Technical sheet

A.01A.02

SystemS-63

Insulated concrete formwork (ICF) wall

A load-bearing reinforced-concrete wall cast inside polystyrene formwork blocks that stay in place. The blocks interlock dry like toy bricks, are reinforced and filled with concrete: the wall is born already insulated on both faces, without thermal bridges and with great inertia. It is a fast and very energy-efficient system, where the care lies in the pour and in the fire protection of the polystyrene.

PareteR.C. cast within insulating EPS formwork

B.01

System build-up5 layers

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

R.C. cast within insulating EPS formwork

Nucleo in c.a.

15-20cm

Isolante (per faccia)

5-7 (+)cm

Trasmittanza U

0,12-0,25W/m2K

Inerzia termica

alta (massa interna)

Reazione al fuoco

EPS protetto (rivestito)

Montaggio

a secco + getto

Descriptive memo

The ICF wall - Insulated Concrete Forms - turns the usual order upside down. Instead of building the wall and then insulating it, hollow polystyrene blocks are dry-stacked as permanent formwork; reinforcement is placed in their cavity and concrete is poured, which on hardening becomes the load-bearing structure. The forms are not removed: they stay to insulate the wall forever.

Insulation inside and out, no thermal bridges

The concrete is enclosed between two continuous polystyrene leaves, inner and outer. The insulation is uninterrupted by columns or beams - they are inside the pour - so the wall is free of the thermal bridges that plague traditional walls. The central concrete mass, protected by the insulation, adds thermal inertia: it damps the peaks of heat and cold and stabilises the indoor temperature.

The pour: the critical moment

All the soundness of the system depends on the pour. The concrete must be placed fluid but controlled, in limited lifts and well vibrated, so it fills every corner without voids and without pushing too hard on the light forms. Excessive pressure deforms them or bursts them (blow-out): hence they are propped, braced and poured in layers. It is reinforced-concrete work in every sense, with the added fragility of a polystyrene formwork.

Fire, finishes, fixings

Polystyrene is combustible: by law it must always be protected by a covering that delays its contribution to a fire - render outside, plasterboard inside. All finishes are made on those faces. Hung loads (brackets, cabinets) are not fixed to the EPS but anchored to the concrete behind with suitable fixings. With these points taken care of, what remains is a robust, quiet, earthquake-resistant wall with excellent energy performance.

Systems architecture

Why it works

Continuous insulation, mass in the middle

An ICF wall is, in section, a concrete sandwich: a structural core of reinforced concrete with a continuous slab of polystyrene on each face, the whole thing cast inside formwork blocks that are never removed. That simple arrangement quietly solves the hardest problem of a masonry or framed wall — the thermal bridge. Because the insulation runs unbroken on both sides, with no beam, column or floor edge piercing it, the heat-loss «leaks» that normally form at those junctions are simply not there, and the temperature falls almost entirely across the two polystyrene layers. Meanwhile the heavy concrete core, kept warm on the inside of the insulation, stores heat and gives the wall a thermal inertia that damps the day-night swings — comfort in summer, stability in winter, and good airborne sound insulation as a bonus. The price of all this is paid at the pour: the concrete has to be placed and vibrated carefully, in lifts, so it fills the forms completely without bursting them, and the combustible polystyrene must always be covered by a fire-protective render or board, with heavy loads fixed through to the concrete behind.

Insulation and speed in one wall

Comparison · insulants

ICF wall

all-in-one

R.C. + external insulation

good, slower

Insulated block masonry

fair

Bare R.C. wall

cold, bridged

Longer bar = the more the wall delivers insulation, thermal mass and structure together, fast. The ICF wall arrives already insulated on both faces and bridge-free, where other walls need a separate insulation trade to get there.

Nodal details

Critical junctions · sections

D.01

The formwork block (interlock)

Two hollow polystyrene blocks, stacked dry. Their top and bottom edges interlock like a building brick, so a course locates itself on the one below without glue or mortar. Plastic webs cast into the block hold the two EPS faces a fixed distance apart and carry the steel reinforcement in the cavity between them. Concrete poured into that continuous cavity fills it and, on hardening, becomes a monolithic reinforced wall - permanently jacketed in insulation on both faces.

Outer form (EPS)
Web tie of the block
Pour cavity (R.C.)
Interlock between courses
Reinforcement
Inner form (EPS)

D.02

The floor junction

Where a floor lands on the wall, the inner polystyrene is interrupted to let the slab bear on the concrete core, and the wall steel runs on past so the structure is continuous. Two things must be looked after at that gap: the outer insulation is kept unbroken across the floor edge so no thermal bridge forms, and the interruption on the inside is fire-stopped and re-insulated, since the exposed polystyrene must never be left as a path for fire.

ICF wall (core)
Floor (bearing)
Continuity of reinforcement
Fire-protective lining
Continuous outer insulation
Form stopped at the floor

Installation controls

Specification · checklist

01 · Forms

Blocks interlocked

Plumb and braced

Bucks at openings

02 · Reinforcement

Bars to design

Laps and corners

Cover in the cavity

03 · Pour

Limited lifts

Vibrated, no voids

Alignment watched

04 · Thermal

Insulation continuous

Floor edges wrapped

Bridges avoided

05 · Fire & finish

Lining to rating

No exposed EPS

Loads fixed to concrete

Recurring defects

Diagnostics · site

Meccanica

Bursting and instability of the forms during the pour

CauseThe fresh concrete pushes hard on the light polystyrene forms; poured too fast, too high or unbraced, they bow, go out of plumb or burst open (blow-out), wrecking the wall line.

PreventionPouring in limited lifts, propping and bracing, a controlled-fluidity mix, corners and openings reinforced, the alignment watched as it goes.

Termica

Thermal bridges at floors and openings

CauseWhere a floor lands or an opening is formed, the continuous insulation is broken; if the gap is not re-insulated it becomes a cold line, with heat loss and condensation risk.

PreventionInsulated bucks at openings, the outer insulation kept continuous over floor edges, the interruptions re-insulated, the junctions detailed thermally.

Termo-igrometrica

Fire behaviour of the EPS

CausePolystyrene is combustible and gives off smoke; left exposed, or covered with too thin a lining, it is a fire risk that the law does not allow.

PreventionA fire-protective lining to the rating (plasterboard inside, render outside), no exposed EPS, fire-stops at junctions, the cover thickness verified.

Termo-igrometrica

Rising damp at the base

CauseThe polystyrene and the concrete can wick and hold moisture from the ground at the foot of the wall, wetting the base and feeding damp into the finishes.

PreventionA damp-proof course at the base, a kicker above grade, drainage, the foot detailed against capillary rise.

Component materials

The network · materials

Expanded Synthetic Polymers

EPS — Expanded Polystyrene

Structural conglomerate

Reinforced Concrete

Rigid Hydraulic Mortar

Cement Plaster

Reference regulations

2 norms

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