The net capacity factor is the
unitless
A dimensionless quantity (also known as a bare quantity, pure quantity, or scalar quantity as well as quantity of dimension one) is a quantity to which no physical dimension is assigned, with a corresponding SI unit of measurement of one (or 1) ...
ratio of actual electrical energy output over a given period of time to the theoretical maximum electrical energy output over that period. The theoretical maximum energy output of a given installation is defined as that due to its continuous operation at full
nameplate capacity over the relevant period. The capacity factor can be calculated for any electricity producing installation, such as a
fuel consuming
power plant or one using
renewable energy
Renewable energy is energy that is collected from renewable resources that are naturally replenished on a human timescale. It includes sources such as sunlight, wind, the movement of water, and geothermal heat. Although most renewable energy ...
, such as wind or the sun. The average capacity factor can also be defined for any class of such installations, and can be used to compare different types of electricity production.
The actual energy output during that period and the capacity factor vary greatly depending on a range of factors. The capacity factor can never exceed the
availability factor, or
uptime during the period. Uptime can be reduced due to, for example, reliability issues and maintenance, scheduled or unscheduled. Other factors include the design of the installation, its location, the type of electricity production and with it either the fuel being used or, for renewable energy, the local weather conditions. Additionally, the capacity factor can be subject to regulatory constraints and
market forces, potentially affecting both its fuel purchase and its electricity sale.
The capacity factor is often computed over a timescale of a year,
averaging out most temporal fluctuations. However, it can also be computed for a month to gain insight into seasonal fluctuations. Alternatively, it can be computed over the lifetime of the power source, both while operational and after decommissioning. A capacity factor can also be expressed and converted to
full load hour
Full Load hour is a measure of the degree of utilisation of a technical system. Full load hours refer to the time for which a plant would have to be operated at nominal power in order to convert the same amount of electrical work as the plant has ...
s.
Sample calculations
Nuclear power plant
Nuclear power plants are at the high end of the range of capacity factors, ideally reduced only by the
availability factor, i.e. maintenance and refueling. The largest nuclear plant in the US,
Palo Verde Nuclear Generating Station has between its three reactors a nameplate capacity of 3,942 MW. In 2010 its annual generation was 31,200,000 MWh, leading to a capacity factor of:
:
Each of Palo Verde’s three reactors is refueled every 18 months, with one refueling every spring and fall. In 2014, a refueling was completed in a record 28 days, compared to the 35 days of downtime that the 2010 capacity factor corresponds to.
In 2019,
Prairie Island 1 was the US unit with the highest factor and actually reached 104.4%.
Wind farm
The Danish offshore wind farm
Horns Rev 2 has a nameplate capacity of 209.3 MW.
it has produced 6416 GWh since its commissioning 7 years ago, i.e. an average annual production of 875 GWh/year and a capacity factor of:
:
Sites with lower capacity factors may be deemed feasible for wind farms, for example the onshore 1 GW
Fosen Vind
Fosen Vind is a complex of six onshore wind farms in Fosen, Norway, commissioned in 2018-20. With a nameplate capacity of 1 GW the project is Europe's second largest onshore wind farm (second to the Markbygden Wind Farm); it more than doubl ...
which is under construction in Norway has a projected capacity factor of 39%. Feasibility calculations may be affected by seasonality. For example in Finland, capacity factor during the cold winter months is more than double compared to July.
While the annual average in Finland is 29.5%,
the high demand for heating energy correlates with the higher capacity factor during the winter.
Certain onshore wind farms can reach capacity factors of over 60%, for example the 44 MW Eolo plant in Nicaragua had a net generation of 232.132 GWh in 2015, equivalent to a capacity factor of 60.2%, while United States annual capacity factors from 2013 through 2016 range from 32.2% to 34.7%.
Since the capacity factor of a wind turbine measures actual production relative to possible production, it is unrelated to
Betz's coefficient of 16/27
59.3%, which limits production vs. energy available in the wind.
Hydroelectric dam
the
Three Gorges Dam in China is, with its nameplate capacity of 22,500 MW, the largest power generating station in the world by installed capacity.
In 2015 it generated 87 TWh, for a capacity factor of:
:
Hoover Dam has a nameplate capacity of 2080 MW
and an annual generation averaging 4.2 TW·h.
(The annual generation has varied between a high of 10.348 TW·h in 1984, and a low of 2.648 TW·h in 1956.
).
Taking the average figure for annual generation gives a capacity factor of:
:
Photovoltaic power station
At the low range of capacity factors is the
photovoltaic power station
A photovoltaic power station, also known as a solar park, solar farm, or solar power plant, is a large-scale grid-connected photovoltaic power system (PV system) designed for the supply of merchant power. They are different from most building- ...
, which supplies power to the electricity grid from a large-scale
photovoltaic system
A photovoltaic system, also PV system or solar power system, is an electric power system designed to supply usable solar power by means of photovoltaics. It consists of an arrangement of several components, including solar panels to absorb and co ...
(PV system).
An inherent limit to its capacity factor comes from its requirement of
daylight, preferably with a sun unobstructed by clouds, smoke or
smog
Smog, or smoke fog, is a type of intense air pollution. The word "smog" was coined in the early 20th century, and is a portmanteau of the words ''smoke'' and '' fog'' to refer to smoky fog due to its opacity, and odor. The word was then inte ...
, shade from trees and building structures.
Since the amount of sunlight varies both with the time of the day and the seasons of the year, the capacity factor is typically computed on an annual basis.
The amount of available sunlight is mostly determined by the
latitude of the installation and the local cloud cover.
The actual production is also influenced by local factors such as dust and ambient temperature, which ideally should be low. As for any power station, the maximum possible power production is the nameplate capacity times the number of hours in a year, while the actual production is the amount of electricity delivered annually to the grid.
For example,
Agua Caliente Solar Project, located in
Arizona
Arizona ( ; nv, Hoozdo Hahoodzo ; ood, Alĭ ṣonak ) is a U.S. state, state in the Southwestern United States. It is the list of U.S. states and territories by area, 6th largest and the list of U.S. states and territories by population, 14 ...
near the 33rd
parallel and awarded for its excellence in renewable energy has a nameplate capacity of 290 MW and an actual average annual production of 740 GWh/year.
Its capacity factor is thus:
:
.
A significantly lower capacity factor is achieved by
Lauingen Energy Park
The Lauingen Energy Park is a 25.7–megawatt (MW) photovoltaic power station, located in Bavarian Swabia, Germany. It covers an area of and was commissioned in June 2010.
The project was built in three phases:
* The 10.0 MW Helmeringen 1 (alr ...
located in
Bavaria
Bavaria ( ; ), officially the Free State of Bavaria (german: Freistaat Bayern, link=no ), is a state in the south-east of Germany. With an area of , Bavaria is the largest German state by land area, comprising roughly a fifth of the total l ...
, near the 49th parallel. With a nameplate capacity of 25.7 MW and an actual average annual production of 26.98 GWh/year it has a capacity factor of 12.0%.
Determinants of a plant capacity factor
There are several reasons why a plant would have a capacity factor lower than 100%. These include technical constraints, such as availability of the plant, economic reasons, and availability of the energy resource.
A plant can be out of service or operating at reduced output for part of the time due to equipment failures or routine maintenance.
This accounts for most of the unused capacity of
base load power plants. Base load plants usually have low costs per unit of electricity because they are designed for maximum efficiency and are operated continuously at high output.
Geothermal power plants,
nuclear power plant
A nuclear power plant (NPP) is a thermal power station in which the heat source is a nuclear reactor. As is typical of thermal power stations, heat is used to generate steam that drives a steam turbine connected to a generator that produces e ...
s,
coal-fired plants and
bioenergy plants that burn solid material are almost always operated as base load plants, as they can be difficult to adjust to suit demand.
A plant can also have its output curtailed or intentionally left idle because the electricity is not needed or because the price of electricity is too low to make production economical.
This accounts for most of the unused capacity of
peaking power plant
Peaking power plants, also known as peaker plants, and occasionally just "peakers", are power plants that generally run only when there is a high demand, known as peak demand, for electricity. Because they supply power only occasionally, the po ...
s and
load following power plants.
Peaking plants may operate for only a few hours per year or up to several hours per day.
Many other power plants operate only at certain times of the day or year because of variation in loads and electricity prices.
If a plant is only needed during the day, for example, even if it operates at full power output from 8 am to 8 pm every day (12 hours) all year long, it would only have a 50% capacity factor.
Due to low capacity factors, electricity from peaking power plants is relatively expensive because the limited generation has to cover the plant fixed costs.
A third reason is that a plant may not have the fuel available to operate all of the time.
This can apply to fossil generating stations with restricted fuels supplies, but most notably applies to intermittent renewable resources.
Solar PV and wind turbines have a capacity factor limited by the availability of their "fuel", sunshine and wind respectively.
A hydroelectricity plant may have a capacity factor lower than 100% due to restriction or scarcity of water, or its output may be regulated to match the current power need, conserving its stored water for later usage.
Other reasons that a power plant may not have a capacity factor of 100% include restrictions or limitations on air permits and limitations on transmission that force the plant to curtail output.
Capacity factor of renewable energy
For
renewable energy
Renewable energy is energy that is collected from renewable resources that are naturally replenished on a human timescale. It includes sources such as sunlight, wind, the movement of water, and geothermal heat. Although most renewable energy ...
sources such as
solar power,
wind power and
hydroelectricity
Hydroelectricity, or hydroelectric power, is electricity generated from hydropower (water power). Hydropower supplies one sixth of the world's electricity, almost 4500 TWh in 2020, which is more than all other renewable sources combined a ...
, the main reason for reduced capacity factor is generally the availability of the energy source.
The plant may be capable of producing electricity, but its "fuel" (
wind,
sunlight
Sunlight is a portion of the electromagnetic radiation given off by the Sun, in particular infrared, visible, and ultraviolet light. On Earth, sunlight is scattered and filtered through Earth's atmosphere, and is obvious as daylight ...
or
water
Water (chemical formula ) is an inorganic, transparent, tasteless, odorless, and nearly colorless chemical substance, which is the main constituent of Earth's hydrosphere and the fluids of all known living organisms (in which it acts as ...
) may not be available.
A hydroelectric plant's production may also be affected by requirements to keep the water level from getting too high or low and to provide water for
fish downstream.
However, solar, wind and hydroelectric plants do have high
availability factors, so when they have fuel available, they are almost always able to produce electricity.
When hydroelectric plants have water available, they are also useful for load following, because of their high ''dispatchability''. A typical hydroelectric plant's operators can bring it from a stopped condition to full power in just a few minutes.
Wind farms are variable, due to the natural variability of the wind.
For a wind farm, the capacity factor is determined by the availability of wind, the swept area of the turbine and the size of the
generator.
Transmission line capacity and electricity demand also affect the capacity factor.
Typical capacity factors of current wind farms are between 25 and 45%. In the United Kingdom during the five year period from 2011 to 2019 the annual capacity factor for wind was over 30%.
Solar energy
Solar energy is radiant light and heat from the Sun that is harnessed using a range of technologies such as solar power to generate electricity, solar thermal energy (including solar water heating), and solar architecture. It is an essenti ...
is variable because of the daily rotation of the earth, seasonal changes, and because of cloud cover.
For example, the Sacramento Municipal Utility District observed a 15% capacity factor in 2005.
However, according to the
SolarPACES programme of the
International Energy Agency
The International Energy Agency (IEA) is a Paris-based autonomous intergovernmental organisation, established in 1974, that provides policy recommendations, analysis and data on the entire global energy sector, with a recent focus on curbing carb ...
(IEA), solar power plants designed for solar-only generation are well matched to summer noon peak loads in areas with significant cooling demands, such as
Spain
, image_flag = Bandera de España.svg
, image_coat = Escudo de España (mazonado).svg
, national_motto = '' Plus ultra'' ( Latin)(English: "Further Beyond")
, national_anthem = (English: "Royal March")
, ...
or the
south-western United States
The Southwestern United States, also known as the American Southwest or simply the Southwest, is a geographic and cultural region of the United States that generally includes Arizona, New Mexico, and adjacent portions of California, Colorado ...
,
[ although in some locations solar PV does not reduce the need for generation of network upgrades given that air conditioner peak demand often occurs in the late afternoon or early evening when solar output is reduced.
SolarPACES states that by using thermal energy storage systems the operating periods of solar thermal power (CSP) stations can be extended to become dispatchable (load following).][Thomas R. Mancini and Michael Geyer (2006)]
Spain Pioneers Grid-Connected Solar-Tower Thermal Power
SolarPACES, OECD/ IEA, p. 3.
Geothermal has a higher capacity factor than many other power sources, and geothermal resources are generally available all the time.
Capacity factors by energy source
Worldwide
*Nuclear power 88.7% (2006 - 2012 average of US's plants).
* Hydroelectricity, worldwide average 44%, range of 10% - 99% depending on water availability (with or without regulation via storage dam).
* Wind farms 20-40%.
* CSP solar with storage and Natural Gas backup in Spain 63%, California 33%.
* Photovoltaic solar in Germany 10%, Arizona 19%, Massachusetts 13.35% (8 year average as of July 2018).
United States
According to the US Energy Information Administration (EIA), from 2013 to 2017 the capacity factors of utility-scale generators were as follows:
, -
! colspan="8", Non-fossil fuels !! Coal !! colspan="4" , Natural Gas !! colspan="3" , Petroleum Liquids
, -
!Nuclear !! Hydro !!Wind !!Solar PV !!Solar CSP
CSP may refer to:
Education
* College Student Personnel, an academic discipline
* Commonwealth Supported Place, a category in Australian education
* Concordia University (Saint Paul, Minnesota), US
Organizations
* Caledonian Steam Packet Compa ...
!!Landfill Gas
and !!Other Biomass
including Wood !! Geothermal !! !! !! !! !! !! !! !!
, -
, 89.9% , , 38.9% , , 32.4% , , NA , , NA , , 68.9% , , 56.7% , , 73.6% , , 59.8% , , 48.2% , , 4.9% , , 10.6% , , 6.1% , , 12.1% , , 0.8% , , 2.2%
, -
, 91.7% , , 37.3% , , 34.0% , , 25.9% , , 19.8% , , 68.9% , , 58.9% , , 74.0% , , 61.1% , , 48.3% , , 5.2% , , 10.4% , , 8.5% , , 12.5% , , 1.1% , , 1.4%
, -
, 92.3% , , 35.8% , , 32.2% , , 25.8% , , 22.1% , , 68.7% , , 55.3% , , 74.3% , , 54.7% , , 55.9% , , 6.9% , , 11.5% , , 8.9% , , 13.3% , , 1.1% , , 2.2%
, -
, 92.3% , , 38.2% , , 34.5% , , 25.1% , , 22.2% , , 69.7% , , 55.6% , , 73.9% , , 53.3% , , 55.5% , , 8.3% , , 12.4% , , 9.6% , , 11.5% , , 1.1% , , 2.6%
, -
, 92.2% , , 43.1% , , 34.6% , , 25.7% , , 21.8% , , 68.0% , , 57.8% , , 74.0% , , 53.7% , , 51.3% , , 6.7% , , 10.5% , , 9.9% , , 13.5% , , 0.9% , , 2.3%
, -
, 92.6% , , 42.8% , , 37.4% , , 26.1% , , 23.6% , , 73.3% , , 49.3% , , 77.3% , , 54.0% , , 57.6% , , 11.8% , , 13.7% , , NA , , 13.9% , , 2.5% , , NA
However, these values often vary significantly by month.
United Kingdom
The following figures were collected by the Department of Energy and Climate Change
The Department of Energy and Climate Change (DECC) was a department of the Government of the United Kingdom created on 3 October 2008, by Prime Minister Gordon Brown to take over some of the functions related to energy of the Department for Busin ...
on the capacity factors for various types of plants in UK grid:
See also
* Demand factor
* Intermittent power source
References
{{Authority control
Power station technology