Abstract
Microgrids represent a flexible way to integrate renewable energy sources with programmable generators and storage systems. In this regard, a synergic integration of those sources is crucial to minimize the operating cost of the microgrid by efficient storage management and generation scheduling. The forecasts of renewable generation can be used to attain optimal management of the controllable units by predictive optimization algorithms. This paper introduces the implementation of a two-layer hierarchical energy management system for islanded photovoltaic microgrids. The first layer evaluates the optimal unit commitment, according to the photovoltaic forecasts, while the second layer deals with the power-sharing in real time, following as close as possible the daily schedule provided by the upper layer while balancing the forecast errors. The energy management system is experimentally tested at the Multi-Good MicroGrid Laboratory under three different photovoltaic forecast models: (i) day-ahead model, (ii) intraday corrections and (iii) nowcasting technique. The experimental study demonstrates the capability of the proposed management system to operate an islanded microgrid in safe conditions, even with inaccurate day-ahead photovoltaic forecasts.
Highlights
The definition proposed by Lasseter in [1] of the microgrid (MG) concept is nowadays worldwide recognized
This paper introduces the implementation of a two-layer hierarchical energy management system for islanded photovoltaic microgrids
The first layer is based on deterministic MILP optimization for unit commitment and storage management, and the second layer is based on PI control to follow the schedule chosen by the first layer while compensating for the real-time unbalances of the MG generation
Summary
The definition proposed by Lasseter in [1] of the microgrid (MG) concept is nowadays worldwide recognized. Relevant effort has been made to study and develop MG EMS, but on-field validation of MG control based on experimental activities is needed to fully characterize the outcomes of the EMS implementation In this respect, experimental MGs play an essential role, allowing the demonstration of the MGMG concept, as well as the identification and overcoming of the technical barriers [15]. The work [16] presents both simulation and experimental results of a single-layer EMS based on MILP optimization They considered a grid-connected MG, demonstrating the capability of a rolling horizon approach in minimizing the operating cost. A hierarchical scheme is proposed in [18], considering real-time experiments for on-grid systems made of a PV field, a wind turbine and BESS They validated the performances of hierarchical EMS by comparing it with single-layer EMS. A persistent PV forecast is adopted as an update of the forecast every 3 h and performance is evaluated through simulations of an on-grid case [21]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
