Friedemann Möller scite author profile

This paper presents the results of comprehensive testing, and subsequent detailed analysis of obtained test results, evaluating harmonic and interharmonic performance of PV inverters (PVInvs) for a range of different operating conditions. The presented results indicate significant power-dependent changes in harmonic and interharmonic emissions of tested PVInvs for different supply voltage conditions (presence of voltage waveform distortions and various source impedance values). To correctly quantify and describe these changes inPVInvs' performance, the paper discusses and applies measurement procedures and metrics for evaluating harmonic and interharmonic emission recommended in existing standards, as well as some additional metrics and indicators. For some operating conditions, tested PVInvs significantly increase both harmonic and interharmonic emission, and paper also discusses impact of PVInvs' controls (e.g. maximum power point tracking control) as a possible origin of the interharmonic distortion.

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Stochastic Assessment of Voltage Unbalance Due to Single-Phase-Connected Solar Power

Schwanz

Möller

Rönnberg

et al. 2017

IEEE Trans. Power Delivery

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A stochastic method is presented in this paper to estimate the future voltage unbalance in a low-voltage distribution network with high-penetration of single-phase photovoltaic inverters (PVIs). Location and phase allocation of the PVIs are considered as input parameters for the stochastic simulation. The method has been applied to three different lowvoltage networks: two in Sweden and one in Germany. In the Swedish networks, for 6-kW single-phase PVIs, it is likely that the contribution from single-phase photovoltaic inverters to the voltage unbalance exceeds 1%. The 2% value is unlikely to be exceeded. In the German network, for 4.6-kW single-phase PVIs the voltage unbalance is between 1.35% and 2.62%.The risk of high voltage unbalance can be reduced by a combination of controlled distribution over the phases and reduction of the maximum size for a single-phase PVI.

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Stochastic assessment of voltage unbalance due to single-phase-connected solar power

Schwanz

Möller

Rönnberg

et al. 2016

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Component-based modelling of EV battery chargers

Molin

Kourtza

et al. 2015

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Analysis and Modelling of Power-Dependent Harmonic Characteristics of Modern PE Devices in LV Networks

Collin

Djokić

et al. 2017

IEEE Trans. Power Delivery

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This paper presents results of experimental and analytical evaluation of power-dependent harmonic emission of three common types of modern low voltage (LV) power electronic (PE) devices. After a detailed analysis of comprehensive test results, based on both existing and new waveform distortion indices, the development of component-based models of PE devices is discussed. The paper demonstrates the importance of including PE devices' controls for accurate modelling of their characteristics over the entire range of operating powers. Most of the analysed PE devices exhibit strong power-dependent changes of characteristics, additionally influenced by supply voltage conditions, which are important for the analysis of both existing networks and future "smart grids". ).testing of EVBCs, despite the fact that the power during the charging cycle is variable, and will typically reduce during the latter stages. Test procedures for power-generating LV PE devices do consider variable power operation, with [3] and [5] specifying test points at 100% and 50% (and 25% in [3]) of P rated for PVIs. However, the actual output of any PVI can be, and often is lower, dependent on ambient conditions. Across the operating range, the performance of the internal control circuits of a PE device may be compromised, altering the device's characteristics. This may have a negative impact on the supply grid when such equipment is connected in large numbers. This paper presents a detailed experimental-based characterization of a number of SMPS', EVBCs and PVIs across their entire operational ranges and for different supply conditions. Two new indices are introduced for the analysis, which allow separate assessment of the contributions from the low-frequency (LF) harmonics and all other waveform distortions to the device's total operating current. This is of particular importance for the analysis of modern PE devices, for which LF harmonics might not be the most significant part of the total waveform distortion (e.g. [8]). The analysis of measurements is supported by the development of componentbased (circuit-based) models, capable of correctly reproducing the harmonic characteristics over the entire operating range.This paper shows that mostof tested PE devices exhibit distinctive power-dependent performance changes. The impact of realistic supply voltage conditions, i.e. distorted voltage and source impedance, on device characteristics is also considered and is shown to have considerable impact on certain types of equipment. Particular attention is given to the increased distortion in low and very low power operating modes (defined as below 30% and 10% of P rated ), as this issue has received limited attention in literature and is not fully captured by existing indices. When operating in very low power mode, some of the measured PE devices enter unstable operating regions or disconnect (i.e. 'trip' via their internal protection). These effects signify the importance of PE devices' controls when evaluating and modelling power-dependent changes in...

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