Pioneering Percussion Driven Earth Anchors (PDEA®) for over 35 Years

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How the System Works

There are three steps to the installation of an anchor system:

DRIVING THE ANCHOR

Illustration of driving a percussion driven earth anchor

REMOVING THE RODS

Illustration of removing the drive rods

LOADLOCKING

Illustration of a Platipus Anchor being loadlocked

The same three basic steps apply to the installation of all anchor systems, from the smallest S2 to the largest B10.

 

 

Typical Anchor Behaviour

Loadlocking anchor on a slope graphic

Loadlock – The first stage is where a load is applied to rotate the anchor into its loadlocked position. Elements of both load and extension are present.

Loadlocking anchor on a slope graph

Compaction & load of anchor on a slope graphic

Compaction & Load – The second stage is where the anchor system is generating a frustum of soil immediately in front of the anchor. At this point load normally increases with minimum extension. The soil type will affect the overall extension.

Compaction & load of anchor on a slope graph

Maximum load range of the anchor on a slope graphic

 Maximum Load Range – The third stage is where the anchor produces its ultimate load. As the anchor load approaches the bearing capacity of the soil, the rate of increase in load will reduce until bearing capacity failure of the soil takes place.

Maximum load range of the anchor on a slope graph

Bearing capacity of the anchor on a slope graphic

Bearing Capacity Failure – Caution: If the mechanical shear strength of the soil is exceeded, the residual load will decrease with continued extension as the anchor shears through the ground.

Bearing capacity of the anchor on a slope graph

Stress Distribution & Bearing Capacity

The stress distribution in front of a loaded anchor can be modeled using foundation theory. The ultimate performance of an anchor within the soil is defined by the load at which the stress concentration immediately in front of the anchor exceeds the bearing capacity of the soil.

Factors that will affect the ultimate performance of the anchor include:-

  • Physical properties of the soil
  • Size of the anchor
  • Depth of installation
  • The load applied

Platipus anchors perform exceptionally well in a granular soil, displaying short loadlock and extension characteristics, a broad frustum of soil immediately in front of the anchor and extremely high loads.

Stiff cohesive soils, such as boulder clays, can also give outstanding results. However, weaker cohesive soils, like soft alluvial clays, can result in long loadlock and extension distances and a small frustum of soil in front of the anchor. Consequently these conditions require a larger size of anchor and if possible a deeper driven depth to achieve design loads.

Granular Non-Cohesive Soil - Terzaghi graphic

Granular Soils (Drained)

Soft Cohesive Soil - Skempton graphic

Cohesive Soils (Undrained)