Proposal of a Key Performance Indicator for Railway Track Based on LCC and RAMS Analyses
Publication: Journal of Construction Engineering and Management
Volume 144, Issue 2
Abstract
The performance of railway tracks can be assessed by separately applying different approaches, such as reliability, availability, maintainability, and safety (RAMS) and lifecycle costing (LCC). Results of these approaches are not comprehensive because RAMS management lacks an LCC perspective and balance, whereas LCC develops an economic analysis but does not address specific issues of railway performance. Based on these considerations, this study defines a key performance indicator (KPI) for railway tracks as merging the LCC and RAMS approaches at a given time. Innovative algorithms are set up for LCC, RAMS, and their relationship in the definition of KPI. Algorithms are applied to two different track alternatives (ballasted and ballastless), and the KPI trend over time is assessed. Case study results show that the KPI of ballasted tracks is higher in the short-term, whereas the slab track performs better in the long-term. The trend of KPI for the two solutions under investigation shows that the breakeven point depends on traffic and speed in the railway lines. The method setup as well the results obtained contribute to the body of knowledge of construction engineering because: (1) the equations set up allow deriving agency-based algorithms through calibration; (2) the model set up and implemented allows agencies to handle basic technical instances (e.g., RAMS) and lifecycle-related issues (in which sustainability is considered) in a synergistic and quantitative way; and (3) the previously mentioned KPI has the potential to quantitatively affect decision making across the entire cycle of life (design, maintenance, and renewal).
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Data Availability Statement
All data generated or analyzed during the study are included in the published paper. Information about the Journal’s data sharing policy can be found here: http://ascelibrary.org/doi/10.1061/%28ASCE%29CO.1943-7862.0001263.
References
Ahrén, T., and Parida, A. (2009). “Overall railway infrastructure effectiveness (ORIE): A case study on the Swedish rail network.” J. Q. Maint. Eng., 15(1), 17–30.
Andrés, A., Gómez, M., and Gutiérrez, L. (2015). “Work package 1.1 under sub-project1 (SP1) of the capacity4rail (C4R) project.” ⟨http://www.capacity4rail.eu/IMG/pdf/c4r_-_d111_-_design_requirements_and_improved_guidelines_v1.1_-_public-2.pdf⟩ (Feb. 20, 2014).
BSI (British Standards Institution). (2014). “Reliability of systems, equipment and components. Guide to reliability and maintainability.” BS 5760-0:2014, London.
Bull, J. W. (2015). Life cycle costing: For the analysis, management and maintenance of civil engineering infrastructure, Whittles Publishing, Dunbeath, U.K., 224.
Calvo, F., de Ona, J., Lopez, G., Garach, L., and de Ona, R. (2013). “Rail track costs management for efficient railway charges.” Proc. Inst. Civ. Eng. Transp., 166(6), 325–335.
CENELEC (European Committee for Electrotechnical Standardization). (1999). “Railway applications—The specification and demonstration of reliability, availability, maintainability and safety (RAMS). Part 1: Basic requirements and generic process.” EN 50126-1, Brussels, Belgium.
Dingler, M. H., Lai, Y.-C., and Barkan, C. P. L. (2011). “Economics of expanding capacity on a single track heavy haul railway line.” Proc., 11th Int. Heavy Haul Railway Conf., International Heavy Haul Association, Virginia Beach, VA.
Esveld, C. (2001). Modern railway track, 2nd Ed., Delft Univ. of Technology, Delft, Netherlands.
European Commission. (2011). “WHITE PAPER Roadmap to a single European transport area—Towards a competitive and resource efficient transport system.” Brussels, Belgium.
Gautier, P. E. (2015). “Slab track: Review of existing systems and optimization potentials including very high speed.” Constr. Build. Mater., 92(2015), 9–15.
Giunta, M. (2016). “Assessment of the sustainability of traditional and innovative rail track system.” Proc., Int. Conf. on Traffic and Transport Engineering, City Net Scientific Research Center, Ltd., Belgrade, Serbia.
Giunta, M., and Praticò, F. G. (2017). “Design and maintenance of high-speed rail tracks: A comparison between ballasted and ballast-less solutions based on life cycle cost analysis.” Proc., Int. Congress on Transport Infrastructure and System, Taylor & Francis, London.
González-Arechavala, Y., Rodríguez-Mondéjar, J. A., and Latorre-Lario, G. (2010). “The opportunity to improve software RAMS.” WIT Transactions on state-of-the-art in science and engineering, Vol. 46, WIT Press, Ashurst, U.K., 12.
He, Q., Li, H., Bhattacharjya, D., Parikh, D. P., and Hampapur, A. (2015). “Track geometry defect rectification based on track deterioration modelling and derailment risk assessment.” J. Oper. Res. Soc., 66(3), 392–404.
Ian, W. H., Parry, I. W. H., and Timilsina, G. R. (2009). Pricing externalities from passenger transportation in Mexico City, The World Bank, Washington, DC.
INNOTRACK (Innovative Track System). (2006). “Guideline for LCC and RAMS analysis.”, Publications Office of the European Union EU Bookshop and CORDIS Unit, Luxembourg.
ISO. (2008). “Buildings and constructed assets—Service-life planning—Part 5: Life-cycle costing.” ISO 15686-5:2008, Geneva.
Lai, Y.-C, and Barkan, C. P. L. (2009). “Enhanced parametric railway capacity evaluation tool.” Transp. Res. Rec., 2117(-1), 33–40.
Liyin, S., Yuzhe, W., and Xiaoling, Z. (2011). “Key assessment indicators for the sustainability of infrastructure projects.” J. Constr. Eng. Manage., 441–451.
Lovett, A. H., Dick, C. T., Ruppert, C. J., Jr., and Barkan, C. P. L. (2015). “Cost and delay of railroad timber and concrete crosstie maintenance and replacement.” Transp. Res. Rec., 2476, 37–44.
Milford, R. L., and Allwood, J. M. (2010). “Assessing the CO2 impact of current and future rail track in the UK.” Transp. Res. Part D, 15(2), 61–72.
Military Handbook. (1991). “Reliability prediction of electronic equipment.” MIL-HDBK-217F 1991, U.S. Dept. of Defence, Washington, DC.
MoD (Ministry of Defence). (2012). “‘Reliability and Maintainability (R&M)’ Part No. 1: Management responsibilities and requirements for programmes and plans.” Def Stan 00-40 2012, Glasgow, Scotland.
Patra, A. (2007). RAMS and LCC in rail track maintenance, Luleå Univ. of Technology, Luleå, Sweden, 37–71.
Praticò, F. G. (2017). “A few dilemmas pertaining transportation infrastructures and their sustainability.” Sustainability Issues in Civil Engineering, SivakumarBabu, G., Saride, S., and Basha, B., eds., Springer, Singapore.
Praticò, F. G., and Giunta, M. (2016a). “Assessing the sustainability of design and maintenance strategies for rail track by means life cycle cost analysis.” Proc., COMPRAIL 2016 15th Int. Conf. on Railway Engineering design and operation, Vol. 162, WIT Press, Ashurst, U.K., 251–262.
Praticò, F. G., and Giunta, M. (2016b). “Issues and perspectives in railway management from a sustainability standpoint.” Proc., Int. Conf. on Transportation Infrastructure and Materials, DESTech Publications, Lancaster, PA, 479–486.
Profillidis, V. A. (2014). Railway engineering, 4th Ed., Ashgate Publishing, Abingdon, U.K.
RSAC (Railroad Safety Advisory Committee). (1999). Implementation of positive train control systems, Washington, DC.
Sadeghi, J., and Askarinejad, H. (2010). “Development of improved railway track degradation models.” Structure and infrastructure engineering: Maintenance, management, life-cycle design and performance, Vol. 6, Taylor & Francis, London, 675–688.
Schafer, D. H., and Barkan, C. P. L. (2008). “A prediction model for broken rails and an analysis of thier economic impact.” Proc., American Railway Engineering and Maintenance-of-Way Association Annual Conf., AREMA, Lanham, MD.
Schlake, B. W., Barkan, C. P. L., and Edwards, J. R. (2011). “Train delay and economic impact of in-service failures of railroad rolling stock.” Transp. Res. Rec., 2261, 124–133.
Silavong, C., Guiraud, L., and Brunel, J. (2014). “Estimating the marginal cost of operation and maintenance for French railway network.” International Transportation Economics Association Conf., ITEA, Kiev, Ukraine.
Smith, D. J. (2005). Reliability, maintainability and risk—Practical methods for engineers, 7th Ed., Butterworth-Heinemann, Oxford, U.K.
Stenström, C., Parida, A., and Galar, D. (2012). “Performance indicators of railway infrastructure.” Int. J. Railway Tech., 1(3), 1–18.
Tzanakakis, K. (2013). The railway track and its long term behaviour: A handbook for a railway track of high quality, Springer, Heidelberg.
Yin, Y., and Siriphong, L. (2006). “Internalizing emission externality on road networks.” Transp. Res. Part D, 11(4), 292–301.
Zoeteman, A. (2001). “Life cycle cost analysis for managing rail infrastructure: Concept of a decision support system for railway design and maintenance.” Eur. J. Transp. Infrastruct. Res., 1(4), 391–413.
Zoeteman, A. (2006). “Asset maintenance management: State of the art in the European railways.” Int. J. Crit. Infrast., 2(2–3), 171–186.
Information & Authors
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Published In
Journal of Construction Engineering and Management
Volume 144 • Issue 2 • February 2018
Copyright
©2017 American Society of Civil Engineers.
History
Received: Apr 6, 2017
Accepted: Jul 19, 2017
Published online: Nov 25, 2017
Published in print: Feb 1, 2018
Discussion open until: Apr 25, 2018
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