Abstract:The deformation of pipeline can be induced by adjacent tunneling, in turn, the safety of pipeline will be affected. Most of the theoretical studies in this regard simplify the existing pipelines as Euler–Bernoulli beams lying on the Winkler and Pasternak foundation models, without considering the shear effect of pipelines and the influence of the three-parameter Kerr foundation model on the pipeline-soil interaction. Based on this, an analytical method for predicting the longitudinal deformation of pipelines was proposed. Firstly, the vertical soil-free settlement around the tunnel induced by tunneling was calculated by the Loganathan function, then the soil-free settlement was put upon the centerline of an existing pipeline, to simplify the tunnel as the Timoshenko beam and the three-type Kerr foundation model was selected to simulate the pipeline-soil interaction, a bending moment assumption of the shear layer was proposed and the response of existing pipeline could be solved by considering with the boundary conditions at the ends of the pipeline. The results of the engineering case study show that compared with the theoretical analysis method in the existing literature, the theoretical analysis calculated by the method in this paper is closer to the existing measured data. Compared with the calculation results of the Euler–Bernoulli beam, the Timoshenko beam calculation results are more advantageous. Further parameter studies show that with the increment of the shear stiffness of the existing pipeline, the ability of pipeline to resist deformation gradually increases, which will lead to the gradual decrease of pipeline deformation but will cause the reverse increment of pipeline internal force. With the increment of volume loss rate, the external force on the existing pipeline gradually increases, which results in the increase of pipeline deformation and internal force. With the gradual increment of the diameter of the pipeline, the pipeline-soil interaction force caused by the tunneling underneath is gradually increased, which eventually leads to the stress and strain of the existing pipeline.