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Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering PDF Download

4.7. Counter-current multi-stage absorption (Tray absorber) 
In tray absorption tower, multi-stage contact between gas and liquid takes place. In each tray, the liquid is brought into intimate contact of gas and equilibrium is reached thus making an ideal stage. In ideal stage, average composition of liquid leaving the tray is in equilibrium with liquid leaving that tray. The most important step in design of tray absorber is the determination of number of trays. The schematic of tray tower is presented in figure 4.7. The liquid enters from top of the column whereas gas is added from the bottom. The efficiency of the stages can be calculated as:

Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                      (4.18)

Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Figure 4.7: Schematic of tray tower.
The following parameters should be known for the determination of “number of stages”
(1) Gas feed rate
(2) Concentration of gas at inlet and outlet of the tower
(3) Minimum liquid rate; actual liquid rate is 1.2 to 2 times the minimum liquid rate.
(4) Equilibrium data for construction of equilibrium curve
Now, the number of theoretic stages can be obtained graphically or algebraically. 
 

(A) Graphical Method for the Determination of Number of Ideal Stages 
Overall material balance on tray tower
Gs(YN+1 -Y1)=Ls(XN -X0)                                                                                 (4.19)
This is the operating line for tray tower.

If the stage (plate) is ideal, (Xn, Yn) must lie on the equilibrium line, Y*=f(X). Top plate is located at P(X0, Y1) and bottom plate is marked as Q(XN, YN+1) in X-Y plane. A vertical line is drawn from Q point to D point in equilibrium line at (XN, YN). From point D in equilibrium line, a horizontal line is extended up to operating line at E (XN-1, YN). The region QDE stands for N-th plate (refer Figure 4.8). We may get fraction of plates. In that situation, the next whole number will be the actual number of ideal plates. If the overall stage efficiency is known, the number of real plates can be obtained from Equation (4.18). 
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering

Figure 4.8: Graphical determination of number of ideal stages.

(B) Algebraic Determination of Number of Ideal Stages 
If both operating line and equilibrium lines are straight, number of ideal stages can be calculated algebraically.
Let solute transfers from gas to liquid (Absorption)
Equilibrium line, Y=αX 

Point (XN, YN) lies on the equilibrium line: YN=αXN                        (4.20)
Operating line: 
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering  
Now Equation 4.22 becomes,
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                         (4.23)
This Equation is linear first order “difference Equation” (non-homogeneous).

Solution by finite difference method 
Corresponding homogeneous Equation: Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                    (4.24)
Solution is   Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                                             (4.25)
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                                           (4.26)
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                                                                       (4.27)
Non-homogeneous Equation has a particular solution, which is constant.
Assuming YN=YN+1, we have, Y=K
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                                                      (4.28)
The complete solution is as follows:
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                         (4.29)
Initial conditions:
N=0; Y0=αX
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering  
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                   (4.30) 

Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                         (4.31)
When N=N+1;
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering            (4.32)
Taking logarithm in both the sides we get: 
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                   
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                 (4.33)
When Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering  Equation (4.23) becomes
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering → Operating line Equation                 (4.34)
Put N=N, N-1, N-2, ………..3,2,1 and add to get
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                                            (4.35)

Let solute is transferred from liquid to gas (stripping). 
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                             (4.36)
When Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering Equation (4.23) becomes
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering                                                                     (4.37)

These four Equations (4.33, 4.35-4.37) are called “Kremser Equations”. 

Example Problem 4.2 : It is desired to absorb 95% of acetone by water from a mixture of acetone and nitrogen containing 1.5% of the component in a countercurrent tray tower. Total gas input is 30 kmol/hr and water enters the tower at a rate of 90 kmol/hr. The tower operates at 27�C and 1 atm. The equilibrium relation is Y=2.53X. Determine the number of ideal stages necessary for the separation using (a) graphical method as well as (b) Kremser analysis method.

Solution 4.2:
Basis: 1 hour
GN+1=30 kmol
yN+1=0.015
L0=90 kmol Moles acetone in = 30�0.015 moles=0.45
moles Moles nitrogen in = (30-0.45)
moles=29.55 moles Moles acetone leaving (95% absorbed) = 0.45�(1-0.95) moles=0.0225 moles
Gs=29.55 moles
Ls=90 moles
α=2.53 [as, Y=2.53X] 
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering = 0.015
Rewriting Equation (4.19) (operating line) as
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
XN=4.68�10-3
 

(a) Solution by graphical method 
Construction of operating line PQ:
P(X0, Y1)=P(0, 7.61�10-4 )
Q(XN, YN+1)=Q(4.68�10-3, 0.015)

Construction of equilibrium line (Y=2.53X):
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
From graphical construction (Figure 4.9), the number of triangles obtained is more than 7. Hence number of ideal stages is 8.

Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Figure 4.9: Graphical construction for determination of number of stages

(b) Solution by Kremser analysis method 
As Ā≠1, according to Kremser analysis method:
Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering
Number of ideal stages is 8.

The document Countercurrent Multistage Absorption (Tray Absorber) | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Countercurrent Multistage Absorption (Tray Absorber) - Mass Transfer - Chemical Engineering

1. What is countercurrent multistage absorption in chemical engineering?
Ans. Countercurrent multistage absorption, also known as tray absorber, is a process used in chemical engineering to separate a gas mixture by selectively absorbing one or more components of the gas into a liquid solvent. It involves passing the gas mixture upwards through a series of trays or stages, while the liquid solvent flows downwards. The gas and liquid flow in opposite directions, creating a countercurrent flow, which allows for efficient mass transfer and separation of the desired components.
2. How does tray absorber work in countercurrent multistage absorption?
Ans. In a tray absorber, each tray or stage consists of perforated plates or trays with liquid flowing over them. The gas mixture is introduced at the bottom of the column and flows upwards through the trays, while the liquid solvent is introduced at the top and flows downwards. As the gas and liquid flow in opposite directions, they come into contact on each tray, allowing for mass transfer between them. The desired components in the gas are absorbed into the liquid solvent, resulting in their separation from the gas mixture.
3. What are the advantages of countercurrent multistage absorption using tray absorbers?
Ans. Countercurrent multistage absorption using tray absorbers offers several advantages in chemical engineering. Firstly, it provides high separation efficiency due to the countercurrent flow pattern, which maximizes mass transfer between the gas and liquid phases. Secondly, it allows for flexibility in selecting the appropriate solvent, as different solvents can be used on different trays to optimize the separation of different components. Additionally, tray absorbers are compact in size, allowing for efficient use of space in industrial applications. They also offer easy control and adjustment of operating conditions, making them suitable for a wide range of gas separation processes.
4. What factors affect the performance of countercurrent multistage absorption using tray absorbers?
Ans. Several factors can influence the performance of countercurrent multistage absorption using tray absorbers. The choice of solvent is crucial, as it should have high selectivity for the desired components and good solubility. The gas and liquid flow rates, as well as the tray design, including tray spacing and tray efficiency, also play a significant role. Temperature and pressure conditions can affect the solubility and mass transfer rates, so they need to be carefully controlled. Additionally, the presence of impurities or contaminants in the gas stream can impact the absorption process and may require additional treatment steps.
5. What are some typical applications of countercurrent multistage absorption using tray absorbers?
Ans. Countercurrent multistage absorption using tray absorbers finds applications in various industries. It is commonly used in gas processing plants to separate and purify different components of natural gas, such as the removal of acid gases like carbon dioxide and hydrogen sulfide. It is also used in the petrochemical industry for the separation of hydrocarbon components in refinery processes. Additionally, tray absorbers are employed in environmental control systems to remove pollutants from flue gases emitted by power plants and industrial facilities.
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