All systems
Technical sheet
A.01A.02
SystemS-30

Composite steel-deck floor

A composite floor in which a profiled steel deck acts as permanent formwork and, once the concrete has set, collaborates with the slab as bottom reinforcement. Laid on the beams and topped with a slab, it gives a light, very fast load-bearing deck, with no props over modest spans and no formwork. It is the typical solution in steel-framed buildings, where the deck is fixed to the beams and, with shear connectors, makes them act compositely with the floor.

SolaioSteel-concrete composite floor
B.01
System build-up6 layers
ESTRADOSSOINTRADOSSO1. Pavimento2. Massetto3. Soletta + rete4. Connettori5. Lamiera grecata6. Trave d’acciaio

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

Steel-concrete composite floor
Spessore della soletta H
12-18cm
Spessore della lamiera
0,8-1,5mm
Luce (senza puntelli)
2-4m
Luce (con appoggi)
fino a 6-7m
Connettori a piolo
Ø 16-22mm
Resistenza al fuoco
REI 30-120
Descriptive memo

A composite floor in which a profiled steel deck acts as permanent formwork and, once the concrete has set, collaborates with the slab as bottom reinforcement. Laid on the beams and topped with a slab, it gives a light, very fast load-bearing deck, with no props over modest spans and no formwork. It is the typical solution in steel-framed buildings, where the deck is fixed to the beams and, with shear connectors, makes them act compositely with the floor.

The composite steel-deck floor unites two materials at their respective strengths: the steel of the deck, at the bottom, resists tension; the concrete of the slab, at the top, resists compression. The profiled deck, laid on the beams, first acts as permanent formwork — carrying the fresh pour — and then as tension reinforcement, collaborating with the hardened concrete.

Deck as formwork and as reinforcement

During the pour the deck alone carries the weight of the fresh concrete and the workers, shedding it onto the beams: over modest spans no props are needed. Once cured it changes role and becomes a resisting part of the floor: the ribs with embossments or dovetails key into the concrete and prevent slip, so deck and slab work as one composite section.

The connectors: floor and beam together

For the steel beam too to collaborate with the floor, stud connectors («Nelson studs») are welded to its top flange, embedded in the pour. They transfer the shear at the beam-slab interface and make them a single composite beam, far stiffer and stronger than the bare beam: this is what allows wide spans with slim depths in steel buildings.

Lightness, fire and services

The system is light and fast, ideal for dry construction and for strengthening in refurbishment. Two points must be managed: the fire resistance, because the steel exposed at the soffit must be protected (intumescent paints, suspended ceilings, or added reinforcement) to ensure the REI class; and the routing of services, which the ribs themselves can house. Mesh or added reinforcement in the slab controls cracking and the negative moments over the supports.

Systems architecture

Why it works

Composite section · connector shear
n. axisslab: compressiondeck / bottom flange: tensionstuds

Steel and concrete divide the tasks. Below, the profiled deck resists tension; above, the slab resists compression; in between, the deck’s embossments prevent slip and make them work as one section. The same holds for the beam: stud connectors welded to the flange transfer the shear at the interface and make beam and slab a single composite beam — far stiffer and stronger than the bare beam. It is the principle that brings wide spans with light structures.

Self-weight by floor type (kN/m²)

Comparison · insulants
Composite steel deck
≈ 2.0–2.8
Predalles
≈ 3.0–4.0
Clay-and-concrete
≈ 3.5–4.5
Solid R.C. slab
≈ 5.0–6.0

Shorter bar = lighter floor. The composite deck is among the lightest, ideal on steel frames and for strengthening, where every kilo on the structure and foundations counts.

Nodal details

Critical junctions · sections
123456
D.01
Stud connector and bearing

The deck bears on the beam’s top flange; stud connectors welded through it (or to the flange) are embedded in the slab. They transfer the shear at the interface, making beam and slab a single composite beam.

  1. Concrete slab + mesh
  2. Profiled steel deck
  3. Steel beam
  4. Stud connector
  5. Bearing on the beam
  6. Stud embedded in the pour
123456
D.02
Continuity over the support

Over an internal support the slab is continuous: top (negative-moment) reinforcement is placed across the support to tie the two spans and control cracking, while the connectors keep the composite action.

  1. Collaborating slab
  2. Continuity reinforcement (negative)
  3. Deck (left span)
  4. Deck (right span)
  5. Support beam
  6. Connectors

Installation controls

Specification · checklist

01 · Beams & bearings

Beam alignment and levels
Minimum bearing of the deck
Top flange clean for welding

02 · Deck laying

Laying direction and laps
Deck fixed to the beams
Edge trims and closures

03 · Connectors & reinforcement

Studs welded and checked
Continuity / negative reinforcement
Mesh continuous and lapped

04 · Slab pour

Concrete class and thickness
Props where required
Curing of the cast

05 · Fire protection

Protection of the exposed steel
Intumescent / ceiling to REI
Penetrations sealed

Recurring defects

Diagnostics · site
Adesione
Slip at the interface (insufficient connectors)
CauseToo few studs or a smooth deck: the slab slides over the deck (or over the beam) and the section loses its composite action, becoming more deformable.
PreventionConnectors to design, deck with embossments, clean interface, welds checked.
Termo-igrometrica
Corrosion of the deck
CauseIn damp or aggressive environments the exposed galvanised deck, especially at cut edges, corrodes and loses its reinforcing role.
PreventionGalvanising / coating suited to the environment, sealed edges, protection in wet rooms, no condensation.
Termica
Collapse in fire (exposed steel)
CauseThe steel deck exposed at the soffit loses strength fast in a fire; unprotected, the floor can fail before the required REI time.
PreventionIntumescent paint, fire ceilings, added reinforcement in the ribs, design to the REI class.
Meccanica
Casting overload (no props)
CauseDuring the pour the deck alone carries the fresh concrete: over too long a span, with no props, it deflects too much (ponding) or fails.
PreventionSpan and deck to design, temporary props where needed, gradual pour, deflection check.

Component materials

The network · materials
bagno Zn · 450 °Cη Zn puroζ FeZn₁₃δ FeZn₇Γ Fe₃Zn₁₀acciaiobasesp. totale 45–85 µmZINCO A CALDO
Metallurgical coating
Hot-Dip Galvanized Steel
Conglomerate
Concrete
Structural alloy
Steel S235 / S355

Reference regulations

2 norms

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