Patent Description:
<CIT> describes a detector used for partial dicharge detection apparatus for insulation diagnosis of electric equipment. <CIT>discloses a partial discharge monitoring system, comprising multiple partial discharge transducers, each partial discharge transducer comprising a partial discharge sensor and a LED in series with the sensor. The LED receives an electrical sensor signal from the partial discharge sensor and generates an analog light signal in response to the electrical sensor signal. Each PD transducer further comprises an amplifier and a resistor coupled between the sensor and the LED. The monitoring system also comprises optical fibers coupled to receive light from the LED and configured to carry the analog light signal from a location proximate to the electrical system to a location remote from the electrical system, where there is a light receiving device.

Embodiments not falling within the scope of the claims are expelmary only.

Some embodiments are directed to a partial discharge (PD) transducer that includes a PD sensor configured to sense a PD event of an electrical system. At least one light emitting device (LED) is arranged in series with the PD sensor. The LED is configured to receive the electrical sensor signal from the PD sensor and to generate a light signal in response to the electrical sensor signal.

According to some embodiments, the at least one LED comprises a first LED coupled to receive the electrical sensor signal from the PD sensor and to generate a first light signal in response to positive going pulses of the electrical sensor signal. A second LED is arranged in parallel with the first LED. The second LED is coupled to receive the electrical sensor signal from the PD sensor and to generate a second light signal in response to negative going pulses of the electrical sensor signal.

The invention relates to a partial discharge monitoring system according to claim <NUM>. The monitoring system includes multiple PD transducers according to either of the embodiments discussed above. At least one optical fiber is optically coupled to receive light from the LED and to carry the analog light signal from a location proximate to the monitored electrical system to a location remote from the monitored electrical system. At least one light receiving device located at the remote location generates an analog electrical signal in response to the analog light signal.

Some embodiments are directed to a method of obtaining a signal indicative of a PD event. According to the method, a PD event of a monitored electrical system is sensed and an electrical sensor signal is generated in response to the PD event. The electrical sensor signal is converted to an analog light signal. The analog light signal is transmitted from a location of the monitored electrical system to a location remote from the monitored electrical system through an optical fiber. In response to the analog light signal, an analog electrical signal is generated at the remote location.

Although partial discharge (PD) is more likely to occur in high voltage components, e.g., components having operating voltages greater than about <NUM> volts, PD can also affect lower voltage components. Partial discharge sites may correspond to locations where imperfections in the insulation of an electrical device are present. Monitoring a device for PD allows early warning that the device needs to be repaired before more serious failures occur.

Partial discharge (PD) events are localized electrical discharges that only partially bridge the insulation between conductors or between a conductor and ground. Each PD event produces a high frequency electrical signal that can be sensed.

Some embodiments discussed herein are directed to monitoring an electrical device for the occurrence of partial discharge events. The electrical device is an electrically connected component of an electrical system. In one example, the electrical system includes the electrical device, e.g., a transformer, and a connector that connects the transformer to the electrical power grid or to another electrical device.

Some embodiments discussed herein are directed to PD detection circuitry that includes an electrical-optical transducer. <FIG> is a schematic diagram of a PD detection circuitry <NUM> comprising electrical-optical transducer <NUM> configured to convert the electrical sensor signal from a PD sensor <NUM> to a light signal. In general, the PD sensor <NUM> may be any type of PD sensor. For example, the PD sensor <NUM> may be or comprise a capacitive coupling sensor. The PD sensor <NUM> may be or comprise a transient earth voltage sensor, or a high frequency coupling capacitor. The transducer <NUM> comprises a light emitting device (LED) <NUM> in series with the PD sensor <NUM>. In the invention there is included a current limiting resistor either in series or in parallel with the LED <NUM>.

The LED <NUM> may comprise a light emitting diode or laser, for example. The PD sensor <NUM> generates an electrical signal that causes a current to flow in the loop indicated by arrow <NUM>. The electrical signal drives the LED <NUM> which generates an analog light signal <NUM> indicative of the PD event in response to the electrical signal. The LED <NUM> is optically coupled to an optical fiber <NUM> arranged to carry the analog light signal <NUM> to a remote location for further processing. In some embodiments, the transducer <NUM> and input end <NUM> of the optical fiber <NUM> are disposed at the location of the monitored electrical component <NUM> and further processing to detect the occurrence of the PD event and/or to extract information about the occurrence of PD events at the remote location.

In some embodiments, the information about the PD event may be carried through the optical fiber <NUM> by the analog light signal <NUM> as in <FIG>. In other embodiments the light signal is re-converted to an electrical signal and the electrical signal carries the information indicative of the PD event to the remote location. In the invention, the analog light signal <NUM> is be converted to an electrical signal by a photodetector, and the electrical signal may be processed, e.g., by filtering, amplification and/or analog to digital (A/D) conversion. The circuitry that implements the filtering, amplification, and A/D conversion can be disposed at the location of the monitored component <NUM>. In some embodiments, the digitized electrical signal may be re-converted to a digital light signal before the digital light signal is coupled into an optical fiber. In such an embodiment, the digital light signal carries the information about the PD event from the monitored electrical component to the remote location.

<FIG> is a schematic diagram of another version of an electrical-optical transducer <NUM> in accordance with some embodiments. In this example, the transducer <NUM> optionally includes a high pass filter <NUM>. In the embodiment shown in <FIG>, the high pass filter <NUM> includes a capacitor <NUM> and resistor <NUM> connected in series. The high pass filter <NUM> attenuates low frequencies in the electrical sensor signal. The resistance <NUM> is selected to limit current to the LEDs <NUM>, <NUM>.

First and second LEDs <NUM>, <NUM> are arranged with opposite polarity and in parallel with each other. The first and second LEDs <NUM>, <NUM> convert the electrical signal generated by the PD sensor <NUM> into light signals <NUM>, <NUM>. The first LED <NUM> generates a first analog light signal <NUM> in response to the positive-going portion of the sensor signal and the second LED <NUM> generates a second analog light signal <NUM> in response to the negative-going portion of the sensor signal.

The voltage fluctuation caused by partial discharge events are typically quite fast (oscillating with tens of ns). Recording such a fast signal requires costly data acquisition cards. Adding low pass filtering in the LED circuit results in generated slow light pulses (<NUM>µsec to few µsec) that can be recorded with lower cost components. In some embodiments, the LEDs <NUM>, <NUM> can be selected such that the response times of the LEDs <NUM>, <NUM> provide low pass filtering of the sensor signals. For example, in some implementations, acceptable low pass filtering of the sensor signal can be achieved when the LEDs <NUM>, <NUM> have rise and fall times of about <NUM> ns. Alternatively, a low pass filter can be added to the circuit.

LEDs <NUM>, <NUM> can be respectively optically coupled to corresponding first and second optical fibers <NUM>, <NUM>. LED <NUM> is optically coupled to optical fiber <NUM> and LED <NUM> is optically coupled to optical fiber <NUM>. In some embodiments, the transducer <NUM> and input ends <NUM>, <NUM> of the optical fibers <NUM>, <NUM> are located at the monitored electrical device <NUM>. The optical fibers <NUM>, <NUM> extend to carry the first and second analog light signals <NUM>, <NUM> to a remote location for further processing. The optical interconnect comprising the LEDs and the optical fibers provides a signal pathway with good electrical isolation and low electromagnetic interference between the monitored component and the remote location where the optical signal is received and processed.

As discussed above, in some embodiments, the information about the PD event may be carried through the optical fibers <NUM>, <NUM> by the analog light signals <NUM>, <NUM>. In other embodiments the light signals <NUM>, <NUM> are converted to electrical signals at the location of the monitored electrical device <NUM> and the electrical signals carry the information indicative of the PD to the remote location as previously discussed.

For the direct electrical to optical transducers shown in <FIG>, <FIG>, and <FIG> in which LEDs are connected to the PD sensor without an active device such as an op-amp interposed between the LEDs and the sensor, PD events that generate a voltage smaller than the LED's turn-on voltage will not produce an optical signal. This can however be tuned by changing the high-pass filter characteristics in order to couple in some of the <NUM> (base) frequency. This <NUM> base frequency can be used to bias the LED so that even small events are transduced into an optical signal. It is also possible to use an LED with a lower turn-on voltage in order to increase the sensitivity of the device.

<FIG> illustrates an embodiment of an electrical-optical transducer <NUM> for PD detection. Transducer <NUM> has many of the same components previously discussed in conjunction with transducer <NUM>. Transducer <NUM> additionally comprises a rectifier/regulator <NUM> connected between the LEDs <NUM>, <NUM> and ground, bringing the effective turn-on voltage of the LEDs <NUM>, <NUM> to about 0V. In the configuration shown in <FIG>, the inclusion of the rectifier/regulator <NUM> makes it possible to measure charge less than about <NUM> nC, allowing even a small PD to produce an optical output from the LEDs <NUM>, <NUM>. Rectifier/regulator <NUM> may have a connection to voltage input <NUM> so that the voltage across the LED is only related to the high-frequency components of input signal <NUM>.

<FIG> illustrates another implementation of an electrical-optical transducer <NUM> for detecting PD events of a monitored electrical component <NUM>, according to the invention. Transducer <NUM> includes an operational amplifier <NUM> coupled between the PD sensor <NUM> and LEDs <NUM>, <NUM> which are arranged with opposite polarity and in parallel. The resistor <NUM> is selected to limit current to the LEDs <NUM>, <NUM>. Using an amplifier <NUM> between the PD sensor <NUM> and the LEDs <NUM>, <NUM> (compared to the direct-to-LED method) provides an output optical power that is linear with PD charge. Using this technique, small PD events can generate a measurable optical signal.

According to some implementations, a PD monitoring system can include multiple PD transducers as discussed above positioned on a single component to monitor multiple locations of the component or positioned on multiple components. <FIG> schematically depicts a PD monitoring system comprising N PD sensors, <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N, and N electrical to optical transducers <NUM>-<NUM>, <NUM>-<NUM> through <NUM>-N. Each PD transducer <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N is respectively positioned in proximity to a corresponding electrical component <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N. PD sensors <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-N are respectively coupled to components <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-N to sense PD events of the components <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-N. The sensor outputs of PD sensors <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-N are respectively coupled to the PD transducers <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-N.

Each PD transducer <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N illustrated in this embodiment includes two LEDs as previously discussed in connection with <FIG> or <FIG>. Each LED is optically coupled to an optical fiber <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM> through <NUM>-N, <NUM>-N. The PD transducers <NUM>-<NUM>, <NUM>- <NUM> through <NUM>-N and the input ends <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N, <NUM>-N of the optical fibers <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM> through <NUM>-N, <NUM>-N are positioned in close proximity to the monitored component <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N. The optical fibers <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM> through <NUM>-N, <NUM>-N carry light signals that include information about PD events of the monitored components <NUM>-<NUM>, <NUM>-<NUM>, through <NUM>-N to central processing circuitry <NUM> where the light signals are converted to electrical signals and processed to extract the PD information.

<FIG> is a block diagram illustrating a representative embodiment of a portion of the central processing circuitry <NUM> in more detail. The portion of the central processing circuitry shown in <FIG> includes first and second photodetectors <NUM>, <NUM> respectively optically coupled to the output ends of optical fibers <NUM>, <NUM>. Optical fibers <NUM>, <NUM> carry the light signals, e.g., analog light signals from first and second LEDs of a PD transducer located at the component being monitored for PD. The photodetectors <NUM>, <NUM> receive the light signals and convert them into electrical signals. For example, each photodetector may comprise a silicon p-i-n diode, a silicon photomultiplier or other types of photodetectors. After the optical to electrical conversion, the electrical signals from each photodetector <NUM>, <NUM> are amplified, e.g., by transimpedance amplifiers <NUM>, <NUM> which are implemented using an operational amplifier. The amplified electrical signals are then digitized by A/D converters <NUM>, <NUM> and the digitized signals are provided to circuitry <NUM> configured to extract the PD information from the digitized signals. In some embodiments the circuitry comprises a processor that executes stored program instructions to extract the PD information from the digitized signals. Additional signal processing may be implemented anywhere along the communication link between the PD transducer and the central processing circuitry <NUM> and/or by the processing circuitry <NUM>.

Partial discharge events vary in total charge and it may be useful to determine the total charge (measured in Coulombs) transferred in a PD event. Larger-charge PD events typically signify greater damage or voltage stress on the electrical device. For AC systems, the phase-angles where PD occurs also can be used to identify problems in medium-voltage and high-voltage components.

The magnitude of a PD event can be characterized by the amount of charge at the PD sensor. The amount of charge of the PD event is related to the magnitude of the PD sensor signal. The conversion of sensor signal magnitude to PD event charge can be obtained through a calibration technique implemented by the partial discharge detection processor in which a known charge is injected into the electrical device when the electrical device is turned off.

If the sensor signal is used to drive LEDs directly (e.g., without an amplifier interposed between the PD sensor and the LEDs as in the configurations of <FIG>, <FIG>, <FIG>) then the PD charge is not linearly related to the measured voltage. However, the PD charge can be calculated given the known voltage magnitude/shape of the event on both LEDs. The optical signals, transduced back to electrical signals using a photodiode, may be combined using a two-dimensional fit or a formula for determining the charge.

In some embodiments, a PD event processor may be configured to detect degradation of the electrical system based on PD event signals. For example, the processor may store information obtained from the PD event signals taken at different points in time. The processor may compare the information from successive PD events to determine that the electrical system is changing, e.g., degrading with time. In one scenario, the processor may obtain the magnitude of the PD charge signal and/or total charge transferred for successive PD events. If the magnitude of the PD charge signals and/or a rate at which they are increasing over time, the processor may trigger an alert or notification allowing operators to take action before a catastrophic failure occurs. In another scenario, the processor may obtain a first signature (e.g., a snapshot) of the PD sensor signal (or other signal) corresponding to the PD event at a first point in time and compare the first signature to a second signature obtained from a PD event that occurs at a second point in time. The processor may compare morphology, magnitude, timing, envelope rise time, envelope fall, time, and/or other parameters of the first and second signatures to detect changes in the electrical system. If the changes in the signal signature indicate degradation, the processor may trigger an alert or notification responsive to the signal signature changes allowing operators to take appropriate action. According to some embodiments, the processor may be configured to predict a time of failure of the monitored electrical system based on recent usage trends and/or load pattern trends.

One difficulty with partial discharge detection is that fast data acquisition devices (faster than <NUM> million samples per second) are typically required in order to accurately record the PD signal. These fast data acquisition devices are expensive. Embodiments discussed herein are directed to detectors and methods for recording high-frequency PD signals (e.g. ><NUM>) on a lower frequency (e.g. <NUM>) digitizer. Some approaches described herein involve extracting the envelope of the signal of the PD event. The envelope of the PD signal can be digitized using a less expensive, lower frequency digitizer than the PD signal itself.

A signal from a partial discharge sensor, for example a capacitive sensor, a transient earth voltage probe, high-frequency current transformer or high-frequency antenna, may be used to pick up the electrical signal of the PD events. Some PD sensors, e.g., a capacitive sensor and/or current transformers, may be able to also detect the base operating frequency of the monitored electrical system in the case that the power is AC. In some scenarios, e.g. with high-voltage DC transmission, there is no intended "base" frequency, but it may be desirable to record the low frequency component of such signals in order to check for oscillations and/or other signal anomalies.

<FIG> shows a block diagram of partial discharge system <NUM> in accordance with some embodiments. The system comprises a partial discharge (PD) sensor <NUM> configured to sense a PD event of an electrical system and to generate a sensor signal in response to the PD event. The PD sensor <NUM> may comprise one or more of a coupling capacitor, a transient earth voltage sensor, a current transformer and an antenna. As depicted in <FIG>, the PD sensor signal <NUM> is a relatively high frequency signal, e.g., having frequency components on the order of <NUM> of MHz, for example. The envelope <NUM> of the PD signal <NUM> is a curve that has a positive-going portion 1201a that joins the positive going peaks of the PD signal and a negative going portion 1201b that joins the negative going peaks. The highest frequency components of the envelope signal <NUM> may be less than <NUM>, or less than <NUM>, for example.

An envelope generator <NUM> is coupled to receive the sensor signal from the PD sensor <NUM>. The envelope generator <NUM> extracts the envelope signal from the sensor signal. The envelope generator <NUM> may extract the envelope signal from one or both of a positive-going portion of the sensor signal and a negative-going portion of the sensor signal.

A digitizer <NUM> is coupled to the envelope generator <NUM> and is configured to convert the envelope signal to a digital representation of the envelope signal. In some embodiments, the bandwidth of the digitizer <NUM> may be less than about <NUM>/<NUM> or even less than about <NUM>/<NUM> the desired frequency component to be measured. The output of the digitizer may be provided to a processor <NUM> that is configured to analyze the envelope signal to determine characteristics of the PD event. For example, the processor <NUM> may determine the total charge transferred during the PD event. In some embodiments, the processor <NUM> may store information obtained from envelope signals taken at different points in time. The processor <NUM> may compare the information from envelope signals obtained from successive PD events to determine that the electrical system is degrading or otherwise changing over time. For example, the processor may obtain the magnitude of the envelope signal and/or the total charge transferred for successive PD events. If the magnitude of the envelope signal, the phase-resolved PD pattern, and/or the total charge transferred is increasing over time, the processor <NUM> may trigger an alert or notification responsive to the increasing envelope signal magnitude and/or total charge transferred, allowing operators to take action before a catastrophic failure occurs. In another scenario, the processor may obtain a first signature (e.g., a snapshot) of the envelope signal during a first PD event at a first point in time and compare the first signature to a second signature during a second PD event obtained at a second point in time. The processor <NUM> may compare morphology, magnitude, envelope timing, rise time, envelope fall time, and/or other parameters of the first and second signatures to detect changes in the electrical system. If the changes in the signal signature are consistent with degradation, the processor <NUM> may trigger an alert or notification responsive to signal signature changes allowing operators to take appropriate action.

Higher usage and/or higher loading of the electrical system correlate to PD events that occur at higher frequency, have higher magnitude, produce a greater total charge transferred, and/or have other characteristics that indicate usage and/or loading of the system. According to some embodiments, the processor <NUM> may keep track of these PD event characteristics and determine the usage and/or loading of the electrical system over time. In some implementations, the processor can predict a time to failure for the electrical system based on the usage and/or loading trends of the system and/or on characteristics of the PD events.

<FIG> provides a more detailed block diagram of a PD detection system 1100B in accordance with some embodiments. The PD sensor <NUM> provides an electrical signal responsive to a PD event of a monitored electrical system. As illustrated in <FIG>, the envelope generator <NUM> includes a high pass filter coupled to the PD sensor. The high pass filter <NUM> may have a cut off frequency such that frequencies less than about <NUM> in the electrical PD sensor signal are substantially attenuated by the filter <NUM>. For example, when monitoring an AC electrical system for PD events, the high pass filter <NUM> would typically block the line frequency. The envelope generator <NUM> can include rectifier circuitry <NUM> that <NUM>) blocks the negative-going portion and passes the positive-going portion of the signal at the output of the high pass filter <NUM>; <NUM>) blocks the positive-going portion and passes the negative-going portion of the signal at the output of the high pass filter <NUM>; and/or <NUM>) provides the absolute value of the positive-going and negative-going portions of the signal at the output of the high pass filter <NUM>. The output of the rectifier circuitry <NUM> is coupled to a low pass filter <NUM> that attenuates high frequency components from the rectified signal, providing the envelope signal at the output of the low pass filter <NUM>. The envelope generator <NUM> optionally includes an amplifier <NUM> that amplifies the envelope signal. The envelope signal is converted from an analog signal to a digital signal by digitizer element <NUM> of the digitizer <NUM>. Optionally, the electrical signal at the output of the rectifier <NUM> may be converted to an optical signal and the optical signal may be re-converted to an electrical signal prior to amplification by amplifier <NUM>. Optical signals may be desirable for electrical isolation or electromagnetic interference reduction in some implementations.

In some embodiments, the cut off frequencies of the high pass <NUM> and/or low pass <NUM> filters can be tunable. Tunable filters allow the spectrum of PD signal amplitudes at different frequencies to be produced. Tunable filters can also be used to choose a specific measurement band, thus avoiding picking up environmental background noise, such as radio frequency signals, PD from other sources, etc., and increasing the sensitivity of the PD detection system.

In some embodiments, the PD detection system 1100B can optionally include a channel <NUM> that detects the operational frequency of a monitored AC electrical system. Channel <NUM> includes a low pass filter <NUM> that substantially attenuates frequencies that are above, e.g., <NUM> times, <NUM> times, <NUM> times, the operating frequency of the AC system being monitored for PD events while passing frequencies that are below operating frequency of the monitored AC system. The filtered signal may be amplified by amplifier components <NUM> and/or <NUM>. In some embodiments, the signal between amplifier <NUM> and <NUM> may be an electrical signal. In other embodiments, the output of amplifier <NUM> may be converted to an optical signal and reconverted to an electrical signal before the input of amplifier <NUM>. The output of amplifier <NUM> is converted from an analog signal to a digital signal by digitizer component <NUM>. By detecting the base frequency, the phase angle of a detected PD event can be easily recorded using the same digitizer.

The output of the digitizer components <NUM>, <NUM> may be coupled to a processor (not shown in <FIG>). The processor can be configured to analyze the envelope signal, e.g., as further described in connection with <FIG>.

<FIG> provide simplified schematic diagrams of several PD detection systems in accordance with various embodiments. The schematic arrangements shown in <FIG> provide just a few of many circuit implementations for achieving PD detection systems that down-convert the frequency of the PD signal to a lower frequency envelope signal which can be more cost effectively digitized and analyzed in accordance with approaches described herein.

<FIG> is a simplified schematic of a PD detection system <NUM> comprising a single sided direct electrical envelope generator <NUM> in accordance with some embodiments. The PD sensor <NUM> provides an electrical signal responsive to a PD event of a monitored electrical system. As illustrated in <FIG>, the envelope generator <NUM> includes a high pass filter <NUM> a coupled to the PD sensor <NUM>. In <FIG>, the high pass filter <NUM> is depicted as a passive filter comprising a capacitor <NUM> and a resistor <NUM>, however it will be appreciated that other types of high pass filter circuits may be used. The envelope generator <NUM> includes rectifier circuitry <NUM> illustrated as a diode that is arranged to block the negative-going portion and to pass the positive-going portion of the signal at the output 1311b of the high pass filter <NUM>. The output 1312b of the rectifier circuitry <NUM> is coupled to a low pass filter <NUM> that attenuates high frequency components from the rectified signal, providing the envelope signal at the output 1313b of the low pass filter <NUM>. In <FIG>, the low pass filter <NUM> is depicted as a passive filter comprising a capacitor <NUM> and a resistor <NUM>, however it will be appreciated that other types of low pass filter circuits may be used. The envelope signal is converted from an analog signal to a digital signal by digitizer component <NUM> of digitizer <NUM>.

In some embodiments, the cut off frequencies of the high pass <NUM> and/or low pass <NUM> filters can be tunable. Tunable filters allow the spectrum of PD signal amplitudes at different frequencies to be produced. Tunable filters can also be used to avoid picking up environmental background noise, such as radio frequency signals, PD from other sources, etc., thus increasing the sensitivity of the PD detection system.

In some embodiments, the PD detection system <NUM> can optionally include a second channel <NUM> that detects the operating frequency of a monitored AC electrical system. Channel <NUM> includes a low pass filter <NUM> that substantially attenuates frequencies that are above, e.g., <NUM> times, <NUM> times, <NUM> times, the operating frequency while passing frequencies that are below operating frequency of the electrical system. In <FIG>, the low pass filter <NUM> is depicted as a passive filter comprising a capacitor <NUM> and a resistor <NUM>, however it will be appreciated that other types of low pass filter circuits may be used. The output 1315b of the low pass filter <NUM> is converted from an analog signal to a digital signal by digitizer component <NUM>. The output of the digitizer components <NUM>, <NUM> may be coupled to a processor (not shown in <FIG>). The processor can be configured to analyze the envelope signal, e.g., as further described in connection with <FIG>.

<FIG> is a simplified schematic of a PD detection system <NUM> comprising a single-sided direct amplified electrical envelope generator <NUM> in accordance with some embodiments. Many of the components of the PD detection system <NUM> are similar to those previously discussed in connection with the single-sided direct electrical envelope generator <NUM>. The PD detection system <NUM> includes an amplifier <NUM> and biasing resistors <NUM>, <NUM> connected between the high pass filter <NUM> and the low pass filter <NUM>. A rectifier <NUM> may optionally be connected between the high pass filter <NUM> and the amplifier <NUM> and/or between the amplifier <NUM> and the low pass filter <NUM>. The output of the envelope generator <NUM> provides an amplified envelope signal which is provided to the digitizer component <NUM>. The digitized signals produced by the digitizer component 1351may be provided to a processor (not shown in <FIG>) that performs further analysis of the PD event as discussed above. In this particular embodiment, an optional separate channel for detecting the operational frequency of the monitored AC system may optionally be included but is not shown.

<FIG> is a simplified schematic of a PD detection system <NUM> comprising a double sided direct electrical envelope generator <NUM> in accordance with some embodiments. The PD sensor <NUM> provides an electrical signal responsive to a PD event of a monitored electrical system. Envelope generator <NUM> includes a high pass filter <NUM> represented here as a passive high pass filter comprising capacitor <NUM> and resistor <NUM>. As illustrated in <FIG>, the envelope generator <NUM> includes two electrical channels <NUM>, <NUM> wherein channel <NUM> passes the positive-going signal output of the high pass filter <NUM> and channel <NUM> passes the negative-going signal output of the high pass filter <NUM>. Rectifier <NUM> passes the positive-going high pass filtered signal to low pass filter <NUM>. Oppositely arranged rectifier <NUM> passes the negative-going high pass filtered signal to low pass filter <NUM>.

Low pass filter <NUM> attenuates high frequency components from the positive-going signal, providing the positive-going envelope portion at the output 1513b of the low pass filter <NUM>. In <FIG>, the low pass filter <NUM> is depicted as a passive filter comprising a capacitor <NUM> and a resistor <NUM>, however it will be appreciated that other types of low pass filter circuits may be used. It is also possible for low-pass circuitry to be built-in to a digitizer, and in some embodiments no extra low-pass filters are required. The positive-going portion of the envelope signal is converted from an analog signal to a digital signal by digitizer <NUM>.

Low pass filter <NUM> attenuates high frequency components from the negative-going signal, providing the negative-going envelope portion at the output 1516b of the low pass filter <NUM>. In <FIG>, the low pass filter <NUM> is depicted as a passive filter comprising a capacitor <NUM> and a resistor <NUM>, however it will be appreciated that other types of low pass filter circuits may be used. The negative-going portion of the envelope signal is converted from an analog signal to a digital signal by digitizer <NUM>.

The PD detection system <NUM> can optionally include a channel <NUM> that detects the operating frequency of a monitored AC electrical system. Channel <NUM> includes a low pass filter <NUM> that substantially attenuates frequencies that are above, e.g., <NUM> times, <NUM> times, <NUM> times, the operating frequency while passing frequencies that are below operating frequency of the electrical system. In <FIG>, the low pass filter <NUM> is depicted as a passive filter comprising a capacitor <NUM> and a resistor <NUM>, however it will be appreciated that other types of low pass filter circuits may be used. The output 1515b of the low pass filter <NUM> can be converted from an analog signal to a digital signal by digitizer <NUM>. The output of the digitizer <NUM> may be coupled to a processor (not shown in <FIG>). The processor can be configured to analyze the envelope signal, e.g., as further described in connection with <FIG>.

In some embodiments, the cut off frequencies of the high pass filter <NUM> and/or low pass filters <NUM>, <NUM>, <NUM> can be tunable as discussed above.

<FIG> is a simplified schematic diagram of a PD detection system <NUM> that includes a single-sided amplified optical envelope generator <NUM> in accordance with some embodiments. The PD sensor <NUM> provides an electrical signal responsive to a PD event of a monitored electrical system. Envelope generator <NUM> includes a high pass filter <NUM> represented here as a passive high pass filter comprising capacitor <NUM> and resistor <NUM>. The high pass filter <NUM> may in general comprise any type of high pass filter and may optionally have a tunable cut off frequency as discussed herein.

Rectifier <NUM> may optionally be coupled at the output 1611b of the high pass filter <NUM> between the high pass filter <NUM> and amplifier <NUM>. Rectifier <NUM> passes the positive-going portion of high pass filtered signal. If the high frequency components of the signal at output 1611b exceed the slew rate of the amplifier <NUM>, the amplified signal at the output of amplifier <NUM> may be distorted. In some configurations, the characteristics of rectifier <NUM> may be selected such that the slew rate requirements of amplifier <NUM> are reduced. For example, the response time (rise and/or fall times) of the rectifier <NUM> may be selected to attenuate high frequency components of the signal at output 1611b.

The signal at the output 1690b of amplifier <NUM> drives a light emitting diode (LED) <NUM> wherein the current through LED <NUM> is limited by resistor <NUM>. Light generated by LED <NUM> is detected by photodetector <NUM> and is converted to an electrical signal at the photodetector output 1681b. Optionally, amplifier <NUM> is included in the envelope generator <NUM> to provide a second stage of amplification. The amplified signal at the output 1682b of amplifier <NUM> is digitized by digitizer <NUM>. The digitized signals produced by the digitizer <NUM> may be provided to a processor (not shown in <FIG>) that performs further analysis of the PD event as discussed above.

In various embodiments, low pass filtering of the signal at the output of the photodetector 1681b can be achieved by reducing the bandwidth of the amplifier <NUM>. The low pass filtering function of the envelope generator <NUM> can be provided by the rectifier <NUM>, the LED <NUM>, the photodetector <NUM> and/or amplifier <NUM>. The transient input and/or output response characteristics of each, some, or all of these components may provide low pass filtering that produces the envelope signal. In this particular embodiment, an optional separate channel for detecting the operational frequency of the monitored AC system may be included but is not shown.

<FIG> is a simplified schematic diagram of a PD detection system <NUM> that includes a double-sided optical envelope generator <NUM> in accordance with some embodiments. The PD sensor <NUM> provides an electrical signal responsive to a PD event of a monitored electrical system. Envelope generator <NUM> includes a high pass filter <NUM> represented here as a passive high pass filter comprising capacitor <NUM> and resistor <NUM>. The high pass filter <NUM> may in general comprise any time of high pass filter and may optionally have a tunable cut off frequency as discussed herein.

The signal at the output 1711b of high pass filter <NUM> drives LEDs <NUM> and <NUM>. A first channel <NUM> that includes LED <NUM> converts the positive-going portion of the signal at the output 1711b to a first light signal. A second channel <NUM> that includes LED <NUM> converts the negative-going portion of the signal at the high pass filter output 1711b to a second light signal. Photodetector <NUM> reconverts the first light signal to an electrical signal at the output 1781b of the photodetector <NUM>. Photodetector <NUM> reconverts the second light signal to an electrical signal at the output 1783b of the photodetector <NUM>.

Optionally, amplifiers <NUM>, <NUM> are included in the envelope generator <NUM>. The amplified signals at the outputs 1782b, 1784b are digitized by digitizer components <NUM>, <NUM>, respectively. The digitized signals produced by the digitizer components <NUM>, <NUM> may be provided to a processor (not shown in <FIG>) that performs further analysis of the PD event as discussed above.

In various embodiments, low pass filtering of the envelope generator <NUM> in signal channel <NUM> can be provided by LED <NUM>, photodetector <NUM> and/or amplifier <NUM>. The characteristics of each, some, or all of these components, such as bandwidth, transient input response and/or transient output response, may provide low pass filtering that produces the envelope signal. Similarly, in various embodiments, low pass filtering of the envelope generator <NUM> in signal channel <NUM> can be provided by LED <NUM>, photodetector <NUM> and/or amplifier <NUM>. The characteristics of each, some, or all of these components, such as bandwidth, transient input response and/or transient output response, may provide low pass filtering that produces the envelope signal. In this particular embodiment, an optional separate channel for detecting the operational frequency of the monitored AC system may be included but is not shown.

<FIG> is a simplified schematic diagram of a PD detection system <NUM> that includes a double-sided optical envelope generator <NUM> in accordance with some embodiments. Many of the components of the PD detection system <NUM> are similar to those previously discussed in connection with the double-sided optical envelope generator <NUM>. The envelope generator <NUM> includes amplifier <NUM> connected between the high pass filter <NUM> comprising capacitor <NUM> and resistor <NUM> and LEDs <NUM>, <NUM>. Although shown as a passive analog filter, the high pass filter <NUM> may in general be any type of filter. In some embodiments, the high pass filter is tunable as discussed above. Resistor <NUM> is included to limit the current through LEDs <NUM> and <NUM>. LED <NUM> in channel <NUM> converts the positive-going portion of the signal at the output 1890b of amplifier <NUM> to a first light signal. LED <NUM> in channel <NUM> passes the negative-going portion of the signal at the output 1890b of amplifier <NUM> to a second light signal.

The first light signal is reconverted to an electrical signal at the output 1881b of photodetector <NUM>. The second light signal is reconverted to an electrical signal at the output 1883b of the photodetector <NUM>.

Optionally, amplifiers <NUM>, <NUM> are included in the envelope generator <NUM>. The amplified signals at the outputs 1882b, 1884b are digitized by digitizer components <NUM>, <NUM>, respectively. The digitized signals produced by the digitizer components <NUM>, <NUM> may be provided to a processor (not shown in <FIG>) that performs further analysis of the PD event as discussed above.

A test using a <NUM> V- <NUM> V potential transformer was performed to demonstrate the PD transducer as discussed herein. A capacitive coupler using the PD transducer circuit shown in <FIG> was tested. Internal partial discharges were generated by running the transformer in air at <NUM> VAC applied. <FIG> is a graph of the voltage across the coupling capacitor during a PD event. In <FIG>, the voltage graphs of multiple PD events are overlaid.

The light signals of the first and second transducer LEDs (elements <NUM> and <NUM> in <FIG>) were converted to electrical signals using first and second silicon photomultiplier detectors. The outputs of the first and second photomultiplier detectors were amplified by first and second transimpedance amplifiers. <FIG> is a graph of the voltage signal output of the transimpedance amplifier that represents the light signal from the first LED, where the different traces represent different PD events. <FIG> is a graph of the voltage signal output of the transimpedance amplifier that represents the light signal from the second LED. The LEDs used in the PD transducer of this example had <NUM>µsec response times, thus the fast oscillations of the signal from the capacitive couplers were not present in the voltage signals shown in <FIG>.

<FIG> shows a comparison the voltage signal representing the light signal from the first LED (component <NUM> in <FIG>) to the maximum signal (PD charge) from the capacitive PD sensor (element <NUM> in <FIG>). <FIG> shows a comparison the voltage signal representing the light signal from the second LED (component <NUM> in <FIG>) to the maximum signal (PD charge) from the capacitive PD sensor (component <NUM> in <FIG>). From these comparisons, it is noted that the PD charge of the capacitive PD sensor is correlated to the voltage signals representing the light signals of the first and second LEDs.

Claim 1:
A partial discharge monitoring system, comprising multiple partial discharge transducers, each partial discharge transducer comprising:
a partial discharge, PD, sensor (<NUM>) configured to sense a partial discharge event of an electrical system; and
at least one light emitting device, LED, (<NUM>) in series with the PD sensor, the LED configured to:
receive an electrical sensor signal from the PD sensor; and
generate an analog light signal in response to the electrical sensor signal;
wherein a response time of the LED comprises:
a rise time greater than about <NUM> ns; and
a fall time greater than about <NUM> ns;
each PD transducer further comprising:
an amplifier (<NUM>) coupled between the PD sensor and the at least one LED; and
at least one resistor (<NUM>) configured to limit current to the at least one LED; and the PD monitoring system further comprising:
at least one optical fiber (<NUM>) optically coupled to receive light from the at least one LED and configured to carry the analog light signal from a location proximate to the electrical system to a location remote from the electrical system;
at least one light receiving device at the remote location configured to generate an analog electrical signal in response to the received analog light signal; and
a PD detection processor, configured to either:
compare a signature of the electrical sensor signal or a signal derived therefrom to a previously obtained signature of the electrical sensor signal or the signal derived therefrom; and determine degradation of the electrical system based on the comparison; or
determine one or both of usage and load pattern of the electrical system based on characteristics of PD events; and predict failure of the electrical system based on the one or both of usage and load pattern.