2,974 research outputs found
Secondary Frequency and Voltage Control of Islanded Microgrids via Distributed Averaging
In this work we present new distributed controllers for secondary frequency
and voltage control in islanded microgrids. Inspired by techniques from
cooperative control, the proposed controllers use localized information and
nearest-neighbor communication to collectively perform secondary control
actions. The frequency controller rapidly regulates the microgrid frequency to
its nominal value while maintaining active power sharing among the distributed
generators. Tuning of the voltage controller provides a simple and intuitive
trade-off between the conflicting goals of voltage regulation and reactive
power sharing. Our designs require no knowledge of the microgrid topology,
impedances or loads. The distributed architecture allows for flexibility and
redundancy, and eliminates the need for a central microgrid controller. We
provide a voltage stability analysis and present extensive experimental results
validating our designs, verifying robust performance under communication
failure and during plug-and-play operation.Comment: Accepted for publication in IEEE Transactions on Industrial
Electronic
Plug-and-play Solvability of the Power Flow Equations for Interconnected DC Microgrids with Constant Power Loads
In this paper we study the DC power flow equations of a purely resistive DC
power grid which consists of interconnected DC microgrids with constant-power
loads. We present a condition on the power grid which guarantees the existence
of a solution to the power flow equations. In addition, we present a condition
for any microgrid in island mode which guarantees that the power grid remains
feasible upon interconnection. These conditions provide a method to determine
if a power grid remains feasible after the interconnection with a specific
microgrid with constant-power loads. Although the presented condition are more
conservative than existing conditions in the literature, its novelty lies in
its plug-and-play property. That is, the condition gives a restriction on the
to-be-connected microgrid, but does not impose more restrictions on the rest of
the power grid.Comment: 8 pages, 2 figures, submitted to IEEE Conference on Decision and
Control 201
Multiagent-Based Control for Plug-and-Play Batteries in DC Microgrids with Infrastructure Compensation
The influence of the DC infrastructure on the control of power-storage flow in micro- and smart grids has gained attention recently, particularly in dynamic vehicle-to-grid charging applications. Principal effects include the potential loss of the charge–discharge synchronization and the subsequent impact on the control stabilization, the increased degradation in batteries’ health/life, and resultant power- and energy-efficiency losses. This paper proposes and tests a candidate solution to compensate for the infrastructure effects in a DC microgrid with a varying number of heterogeneous battery storage systems in the context of a multiagent neighbor-to-neighbor control scheme. Specifically, the scheme regulates the balance of the batteries’ load-demand participation, with adaptive compensation for unknown and/or time-varying DC infrastructure influences. Simulation and hardware-in-the-loop studies in realistic conditions demonstrate the improved precision of the charge–discharge synchronization and the enhanced balance of the output voltage under 24 h excessively continuous variations in the load demand. In addition, immediate real-time compensation for the DC infrastructure influence can be attained with no need for initial estimates of key unknown parameters. The results provide both the validation and verification of the proposals under real operational conditions and expectations, including the dynamic switching of the heterogeneous batteries’ connection (plug-and-play) and the variable infrastructure influences of different dynamically switched branches. Key observed metrics include an average reduced convergence time (0.66–13.366%), enhanced output-voltage balance (2.637–3.24%), power-consumption reduction (3.569–4.93%), and power-flow-balance enhancement (2.755–6.468%), which can be achieved for the proposed scheme over a baseline for the experiments in question.</p
Review on Control of DC Microgrids and Multiple Microgrid Clusters
This paper performs an extensive review on control schemes and architectures applied to dc microgrids (MGs). It covers multilayer hierarchical control schemes, coordinated control strategies, plug-and-play operations, stability and active damping aspects, as well as nonlinear control algorithms. Islanding detection, protection, and MG clusters control are also briefly summarized. All the mentioned issues are discussed with the goal of providing control design guidelines for dc MGs. The future research challenges, from the authors' point of view, are also provided in the final concluding part
Plug-and-play robust voltage control of DC microgrids
The purpose of this paper is to explore the applicability of linear time-invariant dynamical systems with polytopic uncertainty for modeling and control of islanded dc microgrids under plug-and-play (PnP) functionality of distributed generations (DGs). We develop a robust decentralized voltage control framework to ensure robust stability and reliable operation for islanded dc microgrids. The problem of voltage control of islanded dc microgrids with PnP operation of DGs is formulated as a convex optimization problem with structural constraints on some decision variables. The proposed control scheme offers several advantages including decentralized voltage control with no communication link, transient stability/performance, PnP capability, scalability of design, applicability to microgrids with general topology, and robustness to microgrid uncertainties. The effectiveness of the proposed control approach is evaluated through simulation studies carried out in MATLAB/SimPowerSystems Toolbox
Network Topology Invariant Stability Certificates for DC Microgrids with Arbitrary Load Dynamics
DC microgrids are prone to small-signal instabilities due to the presence of
tightly regulated loads. This paper develops a decentralized stability
certificate which is capable of certifying the small-signal stability of an
islanded DC network containing such loads. Utilizing a novel homotopy approach,
the proposed standards ensure that no system eigenmodes are able to cross into
the unstable right half plane for a continuous range of controller gain levels.
The resulting "standards" can be applied to variety of grid components which
meet the specified, but non-unique, criteria. These standards thus take a step
towards offering plug-and-play operability of DC microgrids. The proposed
theorems are explicitly illustrated and numerically validated on multiple DC
microgrid test-cases containing both buck and boost converter dynamics
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