voltage under various loading conditions, including propulsion motor (PM) and online pulsed power load (PPL). Method: The shunt DCES is designed to provide current into the MVDC bus, which reduces the bus current ripple to attain a stable bus voltage with reduced ripple. A dual loop control with a battery management system (BMS) is proposed for the shunt DCES and simulated in MATLAB/Simulink. BMS is designed based on the state of charge (SOC) of the battery and bus current ripple extracted from the system's source and load side currents. The current supplied by the shunt DCES and the extracted ripple current validate the effectiveness of the proposed control. Total harmonic distortions (THDs) as a measure of voltage ripple of the MVDC bus voltage at different intervals are measured and compared for both systems, with and without shunt DCES. Result: It was observed that the shunt DCES could reduce the voltage ripple well below the permissible limit, which is 5 % as per IEEE 1709. Conclusion: The proposed control strategy could attain a reduction of 68-85 % in THD under peak to off-peak loading conditions with the addition of shunt DCES.
AES板载MVDC母线电压稳定的并联直流弹簧控制策略
背景:全电船舶(AES)电气系统,特别是军用船舶,目前的趋势是向中压直流(MVDC)配电方向发展。母线电压不稳定是直流配电系统中的一个主要问题。目前,直流电弹簧(DCES)被广泛应用于低压直流(LVDC)微电网中,以解决电压不稳定问题。本文扩展了并联DCES在MVDC电网中稳定母线电压的应用。该工作提出了对IEEE 1709中描述的MVDC船载配电系统架构的补充,通过将并联DCES与一种新的控制策略集成在一起,以稳定各种负载条件下的母线电压,包括推进电机(PM)和在线脉冲功率负载(PPL)。方法:设计分流式dce,为MVDC母线提供电流,减少母线电流纹波,以达到稳定的母线电压,纹波减小。提出了一种带电池管理系统(BMS)的并联DCES双环控制方案,并在MATLAB/Simulink中进行了仿真。BMS是基于电池的荷电状态(SOC)和从系统源侧和负载侧电流中提取的母线电流纹波来设计的。并联dce提供的电流和提取的纹波电流验证了所提控制的有效性。总谐波畸变(THDs)作为MVDC母线电压在不同间隔的电压纹波的测量,并对两个系统进行了测量和比较,有和没有并联dce。结果:观察到并联DCES可以将电压纹波降低到远低于IEEE 1709允许的极限,即5%。结论:在峰非峰负荷条件下,加入分流式dce后,所提出的控制策略可使THD降低68- 85%。
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来源期刊
Recent Advances in Electrical & Electronic Engineering
Recent Advances in Electrical & Electronic Engineering ENGINEERING, ELECTRICAL & ELECTRONIC-
CiteScore
1.70
自引率
16.70%
发文量
101
期刊介绍: Recent Advances in Electrical & Electronic Engineering publishes full-length/mini reviews and research articles, guest edited thematic issues on electrical and electronic engineering and applications. The journal also covers research in fast emerging applications of electrical power supply, electrical systems, power transmission, electromagnetism, motor control process and technologies involved and related to electrical and electronic engineering. The journal is essential reading for all researchers in electrical and electronic engineering science.
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