Effect of Modelling Inhomogeneous Wave Conditions on Structural Responses of a Very Long Floating Bridge

Jian Dai; Christos Stefanakos; Bernt J. Leira; Hagbart Skage Alsos

doi:10.3390/jmse9050548

Effect of Modelling Inhomogeneous Wave Conditions on Structural Responses of a Very Long Floating Bridge

Journal of Marine Science and Engineering ◽

10.3390/jmse9050548 ◽

2021 ◽

Vol 9 (5) ◽

pp. 548

Author(s):

Jian Dai ◽

Christos Stefanakos ◽

Bernt J. Leira ◽

Hagbart Skage Alsos

Keyword(s):

Water Environment ◽

Bridge Structure ◽

Inhomogeneous Wave ◽

Wave Condition ◽

Analysis And Design ◽

Inhomogeneous Waves ◽

Modelling Analysis ◽

Structural Responses ◽

Floating Bridge ◽

Wave Conditions

Floating bridges are suitable for connecting land parcels separated by wide and deep waterbodies. However, when the span of the crossing becomes very long, the water environment exhibits inhomogeneities which introduce difficulties to the modelling, analysis and design of the bridge structure. The wave inhomogeneity may be described by means of field measurement and/or numerical simulations. Both approaches face complications when the resolution is much refined. It is thus important to examine the effect of the resolution related to the modelling of inhomogeneous waves on the global structural responses. In this study, a hypothetical crossing at the Sulafjord is chosen, and the wave environment in the year 2015 at 10 positions along the crossing is numerically computed. Next, different inhomogeneous wave conditions are established based on the wave data at 3, 5, and 10 positions, respectively. Time-domain simulations are conducted to examine the effect of different modelling approaches of the inhomogeneous wave condition on the global responses of a long, straight and side-anchored floating bridge.

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A Time-Domain Method for Hydroelastic Analysis of Floating Bridges in Inhomogeneous Waves

Volume 9: Offshore Geotechnics; Torgeir Moan Honoring Symposium ◽

10.1115/omae2017-62534 ◽

2017 ◽

Cited By ~ 2

Author(s):

Shixiao Fu ◽

Wei Wei ◽

Shaowu Ou ◽

Torgeir Moan ◽

Shi Deng ◽

...

Keyword(s):

Time Domain ◽

Time Domain Method ◽

Dynamic Responses ◽

Irregular Waves ◽

Frequency Domain Method ◽

Wave Condition ◽

Inhomogeneous Waves ◽

Domain Method ◽

Hydroelastic Analysis ◽

Floating Bridge

Based on the three dimensional potential theory and finite element method (FEM), this paper presented a method for time-domain hydroelastic analysis of a floating bridge in inhomogeneous waves. A floating bridge in both regular and irregular waves, is taken as a numerical example. This method is firstly validated by the comparisons of the results between frequency domain method and presented time domain method under regular wave condition. Then the hydroeleastic responses of the floating bridge in waves with spatially varying significant wave height/peak period are presented, with the purpose to illustrate the feasibility of the proposed method. The primary results at this stage indicate that the inhomogeneity of the waves might affect the structure dynamic responses of the floating bridge in waves.

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Wave load effect analysis of a floating bridge in a fjord considering inhomogeneous wave conditions

Engineering Structures ◽

10.1016/j.engstruct.2018.02.066 ◽

2018 ◽

Vol 163 ◽

pp. 197-214 ◽

Cited By ~ 17

Author(s):

Zhengshun Cheng ◽

Zhen Gao ◽

Torgeir Moan

Keyword(s):

Wave Load ◽

Inhomogeneous Wave ◽

Effect Analysis ◽

Load Effect ◽

Floating Bridge ◽

Wave Conditions

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A Time-Domain Method for Hydroelasticity of a Curved Floating Bridge in Inhomogeneous Waves

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4041581 ◽

2018 ◽

Vol 141 (1) ◽

Cited By ~ 2

Author(s):

Wei Wei ◽

Shixiao Fu ◽

Torgeir Moan ◽

Chunhui Song ◽

Shi Deng ◽

...

Keyword(s):

Time Domain ◽

Time History ◽

Dynamic Responses ◽

Irregular Waves ◽

Inhomogeneous Wave ◽

Inhomogeneous Waves ◽

Hydroelastic Analysis ◽

History Of ◽

Floating Bridge ◽

The Time Domain

This paper presents a time-domain hydroelastic analysis method for bridges supported by floating pontoons in inhomogeneous wave conditions. The inhomogeneous wave effect is accounted for by adopting different wave spectra over different regions along the structure, then the time history of inhomogeneous first-order wave excitation forces on the floating pontoons can be obtained. The frequency-domain hydrodynamic coefficients are transformed into the time-domain hydroelastic model using Cummins' equations. The linear hydroelastic responses of a curved floating bridge with end supports, subjected to irregular waves with spatially varying significant wave heights and peak periods, are investigated. Moreover, sensitive analyses are performed to study the effects of the inhomogeneity on the hydroelastic responses. The primary results indicate that the inhomogeneity of the waves has a significant effect on the dynamic responses of the floating bridge.

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Extreme Wave Condition at Doggerbank

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4033564 ◽

2016 ◽

Vol 138 (4) ◽

Author(s):

Espen Engebretsen ◽

Sverre K. Haver ◽

Dag Myrhaug

Keyword(s):

Wind Turbines ◽

Wind Farm ◽

Offshore Wind ◽

Extreme Condition ◽

Exceedance Probability ◽

Extreme Wave ◽

Sea State ◽

Wave Condition ◽

The North ◽

Wave Conditions

In design of offshore wind turbines, extreme wave conditions are of interest. Usually, the design wave condition is taken as the sea state corresponding to an annual exceedance probability of 2 × 10−2, i.e., a return period of 50 years. A possible location for a future wind farm, consisting of bottom fixed wind turbines, is the Doggerbank area. The water depth in this area varies from about 60 m in the north to about 20 m in the south. The hindcast database NORA10 provides sea state characteristics from 1957 to present over a domain covering Doggerbank. Regarding the deeper areas just north of Doggerbank, this hindcast model is found to be of good quality. Larger uncertainties are associated with the hindcast results as we approach shallower water further south. The purpose of the present study is to compare sea state evolution over Doggerbank as reflected by NORA10 with the results of the commonly used shallow water hindcast model SWAN. The adequacy of the default parameters of SWAN for reflecting changes in wave conditions over a sloping bottom is investigated by comparison with model test results. Extreme wave conditions for two locations 102.5 km apart in a north–south direction are established using NORA10. This is done using both, an all sea states approach and a peak over threshold (POT) approach. Assuming the extremes for the northern position to represent good estimates, the wave evolution southward is analyzed using SWAN. The extreme condition obtained from NORA10 in the northern position is used as input to SWAN and the results from the two hindcast models are compared in the southern position. SWAN seems to suggest a somewhat faster decay over Doggerbank compared to NORA10.

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Simulation of Hurricane Seas in a Multidirectional Wave Basin

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.2919923 ◽

1991 ◽

Vol 113 (3) ◽

pp. 219-227 ◽

Cited By ~ 2

Author(s):

A. Cornett ◽

M. D. Miles

Keyword(s):

Ocean Waves ◽

Entropy Method ◽

Wave Spectra ◽

Single Wave ◽

Wave Condition ◽

Wave Basin ◽

Wide Range ◽

Directional Wave ◽

Wave Conditions ◽

Multidirectional Wave

This paper describes the generation and verification of four realistic sea states in a multidirectional wave basin, each representing a different storm wave condition in the Gulf of Mexico. In all cases, the degree of wave spreading and the mean direction of wave propagation are strongly dependent on frequency. Two of these sea states represent generic design wave conditions typical of hurricanes and winter storms and are defined by JONSWAP wave spectra and parametric spreading functions. Two additional sea states, representing the specific wave activity during hurricanes Betsy and Carmen, are defined by tabulated hindcast estimates of the directional wave energy spectrum. The Maximum Entropy Method (MEM) of directional wave analysis paired with a single-wave probe/ bi-directional current meter sensor is found to be the most satisfactory method to measure multidirectional seas in a wave basin over a wide range of wave conditions. The accuracy of the wave generation and analysis process is verified using residual directional spectra and numerically synthesized signals to supplement those measured in the basin. Reasons for discrepancy between the measured and target directional wave spectra are explored. By attempting to reproduce such challenging sea states, much has been learned about the limitations of simulating real ocean waves in a multidirectional wave basin, and about techniques which can be used to minimize the associated distortions to the directional spectrum.

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Traffic on the Great Lakes and New Labrador Developments

Marine Technology and SNAME News ◽

10.5957/mt1.1968.5.4.347 ◽

1968 ◽

Vol 5 (04) ◽

pp. 347-373

Author(s):

Robert B. Harris

Keyword(s):

Great Lakes ◽

Wave Height ◽

Significant Wave Height ◽

Design Criteria ◽

Severe Storm ◽

Significant Wave ◽

Hood Canal ◽

Floating Bridge ◽

Wave Conditions

On 13 February 1979, the entire west span of the Hood Canal Floating Bridge sank under the action of a very severe storm. Although the significant wave height was estimated as high as 4.7 feet, wind and wave conditions during the storm were well within the design criteria of the bridge.

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