Answer:
Explanation:
SO; If we assume that:
P should be the diffusion of oxygen towards the surface ; &
Q should be the diffusion of carbondioxide away from the surface.
Then the total molar flux of oxygen is illustrated by :
[tex]Na,x = - cD_{PQ}\frac{dy_P}{dr} +y_P(NP,x + N_Q,x)[/tex]
where;
r is the radial distance from the center of the carbon particle.
Since ;
[tex]N_P,x = - N_Q, x[/tex] ; we have:
[tex]Na,x = - cD_{PQ}\frac{dy_P}{dr}[/tex]
The system is not steady state and the molar flux is not independent of r because the area of mass transfer [tex]4\pi r^{2}[/tex] is not a constant term.
Therefore, using quasi steady state assumption, the mass transfer rate [tex]4\pi r^{2}N_{P,x}[/tex] is assumed to be independent of r at any instant of time.
[tex]W_{P}=4\pi r^{2}N_{P,x}[/tex]
[tex]W_{P}=-4\pi r^{2}cD_{PQ}\frac{dy_{P}}{dr}[/tex]
= constant
The oxygen concentration at the surface of the coal particle [tex]yP,R[/tex] will be calculated from the reaction at the surface.
The mole fraction of oxygen at a location far from pellet is 1.
Thus, separating the variables and integrating result into the following:
[tex]W_{P}\int_{R}^{\infty} \frac{dr}{r^{2}}=-4\pi[/tex]
[tex]r^{2}cD_{PQ}\int_{y_{P,R}}^{y_{P,\infty }}dy_{P}[/tex]
[tex]-W_{P}\frac{1}{r}\mid ^{\infty }_{R}= -4\pi cD_{PQ}(y_{P,\infty }-y_{P,R})[/tex]
[tex]=> W_{P}= - 4\pi cD_{PQ}(1-y_{P,R})R[/tex]
The mole of oxygen arrived at the carbon surface is equal to the mole of oxygen consumed by the chemical reaction.
[tex]W_{P} = 4 \pi R^2R"[/tex]
[tex]W_{P}= 4\pi R^{2}k_{1}"C_{O_{2}}\mid _{R}[/tex]
[tex]W_{P}= 4\pi R^{2}k_{1}"c y _{P,R}[/tex]
[tex]-4\pi cD_{PQ}(1-y_{P,R})R= - 4\pi R^{2}k_{1}"c y _{P,R}[/tex]
[tex]y_{P,R}=\frac{D_{PQ}}{D_{PQ}+Rk_{1}}[/tex]
[tex]y_{P,R}=\frac{1.7 \times 10^{-4}}{1.7\times 10^{-4}+10^{-3}\times 0.1}[/tex]
[tex]\mathbf{= 0.631}[/tex]
Obtaining the total gas concentration from the ideal gas law; we have the following:
where;
R= [tex]0.082m^3atm/kmolK[/tex]
[tex]c=\frac{P}{RT} \\ \\ c=\frac{1}{0.082\times 1450} \\ \\ = 0.008405kmol/m^3[/tex]
The steady state [tex]O_2[/tex] molar consumption rate is:
[tex]W_{P}= -4\pi cD_{PQ}(1-y_{P,R})R[/tex]
[tex]W_{P}= -4\pi (0.008405)(1.7\times 10^{-4})(1-0.631)(10^{-3})[/tex]
[tex]W_{P}= - 6.66\times 10^{-9}kmol/s[/tex]
