Behavior of Granular Column-Improved Clay Under Cyclic Shear Loading

A critical performance aspect of FRP retrofitted concrete elements is the bonding of the FRP sheet to the concrete surface. In general, the performance is limited by the debonding of the loaded FRP sheets from the concrete surface. One method to delay debonding and enhance the capacity is the use of FRP anchors which interlock the FRP sheet to the concrete body. FRP anchors are made of rolled FRP fibres epoxied into in predrilled boreholes. There are a considerable number of studies on FRP strengthening methods available, and also FRP anchors attract more attention of the research community recently. However, to date FRP anchors were tested in a system together with the FRP sheet attached to the concrete, inhibiting the development of general design models. Moreover, the anchor behaviour was never tested for cyclic loads, though most applications are for seismic retrofitting schemes and cyclic shear loading generally results in reduced load capacity due to fatigue failure. To overcome the deficit in knowledge, shear tests on various FRP anchors were carried out. For these tests, FRP anchors were installed in concrete specimens on a separating steel section. The FRP anchor was then directly loaded to determine the capacity of the isolated component. This paper describes the testing approach and procedure. Details on the experimental results for static tests are presented and an outlook on seismic tests is given.

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Interlaminar Damage Behavior of CFRP Composite Laminates under Cyclic Shear Loading Conditions

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1125.121 ◽

2015 ◽

Vol 1125 ◽

pp. 121-125 ◽

Cited By ~ 1

Author(s):

Muhammad A'imullah Abdullah ◽

Mohammad Reza Arjmandi ◽

Seyed Saeid Rahimian Koloor ◽

King Jye Wong ◽

Mohd Nasir Tamin

Keyword(s):

Composite Laminates ◽

Quantitative Description ◽

Shear Loading ◽

Zone Model ◽

Fe Model ◽

Critical Energy Release Rate ◽

Cyclic Shear ◽

Load Amplitude ◽

Cfrp Composite ◽

Interlaminar Damage

This paper provides quantitative description of interlaminar damage process in CFRP composite laminates under cyclic shear loading. Quasi-static end-notched flexural (ENF) test on 16-ply CFRP composite laminate beam, [0]16 and its complementary validated FE model provide the reference “no-interlaminar damage” condition. Two identical ENF samples were fatigue to 50000 cycles, but at different load amplitude of 90 and 180 N, respectively (Load ratio, R = 0.1) to induce selectively property degradation at the interface crack front region. Subsequent quasi-static ENF tests establish the characteristic of the interlaminar damage degradation. The residual peak load for the fatigued ENF samples is measured at 1048 and 914 N for the load amplitude of 90 and 180 N, respectively. Cyclic interlaminar shear damage is represented by a linear degradation of the residual critical energy release rate, GIIC with the accumulated damage. Reasonably close comparisons of the predicted residual load-displacement responses with measured curves serve to verify the suitability of the assumed bilinear traction-separation law for the cyclic cohesive zone model (CCZM) used.

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Optimization of Tack Coat Application Rate for Geocomposite Membrane on Bridge Decks

Transportation Research Record Journal of the Transportation Research Board ◽

10.3141/1740-18 ◽

2000 ◽

Vol 1740 (1) ◽

pp. 143-150 ◽

Cited By ~ 20

Author(s):

Erin P. Donovan ◽

Imad L. Al-Qadi ◽

Amara Loulizi

Keyword(s):

Bridge Decks ◽

Asphalt Binder ◽

Application Rate ◽

Shear Loading ◽

Cyclic Shear ◽

Applied Loading ◽

Tack Coat ◽

Concrete Bridge Deck ◽

Critical Components ◽

Nonwoven Geotextile

One of the critical components of the U.S. civil infrastructure, bridges, has rapidly deteriorated in the past two decades and is in need of maintenance and rehabilitation. Geosynthetics may have the potential to provide a long-term solution to some of the problems that are present in these bridges, mainly, chloride intrusion into bridge decks. When installed properly, geosynthetics can act as both a moisture barrier and a stress absorption layer. However, the tack coat application rate is critical, as an excessive amount can cause eventual slippage, whereas too little may result in debonding. A new geocomposite membrane that comprises a low-modulus polyvinyl chloride layer sandwiched between two layers of nonwoven geotextile has recently been introduced for use in highway systems for water impermeation and strain energy absorption. A laboratory testing program was conducted to determine the optimum asphalt binder tack coat application rate that needs to be applied in the field. To accomplish this, a fixture was designed to allow the application of cyclic shear loading at the geocomposite membrane interface when used as an interlayer simulating a concrete bridge deck overlaid with the geocomposite membrane and a hot-mix asphalt (HMA) overlay. The study concluded that 1.75 kg of PG 64-22 binder per m2 is an optimum value to achieve excellent bonding and minimum slippage potential. For the upper surface in contact with a wearing surface mix, a tack coat application rate of 1.5 kg/m2 may be used. When the geocomposite membrane was included between concrete and HMA, failure occurred after a much larger number of applied loading cycles than the number of loading cycles to failure when the geocomposite was absent. In addition, the slope of shear stress versus the number of loading cycles at failure was much greater when the geocomposite was absent.

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Methodology for extracting interface damage properties of FRP composite laminates under cyclic shear loading conditions

2017 3rd International Conference on Power Generation Systems and Renewable Energy Technologies (PGSRET) ◽

10.1109/pgsret.2017.8251827 ◽

2017 ◽

Author(s):

M. A. Abdullah ◽

A. Abdul-Latif ◽

M. N. Tamin

Keyword(s):

Composite Laminates ◽

Shear Loading ◽

Loading Conditions ◽

Cyclic Shear ◽

Interface Damage ◽

Frp Composite

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A Comparative Study of the Response of Double Shearing and Hypoplastic Models

Materials: Processing, Characterization and Modeling of Novel Nano-Engineered and Surface Engineered Materials ◽

10.1115/imece2002-32500 ◽

2002 ◽

Cited By ~ 1

Author(s):

Huaning Zhu ◽

Morteza M. Mehrabadi ◽

Mehrdad Massoudi

Keyword(s):

Cyclic Loading ◽

Mechanical Response ◽

Constitutive Relations ◽

Constitutive Models ◽

Shear Loading ◽

Biaxial Compression ◽

Finite Element Program ◽

Cyclic Shear ◽

Hypoplastic Model ◽

Element Program

The principal objective of this paper is to compare the mechanical response of a double shearing model with that of a hypoplastic model under biaxial compression and under cyclic shear loading. As the origins and nature of these two models are completely different, it is interesting to compare the predictions of these two models. The constitutive relations of the double shearing and the hypoplastic models are implemented in the finite element program ABACUS/Explicit. It is found that the hypoplastic and the double shearing constitutive models both show strong capability in capturing the essential behavior of granular materials. In particular, under the condition of non-cyclic loading, the stress ratio and void ratio predictions of the double shearing and the hypoplastic models are relatively close, while under the condition of cyclic loading, the predictions of these models are quite different. It is important to note that in the double shearing model employed in this comparison the shear rates on the two slip systems are assumed to be equal. Hence, the conclusions derived in this comparison pertain only to this particular double shearing model. Similarly, the hypoplasticity model considered here is that proposed by Wu, et al. [30] and the conclusions reached here pertain only to this particular hypoplasticity model.

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