Nusselt number for short tube thermal development Calculator

✖The Reynolds Number is a dimensionless quantity that helps predict flow patterns in different fluid flow situations, particularly distinguishing between laminar and turbulent flow in tubes.ⓘ Reynolds Number [Re]			+10% -10%
✖The Prandtl Number is a dimensionless quantity that relates the rate of momentum diffusion to thermal diffusion in fluid flow, indicating the relative importance of convection and conduction.ⓘ Prandtl Number [Pr]			+10% -10%
✖The Length is the measurement of the distance along the flow direction in a laminar flow scenario within tubes, influencing flow characteristics and heat transfer efficiency.ⓘ Length [L]			+10% -10%
✖The Diameter of Hydrodynamic Entry Tube is the width of the tube where fluid enters, influencing flow characteristics and pressure drop in laminar flow conditions.ⓘ Diameter of Hydrodynamic Entry Tube [D_hd]			+10% -10%

✖The Nusselt Number is a dimensionless quantity that represents the ratio of convective to conductive heat transfer in fluid flow, indicating the efficiency of heat transfer.ⓘ Nusselt number for short tube thermal development [Nu]

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Nusselt number for short tube thermal development Solution

STEP 0: Pre-Calculation Summary

Formula Used

Nusselt Number = 1.30*((Reynolds Number*Prandtl Number)/(Length/Diameter of Hydrodynamic Entry Tube))^0.333
Nu = 1.30*((Re*Pr)/(L/D_hd))^0.333
This formula uses 5 Variables

Variables Used

Nusselt Number - The Nusselt Number is a dimensionless quantity that represents the ratio of convective to conductive heat transfer in fluid flow, indicating the efficiency of heat transfer.
Reynolds Number - The Reynolds Number is a dimensionless quantity that helps predict flow patterns in different fluid flow situations, particularly distinguishing between laminar and turbulent flow in tubes.
Prandtl Number - The Prandtl Number is a dimensionless quantity that relates the rate of momentum diffusion to thermal diffusion in fluid flow, indicating the relative importance of convection and conduction.
Length - (Measured in Meter) - The Length is the measurement of the distance along the flow direction in a laminar flow scenario within tubes, influencing flow characteristics and heat transfer efficiency.
Diameter of Hydrodynamic Entry Tube - (Measured in Meter) - The Diameter of Hydrodynamic Entry Tube is the width of the tube where fluid enters, influencing flow characteristics and pressure drop in laminar flow conditions.

STEP 1: Convert Input(s) to Base Unit

Reynolds Number: 4000 --> No Conversion Required
Prandtl Number: 0.7 --> No Conversion Required
Length: 3 Meter --> 3 Meter No Conversion Required
Diameter of Hydrodynamic Entry Tube: 0.046875 Meter --> 0.046875 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Nu = 1.30*((Re*Pr)/(L/D_hd))^0.333 --> 1.30*((4000*0.7)/(3/0.046875))^0.333

Evaluating ... ...

Nu = 4.57497837312765

STEP 3: Convert Result to Output's Unit

4.57497837312765 --> No Conversion Required

FINAL ANSWER

4.57497837312765 ≈ 4.574978 <-- Nusselt Number

(Calculation completed in 00.004 seconds)

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< Laminar Flow Calculators

Diameter of hydrodynamic entry tube

LaTeX Go Diameter of Hydrodynamic Entry Tube = Length/(0.04*Reynolds Number Dia)

Hydrodynamic entry length

LaTeX Go Length = 0.04*Diameter of Hydrodynamic Entry Tube*Reynolds Number Dia

Reynolds Number given Darcy Friction Factor

LaTeX Go Reynolds Number Dia = 64/Darcy Friction Factor

Darcy friction factor

LaTeX Go Darcy Friction Factor = 64/Reynolds Number Dia

Nusselt number for short tube thermal development Formula

LaTeX Go

Nusselt Number = 1.30*((Reynolds Number*Prandtl Number)/(Length/Diameter of Hydrodynamic Entry Tube))^0.333
Nu = 1.30*((Re*Pr)/(L/D_hd))^0.333

What is internal flow

internal flow is a flow for which the fluid is confined by a surface. Hence the boundary layer is unable to develop without eventually being constrained. The internal flow configuration represents a convenient geometry for heating and cooling fluids used in chemical processing, environmental control, and energy conversion technologies.

An example includes flow in a pipe.

How to Calculate Nusselt number for short tube thermal development?

Nusselt number for short tube thermal development calculator uses Nusselt Number = 1.30*((Reynolds Number*Prandtl Number)/(Length/Diameter of Hydrodynamic Entry Tube))^0.333 to calculate the Nusselt Number, Nusselt number for short tube thermal development formula is defined as a dimensionless quantity that characterizes the convective heat transfer relative to conductive heat transfer in laminar flow within short tubes, indicating the efficiency of thermal development. Nusselt Number is denoted by Nu symbol.

How to calculate Nusselt number for short tube thermal development using this online calculator? To use this online calculator for Nusselt number for short tube thermal development, enter Reynolds Number (Re), Prandtl Number (Pr), Length (L) & Diameter of Hydrodynamic Entry Tube (D_hd) and hit the calculate button. Here is how the Nusselt number for short tube thermal development calculation can be explained with given input values -> 4.574978 = 1.30*((4000*0.7)/(3/0.046875))^0.333.

FAQ

What is Nusselt number for short tube thermal development?

Nusselt number for short tube thermal development formula is defined as a dimensionless quantity that characterizes the convective heat transfer relative to conductive heat transfer in laminar flow within short tubes, indicating the efficiency of thermal development and is represented as Nu = 1.30*((Re*Pr)/(L/D_hd))^0.333 or Nusselt Number = 1.30*((Reynolds Number*Prandtl Number)/(Length/Diameter of Hydrodynamic Entry Tube))^0.333. The Reynolds Number is a dimensionless quantity that helps predict flow patterns in different fluid flow situations, particularly distinguishing between laminar and turbulent flow in tubes, The Prandtl Number is a dimensionless quantity that relates the rate of momentum diffusion to thermal diffusion in fluid flow, indicating the relative importance of convection and conduction, The Length is the measurement of the distance along the flow direction in a laminar flow scenario within tubes, influencing flow characteristics and heat transfer efficiency & The Diameter of Hydrodynamic Entry Tube is the width of the tube where fluid enters, influencing flow characteristics and pressure drop in laminar flow conditions.

How to calculate Nusselt number for short tube thermal development?

Nusselt number for short tube thermal development formula is defined as a dimensionless quantity that characterizes the convective heat transfer relative to conductive heat transfer in laminar flow within short tubes, indicating the efficiency of thermal development is calculated using Nusselt Number = 1.30*((Reynolds Number*Prandtl Number)/(Length/Diameter of Hydrodynamic Entry Tube))^0.333. To calculate Nusselt number for short tube thermal development, you need Reynolds Number (Re), Prandtl Number (Pr), Length (L) & Diameter of Hydrodynamic Entry Tube (D_hd). With our tool, you need to enter the respective value for Reynolds Number, Prandtl Number, Length & Diameter of Hydrodynamic Entry Tube and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

How many ways are there to calculate Nusselt Number?

In this formula, Nusselt Number uses Reynolds Number, Prandtl Number, Length & Diameter of Hydrodynamic Entry Tube. We can use 3 other way(s) to calculate the same, which is/are as follows -

Nusselt Number = 3.66+((0.0668*(Diameter of Hydrodynamic Entry Tube/Length)*Reynolds Number Dia*Prandtl Number)/(1+0.04*((Diameter of Hydrodynamic Entry Tube/Length)*Reynolds Number Dia*Prandtl Number)^0.67))
Nusselt Number = 1.67*(Reynolds Number Dia*Prandtl Number*Diameter of Hydrodynamic Entry Tube/Length)^0.333
Nusselt Number = 3.66+((0.104*(Reynolds Number Dia*Prandtl Number*(Diameter of Thermal Entry Tube/Length)))/(1+0.16*(Reynolds Number Dia*Prandtl Number*(Diameter of Thermal Entry Tube/Length))^0.8))

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