Rural transformer failure (Fluke)

Problem description

This case history involves the investigation of a utility transformer failure that occurred in a rural area surrounded mostly by farmland and open space. The failure occurred in a location where power quality problems are rare.

Fig. 1 shows a one-line diagram of the system. The failed transformer was at the end of a medium voltage utility feeder. The transformer secondary was configured as a 120/208 V, 3-phase, 4-wire system. The load consisted of three end-users: a small apartment complex, a dairy farm and a golf course clubhouse.

Fig. 1 Connections to the rural power transformer

Fig. 1 Connections to the rural power transformer

The engineer began his investigation by checking for reports of problems with other transformers connected to the same feeder. This bit of Rural transformer failure research didn’t turn anything up, so he concluded the problem was probably related to the secondary loads. His next step was to question the end-users.

The farm owner said his milk processing equipment was running when the transformer failed. He also said nothing unusual had occurred prior to the failure, and his equipment continued to work normally after the transformer was replaced.

The apartment manager recalled that things were quiet at his facility on the evening the failure occurred. His apartment dwellers were home, cooking dinner and watching TV. Nothing unusual had occurred.

The golf course superintendent said the club had sponsored a large tournament on the day the transformer failed. The club had rented several battery powered golf carts to supplement their normal fleet. Operators plugged all of these in for recharging at the end of the tournament. About an hour after that, a fuse blew in the clubhouse’s main service panel.

The superintendent replaced the fuse, and not long after that the power went out — this time, Dairy Farm due to a failed transformer.


The engineer asked to have a golf cart set up for charging, so he could record the harmonic spectrum and waveform of the battery charger current. The results are shown in Fig. 2 and Fig. 3.

Fig. 2 Golf cart battery charger current waveform

Fig. 2 Golf cart battery charger current waveform

Fig. 3 Harmonic spectrum of battery charger current

Fig. 3 Harmonic spectrum of battery charger current

Theory and analysis

Battery chargers are invariably non-linear loads that generate harmonic currents, due to the action of diodes or other semiconductors that convert ac to dc. The waveform shown in Fig. 2 is typical of a transformer coupled diode rectifier. The Fluke 43B showed the total harmonic distortion (THD) of the golf cart charger current to be 37 %. Values above 20 % would be dangerously high, given the estimated size of the charger load in relation to the total transformer load.

When harmonic currents are flowing in a transformer, theresult is extra heat in the windingsand core laminations. Losses from high-frequency eddy currents constitute the primary cause of this extra heat. Some additional harmonic heating is due to skin effect, where the effective cross-section of a conductor is reduced at high harmonic frequencies. The amount of harmonic heating a transformer can tolerate is inversely proportional to the total secondary load. A heavily loaded transformer can overheat and fail if a large portion of the load current contains harmonics.

In the case of the rural transformer, three end-users contributed to the total load and all three experienced peak loads at the same time. The timing of the blown fuse and


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