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Special Module 
Multi-component absorption 
S1. Introduction 
In multi-component absorption, a gas mixture is contacted with a liquid solvent to selectively dissolve more components by mass transfer from the gas to the liquid solvent. The components transferred to the liquid are referred to as solute or absorbate. The absorption is used to separate gas mixtures, remove impurities from a gas or recover valuable chemicals. A typical absorption operation is shown in Figure S1.


Special Module - Mass Transfer | Mass Transfer - Chemical Engineering 
Figure S1: Typical absorption process

The gas containing air (oxygen, nitrogen and argon of 21, 78 and 1% respectively), water vapor and acetone vapor is fed in a counter-current multistage absorber to remove acetone vapor by contacting the gas mixture with suitable solvent like water. From the material balance analysis as per system shown in Figure, 99.5% of the acetone is absorbed. The gas leaving the absorber contains some other components. Though the major component acetone vapor is absorbed, the small amounts of other components nitrogen and oxygen are also absorbed by the water solvent. The fraction of component absorbed in the absorber depends on the number of equilibrium stages and the absorption factor (A = L/KV) for that component. The equilibrium relationship between composition in the gas and the liquid phase in the absorber is expressed as:
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                              (S1)
where
y = mole fraction of specified component in the gas phase,
x = mole fraction of specified component in the liquid phase,
K = vaporization equilibrium constant for specified component on plate or stage n,
n = arbitrary theoretical plate in the absorber.
In terms of total molar flow rates of the gas and liquid, and the flow rates for the specified component Equation (S1) can be written as
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                             (S2)
Or
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                           (S3)

where ln = mole of specified component in the liquid stream leaving plate n,
v= mole of specified component in the vapor stream leaving plate n,
L= total mole of liquid stream leaving plate n,
Vn = total mole vapor stream leaving plate n
In Equation (S3), the term Ln /KnVn is referred to as the absorption factor which is expressed as
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                                  (S4)
where Ais the absorption factor.

Kremser and Brown equation for multicomponent absorption 
The general equations involving the theoretical plate concept and the assumption of equilibrium between a gas and a liquid on each theoretical plate can be derived by writing material balances around any plate and in the column. The material balance equation is then combined with the equilibrium expressions to give a generalized equation for the absorption.
The material balance for any component around plate n of the absorber shown in the can be written as 
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                     (S5)
The equations suitable for predicting component distributions in multicomponent absorption is more easily handled if compositions are placed as defined by X’ and Y’, where X’= moles of one component in the liquid stream per mole of solvent entering the absorber, Y’= moles one component in the gas stream leaving any plate
For plate n these concentration are defined as
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                                             (S6)
and
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                                        (S7)
Then the Equation (S5) can be written as;
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                  (S8)
The material balance equation can be written for overall column as
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                     (S9)
Equation (S9) can be plotted as straight lines and can be used for any absorption process. The equilibrium relationship between the gas and liquid on the tray in terms of the new composition parameters can be written as:
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                    (S10)
By substituting the Equation (S10), the Equation (S8) becomes
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                               (S11)
where Special Module - Mass Transfer | Mass Transfer - Chemical Engineering For a one-plate absorber Equation (S11) is
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                   (S12)
For the second plate the material balance would be
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                              (S13)
By combining Equations (S12) and (S13) the material balance for a two tray absorber can then be written as
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                   (S14)
The same procedure is followed for an absorber with three plates and finally, for absorber with N trays
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering
To obtain the equation in terms of the absorber terminal conditions, Y/N can be determined by combining Equation (S15) with an overall component material balance around the column. The overall component material balance is
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                             (S16)
An expression obtained from Equation (S10) for X/N is
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                              (S17)
If the X/N is replaced in Equation (S16) by Equation (S17), one can write
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                       (S18)
By introducing the Equation (S18), Equation (S15) can then be written in terms of the terminal absorber conditions as:
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering
The Equation (S19) can be used to determine terminal stream flow rates in a multicomponent absorber. The left side of Equation (S19) is the fractional absorption for any component if the liquid and gas flow rates for each tray in the column in addition to the tray is known. If an average value of the absorption factor is assumed to be valid for each tray as A=A1=A2=…..=AN, the absorption factors in Equation (S19) can be written as
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering              (S20)
and
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering         (S21)
By substituting the identities above into Equation (S19), the following expression can be obtained
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                   (S22)
where A is the average absorption factor. The Equation (S22) is known as the Kremser (1930) and Brown (1932) equation. If the value of the average absorption factor for that component is known, the composition of the off-gas from the absorber and the amount of material absorbed into the solvent may be readily calculated. The average absorption factor can be defined as:
Special Module - Mass Transfer | Mass Transfer - Chemical Engineering                                                       (S23)
where Kavg is the value of the average equilibrium constant for each component at the average temperature and pressure in the absorber. Equation (S22) can be solved either analytically or graphically. Any variable may be determined if the other two are known.

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FAQs on Special Module - Mass Transfer - Mass Transfer - Chemical Engineering

1. What is mass transfer in chemical engineering?
Ans. Mass transfer in chemical engineering refers to the movement of substances from one phase to another, typically involving the transfer of mass between a liquid and a gas or between two immiscible liquids. It plays a crucial role in various industrial processes, such as distillation, absorption, extraction, and drying.
2. How is mass transfer different from heat transfer in chemical engineering?
Ans. While both mass transfer and heat transfer involve the movement of substances, they differ in terms of what is being transferred. Mass transfer involves the transfer of mass or substances, whereas heat transfer involves the transfer of thermal energy. Additionally, mass transfer is often associated with phase changes, such as evaporation or condensation, while heat transfer can occur without any change in phase.
3. What are the different mechanisms of mass transfer?
Ans. There are three main mechanisms of mass transfer: diffusion, convection, and migration. Diffusion is the random movement of molecules from an area of high concentration to an area of low concentration. Convection involves the bulk movement of fluid carrying the mass. Migration, also known as electromigration, occurs when charged species migrate under the influence of an electric field.
4. How is mass transfer quantified in chemical engineering?
Ans. Mass transfer is quantified using various parameters, such as mass transfer coefficient, flux, and concentration gradient. The mass transfer coefficient represents the efficiency of mass transfer and is often determined experimentally. The flux refers to the amount of mass transferred per unit area per unit time. The concentration gradient represents the difference in concentration between two points and drives the mass transfer process.
5. What are some applications of mass transfer in chemical engineering?
Ans. Mass transfer has numerous applications in chemical engineering. It is used in processes such as distillation, where it separates different components of a liquid mixture based on their volatility. Absorption involves mass transfer of a gaseous component into a liquid phase. Extraction utilizes mass transfer to separate solutes from a liquid or solid mixture. Additionally, mass transfer is essential in various separation and purification techniques used in the pharmaceutical, food, and petrochemical industries.
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