Dielectric Fluid Sampling & Analysis
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Dielectric Fluid Sampling & Analysis Burlington Electrical Testing procures oil samples to perform a Dissolved Gas Analysis (DGA) and an Oil Content evaluation of switchgear insulating fluids in accordance with NETA and IEEE/ANSI (C57.104-1991) specifications. Insulation fluids analyzed include Mineral Oils, PCBs, Perc, R-Temp, and Silicone based. Hydrocarbon, mineral-based, oils are commonly used in transformers as insulating fluids because of their high dielectric strength and chemical stability. Under normal operating conditions little decomposition occurs in these oils. However, under a fault condition, the oil will undergo chemical degradation. This breakdown releases various gases and chemicals into the oil. Only from a qualitative and quantitative analysis of the gases present, is it possible to distinguish such fault processes as Corona, Sparking, Overheating and Arcing occurring in the Transformer. A Dissolved Gas Analysis can provide: 1. 2. 3. 4. 5. 6.
Indication of an ongoing problem Prevention of a serious occurrence such as explosion or sudden outtage Advanced warning of developing faults A determination of the improper use of the apparatus tested Status checks on new and repaired units A means to trend the levels in order to conveniently schedule repairs
The interpretation of data from a DGA can be complex due to the many different characteristics and operating conditions that affect gas formation. Therefore establishing a baseline and performing regular testing and monitoring the content is the best way to determine and control the fault process. A summary of mineral oil analysis and interpretations can be found below: Printer-friendly version of tables
Dissolved Gas Analysis
Interpretation
Hydrogen* H2 Methane* CH 4 Ethane* C 2H 6
Thermal decomposition of the cellulose insulation material - overheating condition. Overheating or other fault conditions have occurred or exist inside the transformer. Low energy arcing has occurred or exists inside the transformer.
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Acceptable Limits 500 ppm (0.05%) (Max.) 100 ppm (0.010%) (Max.) 50 ppm (0.005%) (Max.)
24/9/2007
Dielectric Fluid Sampling & Analysis
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Ethylene* C 2H 4 Acetylene* C 2H 2 Oxygen O2 CarbonMonoxide* CO Carbon Dioxide CO 2 * Combustible Gas
Transformer is operating hot or localized overheating has occurred or exists. High energy arcing has occurred or exists inside the transformer. Thermal decomposition of the cellulose insulation material - overheating condition. Thermal decomposition of the cellulose insulation material - overheating condition. Thermal decomposition of the cellulose insulation material - overheating condition.
20,000 ppm (2.00%) (Max.)
Interpretation
Acceptable Limits
Oil Screen Analysis
50 ppm (0.005%) (Max.) 0 ppm (0.00%) (Max.)
1,000 ppm (0.10%) (Max.) 10,000 ppm (1.00%) (Max.)
Moisture Content
Reveals if transformer tank is sealed or 25 ppm ↓ 69KV XFRM (Max.) cellulosic breakdown via the level of water 35 ppm ↑ 69KV XFRM (Max.) present. 24 dyne/cm (Min.) Interfacial Tension Reveals the presence of sludge. Precursor to the insulation’s failure to properly cool the unit. Acid Number The amount of acidic or alkaline material 0.20 mg KOH/g-oil (Max.) present. Color Number Elevated number indicates oil contamination 0.5 (New Oil) – 8.0 (Worse or deterioration of the oil. case ) Dielectric Reveals conductive contaminants in the oil 24 KVAC (Min.) Breakdown such as metallic cuttings, fibers or free water. Approx 0.875 @15°C Specific Gravity Helps reveal if oil has been mixed with other fluids. Power Factor Reveals leakage current through oil. 0.5% ↓ 69KV XFRM @ 25°C Elevated power factor reveals moisture, 1.0% ↑ 69KV XFRM @ 25°C resins or fuel oils. (Max.) Furanic Compound testing is used to determine the approximate age of transformer insulation and to estimate the remaining life of the transformer. This process is performed by first procuring an insulating fluid sample from a transformer (which can be performed on line), and then analyzing the sample with a Liquid Chromatograph. The chromatograph detects decomposed cellulose compounds in the oil. The most significant compound is 2-Furfuraldehyde; concentrations of this compound correlate the Degree of Polymerization (DP), which is a number that relates to the average number of DGlucopyranose monomers present in cellulose chain. The higher the numbers of D-Glucopyranose monomers present the better the condition of the insulation in the transformer. The following chart gives a quick reference of the DP # to the age of the transformer.
New Kraft Paper Middle aged Paper Old paper Dust
1000 – 1300 approx. 500 less than 250 less than 150
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24/9/2007