Finite Element Modelling of Anchorage to Concrete Systems at Different Strain Rates

Saeab, Al; Ahmed, Lenda T.

doi:10.22215/etd/2019-13817

Cited by 1 publication

(1 citation statement)

References 96 publications

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“…The issue of the influence of the depth of anchoring on the formation of the angle of the cone of destruction a and the shape of the fracture trajectory (which affects the potential volume Simulations showed a weak effect of anchorage depth (in the considered range of values of this parameter) on the extent of the fracture (failure surface) which slightly deviates from the signaled relationships found in concretes, especially for much larger anchorage depths than realized by studies [49,50] and realized by the presented numerical studies. However, the presented results of the study are consistent with the results of extensive research [51], where the dependence of the failure cone angle but on the anchor pull-out rate (the rate of inflicted deformation of the rock) was demonstrated, while no such dependence on the depth of anchorage was found.…”

Section: Discussionsupporting

confidence: 90%

Influence of Anchor Depth and Friction Coefficient Between Anchor and Rock on the Trajectory of Rock Masses Detachment

Jonak¹,

Karpiński²,

Wójcik³

2023

Adv. Sci. Technol. Res. J.

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This work presents the results of a FEA (Finite Element Analysis) concerning the propagation of the fracture trajectory during the detachment of rock masses. The analysis considers mechanical anchoring parameters, including the depth of anchoring and the friction between the anchor head and the brittle material. The analysis involved varying the effective anchorage depth h ef = 50, 100, and 150 mm, along with considering different coefficients of friction (μ) for the anchor head against the rock, including 0.15, 0.3, and 0.45. The results indicated that within the chosen range of anchorage depths, the extent of damage increases with the depth of anchor embedment. However, the depth of anchoring, considering the studied range of this parameter and the assumed mechanical properties of the rock, did not have a significant effect on the value of the angle cone (α 0 ) during the initial phase of the medium's destruction. For the friction coefficient μ = 0.15, there is a clear deep penetration into the fracture at its initial stage of development (at the initial angle of α 0 = -20°), promoting further spread of the fracture on the free surface. For larger values of the friction coefficient (μ = 0.3 and 0.45) -the trend is less pronounced (α 0 = -2°÷-8°) resulting in a decrease in the crack range.

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Section: Discussionsupporting

confidence: 90%