All systems
Technical sheet
A.01A.02
SystemS-22

Quartz-hardened industrial concrete floor

A continuous, joint-free floor made of a concrete slab cast on the ground (or on a structural floor) and surface-hardened with a quartz dry-shake. Designed to withstand heavy forklift traffic, abrasion and the concentrated loads of racking, it combines structure and finish in a single pour. Mesh or fibres control shrinkage cracking, while properly cut joints govern the movements of the large surface.

PavimentazioneContinuous slab-on-ground floor
B.01
System build-up6 layers
muletto1. Quarzo (usura)2. Lastra FRC3. Giunto di controllo4. Rete / fibre5. Barriera vapore6. Isolante XPS7. Vespaio

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

Continuous slab-on-ground floor
Spessore della lastra
12-25cm
Strato d'usura (quarzo)
2-3mm
Classe del calcestruzzo
C25/30 - C32/40
Maglia dei giunti di controllo
4-6m
Planarità (su 2 m)
≤ 3-5mm
Portata d'esercizio
30-80kN/m2
Descriptive memo

A continuous, joint-free floor made of a concrete slab cast on the ground (or on a structural floor) and surface-hardened with a quartz dry-shake. Designed to withstand heavy forklift traffic, abrasion and the concentrated loads of racking, it combines structure and finish in a single pour. Mesh or fibres control shrinkage cracking, while properly cut joints govern the movements of the large surface.

An industrial floor is a large-area concrete slab that serves at once as the supporting structure and the working surface. It is cast on a prepared base — sub-base, insulation, vapour barrier and, usually, a reinforced ground slab or screed — and finished on top while the concrete is still fresh. The result is a continuous, flat and durable plane, able to carry trolleys, forklifts and automated warehouses for years.

The quartz dry-shake: a skin that resists

Onto the fresh concrete, during floating, a quartz (or corundum) and cement dry-shake is spread: worked in with power trowels, it forms a very hard, dense and low-porosity surface layer, intimately bonded to the slab. It is this hardened «skin» that resists wheel abrasion, impact and dusting, where bare concrete would crumble. Careful curing keeps the surface from losing water too fast and cracking.

Crack control: mesh, fibres and joints

Concrete shrinks as it dries and cracks if its movement is restrained. To control it the slab is reinforced with welded mesh or fibres (steel or polymer) that stitch the micro-cracks, and control joints are cut within a few hours of the pour: by scoring the surface you «pre-set» where the slab will crack, in straight, hidden lines instead of at random. Joints divide the large surface into regular bays and absorb their movements.

Base and in-use performance

Performance depends as much on the slab as on what lies beneath: a well-compacted, uniform base prevents differential settlement and edge «curling». Flatness is checked to strict tolerances where there is high racking or automated guided vehicles. Where chemical resistance or maximum cleanability is needed — food, pharmaceutical — a resin coating is applied instead of, or over, the dry-shake.

Systems architecture

Why it works

Controlled shrinkage · control joints
WITHOUT jointsrandom cracksWITH control jointssaw cut = weakened plane: the crack hides under the jointmesh and fibres keep the cracks tight

As it dries, concrete shrinks: if it cannot move, it cracks at random. Rather than fighting it, you guide it. Sawing the surface at regular intervals creates a weakened plane: the slab, having to crack somewhere, does so right beneath it, in a straight line hidden in the cut, while mesh and fibres stitch the micro-cracks and keep them tight. The large surface is thus divided into bays that move without damage.

Surface resistance to abrasion

Comparison · insulants
Bare concrete
low
Resin coating
chemical
Quartz dry-shake
high
Corundum dry-shake
very high

Longer bar = harder, longer-lasting surface. The quartz dry-shake offers the best value for general industry; corundum is for the heaviest traffic, a resin coating where chemicals or hygiene rule.

Nodal details

Critical junctions · sections
123456
D.01
Control and construction joints

The control joint is a saw cut about a third of the depth: it weakens the section so the shrinkage crack forms straight beneath it, then it is sealed. At construction joints, greased dowels transfer the load while letting the slabs move.

  1. Concrete slab
  2. Control joint (saw cut ~1/3)
  3. Joint sealant
  4. Induced crack below the cut
  5. Construction joint
  6. Load-transfer dowel (greased one side)
123456
D.02
Perimeter joint and edge

Along walls and columns a compressible strip detaches the slab, so it can shrink and move without restraint (and without cracking at the edges). Below, the turned-up vapour barrier and the insulation complete the build-up.

  1. Wall
  2. Compressible perimeter strip
  3. Quartz wearing layer
  4. Concrete slab
  5. Turned-up vapour barrier
  6. XPS insulation + sub-base

Installation controls

Specification · checklist

01 · Base & build-up

Compacted, level sub-base
Insulation and vapour barrier
Bearing capacity checked

02 · Reinforcement & joints

Mesh / fibres to design
Dowels at construction joints
Joint grid set out

03 · Pour & levelling

Concrete class and consistency
Laser screeding to level
No working over bleed water

04 · Dry-shake & finish

Quartz spread at the right set
Power-floating and trowelling
Final closing of the surface

05 · Joints, curing & testing

Early saw cutting of control joints
Curing (compound / moist)
Flatness and surface-hardness check

Recurring defects

Diagnostics · site
Meccanica
Shrinkage cracking away from the joints
CauseJoints cut too late or too far apart, or a too-wet, badly cured mix: the slab cracks where it wants to, in random lines across the field instead of along the joints.
PreventionEarly sawing, joint grid to design, controlled water and curing, mesh and fibres.
Meccanica
Edge curling at the joints
CauseThe top dries and shrinks faster than the bottom: the slab edges lift («curl») at the joints, then break under the wheel loads that hammer the raised edge.
PreventionEven curing, dowels at the joints, balanced mix, sometimes joints filled with semi-rigid resin.
Adesione
Delamination of the quartz layer
CauseA dry-shake spread at the wrong time, over-worked or over bleed water, does not bond to the slab: the hardened skin detaches in flakes under traffic.
PreventionSpreading at the right set, no working over bleed water, dosage and trowelling to the rules, curing.
Meccanica
Differential settlement of the sub-base
CauseA poorly compacted or uneven sub-base settles unevenly under load: the slab, unsupported in places, cracks and steps at the joints.
PreventionCompacted, level sub-base, checked bearing capacity, slab thickness and reinforcement to the loads.

Component materials

The network · materials
TRAVE FRC
Fiber reinforced concrete (FRC)
Fiber Reinforced Concrete (FRC)
Structural alloy
Steel S235 / S355
applicazionein corsoRESINA EP.sp. 3 mm
Thermosetting Resin
Epoxy Resin

Reference regulations

2 norms

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