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Goseberg, Nils [Author]; Schlurmann, Torsten [Author]

Non-stationary flow around buildings during run-up of tsunami waves on a plain beach - [published Version]

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  • Media type: Text; E-Article
  • Title: Non-stationary flow around buildings during run-up of tsunami waves on a plain beach
  • Contributor: Goseberg, Nils [Author]; Schlurmann, Torsten [Author]
  • Published: Reston : American Society of Civil Engineers (ASCE), 2014
  • Published in: Proceedings of the Coastal Engineering Conference (2014)
  • Issue: published Version
  • Language: English
  • DOI: https://doi.org/10.15488/894
  • ISSN: 2156-1028
  • Keywords: Long wave ; Tsunami ; Beaches ; Konferenzschrift ; Obstacle ; Experimental investigations ; Coastal engineering ; Wave-structure interaction ; Spatiotemporal evolution ; Wave run-up ; Wake angle ; Long waves ; Side-by-side arrangements ; Non-stationary flows ; Wakes
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  • Description: This paper presents an experimental investigation that focuses on some predominant flow features that arise around surface mounted vertical obstacles which are exposed to a transient flow. The flow under investigation is caused by a tsunami-like long wave that climbs up a 1:40 sloping plain beach. In this study the wave height in offshore waters is varied. A single obstacle of 10 cm width as well as side-by-side arrangement of two identical square obstacles with different spacing are considered at an approximate length scale of 1 in 100. The analysis reveals important flow features around the various obstacle configurations. Particular emphasize is laid on the spatiotemporal evolution of the wake angle that linearly increases over time irrespective of the obstacle spacing. The growth rate of the wake angle reciprocally depends on the gap ratio over the investigated range of g† = 0.0 to g† = 3.0.
  • Access State: Open Access
  • Rights information: Attribution (CC BY)