Synchronization of three-phase converters and virtual microgrid implementation utilizing the Power-Hardware-in-the-Loop concept

Vodyakho, O.; Edrington, Chris S.; Steurer, M.; Azongha, S.; Fleming, F.

doi:10.1109/apec.2010.5433667

Cited by 19 publications

(5 citation statements)

References 7 publications

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“…Instead, an emerging approach is to test one or more ICSs by connecting them to a software-simulated distribution system model, which may also include other ICSs. This mixed fullpower hardware and software simulation approach, often called power hardware-in-the-loop (PHIL), has been used extensively to test many complex systems including small (<10 kW) [5], [6], [7], and large (500 kW) [8] grid-connected PV inverters, PV/super capacitor systems for power quality control [9], a microgrid-connected STATic synchronous COMpensator [10], and EPS-connected motor drives at the 25 kVA [11] and 5 MVA [12] power levels.…”

Section: System Evaluation Using Hardware-in-the-loop Techniquesmentioning

confidence: 99%

Implementation and validation of advanced unintentional islanding testing using power hardware-in-the-loop (PHIL) simulation

Lundstrom

Mather

Shirazi

et al. 2013

2013 IEEE 39th Photovoltaic Specialists Conference (PVSC)

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Unprecedented investment in new renewable power (especially solar photovoltaic) capacity is occurring. As this new generation capacity is interconnected with the electric power system (EPS), it is critical that their grid interconnection systems have proper controls in place so that they react appropriately in case of an unintentional islanding event. Advanced controls and methods for unintentional islanding protection that go beyond existing standards, such as UL 1741 and IEEE Std 1547, are often required as more complex high penetration photovoltaic installations occur. This paper describes the implementation, experimental results, and validation of a power hardware-in-theloop (PHIL)-based platform that allows for the rapid evaluation of advanced anti-islanding and other controls in complex scenarios. The PHIL-based approach presented allows for accurate, real-time simulation of complex scenarios by connecting a device under test to a software-based model of a local EPS. This approach was validated by conducting an unintentional islanding test of a photovoltaic inverter, as described in IEEE 1547.1, using both PHIL and discrete hardware-based test configurations. The comparison of the results of these two experiments demonstrates that this novel PHIL-based test platform accurately emulates traditional unintentional islanding tests. The advantage of PHIL-based testing over discrete hardware-only testing is demonstrated by completing an IEEE 1547.1 unintentional islanding test using a very precisely tuned resonant circuit that is difficult to realize with discrete hardware using PHIL.Index Terms -unintentional islanding, power hardware-inthe-loop (PHIL), hardware-in-the-loop (HIL), inverter, interconnection, IEEE Std 1547, loss-of-mains, photovoltaic (PV), high penetration.

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Section: System Evaluation Using Hardware-in-the-loop Techniquesmentioning

confidence: 99%

Implementation and validation of advanced unintentional islanding testing using power hardware-in-the-loop (PHIL) simulation

Lundstrom

Mather

Shirazi

et al. 2013

2013 IEEE 39th Photovoltaic Specialists Conference (PVSC)

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“…Concerning FACTSs, PHIL simulations were performed in [114]; however, a hardware PV inverter was used, while a D-STATCOM was simulated in the DRTS. PHIL simulation for studying the synchronization issues of voltage source converters, including STATCOMs, was performed in [115]. Contrary to CHIL simulation, where only the control system is tested, in PHIL simulation, the hardware power device is tested, which includes both the control system and power circuit.…”

Section: Hardware In the Loop Testing Of Factsmentioning

confidence: 99%

FACTS Providing Grid Services: Applications and Testing

et al. 2019

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The role of flexible alternating current transmission systems (FACTSs) in the provision of grid services is becoming increasingly important, due to the massive integration of intermittent renewable energy sources, energy storage systems, and the decommissioning of thermal plants. A comprehensive literature review of grid services offered by FACTS is performed, focusing on the different grid services that they can provide, such as power flow control, reactive power control, voltage control, power quality improvement, harmonic mitigation, improvement of transient stability, and damping of inter-area and intra-area oscillations. These grid services need to be realistically and economically validated in suitable testing environments. A review of relevant standards, guides, and the literature is performed, which covers the entire range from functional specification and factory testing up to the field testing of FACTS. Advanced industry practices, such as controller hardware in the loop (CHIL) testing of FACTS controllers by the manufacturer, and recent trends, such as CHIL testing of replica controllers by the owner, are underlined. Limitations of conventional testing and CHIL testing are explained and the use of power hardware in the loop (PHIL) simulation for FACTS testing is discussed. CHIL and scaled-down PHIL tests on a transmission static synchronous compensator (STATCOM) are performed and a comparison of the results is presented.

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“…Several researches involve the PHIL concept using the Real Time Digital Simulation (RTDS) [6] as a powerful tool to perform flexible and high-speed real time simulations [1][2][3], [7][8][9][10][11][12][13][14]. RTDS uses a graphical environment to build up the simulated network of any complexity.…”

Section: Introductionmentioning

confidence: 99%

Real-Time Simulation Technique of a Microgrid Model for DER Penetration

Mentesidi¹,

Rikos²,

Kleftakis³

2014

EAI Endorsed Transactions on Energy Web

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Comprehensive analysis of Distributed Energy Resources (DER) integration requires tools that provide computational power and flexibility. In this context, throughout this paper PHIL simulations are performed to emulate the energy management system of a real microgrid including a diesel synchronous machine and inverter-based sources. Moreover, conventional frequency and voltage droops were incorporated into the respective inverters. The results were verified at the real microgrid installation in the Centre for Renewable Energy Sources (CRES) premises. This research work is divided into two steps: A) Real time in RSCAD/RTDS and Power Hardware-in-the-Loop (PHIL) simulations where the diesel generator´s active power droop control is evaluated, the battery inverter´s droop curves are simulated and the load sharing for parallel operation of the system´s generation units is examined. B) microgrid experiments during which various tests were executed concerning the diesel generator and the battery inverters in order to examine their dynamic operation within the LV islanded power system.

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Synchronization of three-phase converters and virtual microgrid implementation utilizing the Power-Hardware-in-the-Loop concept

Cited by 19 publications

References 7 publications

Implementation and validation of advanced unintentional islanding testing using power hardware-in-the-loop (PHIL) simulation

Implementation and validation of advanced unintentional islanding testing using power hardware-in-the-loop (PHIL) simulation

FACTS Providing Grid Services: Applications and Testing

Real-Time Simulation Technique of a Microgrid Model for DER Penetration

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