Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes Solution

STEP 0: Pre-Calculation Summary
Formula Used
Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]/((Fluid Viscosity at Average Temperature*Tube Loading)))^(1/3)
haverage = 0.926*kf*((ρf)*(ρf-ρV)*[g]/((μ*Γv)))^(1/3)
This formula uses 1 Constants, 6 Variables
Constants Used
[g] - Gravitational acceleration on Earth Value Taken As 9.80665
Variables Used
Average Condensation Coefficient - (Measured in Watt per Square Meter per Kelvin) - Average Condensation Coefficient is the mean heat transfer coefficient considering both inner and outer heat transfer during condensation.
Thermal Conductivity in Heat Exchanger - (Measured in Watt per Meter per K) - Thermal Conductivity in Heat Exchanger is the proportionality constant for the heat flux during conduction heat transfer in a heat exchanger.
Fluid Density in Heat Transfer - (Measured in Kilogram per Cubic Meter) - Fluid Density in Heat Transfer is defined as the ratio of mass of given fluid with respect to the volume that it occupies.
Density of Vapor - (Measured in Kilogram per Cubic Meter) - Density of Vapor is defined as the ratio of mass to the volume of vapor at particular temperature.
Fluid Viscosity at Average Temperature - (Measured in Pascal Second) - Fluid viscosity at Average Temperature in Heat Exchanger is a fundamental property of fluids that characterizes their resistance to flow in a heat exchanger.
Tube Loading - Tube Loading refers to the thin film of the condensate which is formed during the condensation of vapors in a condenser type heat exchanger.
STEP 1: Convert Input(s) to Base Unit
Thermal Conductivity in Heat Exchanger: 3.4 Watt per Meter per K --> 3.4 Watt per Meter per K No Conversion Required
Fluid Density in Heat Transfer: 995 Kilogram per Cubic Meter --> 995 Kilogram per Cubic Meter No Conversion Required
Density of Vapor: 1.712 Kilogram per Cubic Meter --> 1.712 Kilogram per Cubic Meter No Conversion Required
Fluid Viscosity at Average Temperature: 1.005 Pascal Second --> 1.005 Pascal Second No Conversion Required
Tube Loading: 0.957236251929515 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
haverage = 0.926*kf*((ρf)*(ρfV)*[g]/((μ*Γv)))^(1/3) --> 0.926*3.4*((995)*(995-1.712)*[g]/((1.005*0.957236251929515)))^(1/3)
Evaluating ... ...
haverage = 679.987849178839
STEP 3: Convert Result to Output's Unit
679.987849178839 Watt per Square Meter per Kelvin --> No Conversion Required
FINAL ANSWER
679.987849178839 679.9878 Watt per Square Meter per Kelvin <-- Average Condensation Coefficient
(Calculation completed in 00.008 seconds)

Credits

Creator Image
Created by Rishi Vadodaria
Malviya National Institute Of Technology (MNIT JAIPUR ), JAIPUR
Rishi Vadodaria has created this Calculator and 200+ more calculators!
Verifier Image
Verified by Vaibhav Mishra
DJ Sanghvi College of Engineering (DJSCE), Mumbai
Vaibhav Mishra has verified this Calculator and 200+ more calculators!

Heat Transfer Coefficient in Heat Exchangers Calculators

Heat Transfer Coefficient for Condensation Outside Horizontal Tubes
​ LaTeX ​ Go Average Condensation Coefficient = 0.95*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer*(Fluid Density in Heat Transfer-Density of Vapor)*([g]/Fluid Viscosity at Average Temperature)*(Number of Tubes in Heat Exchanger*Length of Tube in Heat Exchanger/Mass Flowrate in Heat Exchanger))^(1/3))*(Number of Tubes in Vertical Row of Exchanger^(-1/6))
Heat Transfer Coefficient for Condensation Inside Vertical Tubes
​ LaTeX ​ Go Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer/Fluid Viscosity at Average Temperature)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]*(pi*Pipe Inner Diameter in Exchanger*Number of Tubes in Heat Exchanger/Mass Flowrate in Heat Exchanger))^(1/3)
Heat Transfer Coefficient for Condensation Outside Vertical Tubes
​ LaTeX ​ Go Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer/Fluid Viscosity at Average Temperature)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]*(pi*Pipe Outer Dia*Number of Tubes in Heat Exchanger/Mass Flowrate in Heat Exchanger))^(1/3)
Heat Transfer Coefficient for Plate Heat Exchanger
​ LaTeX ​ Go Plate Film Coefficient = 0.26*(Thermal Conductivity in Heat Exchanger/Equivalent Diameter in Heat Exchanger)*(Reynold Number for Fluid^0.65)*(Prandlt Number for Fluid^0.4)*(Fluid Viscosity at Average Temperature/Fluid Viscosity at Tube Wall Temperature)^0.14

Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes Formula

​LaTeX ​Go
Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]/((Fluid Viscosity at Average Temperature*Tube Loading)))^(1/3)
haverage = 0.926*kf*((ρf)*(ρf-ρV)*[g]/((μ*Γv)))^(1/3)

What is Heat Transfer Coefficient for Condensation Inside Tubes?

Heat Transfer Coefficient for Condensation Inside Tubes is the heat transfer coefficient when the vapors gets condensed into liquid phase in to the surface of tubes in a shell and tube heat exchanger. The Condenser orientation in such process is vertical positioning and the vapors are allowed to condense over the internal surface of the tubes present. The Vapors that condenses in such orientation, makes their contact with the internal perimeter of the tubes thus the inner periphery is taken into considerations.

What is Condenser?

Condenser is a special type of Heat Exchanger in which hot vapors transfer their latent heat to the colder fluid and thus results into condensation of vapors into liquid phase.

How to Calculate Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes?

Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes calculator uses Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]/((Fluid Viscosity at Average Temperature*Tube Loading)))^(1/3) to calculate the Average Condensation Coefficient, The Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes formula is defined as the film coefficient for heat transfer when the vapors are condensed Inside a vertical tube into its liquid phase. Average Condensation Coefficient is denoted by haverage symbol.

How to calculate Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes using this online calculator? To use this online calculator for Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes, enter Thermal Conductivity in Heat Exchanger (kf), Fluid Density in Heat Transfer f), Density of Vapor V), Fluid Viscosity at Average Temperature (μ) & Tube Loading v) and hit the calculate button. Here is how the Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes calculation can be explained with given input values -> 773.0334 = 0.926*3.4*((995)*(995-1.712)*[g]/((1.005*0.957236251929515)))^(1/3).

FAQ

What is Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes?
The Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes formula is defined as the film coefficient for heat transfer when the vapors are condensed Inside a vertical tube into its liquid phase and is represented as haverage = 0.926*kf*((ρf)*(ρfV)*[g]/((μ*Γv)))^(1/3) or Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]/((Fluid Viscosity at Average Temperature*Tube Loading)))^(1/3). Thermal Conductivity in Heat Exchanger is the proportionality constant for the heat flux during conduction heat transfer in a heat exchanger, Fluid Density in Heat Transfer is defined as the ratio of mass of given fluid with respect to the volume that it occupies, Density of Vapor is defined as the ratio of mass to the volume of vapor at particular temperature, Fluid viscosity at Average Temperature in Heat Exchanger is a fundamental property of fluids that characterizes their resistance to flow in a heat exchanger & Tube Loading refers to the thin film of the condensate which is formed during the condensation of vapors in a condenser type heat exchanger.
How to calculate Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes?
The Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes formula is defined as the film coefficient for heat transfer when the vapors are condensed Inside a vertical tube into its liquid phase is calculated using Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]/((Fluid Viscosity at Average Temperature*Tube Loading)))^(1/3). To calculate Heat Transfer Coefficient with Tube Loading for Condensation Inside Vertical Tubes, you need Thermal Conductivity in Heat Exchanger (kf), Fluid Density in Heat Transfer f), Density of Vapor V), Fluid Viscosity at Average Temperature (μ) & Tube Loading v). With our tool, you need to enter the respective value for Thermal Conductivity in Heat Exchanger, Fluid Density in Heat Transfer, Density of Vapor, Fluid Viscosity at Average Temperature & Tube Loading 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 Average Condensation Coefficient?
In this formula, Average Condensation Coefficient uses Thermal Conductivity in Heat Exchanger, Fluid Density in Heat Transfer, Density of Vapor, Fluid Viscosity at Average Temperature & Tube Loading. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer/Fluid Viscosity at Average Temperature)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]*(pi*Pipe Inner Diameter in Exchanger*Number of Tubes in Heat Exchanger/Mass Flowrate in Heat Exchanger))^(1/3)
  • Average Condensation Coefficient = 0.95*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer*(Fluid Density in Heat Transfer-Density of Vapor)*([g]/Fluid Viscosity at Average Temperature)*(Number of Tubes in Heat Exchanger*Length of Tube in Heat Exchanger/Mass Flowrate in Heat Exchanger))^(1/3))*(Number of Tubes in Vertical Row of Exchanger^(-1/6))
  • Average Condensation Coefficient = 0.926*Thermal Conductivity in Heat Exchanger*((Fluid Density in Heat Transfer/Fluid Viscosity at Average Temperature)*(Fluid Density in Heat Transfer-Density of Vapor)*[g]*(pi*Pipe Outer Dia*Number of Tubes in Heat Exchanger/Mass Flowrate in Heat Exchanger))^(1/3)
Let Others Know
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!