Refer to FIGURE 5.1 below and answer the questions that follow - NSC Electrical Technology Power Systems - Question 5 - 2024 - Paper 1

One advantage of a shell-type transformer is that it is less prone to magnetic stray loss compared to a core-type transformer.

The configuration of the primary and secondary windings in the transformer is star-delta (or delta-star) configuration.

When an alternating voltage is applied to the primary windings of the transformer, an alternating magnetic flux is established in the core. This flux links with the secondary windings, inducing an electromotive force (e.m.f.) of the same frequency. When the load is connected to the secondary windings, a current flows through it. Power is thus transferred magnetically from the primary to the secondary windings.

An increase in the load will increase the secondary current, resulting in a more prominent primary current drawn from the supply.

The dielectric oil provides electrical insulation between the windings and the case, helping to provide cooling and preventing breakdown of the windings.

The two types of losses include hysteresis losses and eddy current losses.

Two cooling methods include:

1. Air Natural: Transformers are cooled by natural air flow around the transformer windings.
2. Air Forced: Transformers are cooled by air being forced through a fan above the windings.

The conductor size in a single-phase transformer is larger than that required for a three-phase transformer. For the same power, the conductor size for a three-phase transformer is 75% of what is needed for a single-phase transformer.

To calculate the line current, we use the formula: $I_L = \frac{P_{tr}}{\sqrt{3} \times V_{L1} \times \cos \phi}$ By substituting the known values: $I_L = \frac{300 \times 10^3}{\sqrt{3} \times 600 \times 0.87} = 331.82 A$

The phase current can be calculated using the formula: $I_{ph} = \frac{I_L}{\sqrt{3}}$ Substituting the values gives: $I_{ph} = \frac{331.83}{\sqrt{3}} = 191.58 A$

To find the primary line current, we use the formula: $I_{L1} = \frac{P}{\sqrt{3} \times V_{L1} \times \cos \phi}$ Substituting in the values: $I_{L1} = \frac{300 \times 10^3}{\sqrt{3} \times 8 \times 10^3 \times 0.87} = 24.89 A$

Two protection relays used in three-phase transformers are:

1. Buchholz relay (B)
2. Restricted fault relay (REF)