Permeable pavement functions as a porous infrastructure interface allowing the infiltration and evaporation of rainfall–runoff while functioning as a relatively smooth load-bearing surface for vehicular transport. Hydraulic conductivity (k) of permeable pavement is an important hydraulic property and is a function of the pore structure. This study examines k for a cementitious permeable pavement (CPP) through a series of pore-structure models. Measurements utilized include hydraulic head as well as total porosity, (/t), effective porosity (/e), tortuosity (Le/L) and pore size distribution (PSD) indices generated through X-ray tomography (XRT). XRT results indicate that the permeable pavement pore matrix is hetero- disperse, with high tortuosity and /t – /e. Power law models of k–/t and k–/e relationships are developed for a CPP mix design. Results indicate that the Krüger, Fair-Hatch, Hazen, Slichter, Beyer and Terzaghi models based on simple pore-structure indices do not reproduce measured k values. The conventional Kozeny–Carman model (KCM), a more parameterized pore-structure model, did not reproduce measured k values. This study proposes a modified KCM utilizing /e, specific surface area (SSA)pe and weighted tortuosity (Le/L)w. Results demonstrate that such permeable pavement pore-structure parameters with the modified KCM can predict k. The k results are combined with continuous simulation modeling using historical rainfall to provide nomographs examining permeable pavement as a low impact development (LID) infrastructure component
Pore-structure models of hydraulic conductivity for permeable pavement / Kuang, X.; Sansalone, J.; Ying, G.; Ranieri, Vittorio. - In: JOURNAL OF HYDROLOGY. - ISSN 0022-1694. - 399:3-4(2011), pp. 148-157. [10.1016/j.jhydrol.2010.11.024]
Pore-structure models of hydraulic conductivity for permeable pavement
RANIERI, Vittorio
2011-01-01
Abstract
Permeable pavement functions as a porous infrastructure interface allowing the infiltration and evaporation of rainfall–runoff while functioning as a relatively smooth load-bearing surface for vehicular transport. Hydraulic conductivity (k) of permeable pavement is an important hydraulic property and is a function of the pore structure. This study examines k for a cementitious permeable pavement (CPP) through a series of pore-structure models. Measurements utilized include hydraulic head as well as total porosity, (/t), effective porosity (/e), tortuosity (Le/L) and pore size distribution (PSD) indices generated through X-ray tomography (XRT). XRT results indicate that the permeable pavement pore matrix is hetero- disperse, with high tortuosity and /t – /e. Power law models of k–/t and k–/e relationships are developed for a CPP mix design. Results indicate that the Krüger, Fair-Hatch, Hazen, Slichter, Beyer and Terzaghi models based on simple pore-structure indices do not reproduce measured k values. The conventional Kozeny–Carman model (KCM), a more parameterized pore-structure model, did not reproduce measured k values. This study proposes a modified KCM utilizing /e, specific surface area (SSA)pe and weighted tortuosity (Le/L)w. Results demonstrate that such permeable pavement pore-structure parameters with the modified KCM can predict k. The k results are combined with continuous simulation modeling using historical rainfall to provide nomographs examining permeable pavement as a low impact development (LID) infrastructure componentI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.