Abstract
Insulators comprise only 5% of the capital cost of transmission lines; they are accountable for 70% of line interruptions and 50% of maintenance costs of transmission lines. Major transmission lines situated in different parts of the world were mostly all constructed 30 years ago. These lines have either completed or are approaching the active life at 30 years. It is not possible to replace all insulators at a time in any utility. From a standpoint of consistency, it is quite important to locate insulators that require replacement prior to the occurrence of failure. Recalling these issues, a replacement strategy was modeled on insulator samples, operated at 154 kV, mechanical and electrical rating (M+E) 25,000 lbs and within the 10–50 years (Y) age group, collected in bulk for laboratory evaluation, based on the probability of mechanical failure (P(F)) of insulators. For conducting these studies, tensile load test such as combined electrical and mechanical failing load test was performed on selected 30 new and aged porcelain insulator samples from bulk to access recent condition. It was observed that insulators under service for 50 years manifested a decrease of 89.3% in quality factor (K), as compared to insulators within 10 years of service. A micro-structural study was carried out by using an optical microscope (OM) and a scanning electron microscope (SEM) for the further confirmation of previous evaluations. P(F) was derived by implementing Weibull distribution on the experimental observations. It was observed that insulators with an age of 50 years depicted a 2.7% increase in P(F), as compared to insulators with an age of 10 years. This article discussed a strategy for accessing the recent condition of new, aged bulk samples and the criteria of the replacement of the insulator string based on P(F).
Highlights
Insulators serve the bi-fold function of supporting conductor and provide isolation electrically from the ground
The later part was focused on the calculation of P(F), the relation between failure load, P(F) and the replacement strategy based on reference P(F)
optical microscope (OM) and scanning electron microscope (SEM) images were used to study the microstructural defects of samples due to aging
Summary
Insulators serve the bi-fold function of supporting conductor and provide isolation electrically from the ground. These techniques neither evaluate the intensity of damage nor provide any reference problem, a replacement strategy was outlined, based on the probability of mechanical failure (P(F)). Porcelain insulator samples which required laboratory evaluation were collected bulk from different utilities operating at 154 kV, within the age group of 10–50 Y, located in South Korea. A failure mechanism study was performed on 30 selected porcelain insulator samples from bulk. A failure mechanism study was performed on 30 selectedporcelain insulator samples from collected samples, with traces of visual damage. This article analyzes the recent condition of new and aged bulk samples based on mechanical load test and microstructural studies. The later part was focused on the calculation of P(F), the relation between failure load, P(F) and the replacement strategy based on reference P(F)
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