Three Phase Autotransformer Connections

1. 3 Phase Auto Transformer Connections
2. Autotransformer Grounding
3. Three Phase Auto Transformer Connection Diagram

HPS offers three phase autotransformers for applications where voltage isolation is not necessary, but some level of voltage adjustment is required. A three-phase transformer consists of the interconnection of three single-phase transformers in Y– or D – connection. This transformer connects two three-phase systems of different voltages (according to. In this section, we'll review the operating characteristics of basic delta-delta, wye-wye, delta-wye and wye-delta connections of the transformer. The construction of a three-phase transformer can be represented as shown in Figure 1. The shell type core has three sets of primary and secondary windings. How these windings are connected together determines the configuration of the transformer (delta, wye, etc). Three phase transformer connections Windings of a three phase transformer can be connected in various configurations as (i) star-star, (ii) delta-delta, (iii) star-delta, (iv) delta-star, (v) open delta and (vi) Scott connection. These configurations are explained below.

In this section, we'll review the operating characteristics of basic delta-delta, wye-wye, delta-wye and wye-delta connections of the transformer.

The construction of a three-phase transformer can be represented as shown in Figure 1. The shell type core has three sets of primary and secondary windings. How these windings are connected together determines the configuration of the transformer (delta, wye, etc).

Figure 1: Three-Phase Transformer Construction

Wye-Wye (Y-Y) Connected Transformer

The transformer in Figure 1 can be represented as shown in Figure 2. T_1, T_2, and T₃ represent the same three primary/secondary coil pairs shown on the shell type core. The lines labeled ΦA₁, ΦB₁ and ΦC₁ represent primary line conductors that connect to the primary coils, and the line labeled N₁ represents a neutral conductor. Likewise, the lines labeled ΦA₂, ΦB₂ and ΦC₂ represent secondary line conductors and N₂ represents a neutral conductor.

Figure 2: Elements of a transformer wiring diagram.

When wired as shown in Figure 3, the shell type transformer forms a Y-Y (wye-primary-wye secondary) circuit. As such, the transformer primary and secondary current and voltage relationships are as follows:

$begin{matrix}{{E}_{L}}=sqrt{3}times {{E}_{P}}=1.732times {{E}_{P}} & {} & {{I}_{L}}={{I}_{P}} end{matrix}$

$begin{matrix}{{E}_{P}}=frac{{{E}_{L}}}{sqrt{3}}=frac{{{E}_{L}}}{1.732} & {} & {{I}_{N}}={{I}_{A}}+{{I}_{B}}+{{I}_{C}}=0 end{matrix}$

Where E_L and I_L are the line values, and E_P and I_P are phase values. Wudfrd.sys windows 10. These relationships assume that the Y-Y circuit is balanced (Before reading on, take a moment to trace out the circuit connections in Figure 3 to verify that the diagram represent the same circuit).

Figure 3: Y-Y transformer Schematic & Wiring Diagram

There are two points to be made:

• The wiring diagram in Figure 3a can be made implemented using a bank (group) of three single phase (1Φ) transformers.

• Y-Y Transformers are used in industrial applications and are preferred over ∆-∆ transformers when it is critical to have a neutral connection in the secondary circuit.

• You May Also Read: Three Phase Transformer Connections Phasor Diagrams

3 Phase Auto Transformer Connections

Delta-Delta (∆-∆) Connected Transformer

When wired as shown in Figure 4, the shell type transformer forms a ∆-∆ (delta primary-delta secondary) circuit. Note that there is no neutral line in the wiring diagram. The transformer, primary and secondary current, and voltage relationships are as follows:

$begin{matrix}{{E}_{L}}={{E}_{P}} & {} & {{I}_{L}}=sqrt{3}times {{I}_{P}}=1.732times {{I}_{P}} end{matrix}$

$begin{matrix}{{I}_{P}}=frac{{{I}_{L}}}{sqrt{3}}=frac{{{I}_{L}}}{1.732} & {} & {{I}_{N}}={{I}_{A}}+{{I}_{B}}+{{I}_{C}}=0 end{matrix}A$

Where E_L and I_L are line values, and E_P and I_P are phase values. These relationships assume that the ∆-∆ the circuit is balanced (Before reading on, take a moment to trace out the circuit connections in Figure 4 to verify the diagrams represent the same circuit).

Figure 4: Delta-Delta (∆-∆) Transformer Schematic & Wiring diagrams.

As was the case with the Y-Y circuit, the wiring diagram in Figure 4a can be implemented using a bank of single-phase transformers. Note that ∆-∆ transformers are most commonly found in Industrial applications.

Wye-Delta (Y-∆)Connected Transformer

When wired as shown in Figure 5, the shell type transformer forms a Y-∆ (wye primary-delta secondary) circuit. Note that there is a neutral connection in the primary circuit, but none in the secondary circuit. (Before reading on, take a moment to trace out the circuit connections in Figure 5 to verify that the diagrams represent the same circuit).

Figure 5 Wye-Delta (Y-∆) transformer Schematic & Wiring diagrams.

As was the case with the previous circuits, the wiring in the diagram in Figure 5a can be (and often is) implemented using a bank of single phase (1Φ) transformer. Note that Y-∆ connected transformers are most commonly used in high voltage transmission system.

Delta-Wye (∆–Y) Connected Transformer

When wired as shown in Figure 6, the shell type transformer forms ∆-Y (delta primary-wye secondary) circuit. Note that there is a neutral connection in the secondary circuit, but none in the primary circuit. (Before reading on, take a moment to trace out the circuit connections in Figure 6 to verify that the diagram represents the same circuit).

Figure 6 (Delta-Wye )∆-Y transformer Schematic & Wiring Diagram

As was the case with the previous circuits, the circuit in Figure 6a can be implemented using a single phase (1Φ) transformers. Note that ∆-Y connected transformers are most commonly found in commercial and industrial applications.

Why Using Single Phase Transformer Banks?

As mentioned earlier, each transformer introduced in this section can be constructed using a bank (group) of single-phase transformers. Such a transformer bank is shown in Figure 7.

Figure 7 Three single-phase transformers wired as a three-phase transformer bank

Why use three single phase transformer banks in place of a single three-phase transformer? Two reasons: convenience and practicality.

The most common failure in any three-phase system is a grounding fault where one phase fails (shorts) to ground. When a single three-phase transformer is being used, the failure of one phase necessitates replacement of the entire transformer. However, when a bank of single-phase transformers is used, the failure of any phase requires the replacement of that phase transformer only; and it is easier and cheaper to replace a single phase transformer than a three-phase transformer.

Also, a group of three single phase transformers can be wired as any of the connections that were introduced in this section. Three phase transformers are manufactured in specific configurations, and therefore do not have this flexibility.

Open Phases in Three Phase Transformers

Figure 3: Y-Y transformer Schematic & Wiring Diagram

There are two points to be made:

• The wiring diagram in Figure 3a can be made implemented using a bank (group) of three single phase (1Φ) transformers.

• Y-Y Transformers are used in industrial applications and are preferred over ∆-∆ transformers when it is critical to have a neutral connection in the secondary circuit.

• You May Also Read: Three Phase Transformer Connections Phasor Diagrams

3 Phase Auto Transformer Connections

Delta-Delta (∆-∆) Connected Transformer

When wired as shown in Figure 4, the shell type transformer forms a ∆-∆ (delta primary-delta secondary) circuit. Note that there is no neutral line in the wiring diagram. The transformer, primary and secondary current, and voltage relationships are as follows:

$begin{matrix}{{E}_{L}}={{E}_{P}} & {} & {{I}_{L}}=sqrt{3}times {{I}_{P}}=1.732times {{I}_{P}} end{matrix}$

$begin{matrix}{{I}_{P}}=frac{{{I}_{L}}}{sqrt{3}}=frac{{{I}_{L}}}{1.732} & {} & {{I}_{N}}={{I}_{A}}+{{I}_{B}}+{{I}_{C}}=0 end{matrix}A$

Where E_L and I_L are line values, and E_P and I_P are phase values. These relationships assume that the ∆-∆ the circuit is balanced (Before reading on, take a moment to trace out the circuit connections in Figure 4 to verify the diagrams represent the same circuit).

Figure 4: Delta-Delta (∆-∆) Transformer Schematic & Wiring diagrams.

As was the case with the Y-Y circuit, the wiring diagram in Figure 4a can be implemented using a bank of single-phase transformers. Note that ∆-∆ transformers are most commonly found in Industrial applications.

Wye-Delta (Y-∆)Connected Transformer

When wired as shown in Figure 5, the shell type transformer forms a Y-∆ (wye primary-delta secondary) circuit. Note that there is a neutral connection in the primary circuit, but none in the secondary circuit. (Before reading on, take a moment to trace out the circuit connections in Figure 5 to verify that the diagrams represent the same circuit).

Figure 5 Wye-Delta (Y-∆) transformer Schematic & Wiring diagrams.

As was the case with the previous circuits, the wiring in the diagram in Figure 5a can be (and often is) implemented using a bank of single phase (1Φ) transformer. Note that Y-∆ connected transformers are most commonly used in high voltage transmission system.

Delta-Wye (∆–Y) Connected Transformer

When wired as shown in Figure 6, the shell type transformer forms ∆-Y (delta primary-wye secondary) circuit. Note that there is a neutral connection in the secondary circuit, but none in the primary circuit. (Before reading on, take a moment to trace out the circuit connections in Figure 6 to verify that the diagram represents the same circuit).

Figure 6 (Delta-Wye )∆-Y transformer Schematic & Wiring Diagram

As was the case with the previous circuits, the circuit in Figure 6a can be implemented using a single phase (1Φ) transformers. Note that ∆-Y connected transformers are most commonly found in commercial and industrial applications.

Why Using Single Phase Transformer Banks?

As mentioned earlier, each transformer introduced in this section can be constructed using a bank (group) of single-phase transformers. Such a transformer bank is shown in Figure 7.

Figure 7 Three single-phase transformers wired as a three-phase transformer bank

Why use three single phase transformer banks in place of a single three-phase transformer? Two reasons: convenience and practicality.

The most common failure in any three-phase system is a grounding fault where one phase fails (shorts) to ground. When a single three-phase transformer is being used, the failure of one phase necessitates replacement of the entire transformer. However, when a bank of single-phase transformers is used, the failure of any phase requires the replacement of that phase transformer only; and it is easier and cheaper to replace a single phase transformer than a three-phase transformer.

Also, a group of three single phase transformers can be wired as any of the connections that were introduced in this section. Three phase transformers are manufactured in specific configurations, and therefore do not have this flexibility.

Open Phases in Three Phase Transformers

When one of the phase inductors in a wye-connected circuit opens, the entire circuit is effectively reduced to a single-phase circuit. This principle is illustrated in Figure 8a. When L₁ opens, ΦA is isolated from the circuit. When this occurs, there is no current through L₁ and only E_BC is unchanged. In effect, the three-phase circuit has been reduced to a single phase circuit.

Figure 8 Wye (Y) and Delta( ∆) circuit voltages.

When one of the phase inductors in a delta connected circuit opens, the circuit still operates as a three-phase circuit (at reduced capacity). This principle is illustrated in Figure 8b. When L₁ opens, none of the phase inputs is isolated from the circuit, so three-phase operation continues. However, there is no current through L₁, which does affect the overall operation of the delta circuit. The kVA rating of the transformer is reduced because the power handling capacity of L₁ is reduced to 0W. Even so, the circuit can continue three-phase operation at reduced opacity.

Open Delta Connection

As stated earlier, a delta connected transformer can operate at a reduced capacity if one of its phases opens. This principle makes it possible to produce a three-phase circuit using only two single-phase transformers. This Open Delta Connection, which is rarely encountered anymore, is shown in Figure 9.

Note that the kVA rating of an open delta connection is limited to approximately 87% of the sum of the nameplate kVA ratings of the two single-phase transformers. For example, if each transformer has a rating of 100kVA, then the kVA rating of the open delta bank is 200KVA × 87% = 174 kVA. This is due to the fact that only two transformers are carrying the load of three.

Figure 9 Open-delta transformer Schematic & Wiring Diagram

3 Phase Step Up Transformer 240 to 480 Wiring Diagram– wiring diagram is a simplified pleasing pictorial representation of an electrical circuit. It shows the components of the circuit as simplified shapes, and the capability and signal contacts in the company of the devices.

A wiring diagram usually gives suggestion very nearly the relative approach and conformity of devices and terminals upon the devices, to put up to in building or servicing the device. This is unlike a schematic diagram, where the understanding of the components' interconnections upon the diagram usually does not acquiesce to the components' swine locations in the ended device. A pictorial diagram would con more detail of the creature appearance, whereas a wiring diagram uses a more figurative notation to put emphasis on interconnections beyond beast appearance.

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Autotransformer Grounding

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Three Phase Auto Transformer Connection Diagram

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