References
- [1] Abdoun, T.H., et al. (2009). Factors influencing the behavior of buried pipelines subjected to earthquake faulting. Soil Dynamics and Earthquake Engineering, 29 (3), 415-427.
- [2] Honegger, D.G., Wijewickreme, D. (2013). Seismic risk assessment for oil and gas pipelines. In Seismic Risk Analysis and Management of Civil Infrastructure Systems. Woodhead Publishing, Part IV, 682-715.
- [3] Lanzano, G., et al. (2014). Seismic vulnerability of gas and liquid buried pipelines. Journal of Loss Prevention in the Process Industries, 28, 72-78.
- [4] Chen, W.W., et al. (2002). Seismic response of natural gas and water pipelines in the Ji-Ji earthquake. Soil Dynamics and Earthquake Engineering, 22 (9-12), 1209-1214.
- [5] Figiel, W., Tarnowski, J. (2005). Badania wspolczynnika tarcia rurociągu i gruntu na terenach gorniczych w obecnosci wstrzasow. Eksploatacja i Niezawodnosc- Maintenance and Reliability, 4, 55-63.
- [6] Khan, F., Yeakle, C., Gomaa, S. (2012). Characterization of the mechanical properties of a new grade of ultra high molecular weight polyethylene and modeling with the viscoplasticity based on overstress. Journal of the Mechanical Behavior of Biomedical Materials, 6, 174-180.
- [7] Kiass, N., Khelif, R., Boulanouar, L., Chaoui, K. (2005). Experimental approach to mechanical property variability through a high-density polyethylene gas pipe wall. Journal of Applied Polymer Science, 97, 272-281.
- [8] Zheng, W., Elboujdaini, M., Revie, R.W. (2011) Stress corrosion cracking in pipelines. In Stress Corrosion Cracking - Theory and Practice. Woodhead Publishing, 749-771.
- [9] Bai, Q., Bai, Y. (2014). Subsea Pipeline Design, Analysis, and Installation (1st ed.). Elsevier.
- [10] Inaudi, D. (2013). Pipelines. In Handbook of Technical Diagnostics. Fundamentals and Applications to Structures and Systems. Springer, 453-470.
- [11] Janson, L.E. (1993). Method for tightness testing of plastics pressure pipelines. Construction and Building Materials, 7 (4), 241-244.
- [12] Frings, J., Walk, T. (2011). Distributed fiber optic sensing enhances pipeline safety and security. Oil Gas European Magazine, 37 (3), 132-136.
- [13] Gawedzki, W. (2001). Optymalizacja tensometrycznego czujnika odkształcen gazociagu eksploatowanego w warunkach niestabilnego srodowiska. In Materiały Kongresu Metrologii KKM, 24-27 June 2001. Warszawa, Poland: BEL Studio, 2, 605-608.
- [14] Gawedzki, W., Jurkiewicz, J. (1996). A branched system for measurements of the slow-variable forces using a strain gauge method. In IEEE Instrumentation and Measurement Technology Conference & IMEKO Technical Committee 7 (IMTC/96 - IMEKO TC-7), 4-6 June 1996, Brussels, Belgium. IEEE, Vol. I and II, 196-199.
- [15] Walk, T., Frings, J. (2010). Fiber optic sensing can help reduce third-party threats. Oil & Gas Journal, 108 (33), 128-133.
- [16] Hofstotter, P., Kosiedowski, P. (1971). Messung der durch Erdabsenkungen hervorgerufenen Zusatzbeanspruchungen an erdverlegten Fernleitungen. Sonderdruck aus Bander Bleche Rohre, (12) 6, 261-265.
- [17] Reed, Ch., Robinson, A.J., Smart, D. (2004). Techniques for monitoring structural behaviour of pipeline systems. Amer Water Works Assn.
- [18] Qingmin, H., et al. (2013). Natural gas pipeline leakage detection based on FBG strain sensor measuring technology and mechatronics automation (ICMTMA). In Proceedings of Fifth IEEE International Conference on Measuring Technology and Mechatronics Automation, 16-17 January 2013. IEEE, 712-715.
- [19] HBM Test and Measurement. http://www.hbm.com/.
- [20] Syrek, K. (2013). Laboratoryjna weryfikacja tensometrycznej metody pomiaru odkształceń polietylenowych rur gazowych. Unpublished B.Sc. Thesis, AGH-UST Krakow, Poland.