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Estimate the correct gas pipe diameter based on total appliance load and pipe length, following UK BS 6891 guidance.
Instantly calculate the correct gas pipe size for any boiler, appliance or installation. Includes sizing charts, BS 6891 tables, formulas and a full step-by-step guide.
Gas pipe sizing is the process of choosing the right internal pipe diameter to deliver enough gas β at the right pressure β to every appliance in a property. Get it right and your boiler, cooker and fires all work perfectly. Get it wrong and you risk pressure drops, appliance lockouts, and serious safety problems.
In the UK, natural gas systems typically operate at a supply pressure of 21 mbar. Under BS 6891 (the standard for low-pressure gas pipework), the maximum allowable pressure drop between the meter and any appliance is just 1 mbar. That tiny margin means pipe diameter, pipe length and total gas demand must all be calculated carefully.
This page gives you everything you need: a free gas pipe sizing calculator, UK sizing charts, the sizing formula explained simply, a worked example, common mistakes to avoid and a full FAQ.
Undersized pipes can starve appliances of gas, create pressure fluctuations and increase the risk of incomplete combustion.
Correctly sized gas pipework ensures appliances run at their rated output, reducing fuel waste and energy bills.
UK gas installations must comply with Gas Safety (Installation and Use) Regulations and BS 6891. Correct sizing is a legal requirement.
Enter your total appliance load and pipe run details. Results follow BS 6891 / IGE/UP/2 guidance.
The calculator needs four inputs:
The output is the minimum recommended outside diameter (OD) in millimetres, based on a maximum 1 mbar pressure drop at 21 mbar supply pressure.
The tables below show the maximum gas load (kW) that each standard pipe size can carry at different pipe lengths, following UK BS 6891 guidance for natural gas at 21 mbar supply pressure and a 1 mbar maximum pressure drop. Use these alongside the gas pipe size calculator to verify your selection.
| Pipe OD | Internal Γ (approx) | 3 m run | 6 m run | 10 m run | 15 m run | 20 m run | 30 m run |
|---|---|---|---|---|---|---|---|
| 15 mm | 13.6 mm | 28 kW | 19 kW | 14 kW | 11 kW | 9 kW | 7 kW |
| 22 mm | 19.6 mm | 87 kW | 60 kW | 45 kW | 36 kW | 30 kW | 23 kW |
| 28 mm | 25.6 mm | 180 kW | 126 kW | 95 kW | 75 kW | 63 kW | 48 kW |
| 35 mm | 32.0 mm | 340 kW | 240 kW | 180 kW | 142 kW | 120 kW | 92 kW |
| 42 mm | 38.8 mm | 580 kW | 410 kW | 306 kW | 243 kW | 204 kW | 157 kW |
Values are indicative for Type R250 copper tube (EN 1057) at 21 mbar supply, 1 mbar max drop, natural gas calorific value 38.6 MJ/mΒ³. For precise design, consult manufacturer tables or a Gas Safe engineer.
| Appliance Load | Short Run (< 6 m) | Medium Run (6β15 m) | Long Run (> 15 m) | Typical Use Case |
|---|---|---|---|---|
| Up to 15 kW | 15 mm β | 15 mm | 22 mm | Small gas fire, tumble dryer |
| 16β25 kW | 15 mm | 22 mm Rec. | 22 mm | 24 kW combi boiler |
| 26β35 kW | 22 mm | 22 mm Rec. | 28 mm | 30β35 kW system boiler |
| 36β50 kW | 22 mm | 28 mm Rec. | 28 mm | Boiler + hob + fire |
| 51β80 kW | 28 mm | 28 mm | 35 mm Rec. | Large house, multiple appliances |
| 81β120 kW | 35 mm | 35 mm | 42 mm | Light commercial |
| 121 kW+ | Specialist design required β IGE/UP/2 Edition 3 | Commercial / industrial | ||
| Pipe OD | 10 ft (3 m) | 20 ft (6 m) | 50 ft (15 m) | 100 ft (30 m) |
|---|---|---|---|---|
| 15 mm | 95,400 BTU | 64,800 BTU | 37,500 BTU | 24,000 BTU |
| 22 mm | 297,000 BTU | 205,000 BTU | 123,000 BTU | 78,000 BTU |
| 28 mm | 615,000 BTU | 430,000 BTU | 257,000 BTU | 164,000 BTU |
| 35 mm | 1,160,000 BTU | 820,000 BTU | 485,000 BTU | 314,000 BTU |
1 kW β 3,412 BTU/hr. BTU values rounded for practical use.
UK domestic and light commercial gas systems use metric copper or steel pipe. Here are the standard gas pipe sizes and where each is typically used.
| Feature | Copper Pipe | Steel / Black Iron Pipe |
|---|---|---|
| Standard (UK) | EN 1057, Type R250 | BS EN 10255 |
| Common sizes | 15, 22, 28, 35, 42 mm OD | DN15, DN20, DN25, DN32, DN40 |
| Typical use | Domestic, residential, small commercial | Commercial, industrial, high-pressure runs |
| Flow resistance | Slightly higher (smooth bore) | Lower internal roughness when new |
| Corrosion | Excellent resistance | Requires protection / coatings externally |
| Jointing | Solder, compression, press-fit | Threaded, flanged, welded |
| Cost | Moderate | Lower per metre but higher labour |
You don't need to use the formula manually β the calculator above does it for you. But understanding the logic helps you make better decisions and spot potential problems.
A gas pipe must deliver a high enough volumetric flow rate (measured in mΒ³/h) to meet the total appliance demand, without losing too much pressure along the way.
The key relationship is this: the longer or narrower the pipe, the more resistance it creates, and the more pressure you lose before the gas reaches the appliance.
In practice, Gas Safe engineers use manufacturer sizing tables (published by British Gas / Transco) or software tools rather than calculating this by hand. The maximum permitted pressure drop for domestic gas pipework under BS 6891 is 1 mbar.
Every elbow, tee or valve creates turbulence and adds resistance. Engineers convert these to an "equivalent pipe length" β extra metres added to the measured pipe run before looking up sizing tables.
| Fitting Type | 15 mm equiv. | 22 mm equiv. | 28 mm equiv. |
|---|---|---|---|
| 90Β° elbow | 0.5 m | 0.8 m | 1.0 m |
| Equal tee (flow through branch) | 1.5 m | 2.0 m | 2.5 m |
| Ball valve / isolating cock | 0.3 m | 0.5 m | 0.6 m |
| 45Β° elbow | 0.3 m | 0.5 m | 0.6 m |
| Meter / regulator | Typically 3β5 m equivalent β check manufacturer data | ||
This is the most common scenario in UK domestic gas work. Here's exactly how to calculate the correct gas pipe size for a 24 kW combi boiler with a 10 m pipe run.
In this example: one 24 kW combi boiler. If there were also a gas hob (10 kW) and a gas fire (5 kW), the total would be 39 kW. Here, total load = 24 kW.
Measure along the actual pipe route β not a straight line. In this example the measured run is 8 m, with 4 elbows. Each elbow on 22 mm pipe = 0.8 m equivalent. So: 8 + (4 Γ 0.8) = 11.2 m equivalent pipe length.
Q = 24 kW Γ· 10.73 kWh/mΒ³ = 2.24 mΒ³/h. This is the gas flow your pipe must deliver.
Using the BS 6891 / Transco table for copper pipe, 21 mbar supply, 1 mbar max drop: at 11.2 m equivalent length and 24 kW demand β 22 mm OD copper pipe is sufficient. The table shows 22 mm can carry up to 45 kW at 10 m, well above our 24 kW requirement.
Most UK domestic gas meters have a 22 mm outlet connection. If upgrading to a larger boiler or adding appliances, check the meter outlet capacity and contact Cadent / SGN if an upgrade is needed.
22 mm OD copper pipe is the correct gas pipe size for a 24 kW combi boiler on a 10 m run in this scenario. If the run were longer than 20 m, 28 mm would be required.
| Boiler Output | Run < 6 m | Run 6β15 m | Run 15β25 m | Run > 25 m |
|---|---|---|---|---|
| 24 kW combi boiler | 15 mm | 22 mm Rec. | 22 mm | 28 mm |
| 28 kW combi boiler | 22 mm | 22 mm Rec. | 22 mm | 28 mm |
| 30 kW combi boiler | 22 mm | 22 mm | 28 mm Rec. | 28 mm |
| 35 kW system boiler | 22 mm | 22 mm | 28 mm Rec. | 28 mm |
| 40 kW system boiler | 22 mm | 28 mm Rec. | 28 mm | 35 mm |
| Boiler + hob + fire (~45 kW) | 28 mm | 28 mm Rec. | 28 mm | 35 mm |
These recommendations assume a single straight pipe run from the meter to the appliance. Always verify against the manufacturer's commissioning data and the actual site layout.
These are the errors that cause most gas pressure and performance problems in UK properties. Knowing them helps you avoid costly re-work or safety issues.
A 15 mm pipe can only carry around 14 kW at a 10 m run. Most modern combi boilers are 24β35 kW. A 15 mm supply almost guarantees pressure drop problems, especially when the boiler fires at full output.
Sizing based on a straight-line estimate instead of the real pipe route β including drops through floors, bends around joists and tees to other appliances β results in seriously undersized pipe.
Each elbow or tee adds equivalent pipe resistance. On a run with 8 elbows, forgetting to add the equivalent length can undersize the pipe by the equivalent of 6+ extra metres.
When multiple appliances share a pipe section, the pipe must carry the combined gas demand. Sizing only for the boiler and ignoring a gas hob or fire on the same run is a very common mistake.
The UK domestic gas meter and its outlet are typically rated for a maximum flow. Adding a large new boiler or multiple appliances without checking meter capacity can restrict the entire system, regardless of pipe size.
Many older UK properties still have 15 mm gas pipes installed for previous appliances with lower outputs. Simply swapping to a modern high-output boiler without upgrading the gas pipe is a frequent cause of boiler lockouts and poor performance.
To calculate gas pipe size, you need to know three things: (1) the total gas demand in kW of all appliances on that pipe run, (2) the total equivalent pipe length in metres (measured route plus an allowance for fittings), and (3) the pipe material (copper or steel). Convert the kW demand to a volumetric flow rate (mΒ³/h) by dividing by 10.73. Then look up the appropriate pipe diameter from a BS 6891 sizing table, or use a gas pipe sizing calculator like the one at the top of this page. The pipe you choose must carry the required flow with no more than 1 mbar pressure drop at 21 mbar supply pressure.
For most UK domestic combi boilers (24β35 kW) on pipe runs up to 15 m, 22 mm OD copper pipe is the standard recommendation. For runs longer than 20 m, or where multiple appliances share the same pipe section, 28 mm is usually required. A 15 mm pipe is generally too small for modern boilers on anything other than the very shortest spur connections (under 3 m). Always check against the boiler manufacturer's gas supply requirements in the installation manual.
Gas pipe sizing involves four steps: (1) list all appliances supplied by that pipe section and add their kW ratings together; (2) measure the pipe route carefully and add equivalent lengths for fittings (elbows, tees, valves); (3) convert the total kW to a flow rate in mΒ³/h; (4) look up the minimum pipe diameter in the BS 6891 / Transco sizing tables that delivers that flow at your required equivalent length. The gas pipe sizing calculator on this page automates steps 3 and 4 for you.
Gas pipe size is determined by two main factors: the total gas demand (kW) that the pipe must supply, and the total equivalent pipe length. Longer runs and higher demands both require larger diameters to keep pressure drop within the 1 mbar limit specified by BS 6891. You use a gas pipe sizing calculator or published Transco sizing tables to find the minimum acceptable diameter. Always round up to the next standard pipe size β never down.
In the UK, copper gas pipe is measured and sold by outside diameter (OD). So "22 mm pipe" means the outside is 22 mm across. To measure an existing pipe, use a set of pipe ID/OD callipers or wrap a string around the pipe and measure the circumference, then divide by Ο (3.14159) to get the OD. Do not confuse OD with ID (internal diameter) β the internal diameter of 22 mm copper pipe is approximately 19.6 mm. Steel pipe is described differently using DN (nominal bore) sizes; DN20 steel pipe is broadly equivalent in capacity to 22 mm copper.
An undersized gas pipe creates excessive pressure drop. At the appliance end, the gas pressure falls below what the appliance needs to operate correctly. For a boiler, this typically causes: failure to ignite at full output, the boiler locking out on a low-gas-pressure fault, intermittent operation (especially when other appliances are also on), and incomplete combustion in severe cases. An undersized gas line can also cause a boiler to run at reduced output, raising energy bills and shortening appliance life.
Only on a very short spur of 3 m or less. At 10 m, 15 mm copper pipe can only carry around 14 kW β well below the 24 kW demand of the boiler. In practice, most Gas Safe engineers will specify 22 mm as the minimum for any combi boiler connection, even on short runs, to give adequate capacity margin and comply with manufacturer requirements. Using 15 mm pipe for a modern high-output boiler on a standard domestic pipe run will almost certainly cause pressure drop problems.
The most common standard gas pipe sizes in UK domestic properties are 15 mm, 22 mm and 28 mm OD copper tube (to EN 1057). 22 mm is the most widely used size, suitable for most combi boiler installations. 15 mm is used for short spurs to individual appliances. 28 mm is used for the main meter-to-distribution run in properties with multiple gas appliances or longer pipe routes. 35 mm and 42 mm are used in larger domestic or light commercial settings.
The gas pipe sizing formula is based on the Weymouth equation for compressible flow: ΞP = (C Γ L Γ QΒ²) Γ· Dβ΅, where ΞP is pressure drop in mbar, L is equivalent pipe length in metres, Q is flow rate in mΒ³/h, D is internal pipe diameter in mm, and C is a constant that depends on gas type and pipe material. In practice, engineers use published BS 6891 sizing tables (based on this formula) or software tools rather than calculating this by hand. The target is always ΞP β€ 1 mbar for domestic gas.
Yes. If a gas pipe is too small, the boiler cannot receive enough gas at the correct pressure to fire at full rated output. This means the boiler modulates down or locks out, reducing efficiency and increasing run times. On the other hand, correctly sized gas pipework ensures the boiler gets a stable gas supply at 20β21 mbar, allowing it to run at peak efficiency. This is particularly important for condensing boilers, which need stable operation to reach their rated seasonal efficiency.