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Cable tension estimation by means of vibration response andmoving mass technique

Published online by Cambridge University Press:  09 December 2010

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Abstract

This paper approaches a novel technique to estimate cable tension simply based on itsvibration response. The vibration response has been quite extensively adopted in the pastdue to its simplicity and, mainly, because the inverse approach allows the tensionestimation with the cable in its original site. A first tentative approach consists inusing a certain number of experimentally measured natural frequencies to be introduced inthe theoretical vibration formula; this formula, however, involves also the cable length,the cable mass per unit length and its flexural rigidity. Unfortunately, some problemsarise in its application to real structures, such as the case of suspended andcable-stayed bridges, because the exact cable length cannot be measured (it appears at thefourth exponent in the vibration formula); moreover section and weight can be estimatedwithin a certain degree of accuracy, whilst the boundary conditions are often defined withdifficulty. A novel extension of the method is here proposed, which takes advantage from amoving mass travelling on the cable. This is the case occurring when cables are verifiedwith magnetic-based technology to detect rope faults and cross section reduction. In thisway, the extracted natural frequencies are varying with time due to the moving load, andhence they have to be extracted adopting a time-varying approach. Although someapproximation linked to the shape modification must be introduced, a simple iterativeprocedure can be settled, by considering the cable length as an unknown. An estimation ofthe equivalent length is given, and successively this value is used to obtain anestimation of the cable tension.

Type
Research Article
Copyright
© AFM, EDP Sciences 2010

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References

Références

Ricciardi, G., Saitta, F., A continuous vibration analysis model for cables with sag and bending stiffness, Eng. Struct. 30 (2008) 14591472 CrossRefGoogle Scholar
Xu, Y.L., Ko, J.M., Yu, Z., Modal analysis of tower-cable system of Tsing Ma long suspension bridge, Eng. Struct. 19 (1997) 857867 CrossRefGoogle Scholar
Bouaanani, N., Numerical investigation of the modal sensitivity of suspended cables with localized damage, J. Sound Vib. 292 (2006) 10151030 CrossRefGoogle Scholar
Ni, Y.Q., Ko, J.M., Zheng, G., Dynamic analysis of large-diameter sagged cables taking into account flexural rigidity, J. Sound Vib. 257 (2002) 301319 CrossRefGoogle Scholar
Kim, B.H., Park, T., Estimation of cable tension force using the frequency-based system identification method, J. Sound Vib. 304 (2007) 660676 CrossRefGoogle Scholar
Zui, H., Shinke, T., Namita, Y., Practical formulas for estimation of cable tension by vibration method, Am. Soc. Civil Eng. J. Struct. Eng. 122 (1996) 651656 Google Scholar
Au, F.T.K., Cheng, Y.S., Cheung, Y.K., Zheng, D.Y., On the determination of natural frequencies and mode shapes of cable-stayed bridges, Appl. Math. Mod. 25 (2001) 10991115 CrossRefGoogle Scholar
Bellino, A., Garibaldi, G., Marchesiello, S., Time-varying output-only identification of a cracked beam, Key Engineering Materials 413–414 (2009) 643650 CrossRefGoogle Scholar
Sergev, S.S., Iwan, W.D., The natural frequencies and mode shapes of cables with attached masses, J. Energy Resour. Technol. 103 (1981) 237242 CrossRefGoogle Scholar
Cheng, S.P., Perkins, N.C., Closed-form vibration analysis of sagged cable/mass suspensions, J. Appl. Mech. 59 (1992) 923928 CrossRefGoogle Scholar
Al-Qassab, M., Nair, S., Wavelet-Galerkin method for the free vibrations of an elastic cable carrying an attached mass, J. Sound Vib. 270 (2004) 191206 CrossRefGoogle Scholar
Biondi, B., Muscolino, G., New improved series expansion for solving the moving oscillator problem, J. Sound Vib. 281 (2005) 99117 CrossRefGoogle Scholar
P. Van Overschee, B. De Moor, Subspace Identification for Linear Systems: Theory, Implementation, Applications, Kluwer Academic Publishers, Boston London Dordrecht, 1996