⚡ Total Heat Content

Enthalpy Calculator

Calculate moist air enthalpy in BTU/lb and kJ/kg, split into sensible and latent components. Includes a 2-point enthalpy difference calculator for cooling coil and ventilation energy analysis. Use with the cooling coil calculator and full psychrometric calculator.

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⚡ Enthalpy Results
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Using moist air enthalpy to size cooling coils in Canada

Enthalpy is the total heat content of moist air per unit mass of dry air — it combines the sensible heat stored in the air's temperature with the latent heat stored in the water vapour. When a cooling coil processes air, it removes total heat equal to the airflow times the enthalpy difference between entering and leaving conditions. This single number captures both the temperature drop (sensible) and the moisture removal (latent) in one calculation.

The formula for total coil capacity is: Q (BTU/hr) = CFM x 4.5 x (h_entering - h_leaving), where h is in BTU/lb and 4.5 is the standard air mass flow factor at sea level (60.45 minutes/hr x 0.075 lb/ft³). At Canadian cities with significant elevation, the density factor drops. Calgary at 1045 m has a standard air density of about 0.0638 lb/ft³, giving a factor of 3.84 instead of 4.5 — a 15% reduction. This calculator applies the elevation-corrected factor automatically.

Sensible vs. latent enthalpy components

Total enthalpy splits into sensible and latent components. Sensible enthalpy (BTU/lb) = 0.240 x T_db (°F). Latent enthalpy (BTU/lb) = W (lb/lb) x (1061 + 0.444 x T_db). For typical summer comfort cooling from 80°F/50% RH entering to 55°F/95% RH leaving air, sensible enthalpy drops from about 19.2 to 13.2 BTU/lb (6.0 BTU/lb sensible change) while latent enthalpy drops from about 18.9 to 10.0 BTU/lb (8.9 BTU/lb latent change). Total enthalpy change is about 14.9 BTU/lb, with an SHR of roughly 0.40 — indicating a heavily dehumidifying coil.

For dry climates like Calgary and interior BC, summer outdoor air has low humidity ratio. Entering air enthalpy is dominated by sensible heat, and the latent component is small. Coils in these climates have high SHR (0.85-0.95) — most of the cooling work is sensible. Use the cooling coil calculator to compute SHR and apparatus dew point from entering and leaving conditions.

Ventilation enthalpy loads in Canadian climates

Ventilation energy recovery is sized from the enthalpy difference between outdoor and exhaust air. In Toronto summers, outdoor air at 35°C and 60% RH has an enthalpy of about 83 kJ/kg (35.7 BTU/lb), while exhaust air at 24°C and 50% RH has about 48 kJ/kg (20.6 BTU/lb). The enthalpy recovery opportunity is 35 kJ/kg (15.1 BTU/lb) per unit mass of outdoor air — substantial enough to justify energy recovery ventilators (ERVs) in most Canadian commercial buildings. See the HRV/ERV calculator for recovery efficiency analysis.

Frequently Asked Questions

Moist air enthalpy (BTU/lb dry air) = 0.240 x T_db (°F) + W (lb/lb) x (1061 + 0.444 x T_db). For coil sizing, calculate enthalpy at entering conditions (return plus outdoor air mix) and at leaving conditions (design supply air). Total coil capacity (BTU/hr) = CFM x 4.5 x (h_entering - h_leaving). At elevated Canadian cities, replace 4.5 with an elevation-corrected density factor — this calculator applies the correction automatically. Use the cooling coil calculator for full SHR and bypass factor analysis.

Total enthalpy has 2 components. Sensible enthalpy (= 0.240 x T_db) changes with temperature at constant humidity. Latent enthalpy (= W x 1061) changes with moisture content at constant temperature. A cooling coil removes both: sensible cooling reduces dry-bulb temperature, latent removes moisture as condensate. The Sensible Heat Ratio (SHR = sensible / total) is typically 0.75-0.85 for comfort cooling. Use the cooling coil calculator to compute SHR from entering and leaving conditions, and the humidity ratio calculator for latent-only analysis.