Priority-driven self-optimizing power control scheme for interlinking converters of hybrid AC/DC microgrid clusters in decentralized manner

Hybrid AC/DC microgrid clusters are key building blocks of smart grid to support sustainable and resilient urban power systems. In microgrid clusters, the subgrid load-priorities and power quality requirements for different areas vary significantly. To realize optimal power exchanges among microgrid clusters, this paper proposes a decentralized self-optimizing power control scheme for interlinking converters (ILC) of hybrid microgrid clusters. A priority-driven optimal power exchange model of ILCs is built considering the priorities and capacities in subgrids. The optimization objective is to minimize the total DC-voltage/AC-frequency state deviations of subgrids. To realize the decentralized power flow control, an optimal-oriented quasi-droop control strategy of ILCs is introduced to not only achieve a flexible self-optimizing power flow management, but also provide an ancillary function of voltage support. Consequently, as each of ILCs only monitors the local AC-side frequency and DC-side voltage signals, the whole optimal power control of the wide-area microgrid clusters is achieved in a decentralized manner without any communication link. Thus, the proposed control algorithm has the features of decreased cost, increased scalability, reduced geographic restrictions and high resilience in terms of communication faults. Finally, the proposed method is validated by case studies with four interconnected microgrids through hardware-in-loop tests

A review of networked microgrid protection: Architectures, challenges, solutions, and future trends

The design and selection of advanced protection schemes have become essential for the reliable and secure operation of networked microgrids. Various protection schemes that allow the correct operation of microgrids have been proposed for individual systems in different topologies and connections. Nevertheless, the protection schemes for networked microgrids are still in development, and further research is required to design and operate advanced protection in interconnected systems. The interconnection of these microgrids in different nodes with various interconnection technologies increases the fault occurrence and complicates the protection operation. This paper aims to point out the challenges in developing protection for networked microgrids, potential solutions, and research areas that need to be addressed for their development. First, this article presents a systematic analysis of the different microgrid clusters proposed since 2016, including several architectures of networked microgrids, operation modes, components, and utilization of renewable sources, which have not been widely explored in previous review papers. Second, the paper presents a discussion on the protection systems currently available for microgrid clusters, current challenges, and solutions that have been proposed for these systems. Finally, it discusses the trend of protection schemes in networked microgrids and presents some conclusions related to implementation

Dual Inertia-Emulation Control for Interlinking Converters in Grid-Tying Applications

Electric grids are undergoing several changes, mostly driven by the replacement of classical highly-inertial generators by converter-interfaced generation and storage systems. This entails the reduction of inherent inertia levels and might lead to instability issues. In a future scenario formed by grids of different natures and characteristics, power electronic converters will play a key role on grid tying applications. These converters are known as interlinking converters (ICs), and they enable total control over the power flow between interconnected grids. Therefore, they are envisioned to take part not only tying hybrid ac/dc systems but also in ac/ac connections. This paper presents a novel control strategy for ICs named dual inertiaemulation (DIE), that improves the dynamic response of tied grids by emulating inertia at both sides of the converter, and which can be employed at any IC regardless of the interconnected grid type (ac or dc). The proposed control is tested by means of time-domain simulations of WSCC 9-bus and IEEE 14-bus benchmark systems. The obtained results demonstrate that the proposed technique increases the equivalent inertial response of the interconnected grids, hence reducing frequency oscillations and the rate of change of frequency (RoCoF), and improving the frequency nadir

Control and stability of Ac/Dc microgrids

The current society is facing several challenges related to the field of energy, such as the high dependency on fossil fuels, the constant increment in the energy consumption and the environmental problems caused by these factors. The integration of distributed generation systems—mainly based on renewable energies—combined with energy storage systems is the most interesting solution to tackle these issues. However, most of these systems are connected to the grid through electronic converters that actively control the power exchange. This fact causes various problems not suffered since the origins of electric grids in the transition from an electric model dominated by synchronous machines to a model where power electronics gain more importance—even being the dominating systems in some cases. The lack of inertial response and primary reserve, the instabilities caused by the interactions of power electronic systems or the premature situation of direct current grids, which are being employed more widely, stand out as some of the most important challenges that we want to address with this thesis. In this context, the main purpose of the thesis is the development of ac/dc microgrid control strategies that improve the dynamic behaviour of the system. In order to achieve this objective we contemplate four main lines that consist of the identification and analysis of different microgrid topologies and control techniques, the study of primary control operation modes of the systems that compose these microgrids and finally the the development and evaluation of various low-level control strategies for ac and dc microgrids. These techniques are based on the concept of operation of classical synchronous generators, enabling their autonomous operation as well as providing inertial response under grid perturbations. Among the contributions of the thesis, we can highlight on the one hand, the analysis and comparative evaluation of synchronous machine emulation techniques for ac microgrids, where we evaluate their behaviour for different types of perturbations and we examine their stability applying the generalized Nyquist criterion. Regarding dc microgrids, on the other hand, we propose novel control techniques that are analogous to the ones analysed for ac grids. We call these techniques virtual-capacitors, as they emulate the behaviour of these passive elements connected to dc grids. In this case, we thoroughly study their transient as well as steady-state behaviour, and we demonstrate that they can be adapted by simply modifying control parameters. Moreover, we analyse the stability of these techniques through parametric analysis of their dominant eigenvalues.Gaur egungo gizartea energiaren arloko hainbat erronkaren aurrean aurkitzen da, besteak beste, erregai fosilekiko dependentzia handia, kontsumo energetikoaren etengabeko igoera, eta faktore hauek eragiten dituzten ingurumen arazoak. Generazio bananduko sistemen integrazioa—bereziki iturri berriztagarrietan oinarritutakoa—metatze sistemekin bateratuta, arazo horiei aurre egiteko aukera interesgarriena bilakatu da. Hala ere, sistema hauetako gehienak bihurgailu elektronikoen bitartez konektatzen dira sare elektrikotara, potentziaren hartu-emana modu aktiboan kontrolatzen dutelarik. Honek, makina sinkronoez menderatutako modelo elektriko batetik, potentzia elektronika garrantzia hartzen hasten den—edo kasu batzuetan mendean dagoen—modelo baterako trantsizioan hainbat arazo eragiten ditu, sare elektrikoak sortu zirenetik jasan ez direnak. Erantzun inertzial eta erreserba primario eza, bihurgailuen interakzioaren ondoriozko estabilitate arazoak edo korronte zuzeneko sareen egoera goiztiarra, geroz eta gehiago erabiltzen direnak, tesi honen bitartez aurre egin nahi diren erronkarik garrantzitsuenetarikoak dira. Testuinguru honetan, tesiaren helburu nagusia ac/dc mikrosareen portaera dinamikoa hobetzen duten kontrol estrategiak garatzea da. Helburu hau lortzeko lau lerro nagusi planteatu dira, besteak beste, mikrosareen topologia eta kontrol estrategia desberdinen identifikazio eta analisia, sare hauek konposatzen duten sistemen kontrol primarioaren untzionamendu motak azterketa, eta azkenik, bai ac eta bai dc mikrosareendako nibel baxuko kontrol estrategia desberdinen garapena. Azken hauek generadore sinkrono klasikoetan oinarritu dira, modu autonomoan eta bananduan aritzeko gaitasuna emateaz gain, sareko perturbazioen aurrean erantzun inertziala ematea ahalbidetzen dielako. Tesiaren ekarpenen artean, alde batetik, makina sinkronoen emulazioan datzan kontrol estrategien analisia eta konparaketa azpimarratu behar dira. Kasu honetan, teknika hauek hainbat perturbazioetarako ebaluatzen ditugu, eta Nyquisten kriterio generalizatuan oinarrituta estabilitatea aztertzen dugu. Korronte zuzeneko sareei erreparatuz, bestalde, kontrol teknika berriak proposatzen ditugu. Hauei kondentsadore-birtual izena ezarri diegu, elementu pasibo horien erantzun dinamikoa emulatzen dutelako. Hemen, teknika hauen erregimen iraunkorreko eta iragankorreko erantzuna aztertzen dugu, soilik kontrol parametro batzuk aldatuta egokitu daitezkela frogatuz. Hortaz gain, sistema hauen estabilitatea aztertzen dugu berezko balio dominanteen (eigenvalue-en) analisi parametrikoak eginez.La sociedad actual se enfrenta a varios retos importantes en materia energética, entre los que destacan la gran dependencia de los combustibles fósiles, el constante aumento del consumo energético y los problemas medioambientales que estos factores conllevan. La integración de sistemas de generación distribuida—principalmente de origen renovable— combinadas con sistemas de almacenamiento de energía, se presenta como la solución más interesante para hacer frente a estos retos. Sin embargo, la mayor parte de estos sistemas se conectan a la red a través de convertidores electrónicos que controlan el intercambio de potencia de manera activa. Este hecho hace que la transición desde un modelo eléctrico principalmente dominado por máquinas síncronas, hacia un modelo donde la electrónica de potencia comienza a cobrar protagonismo—hasta el punto de llegar a ser dominante en algunos casos—acarree diversos problemas que prácticamente no se han manifestado desde los orígenes de las redes eléctricas. La falta de respuesta inercial y reserva primaria, las inestabilidades debidas a la interacción de los sistemas electrónicos de potencia o la prematura situación de las redes de corriente continua, cada día utilizadas en mayor medida, destacan como algunos de los retos más importantes a los que se quiere dar respuesta a través de esta tesis. En este contexto, el objetivo principal de la tesis es el desarrollo de estrategias de control de microrredes ac/dc que mejoren el comportamiento dinámico del sistema. Para la consecución de este objetivo se han planteado cuatro líneas principales que constan de la identificación y análisis de diferentes topologías y técnicas de control de microrredes, el estudio de los modos de operación del control primario de los sistemas que las componen, y finalmente, el desarrollo y evaluación de diversas técnicas de control de nivel bajo tanto para microrredes ac como dc. Las estrategias de control de nivel bajo desarrolladas en la tesis se basan en el concepto de operación de los generadores síncronos clásicos, lo que les permite operar de manera distribuida y autónoma, aportando a su vez respuesta inercial ante perturbaciones en la red. Entre las contribuciones de la tesis destacan, por un lado, el análisis y comparativa de técnicas de control de emulación de máquinas síncronas para redes ac, donde evaluamos su comportamiento ante diferentes tipos de perturbaciones y examinamos su estabilidad aplicando criterios generalizados de Nyquist. En el ámbito de las redes dc, por otra parte, proponemos nuevas técnicas de control que son análogas a las analizadas para las redes ac, y que denominamos como condensadores-virtuales puesto que emulan el comportamiento dinámico de estos elementos pasivos conectados a la red. En este caso, estudiamos en detalle su comportamiento dinámico y en régimen permanente, demostrando que se pueden adaptar simplemente variando parámetros de control, y analizamos su estabilidad llevando a cabo análisis paramétricos de sus valores propios dominantes

Operation and Control of DC Microgrid

Power harnessing technology from the renewable energy resources has been developed over the past two decades. This technology enabled us to integrate renewable energy-based power generation to the conventional electric power grid. This study aims to improve the dynamic response and the load regulation using improved control strategies of the dc converters used to interface utility and renewable energy-based power generation. The power sharing between multiple dc microgrids/ac-dc microgrids is also investigated