The significance of earthquake-induced dynamic forces in coastal structures design

In the past 20 years, considerable effort has been devoted to replacing the widely used approaches of HIROI, MINIKIN, NAGAI, PLAKIDA and others /1,2,3,4/, for the design of vertical breakwaters under the impact of breaking waves, with improved and more exact calculation methods. However, almost all new theoretical and empirical approaches lacked the support of prototype measurements or test results from model measurements at a larger scale. The difference between the proposed design criteria and classical approaches is sometimes so great that engineers do not have a reliable method for the design of a vertical or composite breakwater. Figure 1 shows the resulting wave forces per unit width due to different theories as a function of the design wave height H.

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Coastal Structures 2003

10.1061/9780784407332 ◽

2004 ◽

Keyword(s):

Coastal Structures

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Coastal Structures and Solutions to Coastal Disasters 2015

10.1061/9780784480311 ◽

2017 ◽

Keyword(s):

Coastal Structures

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Simulation Model of the Dynamic Behavior of a Tire Running Over an Obstacle

Tire Science and Technology ◽

10.2346/1.2148799 ◽

1988 ◽

Vol 16 (2) ◽

pp. 62-77 ◽

Cited By ~ 20

Author(s):

P. Bandel ◽

C. Monguzzi

Keyword(s):

Simulation Model ◽

Dynamic Behavior ◽

Black Box ◽

Box Model ◽

Vehicle Suspension ◽

Empirical Relationships ◽

Static Tests ◽

High Speeds ◽

Dynamic Forces ◽

Vehicle Suspension System

Abstract A “black box” model is described for simulating the dynamic forces transmitted to the vehicle hub by a tire running over an obstacle at high speeds. The tire is reduced to a damped one-degree-of-freedom oscillating system. The five parameters required can be obtained from a test at a given speed. The model input is composed of a series of empirical relationships between the obstacle dimensions and the displacement of the oscillating system. These relationships can be derived from a small number of static tests or by means of static models of the tire itself. The model can constitute the first part of a broader model for description of the tire and vehicle suspension system, as well as indicating the influence of tire parameters on dynamic behavior at low and medium frequencies (0–150 Hz).

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Dynamic Forces behind the Common Currency Risk Factors' Expected Moments

SSRN Electronic Journal ◽

10.2139/ssrn.2994110 ◽

2017 ◽

Author(s):

Jari-Pekka Heinonen

Keyword(s):

Risk Factors ◽

Common Currency ◽

Currency Risk ◽

Dynamic Forces ◽

The Common

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New directions for reinforced concrete coastal structures

Journal of Infrastructure Preservation and Resilience ◽

10.1186/s43065-021-00015-4 ◽

2021 ◽

Vol 2 (1) ◽

Author(s):

Steven Nolan ◽

Marco Rossini ◽

Chase Knight ◽

Antonio Nanni

Keyword(s):

Service Life ◽

Prestressed Concrete ◽

Composite Structures ◽

Construction Materials ◽

Design Guidelines ◽

Coastal Structures ◽

Frp Composites ◽

The Us ◽

Time Dependent Effect ◽

Traditional Construction

AbstractWithin the last century, coastal structures for infrastructure applications have traditionally been constructed with timber, structural steel, and/or steel-reinforced/prestressed concrete. Given asset owners’ desires for increased service-life; reduced maintenance, repair and rehabilitation; liability; resilience; and sustainability, it has become clear that traditional construction materials cannot reliably meet these challenges without periodic and costly intervention. Fiber-Reinforced Polymer (FRP) composites have been successfully utilized for durable bridge applications for several decades, demonstrating their ability to provide reduced maintenance costs, extend service life, and significantly increase design durability. This paper explores a representative sample of these applications, related specifically to internal reinforcement for concrete structures in both passive (RC) and pre-tensioned (PC) applications, and contrasts them with the time-dependent effect and cost of corrosion in transportation infrastructure. Recent development of authoritative design guidelines within the US and international engineering communities is summarized and a examples of RC/PC verses FRP-RC/PC presented to show the sustainable (economic and environmental) advantage of composite structures in the coastal environment.

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EXTREME WAVE PRESSURES AND LOADS ON A PILE-SUPPORTED WHARF DECK - INFLUENCES OF AIR GAP AND WAVE DIRECTION

Coastal Engineering Proceedings ◽

10.9753/icce.v36.waves.5 ◽

2018 ◽

pp. 5

Author(s):

Andrew Cornett

Keyword(s):

Offshore Structures ◽

Model Tests ◽

Scale Model ◽

Extreme Waves ◽

Wave Direction ◽

Coastal Structures ◽

Extreme Wave ◽

Wave Impact ◽

The Past ◽

Water Depths

Many deck-on-pile structures are located in shallow water depths at elevations low enough to be inundated by large waves during intense storms or tsunami. Many researchers have studied wave-in-deck loads over the past decade using a variety of theoretical, experimental, and numerical methods. Wave-in-deck loads on various pile supported coastal structures such as jetties, piers, wharves and bridges have been studied by Tirindelli et al. (2003), Cuomo et al. (2007, 2009), Murali et al. (2009), and Meng et al. (2010). All these authors analyzed data from scale model tests to investigate the pressures and loads on beam and deck elements subject to wave impact under various conditions. Wavein- deck loads on fixed offshore structures have been studied by Murray et al. (1997), Finnigan et al. (1997), Bea et al. (1999, 2001), Baarholm et al. (2004, 2009), and Raaij et al. (2007). These authors have studied both simplified and realistic deck structures using a mixture of theoretical analysis and model tests. Other researchers, including Kendon et al. (2010), Schellin et al. (2009), Lande et al. (2011) and Wemmenhove et al. (2011) have demonstrated that various CFD methods can be used to simulate the interaction of extreme waves with both simple and more realistic deck structures, and predict wave-in-deck pressures and loads.

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