Single‐phase rectifier circuit with output voltage enhancement for automotive generators

Abstract: This study presents a new concept for single-phase diode bridge rectifier circuits applied to automotive applications. The proposed circuit is able to enhance the output voltage to a much higher output level over a wide load range compared to the classical single-phase diode bridge rectifier without using complex control algorithms. This is achieved by embedding two capacitors and two switches to a new designed diode bridge converter topology. The embedded capacitors are charged and discharged simultaneously w… Show more

“…Next step is to implement an effective monitoring technique which generally depends on two essential aspects [27]: Various innovative monitoring techniques have been proposed to capture and indicate the electrical parameters of electrolytic capacitors in real-time [7,14,23,24,[28][29][30]. Most of these methods are based on ESR estimation which can be implemented through two main approaches [31,32]: † ESR = (V CRMS /I CRMS ), where V CRMS and I CRMS are the RMS voltage and RMS current of capacitor, respectively. † ESR = P C /I 2 CRMS , where P C and I CRMS are the average dissipated power and RMS current of capacitor, respectively.…”

“…Next step is to implement an effective monitoring technique which generally depends on two essential aspects [27]: Capturing and indicating the real‐time electrical parameters of capacitor including ESR and/or capacitance. Predicting the EOL of the component for preventive maintenance. Various innovative monitoring techniques have been proposed to capture and indicate the electrical parameters of electrolytic capacitors in real‐time [7, 14, 23, 24, 28–30]. Most of these methods are based on ESR estimation which can be implemented through two main approaches [31, 32]: ESR = ( V CRMS / I CRMS ), where V CRMS and I CRMS are the RMS voltage and RMS current of capacitor, respectively. , where P C and I CRMS are the average dissipated power and RMS current of capacitor, respectively. These two general approaches have been compared and discussed in [32]. Since the real‐time ESR estimation technique is out of the scope of this research, more details regarding this topic can be found in the introduced references.…”

Fractional order equivalent series resistance modelling of electrolytic capacitor and fractional order failure prediction with application to predictive maintenance

“…Next step is to implement an effective monitoring technique which generally depends on two essential aspects [27]: Various innovative monitoring techniques have been proposed to capture and indicate the electrical parameters of electrolytic capacitors in real-time [7,14,23,24,[28][29][30]. Most of these methods are based on ESR estimation which can be implemented through two main approaches [31,32]: † ESR = (V CRMS /I CRMS ), where V CRMS and I CRMS are the RMS voltage and RMS current of capacitor, respectively. † ESR = P C /I 2 CRMS , where P C and I CRMS are the average dissipated power and RMS current of capacitor, respectively.…”

“…Next step is to implement an effective monitoring technique which generally depends on two essential aspects [27]: Capturing and indicating the real‐time electrical parameters of capacitor including ESR and/or capacitance. Predicting the EOL of the component for preventive maintenance. Various innovative monitoring techniques have been proposed to capture and indicate the electrical parameters of electrolytic capacitors in real‐time [7, 14, 23, 24, 28–30]. Most of these methods are based on ESR estimation which can be implemented through two main approaches [31, 32]: ESR = ( V CRMS / I CRMS ), where V CRMS and I CRMS are the RMS voltage and RMS current of capacitor, respectively. , where P C and I CRMS are the average dissipated power and RMS current of capacitor, respectively. These two general approaches have been compared and discussed in [32]. Since the real‐time ESR estimation technique is out of the scope of this research, more details regarding this topic can be found in the introduced references.…”

Fractional order equivalent series resistance modelling of electrolytic capacitor and fractional order failure prediction with application to predictive maintenance

Iterated extended Kalman filter based state estimation of diode circuit

Experimental tests regarding diagnosis of some faults of car alternators