Laboratory Tests and Numerical Simulations of CFRP Strengthened RC Pier Subjected to Barge Impact Load

Sha, Yanyan; Hao, Hong

doi:10.1142/s0219455414500370

Cited by 66 publications

(30 citation statements)

References 19 publications

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“…Barge collisions upon bridge structures were also frequently reported. Such collisions can often lead to catastrophic consequences including human casualties and economic losses; thus substantial investigations regarding the quantification of barge impact loading and dynamic structural responses have been conducted in recent years [3][4][5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

“…e problems related to the above mentioned protective structures have led to the investigation of bridge protections from impact by strengthening the bridge piers themselves, for example, with carbon fibre-reinforced polymers (CFRPs) [6,14]. Such strengthening techniques can improve the pier resistance; that is, the pier undergoes less damage during impact.…”

Section: Introductionmentioning

confidence: 99%

“…Such strengthening techniques can improve the pier resistance; that is, the pier undergoes less damage during impact. However, such technique cannot reduce the maximum impact force; therefore, it is effective for pier protection but not for barge protection [6]. In addition, the studies by Sha and Hao [6] indicate that the effectiveness of the CFRP strengthening technique is very limited regarding the maximum pier displacement.…”

Section: Introductionmentioning

confidence: 99%

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Novel Crashworthy Device for Pier Protection from Barge Impact

Wang

Morgenthal

2018

Advances in Civil Engineering

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Barge impact is a potential hazard for bridge piers located in navigation waterways. Protective structures of different types, for example, dolphin structures, artificial islands, and guiding structures, have been widely used in bridge designs against barge impact. However, such structures often imply high cost and suffer from difficulties in installation as well as maintenance challenges. is paper aims to devise and investigate a new type of crashworthy device which is comprised of vertically supported impact cap connected to the bridge pier using a series of steel beams in a frame-type arrangement. is sacrificial steel structure is designed to form plastic hinges for energy dissipation whilst limiting the force transmitted to the protected pier. e dynamic analysis of the proposed crashworthy device subjected to barge impact is conducted using a simplified impact model previously developed by the authors. e parametric studies in this paper show that the proposed device has a large energy dissipation capacity and that the magnitude of impact force transmitted to the bridge pier can be dramatically reduced. In addition, an optimization model is proposed in this paper to achieve the cost-optimized design of the crashworthy device for a given impact scenario with constraints as per the prescribed design requirements.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Novel Crashworthy Device for Pier Protection from Barge Impact

Wang

Morgenthal

2018

Advances in Civil Engineering

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“…Yuan and Harik [5] and Consolazio and Cowan [6] calculated the impact force of barge collision with rigid bridge piers. Sha and Hao [7,8] further studied vessel-pier collisions with an emphasis on structural damages. Base on the numerical results, they proposed simplified equations for a fast estimation of the collision force [9].…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation of the Collision Damage and Residual Strength of a Floating Bridge Girder

Sha

Amdahl

Dørum

et al. 2018

Volume 11A: Honoring Symposium for Professor Carlos Guedes Soares on Marine Technology and Ocean Engineering

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For bridges across wide and deep waterways, fixed foundation structures are not possible to be built due to technical restrictions. Alternatively, pontoon supported floating bridges which do not require fixed foundations can be installed. As the girders of floating bridges may have a low clearance from the sea level, a critical design consideration is the capability of the girder to resist the collision of passing ships. It is hence important to investigate the collision response of the bridge girder and evaluate girder residual strength after the collision. In this paper, finite element (FE) models of a ship deckhouse and a floating bridge girder are established. The girder response to ship deckhouse collision is investigated through integrated numerical simulations. Parametric studies are conducted to compare the girder response for various girder designs and collision scenarios. The residual strength of the girder after in damaged condition is also investigated. Based on the numerical results, a residual strength index (RSI) is proposed for fast prediction of the girder damage level based on the absorbed energy.

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“…Soleimani et al (2007) conducted impact tests on RC beams, and their results indicate that inertia force cannot be ignored, and it has significant influence on the mechanical performance of the structure. Sha and Hao (2015) conducted pendulum impact tests on RC models strengthened by carbon fiber–reinforced polymer (CFRP) composites. The results show that compared with unstrengthened pier, the strengthened bridge pier has a higher impact resistance capacity and hence endures less structural damage under the same barge impact load.…”

Section: Introductionmentioning

confidence: 99%

The effect of assembling location on the performance of precast concrete beam under impact load

Yan

Sun

Liu

et al. 2017

Advances in Structural Engineering

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With incorporation of assembling joints, precast concrete beams could behave very differently in resisting both static and dynamic loads in comparison to conventional reinforced concrete beams. With no research available on the dynamic behavior of precast concrete beams under impact load, a combined experimental and numerical study is conducted to investigate the dynamic response of precast concrete beams under impact load. The results were also compared with reinforced concrete beams. Four groups of concrete beams were tested with all beams designed with the same reinforcement, but different assembling locations were considered for precast concrete beams. The effects of the assembling location in resisting drop weight impact of precast concrete beams were analyzed. The influence of impact mass and impact velocity on the impact resistance of precast concrete beams were also investigated. The results revealed that the further the assembling location is away from the impact location, the closer the mechanical performance of the precast concrete beam is to that of the reinforced concrete beam. When the assembling location and the impact location coincided, the assembling region suffered from severe local damages. With increased impact velocity and impact energy, the damage mode of the precast concrete beams may change gradually from bending failure to bending-shear failure and eventually to local failure. In addition, the bonding around the assembling interface was found to be effective to resist drop weight impact load regardless of the magnitude of the impact velocity and energy.

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Laboratory Tests and Numerical Simulations of CFRP Strengthened RC Pier Subjected to Barge Impact Load

Cited by 66 publications

References 19 publications

Novel Crashworthy Device for Pier Protection from Barge Impact

Novel Crashworthy Device for Pier Protection from Barge Impact

Numerical Investigation of the Collision Damage and Residual Strength of a Floating Bridge Girder

The effect of assembling location on the performance of precast concrete beam under impact load

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