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Design of packed tower 
The cross sectional view of the packed tower is shown in Figure 4.5.

Design of packed tower may be 
(I) on the basis of individual mass transfer coefficients or
(II) on the basis of overall mass transfer coefficient.
Design Of Packed Tower | Mass Transfer - Chemical Engineering
Figure 4.5: Cross sectional view of packed tower.
 

The column is packed with packing materials (any type) to provide more contact between gas and liquid.
Let, Gand L/ are gas and liquid flow rate per unit area basis, mol/h.m2. ā is specific interfacial contact area between gas and liquid, m2 /m3 . The mole fraction of solute in gas is y. Hence, solute flow rate in gas= G/y mol/h.m2
The decrease in solute flow rate over the thickness dh=d(G/y)                                                                                                   (4.1)
For a unit cross-sectional area (1m2 ), volume of differential section=1×dh m3 and interfacial area of contact in differential section= ā×1×dh m2
If NA is solute flux and ky is individual gas-phase mass transfer coefficient, solute transfer through differential section= ā×dh×NA.
Therefore,
-[G/dy+ y dG/]= ā×dh×NA                                                                       (4.2)
-G/dy - y dG/ = ā×dh×NA                                                                        (4.3)
The change in total gas flow rate (dG) is equal to rate of solute transfer (ā×dh×NA) as carrier gas is not soluble, i.e.,
- dG= ā×dh×NA                                                                                   (4.4)
Putting the value of –dG/ in Equation 4.3, we have,
-G/dy + ā×dh×NA y= ā×dh×NA                                                            (4.5)
-G/dy = ā×dh×NA(1-y)
Design Of Packed Tower | Mass Transfer - Chemical Engineering                                                   (4.6)
Boundary conditions:
h=0; y=y1
h=hT; y=y
Integration of Equation 4.6 gives the height of packed column as follows:
Design Of Packed Tower | Mass Transfer - Chemical Engineering                (4.7)
Interfacial solute concentration, yi is not known; hence the integration of the right hand side of Equation 4.7 is complicated.

STEP-BY-STEP PROCEDURE 
(1) For a particular gas-liquid system, draw equilibrium curve on X-Y plane.
(2) Draw operating line in X-Y plane (PQ) using material balance Equation.
Lower terminal Q (X2, Y2) and upper terminal P (X1, Y1) are placed in x-y plane. Overall mass balance Equation for the absorption tower is as follows:
Design Of Packed Tower | Mass Transfer - Chemical Engineering
Design Of Packed Tower | Mass Transfer - Chemical Engineering                                            (4.8)
If liquid mass flow rate, Ls is not known, minimum liquid mass flow rate (Ls)min is to be determined. Ls is generally 1.2 to 2 times the (Ls)min 
Design Of Packed Tower | Mass Transfer - Chemical Engineering
Figure 4.6: Graphical determination of (Ls)min for absorption.

In Figure 4.6, lower terminal of absorption tower is represented by Q (X2, Y2); i.e., bottom of the tower. Operating line is PQ. If liquid rate is decreased, slope of operating line (Ls/Gs) also decreases and operating line shifts from PQ to P/Q, when touches equilibrium line. This operating line is tangent to equilibrium line.

Design Of Packed Tower | Mass Transfer - Chemical Engineering
The driving force for absorption is zero at P/ and is called “PINCH POINT”.

(3) A point A (x, y) is taken on the operating line. From the known value of kx and ky or kxā and kyā, a line is drawn with slope of kx/ky to equilibrium line, B(xi,yi). Line AB is called “TIE LINE” and xi and yi are known for a set of values of x and y.
(4) Step (3) is repeated for other points in the operating line to get several (xi,yi) sets for y1≥y≥y2.
(5) Calculate flow rate of gas G (kg/h) at each point as G=Gs(1+y).
(6) Calculate height of the packing hT of Equation 4.7 graphically or numerically.
The height of the „stripping column‟ is also obtained in a similar way. For stripping, y2>y1 and driving force is (yi-y). The corresponding design Equation will be
Design Of Packed Tower | Mass Transfer - Chemical Engineering                               (4.9)

The document Design Of Packed Tower | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Design Of Packed Tower - Mass Transfer - Chemical Engineering

1. What is the purpose of a packed tower in chemical engineering?
Ans. A packed tower is used in chemical engineering for various purposes, such as absorption, distillation, and stripping. It provides a large surface area for contact between two phases, allowing for efficient mass transfer and separation processes.
2. How does a packed tower work in chemical engineering?
Ans. In a packed tower, a liquid phase and a gas phase come into contact with each other. The liquid flows down over a packing material, which provides a large surface area. The gas flows countercurrently to the liquid, allowing for the transfer of mass between the two phases. This mass transfer can involve the absorption of a gas into the liquid or the stripping of a volatile component from the liquid.
3. What are the types of packing materials used in packed towers?
Ans. Packed towers can be filled with various types of packing materials, including structured packings, random packings, and dumped packings. Structured packings are typically made of metal or plastic and have a fixed geometry. Random packings, on the other hand, consist of irregularly shaped pieces of material, such as rings or saddles. Dumped packings are loosely filled into the tower and provide a large surface area for contact.
4. What factors affect the performance of a packed tower in chemical engineering?
Ans. Several factors influence the performance of a packed tower, including the choice of packing material, the liquid and gas flow rates, the temperature and pressure conditions, and the chemical properties of the substances involved. Proper design and operation of the packed tower are essential to achieve the desired separation or absorption efficiency.
5. How is the efficiency of a packed tower measured in chemical engineering?
Ans. The efficiency of a packed tower is often evaluated by the height equivalent to a theoretical plate (HETP). It represents the height of an ideal theoretical plate that would provide the same separation efficiency as the packed tower. The lower the HETP value, the higher the efficiency of the packed tower. Other performance parameters, such as pressure drop and mass transfer coefficient, are also used to assess the efficiency of packed towers.
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