Dynamic Response of Train-Ballastless Track Caused by Failure in Cement-Asphalt Mortar Layer

Cement-asphalt (CA) mortar voids in earth's structure are prone to inducing abnormal vibrations in vehicle and track systems and are more difficult to recognize. In this paper, a vehicle-ballastless track coupling model considering cement-asphalt mortar voids is established and the accuracy of the model is verified. There are two main novel results: (1) The displacement of the track slab in the ballastless track structure is more sensitive to the void length. Voids can lead to blocked vibration transmission between the ballastless track slab and concrete base. (2) The wheel-rail vibration acceleration is particularly sensitive to voids in cement-asphalt mortar, making the bogie pendant acceleration a key indicator for detecting such voids through amplitude changes. Additionally, the train body pendant acceleration provides valuable feedback on the cyclic characteristics associated with single-point damage in the cement-asphalt mortar, thereby enhancing the accuracy of dynamic inspections for vehicles. In the sensitivity ordering of the identification indexes of voids, the bogie's vertical acceleration in high-speed trains > the nodding acceleration of the bogie > the vehicle's vertical acceleration. Adaptive suspension parameters can be designed to accommodate changes in track stiffness.