Your search keyword '"Beuzen, Tomas"' showing total 3 results

1. A new approach for scaling beach profile evolution and sediment transport rates in distorted laboratory models.

Author

Bayle, Paul Maxime, Beuzen, Tomas, Blenkinsopp, Christopher Edwin, Baldock, Tom E., and Turner, Ian Lloyd

Subjects

*SEDIMENT transport, *OCEANOGRAPHY, *COASTAL engineering, *WATER waves, *FLUMES, *BEACHES, *WATER levels

Abstract

Laboratory wave flume experiments in coastal engineering and physical oceanography are widely used to provide an improved understanding of morphodynamic processes. Wave flume facilities around the world vary greatly in their physical dimensions and differences in the resulting distortion of the modelled processes are reconciled using scaling laws. However, it is known that perfect model-prototype scaling of all hydro and morphodynamic processes is rarely possible and there is a lack of understanding to what extent distorted models can be used for direct morphological comparison. To address this issue, distorted scale laboratory flume experiments were undertaken in three different facilities, with the aim to measure and compare beach profile evolution under erosive waves and increasing water levels. A novel approach was developed to transform and scale the different experimental geometries into dimensionless coordinates, which enabled a direct quantitative comparison of the beach profile evolution and sediment transport rates between the differing distorted experimental scales. Comparing results from the three experiments revealed that the dimensionless scaled morphological behaviour was similar after the same number of waves – despite very different degrees of model distortion. The distorted profiles appeared to be suitable for comparison as long as a modified version of the Dean number is maintained between them. The new method was then validated with two further published datasets, and showed good agreement for both dimensionless profile shape, dimensionless sediment transport and morphodynamics parameters. The new approach scales the sediment transport by the square of the runup, proportional to HL, rather than H 2, and yields good agreement between the datasets. It is further shown that the new scaling method is also applicable for comparing distorted profile evolution under water level increase, as long as the water level is raised in a similar way between the experiments and by the same total increment relative to the significant wave height (Δh/H s). • Three distorted laboratory wave flume experiments of different scales are compared. • Development of a new scaling methodology for comparing beach profiles of distorted experiments. • Analysis and validation of the method for a fixed and increasing water level. • Qualitative and quantitative comparison of distorted profiles possible by scaling with HL. • Two examples of application of the method, for a fixed and increasing water level. [ABSTRACT FROM AUTHOR]

Published

2021

2. Beach Profile Changes under Sea Level Rise in Laboratory Flume Experiments at Different Scale.

Author

Bayle, Paul M., Beuzen, Tomas, Blenkinsopp, Chris E., Baldock, Tom E., and Turner, Ian L.

Subjects

*FLUMES, *SEA level, *BEACHES, *WATER waves, *REFLECTANCE, *WATER levels, *OCEAN waves

Abstract

Bayle, P.M.; Beuzen, T.; Blenkinsopp, C.E.; Baldock, T.E., and Turner, I.L., 2020. Beach profile changes under sea level rise in laboratory flume experiments at different scales. In: Malvárez, G. and Navas, F. (eds.), Global Coastal Issues of 2020. Journal of Coastal Research, Special Issue No. 95, pp. 192–196. Coconut Creek (Florida), ISSN 0749-0208. Laboratory wave flume experiments have been used to provide improved understanding of beach profile evolution under different wave and water level conditions. However, the understanding of the processes involved in the evolution of beach profile under Sea Level Rise (SLR) toward equilibrium is unclear. Two similar, but distorted experiments were performed at large and medium scale in order to study the qualitative morphological changes involved in beach profile evolution under SLR. Both experiments showed similar beach profile evolution. The profile change predicted by the Profile Translation Model (PTM) and the Bruun Rule underestimated the observed reatreat in both experiments. The length of the active beach profile increased under SLR. For the large scale experiment, the reflection coefficient of the beach decreased while the vertical runup increased significantly. The beachface changed faster than the outer surf zone, making the beach more dissipative. [ABSTRACT FROM AUTHOR]

Published

2020

3. Performance of a dynamic cobble berm revetment for coastal protection, under increasing water level.

Author

Bayle, Paul M., Blenkinsopp, Chris E., Conley, Daniel, Masselink, Gerd, Beuzen, Tomas, and Almar, Rafael

Subjects

*COASTAL changes, *SHORELINE monitoring, *WATER levels, *WATER waves, *ENVIRONMENTAL engineering, *COASTAL engineering, *DYNAMIC stability

Abstract

In a changing climate, sea level rise and projected regional–scale changes in storminess may increase the vulnerability of sandy coastlines to coastal erosion and flooding. As a result, there is increased interest in the development of adaptable, sustainable and effective coastal protection measures to protect these highly variable sandy coastlines. One such example is a dynamic cobble berm revetment; a "soft–engineering" solution (i.e. , not fixed) consisting of a cobble berm constructed around the high tide wave runup limit, that has the potential to stabilise the upper beach, provide overtopping protection to the hinterland and translate with water level rise. However, there have been limited applications of dynamic cobble berm revetments to date, and there is a lack of understanding about the efficacy of this coastal protection to current and changing waves and water levels. This study details a prototype–scale experiment conducted to test the behaviour and performance of a dynamic cobble berm revetment as a form of coastal protection against erosive waves and water level increase. Results from the experiment showed that the revetment was "dynamically stable" under wave action as a consistent global shape was retained even though individual cobbles were mobilised under every swash event. Although the front slope and the crest responded to the incident wave condition, the net rate of change was always an order of magnitude lower than the gross rate of change. Tracking of individual cobbles using Radio Frequency Identification (RFID) technology showed that stability of the revetment was likely maintained by rollover transport of cobbles onto the crest, as the revetment moved upward and landward under water level rise. The presence of the revetment reduced the vertical and horizontal runup as well as the retreat of the upper beach. The experimental results presented suggest that a dynamic cobble berm revetment could be a cheap, efficient and low environmental impact engineering solution for protecting sandy coastlines in a changing climate. Some preliminary design guidelines for coastal engineers are also drawn from this experiment. • A novel experiment was undertaken in the large scale laboratory flume (GWK). • A dynamic cobble berm revetment was tested under water level increase. • The revetment showed a dynamic stability under energetic waves and water level change. • More than 70% of the instrumented cobbles moved landward, under rollover transport. • The presence of the revetment reduced the wave runup and beach face retreat. [ABSTRACT FROM AUTHOR]

Published

2020