Most electrical appliances used in homes and businesses run with alternating current (AC), which means the voltage supplied is pulsating, unlike the constant output of a battery (direct current, DC). In the USA, the voltage supplied by utility companies has a frequency of 60 Hertz, which means it cycles between positive and negative polarity 60 times per second.
Most AC power supplies can be classified into single-phase or three-phase, depending on the characteristics of the voltage supplied. As implied by its name, a three-phase system has three separate AC voltages, each with a frequency of 60 Hz. However, these voltages alternate between positive and negative in a sequence, not simultaneously, providing a constant power supply that is not possible with a single-phase system.
The capacity of AC power systems is measured in volt-amperes (VA), and it is calculated by multiplying voltage and current.
Consider that you need a neutral conductor and a grounding conductor in both cases, in addition to one live conductor for each voltage output. This means you need three wires for the single-phase system, and five wires for the three-phase system. In other words, the three-phase system has 300% the capacity of the single-phase system, while only using only two additional wires (only 67% more copper). When you consider the wiring reduction from using three-phase power in a large commercial or industrial facility, the savings are significant.
Single-phase power is normally used in residential applications, where loads are too small to justify the complexity of a three-phase system. However, the single-phase supplies for individual dwellings are normally derived from a larger-three phase system.
In addition to saving on wiring, three-phase systems have notable performance advantages over their single-phase counterparts. This is especially true for electric motors:
A three-phase system is also more versatile than a single-phase installation. If you need to run a single-phase device with a three-phase power supply, you can use only one of the three conductors. However, there opposite does not apply: three-phase appliances cannot be operated with single-phase power. Motors are an exception: you can run a three-phase motor with a single-phase power supply, but the motor’s mechanical power is drastically reduced and its service life is shortened drastically.
The National Electric Code establishes wiring color requirements for electrical systems. This makes conductors easier to identify, reducing the chance of human error and improving safety. The requirements are summarized in the following table.
|
Conductor |
Three-phase systems, |
Three-phase systems, |
|
Live conductor #1 |
Black |
Brown |
|
Live conductor #2 |
Red |
Orange |
|
Live conductor #3 |
Blue |
Yellow |
|
Neutral conductor |
White |
Grey |
|
Grounding conductor |
Green, Bare or Green & Yellow |
Green, Bare or Green & Yellow |
When a three-phase system supplies both three-phase and single-phase loads, the recommended practice is balancing the single-phase loads among the three phases. An unbalanced voltage supply can be detrimental for some types of equipment. The neutral conductor also carries a higher current when the system is poorly balanced, and this causes power loss in the form of heat dissipation.
Note that wiring is the not the only circuit element that changes between single-phase and three-phase installations. Components such as protection devices, distribution boards and transformers are also built differently. In the case of transformers, you can use three single-phase units to step a three-phase voltage up or down, but a three-phase transformer is less expensive and more compact in most cases.
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