Cable Derating Factors [2026]

$$ I_{eff} = I_{nom} \times k_{temp} \times k_{group} \times k_{soil} \times k_{depth} \times k_{altitude} \times k_{harmonics} \times ... $$

Soil thermal resistivity ($\rho$, in K·m/W) measures how effectively soil transfers heat. Dry sand or gravel is a terrible conductor (high resistivity). Moist clay or loam is excellent (low resistivity). cable derating factors

The real world, however, is far less forgiving. $$ I_{eff} = I_{nom} \times k_{temp} \times k_{group}

A cable at 0.5m depth dissipates heat better than at 1.5m depth. Derating factors for depth are typically small (0.95–0.98 per 0.5m increase) but become significant for long, high-current runs. Moist clay or loam is excellent (low resistivity)

Most codes ignore cyclic factor for safety, but for very intermittent loads (e.g., crane motors), engineering judgment can allow higher peak currents. Putting It All Together: The Cumulative Derating Formula The final effective ampacity is: