On electric field distortion for breakdown mechanism of nanofilled transformer oil

Water impurity is the essential factor of reducing the insulation performance of transformer oil, which directly determines the operating safety and life of a transformer. Molecular dynamics simulations and first-principles electronic-structure calculations are employed to study the diffusion behavior of water molecules and the electrical breakdown mechanism of transformer oil containing water impurities. The molecular dynamics of an oil-water micro-system model demonstrates that the increase of aging acid concentration will exponentially expedite thermal diffusion of water molecules. Density of states (DOS) for a local region model of transformer oil containing water molecules indicates that water molecules can introduce unoccupied localized electron-states with energy levels close to the conduction band minimum of transformer oil, which makes water molecules capable of capturing electrons and transforming them into water ions during thermal diffusion. Subsequently, under a high electric field, water ions collide and impact on oil molecules to break the molecular chain of transformer oil, engendering carbonized components that introduce a conduction electronic-band in the band-gap of oil molecules as a manifestation of forming a conductive region in transformer oil. The conduction channel composed of carbonized components will be eventually formed, connecting two electrodes, with the carbonized components developing rapidly under the impact of water ions, based on which a large number of electron carriers will be produced similar to “avalanche” discharge, leading to an electrical breakdown of transformer oil insulation. The water impurity in oil, as the key factor for forming the carbonized conducting channel, initiates the electric breakdown process of transformer oil, which is dominated by thermal diffusion of water molecules. The increase of aging acid concentration will significantly promote the thermal diffusion of water impurities and the formation of an initial conducting channel, accounting for the degradation in dielectric strength of insulating oil containing water impurities after long-term operation of the transformer.

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Clarifications on the Behavior of Alternative Gases to SF6 in Divergent Electric Field Distributions under AC Voltage

Energies ◽

10.3390/en14041065 ◽

2021 ◽

Vol 14 (4) ◽

pp. 1065

Author(s):

Houssem Eddine Nechmi ◽

Michail Michelarakis ◽

Abderrahmane (Manu) Haddad ◽

Gordon Wilson

Keyword(s):

Electric Field ◽

Electric Fields ◽

Partial Discharge ◽

Mean Value ◽

Electrode System ◽

Polarity Reversal ◽

Buffer Gas ◽

Co2 Gas ◽

Breakdown Mechanism ◽

Positive Cycle

Negative and positive partial discharge inception voltages and breakdown measurements are reported in a needle-plane electrode system as a function of pressure under AC voltage for natural gases (N2, CO2, and O2/CO2), pure NovecTM gases (C4F7N and C5F10O) and NovecTM in different natural gas admixtures. For compressed 4% C4F7N–96% CO2 and 6% C5F10O–12% O2–82% CO2 gas mixtures, the positive-streamer mode is identified as the breakdown mechanism. Breakdown and negative partial discharge inception voltages of 6% C5F10O–12% O2–82% CO2 are higher than those of 4% C4F7N–96% CO2. At 8.8 bar abs, the breakdown voltage of 6% C5F10O–12% O2–82% CO2 is equal to that of 12.77% O2–87.23% CO2 (buffer gas). Synergism in negative partial discharge inception voltage/electric field fits with the mean value and the sum of each partial pressure individually component for a 20% C4F7N–80% CO2 and 6% C5F10O–12% O2–82% CO2, respectively. In 9% C4F7N–91% CO2, the comparison of partial discharge inception electric fields is Emax (CO2) = Emax(C4F7N), and Emax (12.77% O2–87.23% CO2) = Emax(C5F10O) in 19% C5F10O–81%(12.77% O2–87.23% CO2). Polarity reversal occurs under AC voltage when the breakdown polarity changes from negative to positive cycle. Polarity reversal electric field EPR was quantified. Fitting results show that EPR (CO2) = EPR(9% C4F7N–91% CO2) and EPR(SF6) = EPR (22% C4F7N–78% CO2). EPR (4% C4F7N–96% CO2) = EPR (12.77% O2–87.23% CO2) and EPR (6% C5F10O–12% O2–82% CO2) < EPR (4% C4F7N–96% CO2) < EPR (CO2).

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Effect of Temperature on Space Charge Distribution of Oil–Paper Insulation under DC and Polarity Reversal Voltage

Energies ◽

10.3390/en11092271 ◽

2018 ◽

Vol 11 (9) ◽

pp. 2271 ◽

Cited By ~ 3

Author(s):

Qingguo Chen ◽

Jinfeng Zhang ◽

Minghe Chi ◽

Peng Tan ◽

Wenxin Sun

Keyword(s):

Electric Field ◽

Space Charge ◽

Electric Field Distribution ◽

Operating Conditions ◽

Polarity Reversal ◽

Effect Of Temperature ◽

Slow Decay ◽

Voltage Polarity ◽

Field Distortion ◽

Paper Insulation

The electric field distortion caused by space charge is an important factor affecting the operation reliability of oil–paper insulation in a converter transformer. To study the accumulation and decay characteristics of the space charge within oil-impregnated pressboard under DC and polarity reversal voltage, and consider the possible operating conditions of the converter transformer, the space charge behavior of oil-impregnated pressboard was measured by the pulsed electro-acoustic (PEA) method in the temperature range from −20 °C to 60 °C. The effect of temperature on the accumulation and decay characteristics of space charge is also analyzed. The space charge accumulated within the pressboard at low temperature is mainly homocharge injected by the electrode, while heterocharge formed by ion dissociation counteracts some of the homocharge at high temperature. Thus, the space charge of pressboard first increases, then decreases, with an increase in temperature. However, slow decay of the space charge causes severe distortion of the electric field distribution in the pressboard during voltage polarity reversal.

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Cause Analysis and Countermeasures of a Breakdown Failure of Flexible 110 kV Cable Terminal

E3S Web of Conferences ◽

10.1051/e3sconf/20183804004 ◽

2018 ◽

Vol 38 ◽

pp. 04004

Author(s):

Feng Huang

Keyword(s):

Electric Field ◽

Electric Field Intensity ◽

Field Model ◽

Semiconductor Layer ◽

Mechanism Analysis ◽

The Finite Element Method ◽

Cable Insulation ◽

Cause Analysis ◽

Breakdown Mechanism ◽

Calculation Results

disintegration examination and analysis are employed in flexible terminal breakdown of 110 kV XLPE insulated cables. It is considered that the main reason of breakdown is the separation of the stress cone of the terminal and the fracture of the semi- conductive layer of the cable insulation. Therefore, the finite element method is used to electric field model and simulate the dislocation fault of internal stress cone and outer semiconductor layer of cable insulation. The distribution of the electric field intensity is calculated and compared. The simulation and calculation results verify the validity of the breakdown mechanism analysis, and put forward some practical suggestions.

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Effect of electric field at 150 °C on the formation of corrosive sulfur in mineral transformer oil

IEEE Transactions on Dielectrics and Electrical Insulation ◽

10.1109/tdei.2015.004979 ◽

2015 ◽

Vol 22 (5) ◽

pp. 2449-2454 ◽

Cited By ~ 6

Author(s):

B. Gonzalez ◽

O. Gasca ◽

M. Juarez ◽

F. Bravo

Keyword(s):

Electric Field ◽

Transformer Oil

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Discharge and Flashover Behavior in Oil-Paper

Electrical Insulation Breakdown and Its Theory, Process, and Prevention - Advances in Computer and Electrical Engineering ◽

10.4018/978-1-5225-8885-6.ch004 ◽

2020 ◽

pp. 105-128

Keyword(s):

Electric Field ◽

Operating Conditions ◽

Surface Discharge ◽

Discharge Characteristics ◽

Dc Voltage ◽

Composite Field ◽

Field Distortion ◽

Lightning Impulse ◽

Creeping Discharge ◽

Paper Insulation

Due to special operating conditions, the valve side bushing of the converter transformer connected to the converter valve is subject to complex voltage excitation, including DC voltage, AC/DC composite voltage, lightning impulse overvoltage, or composite voltage of operating overvoltage and DC. Under the action of this complicated electric field, the oil-paper insulation of the valve-side bushing of the converter transformer is prone to electric field distortion due to charge accumulation, which causes a surface discharge, which will seriously cause the edge breakdown. At the same time, since the temperature in the converter transformer rises due to a large amount of loss during the operation of the transformer, creeping discharge is more likely to occur under the electrothermal composite field. Hence, it is significant to carry out research on the surface discharge characteristics of the oil-paper insulation on the valve side of the converter transformer under the electrothermal composite field.

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