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Thermal Transmittance

Reference data and engineering information about thermal transmittance for heat transfer applications.

thermaltransmittance

Overview

Engineering reference data for Thermal Transmittance in heat transfer.

Key Formulas

Fourier's Law

q=kTq = -k \nabla T

Heat flux proportional to temperature gradient.

Convective Heat Transfer

Q=hA(TsT)Q = hA(T_s - T_\infty)

Heat transfer between surface and fluid.

Stefan-Boltzmann Law

q=εσT4q = \varepsilon \sigma T^4

Radiative heat flux from a surface.

Thermal Resistance

Rth=LkAR_{th} = \frac{L}{kA}

Resistance to heat conduction.

Variables

SymbolDescriptionUnit
qqHeat fluxW/m²
kkThermal conductivityW/(m·K)
hhConvection coefficientW/(m²·K)
TTTemperatureK
ε\varepsilonEmissivity
σ\sigmaStefan-Boltzmann constant5.67×10⁻⁸ 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:

U=1RU = \frac{1}{R} R=1UR = \frac{1}{U}

For a layered construction (e.g., a wall), the total thermal resistance is the sum of the resistances of each layer (RiR_i), including surface films. The overall thermal transmittance is therefore:

U=1RiU = \frac{1}{\sum R_i}

where Ri\sum R_i 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:

U=1Rair film+Rcondensate film+Rmetal wall+Rproduct filmU = \frac{1}{R_{\text{air film}} + R_{\text{condensate film}} + R_{\text{metal wall}} + R_{\text{product film}}}

This equation is essential for designing and evaluating the efficiency of heat exchangers.

References