Decentralized Mode-Adaptive Guidance and Control for DC Microgrid

Cook, Michael D.; Parker, Gordon G.; Robinett, Rush D.; Weaver, Wayne W.

doi:10.1109/tpwrd.2016.2583384

Cited by 45 publications

(24 citation statements)

References 22 publications

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“…According to (5), all the state variables of each agent will converge to the same value, which depends on the initial values.…”

Section: Distributed Consensus Algorithmmentioning

confidence: 99%

“…DC microgrids are gaining more and more attention due to the competitive advantages they provide over AC microgrids [2,3]. Firstly, DC microgrids can integrate the renewable energy sources (i.e., wind-power, photovoltaic), storage units (i.e., batteries, ultra-capacitors), and DC loads more efficiently, because the AC/DC and DC/AC conversion stages are avoided [4,5]. Secondly, there are no issues with frequency regulation and reactive power flow for the DC microgrids [6,7].…”

Section: Introductionmentioning

confidence: 99%

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Distributed Economic Power Dispatch and Bus Voltage Control for Droop-Controlled DC Microgrids

Zeng

Gao

et al. 2019

Energies

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This paper proposes a distributed economic power dispatch (EPD) and bus voltage control solution for droop-controlled DC microgrids. For the proposed solution, a local power controller and a local voltage controller are added for each distributed generator (DG) to overcome the limitations of the conventional droop control. The power controller generates the first voltage correction term by comparing the local output power of DG with the reference instruction generated by the proposed distributed EPD algorithm, and thus, it can reduce the operation cost of the microgrid by optimally sharing the load demand among all the participating DGs. The voltage controller generates the second voltage correction term by comparing the nominal DC bus voltage value with the average bus voltage generated by the proposed distributed average bus voltage observation (ABVO) algorithm, and thus, it can realize the global bus voltage regulation of the DC microgrid. In contrast with conventional solutions, the control solution can distribute the computational and communication burdens among all the DGs working in parallel, which is more flexible, scalable, and robust against single-point failure. The effectiveness of the proposed control solution is demonstrated through simulation studies.

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“…According to (5), all the state variables of each agent will converge to the same value, which depends on the initial values.…”

Section: Distributed Consensus Algorithmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Distributed Economic Power Dispatch and Bus Voltage Control for Droop-Controlled DC Microgrids

Zeng

Gao

et al. 2019

Energies

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“…Conversely, it is known that the inverters are over-powering the bus load when the bus storage level is increasing. Similar to the decentralized mode adaptive guidance law of [21] for DC microgrids, the decentralized power apportionment guidance law for AC inverter microgrids exploits the state of the bus storage to indicate the power balance of the microgrid, and then adjusts accordingly.…”

Section: Decentralized Power Apportionmentmentioning

confidence: 99%

Optimal and Decentralized Control Strategies for Inverter-Based AC Microgrids

et al. 2019

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This paper presents two control strategies: (i) An optimal exergy destruction (OXD) controller and (ii) a decentralized power apportionment (DPA) controller. The OXD controller is an analytical, closed-loop optimal feedforward controller developed utilizing exergy analysis to minimize exergy destruction in an AC inverter microgrid. The OXD controller requires a star or fully connected topology, whereas the DPA operates with no communication among the inverters. The DPA presents a viable alternative to conventional P − ω/Q − V droop control, and does not suffer from fluctuations in bus frequency or steady-state voltage while taking advantage of distributed storage assets necessary for the high penetration of renewable sources. The performances of OXD-, DPA-, and P − ω/Q − V droop-controlled microgrids are compared by simulation.

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“…This microgrid integrates different energy sources according to the energy availability of the area (solar energy, wind turbines, coal, liquefied petroleum gas, etc., although with a strong propensity for renewable resources, or renewable distributed energy resources -DER), and have a variable architecture according to the advantage of generating energy primarily from one or another energy source. This variable topology makes microgrid control and protection complex and an open-ended engineering research problem [4,5], particularly when considering power flow problems, load sharing, voltage regulation and mitigation of various kinds of power quality issues [6].A great energetic advantage of the microgrids is their greater electrical efficiency when feeding electronic type loads as variable speed drives and LED loads, because they do not need AC/DC and DC/AC converters when feeding them directly in direct current (DC) [7,8]. The DC power supply system has other advantages over the AC (alternating current) system, for example, it has higher reliability and lower cost (disappear problems of reactive power control, skin effect and frequency synchronisation).Among the main issues in the design and control of a DC microgrid are the selection of power converter topologies, voltage control and load sharing [9,10].…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Hybrid Fuzzy-Sliding Control Scheme for Bi-directional SEPIC Converter in Renewable Based DC Microgrid

Sarmiento¹,

Martínez²,

Jacinto³

2018

IJET

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This paper describes a hybrid fuzzy-sliding control scheme for bi-directional SEPIC converter in renewable based DC microgrids. The performance of a DC microgrid is directly dependent on the voltage stability of the DC bus. In operation, the voltage level of the system is affected by the power injection of the power sources connected to the microgrid, in particular those dependent on environmental factors (such as sun and wind), and by the power consumption of non-constant loads. This feature of microgrids makes control a complex engineering problem. Considering this problem, we propose a hybrid control scheme for a SEPIC bi-directional converter capable of regulating the power flow and stabilizing the system's DC bus. Proposed control technique is simulated in a 48 V DC microgrid and results are provided.Keyword -Bi-directional converter, Fuzzy-sliding control, Microgrid, SEPIC converter I. INTRODUCTION Colombia has large regions without electricity service (the coverage of electricity service is only 34%), are regions isolated from the traditional power grid (about 52% of the national territory, and inhabited by about 1,800,000 people) which have been called Non-Interconnected Zones (ZNI) [1]. There are many reasons for this type of deprivation of electricity service, but the most common reason is the high cost of installing the network to power an area with low population density. The most promising solution for supplying electricity to these areas is the installation of microgrids. The global market trend indicates that microgrids are becoming consolidated as an energy solution for the end user (and not necessarily for those not connected to the traditional power grid) that can even bring economic benefits [2].A microgrid is a localized group of different kinds of electrical energy sources, which work together to meet the energy needs of a specific area, and which can operate either in conjunction with the traditional power grid or in isolation [3]. This microgrid integrates different energy sources according to the energy availability of the area (solar energy, wind turbines, coal, liquefied petroleum gas, etc., although with a strong propensity for renewable resources, or renewable distributed energy resources -DER), and have a variable architecture according to the advantage of generating energy primarily from one or another energy source. This variable topology makes microgrid control and protection complex and an open-ended engineering research problem [4,5], particularly when considering power flow problems, load sharing, voltage regulation and mitigation of various kinds of power quality issues [6].A great energetic advantage of the microgrids is their greater electrical efficiency when feeding electronic type loads as variable speed drives and LED loads, because they do not need AC/DC and DC/AC converters when feeding them directly in direct current (DC) [7,8]. The DC power supply system has other advantages over the AC (alternating current) system, for example, it has higher reliability and lower cos...

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Decentralized Mode-Adaptive Guidance and Control for DC Microgrid

Cited by 45 publications

References 22 publications

Distributed Economic Power Dispatch and Bus Voltage Control for Droop-Controlled DC Microgrids

Distributed Economic Power Dispatch and Bus Voltage Control for Droop-Controlled DC Microgrids

Optimal and Decentralized Control Strategies for Inverter-Based AC Microgrids

Hybrid Fuzzy-Sliding Control Scheme for Bi-directional SEPIC Converter in Renewable Based DC Microgrid

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