Abstract
This paper presents a modular hydromechanical approach to assess the short- and long-term surface drainage behavior of arbitrarily deformable asphalt pavements. The modular approach consists of three steps. In the first step, the experimental characterization of the thermomechanical asphalt material behavior is performed. In the second step, information about the long-term material behavior of the asphalt mixtures is integrated on the structural scale via a finite element (FE) tire-pavement model for steady-state rolling conditions and time homogenization in order to achieve a computationally efficient long-term prediction of inelastic deformations of the pavement surface (rut formation). In the third step, information regarding the current pavement geometry (deformed pavement surface) is used to carry out a surface drainage analysis to predict, e.g., the thickness of the water film or the water depth in the pavement ruts as a function of several influencing quantities. For chosen numerical examples, the influence of road geometry (cross and longitudinal slope), road surface (mean texture depth and state of rut deformation), and rainfall properties (rain intensity and duration) on the pavement surface drainage capacity is assessed. These parameters are strongly interrelated, and general statements are not easy to find. Certain trends, however, have been identified and are discussed.
Highlights
Stefan Alber,1 Barbara Schuck,1 Wolfram Ressel,1 Ronny Behnke,2 Gustavo Canon Falla,3 Michael Kaliske,2 Sabine Leischner,3 and Frohmut Wellner3
Information about the longterm material behavior of the asphalt mixtures is integrated on the structural scale via a finite element (FE) tire-pavement model for steady-state rolling conditions and time homogenization in order to achieve a computationally efficient long-term prediction of inelastic deformations of the pavement surface
It is exemplarily shown that the experimental and numerical analysis of geometrical changes of arbitrary asphalt pavements can be combined and coupled with an analysis of functional properties addressing road users’ needs regarding safety and comfort. erefore, a modular hydromechanical approach consisting of three steps (experimental material testing, long-term structural deformation finite element (FE) modeling, and surface drainage modeling) is proposed. is approach is one of the first steps towards a more comprehensive, future vision of long-term pavement performance and its prediction with the help of in situ monitoring, data collection, data management, and modeling techniques—often called a “digital twin” in the context of industrial products or processes
Summary
Modeling of Surface Drainage during the Service Life of Asphalt Pavements Showing Long-Term Rutting: A Modular Hydromechanical Approach. By using the results of appropriate laboratory tests, numerical modeling techniques provide additional means for predicting the rutting behavior of asphalt pavements on the structural scale. Much more information about (future) surface drainage behavior can be determined than by merely using the value of rut depth to describe the risk of aquaplaning In this contribution, it is exemplarily shown that the experimental and numerical analysis of geometrical changes (deformations in the form of ruts) of arbitrary asphalt pavements can be combined and coupled with an analysis of functional properties addressing road users’ needs regarding safety and comfort. Erefore, a modular hydromechanical approach consisting of three steps (experimental material testing, long-term structural deformation finite element (FE) modeling, and surface drainage modeling) is proposed. Via a longterm simulation of the selected tire-pavement configuration, geometrical information regarding the permanent deformation of the pavement surface is obtained. e geometrical data is used as input for the numerical surface drainage
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
