Monitoring of Insulated Rail Joints Based on Gap Value Measurement

Aldo La Placa; Francesco Freddi; Felice Giuliani

doi:10.1007/s40864-023-00206-0

Urban Rail Transit ›› 2024, Vol. 10 ›› Issue (1) : 28 -41. DOI: 10.1007/s40864-023-00206-0

Original Research Papers

Monitoring of Insulated Rail Joints Based on Gap Value Measurement

Author information +

History +

PDF

Abstract

The monitoring of an IRJ would allow targeted maintenance to be carried out, reducing the problems caused by its potential failures. The authors present the results of a test field investigation, that involved the installation of seven longitudinal displacement sensors that continuously record the gap value of insulated rail joints (IRJs). The monitoring of an IRJ would allow targeted maintenance to be carried out, reducing the problems caused by its potential failures. The studied monitoring system was installed in a station of the suburban railway line within the metropolitan city of Bologna (Italy). Analysis of low-and high-frequency recordings was performed. In particular, low-frequency acquisition was used to fit a statistical predictive model that detects a deviation from a standard behaviour and may evidence anomalies. For the high-frequency acquisitions (registered during train passage) some representative quantities, that can provide macroscopic indicators of loss of joint stiffness, were computed. Although gap measurement alone is not exhaustive for identifying all possible failure scenarios, the data acquired by these monitoring devices can represent a possible immediate monitoring solution, based on already available instrumentation, to provide user-friendly predictive analysis systems aiming at improving the railway maintenance.

Keywords

Insulated rail joint / Condition monitoring / Predictive railway maintenance / Data analysis / Gap value measurement system

Cite this article

Download citation ▾

Aldo La Placa, Francesco Freddi, Felice Giuliani. Monitoring of Insulated Rail Joints Based on Gap Value Measurement. Urban Rail Transit, 2024, 10(1): 28-41 DOI:10.1007/s40864-023-00206-0

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Esveld C (2001) Modern railway track, 2nd Edn, MRT-Productions, The Netherlands

[2]	Kerr AD, Cox JE. Analysis and tests of boned insulted rail joints subjected to vertical wheel loads. Int J Mech Sci, 1999, 41: 1253-1272

[3]	Wen Z, Tin X, Zhang W. Contact-impact stress analysis of rail joint region using the dynamic finite element method. Wear, 2005, 258: 1301-1309

[4]	RFI (2014) Procedura operativa subdirezionale RFI DPR PS IFS 118 B, Fabbricazione e gestione GII, Rete Ferroviaria Italiana, Roma

[5]	Davis DD, Akhtar MN, Kohake E, Horiszny K (2005) Effects of heavy axle loads on bonded insulated joint performance. In: Proceedings of the AREMA Annual Conference. Chicago, IL

[6]	Yella S, Ghiamati S, Dougherty M (2009) Condition monitoring of wooden railway sleepers using time-frequency techniques and pattern classification. Conf Proc IEEE Int Conf Syst Man Cybern 4164–4169. https://doi.org/10.1109/ICSMC.2009.5346713

[7]	Wang Z, Su G, Skitmore M Human error risk management methodology for rail crack incidents. Urban Rail Transit, 2015, 1: 257-265

[8]	Talib NH, Bin HK, Bin NA Monitoring large-scale rail transit systems based on an analytic hierarchy process/gradient-based cuckoo search algorithm (GBCS) scheme. Urban Rail Transit, 2020, 6: 132-144

[9]	AREMA (2000) Communications & Signals Manual, Part 8.6.35, The American Railway Engineering and Maintenance of Way Association, Maryland

[10]	Molodova M, Oregui M, Núñez A Health condition monitoring of insulated joints based on axle box acceleration measurements. Eng Struct, 2016, 123: 225-235

[11]	Sun YQ, Spiryagin M, Wu Q Feasibility in assessing the dipped rail joint defects through dynamic response of heavy haul locomotive. J Mod Transp, 2018, 26: 96-106

[12]	Stephen J, Hardwick C, Beaty P Ultrasonic monitoring of insulated block joints. Proc Inst Mech Eng F J Rail Rapid Transit, 2019, 233: 251-261

[13]	Carolan ME, Jeong DY, Perlman AB (2014) Engineering Studies on Joint Bar Integrity, Part II: Finite Element Analyses. Conf Proc ASME/IEE Joint Rail Conf. https://doi.org/10.1115/JRC2014-3708

[14]	RFI (2012) Specifica funzionale RFI TCAR SF AR 12 004 A, Sistema di monitoraggio dei giunti isolati incollati. Specifica del sensore, Rete Ferroviaria Italiana, Roma

[15]	Regione Emilia Romagna (2021) Rapporto annuale di monitoraggio della mobilità e del trasporto in Emilia-Romagna 2021—Mobilità

[16]	Dhanasekar M, Pang T, Marks I (2007) Wheel impacts at insulated rail joints

[17]	Dhanasekar M, Pang T, Ashman T, Marks I (2007) Determination of railhead-wheel contact-impact through measured strain signatures

[18]	Bang S, Bishnoi R, Chauhan AS, et al (2019) Fuzzy logic based crop yield prediction using temperature and rainfall parameters predicted through ARMA, SARIMA, and ARMAX models. 2019 12th International Conference on Contemporary Computing, IC3 2019. https://doi.org/10.1109/IC3.2019.8844901

Funding

National Recovery and Resilience Plan (NRRP), Mission 4 Component 2 Investment 1.4 - Call for tender No. 3138 of 16/12/2021 of Italian Ministry of University and Research funded by the European Union(CN00000023)