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420 kV shunt reactors for reactive power compensation explaining the trends favoring air-core dry-type technology

  • CIGRE 2022
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References

  1. de Kwant C et al (2021) The role of product design in circular business models: an analysis of challenges and opportunities for electric vehicles and white goods. Sustain Prod Consum 27:1728–1742

    Article  Google Scholar 

  2. H. Desing “Product and Service Design for a Sustainable Circular Economy.” (Doctoral dissertation, ETH Zurich, 2021)

  3. Working Group A2.48 CIGRE (2016) Technology and utilisation of oil-immersed shunt reactors (TB 655, May 2016)

    Google Scholar 

  4. F. Javernik, “Grundsatzuntersuchung über die Blindleistungskompensation im österreichischen Übertragungsnetz” (Masterthesis Graz University of Technology, 11-2013)

  5. ELES www.sincrogrid.eu/en. Accessed 20 Dec 2021

  6. IEEE C57.21 (2021) IEEE standard requirements, terminology, and test code for shunt reactors rated over 500 kVA

    Google Scholar 

  7. Working Group B5.37 CIGRE (2013) Protection, monitoring and control of shunt reactors (TB 546, August 2013)

    Google Scholar 

  8. IEC 60076‑6, “Power transformers—Part6: Reactors” (Edition 1.0, 12-2007)

  9. Gaun A et al (2019) Loss optimized design of air-core reactors. B4 International Colloquium, Johannesburg (Paper B4-022)

    Google Scholar 

  10. IEC 60076-10, “Power transformers—Part10: Determination of sound levels” (Edition 2.0, 03-2016)

  11. ISO 3744, “Acoustics—Determination of sound power levels and sound energy levels of noise sources using sound pressure—Engineering methods for an essentially free field over a reflecting plane” (Third edition 2010-10-01)

  12. P. Ebner, „Erdungssysteme und Fundamentbewehrungen im Nahbereich von Luftdrosselspulen“ (Masterthesis Graz University of Technology, 05-2021)

  13. Grisenti A et al (2017) Air-core dry-type reactors for electric power systems—design considerations for high current connections (Cigre Winnipeg B4-138, 10-2017)

    Google Scholar 

Download references

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Authors and Affiliations

  1. Coil Innovation GmbH, Nikola-Tesla-Straße 1, 4070, Eferding, Austria

    Alexander Gaun, Alex Grisenti, Bernhard Fröhlich & Christian Niederauer

Authors
  1. Alexander Gaun
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  2. Alex Grisenti
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  3. Bernhard Fröhlich
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  4. Christian Niederauer
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Correspondence to Alexander Gaun.

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Paper submitted for the CIGRE Session 2022, SC-A2, August 28–September 2, 2022

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Gaun, A., Grisenti, A., Fröhlich, B. et al. 420 kV shunt reactors for reactive power compensation explaining the trends favoring air-core dry-type technology. Elektrotech. Inftech. 140, 144–152 (2023). https://doi.org/10.1007/s00502-022-01091-4

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  • DOI: https://doi.org/10.1007/s00502-022-01091-4

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