Predictive demand side management of a residential house under intermittent primary energy source conditions

•A residential Demand Side Management (DSM) under intermittent grid energy is proposed.•The DSM schedules the operation of temporary and permanent predictable loads.•The NSGA-II and a Fuzzy logic decision maker are applied to find the optimal schedule.•The DSM ensures great coordination between the...

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Bibliographic Details
Published in:Energy and buildings 2016-01, Vol.112, p.110-120
Main Authors: Khoury, J., Mbayed, R., Salloum, G., Monmasson, E.
Format: Article
Language:English
Subjects:
Demand Side Management
Engineering Sciences
Load scheduling
NSGA-II
PV-battery backup
Unreliable grid
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Summary:•A residential Demand Side Management (DSM) under intermittent grid energy is proposed.•The DSM schedules the operation of temporary and permanent predictable loads.•The NSGA-II and a Fuzzy logic decision maker are applied to find the optimal schedule.•The DSM ensures great coordination between the grid, PV-battery backup, and the load.•Results show excellent performance and a high flexibility of the proposed algorithm. This paper targets the process of optimizing the operation of a PV-battery backup system under intermittent grid electricity supply. A predictive scheduling layer is developed as a part of a complete load management process. The main objective of the study is to ensure a permanent power supply for a high energy consuming residential application. The control algorithm plans the activation of predictable loads 24h ahead through compromising between a decrease in the resulting discomfort levels and the conservation of a high autonomy of the system. The strength of the developed control lies in ensuring the complete coordination between all the components of the installation: the grid, PV panels, battery storage, and the load demand. No loss of power supply is allowed during the day and realistic and technical constraints are applied. The demand side management program is formulated as a multi-objective optimization algorithm solved using the Non-dominated Sorting Genetic Algorithm (NSGA-II) technique. A fuzzy logic decision maker is developed for an automatic trade-off process implementing the residents’ preferences. The simulation results show excellent performance and flexibility of the proposed algorithm. The benefits of the load management are proved to have a great impact on the backup installation sizing, which leads to notable reduction of its price.
ISSN:0378-7788
DOI:10.1016/j.enbuild.2015.12.011