Analysis of the hydraulic performance of permeable pavements on a layer-by-layer basis

Permeable pavement systems are a sustainable urban drainage technique created with a highly porous base and subbase. This study first analyses the hydraulic performance of several new permeable pavement systems based on 189 experimental hydrographs. In addition, the analysis explores the influence o...

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Bibliographic Details
Published in:Construction & building materials 2023-07, Vol.387, p.131587, Article 131587
Main Authors: Madrazo-Uribeetxebarria, Eneko, Garmendia Antín, Maddi, Alberro Eguilegor, Gorka, Andrés-Doménech, Ignacio
Format: Article
Language:English
Subjects:
Low impact development
Model calibration
Permeable interlocking concrete block
Permeable pavement
Porous asphalt mixture
SWMM
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Summary:Permeable pavement systems are a sustainable urban drainage technique created with a highly porous base and subbase. This study first analyses the hydraulic performance of several new permeable pavement systems based on 189 experimental hydrographs. In addition, the analysis explores the influence of rain intensity, slope, and, as a novelty, individual layers. Analysed variables were outflow peak, time to peak, and time to specific cumulative discharges. Secondly, based on the experimental hydrographs, the study explores the performance of the permeable pavement module defined in the Storm Water Management Model, carried out in two steps. First, single-layer outflows were used to calibrate parameter values that could not be measured physically, using the differential evolution algorithm and Nash–Sutcliffe model efficiency coefficient as an objective function. Later, complete layout hydrographs were tested without calibration, and model performance was checked. Results show that the superficial permeable interlocking paver layer provides a notably higher retention capacity than the porous asphalt mixture. Individual modelling results show that the soil layer definition is inappropriate for gravel-type layers, even with a geotextile. Despite this, complete section performance is quite good without calibration if the soil layer is not selected on the model. These results are expected to reduce modelling uncertainty, especially when no calibration data is available. [Display omitted] •189 experimental hydrographs are analysed, even individual layer hydrographs.•Surface with a paver layer provides higher retention capacity than an asphalt layer.•Soil layer outflow in SWMM is not satisfactory for granular lined material.•Complete section performance is checked without calibration.•Outflow hydrograph prediction is quite good, as NSE > 0.74.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2023.131587