Waste heat explained

Waste heat is heat that is produced by a machine, or other process that uses energy, as a byproduct of doing work. All such processes give off some waste heat as a fundamental result of the laws of thermodynamics. Waste heat has lower utility (or in thermodynamics lexicon a lower exergy or higher entropy) than the original energy source. Sources of waste heat include all manner of human activities, natural systems, and all organisms, for example, incandescent light bulbs get hot, a refrigerator warms the room air, a building gets hot during peak hours, an internal combustion engine generates high-temperature exhaust gases, and electronic components get warm when in operation.

Instead of being "wasted" by release into the ambient environment, sometimes waste heat (or cold) can be used by another process (such as using hot engine coolant to heat a vehicle), or a portion of heat that would otherwise be wasted can be reused in the same process if make-up heat is added to the system (as with heat recovery ventilation in a building).

Thermal energy storage, which includes technologies both for short- and long-term retention of heat or cold, can create or improve the utility of waste heat (or cold). One example is waste heat from air conditioning machinery stored in a buffer tank to aid in night time heating. Another is seasonal thermal energy storage (STES) at a foundry in Sweden. The heat is stored in the bedrock surrounding a cluster of heat exchanger equipped boreholes, and is used for space heating in an adjacent factory as needed, even months later.[1] An example of using STES to use natural waste heat is the Drake Landing Solar Community in Alberta, Canada, which, by using a cluster of boreholes in bedrock for interseasonal heat storage, obtains 97 percent of its year-round heat from solar thermal collectors on the garage roofs.[2] [3] Another STES application is storing winter cold underground, for summer air conditioning.[4]

On a biological scale, all organisms reject waste heat as part of their metabolic processes, and will die if the ambient temperature is too high to allow this.

Anthropogenic waste heat can contribute to the urban heat island effect. The biggest point sources of waste heat originate from machines (such as electrical generators or industrial processes, such as steel or glass production) and heat loss through building envelopes. The burning of transport fuels is a major contribution to waste heat.

Conversion of energy

See also: Second law of thermodynamics. Machines converting energy contained in fuels to mechanical work or electric energy produce heat as a by-product.

Sources

In the majority of applications, energy is required in multiple forms. These energy forms typically include some combination of heating, ventilation, and air conditioning, mechanical energy and electric power. Often, these additional forms of energy are produced by a heat engine running on a source of high-temperature heat. A heat engine can never have perfect efficiency, according to the second law of thermodynamics, therefore a heat engine will always produce a surplus of low-temperature heat. This is commonly referred to as waste heat or "secondary heat", or "low-grade heat". This heat is useful for the majority of heating applications, however, it is sometimes not practical to transport heat energy over long distances, unlike electricity or fuel energy. The largest proportions of total waste heat are from power stations and vehicle engines. The largest single sources are power stations and industrial plants such as oil refineries and steelmaking plants.

Air conditioning

Conventional air conditioning systems are a source of waste heat by releasing waste heat into the outdoor ambient air whilst cooling indoor spaces. This expelling of waste heat from air conditioning can worsen the urban heat island effect.[5] Waste heat from air conditioning can be reduced through the use of passive cooling building design and zero-energy methods like evaporative cooling and passive daytime radiative cooling, the latter of which sends waste heat directly to outer space through the infrared window.[6] [7]

Power generation

The electrical efficiency of thermal power plants is defined as the ratio between the input and output energy. It is typically only 33% when disregarding usefulness of the heat output for building heat.[8] The images show cooling towers, which allow power stations to maintain the low side of the temperature difference essential for conversion of heat differences to other forms of energy. Discarded or "waste" heat that is lost to the environment may instead be used to advantage.

Industrial processes

Industrial processes, such as oil refining, steel making or glass making are major sources of waste heat.[9]

Electronics

Although small in terms of power, the disposal of waste heat from microchips and other electronic components, represents a significant engineering challenge. This necessitates the use of fans, heatsinks, etc. to dispose of the heat.

For example, data centers use electronic components that consume electricity for computing, storage and networking. The French CNRS explains a data center is like a resistor and most of the energy it consumes is transformed into heat and requires cooling systems.[10]

Biological

Humans, like all animals, produce heat as a result of metabolism. In warm conditions, this heat exceeds a level required for homeostasis in warm-blooded animals, and is disposed of by various thermoregulation methods such as sweating and panting.[11]

Disposal

Low temperature heat contains very little capacity to do work (Exergy), so the heat is qualified as waste heat and rejected to the environment. Economically most convenient is the rejection of such heat to water from a sea, lake or river. If sufficient cooling water is not available, the plant can be equipped with a cooling tower or air cooler to reject the waste heat into the atmosphere. In some cases it is possible to use waste heat, for instance in district heating systems.

Uses

Conversion to electricity

There are many different approaches to transfer thermal energy to electricity, and the technologies to do so have existed for several decades.

An established approach is by using a thermoelectric device,[12] where a change in temperature across a semiconductor material creates a voltage through a phenomenon known as the Seebeck effect.

A related approach is the use of thermogalvanic cells, where a temperature difference gives rise to an electric current in an electrochemical cell.[13]

The organic Rankine cycle, offered by companies such as Ormat, is a very known approach, whereby an organic substance is used as working medium instead of water. The benefit is that this process can reject heat at lower temperatures for the production of electricity than the regular water steam cycle.[14] An example of use of the steam Rankine cycle is the Cyclone Waste Heat Engine.

Cogeneration and trigeneration

Waste of the by-product heat is reduced if a cogeneration system is used, also known as a Combined Heat and Power (CHP) system. Limitations to the use of by-product heat arise primarily from the engineering cost/efficiency challenges in effectively exploiting small temperature differences to generate other forms of energy. Applications utilizing waste heat include swimming pool heating and paper mills. In some cases, cooling can also be produced by the use of absorption refrigerators for example, in this case it is called trigeneration or CCHP (combined cooling, heat and power).

District heating

Waste heat can be used in district heating. Depending on the temperature of the waste heat and the district heating system, a heat pump must be used to reach sufficient temperatures. These are an easy and cheap way to use waste heat in cold district heating systems, as these are operated at ambient temperatures and therefore even low-grade waste heat can be used without needing a heat pump at the producer side.

Pre-heating

Waste heat can be forced to heat incoming fluids and objects before being highly heated. For instance, outgoing water can give its waste heat to incoming water in a heat exchanger before heating in homes or power plants.

Anthropogenic heat

Anthropogenic heat is heat generated by humans and human activity. The American Meteorological Society defines it as "Heat released to the atmosphere as a result of human activities, often involving combustion of fuels. Sources include industrial plants, space heating and cooling, human metabolism, and vehicle exhausts. In cities this source typically contributes 15–50 W/m2 to the local heat balance, and several hundred W/m2 in the center of large cities in cold climates and industrial areas."[15] In 2020, the overall anthropogenic annual energy release was 168,000 terawatt-hours; given the 5.1×10 m surface area of Earth, this amounts to a global average anthropogenic heat release rate of 0.04 W/m.[16] [17]

Environmental impact

Anthropogenic heat is a small influence on rural temperatures, and becomes more significant in dense urban areas.[18] It is one contributor to urban heat islands. Other human-caused effects (such as changes to albedo, or loss of evaporative cooling) that might contribute to urban heat islands are not considered to be anthropogenic heat by this definition.

Anthropogenic heat is a much smaller contributor to global warming than greenhouse gases are.[19] In 2005, anthropogenic waste heat flux globally accounted for only 1% of the energy flux created by anthropogenic greenhouse gases. The heat flux is not evenly distributed, with some regions higher than others, and significantly higher in certain urban areas. For example, global forcing from waste heat in 2005 was 0.028 W/m2, but was +0.39 and +0.68 W/m2 for the continental United States and western Europe, respectively.[20]

Although waste heat has been shown to have influence on regional climates,[21] climate forcing from waste heat is not normally calculated in state-of-the-art global climate simulations. Equilibrium climate experiments show statistically significant continental-scale surface warming (0.4–0.9 °C) produced by one 2100 AHF scenario, but not by current or 2040 estimates. Simple global-scale estimates with different growth rates of anthropogenic heat[22] that have been actualized recently[23] show noticeable contributions to global warming, in the following centuries. For example, a 2% p.a. growth rate of waste heat resulted in a 3 degree increase as a lower limit for the year 2300. Meanwhile, this has been confirmed by more refined model calculations.[24]

A 2008 scientific paper showed that if anthropogenic heat emissions continue to rise at the current rate, they will become a source of warming as strong as GHG emissions in the 21st century.[25]

See also

Notes and References

  1. Andersson, O.; Hägg, M. (2008), "Deliverable 10 - Sweden - Preliminary design of a seasonal heat storage for IGEIA – Integration of geothermal energy into industrial applications, pp. 38–56 and 72–76, retrieved 21 April 2013
  2. Wong, Bill (June 28, 2011), "Drake Landing Solar Community", IDEA/CDEA District Energy/CHP 2011 Conference, Toronto, pp. 1–30, retrieved 21 April 2013
  3. Wong B., Thornton J. (2013). Integrating Solar & Heat Pumps. Renewable Heat Workshop.
  4. Paksoy, H.; Stiles, L. (2009), "Aquifer Thermal Energy Cold Storage System at Richard Stockton College", Effstock 2009 (11th International) - Thermal Energy Storage for Efficiency and Sustainability, Stockholm.
  5. Kovats . Sari . Brisley . Rachel . 2021 . Betts . R.A. . Howard . A.B. . Pearson . K.V. . Health, Communities and the Built Environment . The Third UK Climate Change Risk Assessment Technical Report . Prepared for the Climate Change Committee, London . 38 . Although uptake may increase autonomously in the future, relying on air conditioning to deal with the risk is a potentially maladaptive solution, and it expels waste heat into the environment - thereby enhancing the urban heat island effect. .
  6. Chen . Meijie . Pang . Dan . Yan . Hongjie . November 2022 . Colored passive daytime radiative cooling coatings based on dielectric and plasmonic spheres . Applied Thermal Engineering . 216 . 119125 . 10.1016/j.applthermaleng.2022.119125 . 2022AppTE.21619125C . 251420566 . One such promising alternative is radiative cooling, which is a ubiquitous process of losing surface heat through thermal radiation. Instead of releasing waste heat into ambient air as conventional cooling systems, radiative cooling passively discharges it into outer space. . Elsevier Science Direct.
  7. Aili . Ablimit . Yin . Xiaobo . Yang . Ronggui . February 2022 . Passive sub-ambient cooling: radiative cooling versus evaporative cooling . Applied Thermal Engineering . 202 . 117909 . 10.1016/j.applthermaleng.2021.117909 . 2107.04151 . 2022AppTE.20217909A . 235790365 . Elsevier Science Direct.
  8. News: Annual Electric Generator Report . U.S. Energy Information Administration . 2018-01-01 .
  9. Thermal management of thermoelectric generators for waste energy recovery. Applied Thermal Engineering. Fernández-Yáñez. P.. 2021. 196. 117291. 10.1016/j.applthermaleng.2021.117291. 2021-09-01. free. 2021AppTE.19617291F .
  10. Web site: New Technologies' Wasted Energies. CNRS News. en. 2018-07-06.
  11. Fiala D, Lomas KJ, Stohrer M . A computer model of human thermoregulation for a wide range of environmental conditions: the passive system . J. Appl. Physiol. . 87 . 5 . 1957–72 . November 1999 . 10562642 . 10.1152/jappl.1999.87.5.1957 . 5751821 .
  12. Thermal management of thermoelectric generators for waste energy recovery. Applied Thermal Engineering. Fernández-Yáñez. P.. 2021. 196. 117291. 10.1016/j.applthermaleng.2021.117291. 2021-09-01. free. 2021AppTE.19617291F .
  13. Gunawan . A . Lin . CH . Buttry . DA . Mujica . V . Taylor . RA . Prasher . RS . Phelan . PE . 120138941 . 2013 . Liquid thermoelectrics: review of recent and limited new data of thermogalvanic cell experiments . Nanoscale Microscale Thermophys Eng . 17 . 4. 304–23 . 10.1080/15567265.2013.776149 . 2013NMTE...17..304G .
  14. Techno-economic survey of Organic Rankine Cycle (ORC) systems. Sylvain. Quoilin. Martijn Van Den. Broek. Sébastien. Declaye. Pierre. Dewallef. Vincent. Lemort. 1 June 2013. Renewable and Sustainable Energy Reviews. 22. 168–186. 7 May 2018. 10.1016/j.rser.2013.01.028. live. https://web.archive.org/web/20161003175138/http://orbi.ulg.ac.be/handle/2268/138756. 3 October 2016. free.
  15. Web site: Glossary of Meteorology . . dead . https://web.archive.org/web/20090226045247/http://amsglossary.allenpress.com/glossary/browse?s=a&p=60 . 2009-02-26 .
  16. Energy Production and Consumption . Our World in Data . 27 October 2022 . 24 March 2023. Ritchie . Hannah . Roser . Max . Rosado . Pablo .
  17. Web site: What is the Surface Area of the Earth? . Universe Today . 11 February 2017 . 24 March 2023.
  18. Web site: Heat Island Effect: Glossary. 2009. United States Environmental Protection Agency. 2009-04-06. live. https://web.archive.org/web/20090420122840/http://epa.gov/heatisland/resources/glossary.htm. 2009-04-20.
  19. 10.1002/2015GL063514 . 42 . 11 . Time scales and ratios of climate forcing due to thermal versus carbon dioxide emissions from fossil fuels . Geophysical Research Letters . 4548–4555 . Zhang . Xiaochun. 2015GeoRL..42.4548Z . 2015 . free .
  20. Flanner, M. G. . 2009 . Integrating anthropogenic heat flux with global climate models . Geophys. Res. Lett. . 36. 2 . L02801 . 10.1029/2008GL036465 . 2009GeoRL..36.2801F. 10.1.1.689.5935 . 8371380 .
  21. Impacts of anthropogenic heat on regional climate patterns . Block, A., K. Keuler, and E. Schaller . 2004 . . 31 . 12 . L12211 . 10.1029/2004GL019852 . 2004GeoRL..3112211B . live . https://web.archive.org/web/20110606064210/http://www.agu.org/pubs/crossref/2004/2004GL019852.shtml . 2011-06-06 . free .
  22. [Robert Döpel|R. Döpel]
  23. H. Arnold, "Robert Döpel and his Model of Global Warming. An Early Warning – and its Update." (2013) online. 1st ed.: "Robert Döpel und sein Modell der globalen Erwärmung. Eine frühe Warnung - und die Aktualisierung." Universitätsverlag Ilmenau 2009, .
  24. Chaisson . E. J. . 2008 . Long-Term Global Heating from Energy Usage . Eos . 89 . 28. 253–260 . 10.1029/2008eo280001 . 2008EOSTr..89..253C. free .
  25. Cowern . Nick E.B. . Ahn . Chihak . Thermal emissions and climate change: Cooler options for future energy technology . Cowern Science . November 2008 . 0811.0476 .