Thermal Transmittance
Reference data and engineering information about thermal transmittance for heat transfer applications.
Overview
Engineering reference data for Thermal Transmittance in heat transfer.
Key Formulas
Fourier's Law
Heat flux proportional to temperature gradient.
Convective Heat Transfer
Heat transfer between surface and fluid.
Stefan-Boltzmann Law
Radiative heat flux from a surface.
Thermal Resistance
Resistance to heat conduction.
Variables
| Symbol | Description | Unit |
|---|---|---|
| Heat flux | W/m² | |
| Thermal conductivity | W/(m·K) | |
| Convection coefficient | W/(m²·K) | |
| Temperature | K | |
| Emissivity | — | |
| Stefan-Boltzmann constant | 5.67×10⁻⁸ W/(m²·K⁴) |
Key Equations
The relationship between thermal transmittance (U-value) and thermal resistance (R-value) is fundamental. The overall U-value for a composite layer is determined by the sum of the individual resistances.
The core formulas are:
For a layered construction (e.g., a wall), the total thermal resistance is the sum of the resistances of each layer (), including surface films. The overall thermal transmittance is therefore:
where represents the total thermal resistance of the assembly.
Practical Applications
Heat Exchanger Calculation: The thermal transmittance in a heat exchanger is calculated by considering the resistances of each component in the heat transfer path. The formula is:
This equation is essential for designing and evaluating the efficiency of heat exchangers.