A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Horizontal Pullout Resistance for a Group of Two Vertical Plate Anchors in Clays
Abstract The horizontal pullout capacity of a group of two rigid strip plate anchors embedded along the same vertical plane in clays, under undrained condition, has been determined. An increase of cohesion with depth has also been incorporated. The analysis has been performed by using an upper bound finite element limit analysis in combination with linear optimization. For different clear spacing (S) between the anchors, the efficiency factor ($ η_{cγ} $) has been determined to evaluate the group failure load for different values of (1) embedment ratio (H/B), (2) the normalized rate (m) which accounts for a linear increase of cohesion with depth, and (3) normalized unit weight (γH/$ c_{o} $). The magnitude of the group failure load (1) becomes maximum corresponding to a certain spacing ($ S_{cr} $) between the anchors, and (2) increases with an increase in the γH/$ c_{o} $ up to a certain value before attaining a certain maximum magnitude. The value of $ S_{cr} $/B has been found to vary generally between 0.7 and 1.2. The maximum magnitude of $ η_{cγ} $, associated with the critical spacing, (1) increases generally with increases in H/B, and (2) decreases with an increase in m. For a greater spacing between the anchors, the analysis reveals the development of a local shear zone around the lower anchor plate. The numerical results developed are expected to be useful for purpose of design.
Horizontal Pullout Resistance for a Group of Two Vertical Plate Anchors in Clays
Abstract The horizontal pullout capacity of a group of two rigid strip plate anchors embedded along the same vertical plane in clays, under undrained condition, has been determined. An increase of cohesion with depth has also been incorporated. The analysis has been performed by using an upper bound finite element limit analysis in combination with linear optimization. For different clear spacing (S) between the anchors, the efficiency factor ($ η_{cγ} $) has been determined to evaluate the group failure load for different values of (1) embedment ratio (H/B), (2) the normalized rate (m) which accounts for a linear increase of cohesion with depth, and (3) normalized unit weight (γH/$ c_{o} $). The magnitude of the group failure load (1) becomes maximum corresponding to a certain spacing ($ S_{cr} $) between the anchors, and (2) increases with an increase in the γH/$ c_{o} $ up to a certain value before attaining a certain maximum magnitude. The value of $ S_{cr} $/B has been found to vary generally between 0.7 and 1.2. The maximum magnitude of $ η_{cγ} $, associated with the critical spacing, (1) increases generally with increases in H/B, and (2) decreases with an increase in m. For a greater spacing between the anchors, the analysis reveals the development of a local shear zone around the lower anchor plate. The numerical results developed are expected to be useful for purpose of design.
Horizontal Pullout Resistance for a Group of Two Vertical Plate Anchors in Clays
Sahoo, Jagdish Prasad (author) / Kumar, Jyant (author)
2012
Article (Journal)
English
Horizontal Pullout Resistance for a Group of Two Vertical Plate Anchors in Clays
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