Compute Nusselt number, film coefficient, and heat rate. Test multiple correlations with practical flow inputs. Save clean reports, tables, and notes for design reviews.
| Case | Re | Pr | k (W/m·K) | Dh (m) | Method | Estimated Use |
|---|---|---|---|---|---|---|
| Water in tube | 1800 | 5.80 | 0.60 | 0.020 | Laminar | Low velocity internal flow |
| Oil cooler line | 12000 | 120.00 | 0.13 | 0.015 | Sieder-Tate | Viscosity correction case |
| Air duct insert | 55000 | 0.71 | 0.028 | 0.050 | Gnielinski | General turbulent design check |
| Hot water loop | 30000 | 4.20 | 0.63 | 0.025 | Dittus-Boelter | Quick engineering estimate |
This calculator converts Reynolds number into a heat transfer estimate by first finding the Nusselt number. The selected correlation determines the Nusselt value for the internal flow condition.
For fully developed laminar flow with constant wall temperature:
Nu = 3.66
Used for turbulent flow in many quick design checks:
Nu = 0.023 × Re0.8 × Prn
Use n = 0.4 for heating and n = 0.3 for cooling.
This method often gives a more refined turbulent estimate:
f = (0.79 ln Re - 1.64)-2
Nu = [(f/8)(Re - 1000)Pr] / [1 + 12.7(f/8)1/2(Pr2/3 - 1)]
This method adjusts for viscosity variation near the wall:
Nu = 0.027 × Re0.8 × Pr1/3 × (μ/μw)0.14
Once Nusselt number is known, the film coefficient is:
h = (Nu × k) / Dh
q" = h × ΔT
Q = h × A × ΔT
Reynolds number helps engineers understand flow behavior. It separates laminar, transitional, and turbulent motion. Heat transfer changes strongly with that behavior. A small change in Reynolds number can shift the expected film coefficient. That shift affects exchanger sizing, tube selection, and energy use.
This calculator links Reynolds number with standard convection correlations. It estimates Nusselt number first. Then it converts that value into the convective heat transfer coefficient. If you enter area and temperature difference, it also estimates heat flux and total heat transfer rate.
Laminar flow often uses a constant Nusselt value in fully developed conditions. Turbulent flow usually needs empirical equations. Dittus-Boelter is fast and popular. Gnielinski is often more accurate for many internal flow cases. Sieder-Tate becomes useful when viscosity changes between the bulk fluid and the wall matter.
Use consistent units. Reynolds and Prandtl numbers are dimensionless. Thermal conductivity should be in watts per meter-kelvin. Hydraulic diameter should be in meters. Area should be in square meters. Temperature difference should be in kelvin or degrees Celsius difference. Viscosity inputs should be in the same unit basis.
This tool supports early design work, thermal checks, and classroom validation. It is also useful for comparing several correlations before detailed simulation. Engineers can export the result table, attach it to reports, and document calculation assumptions quickly. Always confirm correlation validity before final equipment sizing.
It indicates the flow regime. That regime guides which heat transfer correlation is reasonable. Laminar and turbulent flows do not transfer heat at the same rate, so the selected equation changes.
Prandtl number connects momentum diffusion and thermal diffusion. Most convection correlations use it because fluids with different thermal behavior can produce different Nusselt numbers even at the same Reynolds number.
Nusselt number is a dimensionless measure of convection strength. A larger value usually means stronger convective heat transfer and a higher film coefficient when thermal conductivity and diameter stay fixed.
Use Gnielinski when you want a more refined turbulent estimate for internal flow. It often performs better over a wider range than a simple quick estimate, but validity limits still matter.
They are only needed for Sieder-Tate. That correlation includes a viscosity ratio correction. If you use another method, the bulk and wall viscosity values are not required for calculation.
Yes. Enter area and temperature difference. The calculator then estimates total heat transfer rate using Q = h × A × ΔT, based on the computed convection coefficient.
It is best for estimation, screening, and validation. Final design should also consider geometry details, entrance effects, roughness, property variation, fouling, and verified design standards.
The note appears when the chosen method may not perfectly match the entered Reynolds or Prandtl range. It helps you review assumptions before relying on the result.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.