Study of the influence of surface reinforcement on the bearing capacity of ice
DOI:
https://doi.org/10.7242/1999-6691/2019.12.1.9Keywords:
surface reinforcement, composite material, ice beam, model experiment, numerical studyAbstract
Practical experience shows that the physical and mechanical properties of the ice cover are unreliable and can strongly depend on various external factors (the presence of snow and wind at the time of freezing, the ambient temperature), if it is reinforced by traditional methods. In this connection, the problem of increasing the bearing capacity of ice by alternative methods, e.g. by introducing reinforcing elements into the ice, is an urgent problem today. The aim of this work is to determine the effect of various reinforcing materials on the carrying capacity of the ice cover. First, a comparison was made between the results of experimental and numerical studies obtained for the maximum deflections and the carrying capacity of ice samples strengthened with steel reinforcement according to the proposed scheme. Secondly, numerical investigation of the strength of ice upon reinforcement with various composite materials was performed. Experiments on strengthening ice samples with A400 steel reinforcement were carried out on a setup specially designed for simulating pure bending conditions. The destruction of the ice cover occurs under the action of pure bending when the vehicle is moving along it. In numerical experiments, the samples were reinforced with surface reinforcing frames with different physical and mechanical properties. Numerical calculations of the stress-strain characteristics of the ice cover were performed in terms of the physically nonlinear deformation model using the FE software package. The paper gives a qualitative and quantitative assessment of the effectiveness of the use of various composite materials as reinforcing elements. It is shown that the application of reinforcing materials to strengthen the ice cover significantly increases its bearing capacity.
Downloads
References
Voytkovskiy K.F. Mekhanicheskiye svoystva l’da [Mechanical properties of ice]. Moscow, Izd-vo AN SSSR, 1960. 99 p.
Bychkovskiy N.N., Gur’yanovA. Ledovyye stroitel’nyye ploshchadki, dorogi i perepravy [Ice construction sites, roads and ferries]. Saratov, Saratovskiy gosudarstvennyy tekhnicheskiy universitet, 2005. 180 p.
Qi C., Lian J., Ouyang Q., Zhao X. Dynamic compressive strength and failure of natural lake ice under moderate strain rates at near melting point temperature. Am. J. Solids Struct., 2017, vol. 14, pp. 1669-1694. http://dx.doi.org/10.1590/1679-78253907">DOI
Prokudin A.N., Odinokov V.I. Numerical modeling of the destruction of ice cover taking into account compressibility and inhomogeneity. mekh. splosh. sred – Computational Continuum Mechanics, 2013, vol. 6, no. 1, pp. 110-118. http://dx.doi.org/10.7242/1999-6691/2013.6.1.14">DOI
Goldstein R.V., Osipenko N.M. Some aspects of strength in sea ice mechanics. Mesomech., 2015, vol. 18, pp. 139-148. https://doi.org/10.1134/S102995991502006X">DOI
Schulson E.M. Low-speed friction and brittle compressive failure of ice: fundamental processes in ice mechanics. Mater. Rev., 2015, vol. 60, pp. 451-478. https://doi.org/10.1179/1743280415Y.0000000010">DOI
Weiss J., Dansereau V. Linking scales in sea ice mechanics. Trans. R. Soc. A, 2017, vol. 375, 20150352. http://dx.doi.org/10.1098/rsta.2015.0352">DOI
Yakimenko O.V., Sirotyuk V.V. Usileniye ledovykh pereprav geosinteticheskimi materialami [Strengthening of ice crossings by geosynthetic materials]. Omsk, SibADI, 2015. 168 p.
Buznik V.M., Landik D.N., Erasov V.S., Nuzhnyi G.A., Cherepanin R.N., Novikov M.M., Goncharova G.Y., Razomasov N.D., Razomasova T.S., Ustyugova T.G. Physical and mechanical properties of composite materials on the basis of an ice matrix. Mater. Appl. Res., 2017, vol. 8, pp. 618-625. https://doi.org/10.1134/S2075113317040050">DOI
Cherepanin R.N., Nuzhnyi G.A., Razomasov N.A., Goncharova G.Yu., Buznik V.M. Physicomechanical properties of glacial composite materials reinforced by Rusar-S fibers. Mater. Appl. Res., 2018, vol. 9, pp. 114-120. https://doi.org/10.1134/S2075113318010082">DOI
Kozin V.M., Zemlyak V.L., Pogorelova A.V., Matyushina A.A., Rogozhnikova E.G., Kandelya M.V., Baurin N.O., Nikolayev S.V. RF Patent No. 2622967, Byull. Izobret., 22 April 2016.
Lavrov V.V. Deformatsiya i prochnost’ l’da [Ice deformation and strength]. Leningrad, Gidrometeoizdat, 1969. 206 p.
Ipatov K.I., Zemliak V.L., Kozin V.M., Vasiliev A.S. The research of stress-strain state of ice cover from the impact of a moving load. Vestnik PGU im. Sholom-Aleykhema, 2017, no. 1(26), pp. 103-113.
Willam K.J., Warnke E.P. Constitutive model for the triaxial behavior of concrete. IABSE reports of the working commissions, 1974, vol. 19. http://doi.org/10.5169/seals-17526">DOI
Klovanich S.F., Bezushko D.I. Metod konechnykh elementov v raschetakh prostranstvennykh zhelezobetonnykh konstruktsiy [The finite element method in calculations for spatial reinforced concrete constructions]. Odessa, Izd-vo ONMU, 2009. 89 p.
Bazant Z.P., Cedolin L. Fracture mechanics of reinforced concrete. ASCE J. Eng. Mech. Div., 1980, vol. 106(6), pp. 1287-1306.
Downloads
Published
Issue
Section
License
Copyright (c) 2019 Computational Continuum Mechanics
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.