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Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering PDF Download

Equimolar counter-diffusion of A and B (NA =-NB) 
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering  → Gas phase                (3.19)
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering → Liquid phase                                        (3.20)

For gas phase diffusion we know, 
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                     (3.21)

Equating Equation (3.19) and Equation (3.21),
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                                     (3.22)

Again,

Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                        (3.23)

Equating Equation (3.19) and Equation (3.23),
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                                     (3.24)
Also,
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                          (3.25)
Equating Equation (3.19) and Equation (3.25),
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                                       (3.26)

For liquid phase diffusion the flux can be written as
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                         (3.27)
Equating Equation (3.20) and Equation (3.27), Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                  (3.28)
Also, 
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                           (3.29)
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                                    (3.30)

Equating Equation (3.8) and Equation (3.17),
Conversions:    Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering 

Example problem 3.1:
Hydrochloric acid (A) diffuses through a thin film of water (B) 4.0 mm thick at 283 K. The concentration of HCl at point 1 on one boundary of the film is 12 wt% and on the other boundary, at point 2 is 4 wt%. The diffusivity of HCl in water is 2.5 x 10-9 m2/s. Calculate the flux of HCl considering water to be stagnant. Density of the solutions at points 1 and 2 are 1060.7 kg/m3 and 1020.15 kg/m3 respectively.

Solution 3.1: Molecular weight of HCl, MA = 36.5 and MB = 18
At point 1, mole fraction of HCl
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering Therefore, xB1 = 1- 0.0629 = 0.9371
Average molecular weight at point 1
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering

At point 2, mole fraction of HCl 
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering
Average molecular weight at point 2 
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering
z = 4 mm = 0.004 m
Flux of HCl,
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering

3.2 Mass transfer under laminar flow condition 
Mass transfer coefficient does not play a big role in laminar flow condition as molecular diffusion exists there. In laminar flow regime, the average liquid phase mass transfer coefficient, kL,av is correlated with Sherwood number (Sh) and DAB as follows:
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                         (3.31)
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                                    (3.32) 

3.3 Mass transfer under turbulent flow past solids
Mass transfer under flow past solid is a practically useful situation. Several theories have attempted to clarify the behavior of mass transfer coefficients. All the theories have some assumptions and some drawbacks. Hence, these are revised frequently. In turbulent flow medium, small fluid an element of different sizes, called eddies, move randomly. These eddies form, interact among others and disappear in the flow path. The total molar flux of a solute ‘A’ due to molecular diffusion and eddy diffusion, JA is as follows:
Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering                                                                            (3.33)
where DE is eddy diffusivity. Eddy diffusivity depends on intensity of local turbulence.

The document Equimolar Counter Diffusion Of A and B (NA =-NB) | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Equimolar Counter Diffusion Of A and B (NA =-NB) - Mass Transfer - Chemical Engineering

1. What is equimolar counter diffusion of A and B?
Ans. Equimolar counter diffusion refers to the simultaneous movement of two different substances, A and B, in opposite directions with equal molar fluxes. This means that the rates at which A and B molecules move are the same, resulting in a balanced diffusion process.
2. How does equimolar counter diffusion occur in chemical engineering?
Ans. Equimolar counter diffusion can occur in chemical engineering systems where two different substances need to be transported in opposite directions. This can be achieved by creating a concentration gradient between the two regions of interest and allowing the substances to diffuse across the barrier separating them.
3. What are the applications of equimolar counter diffusion in chemical engineering?
Ans. Equimolar counter diffusion has several applications in chemical engineering. It is commonly used in separation processes such as membrane separation, where two different components need to be selectively transported in opposite directions. Equimolar counter diffusion is also utilized in catalytic reactors and diffusion-controlled reactions, where precise control of the reactant concentrations is required.
4. How is equimolar counter diffusion different from other diffusion processes?
Ans. Equimolar counter diffusion differs from other diffusion processes in that it involves the simultaneous movement of two different substances in opposite directions with equal molar fluxes. In contrast, other diffusion processes may involve the movement of a single substance or multiple substances with different molar fluxes.
5. What factors affect the equimolar counter diffusion process in chemical engineering?
Ans. Several factors can influence the equimolar counter diffusion process in chemical engineering. These include the concentration gradients of the substances, the properties of the barrier or membrane separating them, temperature, pressure, and the presence of any external driving forces such as electric fields. It is important to consider these factors to optimize the efficiency and effectiveness of equimolar counter diffusion processes.
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