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Ion Exchange Resins
Common
Problems with Ion Exchange Resins and How to Avoid Them
SAMCO
Ion exchange resins
are useful for many industrial water treatment and separation needs when
utilized for suitable
applications.
In these cases, the
technology can be highly efficient with relatively low cost and energy
requirements.
If they are
properly maintained, resin beds can last years before requiring replacement,
and for highly selective removal needs in process streams, ion exchange resins
can prove ideal.
Despite the many
benefits of using ion exchange
resins in the appropriate separation processes, challenging
issues can arise.
In this article, we
generally discuss a list of some “common problems with ion exchange
resins and how to avoid them,” ensuring your facility can keep one
step ahead and remain as productive as possible.
Resin fouling
When your ion
exchange treatment system begins to require more rinsing, becomes more sensitive
to temperature and flow rate variations, or exhibits a decrease in effluent
quality and operating capacity at a quicker-than-anticipated rate, fouled
resins could be to blame.
Over time, it is
natural to lose some percentage of operating ability (which varies widely
depending on the type of resin and application), but if fouling is suspected,
there can be several causes.
Some of the
most common resin foulants include:
· suspended solids such as silica, iron, and manganese, these can
be particles or colloidal
· oils and greases
· bacteria and algae
· organic substances
Once resins are
fouled, it can be difficult and risky to clean them as some of the chemical
agents and methods used in these processes can degrade the resins, making them
unusable.
In general,
caustics are used to remove foulants from anion resins, while acids or strong
reducing agents are used to remove foulants from cation resins.
Similarly,
surfactants are typically used to clean oil from fouled resins, though it is
necessary to use care in selecting a surfactant that will not itself foul the
resin, and sometimes an aggressive backwash with air scour helps.
Organic fouling is
both extremely common and can be difficult to correct, although using a brine
squeeze on anion resin at elevated temperatures may be effective.
Preventative
strategies for organic fouling include prechlorination and clarification,
activated carbon filtration, applying a multistep IX with weak and strong base
resins, and use of specialty IX resins.
Generally, the best
way to avoid resin fouling is to ensure proper pretreatment removes
the foulants before they can become an issue in addition to using appropriate
cleaning, storage, and regeneration measures in the day-to-day
operation of the ion exchange system to make sure no problematic foulants will
accumulate over time.
These procedures
vary widely depending on the type of resin being used as well as the purity of
the feed water, etc., so be sure to consult your water treatment specialist to
learn the proper steps to keeping your
resins suitably maintained.
Oxidation
When present in a
feed stream, oxidants degrade IX resin polymers, causing them to deform
and compact over time.
This compaction
obstructs the flow of liquids through the resin bed, which can compromise the
overall effectiveness of the IX unit, and lead to inconsistent effluent quality
due to channeling in the resin bed.
While oxidation
damage to IX resins cannot be reversed, it can be prevented through
various pretreatment measures.
Common preventative
measures for oxidation degradation include application of activated carbon
filtration, ultraviolet irradiation, or chemical pretreatment through the
application of a reducing agent.
Oftentimes, the
resin manufacturer will have specific guidelines on which resins work best in
certain environments.
Some resins are
built to withstand these degenerative chemicals at certain levels (i.e., higher
crosslinked cation resins in higher concentrations of chlorine), but in
general, it is best to consult with your water treatment specialist and resin
manufacturer regarding the maximum temperature and oxidizing agent exposure as certain
combinations of chemicals and resins can result in potentially harmful byproducts,
such as ammonia or nitrogen gas.
Thermal resin degradation
Extremely high or
low temperatures can permanently compromise the effectiveness of IX
resins.
Over time, thermal
degradation alters the resin’s molecular structure such that it is no longer able
to bind with the functional groups of ions that are key to the IX reaction,
resulting in compromised operational performance and shorter product life.
IX resin capacity
has an inverse relationship with temperature, so it is important to
consider the recommended operational temperatures and other process conditions
to minimize thermal degradation over time.
Generally speaking,
cation resins are more resistant to thermal degradation than are anion resins,
though both can generally withstand brief applications of high heat for
occasional sterilization or other purposes.
While prolonged
exposure to extreme temperatures usually means a shorter useable life for IX
resins, in some cases the costs of more frequent resin replacement may still
not outweigh the costs of energy and equipment needed for temperature control.
Inadequate regeneration
Suboptimal IX
system function can result when regenerant solutions are administered
incorrectly. Sometimes regeneration methods yield varying results, even when
they are implemented with the same procedure.
Resin regeneration
is a complex calculation, and the outcome often depends on the overall resin
condition, regeneration process water quality, regenerant chemical
concentration, flow rate, temperature, and contact time, to name a few.
Both cation and
anion resin can be scaled from improper regeneration.
For example,
regenerating with a too-high concentration of sulfuric acid can cause calcium
sulfate scale on the resin.
With some anion
resins, silica can precipitate with improper caustic concentrations.
With all the
possible scenarios, following the resin manufacturer’s guidelines for
regenerant concentration, application time, and flow control can help prevent
issues and is advisable.
Channeling
Channeling can be
caused by incorrect flow rates, failure of the distributor mechanism, inadequate
backwashing, and blockages by dissolved solids or damaged resin beads.
Resin loss or migration
Resin loss occurs
when resin beads flow out of an IX column, or flow from one vessel to another.
There are multiple
causes for resin loss, including excessive backwashing and mechanical failures
in underdrain screening or other resin retention equipment.
Resin loss may also
result from fragmentation of resin beads due to exposure to high temperatures,
chlorine, and/or osmotic shock, allowing the resin particles to pass through
even intact retention screens.
Resin loss and
migration reduces overall system capacity and efficiency.
In demineralization
systems, for example, the migration of cation resin into the anion
unit can result in sodium leakage and excess rinse time.
How SAMCO can help
SAMCO has over 40
years’ experience custom-designing and manufacturing
ion exchange systems and providing ion exchange resins for a
range of industries and solutions, so please feel free to reach out to us
with your questions. Some of our most innovative solutions come in the form of
the various resin technologies we offer. Our resins cab be extremely effective
in the removal of hardness, alkalinity, chloride, mercury, and organics,
to name a few.
We are also the
Northeast licensed distributor of AMBERPACK™ and UPCORE™ technologies by The
Dow Chemical Company (formerly Rohm and Haas). These are two of the most
advanced ion exchange systems available today.
For more
information or to get in touch, contact us here to
set up a consultation with an engineer or request a quote. We can
walk you through the steps for developing the proper solution and realistic
cost for your ion exchange
treatment system and resin needs.
To learn more about
SAMCO’s innovative technologies and services, visit our innovations
page here.
At
SAMCO, we anticipate the needs of industry, and respond with forward-thinking
solutions. Our focus on industrial applications began in 1987 with the founding
of Northeast equipment supplier and systems servicer CS Kimeric. Acquired from
a Western New York soft water provider with over 30 years in the business, CS
Kimeric was established to provide specialized service for industrial
applications. Over the course of the next decade, it became clear that
industrial clients would benefit from working with a partner capable of
delivering comprehensive, concept-to-completion solutions. In 1998, founder and
CEO Richard Posa established SAMCO as an integrated provider of design,
fabrication, startup, and maintenance services.
Today,
SAMCO serves the process water needs of clients across the nation and globe
from its headquarters in Buffalo, New York. Leveraging the collective skills of
experienced chemical, civil, environmental, electrical, mechanical and process
engineers, chemists, and skilled tradesmen, SAMCO blends a culture of teamwork,
commitment and passion to help solve your unique industrial water treatment
needs.
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