2.8 – Practice Problem

Question

Iron can be one of the most troublesome elements in water. It is very important to treat water containing large amounts of iron because as little as 0.3 ppm (parts per million) of iron can cause damage to manufacturing processes and the environment. The most common forms of iron found in water is ferrous, ${\displaystyle {\text{Fe}}^{+2}}$, and ferric, ${\displaystyle {\text{Fe}}^{+3}}$. The ferrous and ferric increases the acidity of the water. To treat the water, a base is needed such as sodium hydroxide, ${\displaystyle {\text{NaOH}}}$. The base causes a titration with the ferrous titrating to iron hydroxide, ${\displaystyle {\text{Fe(OH)}}_{2}}$, and ferric titrating to ferric hydroxide, ${\displaystyle {\text{Fe(OH)}}_{3}}$. These hydroxides are not soluble in water and therefore can be extracted from the water.

${\displaystyle {\text{Fe}}_{(aq)}^{+2}+2{\text{ }}{\text{NaOH}}_{(aq)}{\text{ }}\rightleftharpoons {\text{ }}{\text{Fe(OH)}}_{2{\text{ }}(s)}+2{\text{ }}{\text{Na}}_{(aq)}^{+1}}$

${\displaystyle {\text{Fe}}_{(aq)}^{+3}+3{\text{ }}{\text{NaOH}}_{(aq)}{\text{ }}\rightleftharpoons {\text{ }}{\text{Fe(OH)}}_{3{\text{ }}(s)}+3{\text{ }}{\text{Na}}_{(aq)}^{+1}}$

You are a chemical engineer working at a mining company. Your boss wants you to make a material balance of the water treatment of iron so that he can analyze the cost of the treatment. You will be using a continuous stirred-tank reactor (CSTR). Assume that only ferrous is present in the water.

${\displaystyle {\text{Fe}}_{(aq)}^{+2}+2{\text{ }}{\text{NaOH}}_{(aq)}{\text{ }}\rightleftharpoons {\text{ }}{\text{Fe(OH)}}_{2{\text{ }}(s)}+2{\text{ }}{\text{Na}}_{(aq)}^{+1}}$

There are two input streams and two output streams. The first input stream, stream 1, contains water, ferrous at 500 ppm. The flow rate of water in this stream is 450 L/h. The second input stream, stream 2, is a 3-molar solution of sodium hydroxide. The first output stream, stream 3, contains pure ferrous oxide. The second output stream, stream 4, contains all the water that entered the system, the sodium and the legal amount of iron in the water at 0.1 ppm.

a) Draw and label the body flow diagram (BFD).

b) Perform a degree of freedom analysis.

Answer

a) Draw and label the body flow diagram (BFD).

First, let’s draw the basic outline of the BFD


Attribution: Said Zaid-Alkailani & UBC [CC BY 4.0 de (https://creativecommons.org/licenses/by/4.0/)]

Now let’s turn everything into a molar basis and fill out our BFD.

${\displaystyle {\dot {V}}_{H_{2}O}=450{\frac {L}{h}}}$

${\displaystyle {\dot {n}}_{H_{2}O}=450{\text{ }}{\frac {L}{h}}\times 1,000{\text{ }}{\frac {g}{L}}\times 0.0556{\text{ }}{\frac {mol}{g}}=25,000{\text{ }}{\frac {mol}{h}}}$

Since we know that the ferrous in stream 1 is 500 ppm and the mole fractions of stream 1 must add to one, we find that:

${\displaystyle y_{(1,Fe^{+2})}=0.0005}$

${\displaystyle y_{(1,H_{2}O)}=1-y_{(1,Fe^{+2})}=1-0.0005=0.9995}$

and that

${\displaystyle {\dot {n}}_{1}={\frac {{\dot {n}}_{H_{2}O}}{y_{(1,H_{2}O)}}}={\frac {25,000{\text{ }}{\frac {mol}{h}}}{0.9995}}=25.01{\text{ }}{\frac {kmol}{h}}}$

Since we know that only pure ferrous oxide exists stream there we find that:

${\displaystyle y_{(1,Fe(OH)_{2})}=1}$

We can now label our BFD to the fullest extent without solving the problem.


Attribution: Said Zaid-Alkailani & UBC [CC BY 4.0 de (https://creativecommons.org/licenses/by/4.0/)]

b) Perform a degree of freedom analysis.

We have 8 unknown labeled variables but since we can deduce two of the mole fractions from the others, let’s just say we have 6 unknown labeled variables. We will use the atomic species balance for this question. The degree of freedom analysis for an atomic species balance is:

${\displaystyle DOF={\text{Unknown variables}}-{\text{independent atomic species balance}}-{\text{molecular balances on independent nonreactive species}}-{\text{other equations relating unknown variables}}}$

We know that:

${\displaystyle {\text{Unknown variables}}=6}$

${\displaystyle {\text{independent atomic species balance}}=4{\text{ }}(H,{\text{ }}Fe,{\text{ }}Na,{\text{and}}{\text{ }}O)}$

${\displaystyle {\text{molecular balances on independent nonreactive species}}=0}$

${\displaystyle {\text{other equations relating unknown variables}}=2}$

Where other equations relating unknown variables is

${\displaystyle y_{(4,Fe^{+2})}=0.0001}$

and that ${\displaystyle NaOH}$ is 3 moles per litre.

${\displaystyle 3{\text{ }}{\frac {NaOH{\text{ }}mol}{H_{2}O{\text{ }}l}}\times {\frac {1{\text{ }}l}{1,000{\text{ }}g}}\times {\frac {18{\text{ }}g}{1{\text{ }}mol{\text{ }}H_{2}O}}=0.054{\text{ }}{\frac {NaOH{\text{ }}mol}{H_{2}O{\text{ }}mol}}}$

${\displaystyle y_{(2,{\text{ }}NaOH)}={\frac {0.054}{0.054+1}}=0.0512}$

${\displaystyle \therefore {\text{ }}DOF=6-4-0-2=0}$