British thermal unit

"BTU" redirects here. For other uses, see BTU (disambiguation).

The British thermal unit (BTU or Btu) is a traditional unit of work equal to about 1055 joules. It is the amount of work needed to raise the temperature of one pound of water by one degree Fahrenheit (Physical analogue: one four-inch wooden kitchen match consumed completely generates approximately 1 BTU). In science, the joule, the SI unit of energy, has largely replaced the BTU.

The BTU/h is most often used as a measure of power in the power, steam generation, heating, and air conditioning industries. It is still used in some metric English-speaking countries (such as Canada, but notably not the United Kingdom). In North America, the heat value (energy content) of fuels is expressed in BTUs.

The notation kBtu or KBTU is often used for thousand BTU, in sizing of heating systems and in the Energy Use Index (EUI) expressed as thousand BTU annual energy use per square foot of building. MBTU represents one million Btu, although the atypical notation MMBtu or mmBtu is sometimes used to represent one million BTU.(see definitions below)

Definitions

A BTU is the amount of heat required to raise the temperature of 1 avoirdupois pound of liquid water by 1 degree Fahrenheit at a constant pressure of one atmosphere.[1] As with the calorie, several definitions of the BTU exist, because the temperature response of water to heat energy is non-linear. This means that the change in temperature of a water mass caused by adding a certain amount of heat to it will be a function of the water's initial temperature. Definitions of the BTU based on different water temperatures can therefore vary by up to 0.5%.

Nominal temperature BTU equivalent in joules Notes
39 °F (3.9 °C) ≈ 1059.67 Uses the calorie value of water at its maximum density (4 °C or 39.2 °F)
Mean ≈ 1055.87 Uses a calorie averaged over water temperatures 0 to 100 °C (32.0 to 212.0 °F)
IT ≡ 1055.05585262 The most widespread BTU uses the International Steam Table (IT) calorie, which was defined by the Fifth International Conference on the Properties of Steam (London, July 1956) to be exactly 4.1868 J
ISO ≡ 1055.056 International standard ISO 31-4 on Quantities and units—Part 4: Heat,[2] Appendix A. This value uses the IT calorie and is rounded to a realistic accuracy
59 °F (15.0 °C) ≡ 1054.804 Chiefly American. Uses the 15 °C calorie, itself now defined as exactly 4.1855 J (Comité international 1950; PV, 1950, 22, 79–80)
60 °F (15.6 °C) ≈ 1054.68 Chiefly Canadian
63 °F (17.2 °C) ≈ 1054.68
Thermochemical ("Th"[3]) ≡ 1054.35026444 Uses the "thermochemical calorie" of exactly 4.184 J

The unit MBtu or mBtu was defined as one thousand BTU, presumably from the Roman numeral system where "M" or "m" stands for one thousand (1,000). This notation is easily confused with the SI mega- (M) prefix, which denotes multiplication by a factor of one million (×106), or with the SI milli- (m) prefix, which denotes division by a factor of one thousand (×10−3).

To avoid confusion, some companies and engineers use the notation "MMBtu" or "mmBtu" to represent one million BTU (although, confusingly, MM in Roman numerals would traditionally represent 2,000) and in many contexts this form of notation is deprecated and discouraged in favour of the more modern SI prefixes. Alternatively, the term therm may be used to represent 100,000 (or 105) BTU, and quad for 1015 BTU. Some companies also use 'BtuE6' in order to reduce confusion between 103 BTU and 106 BTU.[4]

Conversions

One BTU is approximately:

A BTU can be approximated as the heat produced by burning a single wooden kitchen match[5] or as the amount of energy it takes to lift a one-pound weight 778 feet (237 m).[6]

For natural gas

As a unit of power

When used as a unit of power for heating and cooling systems, BTU per hour (BTU/h) is the correct unit, though this is often abbreviated to just "BTU".[8]

Associated units

The BTU should not be confused with the Board of Trade Unit (B.O.T.U.), which is a much larger quantity of energy (1 kW·h or 3,412 BTU).

The BTU is often used to express the conversion-efficiency of heat into electrical energy in power plants. Figures are quoted in terms of the quantity of heat in BTU required to generate 1 kW·h of electrical energy. A typical coal-fired power plant works at 10,500 BTU/kW·h, an efficiency of 32–33%.[12]

See also

References

  1. "What is British thermal unit (Btu)? definition and meaning". Businessdictionary.com. Retrieved 2011-11-11.
  2. International standard ISO 31-4:1992 Quantities and units—Part 4: Heat
  3. Btu - Kilocalories units conversion
  4. EIA (2012-09-17). "What are Mcf, BTU, and therms? How do I convert prices in Mcf to BTUs and therms?". US Government.
  5. Energy and the Environment. Ristinen, Robert A. c. 2006, pg 13
  6. Energy and the Environment. Ristinen, Robert A. c. 2006, pg 14
  7. "Energy Measurements". Energy.gov.ab.ca. Retrieved 5 April 2014.
  8. Ken Matesz (2010). Masonry Heaters: Designing, Building, and Living with a Piece of the Sun. Chelsea Green Publishing. p. 148.
  9. 2009 ASHRAE Handbook – Fundamentals (I-P Edition). (pp: 38.2). American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc
  10. "The GB gas wholesale market". OFGEM. Retrieved Jan 13, 2013. The wholesale gas market in Britain has one price for gas irrespective of where the gas comes from. This is called the National Balancing Point (NBP) price of gas and is usually quoted in price per therm of gas.
  11. Husher, John Durbin. Crises of the 21st Century: Start Drilling-The Year 2020 Is Coming Fast, iUniverse, 2009. Page 376.
  12. Electric Generation Efficiency, NPC Global Oil & Gas Study, 18 July 2007

External links

This article is issued from Wikipedia - version of the Wednesday, January 27, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.