Qusay Salem scite author profile

<p class="abstract">This paper presents the power flow control between the main grid and the microgrid in low-voltage distribution network using H-bridge inverter. Controlling the real power flow in the line using the H-bridge inverter is investigated by implementing the line current control strategy. The feasibility of the proposed H-bridge inverter and its control strategy is validated by varying the line current reference. Hence, the H-bridge inverter will operate in its inductive or capacitive operation mode depending on the reference current value and the output of the PI controller in the control unit. The control strategy of the microgrid distributed generators has also been investigated in which P/V droop characteristics is applied to the power control of each DG in the microgrid. The effectiveness of the proposed approaches is validated through simulations. </p>

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Relationship between Fault Level and System Strength in Future Renewable-Rich Power Grids

Aljarrah

Karimi

Marzooghi³

et al. 2022

Applied Sciences

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The fault level is used as a simple indicator for scanning the system strength in power systems. To an extent, this has proven its efficacy in classical power systems based on synchronous generation (SG). However, power electronics-based renewable energy sources (RESs), due to their controlled and limited fault current contribution, may affect the impedance, fault level, and system strength in a non-linear manner. Hence, this raises a question about the validity of using the fault level as a measure reflecting the system strength in future grids. This paper intends to shed light on the above question by examining the correlation between the fault level and the system strength in future grid scenarios. This is achieved in two steps: first, by employing the measure-based Thevenin impedance for fault level estimation in renewable-rich grids, and second, by comparing these estimated fault levels with those obtained from steady-state and dynamic simulations. While the results have demonstrated the suitability of using the fault level for system strength scanning in scenarios of low penetration of RESs, they revealed that such a tool might be misleading with very high RES penetrations. The findings have been verified using the adjusted IEEE nine-bus test system in DIgSILENT PowerFactory.

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Transition From Grid-Connected to Islanded Drooped Microgrid Based on Islanding Detection Scheme

Salem¹,

Xie²

2016

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Qusay Salem

Dual Operation Mode of a Transformerless H-Bridge Inverter in Low-Voltage Microgrid

Decentralized power control management with series transformerless H-bridge inverter in low-voltage smart microgrid based P/V droop control

A Novel Line Current Control Strategy to Control the Real Power Flow at PCC using H-bridge Inverter

Relationship between Fault Level and System Strength in Future Renewable-Rich Power Grids

Transition From Grid-Connected to Islanded Drooped Microgrid Based on Islanding Detection Scheme

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