Heat Transfer in Heat Exchanger given Cold Fluid Properties Solution

STEP 0: Pre-Calculation Summary
Formula Used
Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid))
Q = modulus(mc*cc*(Tci- Tco))
This formula uses 1 Functions, 5 Variables
Functions Used
modulus - Modulus of a number is the remainder when that number is divided by another number., modulus
Variables Used
Heat - (Measured in Joule) - Heat is the form of energy that is transferred between systems or objects with different temperatures (flowing from the high-temperature system to the low-temperature system).
Mass of Cold Fluid - (Measured in Kilogram) - Mass of Cold Fluid is the mass of the cooler fluid in the heat exchanger.
Specific Heat Capacity of Cold Fluid - (Measured in Joule per Kilogram per K) - Specific Heat Capacity of Cold Fluid is a physical property of matter, defined as the amount of heat to be supplied to a unit mass of the cooler fluid to produce a unit change in its temperature.
Inlet Temperature of Cold Fluid - (Measured in Kelvin) - Inlet Temperature of Cold Fluid is the temperature at which the cold fluid enters the heat exchanger.
Outlet Temperature of Cold Fluid - (Measured in Kelvin) - Outlet Temperature of Cold Fluid is the temperature at which the cold fluid exits the heat exchanger.
STEP 1: Convert Input(s) to Base Unit
Mass of Cold Fluid: 9 Kilogram --> 9 Kilogram No Conversion Required
Specific Heat Capacity of Cold Fluid: 350 Joule per Kilogram per K --> 350 Joule per Kilogram per K No Conversion Required
Inlet Temperature of Cold Fluid: 283 Kelvin --> 283 Kelvin No Conversion Required
Outlet Temperature of Cold Fluid: 303 Kelvin --> 303 Kelvin No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Q = modulus(mc*cc*(Tci- Tco)) --> modulus(9*350*(283- 303))
Evaluating ... ...
Q = 63000
STEP 3: Convert Result to Output's Unit
63000 Joule --> No Conversion Required
FINAL ANSWER
63000 Joule <-- Heat
(Calculation completed in 00.004 seconds)

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Created by Ishan Gupta
Birla Institute of Technology & Science (BITS), Pilani
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10+ Heat Exchanger Calculators

Overall Heat Transfer Coefficient for Unfinned Tube
Go Overall Heat Transfer Coefficient after Fouling = 1/((1/External Convection Heat Transfer Coefficient)+Fouling Factor on Outside of Tube+(((Outside Tube Diameter*(ln(Outside Tube Diameter/Inside Tube Diameter))))/(2*Thermal Conductivity))+((Fouling Factor on Inside of Tube*Outside Tube Surface Area)/Inside Tube Surface Area)+(Outside Tube Surface Area/(Inside Convection Heat Transfer Coefficient*Inside Tube Surface Area)))
Total Heat Transfer Coefficient for Long Cylinder
Go Heat Transfer Coefficient = ((0.023*(Mass Velocity^0.8)*(Thermal Conductivity^0.67)*(Specific Heat Capacity^0.33))/((Diameter of Tube^0.2)*(Viscosity of Fluid^0.47)))
Heat Transfer in Heat Exchanger given Cold Fluid Properties
Go Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid))
Heat Transfer in Heat Exchanger given Hot Fluid Properties
Go Heat = Mass of Hot Fluid*Specific Heat Capacity of Hot Fluid*(Inlet Temperature of Hot Fluid-Outlet Temperature of Hot Fluid)
Rate of Heat Transfer using Correction Factor and LMTD
Go Heat Transfer = Overall Heat Transfer Coefficient*Area of Heat Exchanger*Correction Factor *Log Mean Temperature Difference
Maximum Possible Rate of Heat Transfer
Go Maximum Possible Rate of Heat Transfer = Minimum Capacity Rate*(Inlet Temperature of Hot Fluid-Inlet Temperature of Cold Fluid)
Number of Heat Transfer Units
Go Number of Heat Transfer Units = (Overall Heat Transfer Coefficient*Area of Heat Exchanger)/Minimum Capacity Rate
Heat Transfer in Heat Exchanger given Overall Heat Transfer Coefficient
Go Heat = Overall Heat Transfer Coefficient*Area of Heat Exchanger*Log Mean Temperature Difference
Fouling Factor
Go Fouling Factor = (1/Overall Heat Transfer Coefficient after Fouling)-(1/Overall Heat Transfer Coefficient)
Capacity Rate
Go Capacity Rate = Mass Flow Rate*Specific Heat Capacity

15 Heat Exchanger and its Effectiveness Calculators

Overall Heat Transfer Coefficient for Unfinned Tube
Go Overall Heat Transfer Coefficient after Fouling = 1/((1/External Convection Heat Transfer Coefficient)+Fouling Factor on Outside of Tube+(((Outside Tube Diameter*(ln(Outside Tube Diameter/Inside Tube Diameter))))/(2*Thermal Conductivity))+((Fouling Factor on Inside of Tube*Outside Tube Surface Area)/Inside Tube Surface Area)+(Outside Tube Surface Area/(Inside Convection Heat Transfer Coefficient*Inside Tube Surface Area)))
Effectiveness of Counter-Current Heat Exchanger if Cold Fluid is Minimum Fluid
Go Effectiveness of HE when Cold Fluid is Min Fluid = (modulus((Inlet Temperature of Cold Fluid-Outlet Temperature of Cold Fluid))/(Inlet Temperature of Hot Fluid-Outlet Temperature of Cold Fluid))
Effectiveness of Parallel-Flow Heat Exchanger if Cold Fluid is Minimum Fluid
Go Effectiveness of HE when Cold Fluid is Min Fluid = (Outlet Temperature of Cold Fluid-Inlet Temperature of Cold Fluid)/(Inlet Temperature of Hot Fluid-Inlet Temperature of Cold Fluid)
Effectiveness of Parallel-Flow Heat Exchanger if Hot Fluid is Minimum Fluid
Go Effectiveness of HE when Hot Fluid is Min Fluid = ((Inlet Temperature of Hot Fluid-Outlet Temperature of Hot Fluid)/(Inlet Temperature of Hot Fluid-Inlet Temperature of Cold Fluid))
Effectiveness of Counter-Current Heat Exchanger if Hot Fluid is Minimum Fluid
Go Effectiveness of HE when Hot Fluid is Min Fluid = (Inlet Temperature of Hot Fluid-Outlet Temperature of Hot Fluid)/(Inlet Temperature of Hot Fluid-Outlet Temperature of Cold Fluid)
Heat Transfer in Heat Exchanger given Cold Fluid Properties
Go Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid))
Heat Transfer in Heat Exchanger given Hot Fluid Properties
Go Heat = Mass of Hot Fluid*Specific Heat Capacity of Hot Fluid*(Inlet Temperature of Hot Fluid-Outlet Temperature of Hot Fluid)
Rate of Heat Transfer using Correction Factor and LMTD
Go Heat Transfer = Overall Heat Transfer Coefficient*Area of Heat Exchanger*Correction Factor *Log Mean Temperature Difference
Maximum Possible Rate of Heat Transfer
Go Maximum Possible Rate of Heat Transfer = Minimum Capacity Rate*(Inlet Temperature of Hot Fluid-Inlet Temperature of Cold Fluid)
Number of Heat Transfer Units
Go Number of Heat Transfer Units = (Overall Heat Transfer Coefficient*Area of Heat Exchanger)/Minimum Capacity Rate
Heat Transfer in Heat Exchanger given Overall Heat Transfer Coefficient
Go Heat = Overall Heat Transfer Coefficient*Area of Heat Exchanger*Log Mean Temperature Difference
Heat Exchanger Effectiveness for Minimum Fluid
Go Effectiveness of Heat Exchanger = Temperature Difference of Minimum Fluid/Maximum Temperature Difference in Heat Exchanger
Fouling Factor
Go Fouling Factor = (1/Overall Heat Transfer Coefficient after Fouling)-(1/Overall Heat Transfer Coefficient)
Heat Exchanger Effectiveness
Go Effectiveness of Heat Exchanger = Actual Rate of Heat Transfer/Maximum Possible Rate of Heat Transfer
Capacity Rate
Go Capacity Rate = Mass Flow Rate*Specific Heat Capacity

Heat Transfer in Heat Exchanger given Cold Fluid Properties Formula

Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid))
Q = modulus(mc*cc*(Tci- Tco))

Heat Transfer in a Heat Exchanger

Heat Transfer in a Heat Exchanger gives the heat transferred from hot fluid to cold fluid. The Unit for rate of Heat Transfer is Joules per unit time.

What are the Different Types of Heat Exchanger?

Mainly Heat Exchanger are divided in 4 categories: Hairpin Type Heat Exchanger, Double Pipe Heat Exchanger, Shell and Tube Heat Exchanger & Plate Type Heat Exchanger.

How to Calculate Heat Transfer in Heat Exchanger given Cold Fluid Properties?

Heat Transfer in Heat Exchanger given Cold Fluid Properties calculator uses Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid)) to calculate the Heat, Heat Transfer in Heat Exchanger given Cold Fluid Properties gives the heat energy transferred from the hot fluid to the cold fluid. Heat is denoted by Q symbol.

How to calculate Heat Transfer in Heat Exchanger given Cold Fluid Properties using this online calculator? To use this online calculator for Heat Transfer in Heat Exchanger given Cold Fluid Properties, enter Mass of Cold Fluid (mc), Specific Heat Capacity of Cold Fluid (cc), Inlet Temperature of Cold Fluid (Tci) & Outlet Temperature of Cold Fluid (Tco) and hit the calculate button. Here is how the Heat Transfer in Heat Exchanger given Cold Fluid Properties calculation can be explained with given input values -> 63000 = modulus(9*350*(283- 303)).

FAQ

What is Heat Transfer in Heat Exchanger given Cold Fluid Properties?
Heat Transfer in Heat Exchanger given Cold Fluid Properties gives the heat energy transferred from the hot fluid to the cold fluid and is represented as Q = modulus(mc*cc*(Tci- Tco)) or Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid)). Mass of Cold Fluid is the mass of the cooler fluid in the heat exchanger, Specific Heat Capacity of Cold Fluid is a physical property of matter, defined as the amount of heat to be supplied to a unit mass of the cooler fluid to produce a unit change in its temperature, Inlet Temperature of Cold Fluid is the temperature at which the cold fluid enters the heat exchanger & Outlet Temperature of Cold Fluid is the temperature at which the cold fluid exits the heat exchanger.
How to calculate Heat Transfer in Heat Exchanger given Cold Fluid Properties?
Heat Transfer in Heat Exchanger given Cold Fluid Properties gives the heat energy transferred from the hot fluid to the cold fluid is calculated using Heat = modulus(Mass of Cold Fluid*Specific Heat Capacity of Cold Fluid*(Inlet Temperature of Cold Fluid- Outlet Temperature of Cold Fluid)). To calculate Heat Transfer in Heat Exchanger given Cold Fluid Properties, you need Mass of Cold Fluid (mc), Specific Heat Capacity of Cold Fluid (cc), Inlet Temperature of Cold Fluid (Tci) & Outlet Temperature of Cold Fluid (Tco). With our tool, you need to enter the respective value for Mass of Cold Fluid, Specific Heat Capacity of Cold Fluid, Inlet Temperature of Cold Fluid & Outlet Temperature of Cold Fluid 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 Heat?
In this formula, Heat uses Mass of Cold Fluid, Specific Heat Capacity of Cold Fluid, Inlet Temperature of Cold Fluid & Outlet Temperature of Cold Fluid. We can use 4 other way(s) to calculate the same, which is/are as follows -
  • Heat = Mass of Hot Fluid*Specific Heat Capacity of Hot Fluid*(Inlet Temperature of Hot Fluid-Outlet Temperature of Hot Fluid)
  • Heat = Overall Heat Transfer Coefficient*Area of Heat Exchanger*Log Mean Temperature Difference
  • Heat = Mass of Hot Fluid*Specific Heat Capacity of Hot Fluid*(Inlet Temperature of Hot Fluid-Outlet Temperature of Hot Fluid)
  • Heat = Overall Heat Transfer Coefficient*Area of Heat Exchanger*Log Mean Temperature Difference
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