Influence of armour porosity on the hydraulic stability of cube armour layers

Medina, Josep R.; Molines, Jorge; Gómez-Martín, M. Esther

doi:10.1016/j.oceaneng.2014.06.012

Cited by 28 publications

(24 citation statements)

References 26 publications

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“…Given an armor unit, an armor porosity above recommended values decreases the concrete consumption but also decreases the hydraulic stability (see Medina et al, 2014), affecting the breakwater performance during lifetime.…”

Section: For Cubipod Tests Packing Densities Were Taken From Smolka mentioning

confidence: 99%

Calibration of overtopping roughness factors for concrete armor units in non-breaking conditions using the CLASH database

Molines

Medina

2015

Coastal Engineering

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Section: For Cubipod Tests Packing Densities Were Taken From Smolka mentioning

confidence: 99%

Calibration of overtopping roughness factors for concrete armor units in non-breaking conditions using the CLASH database

Molines

Medina

2015

Coastal Engineering

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“…The specific placement technique is directly related to armor porosity (p%) and interlocking, which significantly affects armor stability. Van der Meer (1999), Yagci and Kapdasli (2003), Bakker et al (2005), and Medina et al (2014) among others, analyzed a variety of CAUs and reported a significant influence of armor porosity on hydraulic stability. Porosity is also directly related to the number of units in the armor, material consumption and hence the construction cost.…”

Section: Ii33 Techniques To Place Armor Unitsmentioning

confidence: 99%

“…Frens (2007) summarized problems caused by different researchers using different criteria regarding the layer coefficient and the porosity concept. To prevent misunderstandings, Medina et al (2014) suggested referring armor porosity p(%)=(1-Φ/n) to a layer coefficient of kΔ=1.00 using the dimensionless placing density Φ=φDn 2 . Different criteria can be used to classify armor units depending on the placement technique.…”

Section:   mentioning

confidence: 99%

“…IV.15. Although cube armor hydraulic stability is significantly affected by armor porosity (see Medina et al, 2014), no clear differences were found when considering armor placement technique.…”

Section: Iv52 Artificial Neural Network Model For Armor Damagementioning

confidence: 99%

“…Using the virtual net method, armor damage was measured after each test conducted with cubes randomly-and uniformly-placed. Since the armor unit placement technique is a critical consideration in the design phase (see Medina et al, 2014), the influence of the placement technique on armor stability was analyzed using artificial neural networks.…”

Section: Iv1 Introductionmentioning

confidence: 99%

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Mound Breakwater Design in Depth-Limited Breaking Wave Conditions

Gamboa¹,

Piedad²

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i Agradecimientos Esta tesis doctoral es el fruto de varios años de trabajo, pero su culminación no habría sido posible sin el apoyo y la ayuda de todas aquellas personas importantes que me rodean.A mi padre, por su dedicación y precocupación por mí. Porque sin él, probablemente no estaría escribiendo estas líneas.A mi madre, por su apoyo incondicional, su alegría y su capacidad de ponerse en el lugar del otro. Gracias por estar siempre a mi lado.A mis hermanos, Patricia y Pepe, a los que quiero con locura aunque siempre estemos de 'peleillas'.A mis amigos, porque a pesar de la distancia que nos separa, sois mi segunda familia.A mis compañeros del LPC y departamento, Ainoha, Gloria, Quique, Vicente, Guille, Tomás, César, Pepe, Ana, Esther, Jose Alberto, Joaquín, Miguel…por la ayuda prestada.A Jorge, por todo. Por sus ánimos, su confianza, su paciencia y su ayuda. Porque siempre has estado ahí sin esperar nada a cambio.A mi director de tesis, Josep, quien me ha transmitido su pasión por la ingeniería marítima. Gracias por haberme ofrecido la posibilidad de trabajar contigo, por la ayuda, la confianza y la disponibilidad mostrada todos estos años.Al Ministerio de Educación, Cultura y Deporte, por la financiación brindada a través del programa de Formación de Profesorado Universitario (FPU 13/01872) para la realización de esta tesis doctoral.Al Ministerio de Economía y Competitividad, por la financiación del proyecto ESCOLIF (BIA2012-33967).A Debra Westall, por revisar este documento.iii Resumen El manto principal de los diques en talud suele estar formado por escollera natural o elementos prefabricados de hormigón; su función es resistir la acción del oleaje. Una revisión del estado del arte pone de manifiesto que son numerosas las fórmulas existentes para el diseño de mantos derivadas de ensayos físicos a escala reducida con oleaje sin rotura por fondo. Sin embargo, la mayoría de diques en talud se construyen en la zona de rompientes con oleaje limitado por fondo, donde las ecuaciones de diseño habituales no son del todo válidas. En esta tesis doctoral se analiza la estabilidad hidráulica de mantos bicapa de escollera, a partir de ensayos a escala reducida con pendiente de fondo m=1/50. En base a los resultados obtenidos de los ensayos físicos, se propone una nueva relación potencial para el diseño de mantos de escollera en condiciones de oleaje limitado por fondo, válida para taludes con cotα=1.5, números de estabilidad 0.98≤Hm0/(ΔDn50)≤2.5, y profundidades relativas a pie de dique de 3.75≤hs/(ΔDn50)≤7.50.Cuando el manto principal está formado por elementos de hormigón, es habitual construir una berma de pie que proporciona apoyo a los elementos del manto y, en su caso, colabora en la protección de la zona inferior del dique contra la socavación. Dicha berma suele construirse con escollera natural y su peso está condicionado al de los elementos del manto en el caso de no haber rotura por fondo. El peso de los elementos de la berma de pie suele ser un orden de magnitud inferior al peso de las unidades del manto; ...

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Hydraulic stability of rock armors in breaking wave conditions

Herrera

Gómez-Martín

Medina

2017

Coastal Engineering

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Armor layers of mound breakwaters are usually designed with empirical formulas based on small-scale tests in non-breaking wave conditions. However, most rubble mound breakwaters are constructed in the depth-induced breaking zone, where they must withstand design storms having some percentage of large waves breaking before reaching the structure; in these cases, the design formulas for non-breaking wave conditions are not fully valid. To characterize double-layer rock armor damage in breaking wave conditions, 2D physical model tests were carried out with a bottom slope m=1/50. In order to develop a simple method to determine the wave parameters in the depth-induced breaking zone, experimental wave measurements were compared to the numerical estimations given by the SwanOne model. An analysis was conducted to select the best characteristic wave height to estimate rock armor damage when dealing with depth-induced breaking waves; the spectral significant wave height, H m0 , estimated at a distance of 3h s seaward from the structure toe, was found to be the most adequate. 2 A new hydraulic stability formula is proposed for double-layer rock armors in breaking wave conditions, considering the observed potential 6-power relationship between the equivalent dimensionless armor damage and the H m0 at 3h s seaward distance from the structure toe.

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Influence of armour porosity on the hydraulic stability of cube armour layers

Cited by 28 publications

References 26 publications

Calibration of overtopping roughness factors for concrete armor units in non-breaking conditions using the CLASH database

Calibration of overtopping roughness factors for concrete armor units in non-breaking conditions using the CLASH database

Mound Breakwater Design in Depth-Limited Breaking Wave Conditions

Hydraulic stability of rock armors in breaking wave conditions

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