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46-419: In 2005, five thermal power plants with installed capacity about 8,700 MW were merged into single company. The power output of these plants in 2007 was around 48  TWh . In April 2010, Gazprom, the major shareholder of OGK-2 and OGK-6 , announced a plan to merge these companies. OGK-2 issued 26.59 billion new shares (81.2% of existing share capital) which were used for conversion of OGK-6 shares at

92-428: A battery is usually expressed indirectly by its capacity in ampere-hours ; to convert ampere-hour (Ah) to watt-hours (Wh), the ampere-hour value must be multiplied by the voltage of the power source. This value is approximate, since the battery voltage is not constant during its discharge, and because higher discharge rates reduce the total amount of energy that the battery can provide. In the case of devices that output

138-401: A change over time. For example: miles per hour, kilometres per hour, dollars per hour. Power units, such as kW, already measure the rate of energy per unit time (kW= kJ / s ). Kilowatt-hours are a product of power and time, not a rate of change of power with time. Watts per hour (W/h) is a unit of a change of power per hour, i.e. an acceleration in the delivery of energy. It is used to measure

184-404: A common billing unit for electrical energy supplied by electric utilities . Metric prefixes are used for multiples and submultiples of the basic unit, the watt-hour (3.6 kJ). The kilowatt-hour is a composite unit of energy equal to one kilowatt (kW) sustained for (multiplied by) one hour. The International System of Units (SI) unit of energy meanwhile is the joule (symbol J). Because a watt

230-442: A different voltage than the battery, it is the battery voltage (typically 3.7 V for Li-ion ) that must be used to calculate rather than the device output (for example, usually 5.0 V for USB portable chargers). This results in a 500 mA USB device running for about 3.7 hours on a 2,500 mAh battery, not five hours. The Board of Trade unit (B.T.U.) is an obsolete UK synonym for kilowatt-hour. The term derives from

276-533: A juice carton). In 1990, the International Committee for Weights and Measures stated that it was too early to choose a single symbol for the litre. Prior to 1979, the symbol ℓ came into common use in some countries; for example, it was recommended by South African Bureau of Standards publication M33 and Canada in the 1970s. This symbol can still be encountered occasionally in some English-speaking and European countries like Germany, and its use

322-408: A litre, known as one millilitre (1 mL), of water has a mass of about 1 g; 1000 litres of water has a mass of about 1000 kg (1  tonne or megagram). This relationship holds because the gram was originally defined as the mass of 1 mL of water; however, this definition was abandoned in 1799 because the density of water changes with temperature and, very slightly, with pressure. It

368-499: A millilitre or mL) is a unit of the cgs system, which preceded the MKS system , which later evolved into the SI system. The abbreviation "cc" is still commonly used in many fields, including medical dosage and sizing for combustion engine displacement . The microlitre (μL) has been known in the past as the lambda (λ), but this usage is now discouraged. In the medical field the microlitre

414-505: A ratio of 1.2141 OGK-6 to 1 OGK-2 share. The merger was completed by 1 November 2011. OGK-2 operates following power stations: Installed capacity of the company is 17,750 MW. TWh A kilowatt-hour ( unit symbol : kW⋅h or kW h ; commonly written as kWh ) is a non-SI unit of energy equal to 3.6 megajoules (MJ) in SI units, which is the energy delivered by one kilowatt of power for one hour . Kilowatt-hours are

460-407: A unit in the left column to the units in the top row, multiply by the factor in the cell where the row and column intersect. All the SI prefixes are commonly applied to the watt-hour: a kilowatt-hour is 1,000 Wh (kWh); a megawatt-hour is 1 million Wh (MWh); a milliwatt-hour is 1/1,000 Wh (mWh) and so on. The kilowatt-hour is commonly used by electrical energy providers for purposes of billing, since

506-485: A yearly basis, in units such as megawatt-hours per year (MWh/yr) gigawatt-hours/year (GWh/yr) or terawatt-hours per year (TWh/yr). These units have dimensions of energy divided by time and thus are units of power. They can be converted to SI power units by dividing by the number of hours in a year, about 8760 h/yr . Thus, 1 GWh/yr = 1 GWh/8760 h ≈ 114.12 kW . Many compound units for various kinds of rates explicitly mention units of time to indicate

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552-424: Is "a litre of water's a pint and three-quarters"; this is very close, as a litre is about 1.76 imperial pints. A cubic foot has an exact volume of 28.316846592 litres. Originally, the only symbol for the litre was l (lowercase letter L), following the SI convention that only those unit symbols that abbreviate the name of a person start with a capital letter. In many English-speaking countries, however,

598-508: Is "litre", a spelling which is shared by most English-speaking countries. The spelling "liter" is predominantly used in American English . One litre of liquid water has a mass of almost exactly one kilogram , because the kilogram was originally defined in 1795 as the mass of one cubic decimetre of water at the temperature of melting ice ( 0 °C ). Subsequent redefinitions of the metre and kilogram mean that this relationship

644-411: Is a metric unit of volume . It is equal to 1 cubic decimetre (dm ), 1000 cubic centimetres (cm ) or 0.001 cubic metres (m ). A cubic decimetre (or litre) occupies a volume of 10 cm × 10 cm × 10 cm (see figure) and is thus equal to one-thousandth of a cubic metre. The original French metric system used the litre as a base unit . The word litre is derived from an older French unit,

690-430: Is by definition one joule per second , and because there are 3,600 seconds in an hour, one kWh equals 3,600  kilojoules or 3.6 MJ. A widely used representation of the kilowatt-hour is kWh , derived from its component units, kilowatt and hour. It is commonly used in billing for delivered energy to consumers by electric utility companies, and in commercial, educational, and scientific publications, and in

736-536: Is calculated by multiplying the device's power consumption in kilowatts by the operating time in hours, and by the price per kilowatt-hour. The unit price of electricity charged by utility companies may depend on the customer's consumption profile over time. Prices vary considerably by locality. In the United States prices in different states can vary by a factor of three. While smaller customer loads are usually billed only for energy, transmission services, and

782-450: Is measured in watts , or joules per second . For example, a battery stores energy. When the battery delivers its energy, it does so at a certain power, that is, the rate of delivery of the energy. The higher the power, the quicker the battery's stored energy is delivered. A higher power output will cause the battery's stored energy to be depleted in a shorter time period. Electric energy production and consumption are sometimes reported on

828-481: Is no longer exact. A litre is a cubic decimetre , which is the volume of a cube 10 centimetres × 10 centimetres × 10 centimetres (1 L ≡ 1 dm ≡ 1000 cm ). Hence 1 L ≡ 0.001  m ≡ 1000  cm ; and 1 m (i.e. a cubic metre, which is the SI unit for volume) is exactly 1000 L. From 1901 to 1964, the litre was defined as the volume of one kilogram of pure water at maximum density (+3.98 °C) and standard pressure . The kilogram

874-596: Is now known that the density of water also depends on the isotopic ratios of the oxygen and hydrogen atoms in a particular sample. Modern measurements of Vienna Standard Mean Ocean Water , which is pure distilled water with an isotopic composition representative of the average of the world's oceans, show that it has a density of 0.999 975 ± 0.000 001  kg/L at its point of maximum density (3.984 °C) under one standard atmosphere (101.325  kPa ) of pressure. The litre, though not an official SI unit, may be used with SI prefixes . The most commonly used derived unit

920-445: Is often expressed as terawatt-hours (TWh) for a given period that is often a calendar year or financial year . A 365-day year equals 8,760 hours, so over a period of one year, power of one gigawatt equates to 8.76 terawatt-hours of energy. Conversely, one terawatt-hour is equal to a sustained power of about 114 megawatts for a period of one year. In 2020, the average household in the United States consumed 893 kWh per month. Raising

966-409: Is sometimes abbreviated as mcL on test results. In the SI system, apart from prefixes for powers of 1000, use of the "centi" (10 ), "deci" (10 ), "deca" (10 ) and "hecto" (10 ) prefixes with litres is common. For example, in many European countries, the hectolitre is the typical unit for production and export volumes of beverages (milk, beer, soft drinks, wine, etc.) and for measuring the size of

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1012-425: Is the millilitre, defined as one-thousandth of a litre, and also often referred to by the SI derived unit name "cubic centimetre". It is a commonly used measure, especially in medicine, cooking and automotive engineering. Other units may be found in the table below, where the more often used terms are in bold. However, some authorities advise against some of them; for example, in the United States, NIST advocates using

1058-668: Is ubiquitous in Japan and South Korea. Fonts covering the CJK characters usually include not only the script small ℓ but also four precomposed characters: ㎕, ㎖, ㎗, and ㎘ for the microlitre, millilitre, decilitre and kilolitre to allow correct rendering for vertically written scripts. These have Unicode equivalents for compatibility, which are not recommended for use with new documents: The CJK Compatibility block also includes U+3351 ㍑ SQUARE RITTORU corresponding to リットル rittoru , Japanese for 'litre'. The first name of

1104-467: Is used with loads or output that vary during the year but whose annual totals are similar from one year to the next. For example, it is useful to compare the energy efficiency of household appliances whose power consumption varies with time or the season of the year. Another use is to measure the energy produced by a distributed power source. One kilowatt-hour per year equals about 114.08 milliwatts applied constantly during one year. The energy content of

1150-505: The litron , whose name came from Byzantine Greek —where it was a unit of weight, not volume —via Late Medieval Latin, and which equalled approximately 0.831 litres. The litre was also used in several subsequent versions of the metric system and is accepted for use with the SI, although not an SI unit —the SI unit of volume is the cubic metre (m ). The spelling used by the International Bureau of Weights and Measures

1196-433: The annual electricity generation for whole countries and the world energy consumption . A kilowatt is a unit of power (rate of flow of energy per unit of time). A kilowatt-hour is a unit of energy. Kilowatt per hour would be a rate of change of power flow with time. Work is the amount of energy transferred to a system; power is the rate of delivery of energy. Energy is measured in joules , or watt-seconds . Power

1242-459: The 16th CGPM conference, the alternative symbol L (uppercase letter L) was adopted. It also expressed a preference that in the future only one of these two symbols should be retained, but in 1990 said it was still too early to do so. In spoken English, the symbol "mL" (for millilitre) can be pronounced as "mil". This can potentially cause confusion with some other measurement words such as: The abbreviation "cc" (for cubic centimetre , equal to

1288-415: The SI. An electric heater consuming 1,000 watts (1 kilowatt) operating for one hour uses one kilowatt-hour of energy. A television consuming 100 watts operating continuously for 10 hours uses one kilowatt-hour. A 40-watt electric appliance operating continuously for 25 hours uses one kilowatt-hour. Electrical energy is typically sold to consumers in kilowatt-hours. The cost of running an electrical device

1334-491: The capacity or size of their container, whereas cubic metres (and derived units) are most commonly used for items measured either by their dimensions or their displacements. The litre is often also used in some calculated measurements, such as density (kg/L), allowing an easy comparison with the density of water. One litre of water has a mass of almost exactly one kilogram when measured at its maximal density, which occurs at about 4 °C. It follows, therefore, that 1000th of

1380-517: The catch and quotas for fishing boats; decilitres are common in Croatia , Switzerland and Scandinavia and often found in cookbooks, and restaurant and café menus; centilitres indicate the capacity of drinking glasses and of small bottles. In colloquial Dutch in Belgium , a " vijfentwintiger " and a " drieëndertiger " (literally "twenty-fiver" and "thirty-threer") are the common beer glasses,

1426-399: The corresponding bottles mention 25 cL and 33 cL. Bottles may also be 75 cL or half size at 37.5 cL for "artisanal" brews or 70 cL for wines or spirits. Cans come in 25 cL, 33 cL and 50 cL. Similarly, alcohol shots are often marked in cL in restaurant menus, typically 3 cL (1.06 imp fl oz; 1.01 US fl oz). In countries where the metric system was adopted as

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1472-558: The daily variation of demand (e.g. the slope of the duck curve ), or ramp-up behavior of power plants . For example, a power plant that reaches a power output of 1 MW from 0 MW in 15 minutes has a ramp-up rate of 4 MW/h . Other uses of terms such as watts per hour are likely to be errors. Several other units related to kilowatt-hour are commonly used to indicate power or energy capacity or use in specific application areas. Average annual energy production or consumption can be expressed in kilowatt-hours per year. This

1518-595: The definition relating the litre to mass was superseded by the current one. Although the litre is not an SI unit, it is accepted by the CGPM (the standards body that defines the SI) for use with the SI. CGPM defines the litre and its acceptable symbols. A litre is equal in volume to the millistere , an obsolete non-SI metric unit formerly customarily used for dry measure . Litres are most commonly used for items (such as fluids and solids that can be poured) which are measured by

1564-593: The litre was "cadil"; standards are shown at the Musée des Arts et Métiers in Paris. The litre was introduced in France in 1795 as one of the new "republican units of measurement" and defined as one cubic decimetre . One litre of liquid water has a mass of almost exactly one kilogram , due to the gram being defined in 1795 as one cubic centimetre of water at the temperature of melting ice. The original decimetre length

1610-473: The media. It is also the usual unit representation in electrical power engineering. This common representation, however, does not comply with the style guide of the International System of Units (SI). Other representations of the unit may be encountered: The hour is a unit of time listed among the non-SI units accepted by the International Bureau of Weights and Measures for use with

1656-496: The millilitre or litre instead of the centilitre. There are two international standard symbols for the litre: L and l. In the United States the former is preferred because of the risk that (in some fonts) the letter l and the digit 1 may be confused. See also Imperial units and US customary units . One litre is slightly larger than a US liquid quart and slightly less than an imperial quart or one US dry quart . A mnemonic for its volume relative to an imperial pint

1702-403: The monthly energy consumption of a typical residential customer ranges from a few hundred to a few thousand kilowatt-hours. Megawatt-hours (MWh), gigawatt-hours (GWh), and terawatt-hours (TWh) are often used for metering larger amounts of electrical energy to industrial customers and in power generation. The terawatt-hour and petawatt-hour (PWh) units are large enough to conveniently express

1748-535: The most common shape of a handwritten Arabic digit 1 is just a vertical stroke ; that is, it lacks the upstroke added in many other cultures. Therefore, the digit "1" may easily be confused with the letter "l" . In some computer typefaces, the two characters are barely distinguishable. As a result, L (uppercase letter L) was adopted by the CIPM as an alternative symbol for litre in 1979. The United States National Institute of Standards and Technology now recommends

1794-628: The name of the Board of Trade which regulated the electricity industry until 1942 when the Ministry of Power took over. This should not be confused with a British Thermal Unit (BTU) which is 1055 J. In India, the kilowatt-hour is often simply called a unit of energy. A million units, designated MU , is a gigawatt-hour and a BU (billion units) is a terawatt-hour. Litre The litre ( Commonwealth spelling ) or liter ( American spelling ) (SI symbols L and l , other symbol used: ℓ )

1840-550: The official measuring system after the SI standard was established, common usage eschews prefixes that are not powers of 1000. For example, in Canada , Australia , and New Zealand , consumer beverages are labelled almost exclusively using litres and millilitres. An exception is in pathology, where for instance blood lead level and blood sugar level may be measured in micrograms/milligrams per decilitre. For larger volumes, kilolitres, megalitres, and gigalitres, have been used by

1886-423: The rated capacity, larger consumers also pay for peak power consumption, the greatest power recorded in a fairly short time, such as 15 minutes. This compensates the power company for maintaining the infrastructure needed to provide peak power. These charges are billed as demand changes. Industrial users may also have extra charges according to the power factor of their load. Major energy production or consumption

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1932-403: The temperature of 1 litre of water from room temperature to the boiling point with an electric kettle takes about 0.1 kWh. A 12 watt LED lamp lit constantly uses about 0.3 kW⋅h per 24 hours and about 9 kWh per month. In terms of human power , a healthy adult male manual laborer performs work equal to about half a kilowatt-hour over an eight-hour day. To convert a quantity measured in

1978-453: The temperature of its maximum density (3.98 °C) under a pressure of 1  atm . This made the litre equal to about 1.000 028  dm (earlier reference works usually put it at 1.000 027  dm ). In 1964, at the 12th CGPM conference, the original definition was reverted to, and thus the litre was once again defined in exact relation to the metre, as another name for the cubic decimetre, that is, exactly 1 dm . In 1979, at

2024-537: The use of the uppercase letter L, a practice that is also widely followed in Canada and Australia . In these countries, the symbol L is also used with prefixes, as in mL and μL, instead of the traditional ml and μl used in Europe. In the UK and Ireland , as well as the rest of Europe, lowercase l is used with prefixes, though whole litres are often written in full (so, "750 ml" on a wine bottle, but often "1 litre" on

2070-420: Was 44.344 lignes , which was revised in 1798 to 44.3296 lignes . This made the original litre 1.000 974 of today's cubic decimetre. It was against this litre that the kilogram was constructed. In 1879, the CIPM adopted the definition of the litre, with the symbol l (lowercase letter L). In 1901, at the 3rd CGPM conference, the litre was redefined as the space occupied by 1 kg of pure water at

2116-647: Was in turn specified as the mass of the International Prototype of the Kilogram (a specific platinum/iridium cylinder) and was intended to be of the same mass as the 1 litre of water referred to above. It was subsequently discovered that the cylinder was around 28 parts per million too large and thus, during this time, a litre was about 1.000 028  dm . Additionally, the mass–volume relationship of water (as with any fluid) depends on temperature, pressure, purity and isotopic uniformity. In 1964,

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