


  
TRANSACTIONS ON ENVIRONMENT AND ELECTRICAL ENGINEERING ISSN 2450-5730 Vol 3, No 1 (2018) 

© Ulrich Lühring, Daniel Wienold, Frank Jenau 

 

Abstract—Partial discharges reduce the residual lifespan of 

operating equipment and can indicate serious deficiencies of 

electrical insulations at an early stage. Regarding AC voltage 

stress, the phase resolved pattern is an established diagnostic 

tool, which allows conclusions about the location and the type of 

fault. Despite the increasing importance of DC transmission 

systems, a comparable proceeding for DC voltage stress does not 

exist. This implies the development and evaluation of alternative 

and suitable basic approaches. Although diverse promising 

approaches are identified, recent research is focused on standard 

atmospheric conditions. Due to the fact that this is just partly 

consistent to real operating conditions, additional research is 

required. Focusing on the time domain analysis of corona 

discharges, occurring under positive DC voltage stress in air, a 

measurement method for investigating the influence of varying 

atmospheric quantities is presented. Measurements are carried 

out for five different relative humidity levels in the range of 20 % 

to 95 % and for four different temperature levels in the range of 

20 °C to 65 °C. As characterizing pulse shape parameters, the 

rise time, the pulse width and the fall time are determined as well 

as the apparent charge. The gained values are compared to each 

other and reconciled with physical processes. 

 

 
Index Terms—corona discharge, DC voltage, humidity level, 

pulse shape parameter, temperature level 

 

I. INTRODUCTION 

ARTIAL discharges are the result of a local electrical stress 

concentration and are defined as localized discharges, 

which partially bridge the electrical insulation between 

 
This manuscript was submitted on June 8

th
, 2018 and revised on June 25

th
, 

2018 as an extended version of the paper “Influence of humidity on pulse 

shape parameters of positive corona discharges in air at DC voltage” 

presented at the 17
th
 International Conference on Environment and Electrical 

Engineering, Milan/Italy, June 2017 [1]. 

Ulrich Lühring, Daniel Wienold and Frank Jenau are with the Institute of 

High Voltage Engineering, TU Dortmund University, Dortmund, Germany      
(e-mail: ulrich.luehring@ tu-dortmund.de). 

 

This work has been funded by the German Federal 

Ministry for Economic Affairs and Energy (BMWi) 
as a part of the E²HGÜ project under grant number 

03ET7514. 

 

conductors [2]. Due to the damaging effect on the condition of 

isolation, the partial discharge (PD) diagnosis is a key 

component of electrical diagnostic procedures. In addition to a 

registration of local weak points, the focus of measurement 

and analysis techniques is in particular on the identification of 

the location and the type of fault. Regarding the latter, it is 

taken advantage of the fact that the appearance of PDs 

depends on various factors, which are influenced by the type 

of fault. Under AC voltage stress the phase resolved pattern is 

the best established and most commonly used diagnostic tool 

to distinguish between different types of fault [3]. This 

diagnostic procedure analyzes the link between discharge 

pulses and the phase angle of their occurrence with respect to 

the test voltage. The application is consequently restricted to 

AC voltage and not transferable to DC voltage. A similar 

recognized diagnostic tool for DC voltage stress does not 

exist.  

The increasing importance of DC transmission systems 

requires the development and evaluation of alternative and 

suitable basic approaches. Therefore, the PD diagnosis at DC 

voltage stress is subject of current research, whereby diverse 

promising basic approaches could be identified. Regarding 

measurements based on the conventional PD measuring 

circuit, experimental tests indicate that an estimation of the 

magnitude of PDs [4], an analysis of the time lag between 

subsequent PD impulses [5] and the time domain analysis [6] 

are appropriated for a precise defect classification. In addition 

to that, unconventional measuring methods, such as the 

capturing of the electromagnetic spectrum by using a 

broadband antenna, are increasingly moving to the fore. With 

respect to DC applications it is e.g. shown in [7] and [8], that 

an evaluation of acquired data of the electromagnetic spectrum 

of PDs in the frequency domain respectively in the time 

domain is suited to distinguish between different types of 

fault. 

An advantage of the time domain analysis is the direct 

relationship between the pulse shape of the PD impulse 

current and the causing processes. Furthermore, it is well 

known that the electromagnetic spectrum of PDs depends on 

the pulse shape of the discharge current [9]. The time domain 

analysis focusses on parameters, which are directly obtained 

from the pulse shape. The rise time, the pulse width and the 

fall time as primary parameters are considered as well as 

About the influence of temperature and 

humidity level on pulse shape parameters of 

positive DC corona discharges in air 

Ulrich Lühring, Daniel Wienold and Frank Jenau 

P 



 

secondary parameters such as the coefficient of variation, the 

kurtosis or the skewness. A comparative analysis of these 

parameters, gained from PDs of idealized and artificial defects 

under DC voltage stress, outlines the possibility to 

differentiate between different types of fault [10] and defects 

in varying insulating media [11], [12]. Extensive experimental 

investigations and statistical evaluations, presented in [6], 

verify that the time domain analysis of PDs enables a precise 

defect classification. Comparative investigations of corona 

discharges occurring under AC and DC voltage stress point 

out, that the associated pulse shape parameters are not affected 

by the voltage waveform [13]. Based on these findings [14] 

demonstrates the general suitability of the time domain 

analysis to identify the type of fault at AC voltage as well. 

The abovementioned investigations have in common that 

they are comprehensively realized under ambient atmosphere, 

which approximately corresponds to the reference atmosphere, 

and under a voltage stress which complies with the partial 

discharge inception voltage or a predefined voltage level 

above it. A variation of these parameters is not taken into 

consideration, which is just partly consistent with real 

operating conditions. Whereas detailed information regarding 

an influence of the test voltage level are outlined in [15], 

additional research concerning the influence of varying 

atmospheric parameters, such as the air pressure, the humidity 

level and the temperature level, on the appearance of PDs has 

to be carried out. Studies in relation to an influence of the gas 

pressure are outlined in [16] and [17]. Although detailed 

information from the presented measurement data are not 

derivable, these investigations indicate increasing discharge 

amplitudes and decreasing pulse widths as well as decreasing 

fall times if the gas pressure is raised. A consideration of a 

varying temperature and humidity level focuses on 

investigations regarding the PD intensity, the discharge 

inception voltage and the breakdown voltage. For example, 

[18] respectively [19] evince a slight decrease of the PD 

inception voltage and the breakdown voltage, if the 

temperature level is raised. Concerning a rising humidity 

level, a decreasing PD inception voltage and an increasing 

breakdown voltage is pointed out in [20] respectively [21]. 

This indicates a dependency between the partial discharge 

impulse current and the temperature level as well as the 

humidity level. 

The purpose of this contribution is to investigate the 

influence of the temperature and the humidity level on the 

pulse shape by focusing on positive corona discharges in air. 

Therefore, corona discharges are generated by using a needle-

to-plate set-up. The latter is part and parcel of an optimized 

measuring circuit. An appropriate measuring method is 

presented and applied to capture the pulse shape of corona 

discharges. To characterize the pulse shapes the rise time, the 

pulse width and the fall time are determined as well as the 

apparent charge for PDs occurring at temperature levels of 

20 °C, 35 °C, 50 °C and 65 °C and for relative humidity levels 

of 20 %, 40 %, 60 %, 80 % and 95 %. 

II. EXPERIMENTAL SET-UP 

An accurate determination of pulse shape parameters 

presupposes a broadband measuring system, consisting of a 

measuring circuit and a measuring instrument. In [22] an 

overall bandwidth of at least 1 GHz is demanded to capture 

initial pulse shapes, which are not impaired by reflection and 

refraction processes. If this requirement is fulfilled, detailed 

information regarding the causing and influencing processes 

can be gained. 

A. PD measuring circuit 

The measurements are implemented by using a basic PD 

measuring circuit, which is in accordance to IEC 60270. As 

shown in Fig. 1, the PD measuring circuit consists of a 

coupling capacitor Cc, a measuring cell with a needle-to-plate 

set-up (DUT), a measuring impedances Zm1 respectively Zm2 

and a decoupling impedance Zd. The latter decouples the 

discharge current circuit from a high voltage power supply U0, 

which provides a positive DC voltage with a low residual 

ripple. To determine the PD inception voltage an external 

quadripole of a PD measuring system is set as Zm1 in series to 

Cc. The pulse shapes are captured with a broadband 

oscilloscope, whose input resistor is set as Zm2 in series to the 

DUT.  

B. Measuring Cell 

A decoupling of the partial discharge impulse current from 

the weak point to the broadband oscilloscope devoid of 

distortions is enabled by using a measuring cell optimized 

from a high voltage and high frequency point of view. Core 

component of the measuring cell, whose sectional view is 

shown in Fig. 2, is a conical transmission line with a constant 

line impedance of approximately 50 Ω. The suitability of such 

a conical transmission line for an accurate measurement of the 

pulse shape is proven in [11] and [23]. In total four air inlets, 

which are arranged radially in the same height, ensure that the 

temperature and the humidity level within the measuring cell 

can comply with the external levels. 

C. Test device 

To generate corona discharges a sharp needle is attached to 

the cylindrical high voltage electrode. The air clearance 

between the ground electrode and the needle tip is set to 

15 mm. 

 

Fig. 1.  PD measuring circuit according to IEC 60270 to determine the PD 

inception voltage and to capture the pulse shape. 

  

Zm1

Zd

CC iPD

U0

DUT

climatic chamber

Zm2



 

III. EXPERIMENTAL PROCEDURE 

The influence of the temperature level and the humidity 

level on the pulse shape of positive corona discharges is 

investigated by considering different climatic conditions. As 

shown in in Fig. 3 13 different climatic conditions are 

considered, whereby the temperature level is varied in the 

range of 20 °C to 65 °C and the relative humidity level is 

varied in the range of 20 % to 95 %. A variation of these is 

made possible by placing the measuring cell in a climatic 

chamber, which is presented in [24]. The climatic chamber is 

characterized by a high long-term stability and an accurate 

regulation of the temperature and the relative humidity level.  

To exclude an influence of the test voltage level, which 

occurs if the test voltage is raised above the inception voltage 

[15], all measurements are executed at the respective PD 

inception voltage. The latter is ascertained in advance for each 

climatic condition. 

A. Determination of the inception voltage 

Up to now, the term of the PD inception voltage under DC 

voltage stress is not clearly defined. In the framework of this 

investigation the PD inception voltage is determined by 

increasing the test voltage in steps of 0.5 kV starting from 

zero. As shown in Fig. 4 the test voltage is enhanced by 

additional 0.5 kV, if PDs are not detected within one minute. 

If sufficient PDs are measurable at a constant test voltage level 

over a period of five minutes, the PD inception voltage is 

assumed to be reached. 

B. Capturing of the pulse shapes 

The climatic conditions are successively provided by the 

climatic chamber, whereby special attention is paid in order to 

prevent the formation of condensate. In the case of a sole 

variation of the humidity level, an additional residence time of 

at least two hours is taken into consideration before 

performing a measurement after having reached a stationary 

state in the climatic chamber. If the temperature level is 

changed, the additional residence time is set to at least 12 

hours. This ensures the desired climatic conditions within the 

measuring cell. 

Previous investigations demonstrate that the first 

determinable pulse shapes reach larger amplitudes than the 

following [25], [26]. Due to these findings, the capturing of 

100 sequent pulse shapes for each climatic condition is started 

after a stress duration of ten minutes. Furthermore, this 

ensures that the PDs are not mainly energized by the 

capacitive field [5]. 

IV. DATA ANALYSIS AND PRESENTATION 

The captured pulse shapes are characterized by the 

determination of the rise time (20 % to 80 %), the pulse width 

(50 % to 50 %), the fall time (80 % to 20 %) and the apparent 

charge. 

To present and compare the location and the distribution of 

the determined pulse shape parameters, box plots are used. 

This kind of graphic representation, which is among others 

shown in Fig. 5, divides the entire range of values into four 

subsets. The median is represented by the bar within the box, 

which itself contains the middle 50 % of all determined 

values. The boundaries of the box are the 25 % quartile and 

the 75 % quartile. Their distance delineates the interquartile 

range. Values, having a greater distance to the box than 1.5 

times of the interquartile range, are designated as outliers and 

are characterized by a plus symbol. 

 

Fig. 3.  Overview of the investigated climatic conditions. 
  

 

Fig. 2.  Sectional view of the measuring cell optimized from a high voltage 

and high frequency point of view. 

  

PVC insulator

conical transmission line

HV-connection

ground electrode

cylindrical HV-electrode

air inlet

 

Fig. 4.  Flow diagram for the determination of the PD inception voltage. 

  

0 kV

Ui

Test voltage

0.5 kV

1.0 kV

1.5 kV

Test device without voltage stress

Determination of the inception voltage Ui

Inception voltage Ui

yes

Sufficient discharges

over a period of

five minutes?

Detection of a

discharge within one

minute?

Increase test voltage by 0.5 kV

yes

no

no



 

V. RESULTS AND DISCUSSION 

A. Appropriateness of the measurement method 

The appropriateness of the experimental procedure 

presented in section III is evaluated by investigating selected 

climatic conditions more than once. To realize the different 

measurement series the climatic condition within the 

measuring cell is adjusted anew and the needle, which is 

attached to the high voltage electrode, is exchanged. In 

addition to that a long-term study is executed to examine the 

temporal development of the considered pulse shape 

parameters. In dependence on the reference atmosphere, these 

measurements are comprehensively carried out at a 

temperature level of 20 °C and an absolute humidity level of 

11 g/m³.  

In terms of two different measurement series, the box plots 

for 100 values of the determined pulse shape parameters are 

exemplarily shown in Fig. 5. Regarding the median the rise 

time evinces with approximately 10 % the largest deviation of 

all considered pulse shape parameters. In contrast, the 

deviation of the associated median values of the pulse width 

and the fall time are smaller than 5 % and therefore very low. 

The temporal development of the pulse shape parameters, 

determined from the captured pulse shapes in a long-term 

study over a period of 360 minutes, is shown in Fig. 6. In the 

case of the rise time, the maximum deviation of all identified 

medians from that after a stress duration of ten minutes 

amounts to 5 %. For the pulse width and the fall time the 

maximum deviation is smaller than 1 %. A consideration of 

the illustrated temporal development clarifies that a significant 

decrease of the medians after a stress duration of 10 minutes is 

not ascertainable. 

Accordingly, the presented measurement method is suited 

to investigate the influence of the temperature and the 

humidity level on pulse shape parameters with a high 

repeatability, if the defined stress duration is obeyed before 

starting the data acquisition.  

B. Influence of the absolute humidity level 

A consideration of the influence of a varying absolute 

humidity on the pulse shape parameters enables a 

simultaneous consideration of the temperature level and the 

relative humidity level. As stated in [27] a conversion is 

feasible according to equation (1).  

𝐴𝐻 =
6.11 ∙ 𝑅𝐻 ∙ 𝑒

17.6∙𝑇
243+𝑇

0.4615 ∙ (273 + 𝑇)
 (1) 

AH: absolute humidity level in g/m³  

RH: relative humidity level in percent  

T: temperature level of ambient air in °C  

 

Fig. 7 exemplarily shows the medians for the pulse width 

and the fall time in dependence on the absolute humidity. It 

should be noted that the fundamental curve progression is 

identical for all considered temperature levels. This indicates 

that the absolute humidity level is the decisive influencing 

factor, whereby an additional influence of the temperature 

level on the pulse shape parameters cannot be excluded. 

C. Influence of the temperature level 

In Fig. 8 the box plots for 100 values of the determined pulse 

shape parameters rise time, pulse width and fall time are 

depicted as well as those for the apparent charge for positive 

corona discharges occurring at a varying temperature level. It 

is shown, that a variation of the temperature level affects the 

pulse shape for both considered relative humidity levels. All 

determined pulse shape parameters decrease with an 

increasing temperature level. This is particularly apparent in 

the case of the fall time and the pulse width. Focusing on the 

latter and on the measurements at a relative humidity level of 

40 %, the median for a temperature level of 20 °C is in the 

range of 130 ns whereas the median for a temperature level of 

65 °C is in the range of 22 ns. This corresponds to a reduction 

of almost one sixth. 

 

Fig. 5.  Box plots for the pulse shape parameters rise time, pulse width and 

fall time of two different measurement series carried out at a temperature 
level of 20 °C and a absolute humidity level of 11 g/m³. 

 

 

Fig. 6.  Temporal development of the the pulse shape parameters rise time, 

pulse width and fall time as part of a long-term study carried out at a 
temperature level of 20 °C and an absolute humidity level of 11 g/m³. 

 



 

  

 
 

Fig. 8.  Box plots for the pulse shape parameters rise time (top left), pulse width (top right), fall time (bottom left) and the apparent charge (bottom right) of 
positive corona discharges occuring under a varying temperature level for relative humidity levels of 40 % and 80 %. 
 

 

 

 

  

Fig. 7.  Medians of the pulse width (left) and the fall time (right) for positive corona discharges in dependence of the absolute humdity. 
 

 

 

 

 



 

  

 
 

Fig. 9.  Box plots for the pulse shape parameters rise time (top left), pulse width (top right), fall time (bottom left) and the apparent charge (bottom right) of 
positive corona discharges occuring under a varying relative humidity level for temperature levels of 20 °C and 50 °C. 
 

 

 

 

D. Influence of the relative humidity level 

The box plots for the determined values concerning an 

influence of the relative humidity level are illustrated in Fig. 9. 

The distribution and the location of the 100 gained values for 

the rise time, the pulse width, the fall time and the apparent 

charge clarifies that the pulse shape is affected by a varying 

relative humidity level. With the exception of the rise time, all 

considered parameters decrease with an increasing relative 

humidity level. In relation to the pulse shape parameters this is 

particularly apparent in the case of the pulse width and the fall 

time. Focusing on the fall time and on the measurements at 

50 °C, the median for a relative humidity level of 20 % is in 

the range of 77 ns whereas the median for a relative humidity 

level of 95 % is in the range of 17 ns. This corresponds to a 

reduction of almost one fifth. Besides the fundamental 

influence of the relative humidity level on the pulse shape 

parameters, the box plots, illustrated in Fig. 9, suggest a linear 

dependency between the location of the pulse shape 

parameters and the relative humidity level for the 

measurements at 20 °C. For the measurements at 50 °C the 

change in value suspects a non-linear relationship. This 

indicates that the relative humidity level is not the decisive 

influencing factor. 

E. Reconciliation with physical processes 

Independent of the considered climatic condition, the 

captured pulse shapes are characterized by a steep ascent and a 

slower descent. Relating to [28] this fundamental curve 

progression is directly traceable to involved physical 

processes. The needle-to-plate setup generates a strongly 

inhomogeneous electric field. Prerequisite for the development 

of a partial discharge process is the availability of a free 

electron in the area of the highest electric field strength. In the 

current case of a needle, appearing as positive high voltage 

electrode, the free electron is accelerated into the area of 

increasing field strength. This is associated with an energy 

absorption. Collisions with gas molecules lead to the 

emergence of secondary electrons and positive ions if the 

ionization energy is reached. A continued existence of the 

necessary ionization condition results in an avalanche effect, 

which causes the steep ascent of the pulse shape. An increase 



 

of the mean free path, e.g. by reducing the air density as a 

result of a rising temperature level, favors this effect. Whereas 

the electrons move very rapidly towards the needle tip and are 

accepted by the anode or attached to molecules with a high 

electron affinity, the positive ions form a positive space 

charge. Because of the low mobility of the positive ions, the 

space charge drifts very slowly in the direction of the cathode. 

This entails a reduction of the effective field strength near the 

needle tip, which hampers the ionization process, favors the 

attachment process and leads to a decreasing discharge 

current. Therefore, the characteristic of the pulse shape is 

significantly dependent on the ionization and the attachment 

coefficient 

Experimental tests prove that a surge of the humidity level 

goes along with an increasing attachment coefficient [29] and 

an increasing ionization coefficient [30]. The same applies to a 

rise of the temperature level [31]. This knowledge is already 

utilized to explain the impact of the temperature and the 

humidity level on the breakdown voltage and the PD inception 

voltage. Coupled with the fact that the mean free path is 

magnified, which favors relevant collision processes, a 

declaration of the ascertained influence of a varying 

temperature and humidity level on the pulse shape parameters 

is enabled. 

Considering the temporal progression of the PD process 

described above, an increasing ionization coefficient results in 

a steeper ascent of the pulse shape and a decreasing rise time. 

Apart from a growing number of free electrons, the hampering 

positive space charge is build up in a shorter time span. This is 

accompanied by a reduction of the pulse width and the 

amplitude. The minimization of the effective field strength 

near the anode enhances the possibility of attachment 

processes. These are favored by an upward attachment 

coefficient, which results in a decreasing fall time. 

Consequently, the apparent charge decreases as well, if all 

abovementioned parameters decline. 

VI. CONCLUSIONS 

To obtain detailed information regarding the influence of 

the temperature and the humidity level, the pulse shapes of 

corona discharges are captured for 13 different climatic 

conditions. By performing a long-term study and carrying out 

investigations at one climatic condition more than once, it is 

proven that the proposed measuring method is suited to 

investigate the influence of the temperature and the humidity 

level. Regarding the latter, a determination of the pulse shape 

parameters results in comparable values, so that a high 

repeatability is achieved. This applies also if the needle, which 

emulates corona discharges, is substituted. A comparative 

analysis of pulse shape parameters, gained from measurements 

at different climatic conditions, illustrates that an increasing 

temperature level at a constant relative humidity level as well 

as an increasing humidity level results in decreasing pulse 

shape parameters. Therefore, the interpretation of PD impulses 

requires a consideration of the climatic condition. The 

dependency can be reconciled with the reliance of the 

ionization coefficient and the attachment coefficient on the 

varying atmospheric parameter. Regarding the influence of the 

humidity level it is assumed that the absolute humidity is the 

decisive influencing factor. To verify this assumption, it is 

recommended to carry out supplementary investigations. This 

should entail an investigation of a varying temperature level at 

a constant absolute humidity. 

 

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 International Conference on Environment and Electrical 

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	I. INTRODUCTION
	II. Experimental set-up
	A. PD measuring circuit
	B. Measuring Cell
	C. Test device

	III. experimental procedure
	A. Determination of the inception voltage
	B. Capturing of the pulse shapes

	IV. data analysis and presentation
	V. results and discussion
	A. Appropriateness of the measurement method
	B. Influence of the absolute humidity level
	C. Influence of the temperature level
	D. Influence of the relative humidity level
	E. Reconciliation with physical processes

	VI. Conclusions
	References