Utility frequency: Difference between revisions

The utility frequency (American English) or mains frequency (British English) is the frequency at which alternating current (AC) is transmitted from a power plant to the end user.

In most parts of the Americas, it is typically 60 Hz, and in most parts of the rest of the world it is typically 50 Hz. Precise details are shown in the list of countries with mains power plugs, voltages and frequencies.

Places that use the 50 Hz frequency tend to use 220/230 voltage, and those that use 60 Hz tend to use 110/120 V.

Other utility frequencies are used. The countries Germany, Austria, and Switzerland use a traction power network for railways, distributing single-phase AC at 16.7 Hz. A frequency of 25 Hz was used for the German railway Mariazeller Bahn and some railway systems in New York and Pennsylvania (Amtrak) in the USA.

The de facto standard for high speed railways and for new non metropolitan railways is 25kVAC. A variant is double this voltage, namely 50kV. The frequency is 50Hz or 60Hz depending on supply.

Frequencies as high as 400 Hz are used in aerospace and some special-purpose computer power supplies and hand-held machine tools. Such high frequencies cannot be economically transmitted long distances, so 400 Hz power systems are usually confined to the building or vehicle. On the other hand, transformers for 400Hz are much smaller and lighter.

Very early AC generating schemes used arbitrary frequencies based on convenience for steam engine, water turbine and generator design, since frequency was not as critical for incandescent lighting loads. Frequencies between 16 2/3 Hz and 133 1/3 Hz were used on different systems, with lower frequencies favoured where loads were primarily composed of motors, and higher frequencies preferred to reduce lighting flicker. For example, the city of Coventry, England, in 1895 had a unique 87 Hz single-phase distribution system that was in use until 1906. Once induction motors became common, it was important to standardize frequency for compatibility with the customer's equipment. Standardizing on one frequency also, later, allowed interconnection of generating plants on a grid for economy and security of operation.

Though many theories exist, and quite a few entertaining urban legends, there is little certitude in the details of the history of 60 Hz vs 50 Hz. What is known is that Westinghouse in the US decided on 60 Hz and AEG in Germany decided on 50 Hz, eventually leading to the world being mostly divided into two frequency camps. What is also well understood is why the frequencies ended up in the 50-60 range: direct current generators that came online in the late 1890:s were more stable at lower rotation speeds, and the flicker of arc or incandescent lighting becomes noticeable somewhere below those levels. Also, steel available for transformer cores at that time operated most efficiently within this frequency range. Westinghouse decided on 60 Hz before 1892 and AEG decided on 50 Hz by 1899. Tesla is believed to have had a key influence in the choice of 60 Hz by Westinghouse, but it may simply have been happenstance: Westinghouse won the World Fair in Chicago (1893) lighting contract, and after that, the Niagara Falls project; both of which were 60 Hz. AEG's choice of 50 Hz is thought by some to relate to a more "metric-friendly" number than 60, which would be peculiar since it is distinctly less efficient than 60Hz. It may also have been an intentional decision to be incompatible. In any case, a plethora of frequencies continued in broad use. For example, London in 1918 had 70 electric authorities with 24 different voltages and 10 different frequencies. It wasn't until after World War II with the advent of affordable electrical consumer goods that broader standards were enacted.

Other frequencies were somewhat common in the first half of the 20th century, and remain in use in isolated cases today, often tied to the 60 Hz system via a rotary converter or static inverter frequency changer. 25 Hz power was used in Ontario, Quebec, the northern USA, and for railway electrification. In the 1950s, much of this electrical system, from the generators right through to household appliances, was converted and standardised to 60 Hz. Some 25 Hz generators still exist at the Beck 1 and Rankine generating stations near Niagara Falls to provide power for large industrial customers who did not want to replace existing equipment; and some 25 Hz motors exist in New Orleans' floodwater pumps [1].

AC-powered appliances can give off a characteristic hum at the multiples of the frequencies of AC power that they use. Most countries have chosen their television standard to approximate their mains supply frequency. This helps prevent powerline hum and magnetic interference from causing visible beat frequencies in the displayed picture. Unless specified by the manufacturer to operate on either 50 or 60 Hz, appliances may not operate efficiently or even safely if used on other than the intended supply frequency.

Early alternating-current generating schemes did not need to standardize the frequency, since most of the load was arc lights and incandescent lighting which worked well at any frequency. Frequencies as low as 16.7 Hz and up to around 140 Hz were produced by alternating current generators in early systems. The frequency was a consequence of the operating speed and design of the generators. In the late 19th century, designers would pick a relatively high frequency for systems featuring transformers and arc lights, so as to economize on transformer materials, but would pick a lower frequency for systems with long transmission lines or feeding primarily motor loads or rotary converters for producing direct current. For example, the city of Coventry, England, in 1895 had a unique 87 Hz single-phase distribution system that was in use until 1906. It was not until the widespread use of alternating current induction motors that a standard frequency was found to be useful. Electrical generators can only be interconnected to operate in parallel if they are of the same frequency and wave-shape. By standardizing the frequency used, generators in a geographic area can be interconnected, providing reliability and cost savings.

Because of the cost of conversion, some parts of the distribution system may continue to operate on original frequencies even after a new frequency is chosen. For example, in Ontario, Canada, parts of the electrical system fed by 25 Hz generators at Niagara Falls continued to use that frequency from 1895 until late in the 1950's. In the United States, the Southern California Edison company had standardized on 50 Hz and did not completely change frequency of their generators and customer equipment to 60 Hz until around 1948.

Utility Frequencies in Use in 1897 in North America

The frequency of large interconnected power distribution systems is tightly regulated so that, over the course of a day, the average frequency is maintained at the nominal value within a few hundred parts per million. While this allows simple electric clocks, relying on synchronous electric motors, to keep accurate time, the primary reason for accurate frequency control is to allow the flow of alternating current power from multiple generators through the network to be controlled.

Frequency of the system will vary as load is added to the system or as generators are shut down; other generators are adjusted in speed so that the average system frequency stays nearly constant. During a severe overload caused by failure of generators or transmission lines, the power system frequency will decline. Loss of an interconnection carrying a large amount of power (relative to system total generation) will cause system frequency to rise. Special protection relays in the power system network sense the decline and may automatically initiate load shedding or tripping of interconnection lines, to preserve the operation of at least part of the network. Quite small frequency deviations, on the order of 0.5 Hz on a 50 Hz or 60 Hz network, will result in automatic load shedding or other control actions to restore system frequency.

Smaller power systems, not extensively interconnected with many generators and loads, may not maintain frequency with the same degree of accuracy.

• Mains
• List of countries with mains power plugs, voltages and frequencies
• Power connector

• Owen, E.L, The Origins of 60-Hz as a Power Frequency, Industry Applications Magazine, IEEE, Volume: 3, Issue 6, Nov.-Dec. 1997, Pages 8, 10, 12-14.
• Furfari, F.A., The Evolution of Power-Line Frequencies 133 1/3 to 25 Hz, Industry Applications Magazine, IEEE, Sep/Oct 2000, Volume 6, Issue 5, Pages 12-14, ISSN: 1077-2618.
• Rushmore, D.B., Frequency, AIEE Transactions, Volume 31, 1912, pages 955-983, and discussion on pages 974-978.

• Edwin J. Houston and Arthur Kennelly, Recent Types of Dynamo-Electric Machinery, copyright American Technical Book Company 1897, published by P.F. Collier and Sons New York, 1902

• Central Station Engineers of the Westinghouse Electric Corporation, Electrical Transmission and Distribution Reference Book, 4th Ed., Westinghouse Electric Corporation, East Pittsburgh PA, 1950, no ISBN

• Donald G. Fink and H. Wayne Beaty, Standard Handbook for Electrical Engineers, Eleventh Edition,McGraw-Hill, New York, 1978, ISBN 007020974X