Technical sheet

A.01A.02

SystemS-49

Embedded retaining wall (soldier-pile)

An embedded retaining wall is a flexible, driven structure: a row of vertical elements — bored piles, micropiles or steel sections — driven into the soil well below the bottom of the excavation. Unlike a gravity wall it resists by embedment, with tie-backs or props for tall heights, and it is the way to dig deep right next to existing buildings.

FondazioniFlexible embedded retaining wall

B.01

System build-up6 layers

Technical section of the system, from inside (left) to outside (right).

Flexible embedded retaining wall

Diametro dei pali

40-80cm

Interasse dei pali

1-3 Ø

Infissione sotto scavo

0,3-0,5 H

Tiranti / puntoni

1-3 ordini

Tipo

berlinese / pali / micropali

Tenuta all'acqua

pali compenetrati / dewatering

Descriptive memo

An embedded retaining wall is a flexible, driven structure: a row of vertical elements — bored piles, micropiles or steel sections — driven into the soil well below the bottom of the excavation. Unlike a gravity wall, which works by weight, it resists by embedment, and it is the way to dig deep next to buildings.

Embedment and passive resistance

Below the excavation bottom, the soil that remains «grips» the elements and provides the passive resistance that balances the thrust of the retained ground. The deeper the dig, the longer the embedment must be: it is this buried, invisible part that holds the wall up. Between the piles, a shotcrete or concrete infill retains the soil.

Tie-backs and props

When the height is great, embedment alone is not enough and the head must be held back: with inclined ground anchors, fixed by a bulb in the stable ground behind, or with props spanning from one side of the excavation to the other. A capping beam links the elements and spreads the forces.

Water and surroundings

A deep excavation lowers the water table and can settle the surrounding ground: dewatering, water ingress between the piles and the settlement of nearby buildings must be controlled and monitored. Made watertight (secant piles, diaphragm), the wall can also become the permanent basement wall.

Systems architecture

Why it works

Embedment and passive resistance

A gravity wall resists by its weight; an embedded wall resists by what is buried. Above the excavation the retained ground pushes the wall (active thrust); below the excavation bottom the soil that is left reacts against it (passive resistance), and it is this — plus any tie-backs at the head — that balances the push. So the buried, invisible length is the whole point: the deeper you dig, the longer the embedment must be, because the part doing the work is the part you can’t see. Where height grows, inclined ground anchors or props hold the head back, and a capping beam shares the forces between the piles.

Suited to deep digs by buildings

Comparison · insulants

Embedded wall (tied)

best

Soldier-pile / micropile

good

Gravity retaining wall

open dig only

Battered open cut

needs space

Longer bar = the better suited to dig deep, hard against existing buildings, with little room. The embedded, anchored wall wins where a gravity wall or an open slope cannot go.

Nodal details

Critical junctions · sections

D.01

Tie-back and capping beam

A capping beam links the pile heads and spreads the load; through it an inclined tie-back reaches back into the stable ground, where a grouted bulb anchors it. Stressed, it pulls the head of the wall back against the thrust — its free length must reach past the failure wedge to the firm ground beyond.

Capping beam
Pile / soldier
Tie-back (strands)
Free length
Grouted bulb
Stable ground

D.02

Infill between the piles (plan)

In plan the piles stand proud and the soil between them arches onto them; a shotcrete infill with a mesh closes the gap and takes the local push, while a weep lets any water out. The closer the piles, the more the soil arches and the lighter the infill can be.

Pile
Pile (adjacent)
Soil arching
Shotcrete infill
Welded mesh
Weep hole

Installation controls

Specification · checklist

01 · Investigation & design

Soil & water profile

Embedment depth

Surcharge and stages

02 · Piles / soldiers

Diameter and spacing

Verticality and depth

Reinforcement / sections

03 · Infill & capping

Shotcrete between piles

Mesh reinforcement

Capping beam

04 · Anchors / props

Tie-back length & bulb

Stressing and testing

Props where used

05 · Water & monitoring

Dewatering / cut-off

Weep / drainage

Settlement monitoring

Recurring defects

Diagnostics · site

Meccanica

Excessive deflection and instability

CauseToo little embedment, missing or under-stressed anchors, or unforeseen loads let the wall bow inwards or fail at the base.

PreventionEmbedment and anchors to design, staged excavation, monitoring of movement, conservative soil parameters.

Meccanica

Settlement of the surrounding ground

CauseWall movement, over-excavation or lowering the water table draws down the soil behind and settles nearby buildings.

PreventionStiff, anchored wall, controlled dewatering, staged dig, monitoring of the adjacent structures.

Termo-igrometrica

Water ingress and leakage between the piles

CauseSpaced piles or a poor infill let groundwater and fines wash into the excavation, undermining the support and the surroundings.

PreventionSecant piles or a cut-off / diaphragm, drainage with filters, dewatering, infill sealed to the piles.

Termo-igrometrica

Corrosion of tie-backs and sections

CauseSteel anchors and soldier sections in aggressive, wet ground lose section to corrosion, especially on permanent works.

PreventionCorrosion protection / double sheathing, sacrificial thickness, grout cover, monitoring on permanent anchors.

Component materials

The network · materials

Structural conglomerate

Reference regulations

1 norm

D.P.R. 380/2001Consolidated Building Act (Testo Unico Edilizia)NazionaleIn force

Informational links to the regulatory framework. Always verify the current text on the official source.