Three-phase electric power

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Image:Threephasepolemountclose.jpg Image:Three Phase Electric Power Transmission.jpg Three-phase is a common method of electric power transmission. It is a type of polyphase system.

This article deals with where, how and why "three phase" is used. For information on the basic mathematics and principles of three phase see three-phase. For information on testing three phase equipment (kit) please see three-phase testing.

Three phase systems may or may not have a neutral wire. A neutral wire allows the three phase system to use a higher voltage while still supporting lower voltage single phase appliances. In high voltage distribution situations it is common not to have a neutral wire as the loads can simply be connected between phases (phase-phase connection).

Three phase has properties that make it very desirable in distribution. Firstly all three wires carry the same current. Secondly power transfer into a linear balanced load is constant.

Most domestic loads are single phase. Generally three phase power either does not enter domestic houses at all, or where it does, it is split out at the main distribution board.

The three phases are typically indicated by colors which vary by country. See the table for more information.

Contents


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Color Codes

Conductors of a three phase system are usually identified by a color code, to allow for balanced loading and to assure the correct phase rotation for induction motors. Colors used may adhere to old standards or to no standard at all, and may vary even within a single installation. However, the current National Electrical Code (2005) does not require any color identification of conductors other than that of the neutral (white or white with a color stripe) the ground (green or green with a yellow stripe) or in the case of a High Leg Delta system, the High Leg must be identified orange.

L1

L2

L3

Neutral

Earth

North America

Red

Black

Blue

White

Green

North America (newer 277/480 installations)

Orange

Brown

Yellow

White

Green

UK until April 2006

Red

Yellow (prev. white)

Blue

Black

Green/yellow striped (green on very old installations)

Europe (including UK) from April 2004

Brown

Black

Grey

Blue

Green/yellow striped

Previous European (varies by country)

Brown or black

Black or brown

Black or brown

Blue

Green/yellow striped

Europe, for busbars Yellow Green Purple
Australia Red White (prev. yellow) Blue Black Green/yellow striped (green on very old installations)


Note that in the U.S. a green/yellow striped wire typically indicates an Isolated ground.

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Circuit Numbering

In the U.S., and perhaps elsewhere, the circuit numbers of a three phase system are identified as follows. The following chart is true for three phase power (Black, Red, Blue) and 277/480 (Brown, Orange, Yellow) installations. The purpose of the standardized circuit number to wire color is for future troubleshooting. If an electrician knows that the wire running to a nonworking plug is blue, the electrician can instantly eliminate 2/3 of the remaining circuits.

Black/Brown
Red/Orange
Blue/Yellow

1/2
7/8
13/14
19/20
25/26
31/32
37/38

3/4
9/10
15/16
21/22
27/28
33/34
39/40

5/6
11/12
17/18
23/24
29/30
35/36
41/42

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Generation and distribution

Image:3-phase flow.gif At the power station, an electrical generator converts mechanical power into a set of alternating electric currents, one from each electromagnetic coil or winding of the generator. The currents are sinusoidal functions of time, all at the same frequency but with different phases. In a three-phase system the phases are spaced equally, giving a phase separation of 120°. The frequency is typically 50 Hz in Europe and 60 Hz in the US and Canada (see List of countries with mains power plugs, voltages and frequencies).

Generators output at a voltage that ranges from hundreds of volts to 30,000 volts. At the power station, transformers "step-up" this voltage to one more suitable for transmission.

After numerous further conversions in the transmission and distribution network the power is finally transformed to the standard mains voltage (i.e. the "household" voltage). The power may already have been split into single phase at this point or it may still be three phase. Where the stepdown is 3 phase, the output of this transformer is usually star connected with the standard mains voltage (120 V in North America and 230 V in Europe) being the phase-neutral voltage. Another system commonly seen in North America is to have a delta connected secondary with a centre tap on one of the windings supplying the ground and neutral. This allows for 240 V three phase as well as three different single phase voltages (120 V between two of the phases and the neutral, 208 V between the third phase (known as a wild leg) and neutral and 240 V between any two phases) to be made available from the same supply.

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Single phase loads

Single-phase loads may be connected to a three-phase system, either by connecting across two live conductors (a phase-to-phase connection), or by connecting between a phase conductor and the system neutral, which is either connected to the center of the Y (star) secondary winding of the supply transformer, or is connected to the center of one winding of a delta transformer (Highleg Delta system). Single-phase loads should be distributed evenly between the phases of the three-phase system for efficient use of the supply transformer and supply conductors.

The line-to-line voltage of a three-phase system is √3 times the line to neutral voltage. Where the line-to-neutral voltage is a standard utilization voltage, (for example in a 240 V/415 V system) individual single-phase utility customers or loads may each be connected to a different phase of the supply. Where the line-to-neutral voltage is not a common utilization voltage, for example in a 347/600 V system, single-phase loads must be supplied by individual step-down transformers. In multiple-unit residential buildings in North America, lighting and convenience outlets can be connected line-to-neutral to give the 120 V utilization voltage, and high-power loads such as cooking equipment, space heating, water heaters, or air conditioning can be connected across two phases to give 208 V. This practice is common enough that 208 V single-phase equipment is readily available in North America. Attempts to use the more common 120/240 V equipment intended for three-wire single-phase distribution may result in poor performance since 240 V heating equipment will only produce 75% of its rating when operated at 208 V.

Where three phase at low voltage is otherwise in use, it may still be split out into single phase service cables through joints in the supply network or it may be delivered to a master distribution board (breaker panel) at the customer's premises. Connecting an electrical circuit from one phase to the neutral generally supplies the country's standard single phase voltage (120 VAC or 230 VAC) to the circuit.

The power transmission grid is organized so that each phase carries the same magnitude of current out of the major parts of the transmission system. The currents returning from the customers' premises to the last supply transformer all share the neutral wire, but the three-phase system ensures that the sum of the returning currents is approximately zero. The delta wiring of the primary side of that supply transformer means that no neutral is needed in the high voltage side of the network.

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Connecting phase-phase

Connecting between two phases provides √3 or 173% of the single-phase voltage (208 VAC in US; 400 VAC in Europe) because the out-of-phase waveforms add to provide a higher peak voltage in the resulting waveform. Such connection is referred to as a line to line connection and is usually done with a two pole circuit breaker. This kind of connection is typically used for high power appliances, such as (in the US) a 2 kW, 208 volt baseboard heater.

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Three phase loads

The most important class of three-phase load is the electric motor. A three phase induction motor has a simple design, inherently high starting torque, and high efficiency. Such motors are applied in industry for pumps, fans, blowers, compressors, conveyor drives, and many other kinds of motor-driven equipment. A three-phase motor will be more compact and less costly than a single-phase motor of the same voltage class and rating; and single-phase AC motors above 10 HP (7.5 kW) are uncommon.

Large air conditioning equipment (for example, most York units above 2.5 tons (8.8 kW) cooling capacity) use three-phase motors for reasons of efficiency and economy.

Resistance heating loads such as electric boilers or space heating may be connected to three-phase systems. Electric lighting may also be similarly connected. These types of loads do not require the revolving magnetic field characteristic of three-phase motors but take advantage of the higher voltage and power level usually associated with three-phase distribution.

Large rectifier systems may have three-phase inputs; the resulting DC current is easier to filter (smooth) than the output of a single-phase rectifier. Such rectifiers may be used for battery charging, electrolysis processes such as aluminum production, or for operation of DC motors.

An interesting example of a three-phase load is the electric arc furnace used in steelmaking and in refining of ores.

In much of Europe stoves are designed to allow for a three phase feed. Usually the individual heating units are connected between phase and neutral to allow for connection to a single phase supply where this is all that is available.

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Phase converters

Occasionally the advantages of three-phase motors make it worthwhile to convert single-phase power to three phase. Small customers, such as residential or farm properties may not have access to a three-phase supply, or may not want to pay for the extra cost of a three-phase service, but may still wish to use three-phase equipment. Such converters may also allow the frequency to be varied allowing speed control. Some locomotives are moving to multi-phase motors driven by such systems even though the incoming supply to a locomotive is nearly always either DC or single phase AC.

Because single-phase power is interrupted at each moment that the voltage crosses zero but three-phase delivers power continuously, any such converter must have a way to store energy for the necessary fraction of a second.

One method for using three-phase equipment on a single-phase supply is with a rotary phase converter, essentially a three-phase motor with special starting arrangements that produces a three-phase system. When properly designed these rotary converters can allow satisfactory operation of three-phase equipment such as machine tools on a single phase supply. In such a device, the energy storage is performed by the mechanical inertia (flywheel effect) of the rotating components.

Some devices are made which create an imitation three-phase from three-wire single phase supplies. This is done by creating a third "subphase" between the two live conductors, resulting in a phase separation of 180° - 90° = 90°. Many three-phase devices will run on this configuration, but at lower efficiency.

Solid-state inverters also can be used to power three-phase motors from a single-phase supply.

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Small scale applications

While most three-phase motors are very big (>1hp), there are small (<50w) three-phase motors. The most common example is a computer fan. An inverter circuit inside the fan converts DC to three-phase AC. This is done to decrease noise (as the torque from a three-phase motor is very smooth compared to that from a single phase motor or a brushed DC motor) and increase reliability (as there are no brushes to wear out, unlike a brushed DC motor).

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Alternatives to three-phase

  • Three-wire single-phase distribution is useful when high voltage three phase is not available, and allows double the normal utilization voltage to be supplied for high-power loads.
  • Two phase power, like three phase, gives constant power transfer to a linear load. But in a three wire system it has a neutral current which is greater than the phase currents. Also motors aren't entirely linear and this means that despite the theory motors running on three phase tend to run smoother than those on two phase. The generators at Niagara Falls installed in 1895 were the largest generators in the world at the time and were two-phase machines. True two-phase power distribution is essentially obsolete. Special purpose systems may use a two-phase system for control. Two-phase power may be obtained from a three-phase system using an arrangement of transformers called a Scott T.
  • Monocyclic power was a name for an asymmetrical modified two-phase power system used by General Electric around 1897 (championed by Charles Proteus Steinmetz and Elihu Thomson; this usage was reportedly undertaken to avoid patent legalities). In this system, a generator was wound with a full-voltage single phase winding intended for lighting loads, and with a small (usually 1/4 of the line voltage) winding which produced a voltage in quadrature with the main windings. The intention was to use this "power wire" additional winding to provide starting torque for induction motors, with the main winding providing power for lighting loads. After the expiration of the Westinghouse patents on symmetrical two-phase and three-phase power distribution systems, the monocyclic system fell out of use.
  • High phase order systems for power transmission have been built and tested. Such transmission lines use 6 or 12 phases and design practices characteristic of extra-high voltage transmission lines. High-phase order transmission lines may allow transfer of more power through a given transmission line right-of-way without the expense of a HVDC converter at each end of the line.
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See also

de:Dreiphasenwechselstrom fi:Kolmivaihevirta fr:triphasé ja:三相交流 sv:Trefassystem

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