A tier-based assessment of masonry quay walls under the effect of traffic loads

Canals delimited with masonry quay walls are integral elements of many Dutch cities. Historically built to enable the efficient transportation of goods, such infrastructure today also gives these cities their historical and monumental character. In recent years, many quay walls in the city of Amsterdam have shown substantial deformation as well as collapse. These quay walls which are constructed in multi-wythe unreinforced brick masonry and are supported on a system of timber piles, today sustain loads associated with the traffic of a modern city which are far higher than what they were originally designed for. This has given rise to a need for research assessing the safety and reliability of these structures, which are not appropriately covered by any normatives or standardised guidelines. This paper presents the results of a numerical modelling approach to understand the same. In particular, a novel methodology to numerically assess the performance of such quay walls under the effect of dynamic traffic loads is first proposed. A two-step modelling approach is adopted in this methodology. In the first step, a 3D soil-block comprising the carriageway adjacent to quay walls is modelled. The passage of a heavy vehicle over a limited distance on the carriageway is then simulated. From this simulation, recordings are made of : a) the distributions of normal stresses on the quay wall at the instant of occurrence of their maxima and b) the time-histories of the same maxima stresses. In the second step, these recordings are applied in combination to a sequence of sections of the 3D numerical model of the quay wall system. The length of each section in the second step measures the same as the limited distance over which the passage of the vehicle on the soil-block was simulated in the first step. Adopting such a simplified yet conservative approach allows simulation of the passage of vehicles over numerical models of long quay wall systems while avoiding the heavy computational burden associated with the explicit modelling of a soil block. The response of quay walls when subjected to dynamic traffic loads simulated using the proposed methodology is ultimately presented.