The Insulation Resilience of Inverter-Fed Low Voltage Traction Machines: Review, Challenges, and Opportunities

Petri, Timo; Keller, Marina; Parspour, Nejila

doi:10.1109/access.2022.3210348

Cited by 13 publications

(2 citation statements)

References 126 publications

(222 reference statements)

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“…Upcoming challenges: This review has characterised the main power device technologies suitable for HGV applications. Nevertheless, considering the converter implementation, other challenges include EMI/EMC [93][94][95], investigating the impact of high voltage commutation rates on motor insulation reliability [96][97][98], power module/converter designs involving multiple chips in parallel and optimised busbars [99][100][101], thermal management and increased power densities [102,103], short circuit detection [104,105] and application-specific qualification methodologies/guidelines, as suggested by the JEDEC JC-70 guidelines and the ECPE guidelines for the qualification of power modules used in motor vehicles (AQG 324) [106]. The increased commercial availability of higher voltage devices (1.7 kV to 3.3 kV rated) may open new avenues for higher voltage charger designs and even higher inverter bus voltages.…”

Section: Discussionmentioning

confidence: 99%

A Review of Power Electronic Devices for Heavy Goods Vehicles Electrification: Performance and Reliability

et al. 2023

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This review explores the performance and reliability of power semiconductor devices required to enable the electrification of heavy goods vehicles (HGVs). HGV electrification can be implemented using (i) batteries charged with ultra-rapid DC charging (350 kW and above); (ii) road electrification with overhead catenaries supplying power through a pantograph to the HGV powertrain; (iii) hydrogen supplying power to the powertrain through a fuel cell; (iv) any combination of the first three technologies. At the heart of the HGV powertrain is the power converter implemented through power semiconductor devices. Given that the HGV powertrain is rated typically between 500 kW and 1 MW, power devices with voltage ratings between 650 V and 1200 V are required for the off-board/on-board charger’s rectifier and DC-DC converter as well as the powertrain DC-AC traction inverter. The power devices available for HGV electrification at 650 V and 1.2 kV levels are SiC planar MOSFETs, SiC Trench MOSFETs, silicon super-junction MOSFETs, SiC Cascode JFETs, GaN HEMTs, GaN Cascode HEMTs and silicon IGBTs. The MOSFETs can be implemented with anti-parallel SiC Schottky diodes or can rely on their body diodes for third quadrant operation. This review examines the various power semiconductor technologies in terms of losses, electrothermal ruggedness under short circuits, avalanche ruggedness, body diode and conduction performance.

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Section: Discussionmentioning

confidence: 99%

A Review of Power Electronic Devices for Heavy Goods Vehicles Electrification: Performance and Reliability

et al. 2023

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“…A higher voltage also poses challenges in the design of electrical components and systems. Higher voltages imply higher stress on the passive components and the winding insulations of the iPMSM [3]- [7], or a higher cosmic ray failure rate of the semiconductors [8], [9], which can lead to a reduced lifetime of the components. Moreover, the high battery voltage, and thus the DC-Link voltage, leads to disadvantages during the operation of the electric drive.…”

Section: Introductionmentioning

confidence: 99%

A Pareto Based Comparison of DC/DC Converters for Variable DC-Link Voltage in Electric Vehicles

Velić,

Becher,

Parspour

2023

IEEE Open J. Power Electron.

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High battery voltages increase inverter switching and harmonic losses of the electric machine. These losses dominate at low speeds in the partial load range, where the customer relevant Worldwide Harmonized Light Vehicles Test Procedure (WLTC) driving cycle is located. By installing a bidirectional DC/DC converter between the inverter and the battery, the input voltage of the inverter can be adjusted to various torque/speed conditions, thereby enhancing the efficiency and range of the electric sports car. Outside of the WLTC, the DC/DC converter is not operated and is short-circuited by a bypass. Additionally, the utilization of synchronous modulation methods, as opposed to space vector pulse width modulation (SVPWM), within the WLTC is made possible by the variable DC-Link voltage, further reducing switching and harmonic losses. In this paper, different topologies of DC/DC converters are proposed. The investigations are conducted on an 800 V system. To facilitate this, a script-based toolchain was developed based on analytic and fast calculating waveform models. The impact of the DC-Link voltage on energy efficiency during the WLTC is examined, and sensitivities are presented. A multi-objective optimization is carried out based on the WLTC driving cycle to demonstrate the maximum trade-offs between increasing the electric range and the power density of the DC/DC converter.

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A novel interpolator designed for laser scanning welding of hairpin windings in electric vehicle motors

Zhu,

Zhang,

Yin

2024

Int J Adv Manuf Technol

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The Insulation Resilience of Inverter-Fed Low Voltage Traction Machines: Review, Challenges, and Opportunities

Cited by 13 publications

References 126 publications

A Review of Power Electronic Devices for Heavy Goods Vehicles Electrification: Performance and Reliability

A Review of Power Electronic Devices for Heavy Goods Vehicles Electrification: Performance and Reliability

A Pareto Based Comparison of DC/DC Converters for Variable DC-Link Voltage in Electric Vehicles

A novel interpolator designed for laser scanning welding of hairpin windings in electric vehicle motors

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