Share:


Field testing and dynamic analysis of old continuous truss steel bridge

    Artūras KILIKEVIČIUS Affiliation
    ; Darius BAČINSKAS Affiliation
    ; Mindaugas JUREVIČIUS Affiliation
    ; Kristina KILIKEVIČIENĖ Affiliation
    ; Antanas FURSENKO Affiliation
    ; Jonas JAKAITIS Affiliation
    ; Eligijus TOLOČKA Affiliation
DOI: https://doi.org/10.3846/bjrbe.2018.394

Abstract

Paper presents dynamic field test and analysis results of a three span railway steel continuous truss bridge over river Neris in Jonava. Bridge was originally constructed in 1914. In the period of the World War II and afterwards the bridge was many time destroyed by German and Soviet armies. In 1948 the new railway bridge was constructed. Object of the present paper is to evaluate dynamic behaviour of the railway bridge after 67 years in service. Experimental dynamic analysis was divided into resonance-vibration, forced-vibration and free vibration studies. Resonance-vibrations of the bridge were excited by separate actions of shock loading and standard locomotive 2M62. Forced-vibrations were measured under the action of locomotive 2M62. Additionally, free vibration tests under passage of freight and passenger trains have been carried out. Structural dynamic response of the bridge was analysed using Brüel & Kjær LAN XI dynamic test system and software. As a result, main dynamic parameters of the bridge were obtained. The main results include: mode shapes, frequencies of natural and forced vibrations, damping ratios, maximum amplitudes of accelerations, dynamic displacements. The obtained values were compared to the requirements of different design codes. Based on the achieved results concluding remarks and recommendations regarding the condition of the bridge after long-term period in service were presented.

Keyword : dynamic displacement, dynamic testing, heritage, modal analysis, railway bridge, still bridge

Published in Issue
Mar 27, 2018
Abstract Views
1021
PDF Downloads
543
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Aničas, J. (1992). Petras Vileišis – įžymus tiltų inžinierius. Statyba ir architektūra, 6-7, 22-24 (in Lithuanian).

Bačinskas, D., Kamaitis, I. Z., & Kilikevičius, A. (2013). A sensor instrumentation method for dynamic monitoring of railway bridges. Journal of Vibroengineering, 15(1), 176-184.

Bačinskas, D., Turla, V., Kilikevičius, A., Ragauskas, P., & Jurevičius, M. (2014). Dynamic testing of railway truss bridge. Journal of vibroengineering, 16(6), 2649-2657. Retrieved from https://www.miestai.net/forumas/

Camara, A., Nguyen, K., Ruiz-Teran, A. M., & Stafford, P. J. (2014). Serviceability limit state of vibrations in under-deck cable-stayed bridges accounting for vehicle-structure interaction. Engineering Structures, 61(1), 61-72. https://doi.org/10.1016/j.engstruct.2013.12.030

Cieškaitė-Brėdikienė, L. (2008). Dizaino raida nuo Morriso iki Morrisono (374 p.). VDA leidykla (in Lithuanian).

Dormer, P. (1993). Design since 1945. New York, NY: Thames & Hudson.

Hill, R. (2007). God’s architect: Pugin and the building of romantic Britain. Allen Lane.

Jakaitis, J. (2013). Miesto erdvinio formavimo dalyvių diskursas šiuolaikinės demokratijos sąlygomis (220 p.). Vilnius: Technika (in Lithuanian). https://doi.org/10.3846/2128-M

Kamaitis, Z. (1995). Gelžbetoninių tiltų būklė ir jos vertinimas: monografija (Condition state and assessment of reinforced concrete bridges: monograph) (182 p.). Vilnius: Technika.

Lees-Maffei, G., & Houze, R. (2010). The design history reader. New York: Berg Publishers.

Lin, C. W., & Yang, Y. B. (2005). Use of a passing vehicle to scan the fundamental bridge frequencies: an experimental verification. Engineering Structures, 27(13), 1865-1878. https://doi.org/10.1016/j.engstruct.2005.06.016

LST EN 1991-2:2004/AC:2010 Eurocode 1: Actions on Structures. Pt. 2, Traffic Loads on Bridges.

LST EN 1990:2004/A1:2006 Eurocode: Basis of Structural Design.„Rail Baltica“ galutinė ataskaita. (2011). Santrauka. Vilnius: „AECOM Limited“.

Ruskin, J. (1989). The seven lamps of architecture (paperback). Dover Publications.

Shiling, P., Yongle, L., Yulong, B., Xin, L., & Shizhong, Q. (2016). Impact of train-induced vibration on railway cable-stayed bridges fatigue evaluation. The Baltic Journal of Road and Bridge Engineering, XI(2), 102-110.

Skeivalas, J., Jurevičius, M., Kilikevičius, A., & Turla, V. (2015). An analysis of footbridge vibration parameters. Measurement 66, 222-228. https://doi.org/10.1016/j.measurement.2015.02.034

Sousa, H., Costa, B. J. A., Henriques A. A., Bento, J, Figueiras, J. A. (2016). Assessment of traffic load events and structural effects on road bridges based on strain measurements. Journal of Civil Engineering and Management, 22(4), 457-469.

Viešosios geležinkelių infrastruktūros 2011–2012 metų tinklo nuostatai. (2010). Informacinis leidinys. Vilnius: AB „Lietuvos geležinkeliai“ (in Lithuanian).

Zambon, I., Vidovic, A., Strauss, A., Matos, J., Amado, J. (2017).Comparison of stochastic prediction models based on visual inspections of bridge decks. Journal of Civil Engineering and Management, (23)5, 553-561.

Zhai, W. M., Xia, H., Cai, C. B., Gao, M., Li, X., Guo, X., Zhang, N., & Wang, K. (2013). High-speed train-track-bridge dynamic interactions – Part I: theoretical model and numerical simulation. International Journal of Rail Transportation, 1(1-2), 3-24. https://doi.org/10.1080/23248378.2013.791498