Number of Ideal Equilibrium Extraction Stages Solution

STEP 0: Pre-Calculation Summary
Formula Used
Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1))
N = (log10(zC/XN))/(log10(((KSolute*E')/F')+1))
This formula uses 1 Functions, 6 Variables
Functions Used
log10 - The common logarithm, also known as the base-10 logarithm or the decimal logarithm, is a mathematical function that is the inverse of the exponential function., log10(Number)
Variables Used
Number of Equilibrium Extraction Stages - The Number of Equilibrium Extraction Stages is the number of Ideal Equilibrium stages required for Liquid-Liquid Extraction.
Mass Fraction of Solute in the Feed - The Mass Fraction of Solute in the Feed is the mass fraction of the solute in the Feed to the Liquid-Liquid Extraction operation.
N Stages Mass Fraction of Solute in Raffinate - The N Stages Mass Fraction of Solute in Raffinate Phase is the mass fraction of the solute in the raffinate phase on solute free basis after N Number of LLE Stages.
Distribution Coefficient of Solute - The distribution coefficient of solute is defined as the concentration of solute in the extract phase divided by the concentration of solute in the raffinate phase.
Solute Free Extract Phase Flowrate in LLE - (Measured in Kilogram per Second) - The Solute Free Extract Phase Flowrate in LLE is the flowrate of the extracting solvent after separation in liquid-liquid extraction operation.
Solute Free Feed Flowrate in Extraction - (Measured in Kilogram per Second) - The Solute Free Feed Flowrate in Extraction is the flowrate of the carrier liquid to the liquid-liquid extraction operation for separation.
STEP 1: Convert Input(s) to Base Unit
Mass Fraction of Solute in the Feed: 0.5 --> No Conversion Required
N Stages Mass Fraction of Solute in Raffinate: 0.0334 --> No Conversion Required
Distribution Coefficient of Solute: 2.6 --> No Conversion Required
Solute Free Extract Phase Flowrate in LLE: 62 Kilogram per Second --> 62 Kilogram per Second No Conversion Required
Solute Free Feed Flowrate in Extraction: 110 Kilogram per Second --> 110 Kilogram per Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
N = (log10(zC/XN))/(log10(((KSolute*E')/F')+1)) --> (log10(0.5/0.0334))/(log10(((2.6*62)/110)+1))
Evaluating ... ...
N = 2.99880717998376
STEP 3: Convert Result to Output's Unit
2.99880717998376 --> No Conversion Required
FINAL ANSWER
2.99880717998376 2.998807 <-- Number of Equilibrium Extraction Stages
(Calculation completed in 00.004 seconds)

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5 Equilibrium Stage Calculations for Immiscible (Pure) Solvent & Carrier Liquid Calculators

Number of Ideal Equilibrium Extraction Stages
Go Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1))
Raffinate Phase Solute Concentration for N Number of Ideal Stage Extraction
Go N Stages Mass Fraction of Solute in Raffinate = ((Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))^Number of Equilibrium Extraction Stages)*Mass Fraction of Solute in the Feed
Feed Solute Concentration for N-number of Ideal Stage Extraction
Go Mass Fraction of Solute in the Feed = N Stages Mass Fraction of Solute in Raffinate/((Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))^Number of Equilibrium Extraction Stages)
Raffinate Phase Solute Concentration for Single Ideal Stage Extraction
Go Single Stage Mass Fraction of Solute in Raffinate = (Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))*Mass Fraction of Solute in the Feed
Feed Solute Concentration for Single Ideal Stage Extraction
Go Mass Fraction of Solute in the Feed = Single Stage Mass Fraction of Solute in Raffinate/(Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))

23 Important Formulas in Liquid-Liquid Extraction Calculators

Number of Extraction Stages by Kremser Equation
Go Number of Equilibrium Extraction Stages = (log10(((Mass Fraction of Solute in the Feed-(Mass Fraction of Solute in the Solvent/Distribution Coefficient of Solute))/(((Mass Fraction of Solute in the Raffinate-Mass Fraction of Solute in the Solvent)/Distribution Coefficient of Solute)))*(1-(1/Extraction Factor))+(1/Extraction Factor)))/(log10(Extraction Factor))
Number of Ideal Equilibrium Extraction Stages
Go Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1))
Raffinate Phase Solute Concentration for N Number of Ideal Stage Extraction
Go N Stages Mass Fraction of Solute in Raffinate = ((Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))^Number of Equilibrium Extraction Stages)*Mass Fraction of Solute in the Feed
Feed Solute Concentration for N-number of Ideal Stage Extraction
Go Mass Fraction of Solute in the Feed = N Stages Mass Fraction of Solute in Raffinate/((Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))^Number of Equilibrium Extraction Stages)
Number of Stages for Extraction Factor equal to 1
Go Number of Equilibrium Extraction Stages = ((Mass Fraction of Solute in the Feed-(Mass Fraction of Solute in the Solvent/Distribution Coefficient of Solute))/(Mass Fraction of Solute in the Raffinate-(Mass Fraction of Solute in the Solvent/Distribution Coefficient of Solute)))-1
Raffinate Phase Solute Concentration for Single Ideal Stage Extraction
Go Single Stage Mass Fraction of Solute in Raffinate = (Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))*Mass Fraction of Solute in the Feed
Feed Solute Concentration for Single Ideal Stage Extraction
Go Mass Fraction of Solute in the Feed = Single Stage Mass Fraction of Solute in Raffinate/(Solute Free Feed Flowrate in Extraction/(Solute Free Feed Flowrate in Extraction+(Solute Free Extract Phase Flowrate in LLE*Distribution Coefficient of Solute)))
Recovery of Solute in Liquid-Liquid Extraction
Go Recovery of Solute in Liquid-Liquid Extraction = 1-((Mass Fraction of Solute in the Raffinate*Raffinate Phase Flowrate in LLE)/(Mass Fraction of Solute in the Feed*Feed Flowrate in Liquid-Liquid Extraction))
Selectvity of Solute based on Activity Coefficients
Go Selectivity = (Activity Coefficient of Solute in Raffinate/Activity Coefficient of Solute in Extract)/(Activity Coefficient of Carrier Liq in Raffinate/Activity Coefficient of Carrier Liquid in Extract)
Selectvity of Solute based on Mole Fractions
Go Selectivity = (Mass Fraction of Solute in the Extract/Mass Fraction of Carrier Liquid in the Extract)/(Mass Fraction of Solute in the Raffinate/Mass Fraction of Carrier Liquid in the Raffinate)
Mass Ratio of Solvent in Raffinate Phase
Go Mass Ratio of Solvent in Raffinate Phase = Mass Fraction of Solvent in the Raffinate/(Mass Fraction of Carrier Liquid in the Raffinate+Mass Fraction of Solute in the Raffinate)
Mass Ratio of Solute in Raffinate Phase
Go Mass Ratio of Solute in Raffinate Phase = Mass Fraction of Solute in the Raffinate/(Mass Fraction of Carrier Liquid in the Raffinate+Mass Fraction of Solute in the Raffinate)
Mass Ratio of Solvent in Extract Phase
Go Mass Ratio of Solvent in Extract Phase = Mass Fraction of Solvent in the Extract/(Mass Fraction of Carrier Liquid in the Extract+Mass Fraction of Solute in the Extract)
Mass Ratio of Solute in Extract Phase
Go Mass Ratio of Solute in Extract Phase = Mass Fraction of Solute in the Extract/(Mass Fraction of Carrier Liquid in the Extract+Mass Fraction of Solute in the Extract)
Extraction Factor based on Raffinate Point Slope
Go Extraction Factor = Raffinate Point Slope of Equilibrium Curve*Solute Free Solvent Flowrate in Extraction/Solute Free Feed Flowrate in Extraction
Extraction Factor at Feed Point Slope of Equilibrium Curve
Go Extraction Factor = Feed Point Slope of Equilibrium Curve*Solute Free Solvent Flowrate in Extraction/Solute Free Feed Flowrate in Extraction
Extraction Factor at Mean Slope of Equilibrium Curve
Go Extraction Factor = Mean Slope of Equilibrium Curve*Solute Free Solvent Flowrate in Extraction/Solute Free Feed Flowrate in Extraction
Geometric Mean of Equilibrium Line Slope
Go Mean Slope of Equilibrium Curve = sqrt(Feed Point Slope of Equilibrium Curve*Raffinate Point Slope of Equilibrium Curve)
Distribution Coefficient of Carrier Liquid from Activity Coefficients
Go Distribution Coefficient of Carrier Liquid = Activity Coefficient of Carrier Liq in Raffinate/Activity Coefficient of Carrier Liquid in Extract
Distribution Coefficient of Carrier Liquid from Mass Fraction
Go Distribution Coefficient of Carrier Liquid = Mass Fraction of Carrier Liquid in the Extract/Mass Fraction of Carrier Liquid in the Raffinate
Distribution Coefficient of Solute from Activity Coefficient
Go Distribution Coefficient of Solute = Activity Coefficient of Solute in Raffinate/Activity Coefficient of Solute in Extract
Distribution Coefficient of Solute from Mass Fractions
Go Distribution Coefficient of Solute = Mass Fraction of Solute in the Extract/Mass Fraction of Solute in the Raffinate
Selectivity of Solute based on Distribution Coefficients
Go Selectivity = Distribution Coefficient of Solute/Distribution Coefficient of Carrier Liquid

Number of Ideal Equilibrium Extraction Stages Formula

Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1))
N = (log10(zC/XN))/(log10(((KSolute*E')/F')+1))

What are the Assumptions for Ideal Extraction?

1. The Solvent and the carrier liquid are immiscible (mutually non-dissolving), this leads to complete recovery of carrier liquid in raffinate phase and complete recovery of extracting solvent in extract phase. 2. The Extraction Solvent Feed to the system is Pure (i.e. has no initial solute). 3. The Extract and Raffinate streams leaving the extraction stage are in equilibrium.

What is Liquid-Liquid Extraction?

Liquid–liquid extraction (LLE), also known as solvent extraction, is a method to separate compounds or metal complexes, based on their relative solubilities in two different immiscible liquids, usually water (polar) and an organic solvent (non-polar). There is a net transfer of one or more species from one liquid into another liquid phase, generally from aqueous to organic. The transfer is driven by chemical potential, i.e. once the transfer is complete, the overall system of chemical components that make up the solutes and the solvents are in a more stable configuration (lower free energy). The solvent that is enriched in solute(s) is called extract. The feed solution that is depleted in solute(s) is called the raffinate.

How to Calculate Number of Ideal Equilibrium Extraction Stages?

Number of Ideal Equilibrium Extraction Stages calculator uses Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1)) to calculate the Number of Equilibrium Extraction Stages, The Number of Ideal Equilibrium Extraction Stages formula is defined as the number of equilibrium extraction stages required to achieve the extraction of raffinate mass fraction from the given feed mass fraction. Number of Equilibrium Extraction Stages is denoted by N symbol.

How to calculate Number of Ideal Equilibrium Extraction Stages using this online calculator? To use this online calculator for Number of Ideal Equilibrium Extraction Stages, enter Mass Fraction of Solute in the Feed (zC), N Stages Mass Fraction of Solute in Raffinate (XN), Distribution Coefficient of Solute (KSolute), Solute Free Extract Phase Flowrate in LLE (E') & Solute Free Feed Flowrate in Extraction (F') and hit the calculate button. Here is how the Number of Ideal Equilibrium Extraction Stages calculation can be explained with given input values -> 2.998807 = (log10(0.5/0.0334))/(log10(((2.6*62)/110)+1)).

FAQ

What is Number of Ideal Equilibrium Extraction Stages?
The Number of Ideal Equilibrium Extraction Stages formula is defined as the number of equilibrium extraction stages required to achieve the extraction of raffinate mass fraction from the given feed mass fraction and is represented as N = (log10(zC/XN))/(log10(((KSolute*E')/F')+1)) or Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1)). The Mass Fraction of Solute in the Feed is the mass fraction of the solute in the Feed to the Liquid-Liquid Extraction operation, The N Stages Mass Fraction of Solute in Raffinate Phase is the mass fraction of the solute in the raffinate phase on solute free basis after N Number of LLE Stages, The distribution coefficient of solute is defined as the concentration of solute in the extract phase divided by the concentration of solute in the raffinate phase, The Solute Free Extract Phase Flowrate in LLE is the flowrate of the extracting solvent after separation in liquid-liquid extraction operation & The Solute Free Feed Flowrate in Extraction is the flowrate of the carrier liquid to the liquid-liquid extraction operation for separation.
How to calculate Number of Ideal Equilibrium Extraction Stages?
The Number of Ideal Equilibrium Extraction Stages formula is defined as the number of equilibrium extraction stages required to achieve the extraction of raffinate mass fraction from the given feed mass fraction is calculated using Number of Equilibrium Extraction Stages = (log10(Mass Fraction of Solute in the Feed/N Stages Mass Fraction of Solute in Raffinate))/(log10(((Distribution Coefficient of Solute*Solute Free Extract Phase Flowrate in LLE)/Solute Free Feed Flowrate in Extraction)+1)). To calculate Number of Ideal Equilibrium Extraction Stages, you need Mass Fraction of Solute in the Feed (zC), N Stages Mass Fraction of Solute in Raffinate (XN), Distribution Coefficient of Solute (KSolute), Solute Free Extract Phase Flowrate in LLE (E') & Solute Free Feed Flowrate in Extraction (F'). With our tool, you need to enter the respective value for Mass Fraction of Solute in the Feed, N Stages Mass Fraction of Solute in Raffinate, Distribution Coefficient of Solute, Solute Free Extract Phase Flowrate in LLE & Solute Free Feed Flowrate in Extraction 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 Number of Equilibrium Extraction Stages?
In this formula, Number of Equilibrium Extraction Stages uses Mass Fraction of Solute in the Feed, N Stages Mass Fraction of Solute in Raffinate, Distribution Coefficient of Solute, Solute Free Extract Phase Flowrate in LLE & Solute Free Feed Flowrate in Extraction. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Number of Equilibrium Extraction Stages = (log10(((Mass Fraction of Solute in the Feed-(Mass Fraction of Solute in the Solvent/Distribution Coefficient of Solute))/(((Mass Fraction of Solute in the Raffinate-Mass Fraction of Solute in the Solvent)/Distribution Coefficient of Solute)))*(1-(1/Extraction Factor))+(1/Extraction Factor)))/(log10(Extraction Factor))
  • Number of Equilibrium Extraction Stages = ((Mass Fraction of Solute in the Feed-(Mass Fraction of Solute in the Solvent/Distribution Coefficient of Solute))/(Mass Fraction of Solute in the Raffinate-(Mass Fraction of Solute in the Solvent/Distribution Coefficient of Solute)))-1
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