Failure Mode, Effects and Criticality Analysis (FMECA) in Power Electronic based Power Systems

Power electronics is becoming an underpinning technology for modern power systems. Power converters are increasingly used in various applications implying different levels of importance in power systems. Hence, optimal decision-making for manufacturing, control, operation and maintenance of them requires understanding of their importance in the power systems. Furthermore, identifying the converters importance may be beneficial for simplifying the system-level reliability modeling in a large Power Electronic based Power Systems (PEPSs). Thereby, a Failure Mode, Effects and Criticality Analysis (FMECA) approach is proposed in this paper in order to figure out the importance of converters in PEPSs. The failure modes are classified by contingency analysis and their effects are predicted by a power system risk measure. Afterwards, the critical modes and critical components are identified. The FMECA is exemplified by a wind farm connected to the grid through an HVDC transmission system. The obtained results imply the criticality of the HVDC control system, its DC filters followed by its converters.

[1]  Saeed Peyghami,et al.  System-Level Reliability-Oriented Power Sharing Strategy for DC Power Systems , 2019, IEEE Transactions on Industry Applications.

[2]  Qiuwei Wu,et al.  A Combined Reliability Model of VSC-HVDC Connected Offshore Wind Farms Considering Wind Speed Correlation , 2017, IEEE Transactions on Sustainable Energy.

[3]  Ramtin Hadidi,et al.  Third eGrid Workshop Maps the Grid of the Future: Attendees Engage to Examine the Role of Power Electronic Applications in Modern Electric Power Systems , 2019, IEEE Power Electronics Magazine.

[4]  Simon Hogg,et al.  Wind energy: UK experiences and offshore operational challenges , 2015 .

[5]  Y. V. Makarov Probabilistic assessment of the energy not produced due to transmission constraints , 2003, 2003 IEEE Bologna Power Tech Conference Proceedings,.

[6]  L. Moore,et al.  Five years of operating experience at a large, utility‐scale photovoltaic generating plant , 2008 .

[7]  Saeed Peyghami,et al.  Decentralized Droop Control in DC Microgrids Based on a Frequency Injection Approach , 2019, IEEE Transactions on Smart Grid.

[8]  Huai Wang,et al.  Mission Profile Based Power Converter Reliability Analysis in a DC Power Electronic Based Power System , 2018, 2018 IEEE Energy Conversion Congress and Exposition (ECCE).

[9]  K. Morison,et al.  Power system security assessment , 2004, IEEE Power and Energy Magazine.

[10]  Marco Liserre,et al.  Reliability of Power Electronic Systems: An Industry Perspective , 2018, IEEE Industrial Electronics Magazine.

[11]  A. Golnas,et al.  PV system reliability: An operator's perspective , 2013, 2012 IEEE 38th Photovoltaic Specialists Conference (PVSC) PART 2.

[12]  Frede Blaabjerg,et al.  The Impact of Topology and Mission Profile on the Reliability of Boost-type Converters in PV Applications , 2018, 2018 IEEE 19th Workshop on Control and Modeling for Power Electronics (COMPEL).

[13]  L. Bertling,et al.  Reliability-Centered Maintenance for Wind Turbines Based on Statistical Analysis and Practical Experience , 2012, IEEE Transactions on Energy Conversion.

[14]  Farrokh Aminifar,et al.  Reliability Evaluation of an HVDC Transmission System Tapped by a VSC Station , 2010, IEEE Transactions on Power Delivery.

[15]  Jan Wenske,et al.  Reliability of Power Converters in Wind Turbines: Exploratory Analysis of Failure and Operating Data From a Worldwide Turbine Fleet , 2019, IEEE Transactions on Power Electronics.

[16]  Callum MacIver,et al.  A Reliability Evaluation of Offshore HVDC Grid Configuration Options , 2016, IEEE Transactions on Power Delivery.