Available online at www.sciencedirect.com ScienceDirect Procedia Engineering 111 (2015 ) 709 716 XXIV R-S-P seminar, Theoretical Foundation of Civil Engineering (24RSP) (TFoCE 2015) Evaluation of track design and track geometry of the track with unconventional structure of railway superstructure Janka Šestáková a, Martin Mečár b * a Department of Railway Engineering, Faculty of Civil Engineering, University of Žilina, Univerzitná 8215/1, SK 010 26 Žilina, Slovak Republic b Department of Railway Engineering, Faculty of Civil Engineering, University of Žilina, Univerzitná 8215/1, SK 010 26 Žilina, Slovak Republic Abstract Department of Railway Engineering realizes monitoring of the experimental section with various constructions of the railway superstructure; experimental section consist of the standard structure of railway superstructure on earthworks and in the concrete channel and slab track structure in tunnel, on bridges and on earthworks. Diagnostics is comprehensively focused on the quality of effective position of the track, structural and geometric structure of the track and on the quality of the elements of the superstructure. Relevant design and geometrical parameters of the track are the track alignment, track top, gauge, superelevation and twist. The paper presents the results of diagnostics and graphical overview of the development of quality parameters. 2015 The Authors. Published by Elsevier B.V. 2015 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license Peer-review (http://creativecommons.org/licenses/by-nc-nd/4.0/). under responsibility of organizing committee of the XXIV R-S-P seminar, Theoretical Foundation of Civil Engineering Peer-review under (24RSP) responsibility of organizing committee of the XXIV R-S-P seminar, Theoretical Foundation of Civil Engineering (24RSP) Keywords: Railway; Slab Track; Track Geometry; Quality. 1. Introduction Railway track quality with increasing time of operation deteriorates. Operational (traffic, repair and maintenance works, etc.) and climate load impacts are reflected by permanent changes in geometric parameters and material characteristics of construction and its elements. These changes may significantly affect safety and flow of traffic. It is necessary to identify the source and progress of changes to optimize minimization and removing these changes in process of repair and maintenance works. * Corresponding author. Tel.: +421-41-513 58 07; fax: +421-41-513 55 10. E-mail address: janka.sestakova@fstav.uniza.sk 1877-7058 2015 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of organizing committee of the XXIV R-S-P seminar, Theoretical Foundation of Civil Engineering (24RSP) doi:10.1016/j.proeng.2015.07.136
710 Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 2. Experimental sections Track section with unconventional construction of railway superstructure called slab track (ST), was put in operation in July 2012 (track No. 2) and in October 2012 (Track No. 1). Track section is part of double-track modernized railway track Nove Mesto nad Vahom Puchov and is situated in the tunnel Turecky vrch and around its portals. Railway superstructure of experimental sections is built as standard structure with ballast bed, construction with improved ballast placed in concrete trough (transition sector) and slab track construction RHEDA 2000 (in the tunnel, on the bridges and on the earthworks). Designed track speed is 160 km/h (velocity zone RP4), gauge is 1 435 mm [1]. Monitoring of experimental section is focused on quality of railway track in transition sections between standard structure of railway superstructure with ballast bed and slab track construction and is carried out as: monitoring of track alignment design and track geometry: comprehensive diagnostics (continuous method); measuring trolley KRAB TM Light recording alignment of rail string SP, SL (mm), gauge RK (mm), change of gauge ZR (mm/m), rail top level of rail string VP, VL (mm), superelevation PK (mm), quasi-twist on a short base ZK (mm/m), supervisory monitoring of track alignment design: a partial diagnostics of track alignment design and track geometry realized by gauge-checker focused on gauge (RK) and superelevation (PK), monitoring of effective position of the track related to track geometry marks [2]. There are presented outputs of comprehensive diagnostics carried out by continuous method in the paper. The diagnostics is realized and assessed according to [3] and [4] for railway tracks of track speed between 120 km/h and 160 km/h (including), i. e. for velocity zone RP4. Limit values of standard in tables 1 and 2 specifies [3]. Experimental sections are located in tracks No. 1 and No. 2 near south portal of tunnel Turecky vrch (sections 1.1 and 2.1), each of length 175 m (km 102.360 000 km 102.535 000) in tracks No. 1 and No. 2 near north portal of tunnel Turecky vrch (sections 2.1 and 2.2), each of length 640 m, (km 104.200 000 km 104.840 000) [5, 6]. 3. Realized measurements Comprehensive diagnostics of track alignment design and track geometry on experimental sections 1.1 and 1.2 has been carried out: 3.10.2012 measurement before putting sections into operation (MSO), 9.4.2013 the first operational measurement (PO1), 8.10.2013 the second operational measurement (PO2), 27.5.2014 the third operational measurement (PO3), 29.10.2014 the fourth operational measurement (PO4) and 17.4.2015 the fifth operational measurement (PO5) and on experimental sections 2.1 and 2.2 10.7.2012 (MSO), 22.4.2013 (PO1), 22.10.2013 (PO2), 28.5.2014 (PO3), 29.10.2014 (PO4) and 25.3.2015 (PO5). Measured of superelevation (PK) compared to designed values and of gauge (RK) compared to standard nominal value 1435 mm are shown on fig. 1 to fig. 8. Values were recorded by carried out by continuously measuring trolley KRAB TM Light and involves quasi-static and dynamic factors of each parameter. These parameters were chosen as the most suitable for the presentation of the progress of quality of railway track by continuous method. Assessment of measurements, which includes above parameters and assessment of all parameters according to part 2 is completely presented by L. Ižvolt and M. Šmalo in the paper Assessment of the Track Geometry Quality from the Aspect of Safe and Reliable Operation of the Railway Track. Comprehensive assessment includes also assessment of alignment of rail string (SP, SL) and rail top level of rail string (VP, VL) of experimental sections, change of gauge (ZR) and quasi-twist on a short base (ZK). Assessment is focused on local errors evaluation and evaluation of each experimental section. Maximal and minimal values of of superelevation (PK) and gauge (RK) of each measurement carried out by comprehensive diagnostics relating to (maximal input MSO, operational and maximal operational PO1 to PO5) are in tables 1 and 2 briefly shown.
Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 711 Fig. 1. Tolerances of Superelevation Track No. 1, Section No. 1. Fig. 2. Tolerances of Gauge Track No. 1, Section No. 1.
712 Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 Fig. 3. Tolerances of Superelevation Track No. 1, Section No. 2. Fig. 4. Tolerances of Gauge Track No. 1, Section No. 2.
Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 713 Fig. 5. Tolerances of Superelevation Track No. 2, Section No. 1. Fig. 6. Tolerances of Gauge Track No. 2, Section No. 1.
714 Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 Fig. 7. Tolerances of Superelevation Track No. 2, Section No. 2. Fig. 8. Tolerances of Gauge Track No. 2, Section No. 2.
Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 715 Table 1. Summary of Limit Deviations of Superelevation (6 Measurement Cycles). Track.Section 1.1 1.2 2.1 2.2 Maximal input MSO Operational Maximal operational PO1 (mm) PO2 PO3 PO4 PO5 min -3-1.18-6 -8-3.42-3.21-3.18-2.30-2.82 max 3 2.24 6 8 0.54 1.94 0.91 3.52 1.03 min -3-2.36-6 -8-2.42-1.64-5.59-1.53-1.83 max 3 2.85 6 8 1.91 2.83 1.16 3.72 3.27 min -3-1.61-6 -8-3.02-2.68-2.75-2.47-2.93 max 3 0.59 6 8 1.76 0.84 0.45 2.75 1.86 min -3-4.00-6 -8-3.43-3.27-3.12-2.79-2.97 max 3 2.77 6 8 1.44 2.53 2.71 3.19 2.06 Table 2.. Summary of Limit Deviations of Gauge (6 Measurement Cycles). Track.Section 1.1 1.2 2.1 2.2 Maximal input MSO Operational Maximal operational PO1 (mm) PO2 PO3 PO4 PO5 min -2 0.11-3 -5 0.05-0.36-0.32 0.10-0.20 max 2 2.76 5 10 2.98 2.87 2.88 3.04 2.99 min -2-1.31-3 -5-1.23-1.40-1.41-1.29-1.38 max 2 2.11 5 10 2.23 2.17 2.12 2.23 2.15 min -2-0.03-3 -5 0.36 0.24-0.04 0.33 0.02 max 2 3.30 5 10 3.32 3.08 2.91 3.20 3.01 min -2-2.01-3 -5-1.36-1.43-1.62-1.38-1.34 max 2 3.32 5 10 3.36 3.15 2.89 3.08 3.12 4. Conclusions From the presented outputs of a comprehensive diagnostics of track alignment design and track geometry of the track it is clear that geometric parameters superelevation (PK) and gauge (RK) after putting track into operation complied with the prescribed. Measurement before putting sections into operation shows errors of PK and also RK parameters, but these errors were repaired before starting operation. Significantly different from the trend of results is the third operational measurement PO3 parameter PK in track No. 1 and section No. 2. At the time of measurement were rail heads in the section very dirty and this fact affected results obtained from the measuring trolley. Therefore, measurement results PO3 of parameter PK in this section will not be classified to the summary assessment. Acknowledgements There are partial results of the grant VEGA 1/0597/14 Analysis of methods used to measure the unconventional railway track construction from the point of view of accuracy and reliability" in the paper.
716 Janka Šestáková and Martin Mečár / Procedia Engineering 111 (2015 ) 709 716 References [1] L. Ižvolt, M. Šmalo, Historical Development and Applications of Unconventional Structure of Railway Superstructure of the Railway Infrastructure of the Slovak Republic, in: Civil and Environmental Engineering. Scientific - Technical Journal, Volume 10, Issue 1 (2014), EDIS University of Žilina, 2014, pp. 79 94, ISSN (Online) 1336-5835. [2] J. Ižvoltová, A. Villim, P. Pisca, Analysis of Height Changes of Ballast-Less Track. in: Geodézia, kartografia a geografické informačné systémy [electronic source], VIII. scientific-professional international conference. Proceedings. Tatranské Matliare,. Košice Technical University, 2014, ISBN 978-80-553-1781-6. [3] STN 73 6360 (1999) Track alignment design and track geometry of normal-gauge tracks (in Slovak), SUTN Bratislava and Amendment 1 (2002), SUTN Bratislava. [4] ZSR SR 103-7 (S) Measurement and Evaluation of Track Geometry by Measuring Trolley KRAB (in Slovak), GR ZSR, 2008. [5] L. Ižvolt, M. Šmalo, Methods of Evaluation of Railway Track Quality around Portals of Newly Built Tunnel Turecky vrch. in: Research forum. Structural aid of EU for research and inovations, 22. - 23.4.2015, Grand hotel Permon, Vysoké Tatry. Výskumné centrum Žilinskej univerzity v Žiline, 2015. ISBN 978-80-554-0973-3. pp. 42-48. [5] L. Ižvolt, Monitoring of Sections of Non-conventional Constructions of the Railway Superstructure and the Transition Areas - 5th and 6th Stage. ZSR Modernization of Railway Track Nove Mesto nad Vahom Puchov, km 100.500 to 159.100, part 24-32-01 Nove Mesto Trencianske Bohuslavice (in Slovak), Zilina: KZSTH: SvF: University of Zilina, 12/2014.