ion exchange - sswm · piero m.armenante njit definition of ion exchange ion exchange is the...
TRANSCRIPT
PIERO M. ARMENANTENJIT
Ion Exchange
PIERO M. ARMENANTENJIT
Definition of Ion ExchangeIon exchange is the process through which ionsin solution are transferred to a solid matrix which,in turn releases ions of a different type but of thesame polarity. In other words the ions insolutions are replaced by different ions originallypresent in the solid
PIERO M. ARMENANTENJIT
Ion Exchange as a Sorption Process• Since ion exchange occurs between a solution
and the internal surface of a solid it can beviewed as a special type of sorption process
• There are many similarities betweenadsorption and ion exchange. The twoprocesses are often analyzed using similarmodels
• Unlike adsorption ion exchange requires aninterchange of materials, i.e., the ions (asopposed to a unidirectional transfer) since theelectroneutrality of the solution must bemaintained
PIERO M. ARMENANTENJIT
Ion Exchange as a Physical Process• During ion exchange the ions being exchanged are
reversibly removed from the wastewater andtransferred to the ion exchanger
• This means that ion exchange is a physicalseparation process in which the ions exchangedare not chemically altered
• Since the chemical characteristics of the ionsexchanged are not modified the use of ionexchange in wastewater treatment is associatedwith the removal of hazardous ionic material(s)from the wastewater and its transfer to the ionexchanger
PIERO M. ARMENANTENJIT
Ion Exchange as a Physical Process(continued)
• Since the ion exchanger only collects thehazardous material the spent exchanger must betreated at the end of a cycle
• Typically this involves the regeneration of the ionexchanger by contacting the spent exchanger witha concentrated solution of an ion (such as H+ orOH-) which can replace the ions adsorbed on theexchanger during the treatment process
• This results in the generation of a spentregenerating solution containing the waste ions ina concentrated form
PIERO M. ARMENANTENJIT
Ion Exchange in Water Softening• Water softening is not a wastewater process.
However it is worth mentioning it because itconstitutes the largest application of ionexchange processes
• Water softening consists of removing divalentions, such as Ca++ or Mg++, from water (theseions result in the so-called water hardness)
• Typically these ions are removed byprecipitation at pH above 10 using the lime-soda process. This process utilizes lime toraise the pH to the desired value (thus addingCa++ ions to the water)
PIERO M. ARMENANTENJIT
Ion Exchange in Water Softening• Mg++ is typically removed as Mg(OH)2 while Ca++ is
typically precipitated by adding soda ash (Na2CO3)as calcium carbonate
• Ion exchangers can be effectively used to removethe hardness from water without raising the pH. Inthis case Na+ is exchanged for Ca++ or Mg++. Theexchanger is then regenerated with concentratedNaCl solutions
• Ion exchange, although more expensive than thelime-soda process, results in a lower concentrationof residual hardness (i.e. below the 30-50 mg/L (asCaCO3) achievable with the lime-soda process)
PIERO M. ARMENANTENJIT
Ion Exchange in Water Deionization• Ion exchangers are also used in complete
water deionization processes
• In this case both cationic and anionicexchangers are used
• Regeneration of the exchangers isaccomplished with strong acids or bases
PIERO M. ARMENANTENJIT
Ion Exchangers in the Treatment ofInorganic and Organic Wastes
• In the vast majority of cases ion exchanger areused to treat wastewaters containing inorganicwastes (i.e., inorganic ions)
• The kinetics of sorption of organic speciesfrom non-polar solvents by ion exchangers istypically unfavorable
• In addition, ion exchangers are generally notvery effective against large organic molecules,mainly because the size of the moleculeswhich dramatically reduces the exchange rate
PIERO M. ARMENANTENJIT
Ion Exchangers in the Treatment ofInorganic and Organic Wastes
(continued)• However, ion exchangers are effectively used
in the treatment of specific organiccompounds (such as phenol sorption ordecolorization of kraft paper mill effluents). Inthis case the ion exchanger does not act assuch but more as an conventional adsorbent
PIERO M. ARMENANTENJIT
Motivation for the Use of IonExchange Processes in Wastewater
TreatmentMany industrial wastewaters contain substancesthat:
• are in ionic form
• are heavy metals in a soluble form
• can be economically recovered and reused
• if removed under the form of sludge wouldproduce a hazardous material to be disposedof under RCRA
PIERO M. ARMENANTENJIT
Common Applications of Ion Exchangein Industrial Wastewater Treatment• Removal of heavy metals from electroplating
wastewaters and other industrial processes
• Polishing of wastewater before discharging
• Nitrogen control (removal of ammonium ion fromwastewaters)
• Removal of salt buildup in close-loop utility water(e.g., removal of salts from cooling water blowdown)
• Purification of acids and bases to reuse them
• Removal of radioactive contaminants in the nuclearindustry
PIERO M. ARMENANTENJIT
Examples of Ion Exchange Processesin Industrial Wastewater Treatment• Recovery of chromic acid from plating rinsewaters
• Recovery of metals from acid copper-plating andnickel-plating rinsewaters
• Recovery of metals from mixed rinsewaters
• Removal of chromates from cooling water circuits
• Recovery, purification and re-use of spent acidsfrom metal pickling and etching processes
• Removal of radioactive components from thewastewaters of nuclear power plants
PIERO M. ARMENANTENJIT
Advantages of Ion Exchange inWastewater Treatment Processes• Capability of handling and separating
components from dilute wastes
• Possibility of concentrating pollutants
• Capability of handling hazardous wastes
• Possibility of recovery expensive materialsfrom waste (e.g., precious metals)
• Possibility of regenerating ion exchanger
• Possibility of recycling components present inthe waste and/or regenerating chemicals
PIERO M. ARMENANTENJIT
Disadvantages of Ion Exchange inWastewater Treatment Processes• Limitation on the concentration in the effluent
to be treated
• In general, lack of selectivity against specifictarget ions
• Susceptibility to fouling by organic substancespresent in the wastewater
• Generation of waste as a result of ionexchanger regeneration
• Down time for regeneration
PIERO M. ARMENANTENJIT
Ion Exchange Materials• Ion exchange materials are made of organic or
inorganic matrices containing ionic functionalgroups
• Both natural ion exchange materials (zeolites)and synthetic ion exchange materials exist
• The vast majority of the ion exchangers usedin industrial wastewater treatment is ofsynthetic origin
• The most common type of synthetic ionexchange materials are organic resins
PIERO M. ARMENANTENJIT
Ion Exchange Resins• Ion exchange resins are organic compounds
polymerized to form a porous tridimensionalmatrix
• A crosslinking agent (e.g., divinylbenzene) isadded during the polymerization reaction togenerate the tridimensional structure
• The resins, in the from of spherical particles,are chemically activated by reacting thepolymer matrix with a compound capable ofintroducing the desired ion exchangefunctional group (e.g., with sulfuric acid tointroduce sulfonic groups)
PIERO M. ARMENANTENJIT
Degree of Crosslinking in IonExchange Resins
• The amount of crosslinking agent addedduring the polymerization reaction determinesthe degree of crosslinking, i.e., the number ofcarbon-carbon bonds interconnecting(crosslinking) the polymeric chains
• A high degree of crosslinking imparts a morerigid structure to the resin but reduces theporosity of the matrix and the ability of largerions to diffuse through it
PIERO M. ARMENANTENJIT
Preparation of Styrene-Divinylbenzene Cationic Exchangers
CH=CH2
CH=CH2
CH=CH2
CH - CH2-CH - CH2-CH - CH2-
- CH - CH2-
- CH - CH2-
CH - CH2-CH - CH2-CH - CH2-
- CH - CH2-
- CH - CH2-
SO3H SO3H
+Polymerization
Sulfonation
PIERO M. ARMENANTENJIT
Strong vs. Weak Ion Exchangers• Strong ion exchangers have highly ionized
functional group. As a result they may easilyexchange their H+ or OH- groups at any pH
• Weak ion exchangers, like the correspondingacids or bases, are only partially ionizedunless they are in a pH range above 7 (forweak acid cation exchangers) or below 7 (forweak basic anion exchangers)
PIERO M. ARMENANTENJIT
Functional Groups in Ion ExchangeResins
The functional groups most commonly found inion exchange resins are:
• Strongly acidic cationic exchanger:sulfonic group (R-SO3H)
• Strongly basic anionic exchanger:quaternary ammonium group (R-R3N+OH-)
• Weakly acidic cationic exchanger:carboxyl group (R-COOH)
• Weakly basic anionic exchanger:amine group (R-NH3OH)
PIERO M. ARMENANTENJIT
Ion Exchange ReactionsThe reversible reactions associated with ion exchange are:
• Strongly acidic cationic exchanger:
2 23 3 2RSO H Ca RSO Ca H+ ⇔ ++ + +b g
• Strongly basic anionic exchanger:
RR NOH SO RR N SO OH3 42
3 2 4 2' '+ ⇔ +− −d i• Weakly acidic cationic exchanger:
2 22
RCOOH Ca RCOO Ca H+ ⇔ ++ + +b g• Weakly basic anionic exchanger:
R NH OH SO R NH SO OH3 42
3 2 4 2+ ⇔ +− −b g
PIERO M. ARMENANTENJIT
Ion Exchange Reaction EquilibriumFor the general ion exchange reversible reaction:
α β α βA B A Bax x
b+ ++ ⇔ +with: α βa b=subscript x = subscript identifying the ionic
species adsorbed on the resin
the equilibrium relationship takes the form:
KA B
A B
q CC q
q C
q CB
Xb
aX
A B
A B
A A
B B
= = =+
+
α β
α β
α β
α β
α
β
b gb g
KB is called the selectivity coefficient.
PIERO M. ARMENANTENJIT
Ion Exchange Reaction Equilibrium(continued)
The selectivity coefficient KB is not a trueequilibrium constant (although often referred toas such) but depends on the experimentalconditions.
Example:
Ca H Ca HX X2 2 2+ + ++ ⇔ +
Kq C
q CB
Ca Ca
H H
=+
+
2
2
d id i
PIERO M. ARMENANTENJIT
Separation Factor in Ion ExchangeAnother "constant" often used to describe ionexchange equilibrium relationships is theseparation factor, αB, defined as:
αBA A
B B
q Cq C
=b gb g
For example:
Ca H Ca HX X2 2 2+ + ++ ⇔ +
αBCa Ca
H H
q C
q C= +
+
2d id i
PIERO M. ARMENANTENJIT
Ion Exchange Selectivity• The selectivity coefficient KB and the
separation factor αB are directly proportionalto the preference of a given ion exchange resintoward different types of ions
• For the same concentration of different ionsthe relative preference of an ion exchangerdepends primarily on two factors, i.e.:
- ionic charge
- ionic size
PIERO M. ARMENANTENJIT
Ion Exchange Selectivity (continued)• Ions with higher valence are typically preferred
by the ion exchange resin. For example atypical cationic resin has the followingpreference:
Th4+ > Al3+ > Ca2+ > Na+
Similarly, an anionic resin typically has thefollowing preference:
PO43- > SO42- > Cl-
• Exceptions are also possible as in thefollowing case:
SO42- > I- > NO3- > CrO42- > Br-
PIERO M. ARMENANTENJIT
Ion Exchange Selectivity (continued)• Among ions having the same charge, the ions
having the smallest hydrated diameter arepreferred by the resin (Remark: ions withlarger unhydrated ionic diameter tend to havesmaller hydrated diameter and are thereforepreferred)
• The resin preference for one ion over anotheris also affected by the degree of crosslinking(and hence the pore size)
PIERO M. ARMENANTENJIT
Typical Order of Ion ExchangePreference by Cationic Ion
Exchangers• Monovalent cations:
Ag+ > Cu+ > K+ > NH4+ > Na+ > H+ > Li+
• Divalent cations:
Pb2+ > Hg2+ > Ca2+ > Ni2+ > Cd2+ > Cu2+ >> Zn2+ > Fe2+ > Mg2+ > Mn2+
• Trivalent cations:
Fe3+ > Al3+
PIERO M. ARMENANTENJIT
Typical Order of Ion ExchangePreference by Anionic Ion
Exchangers
CNS- > ClO4- > I- > NO3- > Br- > CN- > HSO4- > NO2- >
> Cl- > HCO3- > CH3COO- > OH- > F-
Ion Exchange SelectivityCoefficients at 25 oC
PIERO M. ARMENANTENJIT
Equilibrium Isotherm to Describe IonExchange Equilibrium
• Instead of equilibrium models the ionexchange experimental equilibrium data of twoionic species are correlated using adsorptionequations similar to the Langmuir orFreundlich equations
• If this approach is used then additionalexperimental data are collected in test columnfrom which breakthrough curves can beobtained
PIERO M. ARMENANTENJIT
Capacity of Ion Exchangers• The capacity of an ion exchanger is the amount of
ionic species that can be exchanged per unit massof dry exchanger
• The exchange capacity is a function of the numberof available exchange sites in the resin
• The exchange capacity is commonly expressed inmilliequivalents of ionic species per gram of dryweight of ion exchange particles (meq/g)
• The capacity of most ion exchange resin is in therange 2 - 10 meq/g
• Operating factors such as pH may affect thecapacity of the exchanger
PIERO M. ARMENANTENJIT
Swelling of Ion Exchange Resins• When placed in water ion exchange resin
particles tend to swell
• The degree of swelling is affected by thedegree of crosslinking of the polymer. Morecrosslinked resin have a greater mechanicalresistance than less crosslinked resin, andtend to swell less
PIERO M. ARMENANTENJIT
Swelling of Ion Exchange Resins(continued)
• Swelling is also affected by the ions beingtaken up by the resin and their hydrateddiameter. More hydrated ions tend to make theresin swell more than less hydrated ions
• The degree of swelling can be quite significant(e.g., 50% during regeneration). Therefore, theion exchange columns should be designedaccounting for the swelling of the bed
PIERO M. ARMENANTENJIT
Types of Ion Exchange Operations
• Batch Operation
• Moving-Bed Operation
• Fixed-Bed (Column) Operation
PIERO M. ARMENANTENJIT
Ion Exchange Batch OperationThe wastewater is placed in an agitated tank andadded with the ion exchange resins. Afterequilibrium has been reached the resin is filteredand the water is discharged. The resin in nottypically regenerated
Ion Exchange Resin
SpentResin
TreatedWastewater
Contacting Separation
PIERO M. ARMENANTENJIT
Design of Ion Exchange Batch ProcessesA mass balance for an ionic pollutant in an differentialinterval, dt, during a batch operation is:
V dC K A C C dtp= − − *b gwhere: V = volume of wastewater (m3)
K = mass transfer coefficient between ion exchangeparticles and wastewater (m/s)
Ap = cumulative surface area of ion exchange particles(m2)
C = ionic pollutant concentration (g/L)
C* = concentration of ionic pollutant in equilibriumwith concentration q in the particle at time t (g/L)
PIERO M. ARMENANTENJIT
Design of Ion Exchange Batch ProcessesThe previous equation can be integrated to give:
tKa
dCC Cp
C
C
o
= −−z1 '
' '*
where: a = surface area of particles/liquid volume
This equation can be integrated if the equilibriumisotherm is known and by knowing that the massbalance at a generic time, t, is given by:
( ) ( )V C C B q qo o− = −
where: subscript "o" indicates initialconcentrations
PIERO M. ARMENANTENJIT
Design of Ion Exchange Batch ProcessesThe previous integral can be evaluatedgraphically from the following graph:
q (g solute/g carbon)
C (g
/L)
Isotherm
Co
Ceq
qeq
qo
Operating Line- B/V
C
C*
q
PIERO M. ARMENANTENJIT
Approximate Design of Ion ExchangeBatch Processes
During the initial stages of the ion exchangetransfer process it is:
C C>> *
Then:
tKa
dCC Ka
CCp
C
C
p
o
o
≅− =z1 1''
ln
This equation can be used to approximatelyestimate the time required for the pollutantconcentration in the wastewater to drop to adesired level.
PIERO M. ARMENANTENJIT
Moving-Bed Ion Exchange OperationThe resin and the wastewater are movingcountercurrently in the column. The process iscontinuous. This means that not only is thewastewater continuously fed and removed fromthe column but also that fresh resin is added andspent resin is removed. The spent resin is thenregenerated and fed back to the column
PIERO M. ARMENANTENJIT
Fixed-Bed Ion Exchange Columns• "Cocurrent" Column
• "Countercurrent" Column
• Mixed Bed Column
Remark: in any kind of fixed-bed operation with asingle phase passing through a column (e.g., awastewater over a bed of activated carbon or ionexchange resins) the terms cocurrent andcountercurrent lose their meaning. However, inion exchange operations these terms are used toindicate the direction of the regenerating solutionwith respect to that of the wastewater
PIERO M. ARMENANTENJIT
Cocurrent Fixed-Bed Ion Exchange Column• The term "cocurrent" indicates that the direction
of the flow of the regenerating solution (at theend of a cycle) is the same as that of theincoming wastewater (during normal operation)
• Cocurrent operation, although not the mostefficient, is the most common because of itssimple design and operation
• Regeneration is conducted with 1 - 5 N acid orbase solutions
• Typical column height: 0.6 - 1.5 m
• Wastewater flow rate: 8 - 40 bed volumes/hr
PIERO M. ARMENANTENJIT
Countercurrent Fixed-Bed IonExchange Column
• In these columns the regenerating solutionenters the column in a direction opposite tothat of the wastewater. This improves theefficiency of the regeneration processresulting in smaller amounts of spentregenerating solution utilized. This approachalso allows the more concentratedregenerating solution to contact the "cleaner"part of the resin first
• Special care must be pay to preventingfluidization of the resin during regeneration
PIERO M. ARMENANTENJIT
Design of Fixed-Bed Ion ExchangeProcesses
• Fixed-bed ion exchange columns have manysimilarities in common with fixed-bedadsorbers
• For example in fixed-bed ion exchangecolumns an "exchange zone" similar to theadsorption zone is formed and travels throughthe column until the breakpoint is reached
PIERO M. ARMENANTENJIT
Design of Fixed-Bed Ion ExchangeProcesses (continued)
• As a result the design of such processes canbe carried out using an approach similar tothat described to design adsorption fixed-bedcolumns
• More complex models also exist to account forthe fact that ion exchange is also associatedwith charge transport and electroneutrality
PIERO M. ARMENANTENJIT
Simplified Method for Estimation ofFixed-Bed Ion Exchange Performance
From a mass balance for the pollutant atbreakpoint it is:
q B q B Qt C CB So B o
B= = −FHGIK☺ζ
2where: qSo = saturation capacity of the ionexchanger for a specific ion
ζ = amount of pollutant adsorbed in thebed/maximum amount of pollutant that couldbe adsorbed in the bed (at full capacity)
PIERO M. ARMENANTENJIT
Simplified Method for Estimation ofFixed-Bed Ion Exchange Performance
The time required to reach breakthrough is:
t q B
Q C Cq B
Q C CBB
oB
So
oB
=−FHGIK☺
=−FHGIK☺2 2
ζ
PIERO M. ARMENANTENJIT
Two-Stage Ion Exchange Operation
Cation Exchange
Bed(B+ ions)
Anion Exchange
Bed(Y- ions)
A+ Z-
B+ Z- B+ Y-
PIERO M. ARMENANTENJIT
Ion Exchange System for ChromateRemoval and Water Reuse
After Eckenfelder, Industrial Water Pollution Control, 1989, p. 297
PIERO M. ARMENANTENJIT
Regeneration of Fixed-Bed IonExchangers
• Regeneration of ion exchangers in fixed-bedcolumns is typically conducted in place bypassing a regenerating solution (typically astrong acid or a strong base depending on thetype of ion exchanger) through the column
• Since the ion exchange reaction is reversiblethe more concentrated H+, although lesspreferred by the resin than other ions alreadyadsorbed by the resin, are able to replacethose ions thus regenerating the ion exchangebed
PIERO M. ARMENANTENJIT
Regeneration of Ion Exchangers• For example, the reversible reactions
associated with ion exchange in the presenceof a strongly acidic cationic exchanger:
( )2 23 3 2RSO H Ca RSO Ca H+ ⇔ ++ + +
can be reverted to the left (with consequentrelease of Ca++ ions) if a strong acid is passedthrough the bed
• Other concentrated solutions other than acidsor bases can be used as regeneratingsolutions (e.g., NaCl). In such a case theregenerated resin will be loaded with theresulting ion (e.g., Na+ instead of H+)
PIERO M. ARMENANTENJIT
Mixed Bed Ion Exchange Column• In this type of column two types of resin particles
(one cationic and the other anionic) are mixed andplaced in the column
• As the wastewater passes through the columnnearly complete deionization occurs
• Although the effluent from this type of column isvery pure regeneration is inefficient
• Regeneration can be carried out only afterbackwash takes place, during which the resinparticles are classified
• Air is then used to re-mix the resin particles beforeputting the column back in service
PIERO M. ARMENANTENJIT
Mixed-Bed Ion Exchange Operation
After Weber, Physicochemical Processes for Wastewater Control, 1972, p. 293
PIERO M. ARMENANTENJIT
Characteristics of Ion ExchangeColumns for Wastewater Treatment
Ion exchanger particlediameter
0.4 - 0.8 mm
Bed height 0.6 - 2.5 m (2 - 8 ft)
Height-to-diameter ratio 2 to 1
Bed expansion 25 - 50%
Hydraulic loading 1.4 - 6.8 L/m2 s(2 - 10 gpm/ft2)
After Wentz, Hazardous Waste Management, 1989, p. 158 andMetcalf and Eddy, Wastewater Engineering, 1991, p. 757
PIERO M. ARMENANTENJIT
Additional Information and Examples on IonExchange
Additional information and examples can be found in thefollowing references:
• Sundstrom, D. W. and Klei, H. E., 1979, WastewaterTreatment, Prentice Hall, Englewood Cliffs, NJ, pp.356 - 367.
• Wentz, C. W., 1989, Hazardous Waste Management,McGraw-Hill, New York, pp. 156 - 161.
• Corbitt, R. A. 1990, The Standard Handbook ofEnvironmental Engineering, McGraw-Hill, New York,pp. 6.202 - 6.208.
• Treybal, R. E., 1968, Mass Transfer Operation,McGraw-Hill, New York, pp. 490 - 568.
PIERO M. ARMENANTENJIT
Additional Information and Examples on IonExchange
• Metcalf & Eddy, 1991, Wastewater Engineering:Treatment, Disposal, and Reuse, McGraw-Hill, NewYork, pp. 740 - 741; 756 - 757.
• Weber, W. J., Jr., 1972, Physicochemical Process forWater Quality Control, Wiley-Interscience, John Wiley& Sons, New York, pp. 260 - 305.
• Freeman, H. M. (ed.), 1989, Standard Handbook ofHazardous Waste Treatment and Disposal, McGraw-Hill, New York, pp. 6.59 - 6.75.
• Eckenfelder, W. W., Jr., 1989, Industrial WaterPollution Control, McGraw-Hill, New York, pp. 291 -299.