The strengths and shortcomings of mathematical models of Makkonen and Lozowski to estimate the parameters of ice formation on an overhead power line are analyzed. The models are compared with a model of monitoring the intensity of ice formation that is currently undergoing tests on the PJSC IDGC Yuga networks. A conclusion is drawn regarding the necessity of conducting additional comprehensive research.
Similar content being viewed by others
References
E. I. Satsuk, Programmatic and Technical Facilities for Monitoring Electric Power Lines and Power Supply System Management in Extreme Weather Conditions [in Russian], Novocherkassk (2011).
E. P. Lozowski, J. R. Stallabrass, and P. F. Hearty, “The icing of an unheated, nonrotating, cylinder. Part I: a simulation model,” J. Clim. Appl. Meteorol., 22(12), 2053 – 2062 (1983).
E. P. Lozowski, J. R. Stallabrass, and P. F. Hearty, “The icing of an unheated, nonrotating, cylinder. Part II: icing wind tunnel experiments,” J. Clim. Appl. Meteorol., 22(12), 2063 – 2074 (1983).
L. Makkonen, “Estimating intensity of atmospheric ice accretion on stationary structures,” J. Appl. Meteorol., 20(5), 595 – 600 (1981).
L. Makkonen, ” Modeling of ice accretion on wires,” J. Clim. Appl. Meteorol., 23(6), 929 – 939 (1984).
L. Makkonen, T. Laasko, M. Marjaniemi, and K. J. Finstad, “Modelling and prevention of ice accretion on wind turbines” Wind Eng., 25(1), 3 – 21 (2001).
I. Langmuir and K. B. Blodgett, “A mathematical investigation of water droplet trajectories,” in: Collected Works of Irving Langmuir. Vol. 10, Pergamon Press, Oxford (1946), pp. 335 – 393.
K. J. Finstad, E. P. Lozowski, and L. Makkonen, “On the median volume diameter approximation for droplet collision efficiency,” J. Atmos. Sci., 45(24), 4008 – 4012 (1988).
I. I. Levchenko et al., Diagnostics, Reconstruction, and Operation of Overhead Electric Power Lines in Ice Formation Areas: Textbook [in Russian], Izd. dom MÉI, Moscow (2007).
A. F. Dyakov (ed.), Electrical Grids of Extrahigh and Ultrahigh Voltage of the UES in Russia. Theoretical and Practical Bases [in Russian], Izd. NTF Énergoprogress, Moscow (2012).
A. A. Leshchenko and Ya. V. Nazim, “Upgrading methods of determining ice formation loads on overhead overhead electric power lines,” Metall. Konstr., 18(4), 267 – 279 (2012).
D. E. Titov, G. G. Ugarov, and A. G. Soshinov, “Monitoring the intensity of ice formation on overhead electric power lines and contact networks,” Power Technol. Eng., 49(1), 78 – 82 (2015).
D. E. Titov, Monitoring the Intensity of Ice Formation on Overhead Electric Power Lines and Contact Networks: Diss. Cand. Tech. Sci. [in Russian], Saratov (2014).
D. E. Titov, G. G. Ugarov, and A. G. Soshinov, “Monitoring the intensity of ice formation on overhead electric power lines and contact networks,” Élektr. Stantsii, No. 11, 42 – 46 (2014).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Élektricheskie Stantsii, No. 2, February 2017, pp. 29 – 36.
Rights and permissions
About this article
Cite this article
Titov, D.E., Ugarov, G.G. & Ustinov, A.A. Analysis of Application of Models to Assess Parameters of Ice Formation on Overhead Electric Power Lines. Power Technol Eng 51, 240–246 (2017). https://doi.org/10.1007/s10749-017-0817-9
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10749-017-0817-9