Passivity-Based Control for DC-Microgrids with Constant Power Terminals in Island Mode Operation

Murillo-Yarce, Duberney; Garcés-Ruiz, Alejandro; Escobar-Mejía, Andrés

doi:10.17533/udea.redin.n86a05

Cited by 9 publications

(17 citation statements)

References 41 publications

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“…In this part, we are interested in presenting the tertiary control stage in power system operation, i.e., the optimization stage in hierarchical control structures. The tertiary control stage is also called optimal power flow and it can be implemented as centralized or distributed [31]. This works if links are sent to each active device (e.g., power electronic converters) to provide references to primary and secondary controls [32].…”

Section: Mathematical Modelingmentioning

confidence: 99%

Optimal Placement and Sizing of Wind Generators in AC Grids Considering Reactive Power Capability and Wind Speed Curves

et al. 2020

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This paper presents an optimization model for the optimal placement and sizing of wind turbines, considering their reactive power capacity, wind speed, and demand curves. The optimization model is nonlinear and is focused on minimizing power losses in AC distribution networks. Also, paired wind turbine and power conversion systems are treated via chargeability factor η at the peak hour. This factor represents the percentage of usage of the power conversion system in the nominal wind speed conditions, and allows to support reactive power dynamically during all periods of the day as a function of the distribution system requirements. In addition, an artificial neural network is used for short-term forecasting to deal with uncertainties in wind power generation. We assume that the number of wind power distributed generators could be from zero to three generators integrated into the system, considering unit power factors and reactive power injections to follow up the effect of reactive power compensation in the daily operation. The General Algebraic Modeling System (GAMS) is employed to solve the proposed optimization model.

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Section: Mathematical Modelingmentioning

confidence: 99%

Optimal Placement and Sizing of Wind Generators in AC Grids Considering Reactive Power Capability and Wind Speed Curves

et al. 2020

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“…Direct current (DC) distribution networks have attracted much attention in recent years in specialized literature [1], since these networks have better voltage profiles [2] and low energy losses [3]. They are easily controllable since frequency or reactive power are nonexistent concepts in these electrical networks [4]. In the literature, multiple approaches regarding DC networks have been described, such as control methodologies for power electronic converters that interface renewable energies [5] and batteries [6], optimization approaches associated with power losses minimization [2] and analysis of convergence algorithms for power flow analysis [7].…”

Section: Introductionmentioning

confidence: 99%

A Mixed-Integer Conic Formulation for Optimal Placement and Dimensioning of DGs in DC Distribution Networks

et al. 2021

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The problem of the optimal placement and dimensioning of constant power sources (i.e., distributed generators) in electrical direct current (DC) distribution networks has been addressed in this research from the point of view of convex optimization. The original mixed-integer nonlinear programming (MINLP) model has been transformed into a mixed-integer conic equivalent via second-order cone programming, which produces a MI-SOCP approximation. The main advantage of the proposed MI-SOCP model is the possibility of ensuring global optimum finding using a combination of the branch and bound method to address the integer part of the problem (i.e., the location of the power sources) and the interior-point method to solve the dimensioning problem. Numerical results in the 21- and 69-node test feeders demonstrated its efficiency and robustness compared to an exact MINLP method available in GAMS: in the case of the 69-node test feeders, the exact MINLP solvers are stuck in local optimal solutions, while the proposed MI-SOCP model enables the finding of the global optimal solution. Additional simulations with daily load curves and photovoltaic sources confirmed the effectiveness of the proposed MI-SOCP methodology in locating and sizing distributed generators in DC grids; it also had low processing times since the location of three photovoltaic sources only requires 233.16s, which is 3.7 times faster than the time required by the SOCP model in the absence of power sources.

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“…The control of an MT-HVDC is similar to a stand-alone DC microgrid which includes a hierarchical control. In [9], a port-Hamiltonian model in conjunction with the interconnection and damping assignment passivity-based control (PBC) was presented for the primary control. In [8], an optimal power flow from a dynamic analysis based on port-Hamiltonian models for controlling power flows in MT-HVDC systems was proposed.…”

Section: Introductionmentioning

confidence: 99%

“…This method guarantees globally asymptotic stability properties. In comparison with the recent contribution presented in [9], the main advantage of this approach is that our proposed PBC control does not require communication channels in the control step and avoids parametric dependence on the capacitive filter values at each power electronic converter. The approach in [9] required this information to develop its PBC control strategy.…”

Section: Introductionmentioning

confidence: 99%

Stabilization of MT-HVDC grids via passivity-based control and convex optimization

Montoya

Gil-González

Garcés

et al. 2021

Electric Power Systems Research

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Passivity-Based Control for DC-Microgrids with Constant Power Terminals in Island Mode Operation

Cited by 9 publications

References 41 publications

Optimal Placement and Sizing of Wind Generators in AC Grids Considering Reactive Power Capability and Wind Speed Curves

Optimal Placement and Sizing of Wind Generators in AC Grids Considering Reactive Power Capability and Wind Speed Curves

A Mixed-Integer Conic Formulation for Optimal Placement and Dimensioning of DGs in DC Distribution Networks

Stabilization of MT-HVDC grids via passivity-based control and convex optimization

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