Summary

Roof lanterns — also called rooflights, flat roof windows, or pyramid lights — bring natural light into single-storey extensions and kitchens that would otherwise be poorly lit. They are one of the most popular extension upgrades, but they also introduce thermal, structural, and weathering challenges not present in vertical glazing.

The regulatory context spans planning (if the lantern projects above the roof plane by more than permitted), energy performance (Part L limits roof glazing as a % of roof area), and structural (the flat roof and opening must be designed to carry the weight and wind load of the lantern). For new extensions, all three must be considered simultaneously.

Condensation inside the lantern unit is the most common complaint after installation — and is almost always due to inadequate edge sealing between the glazing unit and the frame, or to poor drainage at the frame base.

Key Facts

  • Permitted development (England) — Roof extensions on dwellings: the lantern must not exceed 150mm above the roof plane. Larger projections may require planning consent (check the GPDO 2015 Class A conditions for extensions and alterations).
  • Conservation areas and listed buildings — Permitted development is often withdrawn; check with LPA before installing.
  • Flat roof structural loading — Typical glass lantern 3m × 2m: 80–150kg dead load, plus snow (0.6 kN/m² in most of England). Flat roof structure (joists, beams) must be checked.
  • Part L limits — new extensions: Roof glazing must not exceed 25% of the floor area of the new extension. For replacement lanterns: replacement must achieve U-value ≤1.8 W/m²K for the glazed unit.
  • U-value targets — New-build specification: ≤1.8 W/m²K overall for roof glazing. High-performance lanterns with triple glazing achieve 1.0–1.2 W/m²K.
  • Solar gain — South-facing roof lanterns create significant solar overheating in summer. Solar control glass (low SHGC/g-value) helps. Operable sections (opening panels) are important for ventilation.
  • Glass specification — BS EN 1279 covers hermetically sealed double/triple glazing units. Internally toughened or laminated glass in Zone 0 (directly overhead — all roof applications).
  • Safety glass requirement — All overhead glazing must be either laminated (Category B — designed to retain glass fragments on breakage) or toughened with interlayer. Approved Document K specifies overhead glazing requirements.
  • Condensation channel — Well-designed lanterns have a built-in condensation channel at the base to drain any internal condensate before it reaches the structure.
  • FENSA/CERTASS — Installation is notifiable under Part L (replacement) and Part K (safety) Building Regulations. Use registered installer for self-certification.

Quick Reference Table

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Parameter Requirement
PD projection above roof ≤150mm (GPDO 2015 Class A)
Roof glazing area (new extension) ≤25% of new extension floor area
U-value (new-build roof) ≤1.8 W/m²K (some specs require ≤1.6)
U-value (replacement) ≤1.8 W/m²K
Minimum glass safety class overhead Category B (laminated) per BS EN 12600
Snow load (most of England) 0.6 kN/m² ground snow load
Condensate drainage Integral channel to external
Building Regs notification Part K + Part L — FENSA/CERTASS or Building Notice

Detailed Guidance

Planning Considerations

Roof lanterns on house extensions fall under GPDO 2015 Schedule 2, Part 1, Class A. Permitted development conditions relevant to roof alterations:

  • The alteration must not protrude more than 150mm above the existing roof plane (measured perpendicular to the roof surface)
  • Must not exceed the existing ridge height
  • Materials should match the existing house in appearance
  • PD rights do not apply in: National Parks, AONBs, World Heritage Sites, Conservation Areas, or on listed buildings

Practical implication: Most domestic roof lanterns (which are designed to sit low-profile) are PD. A glazed pyramid on a flat roof extension that protrudes 120mm above the flat roof line is PD. The same lantern on a primary pitched roof slope that projects 160mm would require planning.

Where PD rights are restricted (Conservation Area, Article 4 Direction), submit a Certificate of Lawfulness application to the LPA to confirm PD status before ordering.

Part L Energy Compliance

New extensions: The glazing area of a new extension must be limited. The current calculation under Part L 2021 (England) for extensions:

  • Roof glazing area ≤25% of the floor area of the new space (under thermal separation rules)
  • OR the total energy balance of the extension must be calculated to demonstrate compliance by notional comparison

In practice: a 15m² kitchen extension can have up to 3.75m² of roof glazing. A 3m × 1.25m lantern just meets this limit.

Replacement lanterns: A like-for-like replacement must meet ≤1.8 W/m²K U-value for the glazed unit. Most modern double-glazed roof lanterns with low-E glass already achieve this. Specify the U-value on the order.

Glazing Specification

Sealed unit construction (BS EN 1279):

  • Double or triple insulating glazed units (IGUs)
  • Outer pane: toughened safety glass (BS EN 12150) for impact resistance
  • Inner pane: laminated glass (minimum 4mm/4mm laminated, e.g. 8.8) — Category B per BS EN 12600 — designed to retain fragments if broken
  • Low-E coating on one or more surfaces reduces U-value
  • Argon or krypton gas fill between panes
  • Warm-edge spacer bar reduces cold bridge at edge (linear thermal transmittance ψ)

Solar control glass:

  • Standard low-E glass transmits 70–80% of solar energy (g-value 0.6–0.7)
  • Solar control glass: g-value 0.3–0.4 — reduces solar gain by 50%+ at cost of some visible light transmission
  • Consider for south-facing, large-area installations. Not necessary for north-facing.

Structural Requirements

Roof lanterns impose dead, live, and wind loads on the roof structure. The flat roof opening must be:

  • Trimmed with structural timbers (trimmer and trimming joists)
  • Trimmer joist: same depth as existing joists, doubled up on each side of opening
  • Span calculations needed if opening width exceeds 1.8m (or engineer-designed for wider spans)
  • Padstone or adequate bearing length at each end of trimmer joist

Typical lantern weights:

  • 1.5m × 1m aluminium double-glazed: 60–80kg
  • 3m × 2m aluminium triple-glazed: 150–200kg
  • Factor into joist capacity (BS 8103-3 span tables or engineer's calculation)

Installation and Weather-Sealing

The most critical installation detail is the upstand at the base of the lantern:

  • Minimum 150mm upstand above flat roof surface to prevent water ingress
  • Single-ply membrane must lap up and over the upstand by minimum 150mm
  • Use compatible adhesive tape or cover flashing at the upstand/wall junction
  • Timber kerb (upstand) must be treated against moisture; or use aluminium/steel kerb

Installing the lantern:

  1. Fix kerb/upstand to structural trimmer frame; check level and square
  2. Dress roof membrane up and onto kerb; clamp or seal at top
  3. Fix aluminium base frame of lantern to kerb using appropriate fixings
  4. Apply self-adhesive weatherseal tape to all frame joints
  5. Fit glass units and open-vent mechanisms per manufacturer instructions
  6. Seal base of frame to kerb with neutral-cure silicone

Frequently Asked Questions

Do I need planning permission for a roof lantern on an existing flat-roof extension?

Usually not, if the lantern does not project more than 150mm above the flat roof plane (which most domestic lanterns do not). However, verify PD rights have not been removed (conservation area, Article 4 Direction, prior planning conditions). When in doubt, apply for a Certificate of Lawfulness.

Why is my roof lantern producing condensation on the inside?

External condensation (on the outer surface, first thing in the morning) is normal for high-performance glazing — the outer pane is so well insulated from room warmth that it drops below dew point overnight. This is a sign of a well-performing unit, not a defect.

Internal condensation (within the sealed unit, between the panes) indicates IGU seal failure — the hermetic seal has broken, allowing humid air inside. The unit must be replaced.

Condensation on the inner surface of the inner pane indicates high indoor humidity or cold frames creating cold spots.

Can I install a roof lantern on an existing extension without FENSA registration?

Not legally without Building Control notification. The installation is notifiable under Part K (safety glazing in overhead position) and Part L (thermal compliance). FENSA/CERTASS registration is the simplest route. Alternatively, submit a Building Notice to LABC before installation.

Regulations & Standards