Yeong Han Chun scite author profile

Yeong Han Chun

2Publications

62Citation Statements Received

77Citation Statements Given

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100

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Hongik University

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Network topology and resilience analysis of South Korean power grid

Kim

Eisenberg

Chun

et al. 2017

Physica A: Statistical Mechanics and its Applications

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In this work, we present topological and resilience analyses of the South Korean power grid (KPG) with a broad voltage level.While topological analysis ofKPG only with high-voltage infrastructure shows an exponential degree distribution, providing another empirical evidence of power grid topology, theinclusion of low voltage components generates a distribution with a larger variance and a smaller average degree.This result suggests that the topology of a power gridmay converge to a highly skewed degree distribution if more low-voltage datais considered. Moreover, when compared to ER random and BA scale-free networks, the KPG has a lower efficiency and a higher clustering coefficient, implying that highly clustered structure does not necessarily guarantee a functional efficiency of a network. Error and attack toleranceanalysis,evaluated with efficiency, indicate that the KPG is more vulnerable to random or degree-based attacks than betweenness-based intentional attack.Cascading failureanalysis with recovery mechanism demonstrates that resilience of the network depends on both tolerance capacity and recovery initiation time. Also, when the two factors are fixed, the KPG is most vulnerable among the three networks. Based on our analysis, we propose that the topology of power grids should be designed so the loads are homogeneously distributed, or functional hubs and their neighbors have high tolerance capacity to enhance resilience.

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Dynamic Droop-based Inertial Control of a Wind Power Plant

Hwang

Chun

Park³

et al. 2015

Journal of Electrical Engineering and Technology

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-The frequency of a power system should be maintained within the allowed limits for stable operation. When a disturbance such as generator tripping occurs in a power system, the frequency is recovered to the nominal value through the inertial, primary, and secondary responses of the operating synchronous generators (SGs). However, for a power system with high wind penetration, the system inertia will decrease significantly because wind generators (WGs) are operating decoupled from the power system. This paper proposes a dynamic droop-based inertial control for a WG. The proposed inertial control determines the dynamic droop depending on the rate of change of frequency (ROCOF). At the initial period of a disturbance, where the ROCOF is large, the droop is set to be small to release a large amount of the kinetic energy (KE) and thus the frequency nadir can be increased significantly. However, as times goes on, the ROCOF will decrease and thus the droop is set to be large to prevent over-deceleration of the rotor speed of a WG. The performance of the proposed inertial control was investigated in a model system, which includes a 200 MW wind power plant (WPP) and five SGs using an EMTP-RV simulator. The test results indicate that the proposed scheme improves the frequency nadir significantly by releasing a large amount of the KE during the initial period of a disturbance.

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Yeong Han Chun

Network topology and resilience analysis of South Korean power grid

Dynamic Droop-based Inertial Control of a Wind Power Plant

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