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

Clay-and-concrete floor slab

A composite floor in which reinforced (or prestressed) concrete joists work together with a cast-in-place topping slab, while clay infill blocks lighten the non-structural zones. A solution that combines load-bearing capacity, reduced self-weight and continuity with the Italian building tradition.

SolaioComposite cast-in-place floor structure
B.01
System build-up6 layers
ESTRADOSSOINTRADOSSOCARICO qREI (fuoco)1. Pavimento2. Massetto3. Soletta + rete4. Travetto c.a.5. Pignatta6. Intonaco

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

Composite cast-in-place floor structure
Luce economica
4,5-7,5m
Altezza solaio (H+soletta)
20-29cm
Peso proprio
2,5-3,5kN/m2
Interasse travetti
40-60cm
Resistenza al fuoco
REI 30-120
Sovraccarico (civile)
2,0kN/m2
Descriptive memo

A composite floor in which reinforced (or prestressed) concrete joists work together with a cast-in-place topping slab, while clay infill blocks lighten the non-structural zones. A solution that combines load-bearing capacity, reduced self-weight and continuity with the Italian building tradition.

The clay-and-concrete (laterocemento) floor is the most common horizontal structure of mid-to-late 20th-century Italian construction: a composite system that uses concrete where strength is needed (compression in the slab, reinforcement in the joists) and clay where the only job is to lighten and shape the pour (the infill blocks). Its logic is that of the T-beam: the closely and regularly spaced joists act with the collaborating slab as a sequence of small bending beams.

The joist-slab composite action (T-section)

The structural behaviour rests on the composite T-section: the upper concrete slab, cast in place over the blocks, takes the compression stresses, while the bottom reinforcement of the joists takes the tension due to bending. The clay infill blocks carry no load: they cut the self-weight and act as permanent formwork for the pour. For the composite action to be effective the slab must be thick enough (typically 4-5 cm) and reinforced with a welded mesh that distributes point loads and counters shrinkage cracking.

Pour, reinforcement and structural continuity

Cast in place, the floor is born monolithic: the joists are tied into the perimeter ring beams and, over the supports, top reinforcement (negative moments) and solid block-free bands are arranged to take the shear. The quality of the result depends on the concrete cover, the compaction of the pour and moist curing: insufficient cover or poorly compacted concrete expose the bars to carbonation and corrosion, the leading cause of decay in existing floors. Solid bands and transverse rib-beams also govern the lateral distribution of loads and the deflection.

Acoustics, fire and services: the limits of the system

Structurally efficient as it is, laterocemento is a heavy, stiff floor with two recurring weak points. Acoustically it readily transmits impact noise: meeting the legal requirements calls for a floating screed on a resilient layer, isolated from the walls. Thermally, on the roof or towards unheated spaces, the mass must be paired with insulation. Fire resistance (REI class) is instead provided by the cover to the bars and the thickness of the elements, to be checked against the use. Services, finally, are housed within the screed, not within the structure.

Systems architecture

Why it works

Static scheme · T-section
load qcompression (slab)tension (reinforcement)neutral axis

Under load the floor bends: the cast slab works in compression at the top, the joist reinforcement in tension at the bottom, with the neutral axis in between. The clay blocks only lighten the section — concrete and steel each work where they are strongest.

Self-weight of floor systems compared

Comparison · insulants
Timber floor
≈ 1.0 kN/m²
Steel deck + concrete
≈ 2.5 kN/m²
Clay-and-concrete
≈ 3.0 kN/m²
Precast plank + topping
≈ 3.5 kN/m²
Solid R.C. slab
≈ 5.0 kN/m²

Shorter bar = lighter floor (less load on structure and foundations). But mass is not only a cost: in laterocemento it helps acoustic insulation and fire resistance. The choice balances weight, span, cost and performance.

Nodal details

Critical junctions · sections
123456
D.01
Bearing on the ring beam

Over the support the moment reverses: the clay block is omitted (solid band) to resist the shear, and top reinforcement is placed to take the negative moment, tying the floor into the ring beam.

  1. Load-bearing masonry
  2. R.C. ring beam
  3. Solid band (no infill blocks)
  4. Top reinforcement (negative moment)
  5. Collaborating slab
  6. Joist bearing
123456
D.02
Floating screed

To cut impact noise the screed and the floor finish «float» on a continuous resilient layer, turned up at the wall with a compressible edge strip: no rigid bridge between floor and structure.

  1. Wall
  2. Compressible perimeter strip
  3. Continuous resilient layer
  4. Floating screed
  5. Floor finish
  6. Detachment from the wall

Installation controls

Specification · checklist

01 · Formwork & reinforcement

Soffit and props at the design spacing
Reinforcement, solid bands and distribution bars
Clean and wet the clay blocks before casting

02 · Pour & curing

Concrete of the specified class, well vibrated
Cover guaranteed by spacers
Moist curing, strike at the right time

03 · Slab & mesh

Slab thickness ≥ design
Continuous, lapped welded mesh
Clean joist-to-slab connection

04 · Supports & continuity

Solid bands and top steel over supports
Tying into the ring beams
Connecting bars at the transverse ribs

05 · Acoustics & services

Continuous, turned-up resilient layer
Floating screed detached from the walls
Service chases in the screed, not in the structure

Recurring defects

Diagnostics · site
Meccanica
Cracking on the soffit
CauseExcessive deflection, casting shrinkage, missing or discontinuous mesh in the slab.
PreventionDesign for deflection ≤ L/250, continuous welded mesh, rib-beams and moist curing.
Termo-igrometrica
Corrosion of the reinforcement
CauseInsufficient cover and porous concrete: carbonation reaches the bars and moisture starts the rust that spalls the cover.
PreventionCover suited to the exposure class, dense well-vibrated concrete, crack control.
Adesione
Detachment of the soffit plaster
CausePoor adhesion on the smooth clay blocks, no scratch coat, vibration and thermal cycles.
PreventionBonding scratch coat, plaster-carrying mesh over the joints, compatible plasters.
Biologica
Condensation and mould on the soffit
CauseThermal bridge towards unheated spaces (porticoes, cellars): the cold surface holds moisture and breeds mould.
PreventionInsulation on the soffit or topside, correction of thermal bridges, room ventilation.

Component materials

The network · materials
Structural conglomerate
Reinforced Concrete
clsintonaco~24 cmSOLAIO MISTO
Floor Element
Clay Tiles and Floor Blocks
Conglomerate
Concrete
H₂OH₂OH₂OH₂OTRASPIRAμ ≈ 7abc
Traditional mortar
Lime Plaster

Reference regulations

2 norms

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