Ion Exchange Softening 1
by
technolab-lab-el-bahaa group
general.dr
bahaa badr
water treatment consultant
01229834104
Ion Exchange Softening
Ion-exchange is used extensively in small water systems and individual homes.
Ion-exchange
resin, (zeolite) exchanges one ion from the water being treated for another ion that is in the resin
(sodium is one component of softening salt, with chlorine being the other).
Zeolite resin
exchanges sodium for calcium and magnesium.
The following chemical reactions show the
exchange process, where X represents zeolite, the exchange material.
Removal of carbonate hardness:
Ca(HCO3)
2 + Na2
X ------> CaX + 2NaHCO3
Mg(HCO3)
2 + Na2
X ------> MgX + 2NaHCO3
Removal of non-carbonate hardness:
CaSO4 + Na2
X ----- > CaX + Na2
SO4
CaCl2 + Na2
X ------> CaX + CaCl2
MgSO4 + Na2
X ------> MgX + Na2
SO4
MgCL2 + Na2
X ------> MgX + 2NaC1
These reactions represent cation exchange, the exchange of positive ions. To replenish the
sodium ions used, units need to be regenerated with material containing high amounts of sodium,
normally salt brine. This allows the resin to be reused many times.
Ion-exchange does not alter the water’s pH or alkalinity. However, the stability of the water is
altered due to the removal of calcium and magnesium and an increase in dissolved solids. For
each ppm of calcium removed and replaced by sodium, total dissolved solids increase by 0.15
ppm. For each ppm of magnesium removed and replaced by sodium, total dissolved solids
increase by 0.88 ppm.
Measurements used to express water hardness in ion-exchange differ from units used in limesoda softening. Hardness is expressed as grains per gallon rather than mg/l of calcium carbonate.
1 grain/gallon 17.12 mg/l
If water contains 10 grains of hardness, would hardness be expressed 171.2 mg/l?
10 grains x 17.12 mg/l / grain
= 171.2 mg/l of hardness Ion Exchange Softening 2
ADVANTAGES OF ION-EXCHANGE SOFTENING
Compared with lime-soda ash softening, ion-exchange has certain advantages. It is compact and
has a low capital cost. The chemicals used are safer for the operator to handle and operation is
much easier. It can be almost totally automated. Because resins have the ability to remove all
hardness from the water, treated water must be blended with water that has been by-passed
around the softener (or adjustments made) to obtain a hardness level the operator needs to
maintain.
Many systems have found ion-exchange to be the most cost effective way to produce quality
water for their customers. If zeolite units are used to soften surface water, it must be preceded by
surface water treatment.
EQUIPMENT AND OPERATION
Ion-Exchange Resins
Natural green sand called glauconite has very good exchange capabilities and was once widely
used. Synthetic zeolites, known as polystyrene resins, are most commonly used now. Cost is
reasonable, and it is easy to control the quality of the resin. They also have much higher ion
exchange capacities than the natural material.
The ability of the resin to remove hardness from the water is related to the volume of resin in the
tank. Softeners should remove about 50,000 grains of hardness per cubic foot of resin. Resins
hold hardness ions until they are regenerated with a salt brine solution. The hardness ions are
exchanged for sodium ions in the salt brine.
Example:
If water contains 10 grains per gallon of hardness, how many gallons of water would the resin
remove? The tank holds 500 cubic feet of resin with capability of removing 45,000 grains per
gallon per cubic foot.
Gallons = cubic feet x grains per cubic foot
grains per gallon
= 500 cubic feet x 45,000 grains/cubic foot
10 grains per gallon
= 22,500,000 grains
10 grains/gallon
= 2,250,000 gallons before requiring regeneration Ion Exchange Softening 3
Ion-Exchange Units
These units resemble pressure filters. The interior is generally treated to protect the tank against
corrosion from the salt. The units are normally of the downflow type, and the size and volume of
the units are dictated by the hardness of the water and the volume of treated water needed to be
produced between each regeneration cycle. Resin is supported by an underdrain system that
removes the treated water and distributes brine evenly during regeneration. Minimum depth of
resin should be no less than 24 inches above the underdrain. Ion Exchange Softening 4
Salt Storage
Salt is stored as a brine, ready to be used for regeneration of the resin. The amount of salt needed
ranges from 0.25 to 0.45 pounds for every 1,000 grains of hardness removed. The tank should be
coated with a salt-resistant material to prevent corrosion of the tank walls.
Salts need to meet the AWWA or NSF
standards for sodium chloride. Rock or
pellet salt is the best for preparing brine
and road salt is not acceptable, due to the
dirt that it contains.
Salt storage tanks should be covered to
prevent contamination. A raised curb
should be provided at each access hatch to
prevent contamination by flood water or
rain.
Filling a salt storage tank with water first
and then adding salt is the preferred
method for making brine. The brine is
heavier than water and settles to the
bottom of the tank. The brine is usually
pumped from the tank to the ion-exchange
units. When making brine, water must be
added through an air gap to avoid back
siphonage of the brine to the water system.
Brine Feeding Equipment
Concentrated brine contains approximately 25 percent salt. The brine should be diluted to about
10 percent before added to the softener. It is generally injected with a venturi or a metering
pump. Solubility of salt decreases with a rise in temperature, which forces salt out of solution.
Water that remains after the salt has separated out of the solution is subject to freezing.
Therefore, brine piping should be protected from cold temperatures.
Devices for Blending
A properly operated ion-exchange unit produces water with zero hardness, but with high
corrosivity. Since a total hardness of 85 to 100 mg/l is the most desirable, treated water from the
ion-exchange unit is generally blended with source water to raise hardness in the finished water.
Blending is normally accomplished by metering both the effluent from the softener and added
raw water. Meters are installed in both lines so that the operator can adjust and monitor the
blend. Ion Exchange Softening 5
Softening Cycle
The length of the softening cycle ends when 1 to 5 mg/l of hardness is detected in the effluent
(loading rates for synthetic resins are in the area of 10 to 15 gpm/square foot of media surface
area). Almost all softening units have an alarm on the water meter to indicate when a certain
amount of water has passed through the exchange unit.
Backwash Cycle
Once hardness breaks through, the softener must be regenerated. In down-flow units, the resin
must first be backwashed to loosen the resin (it becomes compacted by the weight of the water),
and to remove any other material that has been filtered out of the water by the resin. The
backwash rate is normally 6 to 8 gpm/square foot of zeolite bed area. The operator needs to
apply enough backwash water to expand the resin bed by about 50 percent. The backwash water
is usually discharged to a box containing orifice plates that measure the flow rate. Distributors at
the top of the unit provide for uniform water distribution and uniform wash-water collection.
Underdrains provide uniform distribution of the backwash water on the bottom of the resin.
Regeneration
Concentrated brine is pumped to the unit from the storage basin. Brine is diluted through the
injector to a solution containing about 10 percent salt before it is passed through the resin. The
time required for regeneration is about 20 to 35 minutes. The flow rate of brine through the resin
is measured in gallons per minute per cubic foot of media. The brine needs to be in contact with
the resin long enough to allow for complete exchange of hardness ions on the resin with sodium
ions in the brine. It is better to allow too much time than to not allow enough. If the resin is not
totally recharged, the next softening run will be short.
Rinse Cycle
The rinse cycle removes remaining brine from the tank. The total amount of rinse water needed
is 20 to 35 gallons per cubic foot of resin. The rinse is started at a slow rate (-2 gpm/square foot
of surface area-) and continues until the chloride concentration of the effluent (which should be
monitored frequently) is quite low.
Disposal of Brine
The volume of brine used during a regeneration cycle, (together with the rinse water that
follows) varies from 1.5 to 7 percent of the amount of water softened by the unit. The chloride
concentration in this wastewater could be as high as 35,000 to 45,000 mg/l. Chlorides will upset
a wastewater treatment plant, and disposal methods have to comply with Minnesota Pollution
Control Agency requirements. Ion Exchange Softening 6
Resin Breakdown
Synthetic resins normally last 15 to 20 years, but certain conditions can cause resin to breakdown
earlier. Oxidation by chlorine is probably the most common cause of resin breakdown. When
chlorine is used to oxidize iron in the water, the chlorine should be removed before ion
exchange.
Iron Fouling
Iron will significantly affect the ability of resins to remove hardness ions. Ferrous iron can be
oxidized during softening and precipitate out as iron oxide on the resin, and no amount of brine
will remove the iron fouling. If iron oxide is formed before ion exchange unit, it can be filtered
out by the resin and removed during the backwashing of the unit. Normally if the iron
concentration in the source water is high, iron removal is provided ahead of the exchange unit to
prevent fouling of the unit.
Suspended Material
Turbidity, organic chemicals, and bacterial slimes resins resulting in the loss of some of the resin
exchange capacity. The best solution is to remove of the suspended matter with coagulation,
sedimentation, and filtration before the softening process.
Unstable Water
Water that has been softened by ion exchange will be corrosive and should be stabilized to
prevent corrosion from taking place in the distribution system. Blending with raw water or
adding phosphates or other chemicals to reduce the corrosivity of the water.
TESTING
Testing should include total hardness of raw and treated water, chloride concentration in the
rinse water, and Langelier Index (pH of stability [pHs] - pH measured). If the Langelier Index is
positive, a calcium scale will tend to coat the pipes in the distribution system. If the Langelier
Index is negative, the water will tend to be corrosive.