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In order to simplify the application and improve diagnostic speed of the diagnostics, a novel method to diagnose multiple open circuit faults in insulated gate bipolar transistors (IGBTs) by three-phase currents for power inverter in electric vehicles is presented. The summation of currents with semi-period phase-difference is described in diagnostic variables with exploration of the current information in faulty condition. In contrast with plentiful existing methods which rely on the motor models and control parameters, this algorithm merely requires phase currents. Meanwhile, the normalized way based on the absolute phase currents and variable parameter moving average method are applied to improve the diagnostic speed and independence of load variation, which contributes to the real-time application in the electric vehicles. Experimental results, using a vector-controlled permanent magnet synchronous motor (PMSM) and digital signal processor MC56F8346, are presented to verify the algorithm effectiveness, showing many features, such as applicability for multiple open circuit faults, well-robustness against false alarms, briefness and agility for the diagnosis function.
Hongqian Wei; Youtong Zhang; Lei Yu; Mengzhu Zhang; Khaled Teffah. A New Diagnostic Algorithm for Multiple IGBTs Open Circuit Faults by the Phase Currents for Power Inverter in Electric Vehicles. Energies 2018, 11, 1508 .
AMA StyleHongqian Wei, Youtong Zhang, Lei Yu, Mengzhu Zhang, Khaled Teffah. A New Diagnostic Algorithm for Multiple IGBTs Open Circuit Faults by the Phase Currents for Power Inverter in Electric Vehicles. Energies. 2018; 11 (6):1508.
Chicago/Turabian StyleHongqian Wei; Youtong Zhang; Lei Yu; Mengzhu Zhang; Khaled Teffah. 2018. "A New Diagnostic Algorithm for Multiple IGBTs Open Circuit Faults by the Phase Currents for Power Inverter in Electric Vehicles." Energies 11, no. 6: 1508.
Khaled Teffah; Youtong Zhang. Corrigendum to “Modeling and experimental research of hybrid PV-thermoelectric system for high concentrated solar energy conversion” [Solar Energy 157 (2017) 10–19]. Solar Energy 2018, 166, 1 .
AMA StyleKhaled Teffah, Youtong Zhang. Corrigendum to “Modeling and experimental research of hybrid PV-thermoelectric system for high concentrated solar energy conversion” [Solar Energy 157 (2017) 10–19]. Solar Energy. 2018; 166 ():1.
Chicago/Turabian StyleKhaled Teffah; Youtong Zhang. 2018. "Corrigendum to “Modeling and experimental research of hybrid PV-thermoelectric system for high concentrated solar energy conversion” [Solar Energy 157 (2017) 10–19]." Solar Energy 166, no. : 1.
In this work, a modeling and experimental study of a new thermoelectric cooler–thermoelectric generator (TEC-TEG) module is investigated. The studied module is composed of TEC, TEG and total system heatsink, all connected thermally in series. An input voltage (1–5 V) passes through the TEC where the electrons by means of Peltier effect entrain the heat from the upper side of the module to the lower one creating temperature difference; TEG plays the role of a partial heatsink for the TEC by transferring this waste heat to the total system heatsink and converting an amount of this heat into electricity by a phenomenon called Seebeck effect, of the thermoelectric modules. The performance of the TEG as partial heatsink of TEC at different input voltages is demonstrated theoretically using the modeling software COMSOL Multiphysics. Moreover, the experiment validates the simulation result which smooths the path for a new manufacturing thermoelectric cascade model for the cooling and the immediate electric power generation.
Khaled Teffah; Youtong Zhang; Xiao-Long Mou. Modeling and Experimentation of New Thermoelectric Cooler–Thermoelectric Generator Module. Energies 2018, 11, 576 .
AMA StyleKhaled Teffah, Youtong Zhang, Xiao-Long Mou. Modeling and Experimentation of New Thermoelectric Cooler–Thermoelectric Generator Module. Energies. 2018; 11 (3):576.
Chicago/Turabian StyleKhaled Teffah; Youtong Zhang; Xiao-Long Mou. 2018. "Modeling and Experimentation of New Thermoelectric Cooler–Thermoelectric Generator Module." Energies 11, no. 3: 576.
An experimental research of a novel combination, within a photovoltaic-thermoelectric (PV-TE) system, for high concentrated solar energy (×300–1000) conversion to electricity is presented. Our hybrid system contains, at its core; a triple junction solar cell (TJSC); a thermoelectric cooler (TEC); a thermoelectric generator (TEG), all settled thermally in series respectively. The thermoelectric cooler enhances the solar cell efficiency by pumping its excess heat through the Peltier effect; the thermoelectric generator plays the role of a heat sink for the TEC, converting some of this waste-heat into electricity by means of the Seebeck effect. The basic steady state finite element modeling demonstrates the contribution of the TEC-TEG Module, inflating the overall efficiency of the hybrid system for high solar concentrated irradiation; the experimental and simulation results are matched. All of which evokes a new system that takes into consideration the PV electric power generation, without compromising the cooling potential and the immediate electric production of the thermoelectric devices.
Khaled Teffah; Youtong Zhang. Modeling and experimental research of hybrid PV-thermoelectric system for high concentrated solar energy conversion. Solar Energy 2017, 157, 10 -19.
AMA StyleKhaled Teffah, Youtong Zhang. Modeling and experimental research of hybrid PV-thermoelectric system for high concentrated solar energy conversion. Solar Energy. 2017; 157 ():10-19.
Chicago/Turabian StyleKhaled Teffah; Youtong Zhang. 2017. "Modeling and experimental research of hybrid PV-thermoelectric system for high concentrated solar energy conversion." Solar Energy 157, no. : 10-19.
To improve the diagnostic detection speed in electric vehicles, a novel diagnostic algorithm of insulated gate bipolar transistor (IGBT) open circuit faults for power inverters is proposed in this paper. The average of the difference between the actual three-phase current and referential three-phase current values over one electrical period is used as the diagnostic variable. The normalization method based on the amplitude of the d-q axis referential current is applied to the diagnostic variables to improve the response speed of diagnosis, and to avoid the noise and the delay caused by signal acquisition. In the parameter discretization process, the variable parameter moving average method (VPMAM) is adopted to solve the variation of the average value over a period with the speed of the motor; hence, the diagnostic reliability of the system is improved. This algorithm is robust, independent of load variations, and has a high resistivity against false alarms. Since only the three-phase current of the motor is utilized for calculations in the time domain, a fast diagnostic detection speed can be achieved, which is significantly essential for real-time control in electric vehicles. The effectiveness of the proposed algorithm is verified by both simulation and experimental results.
Lei Yu; Youtong Zhang; Wenqing Huang; Khaled Teffah. A Fast-Acting Diagnostic Algorithm of Insulated Gate Bipolar Transistor Open Circuit Faults for Power Inverters in Electric Vehicles. Energies 2017, 10, 552 .
AMA StyleLei Yu, Youtong Zhang, Wenqing Huang, Khaled Teffah. A Fast-Acting Diagnostic Algorithm of Insulated Gate Bipolar Transistor Open Circuit Faults for Power Inverters in Electric Vehicles. Energies. 2017; 10 (4):552.
Chicago/Turabian StyleLei Yu; Youtong Zhang; Wenqing Huang; Khaled Teffah. 2017. "A Fast-Acting Diagnostic Algorithm of Insulated Gate Bipolar Transistor Open Circuit Faults for Power Inverters in Electric Vehicles." Energies 10, no. 4: 552.