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ELECTRICAL PROPERTIESOF
CABLE INSULATION MATERIALS
BRUCE S. BERNSTEIN
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Paper-Insulated Lead Covered Cables
PILC-Fundamentals
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INSULATION MATERIALS
• MEDIUM VOLTAGE– Polyethylene[PE]
– Crosslinked PE [XLPE]
– Tree Retardant Crosslinked PE[TR-XLPE]
– Ethylene-PropyleneElastomers [EPR]
– PILC
• HIGH VOLTAGE
• Crosslinked Polyethylene
• PAPER/OIL
• Paper/Polypropylene [PPP]
• SF6 Gas
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PILC
• Cable is comprised of Paper strips wound overconductor with construction impregnated withdielectric fluid (oil)
• Long Service History• Reliable/used since late 1800s• Gradually being replaced by Extruded Cables
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PILC
• Paper derived form wood
• Wood– Cellulose 40%
– Hemicellulose 30% Poor Electrical Properties
– Lignin 30% Serves as adhesive
• Cellulose must be separated from others
• Separation by bleaching– sulfate/sulfite process
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PILC
• CELLULOSE-Insulation Material
• HEMICELULOSE-Non-fibrous– more polar
– losses higher vs. cellulose
• LIGNIN-Amorphous– binds other components in the wood
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Paper/Oil
• Cellulose chemical structure more complex vs. PE orXLPE
• Oil impregnates the cellulose/superior dielectricproperties
• Different cable constructions for Medium vs. HighVoltage
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Paper/Oil
• LEAD SHEATH over cable construction• Protects cable core• Benefit: Superior barrier to outside environment
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COMPARISON OF CABLE INSULATIONMATERIALS
PE / XLPE / TR-XLPE /EPR / PILC
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Polyethylene
• Low Permittivity: limits capacitive currents• Low Tan Delta: Low Losses• Very High dielectric strength (prior to aging)• Easy to process/extrude
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Crosslinked Polyethylene
• All of the above PLUS
• Improved mechanical properties at elevated temperature– does not melt at 105°C and above
– thermal expansion
• Improved water tree resistance vs. PE
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Tree-retardant XLPE
• All of the above PLUS
• Superior Water tree resistance to XLPE
• TR-XLPE properties brought about by– Additives to XLPE
– Modifying the PE structure before crosslinking
– Both
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Paper/Oil PILC
• Long history of reliability– some cables installed 60 or more years !
• More tolerant of some common diagnostic tests toascertain degree of aging– DC testing
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EPR
• Compromise of extruded cable properties– Permittivity, Tan Delta > XLPE’s
– Dielectric strength slightly lower
• High temperature properties :– Equal to or > XLPE’s
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Advantages of Extruded Cables
• Reduced Weight vs. Paper/Oil
• Accessories more easily applied
• Easier to repair faults
• No hydraulic pressure/pumping requirements
• Reduced risk of flammability/propagation
• Economics– Initial and lifetime costs
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Extruded Cables at High Temperatures
• PE/XLPE/TR-XLPE– At elevated temperatures, crystalline regions start to melt
– Thermal expansion
– Physical/mechanical strength reduced
– At 105°C crystallinity gone:
– PE flows
– XLPE and TR-XLPE crosslinking allows for maintenanceof FORM stability
– At high temperatures, crosslinks substitute for the crystallinity atlow temperature
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Extruded Cables at High Temperature
• PE/XLPE/TR-XLPE– Although Crosslinks serve as Crystallinity substitute, they do NOT
provide same degree of
• toughness
• moisture resistance
• Impact resistance– Crosslinking assists in maintaining form stability, but not
mechanical properties
– Physical/electrical properties change as temperature increases
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Extruded Cables at High Temperature
• EPR– Little to no crystallinity initially
– Form stability maintained due to presence of inorganic mineralfiller (clay)
– Physical and electrical properties change to some extent astemperature is increased
– Present day issue: operating reliability at higher temperatures vs.semicrystalline polymer insulation
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Paper/Oil at High Temperature
• Cellulose: No significant thermal expansion– compare with extruded cables
• Oil: Some thermal expansion
• Degradation mechanisms differ at elevated temperature
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Thermal Degradation
• Paper/Oil– Cellulose degradation
consistent from batch to batch
– Starts to degrade immediatelyunder thermal stress
– Moisture evolves
– Follows Arrhenius model
– Oil may form wax overtime(Polymerization)
• Extruded– Degradation is polymer
structure related
– Degradation related toantioxidant efficiency
– Does not start untilstabilization system affected
– No water evolution
– No proven model exists
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Summary: Paper/Oil
• Natural Polymer
• Carbon/Hydrogen/Oxygen
• More polar
• Not Crosslinked
• Linear Fibrils/no thermalExpansion
• Oil expands thermally
• Thermal degradation ofcellulose at weak link (C-O)
• DC : No harmful Effect onAged cable-does remove weaklink
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Summary: Extruded Materials
• Synthetic Polymer
• Carbon/Hydrogen
• Less Polar
• Branched chains
• Non-fibril
• Partly crystalline: much less forEPR
• Mineral fillers (EPR)
• Thermal expansion onheating
• Crosslinked
• Degrades at weakenedregions/crosslinks ‘holdtogether’ form stability
• DC: Latent problem -effectdepends on age (XLPE)
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Electrical Properties ___________________
Determined By Physical and ChemicalStructure
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Polyolefin Properties
� Electrical properties/General– Dielectric constant
– Dissipation factor
– Volume resistivity
– Dielectric strength
� Polyolefin properties– Structure/property relationships
– Dielectric strength
– Partial Discharge
� Measurement Methods
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Electrical Properties of Polyolefins
• The Electrical Properties of Polyolefins may be separated into twocategories:
– Those observed at low electric field strengths
– Those at very high field strengths
• LOW FIELD– Dielectric constant/dissipation factor
– Conductivity
¾ Determines how good a dielectric is the insulation
¾
• HIGH FIELD
• -Partial discharges (corona)¾ Controls functioning and reliability
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How does Polymer Insulation Respond toVoltage Stress
• Polar Regions tend to migrate toward electrodes• Motion Limited• Insulation becomes slightly ‘mechanically stressed’• Charge is stored• Properties change• Next few slides seek to picture events in idealized
terms
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Polymer Polymer
+
–
No field DC field applied,polymer becomes
polarized
POLARIZATION OF A POLYMER THAT CONTAINSMOBILE CHARGE CARRIERS
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Electrode
ORIENTATION OF POLYMERUPON APPLICATION OF VOLTAGE STRESS
Alignment of Charge Carriers
Electrode Electrode ElectrodePolymerPolymer
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IDEALIZED DESCRIPTIONorientation of polar functionality of polymer chains under voltage
stress
No Voltage Voltage Stress Applied
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NO FIELD FIELDAPPLIED
ELECTRONICPOLARIZATION
ATOMIC POLARIZATION
ORIENTATION POLARIZATION
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What happens to Dielectric when FieldApplied?
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POLARIZATION OF A POLYMER THAT CONTAINSSIDE GROUPS WITH PERMANENT DIPOLES
No field field applied,polymer becomes
polarized
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SCHEMATIC OF SOME NORMAL MODESOF MOTION OF A POLYMER CHAIN
First Mode Second Mode Third Mode
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Application of Low Voltage Stress
• Dielectric Constant:Ability to ‘hold’ charge¾ Lower Polarity -> Lower K
•
• Dissipation Factor: Losses that occur as a result of energydissipated as heat, rather than electrical energy¾ > Polarity leads to > Losses
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DC vs. AC
Under DC- Polarization persists
Under AC-Constant motion of thepolymer segments due to changingpolarity
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Dielectric Constant
• TECHNICAL DEFINITION
• In a given medium (e.g. for our purposes, in a specificpolymer insulation)—it is the Ratio of
– (a) the quantity of energy that can be stored,
to
– (b) the quantity that can be stored in a vacuum
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Dielectric Constant
• Relatively small if no permanent dipoles are present
• Approximately proportional to density
• Influenced by presence of permanent dipoles:• Dipoles orient in the electric field
• inversely proportional to temperature
• Orientation requires a finite time to take place
• is dependent upon frequency
• Relaxation time for orientation of a dipole is also temperaturedependent
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Dielectric Constant
• The dielectric constant of the electrical-insulating materialsranges from:
¾ a low of about 2 or less for materials with lowest electrical-losscharacteristics,
¾ up to 10 or so for materials with highest electrical losses
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Dielectric Constant of Common Polymers
• Polyethylene 2.28• Polypropylene 2.25• Butyl Rubber 2.45• Poly MMA 2.7-3.2• Nylon 66 3.34• PPLP (Oil-Impregnated) 2.7
Sources: M.L.Miller “Structure of Polymers”,Dupont and Tervakoski Literature
• Cellulose Acetate 3.2-7.0
• PVC 2.79
• Mylar (Polyester) 3.3
• Kapton (Polyimide) 3.6
• Nomex (Polyamide) 2.8
• Cyanoethylcellulose 13.3
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DIELECTRIC LOSSES
• From a materials perspective, losses result frompolymer chain motion
• Leads to heat evolution• Chain motion influence on electrical properties are
depicted on next few slides
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�’ AND �” AS A FUNCTION OF FREQUENCY
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Dispersion
• Dipoles RIGIDLY attached - oriented by MAIN chain motion
• Dipoles FLEXIBLY attached - orientation of pendant dipoles
and/or
orientation by chain segmental motion
(shows TWO dispersion regions)
at different frequencies
• PE that has been OXIDIZED
• PE that is a copolymer with polar monomer, e.g., SOME TR-XLPE
Note: 60Hz is not necessarily where these phenomena show maxima
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Dispersion
• At frequencies where dispersion occurs– some energy stored– some energy dissipated as heat
Complication:� In the dispersion region, some dipoles are oriented while
others are moving.� Hence some dipoles move in a field that is COMPOSITE
of applied field and local dipole induced field - calledINTERNAL FIELD effect
� Leads to phenomena that are not sharply defined
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Electrical Properties of PolyolefinsPoly Olefin Structure and Dielectric Behavior
• The electrical behavior of insulating materials isinfluenced by temperature, time, moisture and othercontaminants, geometric relationships, mechanical stressand electrodes, and frequency and magnitude of appliedvoltage. These factors interact in a complex fashion.– Saturated hydrocarbons are non-polar
– Dielectric constants are low
– Dielectric constants essentially frequency-independent (if pure)
– Dielectric constants change little with temperature
The change that occurs is related to density changes
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Electrical Properties of PolyolefinsPoly Olefin Structure and Dielectric Behavior
• Dielectric constant can be expressed for these nearly non-polar polymers by an expression of the form:
e = A + B(d - da)Where,
B is a constant,
d is the density and
da is the density at which the dielectric constant is equal to A.
Dielectric constants for this equation fit a large number of data forpolyethylene:
e = 2.276 + 2.01(d - 0.9200)
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INSULATION POLYMERS AND DISPERSION
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PermittivityorDielectricConstant
At high frequenciesdipoles cannot returnrapidly enough -charging cannotoccur/dielectric constantis low
Frequency atwhich dipolesrespond tothe field
At high frequencies,dipoles cannotmove rapidlyenough to respond –lossesare low
HH’ and HH” as a functionof frequency – atconstant temperature
Permanent dipoles FOLLOWvariations in the AC field –hence current and voltageout of phase – losses low
Losses
Frequency at which permittivity drops and losses increaseis where the polymer is said to show dispersion
At low frequenciesdipoles can align --dielectric constantis high
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ELECTRIC BREAKDOWN
• INABILITY OF INSULATION TO OPERATE or HOLDCHARGE UNDER STRESS– Insulation inherent properties
– Thermal
• Stream of electrons released
• Discharge-– Preceded by Partial Discharge
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Electric BreakdownTypes of Breakdown
• Failure of a material due to the application of a voltagestress– called the dielectric strength– expressed as kV/mm or V/mil
• Electric breakdown occurs when the applied voltage canno longer be maintained across the material in a stablefashion without excessive flow of current and physicaldisruption
• Theoretical understanding not clear even now• What is clear is that there are several mechanisms of
failure
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Electric BreakdownTypes of Breakdown
Intrinsic Breakdown• Defined by the characteristics of the material itself in pure and defect-
free form under test conditions which produce breakdown at thehighest possible voltage. Never achieved experimentally.
Thermal Breakdown• Occurs when the rate of heating exceeds the rate of cooling by thermal
transfer and thermal runaway occurs under voltage stress
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Electric BreakdownTypes of Breakdown
Discharge-Induced Breakdown• Occurs when electrical discharges occur on the surface or
in voids of electrical insulation. Ionization causes slowdegradation. Corona, or partial discharge, is characterizedby small, local electrical discharges
Treeing-Electrical• Results from partial discharge
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AC Breakdown Strength of 15 kV XLPE CableVs. Position on Cable Run
For One 5000 Foot Reel of 50,000 Foot Run
200
400
600
800
1000
1200
1400
0 80 160 240 320 400 480
Position on Cab le Run (sam ple num ber)
AC
Bre
ak
do
wn
(v
olt
s/m
il)
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WEIBULL
• Commonly used to characterize time to failure information
• Defines– Characteristic Time to Failure
• Scale Factor/ 63.2% probability of failure
• Shape parameter/slope of failure times
• Called two parameter Weibull distribution
• Controversial: “Most physical models do predict this type of distributionfor failure as a function of time (but not necessarily of voltage stress”)Dissado and Fothergill, Page 323
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10.00 100.001.00
5.00
10.00
50.00
90.00
99.00
0.9
1.0
1.2
1.4
1.6
2.0
3.0
4.0
6.0E
K
Probability - Weibull
Time, (t)
Cum
ulat
ive
% o
f Sam
ples
Fai
led
WeibullData 1
W2 RRX - SRM MEDF=8 / S=4CB[FM]@90.00%2-Sided-B [T1]
E ������� K �������� U ������
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Short-Time Voltage Breakdownof Polyethylene
0
10
20
30
40
50
60
70
0 50 100 150 200
Th ickness
Pe
ak
Vo
lta
ge
(k
V)
AC and DC at -196°C
DC at room temperature
AC (60 Hz) at room temperature
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Dielectric StrengthImportant Points to Remember !
� AC breakdown strength value NOT absolute– Related to rate of rise of the applied voltage stress
• 5 minute step rise
• 10 minute step rise
• 30 minute step rise
• Ramp
� Real world/stress is constant¾ Voltage endurance
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Electric Breakdown
• Thickness, area, shape and nature of the conducting contaminantsinfluence the breakdown voltage of plastics
• If the failure occurs at the periphery of the plastic instead of passingthrough, it is called a flashover
• Corona is not easily produced by a d-c voltage, even though thevoltage across the air in a void is high, because initiation of coronaalso involves the rate of voltage change
• The localized voltage stress at a metal point (needle) is very high
• Dielectric strength depends on the thickness of sample
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Electric BreakdownTypes of Breakdown
Treeing- Water• Water tree growth induced by water in presence of voltage
stress. Water trees generate at much lower stresses thanelectrical trees. Not a direct cause of breakdown
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Water Treeing
• First reported in 1968
• Bahder, et al. 1972: First distinguished between water andelectrical trees– Water trees/electrochemical trees
• Water and Voltage stress required
• Lead to reduced dielectric strength
• Cleanliness required– All known since mid-late 1970’s
• Progress (?)– Ions influence
– Jackets
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Theories of Water Treeing
• Mechanical: fatigue of matrix
• Chemical: field brings about reactions
• Thermodynamic: migration of water into pre-oxidizedareas
• Electrical: acceleration of electrons across voids damagesmatrix
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A Model of Water Trees in PE
cations
anions
PE outsidewater tree
crystalline
amorphous
ionic endgroups
limitingdiameter
Void withtrapped salt
limitingdiameter
limitingdiameter
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General Procedure For Performing ElectricBreakdown Measurements
• The test specimen, (a sheet a few mils thick) is placed between disk-shaped electrodes having a diameter much smaller than the width ofthe specimen
• The edges of the electrodes must have a rounded edge
• Either a direct or alternating potential is applied across the electrodesand the potential is raised at some uniform rate until breakdown occurs
• Since the actual breakdown process generally involves non-uniformities in the insulating material, resulting in local concentrationof the electric field, extreme care must be exercised in cleaning theelectrodes and specimens
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General Procedure For Performing ElectricBreakdown Measurements
• A number of specimens are tested in order that themeasurements may be a true reflection of the statisticaldistribution of inhomogeneities in the material under study
• The following variables must be strictly controlled andidentical in a series of tests:– Specimen thickness
– Electrode shape and size
– Temperature
– Frequency of applied field
– Rate of increase of the field
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General Procedure For Performing ElectricBreakdown Measurements
• In addition, care must be exercised in controlling themoisture content and other pretreatment variables ofthe specimen
• In general, such breakdown tests are associated withsome particular conditions in which the insulationmaterial will be used, and these conditions thereforebecome the dominant factors in designing the testprocedures
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TYPICAL GEOMETRIC ARRANGEMENTS ILLUSTRATINGTHE USE OF PLASTICS AS AN INSULATOR
HV X
t1
Air, liquid, etc.Plastic
Metal electrode
t2
Ground Ground
Ground
X
t
HV
High voltage gradientat a sharp point
Configuration with nonuniformvoltage gradient along the surfaceTwo dielectrics in series
HV
t
X
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TYPICAL GEOMETRIC ARRANGEMENTS ILLUSTRATINGTHE USE OF PLASTICS AS AN INSULATOR
Uniform voltage gradient under electrode,nonuniform at edge of electrode and along
creepage path on the surface
An inset Rogowski (curved)electrode provides uniform
voltage gradient
Voltage gradient is not uniformacross the diameter; is highest
at the inner conductor
HV
Ground
HV
Ground
HV
Ground
X
t t
t
tX
R1
R2
Air, liquid, etc.Plastic
Metal electrode
Uniform voltage gradientalong surface of plastic
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ELECTRICAL PROPERTIES
• Survey of topics reviewed– Dielectric constant
– Dissipation factor
– Dielectric strength
– Water Treeing
• Electrical Properties at low voltage stress are dependentupon Chemical structure of Insulation
______________________________________
• Reliability (Life) dependent upon other factors– Aging, local environment / beyond scope of this talk
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THANK YOU