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Approach to rational calculation of superelevation in dual gauge track

Abstract

One of the technical possibilities to solve a gauge crossing is to install a dual gauge. This solution has several advantages and disadvantages discussed in this paper. Lack of experience of maintenance and lack of standards for the design of dual track are among the most important disadvantages. The wheel and rail interface on track curves is more difficult than in straight sections. Therefore, the subject of the present article is a geometrical parameter of dual gauge track, i.e., the rail superelevation, which has an impact on the wheel–rail interaction at curves and influences the value of uncompensated acceleration, occurring when a train passes a curve, and, consequently, the intensity of rail wear. The objective of the present article is to analyse the features of dual gauge track and the superelevation calculation methodology considered, to present the approach to rational calculation of superelevation for dual gauge track of Šeštokai–Mockava (Lithuania–Poland) using several calculation versions as well as to make recommendations for the calculation of superelevation.

Keyword : track curve, standard gauge (1435 mm), Russian gauge (1520 mm), train speed, uncompensated lateral acceleration, wheel–rail interaction, gauge crossing

How to Cite
Gailienė, I., Gedaminskas, M., & Laurinavičius, A. (2018). Approach to rational calculation of superelevation in dual gauge track. Transport, 33(3), 699-706. https://doi.org/10.3846/transport.2018.1577
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Jul 10, 2018
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