How Do I Calculate Pipe Flow Rates, Velocity & Pressure Drop for Domestic Plumbing?
Quick Answer: For domestic water supply, target a flow velocity of 1–3 m/s in copper pipes. Use the Hazen-Williams or Colebrook-White equation for pressure drop, or reference BS EN 806-3 design flow tables. A 22mm copper pipe (15mm internal diameter) at 2 m/s carries approximately 21 litres/minute; a 15mm pipe (13mm internal diameter) carries approximately 16 litres/minute at the same velocity.
Summary
Correct pipe sizing ensures adequate flow at all outlets without noise, erosion, or excessive pressure loss. Undersized pipes cause low pressure at taps and showers; oversized pipes are costly and slow to heat up. The fundamental relationship is between pipe bore, flow velocity, and flow rate — get one wrong and the whole system suffers.
In domestic plumbing, BS EN 806 Part 3 provides a simplified design method for sizing cold and hot water distribution pipework. It establishes design flow rates for each appliance type, uses a diversity factor to account for the fact that not all outlets run simultaneously, and sets maximum velocity limits to prevent noise and pipe erosion.
For central heating pipework, CIBSE Guide C and manufacturer data are the primary references. Heating circuits typically operate at 0.5–1.5 m/s, with lower velocities in smaller bore pipes to avoid pump noise.
Key Facts
- Maximum velocity — copper cold water supply — 3 m/s to prevent erosion
- Maximum velocity — copper hot water supply — 1.5 m/s to prevent erosion (hot water softens copper more quickly)
- Minimum velocity — 0.5 m/s to prevent stagnation and Legionella risk
- Target velocity range — 1–2 m/s for most domestic supply pipework
- Design flow rates by appliance (BS EN 806-3) — basin: 0.1 l/s, bath: 0.3 l/s, WC cistern: 0.1 l/s, shower: 0.1–0.2 l/s
- Diversity factor — simultaneous demand is less than sum of all outlets; BS EN 806-3 Table 2 gives loading units
- Pressure at outlet — minimum 0.1 bar at basin, 0.1 bar at WC; shower heads typically 0.5–1.0 bar minimum
- Mains pressure — UK mains typically 1.5–3 bar at stop cock; check with water authority
- Pressure drop in fittings — add equivalent pipe length: elbow ≈ 0.5m, tee ≈ 1.0m, 15mm isolation valve ≈ 2.0m
- Flow rate formula — Q = V × A, where Q = flow (m³/s), V = velocity (m/s), A = cross-sectional area (m²)
- 15mm copper bore — internal diameter approximately 13.6mm; area = 0.000145 m²
- 22mm copper bore — internal diameter approximately 20.2mm; area = 0.000320 m²
- 28mm copper bore — internal diameter approximately 26.2mm; area = 0.000539 m²
- MDPE pipe bore — 25mm MDPE has approximately 20.4mm internal diameter (varies by SDR rating)
Quick Reference Table
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Try squote free →| Pipe Size | Internal Bore | Flow at 1 m/s (l/min) | Flow at 2 m/s (l/min) | Max Flow (3 m/s) (l/min) |
|---|---|---|---|---|
| 15mm copper | 13.6mm | 8.7 | 17.4 | 26.1 |
| 22mm copper | 20.2mm | 19.2 | 38.4 | 57.6 |
| 28mm copper | 26.2mm | 32.3 | 64.6 | 96.9 |
| 35mm copper | 32.6mm | 50.0 | 100.0 | 150.0 |
| 25mm MDPE | 20.4mm | 19.6 | 39.2 | 58.8 |
| 32mm MDPE | 26.2mm | 32.3 | 64.6 | 96.9 |
| Appliance | Design Flow Rate (BS EN 806-3) | Loading Units |
|---|---|---|
| Basin tap | 0.1 l/s (6 l/min) | 1 |
| Bath tap | 0.3 l/s (18 l/min) | 3 |
| WC cistern | 0.1 l/s (6 l/min) | 1 |
| Shower (mixer) | 0.1 l/s (6 l/min) | 1 |
| Kitchen sink | 0.2 l/s (12 l/min) | 2 |
| Dishwasher | 0.15 l/s (9 l/min) | 2 |
| Washing machine | 0.15 l/s (9 l/min) | 2 |
Detailed Guidance
Calculating Flow Rate from Velocity
The basic flow rate formula is:
Q = V × A
Where:
- Q = volumetric flow rate (m³/s)
- V = velocity (m/s)
- A = pipe bore cross-sectional area (m²)
For a 22mm copper pipe (internal diameter 20.2mm = 0.0202m):
- A = π × (0.0202/2)² = π × 0.01010² = 0.000320 m²
- At V = 2 m/s: Q = 2 × 0.000320 = 0.000640 m³/s = 0.64 litres/second = 38.4 litres/minute
Practical conversion: 1 litre/second = 60 litres/minute = 16.67 gallons/minute
Using BS EN 806 Loading Units
Rather than calculating absolute flow rates for every outlet, BS EN 806-3 uses a loading unit system:
- Assign loading units to each outlet in the building (see table above)
- Total all loading units on the circuit being sized
- Convert to design flow rate using BS EN 806-3 Table 3 (the diversity curve)
- Size the pipe so that this design flow rate is achieved within velocity limits
This method inherently applies a diversity factor — a house with 15 loading units does not demand 15 × 6 l/min simultaneously.
Example: 3-bedroom house with 2 bathrooms:
- 2 × basin (2 LU), 2 × WC (2 LU), 1 × bath (3 LU), 2 × shower (2 LU), 1 × kitchen sink (2 LU), 1 × washing machine (2 LU) = 15 LU
- From BS EN 806-3 diversity table: 15 LU → design flow approximately 0.42 l/s
- At 2 m/s, required bore: A = Q/V = 0.00042/2 = 0.00021 m² → diameter = 16.4mm → use 22mm copper
Calculating Pressure Drop
Pressure drop in straight pipework can be calculated using simplified tables or formulae. For practical site use, the Darcy-Weisbach approach is most reliable:
ΔP = f × (L/D) × (ρV²/2)
Where:
- ΔP = pressure drop (Pa)
- f = Darcy friction factor (typically 0.02–0.03 for copper, 0.01–0.02 for plastic)
- L = pipe length (m)
- D = internal diameter (m)
- ρ = fluid density (kg/m³) — water ≈ 1000 kg/m³ at 10°C
- V = velocity (m/s)
For quick site calculations, use manufacturer pressure drop tables, which give Pa/m at various flow rates. A typical value for 22mm copper at 0.3 l/s is approximately 200–300 Pa/m (2–3 mbar/m).
Rule of thumb: Add 10–20% to calculated pipe length to account for fittings, or use the equivalent length method (add 0.5m per elbow, 1.0m per tee branch, etc.).
Sizing for Central Heating Circuits
Heating systems use slightly different criteria:
- Target velocity: 0.5–1.0 m/s in small bore (15mm, 22mm)
- Maximum: 1.5 m/s to avoid pump noise and erosion
- Pressure drop target: typically 150–300 Pa/m (index circuit)
- Heating load carried: P = ṁ × Cp × ΔT, where ΔT is typically 10–20°C for CH circuits
Example: Radiator circuit carrying 5 kW with 20°C temperature difference:
- Mass flow: ṁ = P/(Cp × ΔT) = 5000/(4186 × 20) = 0.060 kg/s ≈ 0.060 l/s
- At 1 m/s, required area: 0.060/1000 = 0.000060 m² → diameter = 8.7mm → use 15mm copper
Noise and Erosion Limits
Exceeding velocity limits causes two problems:
- Erosion — particularly at bends and fittings, where turbulent flow scours the pipe wall. Hot water pipes erode faster. This is why 15mm hot water supply should be kept under 1.5 m/s.
- Flow noise — velocity over 3 m/s in cold water supply creates audible rushing/hissing in pipes. Often misidentified as water hammer. The fix is to upsize the pipe or add a pressure reducing valve.
Frequently Asked Questions
My customer has low pressure at a shower — how do I diagnose this?
Start at the source: check dynamic mains pressure at the stop cock under flow (a pressure gauge on a hose fitting works). If below 1.5 bar, the issue is supply pressure. If supply pressure is adequate, calculate the pressure loss through the supply pipe: measure total pipe length, count fittings, and use pressure drop tables. Often the problem is a long run of 15mm pipe that should be 22mm. Alternatively, a clogged strainer or partially closed isolation valve can cause dramatic pressure loss.
Should I design to the maximum velocity or a lower working velocity?
Design to a working velocity of 1–2 m/s for most domestic supply. Sizing to the 3 m/s maximum leaves no margin for additional outlets being added later and causes noise at the upper end. The maximum limits in BS EN 806 are absolute limits, not design targets.
Does pipe material affect flow rate significantly?
For the same bore and flow rate, plastic pipe (copper press fit, PEX, PB) has a slightly smoother internal surface than copper (lower roughness factor), meaning slightly less friction and pressure drop. In practice for domestic systems, the difference is small. The more significant factor is ensuring you use the manufacturer's stated internal diameter — a 22mm push-fit plastic pipe may have a different bore than 22mm copper.
How does hot water affect pipe sizing?
Hot water is less dense and less viscous than cold. This means higher velocity for the same flow rate and faster erosion. BS EN 806 recommends keeping hot water velocities below 1.5 m/s rather than the 3 m/s limit for cold. In practice, most domestic hot water pipes are sized conservatively at 15mm (hand basin, shower) and 22mm (bath, high-demand circuits) without detailed calculation.
What's the minimum flow rate I need at a thermostatic shower valve?
Check the manufacturer specification — most quality thermostatic shower valves require a minimum dynamic pressure of 0.5–1.0 bar and a minimum flow rate of 8–15 litres/minute. High-flow rain heads may need 25 l/min or more. This determines not only pipe sizing but whether a combi boiler or cold water storage system can deliver adequate flow.
Regulations & Standards
BS EN 806-3 — Design of installations for water supply; pipe sizing method for cold and hot water
BS EN 806-1 — General requirements for domestic water installations
Water Supply (Water Fittings) Regulations 1999 — Design and installation requirements for water fittings in the UK
CIBSE Guide C — Reference data including pressure drop tables and pipe sizing methods for heating systems
BS 6700 (superseded by BS EN 806) — Still referenced in older installations; same fundamental principles
CIPHE — Chartered Institute of Plumbing and Heating Engineering — Guidance on BS EN 806 and domestic pipe sizing
BS EN 806 Parts 1–5 — Full standard for water supply installations
CIBSE — Chartered Institution of Building Services Engineers — Guide C: Reference data for pipe sizing calculations
Copper Development Association — Copper tube dimensions and pressure ratings
pipe sizing — Practical pipe sizing guide for domestic supply
unvented cylinders — Flow requirements for unvented cylinder discharge
water regulations — Legal requirements for water fittings
mains water boosting — When and how to boost mains pressure