Influence of embedment length on the pullout behavior of steel fibers from ultra-high-performance concrete

•Pullout behavior of straight and half-hooked fibers from UHPC is influenced by the embedment length.•Shorter embedment length generally provides better pullout resistance of steel fibers from UHPC.•Embedment length effect on the pullout behavior is more significant for the half-hooked fiber than th...

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Bibliographic Details
Published in:Materials letters 2020-10, Vol.276, p.128233, Article 128233
Main Authors: Yoo, Doo-Yeol, Je, Junho, Choi, Hong-Joon, Sukontasukkul, Piti
Format: Article
Language:English
Subjects:
Anchorage effect
Bonding strength
Composite materials
Embedment
Embedment length effect
Fiber pullout
Fibre technology
Inclination angle
Materials science
Pullout behavior
Steel fibers
Ultra high performance concrete
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Summary:•Pullout behavior of straight and half-hooked fibers from UHPC is influenced by the embedment length.•Shorter embedment length generally provides better pullout resistance of steel fibers from UHPC.•Embedment length effect on the pullout behavior is more significant for the half-hooked fiber than the straight fiber.•Maximum aspect ratio of 80 is suggested for the half-hooked fiber in UHPC to prevent premature failure.•45°-inclined steel fibers give better pullout performance than the aligned fibers from UHPC equally. Single fiber pullout behavior has been investigated extensively at various embedment lengths, and to generalize the test results of the existing studies, the implication of embedment length on the pullout behavior needs to be analyzed. To this end, experiments were conducted with two types of steel fibers in ultra-high-performance concrete (UHPC) at three embedment lengths and two inclination angles. The effect of embedment length on the pullout behavior was more significant in the half-hooked fiber than the straight one. Its pullout performance was also better than that of the straight fiber up to an embedment length of 10 mm; however, the effectiveness decreased with an increase in the embedment length. At the longest embedment length of 15 mm, the pullout energy and equivalent bond strength obtained for the half-hooked fiber samples were poorer than those obtained for the straight fibers. Therefore, its maximum length is suggested to be below 30 mm at a diameter of 0.375 mm to prevent premature rupture in UHPC.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2020.128233