A Carnot battery is a type of energy storage system that stores electricity in thermal energy storage. During the charging process, electricity is converted into heat and kept in heat storage. During the discharging process, the stored heat is converted back into electricity.[1][2]

A simplified scheme of a typical Carnot battery system

Fritz Marguerre patented the concept of this technology 100 years ago,[3] but its development was recently revitalized, given the increased use of renewable energies and the need to increase the total recovered energy delivered from such sources. In this context, Andre Thess coined the term "Carnot battery" in 2018, prior to the first International Workshop on Carnot Batteries.[4]

The term "Carnot battery" is derived from Carnot's theorem, which describes the maximum efficiency of conversion of heat energy into mechanical energy. The word "battery" indicates that the purpose of this technology is to store electricity. The discharge efficiency of Carnot batteries is limited by the Carnot efficiency. The concept of Carnot batteries covers technologies such as pumped thermal energy storage and liquid air energy storage.[5][6]

Background

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In the transition to low-carbon energy systems, the penetration of variable renewable energy in electrical energy systems increases, and this also increases the need for energy storage. Currently, most of the new installed energy storage capacity comes from electrochemical batteries, such as lithium-ion batteries. This type of battery is suitable for short-term storage but may not be economical for longer durations due to its high energy capacity costs.[7] Thermal energy storage can store energy in inexpensive materials, such as water, rocks, and salts. Therefore, the cost for large-scale systems (e.g. gigawatt hours) can be lower than the cost of electrochemical batteries.[8]

The German Aerospace Center (DLR) and University of Stuttgart have been working on the concept of Carnot batteries that store electricity in high-temperature heat storage since 2014.[8] In 2018, the name "Carnot battery" was used at the Hannover Messe,[9] one of the world's largest trade fairs, by DLR.[8]

System configuration

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Possible energy conversion and storage technologies

A Carnot battery system can be divided into three parts: Power to Thermal (P2T), Thermal Energy Storage (TES), and Thermal to Power (T2P).

Electricity to heat technology

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Electricity can be converted into heat through the use of various technologies.[1]

  • Resistive heating
  • Heat pumps as the technology to pump heat from a lower temperature reservoir to a higher temperature. It can be divided into two groups: the reverse Rankine cycle and the reverse Brayton cycle.
    • The reverse Rankine cycle has been widely used in conventional heat pumps.
    • The concept of using the Brayton cycle for charging and discharging thermal energy was proposed by Prof. Robert B. Laughlin in 2017.[10]
  • Others: In liquid air energy storage systems, the Claude Cycle is used to liquify air. The Lamm–Honigmann process uses thermochemical cycles to convert power to heat.[11]

Thermal energy storage

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According to the mechanism to store heat, thermal energy storage can be divided into three types: sensible heat storage, latent heat storage, and thermochemical storage. The storage materials that have been used for Carnot batteries are:

Heat to electricity

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Heat can be converted into power through thermodynamic cycles, such as the Rankine cycle or Brayton cycle. Some technologies use the property of semiconductor materials to convert heat into electricity, and those are not considered a Carnot battery because there are no thermodynamic cycles involved in the conversion process, such as thermoelectric materials and the "Sun in a box".[13] The typical technologies are:

Advantages and disadvantages

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The Carnot battery is known by several other names such as Pumped Thermal Electricity Storage (PTES) or Pumped Heat Electricity Storage (PHES).[15] This relatively new technology has become one of the most promising large-scale energy storage technologies.

The main advantages of the Carnot battery are:[16]

  • Free choice of site;
  • Small environmental footprint;
  • Life expectancies of 20–30 years;
  • Optional low-cost backup capacity;
  • The components of an underutilized fossil-fueled power plant can be partially reused to build the Carnot batteries unit;

The major drawback of this technology is:[17]

  • The limited roundtrip efficiency 𝜂𝑟𝑜𝑢𝑛𝑑, which relates the electricity 𝑾𝒅𝒊𝒔 delivered during discharge to the electricity 𝑾𝒄𝒉𝒂𝒓 needed to charge the system. Carnot batteries generally aim for a 40-70% efficiency range, significantly lower than pumped-storage hydroelectricity (65-85%).[18]

Application

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Carnot batteries can be used as grid energy storage to store excess power from variable renewable energy sources and to produce electricity when needed.

Some Carnot battery systems can use the stored heat or cold for other applications, such as district heating and cooling for data centers.

Carnot batteries have been proposed as a solution to convert existing coal-fired power plants into a fossil fuel-free generation system by replacing the coal fueled boiler.[19][20] The existing facilities in power plants such as power generation systems and transmission systems can be used.

List of Carnot battery projects

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Although the term Carnot battery is new, many existing technologies can be classified as Carnot batteries.[7]

See also

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References

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  1. ^ a b Dumont, Olivier; Frate, Guido Francesco; Pillai, Aditya; Lecompte, Steven; De paepe, Michel; Lemort, Vincent (2020). "Carnot battery technology: A state-of-the-art review". Journal of Energy Storage. 32: 101756. Bibcode:2020JEnSt..3201756D. doi:10.1016/j.est.2020.101756. hdl:2268/251473. ISSN 2352-152X. S2CID 225019981.
  2. ^ "Task 36 Carnot Batteries Final Report". Technology Collaboration Programme Energy Storage, International Energy Agency. 2023. Retrieved 29 October 2024.
  3. ^ Marguerre F., « Ueber ein neues Verfahren zur Aufspeicherung elektrischer Energie. Mitteilungen der Vereinigung der Elektrizitätswerke 1924;354(55):27e35.
  4. ^ "International Workshop on Carnot Batteries".
  5. ^ "Carnot Battery Energy Storage: A more cost-effective and flexible solution for grid-scale energy storage". Rushlight Events. 30 January 2019. Retrieved 29 October 2020.
  6. ^ Steinmann, Wolf-Dieter; Jockenhöfer, Henning; Bauer, Dan (2019). "Thermodynamic Analysis of High-Temperature Carnot Battery Concepts". Energy Technology. 8 (3): 1900895. doi:10.1002/ente.201900895. ISSN 2194-4288.
  7. ^ a b Josh McTigue (4 December 2019). "'Carnot Batteries' for electricity storage" (PDF). Retrieved 29 October 2020.
  8. ^ a b c "Carnot batteries: Low-cost and location-independent energy storage in the gigawatt hour range". German Aerospace Centre (DLR). 2018.
  9. ^ "HANNOVER MESSE (industrial trade fairs), 23-27 APril, 2018".
  10. ^ Laughlin, Robert B. (2017). "Pumped thermal grid storage with heat exchange". Journal of Renewable and Sustainable Energy. 9 (4): 044103. doi:10.1063/1.4994054. ISSN 1941-7012.
  11. ^ a b c Thiele, Elisabeth; Jahnke, Anna; Ziegler, Felix (2020). "Efficiency of the Lamm–Honigmann thermochemical energy storage". Thermal Science and Engineering Progress. 19: 100606. Bibcode:2020TSEP...1900606T. doi:10.1016/j.tsep.2020.100606. ISSN 2451-9049. S2CID 225010799.
  12. ^ "World's first Carnot battery stores electricity in heat". German Energy Solutions Initiative. 20 September 2020. Retrieved 29 Oct 2020.
  13. ^ Jennifer Chu (5 December 2018). "'Sun in a box' would store renewable energy for the grid". MIT News Office. Retrieved 30 October 2020.
  14. ^ Holy, Felix; Textor, Michel; Lechner, Stefan (2021-12-01). "Gas turbine cogeneration concepts for the pressureless discharge of high temperature thermal energy storage units". Journal of Energy Storage. 44: 103283. Bibcode:2021JEnSt..4403283H. doi:10.1016/j.est.2021.103283. ISSN 2352-152X. S2CID 241770227.
  15. ^ Zhao, Yongliang; Song, Jian; Liu, Ming; Zhao, Yao; Olympios, Andreas V.; Sapin, Paul; Yan, Junjie; Markides, Christos N. (2022-03-01). "Thermo-economic assessments of pumped-thermal electricity storage systems employing sensible heat storage materials". Renewable Energy. 186: 431–456. Bibcode:2022REne..186..431Z. doi:10.1016/j.renene.2022.01.017. ISSN 0960-1481.
  16. ^ W.-D. Steinmann, D. Bauer, H. Jockenhöfer, et M. Johnson, « Pumped thermal energy storage (PTES) as smart sector-coupling technology for heat and electricity », Energy, vol. 183, p. 185‑190, sept. 2019, doi: 10.1016/j.energy.2019.06.058.
  17. ^ W. D. Steinmann, « The CHEST (Compressed Heat Energy STorage) concept for facility scale thermo mechanical energy storage », Energy, vol. 69, p. 543‑552, mai 2014, doi: 10.1016/j.energy.2014.03.049.
  18. ^ A. Koen et P. F. Antunez, « How heat can be used to store renewable energy », The Conversation. http://theconversation.com/how-heat-can-be-used-to-store-renewable-energy-130549 (consulté le févr. 27, 2020).
  19. ^ Susan Kraemer (16 April 2019). "Make Carnot Batteries with Molten Salt Thermal Energy Storage in ex-Coal Plants". SolarPACES.
  20. ^ "Webinar on Carnot Batteries" (PDF). ATA insights. April 2019. Retrieved 29 October 2020.
  21. ^ Olivier Dumont; Vincent Lemort (September 2020). "First Experimental Results of a Thermally Integrated Carnot Battery Using a Reversible Heat Pump / Organic Rankine Cycle". Conference: 2nd International Workshop on Carnot Batteries 2020. Retrieved 29 October 2020.
  22. ^ "project website". TU Berlin. Archived from the original on 15 April 2021. Retrieved 15 April 2021.
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