配电系统中动态电容器配置以减轻灾害:一种模糊方法

2019 International Conference on Power Electronics, Control and Automation (ICPECA) Pub Date : 2019-11-01 DOI:10.1109/ICPECA47973.2019.8975493

Shyam Mohan Parashar, L. G, M. Pande, Zaheeruddin, Jagvir Singh

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引用次数: 3

摘要

所采用的方法是基于模糊逻辑控制技术作为一种模糊推理算法。这项工作的重点是电容器的放置和尺寸，以保持电压分布和节省电力，精确有效地控制无功功率。FLC技术对于提高电能质量和节省电能是非常有用的。FLC用于寻找电容器的最佳位置和尺寸。该方案在IEEE 14总线系统上进行了测试，并对有功、无功质量和节电的电压分布进行了数据分析。考虑了基本负荷、有功损耗和最小电压下的潮流性能评价。对系统母线进行相当于自身无功负荷的无功功率补偿，然后检查各种情况下的功率损耗指标、电压分布、有功功率和无功功率损耗。该方案在该技术下的应用效果显著，性能得到改善。在电压分布保持系统电能质量的前提下，给出了最合适的电容尺寸和位置。

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Dynamic Capacitor Placement To Mitigate Disaster In Distribution System: A Fuzzy Approach

The adopted approach is based on Fuzzy logic control (FLC) technique as a fuzzy inference algorithm. The work is focused on placement and sizing of capacitors to maintain voltage profile and power savings with precise and effective control of reactive power. The FLC technique is very useful to improve power quality with power saving. FLC is used for finding optimal location & size of capacitors. This Scheme is tested on IEEE 14 bus system and data is analyzed for voltage profile with active and reactive power quality and savings. Evaluation of performance for load flow on base load, active power losses and a minimum voltage is considered. The system bus is compensated with reactive power injection equivalent to self reactive load, then checked Power loss Index, Voltage profile, Active power and Reactive power losses for each case. Application of scheme under proposed technic is showing significant result and demonstrate improved performance. The most suitable size and location of the capacitor is achieved under the proposed scheme for maintaining system power quality with voltage profile.

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2019 International Conference on Power Electronics, Control and Automation (ICPECA)

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