2021
DOI: 10.1002/er.6995
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Optimal energy management of microgrids‐integrated nonconvex distributed generating units with load dynamics

Abstract: Summary Microgrid (MG) energy management is a complex task for MG operators to integrate and utilize consumer‐based power sources. The MG energy management systems’ problem will become tedious by considering distributed generation (DG) units' nonconvex characteristics. Therefore, a novel attempt is made to solve the day‐ahead dispatch problem of grid‐connected MG with the nonconvex cost function of DG units, including weekend and weekday load dynamics. At first, the utility‐induced flexible load shaping strate… Show more

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Cited by 25 publications
(15 citation statements)
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“…CPLEX and CBC solvers are based on branch‐and‐cut algorithm, while IPOPT and BDMLP are based on interior‐point and branch‐and‐bound algorithm respectively 51 . CPLEX, the chosen solver to the problem as in References 5,9–14,20–35,40,50 has outperformed the remaining solving algorithms regarding the computation time with 12.5 seconds as depicted in the convergence diagram Figure 3. The worst scenario was obtained with the BDMLP algorithm which found the optimal solution after 17 minutes and 97 453 iterations.…”
Section: System Modelingmentioning
confidence: 99%
See 1 more Smart Citation
“…CPLEX and CBC solvers are based on branch‐and‐cut algorithm, while IPOPT and BDMLP are based on interior‐point and branch‐and‐bound algorithm respectively 51 . CPLEX, the chosen solver to the problem as in References 5,9–14,20–35,40,50 has outperformed the remaining solving algorithms regarding the computation time with 12.5 seconds as depicted in the convergence diagram Figure 3. The worst scenario was obtained with the BDMLP algorithm which found the optimal solution after 17 minutes and 97 453 iterations.…”
Section: System Modelingmentioning
confidence: 99%
“…The amount of energy in each electrical energy storage i at time t + 1 is the sum of the energy level of each energy storage at time t and the charging/discharging decisions at time t, as stated in Equation (32). 48 However, the energy level of each energy storage is bounded within a minimum and a maximum value [Equation (33)].…”
Section: Electrical Energy Storagementioning
confidence: 99%
“…The ESSs and DGs have broad applications in the electrical distribution grids. 31 The study conducted in 32 presents a multi-objective nonlinear optimization which optimizes the siting and sizing of storage systems in the distribution systems. The model excludes depth of discharge (DOD) and reactive power of energy storage system (ESS).…”
Section: Linear Model For Ess and Dgmentioning
confidence: 99%
“…The above state of the art summarizes various mathematical, 22 heuristic, 19 multi-agent-based, 14,15 and reinforcement learning-based 16 EMS strategies with a wide range of objectives. Furthermore, the quantum computational-based algorithms [28][29][30] are also adopted to resolve the problems of optimal scheduling in MG. In addition, applying various DR strategies unified with the EMS problem has enhanced operational costs.…”
Section: State Of the Artmentioning
confidence: 99%