Non Adiabatic Heat of Equilibrium Conversion Calculator

✖Reactant Conversion gives us the percentage of reactants converted into products, displayed as the percentage as a decimal between 0 and 1.ⓘ Reactant Conversion [X_A]			+10% -10%
✖Heat of Reaction per Mole at Temperature T2 is change in enthalpy at T2.ⓘ Heat of Reaction per Mole at Temperature T2 [ΔH_r2]			+10% -10%
✖Mean Specific Heat of Unreacted Stream is the heat required to raise the temperature of one gram of a substance by one Celsius degree of the unreacted reactant after reaction occurred.ⓘ Mean Specific Heat of Unreacted Stream [C^']			+10% -10%
✖The Change in Temperature is the difference between the initial and final temperature.ⓘ Change in Temperature [∆T]			+10% -10%

✖Total Heat is the heat in the system.ⓘ Non Adiabatic Heat of Equilibrium Conversion [Q]

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Formula

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Non Adiabatic Heat of Equilibrium Conversion

Formula

`"Q" = ("X"_{"A"}*"ΔH"_{"r2"})+("C"^{"'"}*"∆T")`

Example

`"1908.12J/mol"=("0.72"*"2096J/mol")+("7.98J/(kg*K)"*"50K")`

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Non Adiabatic Heat of Equilibrium Conversion Solution

STEP 0: Pre-Calculation Summary

Formula Used

Total Heat = (Reactant Conversion*Heat of Reaction per Mole at Temperature T2)+(Mean Specific Heat of Unreacted Stream*Change in Temperature)
Q = (X_A*ΔH_r2)+(C^'*∆T)
This formula uses 5 Variables

Variables Used

Total Heat - (Measured in Joule Per Mole) - Total Heat is the heat in the system.
Reactant Conversion - Reactant Conversion gives us the percentage of reactants converted into products, displayed as the percentage as a decimal between 0 and 1.
Heat of Reaction per Mole at Temperature T2 - (Measured in Joule Per Mole) - Heat of Reaction per Mole at Temperature T2 is change in enthalpy at T2.
Mean Specific Heat of Unreacted Stream - (Measured in Joule per Kilogram per K) - Mean Specific Heat of Unreacted Stream is the heat required to raise the temperature of one gram of a substance by one Celsius degree of the unreacted reactant after reaction occurred.
Change in Temperature - (Measured in Kelvin) - The Change in Temperature is the difference between the initial and final temperature.

STEP 1: Convert Input(s) to Base Unit

Reactant Conversion: 0.72 --> No Conversion Required
Heat of Reaction per Mole at Temperature T2: 2096 Joule Per Mole --> 2096 Joule Per Mole No Conversion Required
Mean Specific Heat of Unreacted Stream: 7.98 Joule per Kilogram per K --> 7.98 Joule per Kilogram per K No Conversion Required
Change in Temperature: 50 Kelvin --> 50 Kelvin No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Q = (X_A*ΔH_r2)+(C^'*∆T) --> (0.72*2096)+(7.98*50)

Evaluating ... ...

Q = 1908.12

STEP 3: Convert Result to Output's Unit

1908.12 Joule Per Mole --> No Conversion Required

FINAL ANSWER

1908.12 Joule Per Mole <-- Total Heat

(Calculation completed in 00.004 seconds)

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Anurag Group of Institutions (AGI), Hyderabad

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Final Temperature for Equilibrium Conversion

Go Final Temperature for Equilibrium Conversion = (-(Heat of Reaction per Mole)*Initial Temperature for Equilibrium Conversion)/((Initial Temperature for Equilibrium Conversion*ln(Thermodynamic Constant at Final Temperature/Thermodynamic Constant at Initial Temperature)*[R])+(-(Heat of Reaction per Mole)))

Initial Temperature for Equilibrium Conversion

Go Initial Temperature for Equilibrium Conversion = (-(Heat of Reaction per Mole)*Final Temperature for Equilibrium Conversion)/(-(Heat of Reaction per Mole)-(ln(Thermodynamic Constant at Final Temperature/Thermodynamic Constant at Initial Temperature)*[R]*Final Temperature for Equilibrium Conversion))

Adiabatic Heat of Equilibrium Conversion

Go Heat of Reaction at Initial Temperature = (-((Mean Specific Heat of Unreacted Stream*Change in Temperature)+((Mean Specific Heat of Product Stream-Mean Specific Heat of Unreacted Stream)*Change in Temperature)*Reactant Conversion)/Reactant Conversion)

Heat of Reaction at Equilibrium Conversion

Go Heat of Reaction per Mole = (-(ln(Thermodynamic Constant at Final Temperature/Thermodynamic Constant at Initial Temperature)*[R])/(1/Final Temperature for Equilibrium Conversion-1/Initial Temperature for Equilibrium Conversion))

Equilibrium Conversion of Reaction at Initial Temperature

Go Thermodynamic Constant at Initial Temperature = Thermodynamic Constant at Final Temperature/exp(-(Heat of Reaction per Mole/[R])*(1/Final Temperature for Equilibrium Conversion-1/Initial Temperature for Equilibrium Conversion))

Equilibrium Conversion of Reaction at Final Temperature

Go Thermodynamic Constant at Final Temperature = Thermodynamic Constant at Initial Temperature*exp(-(Heat of Reaction per Mole/[R])*(1/Final Temperature for Equilibrium Conversion-1/Initial Temperature for Equilibrium Conversion))

Reactant Conversion at Adiabatic Conditions

Go Reactant Conversion = (Mean Specific Heat of Unreacted Stream*Change in Temperature)/(-Heat of Reaction at Initial Temperature-(Mean Specific Heat of Product Stream-Mean Specific Heat of Unreacted Stream)*Change in Temperature)

Reactant Conversion at Non Adiabatic Conditions

Go Reactant Conversion = ((Mean Specific Heat of Unreacted Stream*Change in Temperature)-Total Heat)/(-Heat of Reaction per Mole at Temperature T2)

Non Adiabatic Heat of Equilibrium Conversion

Go Total Heat = (Reactant Conversion*Heat of Reaction per Mole at Temperature T2)+(Mean Specific Heat of Unreacted Stream*Change in Temperature)

Non Adiabatic Heat of Equilibrium Conversion Formula

Total Heat = (Reactant Conversion*Heat of Reaction per Mole at Temperature T2)+(Mean Specific Heat of Unreacted Stream*Change in Temperature)
Q = (X_A*ΔH_r2)+(C^'*∆T)

What are Non Adiabatic Conditions?

Non Adiabatic conditions are conditions or process that does not occur without loss or gain of heat, there will be some heat gaining or losing.

How to Calculate Non Adiabatic Heat of Equilibrium Conversion?

Non Adiabatic Heat of Equilibrium Conversion calculator uses Total Heat = (Reactant Conversion*Heat of Reaction per Mole at Temperature T2)+(Mean Specific Heat of Unreacted Stream*Change in Temperature) to calculate the Total Heat, The Non Adiabatic Heat of Equilibrium Conversion formula is defined as the conversion of the reactant achieved at the process or condition that does not occur without loss or gain of heat, there will be some heat gaining or losing. Total Heat is denoted by Q symbol.

How to calculate Non Adiabatic Heat of Equilibrium Conversion using this online calculator? To use this online calculator for Non Adiabatic Heat of Equilibrium Conversion, enter Reactant Conversion (X_A), Heat of Reaction per Mole at Temperature T2 (ΔH_r2), Mean Specific Heat of Unreacted Stream (C^') & Change in Temperature (∆T) and hit the calculate button. Here is how the Non Adiabatic Heat of Equilibrium Conversion calculation can be explained with given input values -> 1908.12 = (0.72*2096)+(7.98*50).

FAQ

What is Non Adiabatic Heat of Equilibrium Conversion?

The Non Adiabatic Heat of Equilibrium Conversion formula is defined as the conversion of the reactant achieved at the process or condition that does not occur without loss or gain of heat, there will be some heat gaining or losing and is represented as Q = (X_A*ΔH_r2)+(C^'*∆T) or Total Heat = (Reactant Conversion*Heat of Reaction per Mole at Temperature T2)+(Mean Specific Heat of Unreacted Stream*Change in Temperature). Reactant Conversion gives us the percentage of reactants converted into products, displayed as the percentage as a decimal between 0 and 1, Heat of Reaction per Mole at Temperature T2 is change in enthalpy at T2, Mean Specific Heat of Unreacted Stream is the heat required to raise the temperature of one gram of a substance by one Celsius degree of the unreacted reactant after reaction occurred & The Change in Temperature is the difference between the initial and final temperature.

How to calculate Non Adiabatic Heat of Equilibrium Conversion?

The Non Adiabatic Heat of Equilibrium Conversion formula is defined as the conversion of the reactant achieved at the process or condition that does not occur without loss or gain of heat, there will be some heat gaining or losing is calculated using Total Heat = (Reactant Conversion*Heat of Reaction per Mole at Temperature T2)+(Mean Specific Heat of Unreacted Stream*Change in Temperature). To calculate Non Adiabatic Heat of Equilibrium Conversion, you need Reactant Conversion (X_A), Heat of Reaction per Mole at Temperature T2 (ΔH_r2), Mean Specific Heat of Unreacted Stream (C^') & Change in Temperature (∆T). With our tool, you need to enter the respective value for Reactant Conversion, Heat of Reaction per Mole at Temperature T2, Mean Specific Heat of Unreacted Stream & Change in Temperature and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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