Technical sheet

A.01A.02

SystemS-06

Internal dry partition

A non-load-bearing partition built dry: a frame of metal studs, clad on both faces with boards and filled with mineral wool in the cavity. Light, fast, inspectable and easy to modify, it gets its acoustic insulation and fire resistance from layering, not from mass.

Partizione internaLightweight metal-frame and board partition

B.01

System build-up4 layers

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

Lightweight metal-frame and board partition

Spessore totale

7,5-20cm

Potere fonoisolante Rw

43-60dB

Resistenza al fuoco

EI 30-120

Massa superficiale

25-70kg/m²

Strati di lastre

1+1 / 2+2

Reazione al fuoco lastre

Descriptive memo

The dry partition reverses the logic of masonry: instead of entrusting performance to the mass of a single material, it builds it by layering lightweight elements. A metal frame holds the boards; the cavity houses mineral wool and the services; the number and type of boards tune fire and acoustics. It is a system designed «in layers», where each performance is added without loading the building structure.

Acoustics by mass-spring-mass

The secret of dry-system sound insulation is not mass but decoupling. The two board faces (mass) are separated by the mineral-wool cavity (spring): the sound energy that vibrates the first board is largely dissipated and not transmitted to the second. With a few centimetres and a few kilograms one reaches performance that masonry would only achieve with great thickness. The performance is lost, however, through acoustic «short circuits»: unsealed joints, back-to-back electrical boxes, overly rigid studs.

Fire: protection in layers

The fire resistance (EI class) of a dry partition comes from the boards, not the frame. The boards — gypsum, gypsum-fibre or calcium silicate — contain crystallisation water which, by evaporating, keeps the board cool until it is consumed, delaying the passage of heat. By increasing the number of layers and using specific boards (type F, high-resistance) one reaches EI 60, 90 or 120. Staggered joints between layers and correct jointing are an integral part of the certified performance.

Dry construction: lightness and reversibility

Building dry means assembling components, not mixing and waiting for curing. The advantages are speed, the absence of water and drying times, the low weight (a tenth of an equivalent masonry) that loads the structure less, and reversibility: the wall can be dismantled, moved and recycled. In return it demands assembly precision and care for the details — fixings, seals, resilient perimeter strips — because that, and not mass, is where the performance lies.

Systems architecture

Why it works

Acoustics · mass-spring-mass

The two boards (mass) are decoupled by the mineral wool in the cavity (spring): the sound energy that vibrates the first face is dissipated and does not pass to the second. A few centimetres and a few kilograms reach the sound insulation of a much thicker wall — provided no joint or service creates a rigid bridge.

Sound insulation Rw compared

Comparison · insulants

Hollow brick 8 cm, plastered

≈ 38 dB

Clay partition 12 cm

≈ 42 dB

Dry 1+1, 75 mm

≈ 45 dB

Dry 2+2, 100 mm

≈ 54 dB

Dry, twin frame

≈ 60 dB

Longer bar = better insulation. For the same thickness and with a tenth of the weight, the dry system beats masonry thanks to mass-spring-mass; performance grows with layers, wool and decoupling.

Nodal details

Critical junctions · sections

D.01

Perimeter junction

At the perimeter the track is fixed to the slab over a resilient band that decouples the wall from the structure; a bead of sealant closes the joint between board and slab, avoiding acoustic bridges.

Slab (ceiling/floor)
Resilient band
Perimeter track (U)
Stud
Boards
Acoustic sealant

D.02

Joints and boxes (acoustics)

Performance is defended in the details: the second-layer joints are staggered from the first and filled, and the electrical boxes on the two faces must never be back-to-back, so as not to open a path for sound.

First board layer
Second layer (staggered joints)
Joint filling
Mineral wool
Electrical box (offset)
No back-to-back penetrations

Installation controls

Specification · checklist

01 · Setting out & tracks

Set out tracks and studs

Resilient band under the tracks

Fixings suited to the substrate

02 · Frame

Correct stud spacing

Studs free to slide in the tracks

Reinforcement for suspended loads

03 · Services & insulation

Continuous mineral wool, right density

Offset, sealed electrical boxes

No back-to-back service runs

04 · Boards

Layers with staggered joints

Screw fixing and spacing

Detachment from the floor (cut)

05 · Jointing & sealing

Tape and filler on the joints

Acoustic sealant at the perimeter

Treatment of the movement joints

Recurring defects

Diagnostics · site

Meccanica

Sound leaks through rigid bridges

CauseUnsealed joints, back-to-back boxes, overly rigid studs that short-circuit the mass-spring-mass system.

PreventionResilient perimeter band, sealed joints, offset boxes, decoupled studs.

Adesione

Cracking and joint-tape detachment

CauseMissing tape, dusty substrate, structural movements at the joints.

PreventionTape + filler on the joints, correct staggering, movement joints where needed.

Termo-igrometrica

Moisture damage in wet rooms

CauseStandard boards in bathrooms/kitchens, splashes and leaks.

PreventionWater-repellent or cement boards, waterproofing membrane, suitable sealing.

Biologica

Mould in the cavity

CauseTrapped moisture, thermal bridges on partitions against external walls.

PreventionVapour control on the warm side where needed, ventilation, suitable materials.

Component materials

The network · materials

Natural Mineral Insulator

Calcium Silicate

Metallurgical coating

Hot-Dip Galvanized Steel

Mineral Wool

Glass Wool

Reference regulations

2 norms

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