Technical sheet

A.01A.02

SystemS-12

Green roof

A flat roof covered with vegetation, where a build-up of layers - substrate, drainage, filter, root barrier - replaces the mineral ballast with a small ecosystem. It retains and slows rainwater, cools by evapotranspiration, protects the membrane and gives the city back the surface the building occupies.

CoperturaVegetated flat roof (extensive/intensive)

B.01

System build-up6 layers

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

Vegetated flat roof (extensive/intensive)

Ritenzione idrica

estensivo 40-60%

Peso (saturo)

estens. ~1-1,5; intens. >3kN/m²

Spessore substrato

8-30cm

Trasmittanza U (tipica)

0,18-0,26W/m²K

Manutenzione

estensivo: bassa

Pendenza

1-5%

Descriptive memo

The green roof turns the roof from an inert surface into a living system. Over the waterproofing a layered build-up is laid - root barrier, drainage and storage, filter, growing substrate, vegetation - calibrated to the type of green: extensive (sedum and grasses, light and almost maintenance-free) or intensive (a true roof garden, with shrubs and trees, heavier and tended).

Water: retain and slow

The first service of the green roof is hydraulic. Substrate and drainage layer absorb and retain a share of the rain, returning it slowly by evaporation; the rest runs off with a strong delay compared with a traditional roof. In the city, where impervious surfaces saturate the sewers during storms, this attenuation of stormwater reduces the discharge peaks and is increasingly required or incentivised by building regulations.

Climate: cool and protect

The retained water evaporates through the substrate and the plants (evapotranspiration), removing heat: in summer the surface of a green roof stays much cooler than a dark membrane, reducing the cooling load and the urban heat island. The mass of the build-up adds inertia and decrement delay. For the membrane, finally, the green is a shield: screened from sun, frost and UV, its life lengthens as much as, or more than, in the inverted roof.

Root barrier, weights and maintenance: the constraints

Three constraints govern the design. Tightness: a root-resistant membrane (or a dedicated layer) is needed that roots cannot pierce, with a penetration-resistance test. Weights: the water-saturated substrate is heavy (from ~1 kN/m² of the extensive to many kN/m² of the intensive), and must be accounted for in the structure. Maintenance and irrigation: minimal for the extensive, regular for the intensive; in any case perimeter gravel strips and borders around the singular points must be provided, for inspection and fire safety.

Systems architecture

Why it works

Attenuation + evapotranspiration

The vegetated build-up works like a sponge: it retains part of the rain and returns the rest with a strong delay, relieving the sewers during storms. The water evaporating from the plants cools the surface, reducing the heat island, while the green protects the membrane from the sun and extends its life.

Runoff coefficient ψ

Comparison · insulants

Intensive green

ψ ≈ 0.1-0.3

Extensive green

ψ ≈ 0.4-0.5

Gravel (inverted)

ψ ≈ 0.7

Bare membrane

ψ ≈ 0.9-1.0

Shorter bar = more water retained (less load on the sewers). The green, especially intensive, strongly reduces and delays runoff; the bare membrane discharges almost everything at once.

Nodal details

Critical junctions · sections

D.01

Edge and gravel margin

At the perimeter the root barrier rises up the parapet; a gravel margin, separated from the substrate by an edge profile, keeps the drainage inspectable and acts as a firebreak strip.

Parapet
Root barrier turned up
Perimeter gravel margin
Edge profile
Substrate + vegetation
Insulation

D.02

Inspection chamber

The drain must never be buried in the green: it is protected with a gravel ring and an inspection chamber, which prevents substrate and roots from clogging it and allows cleaning.

Vegetation / substrate
Gravel ring
Inspection chamber
Membrane into the drain
Drain / downpipe
Insulation

Installation controls

Specification · checklist

01 · Substrate & tightness

Continuous root barrier

Flood test before the green

Protected upstands and outlets

02 · Drainage

Drainage and storage layer

Filter above the drainage

Accessible inspection chambers

03 · Substrate

Design thickness and composition

Saturated weight verified

Even laying

04 · Edges & safety

Perimeter gravel margins

Edge profiles

Detachment from chimneys and openings

05 · Vegetation & care

Species suited to the exposure

First-establishment irrigation

Maintenance plan

Recurring defects

Diagnostics · site

Biologica

Root penetration

CauseNon-root-resistant or damaged membrane.

PreventionCertified root-resistant membrane (FLL), careful upstands and joints.

Termo-igrometrica

Ponding / poor drainage

CauseInsufficient drainage, low falls, clogged outlets.

PreventionDrainage and filter layer, falls, inspectable chambers.

Meccanica

Unforeseen overload (saturated substrate)

CauseSaturated weight or accumulation not accounted for.

PreventionStructural design for saturated weight, thickness control.

Adesione

Leaks at the singular points

CauseFaulty upstands / outlets under the green.

PreventionCare of the details, inspectable chambers, gravel margins.

Component materials

The network · materials

Synthetic Elastomer

EPDM Membrane

Extruded Synthetic Polymer

XPS (Extruded Polystyrene)

Structural conglomerate

Reinforced Concrete

Reference regulations

2 norms

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