Equipment for Monitoring Synchronous Generators Condition through External Magnetic Field Waveforms

Abstract: This paper presents an equipment for monitoring synchronous generators condition through characteristics of the time derivative of the external magnetic field. The developed monitoring methodology allows the identification of established or incipient faults, by detecting changes in the magnetic signature of the synchronous generator. In this methodology, the measurement of signals outside the machine gives this equipment a non-invasive characteristic, allowing its monitoring without interfering or disturbing i… Show more

“…The induction sensors with nonmagnetic cores are associated with cascaded differential amplifier circuits with variable gains that internally adapt the output signal levels for the digitization step. The system is thus able to measure field amplitudes from mA/m to kA/m at the electrical fundamental frequency [8,22]. In this way, the installation of sensors around the machine becomes easier and adaptable to various configurations and machine types.…”

“…Different regions of the frequency spectrum can be sensitized depending on the type of fault [8]. An extensive experimental investigation performed on generators for different ratings indicates the need to analyze the spectrum in the range from 𝑓 to 3 kHz, or at least up to 1.5 times the slot frequency, defined as 𝑓 = 𝑓 𝑛 , where 𝑛 is the number of stator slots [22]. With the employed hardware [8,22], this strategy allows the detection of faults with greater influence in the high-frequency region, a typical behavior of stator Different regions of the frequency spectrum can be sensitized depending on the type of fault [8].…”

“…An extensive experimental investigation performed on generators for different ratings indicates the need to analyze the spectrum in the range from 𝑓 to 3 kHz, or at least up to 1.5 times the slot frequency, defined as 𝑓 = 𝑓 𝑛 , where 𝑛 is the number of stator slots [22]. With the employed hardware [8,22], this strategy allows the detection of faults with greater influence in the high-frequency region, a typical behavior of stator Different regions of the frequency spectrum can be sensitized depending on the type of fault [8]. An extensive experimental investigation performed on generators for different ratings indicates the need to analyze the spectrum in the range from f m to 3 kHz, or at least up to 1.5 times the slot frequency, defined as f s = f m n s , where n s is the number of stator slots [22].…”

“…Recent publications have reported the investigation of the magnetic signature characteristics obtained by measuring the external magnetic field for incipient fault detection purposes [4,6,[17][18][19][20][21][22]. Although several monitoring strategies have been proposed, most of these approaches are based on spot comparisons of measured frequency spectra, comparing only instantaneous magnetic signatures with and without a defect.…”

“…Although several monitoring strategies have been proposed, most of these approaches are based on spot comparisons of measured frequency spectra, comparing only instantaneous magnetic signatures with and without a defect. For the continuous condition monitoring of the SGs, necessary for the practical application of these methodologies in monitoring equipment, some works have already pointed out the need for periodic monitoring of these spectra, but have not approached any technique for automatic detection of changes that may be associated with incipient faults [8,20,22]. In addition, both the internal and external magnetic field monitoring techniques still lack standards to guide the interpretation of the measured quantities and the fault detection itself, such as those regarding mechanical vibration [23].…”

A Method for Statistical Processing of Magnetic Field Sensor Signals for Non-Invasive Condition Monitoring of Synchronous Generators

“…The induction sensors with nonmagnetic cores are associated with cascaded differential amplifier circuits with variable gains that internally adapt the output signal levels for the digitization step. The system is thus able to measure field amplitudes from mA/m to kA/m at the electrical fundamental frequency [8,22]. In this way, the installation of sensors around the machine becomes easier and adaptable to various configurations and machine types.…”

“…Different regions of the frequency spectrum can be sensitized depending on the type of fault [8]. An extensive experimental investigation performed on generators for different ratings indicates the need to analyze the spectrum in the range from 𝑓 to 3 kHz, or at least up to 1.5 times the slot frequency, defined as 𝑓 = 𝑓 𝑛 , where 𝑛 is the number of stator slots [22]. With the employed hardware [8,22], this strategy allows the detection of faults with greater influence in the high-frequency region, a typical behavior of stator Different regions of the frequency spectrum can be sensitized depending on the type of fault [8].…”

“…An extensive experimental investigation performed on generators for different ratings indicates the need to analyze the spectrum in the range from 𝑓 to 3 kHz, or at least up to 1.5 times the slot frequency, defined as 𝑓 = 𝑓 𝑛 , where 𝑛 is the number of stator slots [22]. With the employed hardware [8,22], this strategy allows the detection of faults with greater influence in the high-frequency region, a typical behavior of stator Different regions of the frequency spectrum can be sensitized depending on the type of fault [8]. An extensive experimental investigation performed on generators for different ratings indicates the need to analyze the spectrum in the range from f m to 3 kHz, or at least up to 1.5 times the slot frequency, defined as f s = f m n s , where n s is the number of stator slots [22].…”

“…Recent publications have reported the investigation of the magnetic signature characteristics obtained by measuring the external magnetic field for incipient fault detection purposes [4,6,[17][18][19][20][21][22]. Although several monitoring strategies have been proposed, most of these approaches are based on spot comparisons of measured frequency spectra, comparing only instantaneous magnetic signatures with and without a defect.…”

“…Although several monitoring strategies have been proposed, most of these approaches are based on spot comparisons of measured frequency spectra, comparing only instantaneous magnetic signatures with and without a defect. For the continuous condition monitoring of the SGs, necessary for the practical application of these methodologies in monitoring equipment, some works have already pointed out the need for periodic monitoring of these spectra, but have not approached any technique for automatic detection of changes that may be associated with incipient faults [8,20,22]. In addition, both the internal and external magnetic field monitoring techniques still lack standards to guide the interpretation of the measured quantities and the fault detection itself, such as those regarding mechanical vibration [23].…”

A Method for Statistical Processing of Magnetic Field Sensor Signals for Non-Invasive Condition Monitoring of Synchronous Generators

Finite Element Analysis of the Noninvasive Detection and Evolution of Faults in a High Power Induction Motor through Neighboring Coil Sensors