Journal ArticleDOI
Photovoltaic Generation Penetration Limits in Radial Distribution Systems
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In this paper, the authors present and discuss studies proving that conductor ampacity and voltage rises are limiting factors that manifest themselves under different conditions, and highlight situations in which line overloads are more restrictive than voltage rises.Abstract:
Photovoltaic generating units connected to distribution systems represent a type of distributed generation (DG) that has been experiencing increased growth in recent years. Higher DG penetration levels may be interesting from many different points of view, but raise important issues about distribution system operation. Therefore, new techniques are needed to determine the maximum amount of DG that may be installed without requiring major changes in the existing electric power system. According to the literature, voltage rises at load bus bars are a serious limiting factor when installing DG. This paper presents and discusses studies proving that conductor ampacity and voltage rises are limiting factors that manifest themselves under different conditions. The present study highlights situations in which line overloads are more restrictive than voltage rises. Variation in substation voltage, load, and its power factor were simulated in a simplified radial distribution system model, and the amount of distributed generation that may be installed was obtained. Mathematic formulae were developed to determine the amount of distributed generation for existing utility systems.read more
Citations
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Representing Battery Energy Storage in Electric Power System Studies
TL;DR: In this article, a generic model is presented which unifies the physical and control aspects of a grid-connected battery energy storage system, and significant insight on this matter can be gained, which is useful to guide operation, investment and policy decisions.
Dissertation
Customer-Side Voltage Regulation to Mitigate PV-induced Power Quality Problems in Radial Distribution Networks
TL;DR: The simulation results show that the proposed VR methodology is effective in addressing voltage magnitude and unbalance violations for most of the PV penetration levels.
Journal ArticleDOI
Coordinated planning in improving power quality considering the use of nonlinear load in radial distribution system
TL;DR: This research is in form of coordinated planning by combining distributed generation placement, capacitor placement and network reconfiguration to simultaneously minimize active power losses, THD, and voltage deviation as an objective function using the particle swarm optimization method.
Distribution system optimization with integrated distributed generation
TL;DR: Severalvolt-var optimization methods have been proposed to improve the expected performance of the distribution system using distributed renewable energy sources and conventional volt-var control equipment:photovoltaic inverter reactive power control for chance-constrained distribution system performance optimisation, integrated distribution system optimization using a chance- Constrained formulation, integrated control of distribution system equipment and distributed generation inverters.
References
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ReportDOI
Distribution System Voltage Performance Analysis for High-Penetration Photovoltaics
TL;DR: In this paper, the performance of commonly used distribution voltage regulation methods under reverse power flow was examined. But the performance was not evaluated in terms of voltage regulation in the case of reverse power flows.
Proceedings ArticleDOI
Voltage Regulation in Radial Distribution Feeders with High Penetration of Photovoltaic
TL;DR: In this article, the impact of active power and reactive power variation on the voltage and losses of a radial low voltage distribution feeder with uniformly distributed loads and non-dispatchable (active power) sources is investigated.
ReportDOI
Power System Planning: Emerging Practices Suitable for Evaluating the Impact of High-Penetration Photovoltaics
TL;DR: In this paper, the authors explore the impact of high-penetration renewable generation on electric power system planning methodologies and outline how these methodologies are evolving to enable effective integration of variable-output renewable generation sources.