Single-lap shear bond tests on Steel Reinforced Geopolymeric Matrix-concrete joints

Bencardino, Francesco; Condello, Antonio; Ashour, Ashraf

doi:10.1016/j.compositesb.2016.11.005

Cited by 44 publications

(49 citation statements)

References 39 publications

(74 reference statements)

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“…This is because of the fact that there is an effective bond length, beyond which, no significant increase in the maximum load occurs. The effective bond length is typically in the range of 150 to 250 mm [5][6][7]15]. As such, it would be misleading to calculate values of the bond strength (max) based on results of specimens with a bonded length greater than the effective bond length.…”

Section: Load-global Slip Relationshipmentioning

confidence: 99%

“…The use of inorganic alkali-activated geopolymeric matrices with ground industrial waste materials, alternative to the polymeric resins and cementitious mortars, would offer a sustainable and eco-friendly strengthening solution. Few studies focused on studying the structural behavior of concrete elements strengthened with fabric-reinforced geopolymeric matrix (FRGM) strengthening systems [13][14][15]. Vasconcelos et al [13] employed metakaolin-based geopolymer mortar as a sustainable alternative to commercial mortars.…”

Section: Introductionmentioning

confidence: 99%

“…Due to its limited fluidity, the geopolymer matrix was unable to penetrate into the carbon fiber filament yarns and transfer the load to the carbon fiber reinforcement. Bencardino et al [15] examined the bond behavior of steel-reinforced geopolymeric matrix-concrete joints in single-lap shear bond tests. An effective bond length of 200 mm was required to develop the maximum bond strength.…”

Section: Introductionmentioning

confidence: 99%

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Bond Behavior of Fabric-Reinforced Geopolymeric Matrix System – A Pilot Study

Obaida¹,

El‐Maaddawy²,

El-Hassan³

2019

World Congress on Civil, Structural, and Environmental Engineering

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This paper presents results of a pilot study carried out to investigate the feasibility and viability of producing a sustainable and eco-friendly structural strengthening solution involving the use of cement-free alkali-activated geopolymeric matrix and carbon fabric textiles. The study focused on examining the bond behavior at the fabric-geopolymeric matrix interface through single-lap shear tests. The geopolymeric matrix was a blend of fly ash/ground granulated blast furnace slag (GGBS) activated by an alkaline solution of sodium silicate and sodium hydroxide. Test parameters included the bonded length, configuration of the textile fabrics, and composition of the matrix. The bond behavior of the specimens with a geopolymeric matrix was characterized and compared to that of similar specimens with a cementitious matrix. All specimen exhibited a debonding mode of failure at the fabric-matrix interface. The bond strength of a specimen with a bi-directional fabric was higher than that of a similar specimen with a unidirectional fabric. The bond strength of the specimens with the geopolymeric matrix was even higher than that of similar specimens with the cementitious matrix. Increasing the fly ash-to-GGBS ratio in the geopolymeric matrix slightly decreased the bond strength but improved the post-peak behavior of the tested specimens.

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Section: Load-global Slip Relationshipmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Bond Behavior of Fabric-Reinforced Geopolymeric Matrix System – A Pilot Study

Obaida¹,

El‐Maaddawy²,

El-Hassan³

2019

World Congress on Civil, Structural, and Environmental Engineering

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“…Using combining composite textiles and inorganic matrices, resulting in what is related to with various names: textile-reinforced concrete (TRC), textile-reinforced mortar (TRM), fabric/fiber reinforced cementitious matrix (FRCM), steel reinforced grout (SRG) and others. Reinforcing fabrics/fibers could be made of steel [2], basalt [3], polyparaphenylene-benzobisoxazole (PBO) [4], carbon [5], aramid or glass [6] and basalt. Many experimental works are available in the literature on FRCM/SRG-concrete bond tests [2][3][4][5][6], flexural strengthening using traditional [7] and innovative eco-friendly [8] technique and on axial behavior of confined masonry columns [9].…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation and Numerical Analysis of Bond Behavior in SRG-Strengthened Masonry Prisms Using UHTSS and Stainless-Steel Fibers

Bencardino

Nisticò

Verre

2020

Fibers

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This paper deals with the experimental and numerical study of the bond behavior of two steel reinforced grout (SRG)-strengthened masonry systems. Ten shear bond tests were carried out on prismatic masonry specimens. The data of experimental tests are recorded and results are given in terms of load/stress-global slip curves, failure modes, tables, graphs and photographic reports, comparing the results of the two strengthening systems. Two kinds of steel fibers available in marketplace were used: ultra-high tensile strength steel galvanized micro-cords and stainless-steel strands. The main target is to obtain information on the behavior of the bond between masonry surface and the two types of SRG composites, which are characterized by two substantial differences: tensile strength with a ratio of 2.4 and the corresponding surface mass density with a ratio of 0.30. Finally, the influence of the matrices coupled with the two systems is critically analyzed. The characterization of the bond behavior is necessary in order to confirm the performance of the SRG systems that have become increasingly used and attractive. It also aims to make a contribution to the existing knowledge especially in relation to the use of low resistance steel fibers (stainless steel) which are still few studied today. Furthermore, using a suitable interface law proposed in the literature, a numerical model is defined and employed to simulate the behavior of the specimens tested in the laboratory. The comparisons show a good agreement between numerical and experimental results in terms of the maximum load, load versus global-slip curves, and crack patterns.

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“…With reference to FRP-concrete end debonding, it is well-known that the corresponding mechanical behavior can be modeled via a cohesive law, that allows also the prediction of the mode II fracture mechanism experimentally observed in failure of strengthened systems [16][17][18][19][20]. Several researchers are being studied this local failure mechanism by proposing different test setups, generally based on either linear variable displacement transducers (LVDTs) or laser meter devices installed on composite plate and located at the beginning of bonded area, as well as on strain gauges, positioned along longitudinal direction [21][22][23]. Some recent studies have introduced a non-contact optical technique, digital image correlation (DIC), to obtain the FRPconcrete slip on extended areas of tested specimen rather than only on the beginning of bonded area [24][25][26][27][28][29][30][31][32].…”

Section: Introductionmentioning

confidence: 99%

Cohesive fracture in composite systems: experimental setup and first results

Berardi¹,

Perrella²,

Cricrı̀³

2019

Frattura Ed Integrità Strutturale

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Composite systems are widely used in many engineering applications for new structures and strengthening of existing ones. Within the structural rehabilitation of civil constructions, the plating technique of beams with Fiber Reinforced Polymer (FRP) represents a quick and optimal intervention with respect to traditional ones. The failure of these composite systems usually occurs due to the FRP debonding, which corresponds to a mode II fracture of concrete specimens. In this paper, a new experimental setup for investigating the mode II fracture behavior of FRP-concrete composite structures is presented. The test equipment consists of both conventional equipment and a non-contact optical technique, Digital Image Correlation (DIC), and the test system was realized at the Design Machine Laboratory of the University of Salerno. A preliminary test was performed and the corresponding results are shown and discussed.

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Single-lap shear bond tests on Steel Reinforced Geopolymeric Matrix-concrete joints

Cited by 44 publications

References 39 publications

Bond Behavior of Fabric-Reinforced Geopolymeric Matrix System – A Pilot Study

Bond Behavior of Fabric-Reinforced Geopolymeric Matrix System – A Pilot Study

Experimental Investigation and Numerical Analysis of Bond Behavior in SRG-Strengthened Masonry Prisms Using UHTSS and Stainless-Steel Fibers

Cohesive fracture in composite systems: experimental setup and first results

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