Power scales as the cube of speed: P_2/P_1 = (N_2/N_1)³. Cutting fan speed in half cuts power to 1/8. This is why VFD speed control on fans and pumps almost always pays back, especially on variable-load systems.

When do affinity laws break down?

Affinity laws assume constant efficiency. Far from BEP they over-predict performance by 5–15%. They also miss Reynolds-number effects at very low speeds and don't apply to viscous fluids requiring viscosity-corrected curves.

What about altitude correction?

Density change directly scales pressure rise and BHP. A fan rated at sea level (ρ = 1.20 kg/m³) at 5,000 ft (ρ = 1.05) delivers same flow at 87% pressure and 87% BHP. Always specify fan and motor at the actual installation density.

Fan Affinity Laws

Predict new operating point from a known one when speed, impeller diameter, or fluid density changes. Same equations work for centrifugal pumps and fans. Used for VFD energy savings analysis, fan trim, and altitude correction.

The cube law and VFD economics

Power scales with the cube of speed. Cutting fan speed in half cuts power to 1/8. This is why variable-frequency-drive (VFD) control on fans and pumps almost always pays back, especially when the system actually varies its load. A constant-speed fan throttling 20% of its flow with a damper might use 90% of full power. The same fan on a VFD doing the same flow uses 50% (= 0.8³) of full power.

For continuous service, the energy savings often pay for the VFD in 1–3 years. Add: smaller starting current, soft starts, less mechanical stress on belts and bearings, and the VFD becomes the standard solution for any motor > 5 hp on variable-load service.

Affinity laws assume constant efficiency

The pure affinity laws assume η_pump = constant across the speed range. This is a good approximation when the operating point traces a "system curve" through the BEP region. Far from BEP, efficiency drops and the affinity laws over-predict performance by 5–15%.

For wide-range speed control, plot the family of fan curves at multiple speeds (each shifted by affinity laws) and find the actual duty point where each crosses the system curve. AMCA Pub. 200 has worked examples.

Diameter trim — limits

Centrifugal pumps and fans can have impellers trimmed to reduce capacity without speed change. Trim is limited to about 75–80% of the maximum diameter — beyond that, the curve flattens, efficiency drops sharply, and the relationships above no longer apply. Trim is permanent (have to swap impeller back for design changes) so VFD is preferred for variable service.

Density correction (altitude, temperature)

Fans see ρ_2/ρ_1 directly proportional to pressure rise and BHP. A fan rated at sea level (ρ = 1.20 kg/m³) installed at 5,000 ft altitude (ρ = 1.05) delivers the same flow at 87% of rated pressure and 87% of rated BHP. Specify fan and motor with this correction at the actual installation density, not at standard conditions.

What's NOT in affinity laws

Reynolds number effects (matter only at very low speeds, < 50% rated)
Viscosity (heavy oils require viscosity-corrected curves; affinity laws are for water/air)
NPSH variation with speed (NPSH_r roughly scales with N², so cavitation is worse at high speed)
Off-BEP operation (system curve drift; revisit selection if duty range is wide)

Reference: AMCA Publication 200 (2010). Air Systems. ASHRAE Handbook (2024), Fundamentals, ch. 21. Hydraulic Institute (2021). HI Pump Standards.