Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer Calculator

⤿

Convective Mass Transfer

Basics of HMT

Conduction

⤿

Convective Mass Transfer Coefficient

Free Stream Velocity

✖Convective Mass Transfer Coefficient is a function of geometry of the system and the velocity and properties of the fluid similar to the heat transfer coefficient.ⓘ Convective Mass Transfer Coefficient [k_L]			+10% -10%
✖The density of Liquid is the mass of a unit volume of liquid.ⓘ Density of Liquid [ρ_L]			+10% -10%
✖The Specific Heat is the amount of heat per unit mass required to raise the temperature by one degree Celsius.ⓘ Specific Heat [c]			+10% -10%
✖The Lewis Number is a dimensionless number defined as the ratio of thermal diffusivity to mass diffusivity.ⓘ Lewis Number [L_e]			+10% -10%

✖The Heat Transfer Coefficient is the rate of heat transfer per unit area per kelvin.ⓘ Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer [h_transfer]

⎘ Copy

👎

Formula

✖

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer

Formula

`"h"_{"transfer"} = "k"_{"L"}*"ρ"_{"L"}*"c"*("L"_{"e"}^0.67)`

Example

`"3122.894W/m²*K"="9.5e-3m/s"*"1000kg/m³"*"120J/(kg*K)"*(("4.5")^0.67)`

Calculator

LaTeX

Reset

👍

Download Heat and Mass Transfer Formula PDF PDF Image

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer Solution

STEP 0: Pre-Calculation Summary

Formula Used

Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67)
h_transfer = k_L*ρ_L*c*(L_e^0.67)
This formula uses 5 Variables

Variables Used

Heat Transfer Coefficient - (Measured in Watt per Square Meter per Kelvin) - The Heat Transfer Coefficient is the rate of heat transfer per unit area per kelvin.
Convective Mass Transfer Coefficient - (Measured in Meter per Second) - Convective Mass Transfer Coefficient is a function of geometry of the system and the velocity and properties of the fluid similar to the heat transfer coefficient.
Density of Liquid - (Measured in Kilogram per Cubic Meter) - The density of Liquid is the mass of a unit volume of liquid.
Specific Heat - (Measured in Joule per Kilogram per K) - The Specific Heat is the amount of heat per unit mass required to raise the temperature by one degree Celsius.
Lewis Number - The Lewis Number is a dimensionless number defined as the ratio of thermal diffusivity to mass diffusivity.

STEP 1: Convert Input(s) to Base Unit

Convective Mass Transfer Coefficient: 0.0095 Meter per Second --> 0.0095 Meter per Second No Conversion Required
Density of Liquid: 1000 Kilogram per Cubic Meter --> 1000 Kilogram per Cubic Meter No Conversion Required
Specific Heat: 120 Joule per Kilogram per K --> 120 Joule per Kilogram per K No Conversion Required
Lewis Number: 4.5 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

h_transfer = k_L*ρ_L*c*(L_e^0.67) --> 0.0095*1000*120*(4.5^0.67)

Evaluating ... ...

h_transfer = 3122.89394455084

STEP 3: Convert Result to Output's Unit

3122.89394455084 Watt per Square Meter per Kelvin --> No Conversion Required

FINAL ANSWER

3122.89394455084 ≈ 3122.894 Watt per Square Meter per Kelvin <-- Heat Transfer Coefficient

(Calculation completed in 00.004 seconds)

You are here -

Home » Physics » Heat and Mass Transfer » Convective Mass Transfer » Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer

Credits

Created by Nishan Poojary

Shri Madhwa Vadiraja Institute of Technology and Management (SMVITM), Udupi

Nishan Poojary has created this Calculator and 500+ more calculators!

Verified by Anshika Arya

National Institute Of Technology (NIT), Hamirpur

Anshika Arya has verified this Calculator and 2500+ more calculators!

< 19 Convective Mass Transfer Calculators

Partial pressure of component A in mixture 1

Go Partial Pressure of Component A in Mixture 1 = Partial Pressure of Component B in Mixture 2-Partial Pressure of Component B in Mixture 1+Partial Pressure of Component A in Mixture 2

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer

Go Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67)

Density of material given convective heat and mass transfer coefficient

Go Density = (Heat Transfer Coefficient)/(Convective Mass Transfer Coefficient*Specific Heat*(Lewis Number^0.67))

Specific heat given convective heat and mass transfer

Go Specific Heat = Heat Transfer Coefficient/(Convective Mass Transfer Coefficient*Density*(Lewis Number^0.67))

Drag Coefficient of Flat Plate Laminar Flow using Schmidt Number

Go Drag Coefficient = (2*Convective Mass Transfer Coefficient*(Schmidt Number^0.67))/Free Stream Velocity

Friction factor of flat plate laminar flow

Go Friction Factor = (8*Convective Mass Transfer Coefficient*(Schmidt Number^0.67))/Free Stream Velocity

Friction factor in internal flow

Go Friction Factor = (8*Convective Mass Transfer Coefficient*(Schmidt Number^0.67))/Free Stream Velocity

Mass Transfer Boundary Layer Thickness of Flat Plate in Laminar Flow

Go Mass Transfer Boundary Layer Thickness at x = Hydrodynamic Boundary Layer Thickness*(Schmidt Number^(-0.333))

Mass Transfer Stanton Number

Go Mass Transfer Stanton Number = Convective Mass Transfer Coefficient/Free Stream Velocity

Average Sherwood Number of Combined Laminar and Turbulent Flow

Go Average Sherwood Number = ((0.037*(Reynolds Number^0.8))-871)*(Schmidt Number^0.333)

Local Sherwood Number for Flat Plate in Turbulent Flow

Go Local Sherwood Number = 0.0296*(Local Reynolds Number^0.8)*(Schmidt Number^0.333)

Local Sherwood Number for Flat Plate in Laminar Flow

Go Local Sherwood Number = 0.332*(Local Reynolds Number^0.5)*(Schmidt Number^0.333)

Average Sherwood Number of Internal Turbulent Flow

Go Average Sherwood Number = 0.023*(Reynolds Number^0.83)*(Schmidt Number^0.44)

Sherwood Number for Flat Plate in Laminar Flow

Go Average Sherwood Number = 0.664*(Reynolds Number^0.5)*(Schmidt Number^0.333)

Average Sherwood Number of Flat Plate Turbulent Flow

Go Average Sherwood Number = 0.037*(Reynolds Number^0.8)

Drag coefficient of flat plate in combined laminar turbulent flow

Go Drag Coefficient = 0.0571/(Reynolds Number^0.2)

Drag coefficient of flat plate laminar flow

Go Drag Coefficient = 0.644/(Reynolds Number^0.5)

Friction factor of flat plate laminar flow given Reynolds number

Go Friction Factor = 2.576/(Reynolds Number^0.5)

Drag coefficient of flat plate laminar flow given friction factor

Go Drag Coefficient = Friction Factor/4

< 17 Mass Transfer Coefficient Calculators

Convective Mass Transfer Coefficient through Liquid Gas Interface

Go Convective Mass Transfer Coefficient = (Mass Transfer Coefficient of Medium 1*Mass Transfer Coefficient of Medium 2*Henry's Constant)/((Mass Transfer Coefficient of Medium 1*Henry's Constant)+(Mass Transfer Coefficient of Medium 2))

Convective Mass Transfer Coefficient

Go Convective Mass Transfer Coefficient = Mass Flux of Diffusion Component A/(Mass Concentration of Component A in Mixture 1-Mass Concentration of Component A in Mixture 2)

Convective Mass Transfer Coefficient for Simultaneous Heat and Mass Transfer

Go Convective Mass Transfer Coefficient = Heat Transfer Coefficient/(Specific Heat*Density of Liquid*(Lewis Number^0.67))

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer

Go Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67)

Convective Mass Transfer Coefficient of Flat Plate in Combined Laminar Turbulent Flow

Go Convective Mass Transfer Coefficient = (0.0286*Free Stream Velocity)/((Reynolds Number^0.2)*(Schmidt Number^0.67))

Convective Mass Transfer Coefficient of Flat Plate Laminar Flow using Reynolds Number

Go Convective Mass Transfer Coefficient = (Free Stream Velocity*0.322)/((Reynolds Number^0.5)*(Schmidt Number^0.67))

Convective Mass Transfer Coefficient of Flat Plate Laminar Flow using Drag Coefficient

Go Convective Mass Transfer Coefficient = (Drag Coefficient*Free Stream Velocity)/(2*(Schmidt Number^0.67))

Convective Mass Transfer Coefficient of Flat Plate Laminar Flow using Friction Factor

Go Convective Mass Transfer Coefficient = (Friction Factor*Free Stream Velocity)/(8*(Schmidt Number^0.67))

Drag Coefficient of Flat Plate Laminar Flow using Schmidt Number

Go Drag Coefficient = (2*Convective Mass Transfer Coefficient*(Schmidt Number^0.67))/Free Stream Velocity

Mass Transfer Boundary Layer Thickness of Flat Plate in Laminar Flow

Go Mass Transfer Boundary Layer Thickness at x = Hydrodynamic Boundary Layer Thickness*(Schmidt Number^(-0.333))

Mass Transfer Stanton Number

Go Mass Transfer Stanton Number = Convective Mass Transfer Coefficient/Free Stream Velocity

Average Sherwood Number of Combined Laminar and Turbulent Flow

Go Average Sherwood Number = ((0.037*(Reynolds Number^0.8))-871)*(Schmidt Number^0.333)

Local Sherwood Number for Flat Plate in Turbulent Flow

Go Local Sherwood Number = 0.0296*(Local Reynolds Number^0.8)*(Schmidt Number^0.333)

Local Sherwood Number for Flat Plate in Laminar Flow

Go Local Sherwood Number = 0.332*(Local Reynolds Number^0.5)*(Schmidt Number^0.333)

Average Sherwood Number of Internal Turbulent Flow

Go Average Sherwood Number = 0.023*(Reynolds Number^0.83)*(Schmidt Number^0.44)

Sherwood Number for Flat Plate in Laminar Flow

Go Average Sherwood Number = 0.664*(Reynolds Number^0.5)*(Schmidt Number^0.333)

Average Sherwood Number of Flat Plate Turbulent Flow

Go Average Sherwood Number = 0.037*(Reynolds Number^0.8)

< 25 Important Formulas in Mass Transfer Coefficient, Driving Force and Theories Calculators

Convective Mass Transfer Coefficient through Liquid Gas Interface

Logarithmic Mean Partial Pressure Difference

Go Logarithmic Mean Partial Pressure Difference = (Partial Pressure of Component B in Mixture 2-Partial Pressure of Component B in Mixture 1)/(ln(Partial Pressure of Component B in Mixture 2/Partial Pressure of Component B in Mixture 1))

Logarithmic Mean of Concentration Difference

Go Logarithmic Mean of Concentration Difference = (Concentration of Component B in Mixture 2-Concentration of Component B in Mixture 1)/ln(Concentration of Component B in Mixture 2/Concentration of Component B in Mixture 1)

Convective Mass Transfer Coefficient

Go Convective Mass Transfer Coefficient = Mass Flux of Diffusion Component A/(Mass Concentration of Component A in Mixture 1-Mass Concentration of Component A in Mixture 2)

Liquid Phase Mass Transfer Coefficient by Two Film Theory

Go Overall Liquid Phase Mass Transfer Coefficient = 1/((1/(Gas Phase Mass Transfer Coefficient*Henry's Constant))+(1/Liquid Phase Mass Transfer Coefficient))

Convective Mass Transfer Coefficient for Simultaneous Heat and Mass Transfer

Go Convective Mass Transfer Coefficient = Heat Transfer Coefficient/(Specific Heat*Density of Liquid*(Lewis Number^0.67))

Gas Phase Mass Transfer Coefficient by Two Film Theory

Go Overall Gas Phase Mass Transfer Coefficient = 1/((1/Gas Phase Mass Transfer Coefficient)+(Henry's Constant/Liquid Phase Mass Transfer Coefficient))

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer

Go Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67)

Average Mass Transfer Coefficient by Penetration Theory

Go Average Convective Mass Transfer Coefficient = 2*sqrt(Diffusion Coefficient (DAB)/(pi*Average Contact Time))

Convective Mass Transfer Coefficient of Flat Plate in Combined Laminar Turbulent Flow

Go Convective Mass Transfer Coefficient = (0.0286*Free Stream Velocity)/((Reynolds Number^0.2)*(Schmidt Number^0.67))

Convective Mass Transfer Coefficient of Flat Plate Laminar Flow using Reynolds Number

Go Convective Mass Transfer Coefficient = (Free Stream Velocity*0.322)/((Reynolds Number^0.5)*(Schmidt Number^0.67))

Fractional Resistance Offered by Liquid Phase

Go Fractional Resistance Offered by Liquid Phase = (1/Liquid Phase Mass Transfer Coefficient)/(1/Overall Liquid Phase Mass Transfer Coefficient)

Convective Mass Transfer Coefficient of Flat Plate Laminar Flow using Drag Coefficient

Go Convective Mass Transfer Coefficient = (Drag Coefficient*Free Stream Velocity)/(2*(Schmidt Number^0.67))

Convective Mass Transfer Coefficient of Flat Plate Laminar Flow using Friction Factor

Go Convective Mass Transfer Coefficient = (Friction Factor*Free Stream Velocity)/(8*(Schmidt Number^0.67))

Liquid Phase Mass Transfer Coefficient using Fractional Resistance by Liquid Phase

Go Liquid Phase Mass Transfer Coefficient = Overall Liquid Phase Mass Transfer Coefficient/Fractional Resistance Offered by Liquid Phase

Fractional Resistance Offered by Gas Phase

Go Fractional Resistance Offered by Gas Phase = (1/Gas Phase Mass Transfer Coefficient)/(1/Overall Gas Phase Mass Transfer Coefficient)

Gas Phase Mass Transfer Coefficient using Fractional Resistance by Gas Phase

Go Gas Phase Mass Transfer Coefficient = Overall Gas Phase Mass Transfer Coefficient/Fractional Resistance Offered by Gas Phase

Mass Transfer Boundary Layer Thickness of Flat Plate in Laminar Flow

Go Mass Transfer Boundary Layer Thickness at x = Hydrodynamic Boundary Layer Thickness*(Schmidt Number^(-0.333))

Mass Transfer Stanton Number

Go Mass Transfer Stanton Number = Convective Mass Transfer Coefficient/Free Stream Velocity

Average Sherwood Number of Combined Laminar and Turbulent Flow

Go Average Sherwood Number = ((0.037*(Reynolds Number^0.8))-871)*(Schmidt Number^0.333)

Local Sherwood Number for Flat Plate in Turbulent Flow

Go Local Sherwood Number = 0.0296*(Local Reynolds Number^0.8)*(Schmidt Number^0.333)

Local Sherwood Number for Flat Plate in Laminar Flow

Go Local Sherwood Number = 0.332*(Local Reynolds Number^0.5)*(Schmidt Number^0.333)

Average Sherwood Number of Internal Turbulent Flow

Go Average Sherwood Number = 0.023*(Reynolds Number^0.83)*(Schmidt Number^0.44)

Sherwood Number for Flat Plate in Laminar Flow

Go Average Sherwood Number = 0.664*(Reynolds Number^0.5)*(Schmidt Number^0.333)

Average Sherwood Number of Flat Plate Turbulent Flow

Go Average Sherwood Number = 0.037*(Reynolds Number^0.8)

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer Formula

Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67)
h_transfer = k_L*ρ_L*c*(L_e^0.67)

What is Heat transfer?

Heat transfer describes the flow of heat (thermal energy) due to temperature differences and the subsequent temperature distribution and changes.
The study of transport phenomena concerns the exchange of momentum, energy, and mass in the form of conduction, convection, and radiation.

How to Calculate Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer?

Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer calculator uses Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67) to calculate the Heat Transfer Coefficient, The Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer formula is defined as the flow of heat due to temperature difference and subsequent temperature change. Heat Transfer Coefficient is denoted by h_transfer symbol.

How to calculate Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer using this online calculator? To use this online calculator for Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer, enter Convective Mass Transfer Coefficient (k_L), Density of Liquid (ρ_L), Specific Heat (c) & Lewis Number (L_e) and hit the calculate button. Here is how the Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer calculation can be explained with given input values -> 3122.894 = 0.0095*1000*120*(4.5^0.67).

FAQ

What is Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer?

The Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer formula is defined as the flow of heat due to temperature difference and subsequent temperature change and is represented as h_transfer = k_L*ρ_L*c*(L_e^0.67) or Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67). Convective Mass Transfer Coefficient is a function of geometry of the system and the velocity and properties of the fluid similar to the heat transfer coefficient, The density of Liquid is the mass of a unit volume of liquid, The Specific Heat is the amount of heat per unit mass required to raise the temperature by one degree Celsius & The Lewis Number is a dimensionless number defined as the ratio of thermal diffusivity to mass diffusivity.

How to calculate Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer?

The Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer formula is defined as the flow of heat due to temperature difference and subsequent temperature change is calculated using Heat Transfer Coefficient = Convective Mass Transfer Coefficient*Density of Liquid*Specific Heat*(Lewis Number^0.67). To calculate Heat Transfer Coefficient for Simultaneous Heat and Mass Transfer, you need Convective Mass Transfer Coefficient (k_L), Density of Liquid (ρ_L), Specific Heat (c) & Lewis Number (L_e). With our tool, you need to enter the respective value for Convective Mass Transfer Coefficient, Density of Liquid, Specific Heat & Lewis Number and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

Home

FREE PDFs

🔍 Search