H. H. Zeineldin scite author profile

Microgrids can be operated either grid-connected to reduce system losses and for peak shaving or islanded to increase reliability and provide backup power during utility outage. Such dual configuration capability imposes challenges on the design of the protection system. Fault current magnitudes will vary depending on the microgrid operating mode. In this paper, a microgrid protection scheme that relies on optimally sizing fault current limiters (FCL) and optimally setting directional overcurrent relays is proposed. The protection scheme is optimally designed taking into account both modes of operation (gridconnected and islanded). The problem has been formulated as a constrained non-linear programming (NLP) problem and is solved using the genetic algorithm (GA) with the static penalty constraint-handling technique. The proposed approach is tested on two medium-voltage networks: a typical radial distribution system and on the IEEE 30-bus looped power distribution system equipped with directly-connected conventional synchronous generators (CSG).

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Optimal coordination of overcurrent relays using a modified particle swarm optimization

Zeineldin

El-Saadany

Salama

2006

Electric Power Systems Research

293

151

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A Novel Approach to Solve Power Flow for Islanded Microgrids Using Modified Newton Raphson With Droop Control of DG

Mumtaz

Syed

Hosani³

et al. 2016

IEEE Trans. Sustain. Energy

228

147

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The study of power flow analysis for microgrids has gained importance where several methods have been proposed to solve these problems. However, these schemes are complicated and not easy to implement due to the absence of a slack bus as well as the dependence of the power on frequency as a result of the droop characteristics. This paper proposes simple and effective modifications to the conventional method (Newton Raphson) to compute the power flow for microgrids. The presented method provides a simple, easy to implement, and accurate approach to solve the power flow equations for microgrids. The proposed method is applied to two test systems: a 6-bus system and a 38-bus system. The results are compared against simulation results from PSCAD/EMTDC which validate the effectiveness of the developed method. The proposed technique can be easily integrated in current commercially available power system software and can be applied for power system studies. Index Terms-Distributed generation (DG), islanded microgrid, power flow.

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Protection Coordination for Microgrids With Grid-Connected and Islanded Capabilities Using Communication Assisted Dual Setting Directional Overcurrent Relays

Sharaf

Zeineldin

El-Saadany

2018

IEEE Trans. Smart Grid

196

125

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Determining Optimal Location and Size of Distributed Generation Resources Considering Harmonic and Protection Coordination Limits

Pandi¹,

Zeineldin²,

Xiao³

2013

IEEE Trans. Power Syst.

217

109

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In this paper, a new optimization problem is proposed to determine the maximum distributed generation (DG) penetration level by optimally selecting types, locations and sizes of utility owned DG units. The DG penetration level could be limited by harmonic distortion because of the nonlinear current injected by inverter-based DG units and also protection coordination constraints because of the variation in fault current caused by synchronous-based DG units. Hence the objective of the proposed problem is to maximize DG penetration level from both types of DG units, taking into account power balance constraints, bus voltage limits, total and individual harmonic distortion limits specified by the IEEE-519 standard, over-current relay operating time limits, and protection coordination constraints. The DG penetration study is formulated as a nonlinear programming (NLP) problem and tested on the IEEE-30 bus looped distribution network with ten load and DG scenarios. Similarly, feasibility assessment of customer owned DG unit installations considering power quality and protection coordination is also studied. Simulation results show the effectiveness of the proposed approach, which can serve as an efficient planning tool for utility operators.

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H. H. Zeineldin

Optimal Protection Coordination for Microgrids With Grid-Connected and Islanded Capability

Optimal coordination of overcurrent relays using a modified particle swarm optimization

A Novel Approach to Solve Power Flow for Islanded Microgrids Using Modified Newton Raphson With Droop Control of DG

Protection Coordination for Microgrids With Grid-Connected and Islanded Capabilities Using Communication Assisted Dual Setting Directional Overcurrent Relays

Determining Optimal Location and Size of Distributed Generation Resources Considering Harmonic and Protection Coordination Limits

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