Heat Transfer Calculator

Heat Transfer Calculator — Conduction, Convection & Radiation

Calculate heat transfer rates for conduction, convection, and radiation. Solve heat transfer problems with step-by-step solutions and unit conversions.

Step 1: Select Heat Transfer Mode

Heat Transfer Mode

Thermal Conductivity (k)

Cross-sectional Area (A)

Thickness (L)

Temperature Difference (ΔT)

Convection Coefficient (h)

Surface Area (A)

Temperature Difference (ΔT)

Emissivity (ε)

0.9

Surface Area (A)

Surface Temperature (T₁)

Surrounding Temperature (T₂)

Overall Heat Transfer Coefficient (U)

Surface Area (A)

Temperature Difference (ΔT)

Understanding Heat Transfer

Heat transfer is the movement of thermal energy from higher temperature to lower temperature regions. The three main modes are conduction (through solids), convection (through fluids), and radiation (through electromagnetic waves).

Step 2: Calculation Options

Decimal Precision

Rounding Method

Show unit comparison table

Show heat transfer rate chart

Show calculation formula

Heat Transfer Formulas

Conduction: Q = k·A·ΔT / L
Convection: Q = h·A·ΔT
Radiation: Q = ε·σ·A·(T₁⁴ – T₂⁴)
Overall: Q = U·A·ΔT

Heat Transfer Calculation Results

Heat Transfer Summary

Unit Comparison

Heat Transfer Formulas

Heat Transfer Rate

2005 W

Conduction through 0.1 m thickness

Kilowatts

2.01 kW

BTU per hour

6841 BTU/hr

Calories per second

479 cal/s

Horsepower

2.69 hp

Heat Transfer Unit Comparison

Unit	Abbreviation	Watts Equivalent	Common Use

Heat Transfer Calculation Formulas

Conduction

Formula: Q = k × A × ΔT / L
Where: Q = heat transfer rate (W), k = thermal conductivity (W/m·K), A = cross-sectional area (m²), ΔT = temperature difference (K or °C), L = thickness (m)
Example: k = 401 W/m·K, A = 0.01 m², ΔT = 50°C, L = 0.1 m → Q = 401 × 0.01 × 50 / 0.1 = 2005 W

Convection

Formula: Q = h × A × ΔT
Where: Q = heat transfer rate (W), h = convection coefficient (W/m²·K), A = surface area (m²), ΔT = temperature difference (K or °C)
Example: h = 25 W/m²·K, A = 1 m², ΔT = 30°C → Q = 25 × 1 × 30 = 750 W

Radiation

Formula: Q = ε × σ × A × (T₁⁴ – T₂⁴)
Where: Q = heat transfer rate (W), ε = emissivity (0-1), σ = Stefan-Boltzmann constant (5.67×10⁻⁸ W/m²·K⁴), A = surface area (m²), T₁ and T₂ = absolute temperatures (K)
Example: ε = 0.9, A = 1 m², T₁ = 500 K, T₂ = 300 K → Q = 0.9 × 5.67e-8 × 1 × (500⁴ – 300⁴) = 2.83 kW

Overall Heat Transfer

Formula: Q = U × A × ΔT
Where: Q = heat transfer rate (W), U = overall heat transfer coefficient (W/m²·K), A = surface area (m²), ΔT = temperature difference (K or °C)
Example: U = 10 W/m²·K, A = 2 m², ΔT = 60°C → Q = 10 × 2 × 60 = 1200 W

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