Roof Gutter & Downpipe Design Calculator (AS/NZS 3500.3:2018)

This calculator follows the general method of AS/NZS 3500.3:2018 — Plumbing and drainage, Part 3: Stormwater drainage (Section 3 and Appendix H). It computes the roof catchment area, the design stormwater flow, the maximum catchment per downpipe, the minimum number of downpipes, and the required downpipe size. Rainfall intensities are the 5 minute duration values from the Standard's Appendix E.

1 Design rainfall

Pick your location to load the AS/NZS 3500.3 Appendix E intensity, or enter a value from the BoM IFD data directly.

Location

Average Recurrence Interval (ARI)

Eaves gutters: ≥20 yr (Table 3.3.4). Box/valley gutters: ≥100 yr.

Design rainfall intensity ^{5 min}I

mm/h

2 Roof catchment

Catchment area accounts for wind-driven rain on the sloping surface: Ac = Ah × (1 + 0.5·tanθ) (Cl 3.4.3.2).

Plan area of roof, A_h

m²

Horizontal plan area of the roof draining to the gutter (include the gutter width).

Length × width (plan).

Roof pitch, θ

24°

Multiplier F = 1.22 · Catchment area A_c = 175 m²

3 Eaves gutter

The gutter's effective cross-sectional area A_e (the waterway below the overflow line, per AS/NZS 2179.1) sets its flow capacity (Fig 3.5.4) and the downpipe size (Table 3.5.2).

Gutter gradient (fall)

Gutter profile (sets A_e)

Indicative typical values only — always confirm A_e from the manufacturer's data sheet.

Effective cross-sectional area, A_e

mm²

Manufacturer-rated gutter capacity (optional)

L/s

If your manufacturer publishes a tested capacity, enter it here for an exact result.

Result · AS/NZS 3500.3:2018

Minimum downpipes

51 m²

Max catchment / downpipe

Required vertical downpipe — Table 3.5.2

100 mm Ø or 100 × 75 mm

Roof slope multiplier, F	1.22
Catchment area, A_c	175 m²
Design rainfall intensity, I	145 mm/h
Total design flow, Q	7.05 L/s
Gutter flow capacity · Fig 3.5.4	2.21 L/s
Catchment / downpipe, A_cdp	54.8 m²
Flow per downpipe	1.76 L/s

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Calculation basis & assumptions

This tool implements the AS/NZS 3500.3:2018 general method for eaves gutter systems (Clause 3.5, flow chart Fig 3.5.2; worked example Appendix H):

Catchment area — Ac = Ah × (1 + 0.5·tanθ), the closed form of the Table 3.4.3.2 multiplier F (Eq 3.4.3.2(2)). Wind direction need not be considered for a hipped/gable roof of constant slope with no contributing walls.
Design flow — Q = Ac × I / 3600 (L/s), with I the 5 min duration intensity.
Rainfall intensity — Appendix E (Australia), 5 min duration. 20 yr ARI for eaves gutters (Table 3.3.4); 500 yr ARI = 1.5 × 100 yr (Cl 3.3.5.1(b)).
Gutter flow capacity — linear digitisation of Figure 3.5.4 between its labelled axis endpoints (A_e 3000→18000 mm² ⇄ 0.68→6.0 L/s for 1:500 & steeper; 3000→24000 mm² for flatter). This reproduces the Appendix H example (A_e=7300 mm² → ≈2.1 L/s) within chart-reading tolerance. For critical work, enter the manufacturer's rated capacity instead.
Catchment per downpipe — Acdp = Qcap × 3600 / I; minimum number of downpipes = ⌈Ac / Acdp⌉.
Downpipe size — Table 3.5.2, selected on A_e and gradient.

The general method excludes localised wind effects, blockage by debris/hail, and reduced capacity from ground movement (Cl 3.2). It assumes regular inspection and cleaning.

⚠ Indicative design aid — verify before use

This calculator is provided as an engineering aid and reproduces the AS/NZS 3500.3:2018 method, but it is not a substitute for design by a competent person. Always confirm rainfall intensities against current Bureau of Meteorology IFD data and gutter properties against manufacturers' data. BOICA accepts no liability for use of this tool. For a checked, certifiable roof drainage design, get in touch.