Transformer Engineering Case Studies

Locally the LV-winding had very high losses, causing conductors to overheat with consequent turn to turn failure. Because of the small amount of cellulose being degraded, the Dissolved Gas Analyses (DGA) may not alert the end user about the imminent failure.

Significant localized tank cover flange heating had been observed by infrared scan on a 185 MVA GSU transformer, compromising the aimed upgrading (by 23%) of the name plate MVA rating. The enhanced oil cooling could not cope with the localized tank hot spot.

Axial forces on HV winding under inrush condition need to be evaluated, taking into account residual core magnetization and the presence of a rectifier transformer connected to the MV. The regulating transformer has to face double inrush currents (its own and the one of the rectifier transformer).

Lead exits in copper with or without slits have been simulated in order to determine the best design from a thermal point of view.

Very high load losses in the LV winding have been observed. The LV winding was built following the “classical” design rules for the transposition of conductors in parallel. However, only simulations can verify the validity of the “classical solution” for each specific design.

The couples magnetic-thermal simulation of a rectifier transformer has been performed. The presence of a complex LV busbars system makes the localization of the hot spots not trivial.

After relatively little time being installed, a significant number of tower transformers have suffered failures. Initially these faults seemed to have no justification apart of a defect of production or design of the transformers, as for example, the current flow was almost always less than nominal.

As a leading transformer manufacturer in the Middle East, UTEC addresses the region’s specific demands, including wide temperature swings and variable loads, by improving insulation to reduce thermal, electrical, and mechanical stress.