Pipe Velocity Calculator

Velocity from flow and pipe internal diameter — or edit the velocity to find the flow a line can carry.

use our flow converter for other units
ID, not nominal — DN100 Sch40 ≈ 102.3
edit to solve for flow
Velocity
m/s
ft/s · area cm² · flow m³/h

The formula

Velocity is simply flow divided by the pipe's internal cross-section:

v = Q ÷ A,   A = π·D²/4

or in the practical metric units this tool uses:

v (m/s) = 353.68 × Q (m³/h) ÷ D² (mm)

The constant 353.68 collapses the unit conversions (m³/h → m³/s and mm² → m²) into one number worth memorising for field estimates.

Worked example

100 m³/h of water through a DN100 Sch 40 pipe (ID = 102.3 mm):

  1. v = 353.68 × 100 ÷ 102.3² = 353.68 × 100 ÷ 10465
  2. v = 3.38 m/s — on the fast side for continuous pumping; DN125 would give 2.1 m/s

Recommended velocity ranges

ServiceTypical target
Pump suction (liquid)0.5 – 1.5 m/s
Pump discharge (liquid)1 – 3 m/s
Gravity drain lines0.5 – 1 m/s
Slurry (keep solids moving)1.5 – 3 m/s
Process gas10 – 25 m/s
Steam (saturated)20 – 40 m/s

These are rules of thumb, not law — the real constraints are pressure drop, erosion, noise, water hammer risk and NPSH. But a line far outside these bands is usually a design smell worth questioning.

Why instrumentation people care

  • Flow meters have velocity windows. Magnetic meters like 1–10 m/s (below ~0.5 m/s accuracy suffers); vortex meters need a minimum Reynolds/velocity to shed vortices at all; ultrasonic meters publish velocity ranges directly.
  • Thermowells in fast gas can resonate — velocity feeds directly into wake-frequency calculations.
  • Erosion at the meter run: high velocity with entrained solids wears orifice plates' sharp edges, silently degrading accuracy.

Frequently asked questions

What is the formula for velocity in a pipe?

v = Q / A, where Q is volumetric flow and A = π·D²/4 is the pipe cross-sectional area from the internal diameter. In practical units: v (m/s) = 353.68 × Q (m³/h) ÷ D² (mm).

What is a good liquid velocity in a pipe?

Typical design targets: 1–3 m/s for pump discharge liquid lines, 0.5–1.5 m/s for suction lines (to protect NPSH), and up to 4–5 m/s for short clean-water runs. Erosive or slurry services run slower.

What velocity should gas lines use?

Common practice is 10–25 m/s for process gas and up to ~30–40 m/s in utility air or vent lines, limited by pressure drop and noise rather than erosion in clean gas.

Do I use the pipe nominal size or internal diameter?

Always the internal diameter (ID). A DN50 Sch 40 steel pipe has an ID of about 52.5 mm — nominal size and ID differ, and the difference grows with wall schedule.

Provided for reference and education. Verify independently before use in safety-critical work. See our disclaimer.

Related tools