Dynamic analysis of free-free Timoshenko beams on elastic foundation under transverse transient ground deformation
Abstract
Underground infrastructure, such as pipelines and tunnels, can be vulnerable to the effect of transient ground deformation (TGD) caused by different vibration sources, including earthquakes and traffic loads. Current design methods are based on simple analytical models that idealize the soil movement as a traveling sinusoidal wave, neglecting both the system's inertia and the relative displacement at the soil-structure interface. However, this assumption may not be valid for buried large diameter pipelines and tunnels requiring accurate dynamic analysis. To analyse the dynamic response of a buried straight beam subjected to transverse TGD, this study develops a new semi-analytical model based on the Timoshenko beam on Winkler foundation theory. The closed-form analytical solution revealed that the vibration spectrum is divided in four parts, separated by three transition frequencies. Across each transition frequency, the oscillatory characteristics of the vibration modes change, significantly affecting the dynamic response of the system. To verify the validity of the proposed model, this work analyses the case study of a buried steel water pipeline of varying lengths and operating conditions, subjected to transverse TGD. Comparison of the obtained analytical solutions with the finite element analysis results showed excellent agreement between the two approaches. The frequency response analysis revealed dynamic amplification of the soil-structure interaction for forcing frequencies near the system's fundamental frequency. These may fall within the range of dominant frequencies characterizing seismic waves, requiring accurate dynamic analysis. The proposed methodology provides a robust analytical framework for evaluating the primary factors impacting the dynamic behavior of buried beams, giving a deeper understanding of the system response under various sources of ground vibration.