Exploring the Causes of Power-Converter Failure in Wind Turbines based on Comprehensive Field-Data and Damage Analysis

Fischer, Katharina; Pelka, Karoline; Puls, Sebastian; Poech, Max-Hermann; Mertens, Axel; Bartschat, Arne; Tegtmeier, Bernd; Broer, Christian; Wenske, Jan

doi:10.3390/en12040593

Cited by 22 publications

(22 citation statements)

References 24 publications

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“…The failure and repair rates associated with the composed components of the studied SSG converter can be obtained from the manufacturer information. However, due to the lack of reliable data, the failure and repair rates of different components can be determined as presented in [17][18][19][20]. Based on the reliability data obtained for different components, in this paper, the equivalent failure and repair rates of the SSG converter are considered to be 2 and 98 times per year, respectively.…”

Section: Numerical Resultsmentioning

confidence: 99%

Reliability assessment of composite power systems containing sea wave slot‐coned generators

Ghaedi

Gorginpour

2020

IET Renewable Power Generation

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Section: Numerical Resultsmentioning

confidence: 99%

Reliability assessment of composite power systems containing sea wave slot‐coned generators

Ghaedi

Gorginpour

2020

IET Renewable Power Generation

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“…A fault in any component of a power conversion chain can result in a partial or total loss of system control and an unplanned maintenance leading to significant production losses. In other situations, these faults can lead to disastrous consequences and risks for personnel, facilities, and the environment, especially when the systems are integrated into safety-relevant facilities such as transport, health, power grids, robotics, or nuclear power plants [7].…”

Section: Introductionmentioning

confidence: 99%

Frequency Response Analysis Technique of Short Circuit Faults Detection in Photovoltaic Single-Phase Inverter Experimental Study

Ouadfel¹,

Hamza²,

Abderzak³

et al. 2021

EJEE

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The work proposed in this paper concerns the study of short circuit faults in a single-phase inverter dedicated to a photovoltaic application by applying the frequency response analysis (FRA) technique on this IGBT-based inverter controlled by a 18F2550 microcontroller, a prototype inverter was designed in the laboratory to be able to apply off-line short-circuit faults using an LRC meter. The FRA technique is based on the comparison of amplitude-frequency and phase-frequency signatures of healthy cases and fault situations. The experimental results also led to the conclusion that frequency response analysis can be used as an effective tool to detect faults in power electronic devices. This method allows for efficient detection and classification of faults with ease of implementation. For fault location, the fault branch is determined according to its position relative to its healthy state.

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“…Multiple studies have identified converters as one of the most frequently failing subsystem in WTs [3,4]. Among converter components, phase modules (insulated gate bipolar transistors (IGBTs), gate-drive circuits, capacitors) were found to be more critical in terms of failure frequency [3,5,6].…”

Section: Introductionmentioning

confidence: 99%

“…Thermal cycling is not the only failure mechanism in IGBT modules. Fischer et al [5] identified ambient humidity and moisture as the dominant failure mechanism in WT converters. However, in their study majority of the converters were liquid-cooled.…”

Section: Introductionmentioning

confidence: 99%

Lifetime Analysis of IGBT Power Modules in Passively Cooled Tidal Turbine Converters

et al. 2020

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Thermal cycling is one of the major reasons for failure in power electronic converters. For submerged tidal turbine converters investigating this failure mode is critical in improving the reliability, and minimizing the cost of energy from tidal turbines. This paper considers a submerged tidal turbine converter which is passively cooled by seawater, and where the turbine has fixed-pitch blades. In this respect, this study is different from similar studies on wind turbine converters, which are mostly cooled by active methods, and where turbines are mostly pitch controlled. The main goal is to quantify the impact of surface waves and turbulence in tidal stream velocity on the lifetime of the converter IGBT (insulated gate bipolar transistor) modules. The lifetime model of the IGBT modules is based on the accumulation of fatigue due to thermal cycling. Results indicate that turbulence and surface waves can have a significant impact on the lifetime of the IGBT modules. Furthermore, to accelerate the speed of the lifetime calculation, this paper uses a modified approach by dividing the thermal models into low and high frequency models. The final calculated lifetime values suggest that relying on passive cooling could be adequate for the tidal converters as far as thermal cycling is concerned.

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Exploring the Causes of Power-Converter Failure in Wind Turbines based on Comprehensive Field-Data and Damage Analysis

Cited by 22 publications

References 24 publications

Reliability assessment of composite power systems containing sea wave slot‐coned generators

Reliability assessment of composite power systems containing sea wave slot‐coned generators

Frequency Response Analysis Technique of Short Circuit Faults Detection in Photovoltaic Single-Phase Inverter Experimental Study

Lifetime Analysis of IGBT Power Modules in Passively Cooled Tidal Turbine Converters

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