Share:


Behaviour of vertical cylindrical tank with local wall imperfections

    Antanas Šapalas Affiliation
    ; Gintas Šaučiuvėnas Affiliation
    ; Konstantin Rasiulis Affiliation
    ; Mečislovas Griškevičius Affiliation
    ; Tomas Gečys Affiliation

Abstract

Design of modern thin-walled metal structures is widely used around the world. In recent decades, more comprehensive research is carried out to investigate the behaviour of various thin-walled structures. Generally, the structure with regular geometry is investigated. In various countries such as USA, Russia, and the European Union issued the standards on regulation of the construction, design and maintenance of thin-walled structures.


The actually used period of tanks usually is longer than recommendatory period. Recommendatory maintenance period of metal tanks is 15–20 years. Therefore, for such structures one of the most considerable questions is the residual load bearing capacity beyond the end of the maintenance period. This phase of using of structures is associated with complex investigation and numerical analysis of thin-walled structures.


In this paper the load bearing capacity of the steel wall of the existing over-ground vertical cylindrical tank in volume of 5,000 m3 with a single defect and with a few contiguous local defects of the shape is analyzed. Calculations carried out are taking into account all the imperfections of the wall geometry.


A major goal of the research – developing a realistic numerical model of the object analyzed, taking into account all the imperfections, determining the wall stress and strain state, exploring the places of extreme points, calculating the residual load bearing capacity of the tank and scrutinizing possible strengthening schemes for defective areas.

Keyword : tank, imperfection, stress concentration factor, strengthening, crash

How to Cite
Šapalas, A., Šaučiuvėnas, G., Rasiulis, K., Griškevičius, M., & Gečys, T. (2019). Behaviour of vertical cylindrical tank with local wall imperfections. Journal of Civil Engineering and Management, 25(3), 287-296. https://doi.org/10.3846/jcem.2019.9629
Published in Issue
Mar 29, 2019
Abstract Views
927
PDF Downloads
630
Creative Commons License

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

References

Aliphanov, L. A. (2004). Regulation of the shape defects and resources of the vertical cylindrical tanks (PhD thesis, Architectural-Building Academy).

American Petroleum Institute. (2012). Welded steel tanks for oil storage (ANSI/API STD 650, 11th ed.). Americal national standard.

Christopher, T. M. (2017). The failure investigation of fuel storage tanks weld joints in Tanzania. International Journal of Mechanical Engineering and Technology, 8(4), 128-137.

Cosham, A., & Hopkins, P. (2004). The effect of dents in pipelines-guidance in the pipeline defect assessment manual. International Journal of Pressure Vessels and Piping, 81, 127-139. https://doi.org/10.1016/j.ijpvp.2003.11.004

Deutsches Institut für Normung. (2008). Steel structure – Part 4: Stability – Analysis of safety against buckling of shells (DIN 18800-4:2008-11). German Standard.

European Committee for Standardization. (2007). Eurocode 3 - Design of steel structures – Part 1-6: Strength and stability of shell structures (EN 1993-1-6:2007).

European Committee for Standardization. (2011). Execution of steel structures and aluminium structures – Part 2: Technical requirements for steel structures (EN 1090-2: 2008+A1:2011).

Kala, Z., Gottvald, J., Stonis, J., & Omishore, A. (2014). Sensitivity analysis of the stress state in shell courses of welded tanks for oil storage. Engineering Structures and Technologies, 6(1), 7-12. https://doi.org/10.3846/2029882X.2014.957899

Kandakov, G. P., Kuznecov, V. V., & Lukijenko, M. I. (1994). Analysing of the crash causes of the vertical cylindrical tanks. Pipeline Transportation, 5, 15-16.

Pasternak, H., & Kubieniec, G. (2016). Implementation of longitudinal welding stresses into structural calculation of steel structures. Journal of Civil Engineering and Management, 22(1), 47-55. https://doi.org/10.3846/13923730.2014.994029

Rasiulis, K., Samofalov, M., & Šapalas, A. (2006). Stress strain state investigation of soft defects on the thin steel plate by using experimental method. In Proceedings of the 11th International Conference “Mechanika” (pp. 283-288).

Romanenko, K., & Samofalov, M. (2005). Analyze and estimation of the soft defects on the thin wall tankages. In Proceedings of the 10th International Conference “Mechanika” (pp. 17-23).

Romanenko, K., Samofalov, M., Šapalas, A., & Aliphanov, L. A. (2004). Linear and physical non-linear stress state analysis of local shape defects on steel cylindrical tank walls by the finite element method. Mechanika, 46(2), 5-13.

Wang, Y., & Zhou, H. (2015). Numerical study of water tank under blast loading. International Journal of Impact Engineering, 90, 42-48. https://doi.org/10.1016/j.tws.2015.01.012

Wang, Y., Liew, J. Y. R., & Lee, S. C. (2015). Structural performance of water tank under static and dynamic pressure loading. International Journal of Impact Engineering, 85, 110-123. https://doi.org/10.1016/j.ijimpeng.2015.06.018

ZAO CNIIPSK im. Mel’nikova. (2004). Vertical cylindrical steel tanks for petroleum and petroleum products. Rules of technical diagnosing, repair and reconstruction (STO 0030-2004). Russian standard (in Russian).

Zhang, Z., Hui, P., Gu, C., Xu, P., Wu, Y., & Hua, Z. (2015). Buckling of cold-stretched cylindrical vessels under external pressure: Experimental and numerical investigation. International Journal of Impact Engineering, 131, 475-486.