An improved IGDT approach for distributed generation hosting capacity evaluation in multi-feeders distribution system with soft open points

•A novel DG hosting capacity evaluation method is proposed for multi-feeders system interconnected by external tie lines and SOPs.•An improved-IGDT model is presented to assess DG hosting capacity considering unpredictable integrated locations and uncertainty in outputs simultaneously.•A hybrid solu...

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Bibliographic Details
Published in:International journal of electrical power & energy systems 2023-12, Vol.154, p.109404, Article 109404
Main Authors: Li, Junkai, Ge, Shaoyun, Liu, Hong, Hou, Tingyu, Wang, Pengxiang, Xing, Pengxiang
Format: Article
Language:English
Subjects:
DG hosting capacity
improved IGDT model
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Summary:•A novel DG hosting capacity evaluation method is proposed for multi-feeders system interconnected by external tie lines and SOPs.•An improved-IGDT model is presented to assess DG hosting capacity considering unpredictable integrated locations and uncertainty in outputs simultaneously.•A hybrid solution procedure integrated with genetic algorithm and model reformulation is developed to determine DG hosting capacity. Unknown integrated locations caused by unpredictable consumers’ willingness and uncertainty in outputs induced by variable natural conditions are acknowledged challenges in the evaluation process of distributed generation (DG) hosting capacity (DGHC). For the former factor, this paper first proposes a novel assessment model to obtain the maximum feasible capacity no matter consumers in which locations have the possibility to stall DG. The decision variables of max operator and min operator are DG capacities and integrated locations respectively. Notably, unlike the previous works for one radial feeder, the interplay of DGHC in multi-feeders interconnected by tie lines and soft open points is also taken into consideration. After that, to combine uncertainties in integrated locations and outputs simultaneously, the above DGHC assessment model is further transformed into an improved information gap decision theory (IGDT) model with worst-case constraints for DG integrated locations. The specific solution procedure is also developed to solve this nonlinear IGDT model effectively. Case studies demonstrate that the evaluation results of DGHC based on this method always have the applicability and feasibility for any nodes in distribution system.
ISSN:0142-0615
DOI:10.1016/j.ijepes.2023.109404