Understanding the effects of hooked-end steel fibre geometry on the uniaxial tensile behaviour of self-compacting concrete

Abdallah, Sadoon; Rees, D. Andrew S.; Ghaffar, Seyed Hamidreza; Fan, Mizi

doi:10.1016/j.conbuildmat.2018.05.191

Cited by 60 publications

(22 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…3 D, 4 D and 5 D) designated as Dramix V R has been widely reported. [29][30][31] Ghasemi et al 29 have reported the effects of distinct steel fiber proportions in a SCC (i.e. 0.1, 0.3 and 0.5% corresponding with 7.8, 23.5, and 39 kg/m 3 ).…”

Section: Introductionmentioning

confidence: 99%

Study of three distinct self-compacting concretes containing marble/granite powder and hooked-end steel fiber contents

Xavier

Gomes

Melo

et al. 2021

Journal of Composite Materials

View full text Add to dashboard Cite

In this investigation distinctive self-compacting concretes (SCC) containing both marble + granite (MG) powder and hooked-end steel fibers (HESF) are investigated. A mixture of conventional SCC (reference), and other five samples containing MG and steel fiber (SF) contents are provided, i.e. 20MG, 20SF, 30MG + 10SF, 20SF and 30MG + 20 SF. Both the fresh and hardened properties of the modified self-compacting concretes are evaluated. Workability of the SCC samples represented by slump flow, L-box, V-funnel, J-ring and flowability T500 is examined. The properties of hardened state of the SCC samples at 7 and 28 days are also evaluated. Modulus of elasticity, water absortion, voids index (indicatig porosity), and specific mass are attained. Comparisons among specific strengths and consumptions of cement per compressive strengths are also provided. The SCC/30MG/10SF sample has a specific strength ∼50% higher than the conventional SCC sample. When a ratio involving porosity per cement consumption per tensile strength is evaluated, the SCC/30MG/10SF sample has this ratio ∼80% higher than the SCC reference. Additionally, the best result of consumption of cement (CC) per compressive strength (CS) (1.28x lower than the SCC reference) at 28 days is that of the SCC/30MG/10SF sample (5.03 kg/m3. MPa−1). This indicates that an environmentally friendly aspect associated with low relative cost, which is an important parameter to consider in future SCC mixture designing.

show abstract

Section: Introductionmentioning

confidence: 99%

Study of three distinct self-compacting concretes containing marble/granite powder and hooked-end steel fiber contents

Xavier

Gomes

Melo

et al. 2021

Journal of Composite Materials

View full text Add to dashboard Cite

show abstract

“…Given the same fiber volume fraction, the 5D hooked-end fibers have the best flexural performance including the load-carrying capacity and post-peak ductility, followed by the 4D and 3D hooked-end fibers, respectively. This is mainly caused by their better pullout resistance, i.e., higher bond strength and pullout work, as reported by some previous studies [10][11][12]. The higher number of hook ends requires a higher force to bend more plastic hinges; hence, the 5D hooked-end fiber had the highest pullout resistance, followed by the 4D and 3D fiber, based on an assumption that the cement matrix was strong enough.…”

Section: Mechanical Propertiesmentioning

confidence: 60%

“…Such a superior bond performance is achieved because of the improved mechanical anchorage, owing to the increased number of hook ends. The peak and post-peak tensile strengths of steel fiber-reinforced concrete (SFRC) with conventional 3D hooked-end fibers were significantly enhanced by using the 4D and 5D hooked-end fibers, according to a previous study performed by Abdallah et al [11]. The 5D hooked-end fiber specimen only exhibited a re-increase in tensile stress (hardening) after a sudden drop in the stress by matrix cracking because of its stronger pullout resistance than the others (i.e., 3D and 4D hooked-end fibers).…”

Section: Introductionmentioning

confidence: 67%

“…The higher number of hook ends requires a higher force to bend more plastic hinges; hence, the 5D hooked-end fiber had the highest pullout resistance, followed by the 4D and 3D fiber, based on an assumption that the cement matrix was strong enough. Abdallah et al [11] reported that the tensile strength and post-cracking hardening behavior of concrete are enhanced by adding 0.5% and 1% hooked-end steel fibers and the 5D hooked-end fiber results in the best tensile performance. Given the identical fiber volume fractions of 0.5% and 1%, only the specimens with 5D hooked-end fibers exhibited a re-increase in the tensile stress after cracking, called hardening, while the others with 3D and 4D hooked-end fibers did not show the hardening behavior.…”

Section: Mechanical Propertiesmentioning

confidence: 99%

“…In recent years, some researchers [10][11][12][13][14] developed a novel multiple hook-end steel fiber and verified its effectiveness based on pullout and tensile tests. Abdallah and Fan [10] reported that the maximum pullout load and energy of conventional hooked-end steel fibers with three-dimensional (3D) geometry are significantly improved by using four-dimensional (4D) and five-dimensional (5D) geometries.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Effects of Hooked-End Steel Fiber Geometry and Volume Fraction on the Flexural Behavior of Concrete Pedestrian Decks

2019

View full text Add to dashboard Cite

This study investigates the effects of hooked-end fiber geometry and volume fraction on the flexural behavior of concrete pedestrian decks. To achieve this, three different fiber geometries, i.e., three-dimensional (3D), four-dimensional (4D), and five-dimensional (5D), and volume fractions of 0.37%, 0.6%, and 1.0% were considered. Test results indicate that a higher number of hook ends can more effectively enhance the flexural strength and flexural strength margin at all volume fractions than a lower number, so that the order of effectiveness of hooked-end fibers on the flexural strength parameters was as follows: 5D > 4D > 3D. To satisfy the ductility index of 0.39, the amounts of 3D, 4D, and 5D hooked steel fibers should be in the range of 0.98%‒1.10%. Moreover, at a fiber volume fraction of 1.0%, only multiple cracking behaviors were observed, and the numerical results indicated that the volume fraction should be equal to 1.0% to guarantee a deflection-hardening response of pedestrian decks, regardless of the hooked-end fiber geometry. Consequently, a 1.0% by volume of hooked-end steel fiber is recommended to replace the minimum longitudinal steel rebars and guarantee a ductile flexural behavior with multiple cracks for pedestrian decks made of high-strength concrete.

show abstract

Einfluss der Stahlfaserbewehrungsarten auf den Betonversagenswiderstand von Befestigungen

Spyridis

Hufelschulte

Mellios

2022

Beton und Stahlbetonbau

View full text Add to dashboard Cite

Stahlfaserbeton (SFB oder SFRC) ist aufgrund seiner vielen Vorteile ein Standardbaustoff für verschiedene Anwendungsbereiche und seine Verwendung scheint weiter zuzunehmen. Dies spiegelt sich neben zahlreichen wissenschaftlichen Veröffentlichungen und Fachkonferenzen auch in den aktuellsten Regelwerken wider, wie z. B. der DAfStb-Richtlinie Stahlfaserbeton und ihrer jüngsten Ergänzung [1], und vor allem in seiner Aufnahme in die nächste Ausgabe des Eurocode 2 [2]. Die Einbringung von Faserbewehrung zielt darauf ab, Zugkräfte über den Riss hinweg zu übertragen. Dies bedeutet, dass Zugspannungen und Rissfortschritt durch die Fasern lokal aufgehalten werden, bis (i) die Faser selbst reißt, (ii) die Faser aus der Betonmatrix herausgezogen wird oder (iii) der Riss sich lediglich in der Matrix zwischen den verteilten Fasern entwickelt. Es ist daher wichtig darauf hinzuweisen, dass dieses Gesamtverhalten von SFB stark von Art, Form, Material, Zugabemenge, Verteilung, Orientierung und Verbundeigenschaften der Faser in Verbindung mit der Zusammensetzung der Matrix beeinflusst wird (vgl. auch [3-5]). Aufgrund der Vielzahl an Einflussfaktoren wird die Faserwirkung in der jeweiligen Matrix üblicherweise als Zugfestigkeit sowie als Nachrissfestigkeit (z. B. beschrieben durch sogenannte Leistungsklassen) bezeichnet und versuchstechnisch bestimmt [3,5].

show abstract

Understanding the effects of hooked-end steel fibre geometry on the uniaxial tensile behaviour of self-compacting concrete

Cited by 60 publications

References 33 publications

Study of three distinct self-compacting concretes containing marble/granite powder and hooked-end steel fiber contents

Study of three distinct self-compacting concretes containing marble/granite powder and hooked-end steel fiber contents

Effects of Hooked-End Steel Fiber Geometry and Volume Fraction on the Flexural Behavior of Concrete Pedestrian Decks

Einfluss der Stahlfaserbewehrungsarten auf den Betonversagenswiderstand von Befestigungen

Contact Info

Product

Resources

About