PSP Diagnostics Compendium Part II_V01_EN.pdf

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Training Compendium

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Diagnostics

Part II

Part II Version 01,17.03.2020 17:07:09
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Table of contents

Table of contents................................................................................................................................... 2
List of figures......................................................................................................................................... 4
List of tables.......................................................................................................................................... 7
Formula.................................................................................................................................................. 8
1 Introduction.............................................................................................................................. 10
2 Basics for transformer measurements.................................................................................... 11
2.1 General.................................................................................................................................... 11
2.2 Dielectric properties of insulating material – the dissipation factor......................................... 12
2.2.1 Dissipation factor: definition of the term.................................................................................. 13
2.2.2 Dissipation factor: ideal component and ideal material........................................................... 13
2.2.3 Dissipation factor: real component and real material.............................................................. 14
2.2.4 Dissipation factor: typical values for transformers and bushings............................................ 15
2.2.5 Dissipation factor: influence of frequency and temperature.................................................... 15
2.2.6 Short circuit and potential connection of capacities................................................................ 16
2.2.7 Negative dissipation factor...................................................................................................... 18
2.2.8 Test methods UST and GST................................................................................................... 19
2.3 Polarization.............................................................................................................................. 21
2.4 Interference of test signal........................................................................................................ 24
2.5 Guarding.................................................................................................................................. 27
2.5.1 Definition of terms................................................................................................................... 27
2.5.2 Measuring principle................................................................................................................. 27
2.6 Device grounding.................................................................................................................... 29
2.6.1 General.................................................................................................................................... 29
2.6.2 Reduction of total resistance of ground loop........................................................................... 29
3 Dissipation factor and capacitance measurement on the transformer.................................... 32
3.1 General.................................................................................................................................... 32
3.2 Definition of terms................................................................................................................... 32
3.3 Components............................................................................................................................ 33
3.4 Influencing factors................................................................................................................... 33
3.5 Measuring principle................................................................................................................. 33
3.6 Evaluation................................................................................................................................ 34
4 Dissipation factor and capacitance measurement on bushings.............................................. 37
4.1 General.................................................................................................................................... 37
4.2 Definition of terms................................................................................................................... 41
4.3 Components............................................................................................................................ 42
4.4 Influencing factors................................................................................................................... 44
4.5 Measuring principle................................................................................................................. 48
4.6 Evaluation................................................................................................................................ 48
4.7 Hot collar................................................................................................................................. 53
5 Moisture in paper – dielectric frequency response with FDS and PDC.................................. 54
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5.1 Definition of terms................................................................................................................... 54
5.2 Components............................................................................................................................ 54
5.3 Influencing factors................................................................................................................... 56
5.3.1 Measuring principle................................................................................................................. 58
5.3.2 Test setup................................................................................................................................ 60
5.3.3 Short circuit............................................................................................................................. 62
5.4 Measuring result...................................................................................................................... 63
5.5 Measures for improving the test signals................................................................................. 66
6 Magnetizing current................................................................................................................. 70
6.1 Definition of terms................................................................................................................... 70
6.2 Components............................................................................................................................ 71
6.3 Influencing factors................................................................................................................... 72
6.4 Measuring principle................................................................................................................. 73
6.5 Evaluation................................................................................................................................ 73
7 Vibro-acoustic measurement.................................................................................................. 77
7.1 General.................................................................................................................................... 77
7.2 Definition of terms................................................................................................................... 77
7.3 Measuring principle................................................................................................................. 78
7.4 Components............................................................................................................................ 79
7.5 Influencing factors................................................................................................................... 80
7.6 Performance of the measurement........................................................................................... 82
7.6.1 Diverter switch operation with diverter switch and tap selector.............................................. 82
7.6.2 Diverter switch operation with selector switch........................................................................ 83
7.6.3 Potential connection sounds................................................................................................... 83
7.6.4 Multi-column application.......................................................................................................... 84
7.7 Documentation........................................................................................................................ 85
7.8 Evaluation................................................................................................................................ 86
8 Frequency response of transformer – FRA............................................................................. 88
8.1 General.................................................................................................................................... 88
8.2 Definition of terms................................................................................................................... 90
8.3 Components............................................................................................................................ 90
8.4 Influencing factors................................................................................................................... 92
8.5 Measuring principle................................................................................................................. 93
8.6 Steps to perform...................................................................................................................... 94
8.7 Evaluation................................................................................................................................ 98
A Attachments.......................................................................................................................... 100
Bushing: Template for temperature documentation.............................................................. 100
Factors, powers and names.................................................................................................. 101
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List of figures

Figure 1 – Ideal and loss-free dielectric................................................................................................ 13
Figure 2 – Substitute diagram of an ideal insulator............................................................................... 14
Figure 3 – Vector diagram of an ideal insulator..................................................................................... 14
Figure 4 – Substitute diagram of the real insulator, parallel connection............................................... 14
Figure 5 – Vector diagram of real insulator........................................................................................... 14
Figure 6 – Two-winding transformer: shorted capacitances of the secondary and grounded winding. 17
Figure 7 – Two-winding transformer: Switch matrix for UST-A measurement...................................... 19
Figure 8 – Plate capacitor: free electrons in conductive material and resulting electric field in dielectric............................................................................................................................................................... 21
Figure 9 – Plate capacitor: free electrons in dielectric.......................................................................... 21
Figure 10 – Plate capacitor: aligned electrons...................................................................................... 22
Figure 11 – Polarization: Schematic overview of types of polarization and time constant................... 23
Figure 12 – Schematic representation of conductor, shield and field lines........................................... 25
Figure 13 – Three-conductor cable: Schematic design with conductor and two shields...................... 26
Figure 14 – Three-conductor cable: Connection to ground potential of inner shield on one side and of
outer shield on two sides....................................................................................................................... 26
Figure 15 – Current of a simple arrangement of an insulation.............................................................. 27
Figure 16 – Current over simple arrangement of an insulation with guard........................................... 28
Figure 17 – Schematic ground loop resistance between transformer and test equipment, dotted....... 30
Figure 18 – Schematic overview ground loop resistance of transformer and test equipment with
increased lead cross-section based on parallel conductors.................................................................. 31
Figure 19 – Three-winding transformer: names of all capacitances..................................................... 34
Figure 20 – Dissipation factor on the transformer: Voltage run for capacitances and dissipation factors
of a three-winding transformer, FFAC15118......................................................................................... 35
Figure 21 – Dissipation factor on the transformer: Frequency run for capacitances and dissipation factors
of a three-winding transformer, FFAC15118......................................................................................... 36
Figure 22 – Bushing: Typical test tap (left), American version (right)................................................... 37
Figure 23 – Bushing: insulation installed later on.................................................................................. 38
Figure 24 – Bushing: cross section of middle tube, paper insulation and condenser layers................ 39
Figure 25 – Bushing: Schematic overview of condenser coatings and insulation material.................. 40
Figure 26 – Bushing: Setup with test tap and condenser body............................................................. 41
Figure 27 – Bushings: Overview manufacturing technologies and distribution in the market............... 42
Figure 28 – Bushing: Test setup with HV cable and potential connection using spiral cable............... 45
Figure 29 – Bushing: Test setup with HV cable leads to measurement errors due to partial discharges............................................................................................................................................................... 46
Figure 30 – High-voltage bushing: Nameplate...................................................................................... 48
Figure 31 – Bushing: Frequency run for capacitances and negative dissipation factors, MR185904.. 49
Figure 32 – OIP bushing: dissipation factor frequency run with moisture in bushing of phase V, deviating
measurement for neutral conductor; MR083167................................................................................... 50
Figure 33 – OIP bushing: dissipation factor voltage run; MR083167.................................................... 50
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Figure 34 – Bushing: Note very low values of dissipation-factor measurement for bushing N up to 50 Hz,
MR1014185........................................................................................................................................... 51
Figure 35 – Bushing: Voltage run on RIP bushings with irregular test contact (red) and regular test
contact (blue)......................................................................................................................................... 51
Figure 36 – Bushing: Frequency run and voltage run of capacitance with typical course for technologies
OIP or RBP; FFAC000601.................................................................................................................... 52
Figure 37 – Hot collar: Overview of measurement of bushing without test tap..................................... 53

Figure 38 – Overview main insulation CHL with test circuit.................................................................... 55

Figure 39 – Dissipation factor over frequency – influence of various parameters................................ 57
Figure 40 – Test setup dielectric frequency response.......................................................................... 58
Figure 41 – Charging and discharging of a capacitor and polarization / depolarization assignment.... 60
Figure 42 – Shield potential connection of test cable on Kelvin clamp: red circle guard connection, blue
circle: short-circuit bridge to the other bushings.................................................................................... 61
Figure 43 – Shield potential connection to transformer: a) with Kelvin clamp, b) with screw terminal. 62
Figure 44 – Example of an FDS measurement using IDAX 300 and software IDAX 5.0..................... 63
Figure 45 – Dielectric frequency response using OMICRON DIRANA and PTM 4.5........................... 64
Figure 46 – Dissipation factor for dielectric frequency response with interferences............................. 64
Figure 47 – Currents of different dielectric response measurements with OMICRON DIRANA, current in
nA and time in seconds on x axis.......................................................................................................... 65
Figure 48 – Disturbed dielectric frequency response with OMICRON DIRANA, current in nA on y axis
and time in seconds on x axis............................................................................................................... 65
Figure 49 – HV power lines with electromagnetic waves that can lead to electrical interferences....... 66
Figure 50 – Disturbed signal improved by input in highest bushing...................................................... 67
Figure 51 – Two-conductor cable: Example of shielded test cable, left to right: jacket, shield net and foil,
dielectric, soul........................................................................................................................................ 68
Figure 52 – On the left, OMICRON DIRANA front with GUARD bushing; on the right: Kelvin clamp with
connection box for three-conductor cable and guard over 4-mm bushing and lab plug (hidden in the
picture)................................................................................................................................................... 68
Figure 53 – Extension of cross-section for guard connection between test equipment and Kelvin clamp............................................................................................................................................................... 69
Figure 54 – Substitute diagram, neglecting the secondary-side winding impedance........................... 71
Figure 55 – Substitute diagram, single-phase, in no-load operation..................................................... 71
Figure 56 – No-load test current: presentation in typical, frequently used bar chart............................. 74
Figure 57 – No-load test current: presentation of eddy iron losses in typical, frequently used bar chart............................................................................................................................................................... 74
Figure 58 – Diagram of transformer turns ratio..................................................................................... 75
Figure 59 – No-load test current I0m at 10 kV test voltage................................................................... 75
Figure 60 – Vibro-acoustic measurement: Example of a specimen with excited transformer during
change-over selector operation, with motor sounds............................................................................. 79
Figure 61 – Vibro-acoustics: Frequency-time presentation in the upper half and envelope graph for
frequency band 10-100 kHz in the lower half of the picture; bad signal to noise relation..................... 81
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Figure 62 – Vibro-acoustics: Frequency-time presentation in upper half and envelope graph for
frequency band 10-100 kHz in lower half of picture; good signal to noise ratio.................................... 81
Figure 63 - Vibro-acoustics: Frequency-time presentation of diverter switch operation and arc of a
change-over selector operation with arc............................................................................................... 83
Figure 64 – Vibro-acoustics: Voltage signal of a complete on-load tap-changer operation without tap
selector or change-over selector........................................................................................................... 86
Figure 65 – Vibro-acoustic measurement: Frequency-time presentation of energized transformer with
drive shaft noise.................................................................................................................................... 87
Figure 66 – Vibro-acoustic measurement: Envelope graph of frequency band 10 kHz -100 kHz with very
good distance between peak at 10 dB and sound at < -40 dB............................................................. 87
Figure 67 – RLC network overview....................................................................................................... 88
Figure 68 – Frequency response of the transformer: Schematic presentation of the test method
frequency response on the transformer with Bode diagram for amplitude and phase......................... 89
Figure 69 – Frequency response of transformer: Dampening in decibel, top part, and phase shift in
degrees, see below............................................................................................................................... 89
Figure 70 – Frequency response of transformer: Dampening and influence of components on typical
frequency bands.................................................................................................................................... 91
Figure 71 – Frequency response of transformer: Positive and negative example of grounding strap.. 92
Figure 72 – Frequency response of transformer: Terminal with coaxial cables for input and reference............................................................................................................................................................... 93
Figure 73 – Frequency response of transformer: Terminal with coaxial cable for measurement......... 94
Figure 74 – Frequency response of transformer: Grounding straps on bushing base.......................... 95
Figure 75 – Frequency response of transformer: Terminals with coaxial cables and strain relief on
bushing pin............................................................................................................................................ 95
Figure 76 – Frequency response of transformer: BNC adapters for coax cables................................. 96
Figure 77 – Frequency response of transformer: Example of connection of all three cables on bushing
for zero measurement........................................................................................................................... 96
Figure 78 – Frequency response of transformer: Documentation of test setup and check of test
equipment and cables using zero measurement.................................................................................. 97
Figure 79 – Frequency response of transformer: Example for pictures and assignment..................... 97
Figure 80 – Frequency response of transformer: Auto transformer with complete regulating and parallel
winding................................................................................................................................................... 98
Figure 81 – Frequency response of transformer: Auto transformer with all winding turns................... 99
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List of tables

Table 1 – Substitute diagram, vector diagram and dissipation factor of the ideal capacitor................. 14
Table 2 – Substitute diagram, vector diagram and dissipation factor of the real capacitor.................. 14
Table 3 – UST measurements............................................................................................................... 20
Table 4 – GST measurements.............................................................................................................. 20
Table 5 – Dissipation factors: Typical values and limit values for bushings at rated frequency and 20 °C............................................................................................................................................................... 52
Table 6 – Bushing: Limit values for deviation of measured to original capacitance at 20 °C and rated
frequency............................................................................................................................................... 52
Table 7 – Frequency and cycle duration of a sinusoidal wave.............................................................. 59
Table 8 – Bushing: Template for documentation of temperatures during measurement.................... 100
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Formula

C̅1 Capacitance of all condenser layers of condenser bushings

C̅2 Capacitance of condenser bushings between test tap and ground potential

C̅HL Capacitance between primary and secondary winding (H for High and L for Low)

C̅H Capacitance between primary winding and ground potential (H for High)

C̅L Capacitance between secondary winding and ground potential (L for Low)

ϵr
relative permittivity

Hi electric field strength in the conductor of a cable

HO electric field strength in the shield of a cable

𝐼0̅ No-load current at rated voltage

̅
𝐼0m No-load test current, no-load current at measured voltage

IC̅ capacitive reactive current, current through purely capacitive consumer / component

̅
𝐼CH Current of capacitance between primary winding and ground potential (H for High)

̅
𝐼CHL Current of capacitance between primary and secondary winding (H for High and L for
Low)

̅
𝐼CL Current of capacitance between secondary winding and ground potential (L for Low)

̅
IFE Iron loss current

𝐼m̅ Test current

𝐼µ̅ Magnetizing current

𝐼n̅ Rated current

IR̅ Active current, current through purely ohmic consumer / component

̅q
U Voltage of a voltage source

̅n
U Rated voltage between two phases in three-phase transformer

̅ FE
R Iron loss resistance
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𝑋̅h Reactance of main inductance

≂ Minus Tilde, stands for AC and DC voltage source
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1 Introduction

The basics about the transformer that are described in Compendium Part I are essential prerequisite for
the present Compendium Part II. We refer to the titles of the relevant chapters of Part I only occasionally.

The described physical and electrical phenomena are presented in simplified terms, with the intention
to achieve basic understanding. This presentation is not intended for a more in-depth examination.
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2 Basics for transformer measurements

2.1 General

The terms used in part II of the compendium are difficult to understand at the beginning. Therefore we
will first give a brief summary of why and for what reason dissipation-factor measurements are
performed.

We are dealing with the power transformer part that insulates high voltages: oil and paper, so-called
dielectrics. If dielectrics cannot insulate two potentials against each other anymore, flashovers will occur
that usually mean the end of a transformer's life.

The components that are to be isolated from one another and the dielectric between the components
form a capacitor. This is an advantage for the measuring technician, because the capacitor can be
measured. To be more specific, impedance of the capacitor is measured. Impedance represents an
ideal and a real part of the capacitor. The ideal part is the loss-free capacitor that consists of capacitance
only. The real part represents the losses in the capacitor.

Basically, these losses are very low. The corresponding current is very small. Current is so small that it
is necessary to equip the test cables with double shields. Sometimes this is not sufficient either, and
additional measures must be taken, which means greater effort than, e.g., test setup for a winding
resistance measurement at 6 A test current.

Over the years, that is, when the dielectric ages, losses in the capacitor or dielectric of the transformer
increase. In addition, there will be more and more water in the paper. On the molecular level, water
consists of dipoles whose behavior depends on frequency. This is another fact that can be exploited by
the measuring technician. At very low frequencies, the behavior of dipoles can be clearly differentiated
from other molecules. Therefore interpretation of the dissipation factor was developed further, and the
original method was enhanced and adjusted.

Dissipation factors of dielectrics can be measured using high voltages, frequency sweep, rated
frequency or very low frequencies. All of the methods have the same goal: interpretation of the results
should allow to assess the condition of the dielectric in the transformer and bushings.

The correlations presented in short form here will be discussed in detail in the following chapters.
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2.2 Dielectric properties of insulating material – the dissipation factor

Transformers utilize voltages and currents. This means that components of different potentials must be
separated from each other or in other words, insulated against each other. Electrically insulating
materials are used for this purpose. Insulating materials that are penetrated by electric fields are called
dielectrics. The property to insulate electric fields more or less well is called permittivity.

As an illustration, let us look at a simple application that is very common in electrical technology. When
a plate capacitor made from two conductive, parallel plates and a dielectric that is placed in-between,
the main job of the dielectric is to let the electric field pass as lossless as possible and at the same time
prevent the charge carriers on the plate from penetrating through the dielectric.

If electrically conductive molecules or molecules that can be changed by the electric field are present in
the dielectric, the dielectric properties of the dielectric change; the keyword here is "polarization". Ohmic
losses can occur, or, in the worst case, faults such as breakdowns.

Losses of a dielectric are very much dependent on frequency and temperature. On the one hand, this
means that temperature as test quantity must always be measured and recorded when testing in the
field and on the other hand, that you can perform tests with different frequencies and identify the
influence of disturbing molecules at specific frequencies.

The majority of transformers that are tested by MR are oil-immersed transformers. Most of the times,
mineral oils, cellulose, that is paper, and pressboard are used as insulation. Cellulose and pressboard
also take on design and mechanical protection tasks and prevent direct contact of conductive
components with different potentials when impact is exerted by external forces. Apart from its job to
improve insulation, mineral oil also cools and greases the on-load tap-changer.

Regarding application of dielectrics in the transformer, one can generally say that aging, moisture, gases
and particles account for the largest amount of weakening of dielectric properties. Therefore insulations
in transformers and bushings are very often tested for water content and electric conductivity.
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2.2.1 Dissipation factor: definition of the term

The dissipation factor - together with other parameters that will not be discussed here - was introduced
to identify quality and aging of an insulator or dielectric. There are other terms that are used as synonyms
and mean the same thing. When dealing with this compendium and with customers, the term dissipation
factor is used.

Dissipation factors for insulator and dielectric are described below. The insulator is a technical
component that comprises a dielectric. The dielectric is to be understood as integral part of a component,
only rarely as single material.

2.2.2 Dissipation factor: ideal component and ideal material

If a dielectric is ideal, it insulates two conductors from each other without losses. The measured current
of the capacitor in which the dielectric is arranged, is then purely capacitive, that is, current precedes
voltage by 90 degrees. The elements in the substitute diagram are presented using AC voltage source
and capacitor, see Figure 1.

IC

Uq ~

Im = IC
A

Figure 1 – Ideal and loss-free dielectric

Impedance of the ideal insulator can be calculated as follows

1 (1)
𝑍̅ = R ∢ 0° + X ∢ − 90 ° = 𝑋̅𝐶 = ∢ − 90 °
2π𝑓𝐶
Ohmic resistance is zero, and therefore the real portion of the current of an ideal insulator becomes
zero. When the ohmic portion of the current becomes zero, the angle between capacitive current and
ohmic current is zero, too. With this, the dissipation factor becomes zero.
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The related electrical substitute diagram, vector diagram and dissipation factor are presented in Table 1.

Table 1 – Substitute diagram, vector diagram and dissipation factor of the ideal capacitor
Vector diagram in the coordinate Dissipation
Substitute diagram
system factor
IC IR̅
tan δ = = 0
IC̅

Im = IC
Uq ≂ XC

Im = IC Uq
A

Figure 2 – Substitute diagram of an ideal insulator Figure 3 – Vector diagram of an ideal insulator

For ideal insulators and dielectrics, test current is identical to capacitive current since there are no
losses, as described above. The angle between test current and capacitive current is zero and therefore
dissipation factor tan δ is zero, too.

2.2.3 Dissipation factor: real component and real material

When an insulator or dielectric is real, there are losses in the dielectric, for example from polarization,
or losses on the insulators caused by surface currents over the shell or the component's outside.

Impedance of the real insulator can be calculated as follows

1 (2)
𝑍̅ = R ∢ 0° + X ∢ − 90° = 𝑅∢ 0° + ∢ − 90°
2π𝑓𝐶

This means that active current is present on a real insulator; it stands for the losses of the insulator. This
is illustrated in the substitute diagram in Figure 4.

Table 2 – Substitute diagram, vector diagram and dissipation factor of the real capacitor
Substitute diagram Vector diagram in the coordinate Dissipation
system factor
I IR̅
tan δ = > 0
IC̅
IR IC
IR
IC
Uq ≂ R XC
δ Im = IC + IR
Im = IR + IC
A
Uq
Figure 4 – Substitute diagram of the real insulator, parallel Figure 5 – Vector diagram of real insulator
connection
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Losses over the surface of an insulator such as a bushing shed, are presented as parallel connection
of ohmic resistance and capacitance. Losses within the insulator or dielectric are calculated as series
connection of ohmic resistance and capacitance; but for reasons of simplicity, this will not be dealt with
in this compendium.

When evaluating an insulator or dielectric using the dissipation factor, current over the surface should
not be recorded. This is discussed in section 2.2.8 in the context of test method selection and in section
2.5 in the context of Guarding.

The vector diagram shown in Figure 5 applies for real components. Capacitive current IC̅ is an ideal
current. This current does not flow but is introduced for reasons of illustration and calculation. This ideal,
capacitive current IC̅ is, together with the ohmic portion IR̅ , the actually measured test current as sum of
ohmic and capacitive current. If test current 𝐼m̅ is purely capacitive, the dissipation factor becomes zero.
This would mean that a dielectric is perfect and ideal, that is, loss-free.

Losses also depend on aging, therefore when comparing old and more recent measurements, aging of
an insulation can be reconstructed and unsafe operating conditions can be identified.

2.2.4 Dissipation factor: typical values for transformers and bushings

In new condition, the values of dissipation factors of insulators and dielectrics are close to zero. As
values are so small, the dissipation factor is multiplied by 100 and then specified in percent. Typical test
values range from 0.2 to 1 percent.

Losses of transformer and bushing insulations are dependent on frequency and, to a large degree, on
temperature. Therefore all of the manufacturer values are referenced to rated frequency and a typical
common temperature of 20 °C.

2.2.5 Dissipation factor: influence of frequency and temperature

All ohmic resistances in this section 2.2 depend on frequency and temperature. At low frequencies,
surface water or moisture in the dielectric can still align its dipoles in accordance with polarity of the
sine-shaped voltage in direction + or –. When increasing frequency, the dipole will align less and less,
until it is not aligned at all to the sine of the input signal at high frequencies. This also implies that ohmic
resistances get less and less.

At the same time, temperature in the dielectric changes mobility of the molecules. This is obvious for
frozen water. Water molecules move less at low temperatures, therefore dissipation factor at low
temperatures is different than dissipation factor at high temperatures. This is very important for
measurement and interpretation by means of comparative values.

Therefore all manufacturer specifications refer to rated frequency and 20 °C. Temperature corrections
using factors will continue to be used, though we are fully aware of the inaccuracy of these factors.
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2.2.6 Short circuit and potential connection of capacities

Measurements on site often require fast technical solutions that can be reached by changing
connections on transformer or test equipment. In this context, let us discuss short-circuit of
capacitances.

When a capacitor or a capacitive arrangement, e.g., two windings, is loaded by a voltage source, this
capacitive arrangement will change its load when the frequency of the voltage source changes. When
the capacitance is short-circuited, the capacitor becomes operatively ineffective and on the other hand,
the capacitor can self-discharge when the voltage source is switched off. The first point is important to
avoid charge time of a capacitor where necessary, this is especially true for direct current. The last point
contributes to safety at work.

A further possibility during measurement is potential connection of a capacitor or capacitor-like
arrangement. On complex test objects such as transformers, it may be necessary to connect
components or arrangements to ground potential to avoid charging and discharging of the resulting
capacitances. This is very often a short-circuit via the transformer grounding. This is illustrated in Figure
6, with the secondary winding connected to ground potential.

Capacitive coupling and circulating currents can only develop if two adjacent parts have different
electrical potentials and an electric field can build up between these potentials. If we put this into
common language, we can say: If both sides of a setup that was first arranged like a capacitor have the
same potential, the electrons do not need to move in any direction because the electrons are already in
balance.

If you notice unintentional charging caused by coupling capacitance during DC measurements or
capacitive interferences especially during high-frequent measurements with AC voltages, connecting
both sides of the capacitor-like setup to ground potential can rectify the problem.

When measuring capacitive setups, always consider which potential is supplied to a component by
short-circuiting or deliberate potential connection. In the above example of a two-winding transformer,
see Figure 6, ground potential was applied to the secondary winding. This changes capacitance C̅H ,
since potential of the transformer tank now brings ground potential closer to the primary winding.

For measurements of capacitance, it is therefore necessary to remove any connections from the
transformer. This is especially true for capacitor banks of industrial transformers.
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primary winding
secondary winding

CHL

CH

CH CL

Figure 6 – Two-winding transformer: shorted capacitances of the secondary and grounded winding
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2.2.7 Negative dissipation factor

As described in previous chapters, the dissipation factor of a real insulator or dielectric is greater than
zero, that is, the dissipation factor assumes a positive value.

Yet negative dissipation factors were occasionally measured during measurements of transformers and
bushings. A negative dissipation factor would mean that charges or current would flow permanently from
the capacitive setup. But since a dielectric does not emit electrons, i.e., is not a current source, this is
not possible.

Therefore it is important to understand that in such cases, the causes are inductive or electrical couplings
or electromagnetic interferences, see section 2.4, or resonances from unfavorable ground loop
impedances or test cable or ground connections, see section 2.6. These causes can often be eliminated
using simple measures or means.
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2.2.8 Test methods UST and GST

Test equipment with several inputs and outputs and several measuring units can be equipped with
switch matrices. The switch matrices are supposed to add or remove inputs for measurement. For
example it may be necessary to test a capacitive current on only one channel, and bypass surface
currents of a bushing around the measuring unit, via the second channel and by means of a so-called
guard.

The dissipation-factor measurement of a two-winding transformer is shown below as simple example.
The switch matrix is presented in a simplified and basic way in the test equipment in Figure 7. The point
is that the equipment itself can make the necessary connections depending on the respective task, and
consequently measure the relevant single or common channels. In the example shown below, only the
capacitive current of the secondary side is routed to the Ampere meter. Current over the bushing surface
and the transformer tank (capacitive and ohmic) is bypassed around the measuring unit.

promary winding
ICHL + ICL+ ICH Source / Ausgang

secondary winding ICHL Input / Eingang A
~ Uq

ICL+ ICH

Input / Eingang B

A
ICHL

CHL

CH CL

ICH ICL Ground / Erdung

Figure 7 – Two-winding transformer: Switch matrix for UST-A measurement

The following terms were established to identify the different connections of the switch matrix
unambiguously:

1. ungrounded specimen test UST, for ungrounded specimen or ungrounded test circuit, and

2. grounded specimen test GST, for grounded specimen or grounded test circuit.

The terms and principles are explained below.

In the group of ungrounded test circuits (UST), only ungrounded channels are measured. Either one or
two test circuit(s) with ground potential connection are always bypassed around the measuring unit.
Therefore three measurements - presented in Table 3 - are possible, that are named in accordance with
the test circuits that are routed into the measuring unit.
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Table 3 – UST measurements
Measurement Input A Input B Ground potential
UST A measured bypassed bypassed
UST B bypassed measured bypassed
UST (A+B) measured measured bypassed

In the group of grounded test circuits (GST), all grounded test circuits are measured. That is, up to three
channels can be measured concurrently. Therefore four measurements - presented in Table 4 - are
possible, that are named in accordance with the test circuits that bypass the measuring unit.

Table 4 – GST measurements
Measurement Input A Input B Ground potential
GST measured measured measured
GSTg A bypassed measured measured
GSTg B measured bypassed measured
GSTg (A+B) bypassed bypassed measured

Transformers are often tested in the substation. In substations, strong electromagnetical stress often
exists due to adjacent overhead and power lines. Therefore it is possible that capacitive and inductive
couplings are integrated into the measurement via the transformer tank. A clear disturbance of the
measurement or falsification of the results can arise from this. As the loop is bypassed around the
measuring unit during UST measurements, this method is more stable and insensitive. Therefore UST
measurement should be preferred to GST measurement whenever this is possible.
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2.3 Polarization

Basically, all materials have free electrons. Depending on number of free electrons or charge carriers,
materials are referred to as conductive and non-conductive.

If voltage is applied to electrically conductive material, an electric field is set up between parallel
structures of different potentials. All free electrons of the conductive material align along the applied
potential, see Figure 8.

IC

++++++++++++++++++

Uq
E

- - - - - - - - - - - - - - - - - -

Figure 8 – Plate capacitor: free electrons in conductive material and resulting electric field in dielectric

If a real dielectric is present between parallel conductors, this dielectric also contains free electrons or
charge carriers, see Figure 9.

IC = 0

Uq = 0 + -
+ -
-
+
- +

Figure 9 – Plate capacitor: free electrons in dielectric

When applying voltage, these free electrons in the dielectric align along the existing electric field, see
Figure 10. The process of charge alignment is called polarization as the simplified arrangement
represents two poles where positive and negative charges move.
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IC

++++++++++++++++++
- - - -
Uq
E

+ + + +
- - - - - - - - - - - - - - - - - -

Figure 10 – Plate capacitor: aligned electrons

There are different types of polarization. They can be subdivided according to their character, which in
turn depends largely on the specific dimensions.

1. Polarization within an atom is called electronic,

2. Polarization within a molecule is called atomic,

3. Polarization of entire molecules is called dipolar, and

4. Polarization of molecules along boundary surfaces of two dielectrics is called boundary
surface polarization.

The duration of the listed polarization types varies. If frequency of the applied electric field varies, rapidly
completed operations are relevant with high frequencies, whereas the slower types are only relevant
when lower frequencies are used, see Figure 11.
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IC = 0 IC
electronic
+++++

Uq = 0 ~ + E=0 Uq ~ + E(f = 1 000 000 000 000 000 Hz)

- - - - -

IC = 0 IC
atomic
+++++

+ - -
Uq = 0 ~ E=0 Uq ~ + + E(f = 1 000 000 000 000 Hz)
- + -

- - - --

IC = 0 IC
dipole
+++++
+ -
- -
Uq = 0 ~ E=0 Uq ~ + + E(f = 1 00 000 000 Hz)
- +

- - - - -

IC = 0 IC
interfacial
+++++
+ -
-
+ -
- + +
Uq = 0 ~ - + E=0 Uq ~ E(f = 0,001 Hz)
-
+ - - +
+
- - - - -

Figure 11 – Polarization: Schematic overview of types of polarization and time constant
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2.4 Interference of test signal

To achieve basic understanding, the physical phenomena and electrical components described in this
chapter are presented in simplified form. This presentation is not intended for a more in-depth
examination.

Conductors, whether cables or wires, are susceptible to interferences from adjacent electric or magnetic
fields. Put simply, there are two influences relevant for substations or industrial complexes:

1. AC power or overhead lines induce induction voltage in adjacent conductors.

2. In every conductor, capacitive influences add current in every adjacent conductor; this current
again causes disturbing voltages.

In accordance with the Faraday principle, a conductive surface such as metal foil or shield mesh can
block a conductor from electric or magnetic fields, see Figure 12. The outer field with magnetic field
strength HO hits the shield mesh, which then absorbs the field. That is, magnetic field strength inside the
conductor Hi is very much smaller than in the shield. This correlation between inside and outside
magnetic field strength is presented in Figure 7, using the mathematical expression Hi ≪ HO.
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Figure 12 – Schematic representation of conductor, shield and field lines

Source: https://sekels-magnetic-shielding.eu/index.php?title=Magnetische_Abschirmungen; requested on 20190412

To discharge the voltages and currents developing in the shield, the shield potential can be connected
to ground potential. Depending on type and character of interfering and test signal, both ends or one
end of the shield are connected to ground potential.

Capacitive and inductive interferences are present in substations and steel works. Where necessary
and possible, a cable with one conductor and two shields is therefore used, see design of three-
conductor cable in Figure 13 as an example.
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shields conductor

insulation
Figure 13 – Three-conductor cable: Schematic design with conductor and two shields

From wdwd - Eigenes Werk, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=24154842; requested on
20190801

To be able to protect the test signal from any type of interference, one of the shields must be connected
to ground potential on one side, the second shield must be connected to ground potential on two sides,
see Figure 14.

Figure 14 – Three-conductor cable: Connection to ground potential of inner shield on one side and of outer shield on two sides
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2.5 Guarding

2.5.1 Definition of terms

The term "guard" refers to the English verb "to guard", meaning to protect or the English noun "guard"
for protector. In measurement technology, it describes bypassing of currents around the measuring unit,
in order that the test signal can be measured and recorded without errors.

A guard belt made of flexible, semi-conductive material is used for bushing measurements. This shell is
attached to the outer shell of the bushing. Please see chapter 4 for details.

The term "guard" is also used when you are planning to connect a shield of the three-conductive cable
to ground potential. In PDC / FDS measurement, there is one connection on the test equipment and one
on the terminal box on the Kelvin clamp, which are called guard bushings. Please see chapter 5 for
details.

2.5.2 Measuring principle

Looking at real insulation, see Figure 15, capacitive current will develop when applying voltage to the
two insulated conductive and parallel materials. Another current flows through particles in dirt or
moisture over the surface of the real insulator. For reasons of simplicity and clarity, losses in the
dielectric are neglected here. Therefore test current in Figure 16 is approximatively the sum of surface
current IR̅ and capacitive current IC̅.

Ic + IR

Uq ≂
IR

IR + IC
A

Figure 15 – Current of a simple arrangement of an insulation

Currents can be bypassed around the measuring unit via the guard. To do so, the guard is connected
to the surface of the insulator, that is connected to ground. For the arrangement of two conductive and
parallel materials, a test circuit in accordance with Figure 16 can be assumed.
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IC + IR

Uq ≂
IR

IR

A
IC
Figure 16 – Current over simple arrangement of an insulation with guard

The arrangements shown in this section are supposed to clarify the "guard" principle. The same principle
applies to more complex geometrical arrangements such as bushings or transformers. The currents
bypassed around the measuring unit can be capacitive or ohmic; they will be presented in more detail
in the respective section.

Surface currents depend on frequency. Consequently, the ohmic portion, that is, loss current, changes
with frequency of the test current. If moisture on the insulation fins of a bushing leads to changed graphs,
this change is also dependent on frequency of the test voltage. This must always been taken into
consideration for the plausibility check.
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2.6 Device grounding

2.6.1 General

Device grounding refers to the electrical connection of a conductive housing, component or device to
ground potential. When a fault or failure occurs, touch voltage of a device should be max. 50 AC voltage
for reasons of personal protection. In addition, fault currents should be diverted in order to protect
components. Furthermore, parasitic and surface currents are diverted to ground.

For the transformer test, the ground point - that is, the point where the terminal of the ground cable is
connected to ground potential - should be identical with the ground point of the transformer.

Basically, transformer test equipment is equipped with safety plugs. Whether this ground potential is
connected and used in the test equipment, cannot be judged from the exterior.

2.6.2 Reduction of total resistance of ground loop

Basically, the algebraic sign of a dissipation factor of a dielectric is positive. The dissipation factor for
real insulations must always be positive. But it occurs occasionally that negative dissipation factors are
measured by the test equipment. In those cases, the ohmic portion of the test circuit is too high. An
important factor for improvement is to reduce ground loop resistance. Ground loop means the portion of
the test circuit that is connected via ground cables, potential connections and substation grounding. In
Figure 17, the ground loop is the dotted line as connection between transformer tank and test equipment
housing.
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Uq
primary winding ICHL + ICL+ ICH
~
ICHL + ICL+ ICH
secondary winding ICHL
A

CHL

CH CL

ICH ICL

Figure 17 – Schematic ground loop resistance between transformer and test equipment, dotted

There are several factors to change the test result; please see detailed description below.

2.6.2.1 Increasing cross-sectional area of conductor

Increasing the cross-sectional area between test equipment and test object improves ground loop
resistance considerably. It is best to use a low-ohmic and low-inductive ground lead for this. A
conventional cable / lead can also be used. Parallel to the existing ground connector, the additional
conductor is connected between ground point of transformer and ground point of test equipment, in
accordance with Figure 18.
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primary winding
secondary winding

CHL

test
equipment
CH CL

Figure 18 – Schematic overview ground loop resistance of transformer and test equipment with increased lead cross-section
based on parallel conductors

2.6.2.2 Contact-circuit resistance on ground point

Reducing contact-circuit resistance leads to a major improvement of ground loop resistance. Moisture,
grease, foreign layers and varnish must be removed before the test, or during troubleshooting at the
latest.

2.6.2.3 Equipotential bonding of test equipment on bushing base

If the dissipation factor of a bushing is still negative after performing all the measures, equipotential
bonding of the test equipment can be directly connected to the bushing flange. This will reduce the
number of potential leads in the ground loop and can therefore reduce the influence of bad contact
transitions from cable terminals and potential leads to the ground loop.

When swapping the test setup to an additional or different bushing, it is also important to attach the
equipotential bonding terminal of the device to the other bushing.
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3 Dissipation factor and capacitance measurement on the transformer

3.1 General

In the following, the term dissipation-factor measurement will be used as synonym for capacitance and
tan δ or Tangens Delta.

Measurement of dissipation factor and HV capacitances has been used for decades to determine the
condition of various equipment such as medium-voltage cables, rotating machines and bushings. For
transformers, the measurement was originally introduced to asses paper insulation, using 10 kV or 12
kV test voltage. For values of 10 kV and more and 15 to 400 Hz, it is the oil distance that is decisive for
the dissipation factor. Therefore dissipation-factor measurement of transformers is only suitable to a
limited extent for interpreting paper insulation.

Capacitance values are sometimes interesting for transformer manufacturers. They are of little use for
diagnosing transformers.

Dielectric frequency response, described in chapter 5, has become a superior system to assess
moisture in transformer insulation.

When dissipation-factor measurement on the transformer is requested by the customer, there are often
other reasons apart from technical ones. Using this unhelpful measurement to determine transformer
condition is often induced by insurance companies, internal regulations or lack of knowledge.

The basics described in chapter 2 are prerequisite for understanding the following relationships.

3.2 Definition of terms

The statements presented in 2.2.1 are valid.

Diagnosis using dissipation-factor measurement on the transformer is a voltage and frequency run. In
most cases, sine-wave 50-Hz voltage in steps of 2 kV up to 12 kV and typical frequencies of 15 Hz,
20 Hz, 35 Hz, 50 Hz, 135 Hz, 220 Hz, 305 Hz, 400 Hz are used for measurement. That is, when talking
about dissipation-factor measurement on a transformer, this refers to a multitude of test points that result
in graphs showing an expected course. In addition, it is a comparative measurement. As dissipation-
factor measurement is not a routine measurement at the transformer manufacturer's site, it is necessary
to perform a footprint measurement in the field, comparing later measurements with this first
measurement.
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3.3 Components

The insulation distances of transformers consist of various windings of paper, pressboard and wood,
and insulating oil. When components of different potentials are insulated against each other by paper
and / or oil, they are capacitors. The properties of the capacitors are defined by geometry (area,
distance) and composition of the dielectric. It has been shown that moisture in paper has less influence
on dissipation-factor measurement than conductivity of the oil.

3.4 Influencing factors

As described above, the result of the dissipation-factor measurement is determined by transformer
insulation. Basically, moisture and acidity in the paper and composition of the oil do have influence. The
ground loop of the transformer to the test equipment has an additional, important influence.

Temperature dependency of the transformer plays an important role. It is generally recommended that
the measurements are always performed at the same temperature, close to 20 °C.

3.5 Measuring principle

All phases of a winding are short-circuited, and primary winding is measured to secondary winding and
to tank.

The most important capacitance is the one between primary and secondary winding. The other
capacitances can also be measured, but they are of secondary importance for transformer diagnosis.
Depending on the rated voltage of the transformer, between 2 kV and 12 kV can typically be tested in
the voltage run and 15 Hz to 400 Hz in the frequency run.

There are no specific designations defined for the dissipation factors and capacitances. In Figure 19, all
capacitances that are possible on a three-winding transformer are shown as example, in accordance
with the naming conventions used by Omicron (equipment manufacturer). The same designation logic
is valid for any other equipment.
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primary winding

secondary winding
tertiary winding

CHL CLT

CH CL CHT CT

Figure 19 – Three-winding transformer: names of all capacitances
Legend: H = high voltage winding, L = low voltage winding, T = tertiary winding

3.6 Evaluation

A measurement is plausible when the capacitances are constant in both the voltage and frequency run,
and are in the range of Nanofarad (nF = 10−9 F) or Pikofarad (pF = 10−12 F). For the three-winding
transformer, this relationship is shown in the upper halves of Figure 20 and Figure 21.

A measurement is plausible when the dissipation factors are constant in the voltage run. In the frequency
run from lower to higher frequencies, it is normal that the dissipation factor increases. These
relationships are shown in the lower halves of Figure 20 and Figure 21 for a three-winding transformer
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Figure 20 – Dissipation factor on the transformer: Voltage run for capacitances and dissipation factors of a three-winding
transformer, FFAC15118

The graph for tan δ cor ICHT in Figure 20 shows a change in the voltage run, and all the values between
primary and tertiary winding are close to or below zero. One the one hand, this insulation distance
between primary and tertiary winding is difficult to measure because capacitance is very low, based on
the transformer geometry, and on the other hand, it is of little importance from an physical point of view.
Therefore, when tertiary windings are involved in dissipation-factor measurements on site, a graph that
is different from other measurements is often accepted.
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Figure 21 – Dissipation factor on the transformer: Frequency run for capacitances and dissipation factors of a three-winding
transformer, FFAC15118

At rated frequency and an oil temperature of 20 °C, the value of 0.5 % is typical for the dissipation factor,
whereas 1 % is considered as borderline.

Low or negative dissipation factors are not plausible. If they do occur, the test setup must be changed,
see section 2.2.7 and section 2.6. All the contacts must be cleaned and dried, the test setup with cross-
section enlargement or ground leads of the test setup must be changed. In addition, the transition
resistance of the test equipment grounding to the transformer should be changed.
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4 Dissipation factor and capacitance measurement on bushings

4.1 General

In the following, the term dissipation-factor measurement is used as synonym for measurement of
capacitances and tan δ or Tangens Delta.

When discussing diagnosis on site with the user, dissipation-factor measurement on bushings used to
mean HV measurement with voltage run up to 12 kV and frequency run of 15 to 400 Hz. In the future,
more and more measurements of the dielectric frequency response (FDS method) of bushings will be
used. This should be taken into consideration when dealing with the customer. When the FDS method
for frequencies up to 10 μHz is used, the influence of moisture on bushings can be shown in greater
detail. The advantage of the 12 kV measurement is that it is easier to detect contact problems of the
test tap using the voltage run.

Bushings can be measured when they are condenser bushings and equipped with a test tap at the
flange of the bushing, see Figure 22 as an example. This applies in particular to bushings for voltages
including 110 kV and more.

Figure 22 – Bushing: Typical test tap (left), American version (right)

Source: Cigré, Working Group A2.43, Brochure 755 Transformer bushing reliability, Paris, 2019

There is a possibility to retrofit condenser bushings with insulation in order to test them. This is done
using insulating sleeves and washers and an insulating gasket that separates transformer and bushing
flange electrically. This setup should provide an insulation resistance of at least 10 kΩ. During operation,
a potential lead must connect transformer and bushing. The lead must be removed for capacitance or
dissipation-factor measurement. The bushing flange can then be used as test tap. It is important not to
mistake the vent screw for test tap. All elements of this section are shown and labelled in Figure 23.
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Vent screw

Potential lead

Figure 23 – Bushing: insulation installed later on

Source: Cigré, Working Group A2.43, Brochure 755 Transformer bushing reliability, Paris, 2019

Aluminum layers in bushings are used in order to achieve a more homogeneous field distribution, that
is necessary for higher voltages, along the bushing conductor. This is done by wrapping electrically
conductive foils in insulation material such as paper, see Figure 24 and Figure 25.
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Figure 24 – Bushing: cross section of middle tube, paper insulation and condenser layers

Source: Krüger, Dr. M: Diagnostic Measurements on High Voltage Bushings, Presentation Omicron Energy, AT, 2014
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Figure 25 – Bushing: Schematic overview of condenser coatings and insulation material

Source: Krüger, Dr. M: Diagnostic Measurements on High Voltage Bushings, Presentation Omicron Energy, AT, 2014
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The insulation between the single condenser layers is crucial for operational safety of transformer and
condenser bushing. Dielectric measurements therefore concentrate on aging and insulation condition
between the condenser layers and any additional insulation that might be present between wrapping
and outer insulator, see Figure 26.

Figure 26 – Bushing: Setup with test tap and condenser body

Source: ABB, ABB, Transformer Bushings type GOB (OIP) - Technical Guide, Ludvika, SE, 2010.

4.2 Definition of terms

The statements presented in 2.2.1 are valid.

Diagnosis using dissipation-factor measurement on bushings is based on voltage and frequency run. In
most cases, sine-wave 50-Hz voltage in steps of 2 kV up to 12 kV and typical frequencies of 15 Hz, 20
Hz, 35 Hz, 50 Hz, 135 Hz, 220 Hz, 305 Hz, 400 Hz are used for measurement. In addition, capacitances
are always measured as well.

After manufacture, bushings are measured at laboratory conditions with rated voltage, rated frequency
and at 20 °C. Listed as VF, tan δ or similar in the test protocol, this value is part of the transformer book,
which is handed over to the customer; it is also printed on the bushing nameplate. It is absolutely
necessary to find out this value on site and document it in a suitable way. Exposure to weather conditions
can make it difficult to read the nameplate, therefore the transformer book should basically and always
be requested on site.

Experience over the past years has shown that measured values of capacitance and dissipation factor
at nominal frequency alone are not significant in regard to aging of the bushing. This is partly because
the influence of water at rated frequency cannot be measured. On the other hand, the environment of
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the bushing in the laboratory is different from its condition when installed in the transformer.
Consequently, the dissipation factor of the bushing after it has been installed in the transformer is lower
than the dissipation factor measured in the lab. With aging, the dissipation factor increases again over
time and reaches the nominal value. That is, dissipation factor values of a 15 year old bushing that are
in the range of the nominal value, can already mean aging. In regard to measurements on site, it is
important to know that measured values around the nominal value or less may well be plausible.

Regarding the measurement itself, bushing technology differences are irrelevant. However, basic
knowledge is necessary for technical discussions and clarification of plausibility. An overview of typical
technologies is therefore shown in Figure 27.

Figure 27 – Bushings: Overview manufacturing technologies and distribution in the market

Source: Krüger, Dr. M: Diagnostic Measurements on High Voltage Bushings, Presentation Omicron Energy, AT, 2014

4.3 Components

Capacitance C̅1 and dissipation factor of this capacitance are measured, by applying voltage to the
bushing pin and measuring back over the test tap.

Loss of condenser layers increases measured capacitance. Supply voltage through the grid remains
constant, with less condenser layers, the voltage load per condenser layer will be increased. In the worst
case, this leads to further flashovers.

Inside the bushing, the influence of the insulating material on the measurement depends on the
technology. Moisture can have a strong influence on paper and oil insulation. No moisture can penetrate
into resin-impregnated synthetic foil bushings, or "RIS" for short, and resin-impregnated GRP bushings,
or "RIF" for short. Originally in RBP bushings, resin in the wrapping excludes oil and moisture. Cracks
develop over time, and oil penetrates into the holes. This will change capacitance and dissipation factor
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without creating a situation that is critical for operation. Furthermore, this is the reason for considerably
increased limit values of RBP bushings.
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4.4 Influencing factors

Design and manufacturing process determine capacitance and dissipation factor. These values do not
change normally. If dissipation factor or capacitance changes, these changes often indicate specific
aging processes, dirt or faults. But the measurement is also strongly influenced by external influences.
In the following, the influences will be described in detail to be able to differentiate between avoidable
external influences and faults.

As they are a capacitive arrangements, bushings must be disconnected on all sides and a distance of
at least 10 cm must be kept to adjacent conductive parts. Short-circuit bridges or cables used as
potential equalization must be sufficiently distant from components with ground potential, since the
applied high voltages may cause insulation damage to cables or incorrect measurements.

General humidity of the surrounding air can also influence the measurement. Always be sure to
document ambient conditions well, to be able to evaluate the result correctly even with very unfavorable
conditions.

Attachment of the HV cable that is part of the test equipment can also influence the measurement
considerably. The HV cable has a grounded shield almost over its whole length. If the cable rests on
components with HV potential, partial discharges between cable shield and component occur above
approx. 4 kV, which can make the measurement useless and damage components.

The last approx. 50 cm of the cable insulation consists of the cable jacket only. This part may touch
conductive parts which have been brought to HV potential. But this should be avoided. Therefore it is
very important to keep sufficient distance when connecting the HV cable to the bushing. See Figure 28
for a favorable test setup. The support used in this case is available at ST3 and should be taken to the
site as a precaution when performing measurements since only the situation on site makes a decision
possible as to whether it should be used or not.
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Figure 28 – Bushing: Test setup with HV cable and potential connection using spiral cable

The test setup shown in Figure 29 leads to dissipation factors that clearly depend on voltage, that is, it
leads to faulty measurements.
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Figure 29 – Bushing: Test setup with HV cable leads to measurement errors due to partial discharges
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Temperature influences the test result substantially. In the ideal case, measurements on bushings
should be performed at 20 °C. Minimum temperature for performing a measurement is 5 °C. Below this
value, the aggregate state of water is variable, rendering the dissipation factor test method unreliable.
To be able to correct test values later on, the following three temperatures are recorded per bushing,
before and after every measurement:

1. Flange temperature at bushing base, corresponding to highest oil temperature in the
transformer, as the case may be,

2. Temperature on bushing head, and

3. Ambient temperature.

The temperatures should be recorded before and after every single bushing measurement. The
corresponding table is available in appendix A.1.

If it is not possible to use a pyrometer or an infrared camera for the measurements, the mean value of
ambient temperature and highest oil temperature of the transformer must be used.

Surface currents over the outmost layer or exterior of the component must be prevented. Dirt and
humidity on the bushing surfaces must be removed. It is important not to leave any textile fibers or oil
films behind. Cleaning agents recommended by the manufacturer must be used especially for silicon
bushings. When using the guard, see section 2.5, cleaning of the bushing is always recommended.

The influence of contact transition resistance existing on bushing connection and test tap has proven to
be of major importance. In addition, humidity on the test tap at the bushing flange modifies the
measurement. Use a blow-dryer to dry the test tap.

Bad ground connections lead to negative or low dissipation factors. Therefore varnish, grease and dirt
must be removed from ground connections on the transformer, see section 2.6.

Capacitance C̅2 is present between test tap and transformer tank. Capacitance depends on the
transformer; therefore it can only be compared with previous measurements.
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4.5 Measuring principle

For measuring capacitance C̅1 , the test equipment output is connected to the connecting bolt of the
bushing. The test tap on the bushing flange is used for the return measurement. Voltage and frequency
run are performed for all bushings that need to be measured. Capacitance C̅2 is measured by applying
max. 500 V at nominal frequency to the test tap. The ground loop is used for the return measurement.

4.6 Evaluation

First find out which technology is used for the bushing; then you can check plausibility of the measured
values. Please note that the exterior appearance cannot be used to identify the technology clearly. For
example, not every oil-filled bushing must have an expansion tank or a sight glass.

Three factors are used to check plausibility:

 Value range,

 Deviation of measured values from manufacturer tests at rated frequency and 20 °C, evaluated
in accordance with the standards, see Figure 30 as nameplate example,

 Course of graphs in regard to the measurements, and

 Comparison between the phases.

Figure 30 – High-voltage bushing: Nameplate

If the measured values are too high, a repeat measurement with cleaned insulation fins and guard
should be performed. The guard should be connected to the second or third fin of the bushing, see
guard in Figure 28 and Figure 29.

If the values are clearly too low, resistance of the ground loop must be reduced, see section 2.6. This is
especially true for negative values as in Figure 31. At least the negative dissipation factors indicate an
incorrect test setup. The course of the graphs and the range of measured values for the capacitances
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seems plausible. But on closer inspection it can be noticed that the graphs are voltage-dependent here,
too, indicating the incorrect test setup.

Figure 31 – Bushing: Frequency run for capacitances and negative dissipation factors, MR185904

It can be plausible if the bushing of the neutral conductor is different when comparing it directly, as -
presupposing symmetrical network operation and load - the neutral conductor does not carry any current
and therefore has lower temperatures, which results in slower aging. In addition, as neutral conductor
bushings are often designed for lower operating voltages, capacitance can be lower, too, see Figure 32
and Figure 33.
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Figure 32 – OIP bushing: dissipation factor frequency run with moisture in bushing of phase V, deviating measurement for
neutral conductor; MR083167

Figure 33 – OIP bushing: dissipation factor voltage run; MR083167

However, it is important to ensure that the measured values are not too low. This is shown using
Figure 34 as an example, where the course of the dissipation factor seems plausible at first glance. For
the N bushing, the measured value for 10 kV at 50 Hz is 0.11 % after temperature correction. The
dissipation factor for new OIP bushings is typically between 0.2 % and 0.4 %, see Table 5 for details. It
can be assumed in the shown measurement that the resistance of the ground loop is too high, and an
increased contact-circuit resistance in the ground loop must be assumed. In this case, measures as
described in section 2.6 were therefore taken, and should be taken in similar cases.
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Figure 34 – Bushing: Note very low values of dissipation-factor measurement for bushing N up to 50 Hz, MR1014185

Voltage-dependent dissipation factors as in Figure 35 indicate contact problems of the test tap to the
last condenser layer. If such measurements occur, the bushing must be taken out of service.

Figure 35 – Bushing: Voltage run on RIP bushings with irregular test contact (red) and regular test contact (blue)

Source: Cigré, Working Group A2.43, Brochure 755 Transformer bushing reliability, Paris, 2019

It is true for dissipation factors that positive measured values and a regular course of the graphs that is
similar in all three phases is a good indication of the plausibility of the measurements. If you compare
the measured values with the manufacturer's values for dissipation factors at rated frequency and check
the deviations according to Table 5, this can be another rough indication of plausibility when you are on
site.
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Table 5 below applies to dissipation factors at rated frequency and 20 °C for bushings, depending on
the manufacturing technology:

Table 5 – Dissipation factors: Typical values and limit values for bushings at rated frequency and 20 °C
Type RIP resin impregnated OIP oil impregnated RBP hard paper
soft paper

IEC 60137 < 0.7 < 0.7 < 1.5

IEEE C57.10.01 < 0.85