Technical sheet

A.01A.02

SystemS-11

Cross-laminated timber (CLT) wall

A load-bearing wall of solid timber panels made of boards glued in crosswise layers (X-LAM or CLT). The crossing of the grain makes the panel rigid and stable in both directions, like a large structural plywood. Prefabricated to the millimetre, light and able to store carbon, it bears, encloses and seals in a single element.

PareteLoad-bearing cross-laminated solid timber wall

B.01

System build-up6 layers

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

Load-bearing cross-laminated solid timber wall

Trasmittanza U (tipica)

0,16-0,22W/m²K

Spessore pannello

9-20cm

Peso proprio

≈ 1/5 del c.a.

Reazione al fuoco

D-s2,d0 (legno)

Carbonio immagazzinato

alto

Montaggio

a secco, prefabbricato

Descriptive memo

The X-LAM (Cross-Laminated Timber) panel brings the logic of plywood into timber at the scale of the building: boards stacked and glued in crosswise layers at 90°, forming a solid panel that works as a load-bearing plate in both directions. It is the heart of massive timber construction, an alternative to the light frame: walls and floors become large prefabricated plates, dry-assembled in a few days.

The crossing of layers: stiffness and stability

Timber is anisotropic: strong along the grain, weak and deformable across it, where it shrinks and swells with moisture. By crossing the layers at 90°, X-LAM cancels this weakness: each layer restrains the adjacent one, and the panel becomes rigid and stable in both directions, with negligible in-plane movement. The result is a two-way load-bearing plate, able to act as a wall and a bracing diaphragm, and to distribute loads around openings without added frames.

Prefabrication and dry construction

The panels are CNC-cut in the factory, complete with openings for doors, windows and services, and arrive on site as a kit. Assembly is dry and very fast: they are lifted, positioned and connected with plates, screws and hold-downs that also govern the seismic behaviour. The light weight (a fifth of reinforced concrete for the same volume) reduces the loads on foundations and cranes, and the dry site eliminates curing times. The timber, finally, stores carbon for the whole life of the building.

Water, fire and acoustics: the fronts to guard

Solid timber has three fronts to manage. Moisture: the panel must be protected from rain on site and forever, with details that keep it dry and ventilated (dry timber does not rot). Fire: X-LAM is combustible but chars slowly and predictably, preserving the inner resisting section; the R class is reached by calculating the charring rate and with protective linings where needed. Acoustics: the modest mass calls for added layers (screeds, suspended ceilings, insulation) and a careful interruption of flanking transmission at the joints.

Systems architecture

Why it works

Crossed layers · stability

By gluing the boards in crosswise layers at 90°, X-LAM removes the cross-grain weakness of timber: each layer restrains the adjacent one and the panel becomes a rigid plate, stable in both directions, with negligible shrinkage. So it bears, braces and distributes loads around openings without added frames.

Embodied carbon of structures

Comparison · insulants

X-LAM (timber)

low / stores C

Clay masonry

medium

Steel

high

Reinforced concrete

very high

Shorter bar = fewer emissions; timber, moreover, stores carbon for the whole life of the building. Steel and R.C. start from high emissions (but are recyclable and durable).

Nodal details

Critical junctions · sections

D.01

Panel-to-panel joint

The panels are joined with a rebated joint or a screwed cover strip; on the inner side a tape ensures the airtightness, decisive for efficiency and to avoid condensation in the joint.

X-LAM panel
Cover-strip joint
Connection screws
Airtight tape (inner side)
Crossed layers

D.02

Base connection

Timber fears rising damp: the panel never touches the concrete. It rests on a sill plate, separated from the ring beam by a membrane (capillary break) and detached from the ground, and is anchored with plates.

Foundation / ring beam
Membrane / DPC (capillary break)
Sill plate
X-LAM panel
Anchor (plate/bolt)
Detachment from the ground

Installation controls

Specification · checklist

01 · Storage & protection

Panels protected from rain and soil

Timber moisture checked

Lifting with proper beams

02 · Assembly

Design sequence and tolerances

Connections (screws, plates, hold-downs)

Plumb and flatness

03 · Airtightness

Continuous tapes on the joints

Sealing of penetrations

Blower-door test

04 · Envelope

Vapour control on the inner side

External insulation and cavity

Ventilated cladding

05 · Fire & acoustics

Protective linings where required

Screeds/ceilings for acoustics

Interruption of flanking transmission

Recurring defects

Diagnostics · site

Biologica

Rot and moisture decay

CauseTimber wetted on site or by leaks / rising damp.

PreventionProtection on site, details that keep it dry and ventilated, detachment from the ground.

Meccanica

Shrinkage and cracking

CauseTimber installed too wet that later dries out.

PreventionIn-service moisture ≤ 12-15%, conditioning, movement joints.

Termo-igrometrica

Thermal bridges and draughts at joints

CauseMissing or discontinuous airtight tapes.

PreventionContinuous tapes, blower-door test.

Adesione

Glue-line delamination

CauseFaulty glue, extreme moisture cycles.

PreventionCertified manufacturers (ETA), moisture control.

Component materials

The network · materials

Thermally modified timber (TMT)

Thermally Modified Timber (TMT)

Natural Mineral Insulator

Calcium Silicate

Reference regulations

2 norms

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