Experimental monitoring and numerical modeling of the thermal regime of selected track substructures

Ižvolt, Libor; Dobeš, Peter; Hodas, Stanislav

doi:10.20858/tp.2019.14.4.8

Artykuł - szczegóły

Tytuł artykułu

Experimental monitoring and numerical modeling of the thermal regime of selected track substructures

Autorzy

Ižvolt Libor , Dobeš Peter , Hodas Stanislav

Treść / Zawartość

Pełne teksty:

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Identyfikatory

DOI

10.20858/tp.2019.14.4.8

Warianty tytułu

Języki publikacji

Abstrakty

The initial part of the paper characterizes major research activities at the Department of Railway Engineering and Track Management (DRETM), Faculty of Civil Engineering, University of Žilina. Subsequently, it outlines the state of art in the field of track substructure dimensioning for the non-traffic load in Slovakia and abroad. The second part of the paper deals with the method of collecting input parameters for numerical modeling of the track substructure freezing using SoilVision software. The following part of the paper compares the results of the track substructure freezing obtained by experimental measurements and numerical modeling in the winter of 2016/2017. The final part of the paper focuses on the results of numerical modeling of the track substructure freezing in terms of the climatic conditions typical of railway infrastructure in the Slovak territory. Moreover, it presents a design of a modified nomogram for determination of the necessary thickness of the frost-susceptible subgrade surface layer and characterizes further related research activities planned to be implemented at the Department in the near future.

Słowa kluczowe

railway track non-traffic load substructure dimensioning numerical modelling

wagon kolejowy obciążenie inne niż ruch drogowy podkonstrukcja wymiarowanie modelowanie numeryczne

Wydawca

Wydawnictwo Politechniki Śląskiej

Czasopismo

Transport Problems

Rocznik

2019

Tom

T. 14, z. 4

Strony

89--100

Opis fizyczny

Bibliogr. 18 poz.

Twórcy

autor

Ižvolt Libor

izvolt@fstav.uniza.sk

University of Žilina, Faculty of Civil Engineering, Univerzitná 8215/1, 010 26 Žilina, Slovak Republic

autor

Dobeš Peter

dobes@fstav.uniza.sk

University of Žilina, Faculty of Civil Engineering, Univerzitná 8215/1, 010 26 Žilina, Slovak Republic

autor

Hodas Stanislav

hodas@fstav.uniza.sk

University of Žilina, Faculty of Civil Engineering, Univerzitná 8215/1, 010 26 Žilina, Slovak Republic

Bibliografia

1. TNŽ 736312, The design of structural layers of subgrade structures (in Slovak). GR ŽSR. Slovakia, 2005. 54 p.
2. Tam, A. Permafrost in Canada's Subarctic Region of Northern Ontario. University of Toronto. 2009.
3. Soliman, H. & Kass, S. & Fleury, N. A Simplified Model to Predict Frost Penetration for Manitoba Soils. Annual Conference of the Transportation Association of Canada Toronto. Ontario, 2008.
4. Newmann, G.P. Heat and mass transfer in unsaturated soils during freezing. M. Sc Thesis. University of Saskatchewan. Canada, 1995.
5. Pentland, J.S. Use of a general partial differential equation solver for solution of heat and mass transfer problems in soils. University of Saskatchewan. Canada, 2000.
6. Higashi, A. Experimental study of frost heaving. Highway Research Abstr. 2/1960.
7. Profillidis, V.A. Railway Management and Engineering. Third edition. England. 2006. 198 p. ISBN 0-7546-4854-0.
8. Skaven-Haug, Sv. The design of frost foundations, frost heat, and soil heat. Norwegian Geotek. Institut. Publication No. 90. Oslo 1971.
9. Farbot, H. & Isaksen, K. & Etzelmüller, B. & Gisnĺs, K. Ground Thermal Regime and Permafrost Distribution under a Changing Climate in Northern Norway. In: Permafrost and Periglacial Processes. Vol. 24. No. 1. 2013. P. 20-38.
10. Sussmann, T.R. & Hyslip, J.P. Track Substructure Design Methodology and Data. In: Proceedings of the ASME Joint Rail Conference. Illinois, USA, 2010.
11. Grodiecki, W. In situ experiments on frost penetration in soils. Rails of the world. 1978. Vol. 6.
12. ORE-Frage D117. Optimal adaptation of the classic superstructure to future traffic. Report No. 15. The effect of frost on the substructure of railway lines and antifreeze measures. 1980.
13. ORE-Frage D117. Optimal adaptation of the classic superstructure to future traffic. Report No. 22, Frost effect on the railway substructure; Frost protection with thermal insulation layers. ORE Utrecht. 1981.
14. Ižvolt, L. & Dobeš, P. & Pitoňák, M. Some experimence and preliminary conclusions from the experimental monitoring of the temperature régime of a subgrade structure. In: COMPRAIL XIV. International Conference on Design and Operation in Railway Engineering. Roma, 24.-26.06.2014. WITPress Southampton, Boston. 2014. P. 267-278. ISSN 1743-4498, ISBN 978-1-84564-766-7.
15. Ižvolt, L. & Dobeš, P. & Pultznerová, A. Monitoring of moisture changes in the construction layers of the railway substructure body and its subgrade. In: Procedia Engineering. 2016. Vol. 161. P. 1049-1056. ISSN 1877-7058.
16. Ižvolt, L. & Dobeš, P. & Mečár, M. Contribution to the methodology of the determination of the thermal conductivity coefficients λ of materials applied in the railway subbase structure. In: Communications: scientific letters of the University of Žilina. 2013. Vol. 15. No. 4. P. 9-17. ISSN 1335-4205.
17. Fredlund, M. SOILVISION, A Knowledge-Based Soils Database. User's Manual. Saskatoon. Saskatchewan, Canada 2011.
18. Thode, R. SVHEAT, 2D/3D Geothermal Modeling Software. Tutorial Manual. Saskatoon, Saskatchewan, Canada 2012. 88 p.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-31e5fece-832a-4f2e-84f5-0f5bbb122a1b