Practice Problems in ADSORPTION and ION EXCHANGE - Solutions

Practice problems in ADSORPTION and ION EXCHANGE  –  Solutions   Solutions

Q1. Adsorption isotherms

We considered three forms of isotherms: Linear:

q    Kc

- gives straight line on plot of q vs. c [1]

Freundlich:

q    Kc n

- gives straight line on log-log plot of q vs. c [2]

Langmuir:

q

q0 c  K   c

- gives straight line of plot of 1/q 1/q vs. 1/c 1/c [3]

The data are closest to a straight line on plot [3], indicating the Langmuir isotherm is the best fit. The linearized form of the Langmuir equation is: 1 q



 K  1

1

q0 c

q0

 

Using the line of best fit for the data in plot [3]:  Intercept   q0 

1 q0

 6.78

1 6.78

 0.147

g glucose g alumina

and Slope 

 K  q0

 0.124

 K   0.124q0  0.1240.147   0.0182

g glucose m 3 solution

Q2. Batch adsorption

Given:  M  = 3 kg granular activated carbon q F  = 0 kg phenol / kg carbon 3

S  = 2.5 m  solution 3 c F  = 0.25 kg phenol / m  solution

Material balance on adsorbate (phenol), assuming solution v olume S  is constant: q F  M   c F  S   qM   cS 

03  0.25 2.5   q 3   c 2.5  Operating line equation : q  0.208  0.833c

Plot the equilibrium data and the operating line. At equilibrium, q and c are in equilibrium, at the intersection of the two lines:

The equilibrium data are best fit by a Freundlich-type isotherm, as shown on the graph. Solving analytically (or graphically) for the intersection of the two lines: ceq  0.109 qeq  0.118

kg phenol m 3 solution kg phenol kg carbon

Percent phenol extracted: - Assuming solution volume S  is constant c F   ceq c F 

 100% 

0.25  0.109 0.25

 100%  56.4%

Q3. Fixed bed adsorption

From Example 2 in class (slide 13): Height of bed: H T = 14 cm   Diameter of bed: D = 4 cm 3 Flow rate = 754 cm /s At the breakpoint: c/c0 = 0.01; t b = 3.65 h Total capacity of bed: t t = 5.16 h   Usable capacity of bed: t u = 3.65 h Length used to break point: H  B = 9.9 cm Length of unused bed: H UNB = 4.1 cm On graph: A1 = 3.65 h; A2 = 1.51 h

(a) For a constant flowrate, a change in the break point time (to t b = 8.5 h) will only change the length of the column, not the diameter ( D = 4 cm).  H UNB is constant; new H  B is proportional to t b: 8.5h  H B (new)   9.9cm  23.1cm 3.65h Height of new column:  HT (new)  HUNB  H B (new)  4.1  23.1  27.2 cm  H T

 

Fraction of capacity used up to the break point: - On a plot of c/c0 vs t ,  A1 (~t b) will change with the length of the column, but  A2 will be constant (same mass transfer zone)

  c   0  1  c0  dt    A1   A2  t b,new   A2  8.5  1.51  10.01h  t b,new  8.5h

t t ,new  t u ,new t u ,new t t ,new





8.5 10.01

 0.849

(b) When the flowrate changes, the diameter need s to change to keep similar flow (velocity) and mass transfer characteristics. The length of the bed and the fraction of capacity used will change with the break point as calculated in (a): H T = 27.2 cm; t u/t t = 0.849.     For a constant flow velocity, the cross-sectional area will chan ge proportionally to the volumetric flow rate:  Anew    

4

2  Dnew 

 Dnew 

 Flow new  Flowold 

2000    754 4 2000 754

 Aold 

2  Dold 

4cm2  6.5cm

Q4. Ion-exchange column

Given:  H T   = 30.5 cm  D = 2.59 cm Mass of ion-exchange resin: 99.3 g 3

Feed flow rate: 1.37 cm /s Feed concentration: c0 = 0.18 M (0.18 mol CuSO4 / L) At the break point (t b), c/c0 = 0.010

Plotting the breakthrough data:

A1

A2

t b

t s

Break point time: from the graph, when c/c0 = 0.010, t b = 460 s

Fraction of total capacity used up to the break point: Usable capacity of the bed: -

  =  ∫ 1 −   = 

Because the break point concentration is small,

 ≅   = 460 

Total capacity of the bed: -

  =  ∫∞ 1 −   =  + 

Can be solved by integrating the area above the curve graphically or numerically Alternatively, it can be shown that ( A1+ A2) = t t  ≈ t  s, the time when c/c0 = 0.5 From the graph,

 ≅   = 645  The fraction of total bed capacity used up to break point is then:

 = 460  = 0.713  645 Length of unused bed:

 =   ⇒  = 460 645 ×30.5 = 21.75  

 =  −  ⇒   = 30.5 − 21.75 = 8.75  Saturation loading capacity of the ion-exchange resin: Amount of Cu being fed into the 99.3 g resin is equal to:

  1  × 645  ×0.18   ×63.54    = 10.106   1.37  × 1000     Saturation loading capacity of the solid:

   =  10.106  = 0.102     99.3  

Q5. Scale-up of ion-exchange column

Given: Column I:

 H T  = 0.4 m 3 Flow rate = 0.2 m /h t b = 8.0 min t u/t t  = 0.65

Column II:

t b = 13.0 min

In mass transfer zone, length of unused bed ( H UNB) is:

 = (1 − )   ( ) ⇒  = 1 − 0.65  × 0.4 = 0.14 

Length of used bed ( H  B)is:

  =     ⇒   = 0.65 × 0.4 = 0.26 

For Column II, the following relation can be applied to determine the length of used bed:

, = , ⇒   =  , × , , , , , ⇒ ,  =  0.268× 13 = 0.4225 

Total length for the column II, assuming that the length of unused bed ( H UNB) is unchanged:

,  = , +  ⇒ ,  = 0.4225 + 0.14 = 0.5625 