Numerical Modelling and Dynamic Response Analysis of Curved Floating Bridges with a Small Rise-Span Ratio

Wan, Ling; Jiang, Dongqi; Dai, Jian

doi:10.3390/jmse8060467

Cited by 10 publications

(3 citation statements)

References 32 publications

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“…The research on the hydrocarbon storage focuses on the development of the world's first floating prestressed light-weight concrete storage facility with a capacity of 300,000 m3 [1,2]. The research on the floating bridge focuses on developing new design concepts for the ASEAN's first floating bridge spanning over 500 m of shallow waterbody [3,4]. An overview of the research activities on these two studies was given in [5].…”

Section: Introductionmentioning

confidence: 99%

Modular Multi-purpose Floating Structures for Space Creation

Dai

Hellan

Watn

et al. 2021

Lecture Notes in Civil Engineering

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Modular multi-purpose floating structures (MMFS) are an innovative approach for space creation on the sea. The basic idea is to create "land on sea" by connecting a number of standardized modular units to form the desired size and shape for generic applications. The research presented in this paper was part of the multi-purpose floating structure (MPFS) project funded by the Land and Liveability National Innovation Challenge (L2 NIC) Directorate and JTC Corporation in Singapore. This paper presents an overview of the concept development and evaluation of the modular units and inter-modular connectors. Results from detailed structural and hydrodynamic analyses as well as scaled model tests show that the proposed solution is technically feasible. The construction methodology and preliminary cost estimate are also presented and discussed.

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Section: Introductionmentioning

confidence: 99%

Modular Multi-purpose Floating Structures for Space Creation

Dai

Hellan

Watn

et al. 2021

Lecture Notes in Civil Engineering

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“…In recent decades, many long-span sea-crossing bridges have been constructed or are in the planning phase to accelerate worldwide ocean development and promote coastal economics [1][2][3]. As a type of auxiliary facility for construction that can be quickly assembled on the sea, the offshore steel trestles (OSTs) have been widely used to construct sea-crossing bridges.…”

Section: Introductionmentioning

confidence: 99%

Kriging Model for Reliability Analysis of the Offshore Steel Trestle Subjected to Wave and Current Loads

Liu

Shang

Liu

et al. 2021

JMSE

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Offshore steel trestles (OSTs) are exposed to severe marine environments with stochastic wave and current loads, making structural safety assessment challenging and difficult. Reliability analysis is a suitable way to consider both wave and current loading intensity uncertainties, but the implicit and complex limit state functions of the reliability analysis usually imply huge computational costs. This paper proposes an efficient reliability analysis framework for OST using the kriging model of optimal linear unbiased estimation. The surrogate model is built with stochastic waves, current parameters, and the corresponding load factors. The framework is then used to evaluate the reliability of an example OST subjected to wave and current loads at three limit states of OST, including first yield (FY), full plastic (FP), and collapse initiation (CI). Three different distributions are used for comparison of the results of failure probability and reliability index. The results and the computational cost by the proposed framework are compared with that from the Monte Carlo sampling (MCS) and Latin hypercube sampling (LHS) method. The influences of sample number on the prediction accuracy and reliability index are investigated. The influence of marine growth on the reliability analysis of the OST is discussed using MCS and the kriging model. The results show that the reliability analysis based on the kriging model can obtain the reliability index for the OST efficiently with less calculation time but similar results compared with MCS and LHS. With the increase of the number of samples, the prediction accuracy of the kriging model increases, and the corresponding failure probability fluctuates greatly at first and then tends to be stable. The reliability of the example OST is reduced with the increase of marine growth, regardless of the limit state.

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“…A cable-supported bridge with a floating tower has been proposed to control the displacement of cable-stayed bridges by tethers connected to the seabed using TLP type and to compensate for the disadvantages of sea-crossing bridges [4]. Unlike fixed tower bridges or small span floating bridges [5], cable-stayed bridges with floating towers additionally moor the floater connected to the towers, tending to show a more complex nonlinear structural behavior due to the tether-tower-cable-girder interaction. For the purpose of transportation, cable-stayed bridges with floating towers require additional horizontal displacement control, as well as vertical displacement, which is important for conventional floating structures.…”

Section: Introductionmentioning

confidence: 99%

Static Behaviors of a Long-span Cable-Stayed Bridge with a Floating Tower under Dead Loads

Jang

Lee

Won

et al. 2020

JMSE

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Owing to the structural characteristics of floating-type structures, they can be effectively applied to overcome the limitation of conventional long-span bridges in deep water. Unlike cable-supported bridges with fixed towers, floating cable-supported bridges show relatively large displacements and rotations under the same load because of floating towers; moreover, the difference in the support stiffness causes differences in the behavior of the superstructures. In addition, the risk of overturning is greater than in conventional floating offshore structures because the center of gravity of the tower is located above the buoyancy center of the floater. A floating cable-supported bridge in which the tether supports the floating main tower is directly influenced by the tether arrangement, which is very important for the stability of the entire structure. In this study, according to the inclined tether arrangement, the outer diameter of the floater, and the buoyancy vertical load ratio (BVR), the static behavioral characteristics of the long-span cable-stayed bridges with floating tower are evaluated through nonlinear finite-element analysis. When the intersection of the tension line of the tether and a pivot point of the tower coincide, the tethers can no longer resist the tower’s rotation. For this reason, a large displacement occurs to equilibrate the structure, and further increases as it approaches the specific slope, even if it is not exactly the specific tether slope. The analytical model of this study indicates that, in terms of increasing the rotational stiffness of the main tower, it is advantageous to increase the floater diameter until a BVR of 1.8 is reached and to increase the axial stiffness of the tether from a BVR of 2.0 or higher.

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Numerical Modelling and Dynamic Response Analysis of Curved Floating Bridges with a Small Rise-Span Ratio

Cited by 10 publications

References 32 publications

Modular Multi-purpose Floating Structures for Space Creation

Modular Multi-purpose Floating Structures for Space Creation

Kriging Model for Reliability Analysis of the Offshore Steel Trestle Subjected to Wave and Current Loads

Static Behaviors of a Long-span Cable-Stayed Bridge with a Floating Tower under Dead Loads

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