Concrete cone is one of the failure modes of anchors in

concrete Concrete is a composite material composed of fine and coarse aggregate bonded together with a fluid cement (cement paste) that hardens (cures) over time. Concrete is the second-most-used substance in the world after water, and is the most ...

, loaded by a

tensile force In physics, tension is described as the pulling force transmitted axially by the means of a string, a rope, chain, or similar object, or by each end of a rod, truss member, or similar three-dimensional object; tension might also be described as t ...

. The failure is governed by crack growth in concrete, which forms a typical cone shape having the anchor's axis as revolution axis.

Mechanical models

ACI 349-85

Under tension loading, the concrete cone failure surface has 45° inclination. A constant distribution of tensile stresses is then assumed. The concrete cone failure load

N_0

of a single anchor in uncracked concrete unaffected by edge influences or overlapping cones of neighboring anchors is given by:

N_0 = f_

Where:

f_

- tensile strength of concrete

A_

- Cone's projected area

Concrete capacity design (CCD) approach for fastening to concrete

Under tension loading, the concrete capacity of a single anchor is calculated assuming an inclination between the failure surface and surface of the concrete member of about 35°. The concrete cone failure load

N_0

of a single anchor in uncracked concrete unaffected by edge influences or overlapping cones of neighboring anchors is given by:

N_0 = k \sqrt ^

, Where:

k

- 13.5 for post-installed fasteners, 15.5 for cast-in-site fasteners

f_

- Concrete compressive strength measured on cubes Pa

- Embedment depth of the anchor m The model is based on fracture mechanics theory and takes into account the

size effect According to the classical theories of elastic or plastic structures made from a material with non-random strength (''f''t), the nominal strength (''σ''N) of a structure is independent of the structure size (''D'') when geometrically similar st ...

, particularly for the factor

^

which differentiates from

^

expected from the first model. In the case of concrete tensile failure with increasing member size, the failure load increases less than the available failure surface; that means the nominal stress at failure (peak load divided by failure area) decreases. Current codes take into account a reduction of the theoretical concrete cone capacity

N_0

considering: (i) the presence of edges; (ii) the overlapping cones due to group effect; (iii) the presence of an eccentricity of the tension load.

Difference between models

The tension failure loads predicted by the CCD method fits experimental results over a wide range of embedment depth (e.g. 100 - 600 mm). Anchor load bearing capacity provided by ACI 349 does not consider ''size effect'' , thus an underestimated value for the load-carrying capacity is obtained for large embedment depths.

Influence of the head size

For large head size, the bearing pressure in the bearing zone diminishes. An increase of the anchor's load-carrying capacity is observed . Different modification factors were proposed in technical literature.

Un-cracked and cracked concrete

Anchors, experimentally show a lower load-bearing capacity when installed in a cracked concrete member. The reduction is up to 40% with respect to the un-cracked condition, depending on the crack width. The reduction is due to the impossibility to transfer both normal and tangential stresses at the crack plane.

References

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