Research ArticleA SiPM-Based Trinal Spectral Sensor Developed for DetectingHazardous Discharges in High-Voltage Switchgear
Xiaobing Yu,1 Chen Shen,1 Yan Jing,1 Ming Ren ,2 Haitao Wu,3 and Lilong Xiao3
1Electric Power Research Institute of State Grid Shaanxi Electric Power Company, Xi’an, 710054 Shaanxi, China2School of Electrical Engineering, Xi’an Jiaotong University, Xi’an 710049, China3Shenzhen Power Supply Bureau, China Southern Power Grid Company Limited, Shenzhen 518054, China
Correspondence should be addressed to Ming Ren; [email protected]
Received 11 September 2019; Accepted 8 January 2020; Published 28 January 2020
Academic Editor: Grigore Stamatescu
Copyright © 2020 Xiaobing Yu et al. This is an open access article distributed under the Creative Commons Attribution License,which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Electric discharges seriously threat the safety of high-voltage switchgear. In this paper, a spectrum-based optical method isproposed for hazardous discharge monitoring. A SiPM-based trinal spectral sensor is developed with good performances interms of sensitivity, defect resolution, and risk evaluation. Experiments carried out on two types of artificial discharges (i.e.,partial discharge and arc discharge) demonstrate that the light intensities coupled in the three spectral bands account fordifferent proportions and the ratio among the three components generally experiences a regular change with increase in severityof discharge. The typical spectral ratio values are then acquired for hazard rating of discharge and recognition of discharge typeswith high confidence.
1. Introduction
Gas-insulated switchgear and metal-enclosed switchgearhave high reliability, low maintenance, and compact sizeand thus are widely used in a power grid. However, someunavoidable insulation defects derived from manufacture,transportation, assembly, or operation can result in partialdischarge (PD) and even electrical arc under a high electricfield, which leads to degradation of the insulation systemand even results in insulation failure. With regard to PD,the monitoring detections developed based on thedischarge-associated effects such as current flow, electro-magnetic (EM) wave, and acoustic wave [1] have been usedfor many years, but their applications are still constrainedby the common knotty issues in practice including the ape-riodic noises distributed in the whole frequency range ofdetection, the indefinable criteria for fault recognition [2, 3].For arc discharge, arc light detection is used for relay protec-tion [4], but it cannot respond to weak light emission fromPDs. In fact, hazardous discharges with releases of lowor high energy are accompanied by light emissions with dif-
ferent spectra. By utilizing the spectral information, the typeand severity of discharge can be estimated without any com-plex signal processing and algorithms. However, the PD lightemission lasts for a very short time (several picoseconds)[5] with low light intensity. A coupling device with highsensitivity, a wide spectral response, and a high-time reso-lution is needed. In this case, the vacuum photomultipliertube (PMT) is used in detecting PD lights, but its irreduciblesize, high driving voltage bias, and high electromagneticinterference (EMI) susceptibility restrict its applications inonline PD monitoring.
With the development of the silicon solid-state photo-electric technology, single-photon-level photosensitivedevices have been produced with micropackaging [6]. Asthe promising alternatives to PMT, the state-of-the-art microsolid-state photoelectric devices such as avalanche photodi-ode (APD) and silicon photomultiplier (SiPM) [7, 8] canserve as the substrate of the multispectral sensor with microsize (~mm2), high quantum efficiency (up to ~40%), andexcellent EM interference immunity (~1 pC) [9]. In thispaper, a trinal spectral sensor array is developed based on
HindawiJournal of SensorsVolume 2020, Article ID 2068280, 9 pageshttps://doi.org/10.1155/2020/2068280
SiPM which presents good properties in sensitivity and line-arity as well as pulse resolution. By experiments, it is indi-cated that different types of discharge shows different lightintensity ratios among the three spectral sensitive ranges.Based on this fact, a risk evaluation method is proposed todistinguish the hazardous discharges with low or high energysuch as partial discharge and arc discharge, which makes itpossible to combine the status monitoring and fault protec-tion of switchgear equipment.
2. Working Principle of a Sensor
2.1. SiPM-Based PD Sensor. Unlike vacuum PMT, SiPMintegrates high density of microcells of APD in a microchipwith millimeter-level size. Each APD unit is activated as aphoton is received and generates a self-sustained avalancheionization, which is called Geiger discharge [8]. By integrat-ing the ionization current of APD units and converting thecurrent into a voltage signal, the photon counting can beachieved as the conventional PMT performs. The basic prin-ciple of SiPM is shown in Figure 1.
The signal-to-noise ratio (SNR) and device current noise(DCR) of the SiPM sensor are impacted by the voltage biasapplied; thus, seeking an appropriate applied voltage is essen-tial for PD detection. For the practical PD detection, theapplied overvoltage was determined experimentally.Figure 2 shows the general SNR of the SiPM sensor as a func-tion of applied overvoltage. Finally, the applied overvoltagewas set at 2.0V.
The 3:07 × 3:07mm2 SiPM (SensL-MicroFJ-30035-TSV)is used as the single unit of the sensor array.
2.2. Trinal Spectral Sensor Array. Based on the circuit of thesingle unit, a multichannel sensor readout circuit can bedeveloped with three units including a DC power supply, aSiPM array substrate, and a multichannel analog amplifier,as shown in Figure 3.
The width of the PD pulses (i.e., the time constant)coupled by the unit can be adjusted by changing the imped-ance in the transimpedance amplifier.
According to the discrepancies in the integral spectraldistributions, three ion beam sputtering (IBS) optical filter
sheets with different spectral responses are chosen for multi-spectral detection, i.e.,
Band1 filter (UV): 260nm~380nm UV shortpass;absolute transmission ðTabsÞ > 66%, average transmissionðTavgÞ > 74%; optical depth of 10-3 (OD3)
Band2 filter (VIS): 370 nm~670nm VIS bandpass;Tabs > 86%, Tavg > 90%; OD3 level
Band3 filter (NIR): 745 nm~1980 nm NIR longpass;Tabs > 85%, Tavg > 90%; OD3 level
Figure 4 shows the transmissions of three optical filtersand the photon detection efficiencies (PDEs) of SiPM in thethree spectral bands. With the three optical filter sheetsinstalled in front of three independent SiPM sensors in thearray, three regions of different sensitive spectra are built.The structure and picture of the trinal spectral PD sensorarray are shown in Figure 5.
Figure 6 gives the typical waveforms of the light pulsessynchronously coupled by the three spectral regions of thesensor. It indicates that for a specific discharge, the light
AnodeSiPM
Cathode
RSPAD
R
Carriers
SPAD
Depletionregion
I
h𝜈
p+
n+
nE
Figure 1: Principle of SiPM.
Applied overvoltage (𝛥V)
Optimal range
Surface dischargeFloating discharge
0.00
2
4
6
8
10
SNR
of S
iPM
PD
sens
or
12
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5
Figure 2: SNR of SiPM PD detection vs. applied overvoltage. Theoperating ambient temperature is approximately 25°C. Surfacedischarge and floating discharge in an atmosphere of air areemployed as PD light sources.
2 Journal of Sensors
pulses coupled by the three spectral units have the samepulse width (~100 ns) but different magnitudes. In practi-cal detection, all the discharge events can be recorded as½phase ðtimeÞ, magnitude ðrelative intensityÞ�.
To verify the effective detection distance of this sensor,the attenuation of the coupled light intensity with distancebetween the sensor and PD source is obtained experimentallyin a dark background, as shown in Figure 7. It indicates thatthe effective detection distance exceeds 4m which is enoughfor coupling the discharge light inside the actual equipment.The life cycle of SiPM is determined by the APD unit. APD iswith a life cycle of ~105 hours, thus ensuring the sufficient lifecycle of the SiPM-based sensor.
3. Experimental Setup
To explore the availability of the SiPM-based trinal spectralsensor in discharge diagnosis, a simulation experiment sys-tem is built, as shown in Figure 8(a). This system consistsof a high-voltage test chamber, a high-frequency currenttransformer, a trinal spectral sensor, a 100 kV/100 kVA ACtransformer, a high-voltage probe (P6015A, 40 kV peak), amultichannel PD detector, and a digital oscilloscope (LeCroyWaveSurfer 64MXs-B, 600MHz, 10GS/s). An epoxy resininsulator is placed between a rod electrode and a plate elec-trode, which is employed as the discharge model, as shownin Figure 8(b). In the experiment, the ambient temperatureis 27°C and the relative humidity is 45%.
4. Results and Analysis
4.1. Stochastic Detection Pattern
4.1.1. Partial Discharge. In this section, the statistical charac-teristics of the light pulses emitted by PDs in the UV, VIS,and NIR ranges are obtained by means of stochastic detec-tion. As an AC electric field is applied, the time lag and inten-sity of discharge vary periodically with the phase of ACvoltage, based on which phase-resolved partial discharge(PRPD) pattern analysis was proposed for PD diagnosisand defect recognition in insulation systems under AC HV.The PD data in a certain number of applied voltage cyclesare plotted on the phase axis in one voltage cycle. This anal-ysis provides the physical properties and stochastic behaviorsof the discharges. In this case of light pulse detection, theapplied voltage peak U , corresponding phase degree ɸ, andlight pulse magnitude I are simultaneously recorded forthousands of AC cycles with optical detection to plot PRPD.
The signal processing procedure is briefly described asfollows.
(i) Convert the occurrence time of each PD (ti) into thephase angle degree (φi) in the same cycle of ACapplied voltage by using
φi = 2π ti ⋅ T−1 − ti ⋅ T
−1� �� � ð1Þ
where T is the period time of a AC cycle.
(ii) Determine the length of window (l) according to thePD intensity in unit time, and count the number ofPDs in the i-th window (Ni) and calculate the averagemagnitude in the i-th window (Ii) by using
Ii =1Nj
〠Ni
j=1I j ð2Þ
Then, the PRPD pattern can be drawn by plotting eachpoint (φi, Ii, and Ni) recorded over a certain time in a fixedcycle of applied voltage. Figure 9 demonstrates the PRPDsand phase-resolved average light intensity curves for thethree spectral bands at different applied voltage levels. Withincrease in applied voltage, the intensities and active phase
R1R2
R3
R5VDDVDD
C5
0VVEE
–
++
–
– +
R4 VEE0V
Output
C4DC
0VC3
C2
C1
Power supply SiPM array Analog amplifier
Figure 3: The readout circuit of the SiPM-based PD sensor array. C1 = C2 = C3 = 10 nF, C4 = 100 pF, C5 = 0:1 μF, R1 = 100Ω, R2 = R5 = 50Ω, R3 = 0:3 kΩ, and R4 = 1 kΩ.
1.2
0.0
PDE
0.1
0.2
0.3
0.4
Ligh
t tra
nsm
ittan
ce
1.0
0.8
0.6
0.4
0.2
0.0200 300 400 500
Wavelength (nm)600
UV band
PDE of SiPM @2V
VIS band
NIR band
700 800 900
Figure 4: Transmissions of the three optical filters and photondefection efficiencies (PDEs) of the SiPM substrate (full band).
3Journal of Sensors
ranges of the light pulses increase gradually. The behaviors ofPDs at negative half cycles show obvious differences to thoseat positive half cycles in terms of PD repetitive rate andmagnitude.
For all cases of different voltages, the light intensity inthe visible spectral band accounts for the majority, whilethat in the near-infrared band accounts for the leastproportion, but with increase in applied voltage, the ratioamong the integral light intensities in the three bands var-ies within a limited range. This rough proportionalityremains unchanged in the whole PD active range frominception to prebreakdown.
4.1.2. Arc Discharge. In the experiment, the arc discharge isgenerated with a rod-epoxy-plate electrode. The arc lengthis controlled by changing the distance between the rod elec-trode and epoxy insulator. The time-domain signals of thelight emission in the full spectral band for the three arc lengthconditions (i.e., 0.5 cm, 1.0 cm, and 2.0 cm) are recorded asshown in Figure 10. Arc discharge is intermittent with a fixedactive period (i.e., active frequency) which is determined bythe arc length. With increase in arc length, the active fre-quency of arc discharge decreases which is also demonstrated
in the light intensity. If the driven power is high enough, theactive frequency is independent of the frequency of the ACvoltage.
With the same stochastic detection but different detec-tion window lengths, the scatter patterns of the light pulsesin the three bands can be obtained synchronously, as shownin Figure 11. It indicates that the intensity components in thethree spectral bands remained unchanged as arc dischargecontinues but account for different proportions. The propor-tion of the visible light component increases with increase inarc length, while the proportions of UV and NIR compo-nents show the opposite. It is also indicated that the ratioamong the three components varies within the limited rangeswith variation of the applied voltage level and arc length. Thisrule is consistent with that of PDs.
4.2. Spectral Ratio Variation. The experimental study showsthat the light intensities coupled in the three spectral bandsaccount for the different proportions and the ratio amongthe three components generally experiences a regular changewith increase in severity of discharge, which means that thespectral distributions can reflect not only the PD type butalso the PD severity. These trinal spectral characteristics pro-vide us a new approach in insulation diagnosis. To quantita-tively investigate the influence of discharge active level on theratio among the intensities in the three spectral bands, the
SiPM-based array
Built-in sensor flange
Optical filter array
Discharge source
Figure 5: The structure and picture of the trinal spectral PD sensor array.
Ligh
t int
ensit
y (a
.u.)
0
1
2
3
4
5
6
2001000 300 400 500Time (ns)
600
VISUV
NIRFull
Figure 6: The PD light pulse waveforms detected by the trinalspectral PD sensor.
Nor
mal
ized
ligh
t int
ensit
y
0.0
0.2
0.4
0.6
0.8
1.0
0.25 0.5 1 2 4Distance (m)
Figure 7: Light intensity attenuation with detection distance. Astable corona discharge (145 pC) is used as the light source.
4 Journal of Sensors
AC
TCchamber
PC
PMT
HFCT
SiPMDAC board
CouplingcapacitorHV
divider
(a)
HV HV
GND GND
PDmodel
Arcmodel
Metal rod Metal rodEpoxy
insulatorEpoxy
insulator
Metal plate Metal plate
(b)
Figure 8: Experimental setup: (a) test system; (b) artificial discharge models (PD and arc).
10–3
10
Ligh
t int
ensit
y (a
.u.)
5
0
0 90 180 270 360
UV band
VIS bandNIR band
Phase degree (°)
(a)
VIS band
VIS band
NIR band
Phase degree (°)
–101
Ligh
t int
ensit
y (a
.u.)
2345
0 50 100 150 200 250 300 350
×10–3
(b)
0.04
Ligh
t int
ensit
y (a
.u.)
00.010.020.03
0 90 180 270 360
UV bandVIS band
NIR band
Phase degree (°)
(c)
UV band
VIS band
NIR band
Phase degree (°)
024
Ligh
t int
ensit
y (a
.u.)
68
1012
0 50 100 150 200 250 300 350
×10–3
(d)
0.08
Ligh
t int
ensit
y (a
.u.)
00.020.040.06
0 90 180 270 360
UV bandVIS band
NIR band
Phase degree (°)
(e)
UV band
VIS band
NIR band
Phase degree (°)
0
0.005
Ligh
t int
ensit
y (a
.u.)
0.01
0.015
0.02
0.025
0 50 100 150 200 250 300 350
(f)
Figure 9: PRPDs and phase-resolved average light intensity curves for the three spectral bands at different applied voltage levels. (a) Appliedvoltage = 4 kV (scatter plots). (b) Applied voltage = 4 kV (average intensities). (c) Applied voltage = 6:5 kV (scatter plots). (d) Appliedvoltage = 6:5 kV (average intensities). (e) Applied voltage = 10:5 kV (scatter plots). (f) Applied voltage = 10:5 kV (average intensities).
5Journal of Sensors
–1–0.02
0.020
–0.8 –0.6 –0.4 –0.2 0 0.2 0.4 0.6 0.8 1
0.5 cm
× 10–4
–10
0.20.1
–0.8 –0.6 –0.4 –0.2 0 0.2 0.4 0.6 0.8 1
1.0 cm
× 10–4
–1–0.05
–0.050.1
0
–0.8 –0.6 –0.4 –0.2
Time (s)
0 0.2 0.4 0.6 0.8 1
2.0 cm
× 10–4
Ligh
t int
ensit
y (a
.u.)
Figure 10: The time-domain signals of the light emission in the full spectral band for the three arc length conditions.
0.04
Ligh
t int
ensit
y (a
.u.)
0.02
–0.02–0.04
0
0 90 180 270 360
UV band
VIS band
NIR bandPhase degree (°)
(a)
0.04
Ligh
t int
ensit
y (a
.u.)
0.02
–0.02–0.04–0.06
0
090 180
270 360
UV band
VIS band
NIR bandPhase degree (°)
(b)
0.04
Ligh
t int
ensit
y (a
.u.)
0.02
–0.02–0.04–0.06
0
0 90180
270 360
UV band
VIS band
NIR bandPhase degree (°)
(c)
Figure 11: The scatter patterns of the light pulses in the three bands: (a) arc length = 5mm; (b) arc length = 10mm; (c) arc length = 15mm.
6 Journal of Sensors
proportion of the light intensity in the spectral band ki isdefined as
ki = φ−1 ⋅ðφ
Ii ⋅ IFULL−1
!, ð3Þ
where φ is the discharge active phase range, IFULL is the lightintensity coupled in the full spectral band.
Figure 12 shows the variations of the three spectral com-ponents with applied voltage for PDs. It indicates that thelight intensities of the three bands increase monotonicallywith increasing applied voltage but with different gradientsespecially in the PD inception stages and prebreakdownstage, as shown in Figure 12(a). With regard to the ratioamong the three components, it varies in a very limited rangewith discharge level ranging from 250pC to 1.3 nC except forthe PD inception stage with relatively low discharge level, asshown in Figure 12(b).
20181614
Ligh
t int
ensit
y (a
.u.)
1210
86420
5 6 7 8 9 10Applied voltage (kV)
UVVISNIR
11 12 13 14 15 16 17
(a)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
Nor
mal
ized
spec
tral
pro
port
ion
1.0
Applied voltage (kV)5 6 7 8 9 10 11 12 13 14 15 16 17
103
102
101
NIRVIS
UV
Disc
harg
e lev
el (p
C)
PD level
(b)
Figure 12: Variations of the three spectral components with applied voltage for PDs (rod-insulator-plate): (a) light intensities in the threespectral bands vs. applied voltage; (b) normalized spectral proportions and discharge level vs. applied voltage.
350
300
250
200
Ligh
t int
ensit
y (a
.u.)
150
100
50
02 5 6 8 10 12
Arc length (mm)
UVVISNIR
14 16 18 20 22 24
(a)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
Nor
mal
ized
spec
tral
pro
port
ion
1.0
Arc length (mm)D
rivin
g po
wer
(kW
)
Arc driving power
0 2 4 6 8 10 12 14 16 18 20 22 24 260.0
0.5
1.0
1.5
2.0
2.5
3.0
NIRVIS
UV
(b)
Figure 13: Variations of the three spectral components with arc length for arc discharge (rod-plate): (a) light intensities in the three spectralbands vs. arc length; (b) normalized spectral proportions and driving power vs. arc length.
7Journal of Sensors
Figure 13 shows the variations of the three spectral com-ponents with applied voltage for arc discharge. It indicatesthat the all the light intensities of the three bands experiencethe up-and-down process with arc discharge length increas-ing from 2mm to 25mm, as shown in Figure 13(a). It canbe seen from Figure 13(b) that the variation trend of the lightintensity is almost consistent with the driving power of thearc discharge which is deemed as the average energy partiallyreleased by light emission in unit time. With regard to theratio among the three components, it remains almostunchanged with arc length increasing from 2mm to 25mmor driving power increasing from 0.4 kW to 2.4 kW.
4.3. Hazard Rating of Discharge. Although the ratios amongthe three spectral components for PD and arc discharge varywith the applied voltage or discharge level, their distributionshave little intersection as shown in Figure 14. For PDs, withincrease in PD level, the total proportions of UV and VISlights decrease from 0.91 to 0.81 and NIR light proportionincreases from 0.09 to 0.20, but the ratio of UV light intensityto VIS intensity stays in the range (0.85, 1). For arc discharge,the light intensities in the three bands change with the driv-ing power, but the ratio of UV intensity to VIS intensity stays
around 0.3 and is almost unaffected by the variations of arclength and driving power.
Table 1 summarizes the typical spectral ratio values forPD and arc discharges at different conditions. Actually, thespectrum of discharge light emission is determined by theenergy release process and the temperature of the electron.Obviously, the difference of energy level between PD andarc discharge is the underlying causes of the difference inspectral ratios for PD and arc discharge. Therefore, the spec-tral ratio can be used as the criterion in evaluations of dis-charge types and discharge risk level with high confidence.According to the spectral ratio, we can determine the follow-ing actions including early prewarning or protection controlin practical use.
5. Conclusion
In this paper, a spectrum-based optical method is proposedfor hazardous discharge monitoring of switchgear equip-ment. Based on the fact that the spectrum of discharge lightemission is determined by the energy release process andthe temperature of the electron, a SiPM-based trinal spectralsensor is developed with good performances in terms of
0.35
0.40
0.45
0.50
0.55
0.60
0.65
0.70
0.75
0.45
UV band
prop
ortio
n
VIS band proportion
0.400.35
0.300.25
0.20
0.08
0.10 NIR
ban
d pr
opor
tion
0.12
0.14
0.16
0.18
0.20
Trinal spectral ratio (PD)Trinal spectral ratio (arc)
High PD level
Low PD level
0.4kW 2.4kW 1.0kW
28pC 1.3nC
Figure 14: Distributions of the trinal spectral ratios for PDs and arc discharge. For PDs, the PD level is ranging from 28 pC to 1.3 nC; for arcdischarge, the driving power is ranging from 0.4 kW to 2.4 kW with arc length changing from 2mm to 25mm.
Table 1: The typical spectral ratio values for PD and arc discharges.
Type of discharge kUV kVIS kNIR PD charge (pC) Driving power (kW)
Weak PD (0.28, 0.44) (0.62, 0.44) (0.09, 0.12) (20, 200) /
Intense PD (0.37, 0.44) (0.43, 0.44) (0.12, 0.20) (200, ~1000) /
Arc discharge (0.21, 0.22) (0.69, 0.71) (0.07, 0.08) / (400, 2500)
8 Journal of Sensors
sensitivity, defect resolution, and risk evaluation. Experi-ments indicate that the ratio among the light intensities inthe three spectral bands can be used as the criterion inevaluations of discharge types and discharge risk level. Forweak and intense PDs, their typical spectral ratios distributein the ranges of (0.28, 0.44) : (0.62, 0.44) : (0.09, 0.12) and(0.37, 0.44) : (0.43, 0.44) : (0.12, 0.20), and for arc discharge,the ratio distributes in the range of (0.21, 0.22) : (0.69,0.71) : (0.07, 0.08) and is almost unaffected by the arc lengthand driving power. In practical use, if a hazardous dischargeevent is detected, the following actions including early pre-warning or protection control can be taken timely accordingto the trinal spectral ratio.
Data Availability
The experiment data in this paper are provided in thesupplementary materials.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
Acknowledgments
This work was supported by the National Key Researchand Development Program of China (Grant No.2018YFB0904400) and the National Natural Science Foun-dation of China (Grant No. 51507130).
Supplementary Materials
File “data1” concludes the data of light intensities in the threespectral bands at different applied voltages for PDs(Figure 11(a)). File “data2” concludes the data of normalizedspectral proportions and discharge level at different appliedvoltages for PDs (Figure 11(b)). File “data3” concludes thedata of light intensities in the three spectral bands at differentarc lengths for arc discharge (Figure 12(a)). File “data4”concludes the data of normalized spectral proportions anddriving power at different arc lengths for arc discharge(Figure 12(a)). (Supplementary Materials)
References
[1] PD IEC/TS 62478,High-voltage test techniques: measurement ofpartial discharge by electromagnetic and acoustic methods, IEC,Geneva, Switzerland, 2016.
[2] R. Albarracín, G. Robles, J. M. Martínez-Tarifa, andJ. Ardila-Rey, “Separation of sources in radiofrequency mea-surements of partial discharges using time-power ratio maps,”ISA Transactions, vol. 58, pp. 389–397, 2015.
[3] G. Robles, J. M. Fresno, and J. M. Martínez-Tarifa, “Separationof radio-frequency sources and localization of partial dischargesin noisy environments,” Sensors, vol. 15, no. 5, pp. 9882–9898,2015.
[4] IEC 62271-200, High-voltage switchgear and controlgear - part200: AC metal-enclosed switchgear and controlgear for ratedvoltages above 1 kV and up to and including 52 kV, IEC stan-dard, 2011.
[5] M. D. Judd and O. Farish, “High bandwidth measurement ofpartial discharge current pulses,” in Proceedings of the IEEEInternational Symposium on Electrical Insulation, vol. 2,pp. 436–439, Arlington, VA, USA, 1998.
[6] S. Cova, M. Ghioni, A. Lotito, I. Rech, and F. Zappa, “Evolutionand prospects for single-photon avalanche diodes and quench-ing circuits,” Journal of Modern Optics, vol. 51, no. 9-10,pp. 1267–1288, 2004.
[7] R. H. Hadfield, “Single-photon detectors for optical quantuminformation applications,” Nature Photonics, vol. 3, no. 12,pp. 696–705, 2009.
[8] D. Renker and E. Lorenz, “Advances in solid state photon detec-tors,” Journal of Instrumentation, vol. 4, no. 4, 2009.
[9] M. Ren, J. Zhou, B. Song, C. Zhang, M. Dong, and R. Albarracín,“Towards optical partial discharge detection with micro siliconphotomultipliers,” Sensors, vol. 17, no. 11, p. 2595, 2017.
9Journal of Sensors