Effective thermal conductivity for annular space between concentric cylinders Calculator

✖Heat Transfer per Unit Length is defined as the movement of heat across the border of the system due to a difference in temperature between the system and its surroundings.ⓘ Heat Transfer per Unit Length [e']			+10% -10%
✖Outside Diameter is the diameter of the outside surface.ⓘ Outside Diameter [D_o]			+10% -10%
✖Inside diameter is the diameter of the inside surface.ⓘ Inside Diameter [D_i]			+10% -10%
✖Inside Temperature is the temperature of air present inside.ⓘ Inside Temperature [t_i]			+10% -10%
✖Outside Temperature is the temperature of air present outside.ⓘ Outside Temperature [t_o]			+10% -10%

✖Effective Thermal Conductivity is the rate of heat transfer through a unit thickness of the material per unit area per unit temperature difference.ⓘ Effective thermal conductivity for annular space between concentric cylinders [k_Eff]

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Effective thermal conductivity for annular space between concentric cylinders Solution

STEP 0: Pre-Calculation Summary

Formula Used

Effective Thermal Conductivity = Heat Transfer per Unit Length*((ln(Outside Diameter/Inside Diameter))/(2*pi)*(Inside Temperature-Outside Temperature))
k_Eff = e'*((ln(D_o/D_i))/(2*pi)*(t_i-t_o))
This formula uses 1 Constants, 1 Functions, 6 Variables

Constants Used

pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288

Functions Used

ln - The natural logarithm, also known as the logarithm to the base e, is the inverse function of the natural exponential function., ln(Number)

Variables Used

Effective Thermal Conductivity - (Measured in Watt per Meter per K) - Effective Thermal Conductivity is the rate of heat transfer through a unit thickness of the material per unit area per unit temperature difference.
Heat Transfer per Unit Length - Heat Transfer per Unit Length is defined as the movement of heat across the border of the system due to a difference in temperature between the system and its surroundings.
Outside Diameter - (Measured in Meter) - Outside Diameter is the diameter of the outside surface.
Inside Diameter - (Measured in Meter) - Inside diameter is the diameter of the inside surface.
Inside Temperature - (Measured in Kelvin) - Inside Temperature is the temperature of air present inside.
Outside Temperature - (Measured in Kelvin) - Outside Temperature is the temperature of air present outside.

STEP 1: Convert Input(s) to Base Unit

Heat Transfer per Unit Length: 0.0095 --> No Conversion Required
Outside Diameter: 0.05 Meter --> 0.05 Meter No Conversion Required
Inside Diameter: 0.005 Meter --> 0.005 Meter No Conversion Required
Inside Temperature: 353 Kelvin --> 353 Kelvin No Conversion Required
Outside Temperature: 273 Kelvin --> 273 Kelvin No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

k_Eff = e'*((ln(D_o/D_i))/(2*pi)*(t_i-t_o)) --> 0.0095*((ln(0.05/0.005))/(2*pi)*(353-273))

Evaluating ... ...

k_Eff = 0.278515527574183

STEP 3: Convert Result to Output's Unit

0.278515527574183 Watt per Meter per K --> No Conversion Required

FINAL ANSWER

0.278515527574183 ≈ 0.278516 Watt per Meter per K <-- Effective Thermal Conductivity

(Calculation completed in 00.004 seconds)

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Home » Physics » Heat and Mass Transfer » Convection » Free convection » Mechanical » Effective Thermal Conductivity and Heat Transfer » Effective thermal conductivity for annular space between concentric cylinders

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< Effective Thermal Conductivity and Heat Transfer Calculators

Heat transfer between concentric spheres given both diameters

LaTeX Go Heat transfer Between Concentric Spheres = (Effective Thermal Conductivity*pi*(Inside Temperature-Outside Temperature))*((Outside Diameter*Inside Diameter)/Length)

Effective thermal conductivity for annular space between concentric cylinders

LaTeX Go Effective Thermal Conductivity = Heat Transfer per Unit Length*((ln(Outside Diameter/Inside Diameter))/(2*pi)*(Inside Temperature-Outside Temperature))

Heat transfer per unit length for annular space between concentric cylinders

LaTeX Go Heat Transfer per Unit Length = ((2*pi*Effective Thermal Conductivity)/(ln(Outside Diameter/Inside Diameter)))*(Inside Temperature-Outside Temperature)

Effective thermal conductivity given Prandtl number

LaTeX Go Effective Thermal Conductivity = 0.386*Thermal Conductivity of Liquid*(((Prandtl Number)/(0.861+Prandtl Number))^0.25)*(Rayleigh Number Based on Turbulance)^0.25

Effective thermal conductivity for annular space between concentric cylinders Formula

LaTeX Go

Effective Thermal Conductivity = Heat Transfer per Unit Length*((ln(Outside Diameter/Inside Diameter))/(2*pi)*(Inside Temperature-Outside Temperature))
k_Eff = e'*((ln(D_o/D_i))/(2*pi)*(t_i-t_o))

What is convection?

Convection is the process of heat transfer by the bulk movement of molecules within fluids such as gases and liquids. The initial heat transfer between the object and the fluid takes place through conduction, but the bulk heat transfer happens due to the motion of the fluid.

Convection is the process of heat transfer in fluids by the actual motion of matter.
It happens in liquids and gases.
It may be natural or forced.
It involves a bulk transfer of portions of the fluid.

How to Calculate Effective thermal conductivity for annular space between concentric cylinders?

Effective thermal conductivity for annular space between concentric cylinders calculator uses Effective Thermal Conductivity = Heat Transfer per Unit Length*((ln(Outside Diameter/Inside Diameter))/(2*pi)*(Inside Temperature-Outside Temperature)) to calculate the Effective Thermal Conductivity, The Effective thermal conductivity for annular space between concentric cylinders formula is defined as the transport of energy due to random molecular motion across a temperature gradient. Effective Thermal Conductivity is denoted by k_Eff symbol.

How to calculate Effective thermal conductivity for annular space between concentric cylinders using this online calculator? To use this online calculator for Effective thermal conductivity for annular space between concentric cylinders, enter Heat Transfer per Unit Length (e'), Outside Diameter (D_o), Inside Diameter (D_i), Inside Temperature (t_i) & Outside Temperature (t_o) and hit the calculate button. Here is how the Effective thermal conductivity for annular space between concentric cylinders calculation can be explained with given input values -> 1465.871 = 0.0095*((ln(0.05/0.005))/(2*pi)*(353-273)).

FAQ

What is Effective thermal conductivity for annular space between concentric cylinders?

The Effective thermal conductivity for annular space between concentric cylinders formula is defined as the transport of energy due to random molecular motion across a temperature gradient and is represented as k_Eff = e'*((ln(D_o/D_i))/(2*pi)*(t_i-t_o)) or Effective Thermal Conductivity = Heat Transfer per Unit Length*((ln(Outside Diameter/Inside Diameter))/(2*pi)*(Inside Temperature-Outside Temperature)). Heat Transfer per Unit Length is defined as the movement of heat across the border of the system due to a difference in temperature between the system and its surroundings, Outside Diameter is the diameter of the outside surface, Inside diameter is the diameter of the inside surface, Inside Temperature is the temperature of air present inside & Outside Temperature is the temperature of air present outside.

How to calculate Effective thermal conductivity for annular space between concentric cylinders?

The Effective thermal conductivity for annular space between concentric cylinders formula is defined as the transport of energy due to random molecular motion across a temperature gradient is calculated using Effective Thermal Conductivity = Heat Transfer per Unit Length*((ln(Outside Diameter/Inside Diameter))/(2*pi)*(Inside Temperature-Outside Temperature)). To calculate Effective thermal conductivity for annular space between concentric cylinders, you need Heat Transfer per Unit Length (e'), Outside Diameter (D_o), Inside Diameter (D_i), Inside Temperature (t_i) & Outside Temperature (t_o). With our tool, you need to enter the respective value for Heat Transfer per Unit Length, Outside Diameter, Inside Diameter, Inside Temperature & Outside Temperature 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 Effective Thermal Conductivity?

In this formula, Effective Thermal Conductivity uses Heat Transfer per Unit Length, Outside Diameter, Inside Diameter, Inside Temperature & Outside Temperature. We can use 3 other way(s) to calculate the same, which is/are as follows -

Effective Thermal Conductivity = 0.386*Thermal Conductivity of Liquid*(((Prandtl Number)/(0.861+Prandtl Number))^0.25)*(Rayleigh Number Based on Turbulance)^0.25
Effective Thermal Conductivity = Heat transfer Between Concentric Spheres/((pi*(Inside Temperature-Outside Temperature))*((Outside Diameter*Inside Diameter)/Length))
Effective Thermal Conductivity = (Heat transfer Between Concentric Spheres*(Outer Radius-Inside Radius))/(4*pi*Inside Radius*Outer Radius*Temperature Difference)

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