Enhancement the Fatigue Life of Floating Breakwater Mooring System Using Tuned Liquid Column Damper

Shahrabi, Mostafa; Bargi, Khosrow

doi:10.1590/1679-78255692

Cited by 3 publications

(2 citation statements)

References 33 publications

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“…Additionaly, Ghosh and Basu (2004); Chakraborty et al (2012) and Espinoza et al (2018) verify the efficiency of the TLCD in the control of seismic excitations. The tuned liquid column damper can also ensure operational safety and increase the fatigue life of the structures to which they are coupled as Shahrabi and Bargi (2019) demonstrate through an analytical and numerical study.…”

Section: Introductionmentioning

confidence: 96%

Effects of soil-structure interaction in seismic analysis of buildings with multiple pressurized tuned liquid column dampers

Mendes

Ribeiro

Pedroso

2019

Lat. Am. j. solids struct.

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In this paper soil-structure interaction (SSI) effects are investigated while an array of Pressurized Tuned Liquid Column Dampers (PTLCD) is employed for seismic vibration control of buildings. This device represents the most general case of a passive damper, with different reduction options to other control devices obtained by simplifying the involved parameters. Soil conditions considerably affect the control device functioning, because dynamic parameters such as natural frequency, damping factor, and natural modes depend on the soil properties. A simplified mathematical model is developed for the building with multiple degrees of freedom connected to a flexible base. For the time-domain analysis, a computational routine is developed for the linearization of the equilibrium equations of the PTLCD, as well as details for the reduction to the other types of passive dampers. Several numerical examples are selected for the analysis of the damper efficiency in reducing seismic vibration considering SSI. These simulations include Kobe earthquake data, which is applied to the model to evaluate the device performance under different scenarios. It is verified the influence of SSI in the natural frequency and structural response, which is related to the earthquake frequency components. Results confirm that the array of PTLCD's can reduce the vibration amplitudes, being more effective for soils with higher stiffness values.

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Section: Introductionmentioning

confidence: 96%

Effects of soil-structure interaction in seismic analysis of buildings with multiple pressurized tuned liquid column dampers

Mendes

Ribeiro

Pedroso

2019

Lat. Am. j. solids struct.

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“…The relationship between man-made structures and the ocean environment is an essential issue in Oceanic Engineering. Since all the structures in offshore and coastal areas -such as Floating Breakwaters (FBWs) -are exposed to water waves, it is necessary to analyze the effects of such structures on the surrounding wave domain (Abbasnia and Ghiasi (2014); Shahrabi and Bargi (2019)). By assuming linear waves and employing the superposition principle, in the investigation of wave-floating structures interaction, two distinct phenomena should be considered (Abul-Azm and Gesraha, 2000;Kao et al, 2015;Cho, 2016).…”

Section: Introductionmentioning

confidence: 99%

Extracting the Solution of Three-Dimensional Wave Diffraction Problem from Two-Dimensional Analysis by Introducing an Artificial Neural Network for Floating Objects

Fouladi

Badiei

Vahdani

2020

Lat. Am. j. solids struct.

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The diffraction of the waves from the two ends of floating breakwaters (FBWs) that have limited length, are practically a three-dimensional (3D). In order to perform a two-dimensional vertical (2DV) analysis to solve the wave diffraction problem, some "correcting factors" are required to modify the 2DV results and make them comparable and verifiable against 3D solutions. The main objective of the current study is to propose a method to obtain these correcting factors and demonstrate its usefulness through some example cases. An Artificial Neural Network (ANN) is trained by three main non-dimensional independent variables to predict the mentioned factors. In order to set up the ANN, a database including both 2DV and 3D results is required. The 2DV results are obtained by employing a semi-analytical method, namely the Scaled Boundary Finite Element Method (SBFEM). A basic change in the location of the scaling center is implemented. The 3D results are obtained via ANSYS AQWA software. Eighty-one cases are simulated on a floating object with rectangular cross-sections. The correlation factor 0.9607 R  for a group of new samples shows that the predicted results are closely matched to the target values. The correcting factor applies the 3D effects of diffracted waves around the structures on 2DV results and produces a more accurate prediction.

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Numerical Investigation into Effect Section Geometry parameters of Floating Breakwaters in single and double rows on its Hydrodynamics performance

Yousefi,

Mahmoudi,

Hajizadeh

2023

Marine Engineering

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Enhancement the Fatigue Life of Floating Breakwater Mooring System Using Tuned Liquid Column Damper

Cited by 3 publications

References 33 publications

Effects of soil-structure interaction in seismic analysis of buildings with multiple pressurized tuned liquid column dampers

Effects of soil-structure interaction in seismic analysis of buildings with multiple pressurized tuned liquid column dampers

Extracting the Solution of Three-Dimensional Wave Diffraction Problem from Two-Dimensional Analysis by Introducing an Artificial Neural Network for Floating Objects

Numerical Investigation into Effect Section Geometry parameters of Floating Breakwaters in single and double rows on its Hydrodynamics performance

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