Effect of the Number of Cross-Tie Lines on the In-Plane Stiffness and Modal Behavior Classification of Orthogonal Cable Networks with Multiple Lines of Transverse Flexible Cross-Ties
Publication: Journal of Engineering Mechanics
Volume 142, Issue 4
Abstract
Using cross-ties to connect a vulnerable cable with its neighbor(s) and forming a cable network is a common countermeasure to suppress bridge stay cable vibrations. An effective design of cross-tie solution should provide an optimum combination of cross-tie installation location, stiffness, and number of cross-tie lines to maximize the network in-plane frequency and structural damping while minimizing the number of excited local modes. However, the mechanics associated with cable networks is not as simple as their geometrical appearance. In particular, the addition of an extra line of cross-ties to an existing cable network would considerably increase the complexity of its structural behavior. While the effects of cross-tie position and stiffness on network response have been investigated in some existing studies, that associated with the number of cross-tie lines is scarce. For better understanding of how the dynamic behavior of a group of cables would be influenced when interconnected by different number of cross-tie lines, the current study proposes an analytical model of cable networks consisting of two parallel main cables interconnected by multiple lines of flexible transverse cross-ties. A new parameter, the degree of mode localization (DML), is introduced to quantitatively evaluate the global nature of a network mode. The in-plane modal responses of two cables when interconnected respectively by one, two, and three lines of cross-ties are analyzed and compared. A parametric study is conducted to assess the impact of various system properties on the in-plane frequency and local mode excitation of networks containing different number of cross-tie lines.
Get full access to this article
View all available purchase options and get full access to this article.
References
ABAQUS 6.10 [Computer software]. SIMULIA Dassault System, Cedex, France.
Ahmad, J., and Cheng, S. (2013a). “Analytical study on in-plane free vibration of a cable network with straight alignment rigid cross-ties.” J. Vib. Control, 21(7), 1299–1320.
Ahmad, J., and Cheng, S. (2013b). “Effect of cross-link stiffness on the in-plane free vibration behaviour of a two-cable network.” J. Eng. Struct., 52, 570–580.
Ahmad, J., and Cheng, S. (2014). “Impact of key system parameters on the in-plane dynamic response of a cable network.” J. Struct. Eng., 04013079.
Ahmad, J., Cheng, S., and Ghrib, F. (2014). “An analytical approach to evaluate damping property of orthogonal cable networks.” Eng. Struct., 75, 225–236.
Bendiksen, O. O. (1987). “Mode localization phenomena in large space structures.” Am. Inst. Aeronaut. Astronautics J., 25(9), 1241–1248.
Bosch, H. R., and Park, S. W. (2005). “Effectiveness of external dampers and cross ties in mitigation of stay cable vibrations.” Proc., 6th Int. Symp. on Cable Dynamics, AIM (Electrical Engineers Association of the Montefiore Institute), Liege, Belgium, 115–122.
Caracoglia, L., and Jones, N. P. (2005a). “In-plane dynamic behavior of cable networks. Part 1: Formulation and basic solutions.” J. Sound Vib., 279(3–5), 969–991.
Caracoglia, L., and Jones, N. P. (2005b). “In-plane dynamic behavior of cable networks. Part 2: Prototype prediction and validation.” J. Sound Vib., 279(3–5), 993–1014.
Caracoglia, L., and Zuo, D. (2009). “Effectiveness of cable networks of various configurations in suppressing stay-cable vibration.” Eng. Struct., 31(12), 2851–2864.
Cornwell, P. J., and Bendiksen, O. O. (1987). “Localization of vibration in large space reflectors.” Proc., 28th AIAA/ASME/ASCE/AHS Structures, Structural Dynamics and Materials Conf., AIAA, New York, 925–935.
Ehsan, F., and Scanlan, R. H. (1989). “Damping stay cables with ties.” 5th US-Japan Bridge Workshop, Tsukuba, Japan, 203–217.
Giaccu, F. G., Barbiellini, B., and Caracoglia, L. (2015a). “Parametric study on the nonlinear dynamics of a three-stay cable network under stochastic free vibration.” J. Eng. Mech., 04014166.
Giaccu, F. G., Barbiellini, B., and Caracoglia, L. (2015b). “Stochastic unilateral free vibration of an in-plane cable network.” J. Sound Vib., 340, 95–111.
Giaccu, F. G., and Caracoglia, L. (2013). “Generalized power-law stiffness model for nonlinear dynamics of in-plane cable networks.” J. Sound Vib., 332(8), 1961–1981.
Giaccu, F. G., Caracoglia, L., and Barbiellini, B. (2014). “Modeling ‘unilateral’ response in the cross-ties of a cable network: Deterministic vibration.” J. Sound Vib., 333(19), 4427–4443.
Irvine, H. M., and Caughey, T. K. (1974). “The linear theory of free vibrations of a suspended cable.” Proc. R. Soc. London, Ser A, 341(1626), 299–315.
Kim, D. O., and Lee, I. W. (1998). “Mode localization in simply supported two span beams of arbitrary span lengths.” J. Sound Vib., 213(5), 952–961.
Kim, D. O., and Lee, I. W. (2000). “Mode localization in structures consisting of substructures and couplers.” Eng. Struct., 22(1), 39–48.
Lankin, J., Kilpatrick, J., Irwin, P., and Nedim, A. (2000). “Wind-induced stay cable vibrations—Measurement and mitigation.” Proc., Advanced Technology in Structural Engineering, ASCE, Reston, VA, 1–8.
Lust, S. D., Friedmann, P. P., and Bendiksen, O. O. (1993). “Mode localization in multi span beams.” AIAA J., 31(2), 348–355.
Pierre, C., Tang, D. M., and Dowell, E. H. (1987). “Localized vibrations of disordered multi-span beams: Theory and experiment.” Am. Inst. Aeronaut. Astronautics J., 25(9), 1249–1257.
Sun, L., Zhou, Y., and Huang, H. (2007). “Experiment and damping evaluation on stay cables connected by cross ties.” 7th Int. Symp. on Cable Dynamics, AIM (Electrical Engineers Association of the Montefiore Institute), Liege, Belgium.
Tabatabai, H., Mehrabi, A. B., Morgan, B. J., and Lotfi, H. R. (1998). “Non-destructive bridge evaluation technology: Bridge stay cable condition assessment.” Federal Highway Administration, Construction Technology Laboratories, Skokie, IL.
Yamaguchi, H., and Nagahawatta, H. D. (1995). “Damping effects of cable cross-ties in cable-stayed bridges.” J. Wind Eng. Ind. Aerodyn., 54–55, 35–43.
Information & Authors
Information
Published In
Journal of Engineering Mechanics
Volume 142 • Issue 4 • April 2016
Copyright
© 2015 American Society of Civil Engineers.
History
Received: Sep 16, 2014
Accepted: Aug 3, 2015
Published online: Dec 16, 2015
Published in print: Apr 1, 2016
Discussion open until: May 16, 2016
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.