Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles Solution

STEP 0: Pre-Calculation Summary
Formula Used
Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Vapor Pressure of Volatile Component)/(Total Pressure of System-(Vaporizing Efficiency*Vapor Pressure of Volatile Component)))
mA = mS*((E*Pvaporvc)/(P-(E*Pvaporvc)))
This formula uses 5 Variables
Variables Used
Moles of Volatile Component - (Measured in Mole) - The Moles of Volatile Component is the amount of moles of Volatile component in a mixture for Steam Distillation.
Moles of Steam - (Measured in Mole) - The Moles of Steam if the amount of moles of steam required for Steam Distillation.
Vaporizing Efficiency - The Vaporizing Efficiency is the factor used to take into account the deviation for steam distillation not operating under equilibrium.
Vapor Pressure of Volatile Component - (Measured in Pascal) - The Vapor Pressure of Volatile Component is the vapor pressure exerted by the Volatile component in a mixture with non-volatiles.
Total Pressure of System - (Measured in Pascal) - The Total Pressure of System is the Total Pressure of the Steam Distillation System under Operation.
STEP 1: Convert Input(s) to Base Unit
Moles of Steam: 4 Mole --> 4 Mole No Conversion Required
Vaporizing Efficiency: 0.75 --> No Conversion Required
Vapor Pressure of Volatile Component: 30000 Pascal --> 30000 Pascal No Conversion Required
Total Pressure of System: 100000 Pascal --> 100000 Pascal No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
mA = mS*((E*Pvaporvc)/(P-(E*Pvaporvc))) --> 4*((0.75*30000)/(100000-(0.75*30000)))
Evaluating ... ...
mA = 1.16129032258065
STEP 3: Convert Result to Output's Unit
1.16129032258065 Mole --> No Conversion Required
FINAL ANSWER
1.16129032258065 1.16129 Mole <-- Moles of Volatile Component
(Calculation completed in 00.008 seconds)

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DJ Sanghvi College of Engineering (DJSCE), Mumbai
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Steam Distillation Calculators

Moles of Volatile component Volatilized from mixture of Non-Volatiles by Steam
​ LaTeX ​ Go Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component)/(Total Pressure of System-Vaporizing Efficiency*Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component))
Moles of Volatile component Volatilized from mixture of Non-Volatiles by Steam at Equilibrium
​ LaTeX ​ Go Moles of Volatile Component = Moles of Steam*(Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component/(Total Pressure of System-Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component))
Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles
​ LaTeX ​ Go Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Vapor Pressure of Volatile Component)/(Total Pressure of System-(Vaporizing Efficiency*Vapor Pressure of Volatile Component)))
Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles at Equilibrium
​ LaTeX ​ Go Moles of Volatile Component = Moles of Steam*(Vapor Pressure of Volatile Component/(Total Pressure of System-Vapor Pressure of Volatile Component))

Important Formulas in Distillation Mass Transfer Operation Calculators

Feed Q-Value in Distillation Column
​ LaTeX ​ Go Q-value in Mass Transfer = Heat Required to Convert Feed to Saturated Vapor/Molal Latent Heat of Vaporization of Saturated Liq
External Reflux Ratio
​ LaTeX ​ Go External Reflux Ratio = External Reflux Flowrate to Distillation Column/Distillate Flowrate from Distillation Column
Internal Reflux Ratio
​ LaTeX ​ Go Internal Reflux Ratio = Internal Reflux Flowrate to Distillation Column/Distillate Flowrate from Distillation Column
Boil-Up Ratio
​ LaTeX ​ Go Boil-Up Ratio = Boil-Up Flowrate to the Distillation Column/Residue Flowrate from Distillation Column

Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles Formula

​LaTeX ​Go
Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Vapor Pressure of Volatile Component)/(Total Pressure of System-(Vaporizing Efficiency*Vapor Pressure of Volatile Component)))
mA = mS*((E*Pvaporvc)/(P-(E*Pvaporvc)))

What is Steam Distillation?

Steam distillation is a separation process that consists of distilling water together with other volatile and non-volatile components. The steam from the boiling water carries the vapor of the volatiles to a condenser; both are cooled and return to the liquid or solid state, while the non-volatile residues remain behind in the boiling container. If, as is usually the case, the volatiles are not miscible with water, they will spontaneously form a distinct phase after condensation, allowing them to be separated by decantation or with a separatory funnel.

How to Calculate Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles?

Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles calculator uses Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Vapor Pressure of Volatile Component)/(Total Pressure of System-(Vaporizing Efficiency*Vapor Pressure of Volatile Component))) to calculate the Moles of Volatile Component, The Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles formula is defined as the moles of volatile component vaporised in a mixture with trace amounts of Non-Volatiles by Steam Distillation not operating under equilibrium. Moles of Volatile Component is denoted by mA symbol.

How to calculate Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles using this online calculator? To use this online calculator for Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles, enter Moles of Steam (mS), Vaporizing Efficiency (E), Vapor Pressure of Volatile Component (Pvaporvc) & Total Pressure of System (P) and hit the calculate button. Here is how the Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles calculation can be explained with given input values -> 1.16129 = 4*((0.75*30000)/(100000-(0.75*30000))).

FAQ

What is Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles?
The Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles formula is defined as the moles of volatile component vaporised in a mixture with trace amounts of Non-Volatiles by Steam Distillation not operating under equilibrium and is represented as mA = mS*((E*Pvaporvc)/(P-(E*Pvaporvc))) or Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Vapor Pressure of Volatile Component)/(Total Pressure of System-(Vaporizing Efficiency*Vapor Pressure of Volatile Component))). The Moles of Steam if the amount of moles of steam required for Steam Distillation, The Vaporizing Efficiency is the factor used to take into account the deviation for steam distillation not operating under equilibrium, The Vapor Pressure of Volatile Component is the vapor pressure exerted by the Volatile component in a mixture with non-volatiles & The Total Pressure of System is the Total Pressure of the Steam Distillation System under Operation.
How to calculate Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles?
The Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles formula is defined as the moles of volatile component vaporised in a mixture with trace amounts of Non-Volatiles by Steam Distillation not operating under equilibrium is calculated using Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Vapor Pressure of Volatile Component)/(Total Pressure of System-(Vaporizing Efficiency*Vapor Pressure of Volatile Component))). To calculate Moles of Volatile component Volatilized by Steam with Trace amounts of Non-Volatiles, you need Moles of Steam (mS), Vaporizing Efficiency (E), Vapor Pressure of Volatile Component (Pvaporvc) & Total Pressure of System (P). With our tool, you need to enter the respective value for Moles of Steam, Vaporizing Efficiency, Vapor Pressure of Volatile Component & Total Pressure of System 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 Moles of Volatile Component?
In this formula, Moles of Volatile Component uses Moles of Steam, Vaporizing Efficiency, Vapor Pressure of Volatile Component & Total Pressure of System. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Moles of Volatile Component = Moles of Steam*(Vapor Pressure of Volatile Component/(Total Pressure of System-Vapor Pressure of Volatile Component))
  • Moles of Volatile Component = Moles of Steam*(Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component/(Total Pressure of System-Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component))
  • Moles of Volatile Component = Moles of Steam*((Vaporizing Efficiency*Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component)/(Total Pressure of System-Vaporizing Efficiency*Mole Fraction of Volatile Comp in Non-Volatiles*Vapor Pressure of Volatile Component))
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