Skip to main content
Speclore

Evaporation Water Surface

Reference data and engineering information about evaporation water surface for thermodynamics applications.

evaporationwatersurface

Overview

Engineering reference data for Evaporation Water Surface in thermodynamics.

Key Formulas

First Law

ΔU=QW\Delta U = Q - W

Energy is conserved — heat added minus work done.

Ideal Gas Law

PV=nRTPV = nRT

Relates pressure, volume, and temperature of an ideal gas.

Heat Transfer

Q=mcΔTQ = mc\Delta T

Sensible heat transfer.

Carnot Efficiency

η=1TC/TH\eta = 1 - T_C/T_H

Maximum efficiency between two temperatures.

Variables

SymbolDescriptionUnit
UUInternal energyJ
QQHeatJ
WWWorkJ
PPPressurePa
VVVolume
TTTemperatureK

Evaporation Coefficient and Heat Supply

The evaporation coefficient Θ\Theta and required heat supply qq are derived from the core equations:

Evaporation Coefficient: Θ=25+19v(kg/m2h)\Theta = 25 + 19v \quad (\text{kg/m}^2\text{h})

Required Heat Supply: q=hwegsq = h_{we} \cdot g_s

Definitions

  • Θ\Theta: Empirical evaporation coefficient (kg/m²h), representing the combined effect of air temperature and velocity.
  • gsg_s: Mass evaporation rate (kg/s).
  • ghg_h: Mass evaporation rate (kg/h).
  • AA: Water surface area (m²).
  • xsx_s: Humidity ratio of saturated air at water temperature (kg H₂O/kg dry air).
  • xx: Humidity ratio of ambient air (kg H₂O/kg dry air).
  • qq: Heat transfer rate required to maintain temperature (kW).
  • hweh_{we}: Specific evaporation enthalpy (latent heat) of water (kJ/kg).

Swimming Pool Example

A 50 m × 20 m pool with water at 20°C. Air velocity is 0.5 m/s.

ParameterValueCalculation
Area, AA1000 m²50×2050 \times 20
xsx_s (at 20°C)0.014659 kg/kg(Given)
xx (25°C, 50% RH)0.0098 kg/kg(From psychrometric chart)
Evaporation coefficient, Θ\Theta34.5 kg/m²h25+19×0.525 + 19 \times 0.5
Evaporation rate, gsg_s0.047 kg/s34.5×1000×(0.0146590.0098)3600\frac{34.5 \times 1000 \times (0.014659 - 0.0098)}{3600}
Heat loss, qq115.3 kW2454×0.0472454 \times 0.047

Methods to Reduce Evaporation Loss

  • Reduce air velocity above the surface – Limited effect.
  • Reduce water temperature – Not comfortable for swimmers.
  • Reduce air temperature – Not a comfort solution.
  • Increase indoor air humidity – Risk of condensation and structural damage.
  • Use pool covers/blankets – Very effective and commonly used during off-operation hours.

Note: Bather activity significantly increases evaporation. Heat pumps are commonly used to recover latent heat from the air and reduce energy consumption.

References