QUESTION 4: THREE-PHASE TRANSFORMERS 4.1 List THREE external conditions that may cause transformer failure - NSC Electrical Technology Power Systems - Question 4 - 2019 - Paper 1

In the event of an earth fault, the phases may become unbalanced, leading to differences in voltage between the phases. This imbalance would activate the protective relay, isolating the transformer from the power supply to prevent damage.

As the load increases, the current drawn from the secondary windings will also increase, which causes the magneto motive force in the secondary windings to rise. Consequently, the primary magneto motive force will need to adjust to balance the load, leading to an increase in the magneto motive force in the primary windings.

1. Air natural cooling (AN): Uses natural airflow to cool the transformer.

2. Air forced cooling (AF): Utilizes fans to increase the airflow over the transformer for more effective cooling.

During the transformation process, some energy is lost as heat due to resistance in the windings and other losses in the core. Therefore, the output power is always slightly less than the input power.

A three-phase core-type transformer consists of three sets of windings wound around a common iron core. The core forms a closed magnetic circuit that improves efficiency and reduces losses. The winding arrangement is typically designed to maximize magnetic coupling and minimize leakage inductance.

The turns ratio (TR) can be calculated using the formula:

$TR = \frac{N_p}{N_s} = \frac{600}{80} = 7.5 : 1$

The primary phase voltage can be calculated as:

$V_{ph} = \frac{V_{L(P)}}{\sqrt{3}} = \frac{6000}{\sqrt{3}} \approx 3464 V$

The secondary phase voltage can be calculated using the turns ratio:

$V_{ph(s)} = V_{ph} \times \frac{N_s}{N_p} = 3464 \times \frac{80}{600} \approx 461.88 V$

The secondary line voltage is given by:

$V_L = V_{ph} \times \sqrt{3} \approx 461.88 \times \sqrt{3} \approx 800 V$

Mutual induction occurs when the magnetic field created in the primary windings induces a voltage in the secondary windings. According to Faraday's law, the induced voltage is proportional to the rate of change of magnetic flux. Thus, when current flows in the primary winding, it creates a changing magnetic field that couples with the secondary winding, inducing a voltage according to the equation:

$V_L = N \frac{d\Phi}{dt}$