Technical sheet

A.01A.02

SystemS-24

Industrial sandwich-panel roof

A lightweight pitched roof for warehouses and logistics, made of self-supporting sandwich panels — two steel sheets enclosing an insulating core — laid on metal purlins. In a single prefabricated element it carries, insulates and weatherproofs: it is laid dry and fast over large areas, with the upper sheet profiled for water run-off and the laps sealed.

CoperturaPrefabricated insulated metal roof

B.01

System build-up5 layers

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

Prefabricated insulated metal roof

Spessore del pannello

40-120mm

Lamiere ext/int

0,4-0,7mm

Luce tra arcarecci

2-6m

Trasmittanza U (PIR)

0,15-0,45W/m2K

Pendenza minima

≥ 7-10%

Reazione al fuoco

B-s2,d0 / A2

Descriptive memo

The sandwich roof panel is the evolution of the simple profiled sheet: between the profiled outer sheet and the flat inner sheet an insulating core (PIR polyurethane or rock wool) is foamed or bonded. The three parts work as one section, so a thin, light panel spans large distances between purlins with no intermediate supports.

Composite behaviour

Under load (snow, wind, maintenance) the upper sheet goes into compression and the lower into tension; without the core the two would slide and buckle at once. The core absorbs the shear and forces them to work together, generating enormous flexural stiffness for the weight. It is the same principle as a composite floor, on a lightweight scale.

Watertightness and insulation

The roof is pitched with a minimum fall: the outer sheet is profiled in tall ribs that channel the water, and the panels lap sideways with a tongue-and-groove joint, often gasketed. The continuous core gives the thermal insulation (very low U-values with PIR) and, in the rock-wool version, the fire resistance and acoustic insulation.

Laying, fixings and thermal movement

Panels are fixed to the purlins with self-drilling screws and sealing caps, in a number and pattern by calculation to resist the wind. The critical points are the fixings (through-holes to seal), the ridges, eaves and rooflights, and thermal movement: a dark sheet in the sun heats far more than the inner one, and the panel tends to bow — an effect to allow for on large formats.

Systems architecture

Why it works

Composite section · core shear

On their own, the two thin sheets would bend and buckle at once. Held apart by the insulating core and bonded to it, they form a composite section like a small I-beam: under load the upper sheet goes into compression, the lower into tension, and the core transfers the shear that stops them sliding over each other. So a light, thin panel becomes very stiff and spans large distances between purlins — and the very core that stiffens it is also the insulation.

Roof installation speed (m²/day)

Comparison · insulants

Sandwich panel

very fast

Sheet + insulation in situ

medium

Tiles on boarding

slow

Clay-and-concrete + membrane

very slow

Longer bar = faster to close the roof. The sandwich panel carries, insulates and weatherproofs in one dry element, far quicker than build-ups assembled layer by layer on site.

Nodal details

Critical junctions · sections

D.01

Fixing and side lap

The panel is screwed to the purlin through the top of a rib, with a sealing cap; the side lap is a tongue-and-groove joint, often gasketed, so the through-fixing and the joint both stay watertight.

Profiled outer sheet
Insulating core
Inner sheet
Screw + sealing cap (on the rib)
Tongue-and-groove joint + gasket
Purlin

D.02

Ridge

At the ridge the two pitches meet under a ridge cap; a closure (foam or profile filler) seals the ribs while leaving a protected gap, so the space above the core can breathe and any condensation dries.

Roof pitch (panel)
Ventilation gap at the ridge
Opposite pitch
Closure under the ridge
Ridge flashing
Fixing screws

Installation controls

Specification · checklist

01 · Structure & purlins

Purlin alignment and spacing

Bearing surfaces flat

Corrosion protection of the steel

02 · Panel laying

Laying direction (lap away from wind)

Panels clean and undamaged

Minimum pitch respected

03 · Fixings

Pattern and number to calculation

Correct torque, sealing caps

More fixings at edges and corners

04 · Joints & flashings

Gasketed side laps

Ridge, eaves and verge flashings

Sealed rooflights and penetrations

05 · Tightness & testing

Watertightness check

No standing water on the roof

Bare edges sealed

Recurring defects

Diagnostics · site

Termo-igrometrica

Condensation and thermal bridges at the fixings

CauseThrough-screws and joints are colder points: with humid interiors, condensation can form there and drip, and the fixings locally cut the insulation.

PreventionSealing caps and gaskets, fixings to design, vapour control inside, ventilation of the building.

Termo-igrometrica

Corrosion of cut edges and sheets

CauseA bare cut edge (grinder), scratches or standing water start the rust, which then creeps under the coating of the steel sheet.

PreventionCold cutting, edges sealed with paint, fall to drain water, suitable coating for the environment (e.g. coastal).

Adesione

Leaks at the fixings and laps

CauseScrews over- or under-tightened, missing gaskets or a side lap with too little fall let the wind-driven water through the joints.

PreventionCorrect torque and sealing caps, gaskets in the laps, minimum pitch respected, sealed ridges and rooflights.

Meccanica

Wind uplift (insufficient fixings)

CauseWind suction on the roof, strongest at the edges and corners, can tear the panels off if the fixings are too few or wrongly placed.

PreventionFixing pattern by calculation, more fixings at edges/corners, fixings suited to the purlin, periodic checks.

Component materials

The network · materials

Metal Composite Panel

Reference regulations

2 norms

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