FILTRATION
~ FACTS, FALLACIES AND FUTURES
The following article
first appeared in Splash, the official and very popular magazine
of the World Waterpark Association. It begins with fundamentals
well known by most PPOA members, but proceeds to bust a number
of popular myths that have been misleading operators since the
Romans invented filtration…
.....Filters,
everywhere in our environment, allow little stuff to pass through
and keep the big stuff out. They’re in cigarettes and coffee
pots, automobiles and air conditioners. They appear as window
screens, fish nets, and accordion-pleated rolls of paper. Filters
are so critical to the function of swimming pools and water
features that a room has been named in their honor. No matter
how important we think these appliances are, however, filters
are often assigned virtues well beyond their capabilities. It’s
important to know what they will do and what they won’t; with
reasonable expectations we can get the very most out of them
? or into them ? and leave sanitation, oxidation and other miracles
of pool care to different devices.
First, let’s look at some FACTS:
.....Obviously,
removing suspended solid material from recreational water to
make it clear and “clean” is our goal. To accomplish this particulate
removal through filtration, there are many alternatives open
to designers and builders. Sand, diatomaceous earth, cartridge
and more ? there exists a variety of types, sub-types and sizes
in the world of pool filtration even among the three major categories.
Which one should we choose?
.....There’s
been plenty of sparring for “best” between pool owners and operators
based on individual preferences and performance comparisons.
However, all three types, assuming they are of good design,
deliver effluent of equal quality. It is little more than an
intellectual exercise to debate which of them will remove the
smallest particles in terms of microns or of water clarity.
Any seasoned operator, when presented with a crystal-clear pool,
would be challenged to determine which category, much less type,
of filter was on line. She or he would have a one-in-three chance;
polished water looks like polished water, no matter how you
got it that way.
.....Of
the two most commonly used filter categories the sand system
is the easiest to understand so will be our focus here. The
specific technology called “high-rate” sand filtration ? now
gaining dominance world-wide ? will be included in most of this
conversation. Let’s first look at the concept called particulate
“entrapment”.
.....Just
what is big and what is little, in the context of water turbidity
and particle size? Good filters stop solid particles from around
5 microns to 20 microns in dimension, and all sizes larger.
(One micron, incidentally, is .00004 inches…) Here are some
interesting size comparisons in terms of known materias. Note
that a typical human hair is 70 microns in diameter and the
lower limit of human visibility is about 40 microns, so 5 or
even 20 microns is pretty tiny indeed.
ONE AVERAGE GRAIN OF TABLE SALT
100 MICRONS
HUMAN HAIR 70 MICRONS
THE LOWER LIMIT OF HUMAN VISION 40 MICRONS
WHITE BLOOD CELLS 25 MICRONS
TALCUM POWDER 10 MICRONS
AVERAGE BACTERIA 2 MICRONS
.....Turbidity,
however, is based on the density (numbers in a specified volume)
of particles even more than on particulate size. Filters must
remove virtually all of the larger material and most of the
smaller in order to render the water “sparkling clear.” (Even
then chlorine or another oxidizer must be in the equation for
that polish you’re looking for…)
Soil is captured in the sand filter bed by a combination of
two processes: First, solid particles lodge in the extremely
small spaces and voids between the sand particles and, second,
gelatinous and mucous-like substances and oils tend to cling
to the grains of filter sand. The latter, then, enhances the
mechanical effectiveness of the former, as “soil entraps soil”
and the filter efficacy actually improves over time and usage.
(In the high-rate version, this phenomenon works its way deep
into the sand bed rather than existing only on the surface ?
hence the term “three-dimensional” filtration.)
As these two dirt-collecting mechanisms work together, the filter
stores up more and more of a gelatin-and-soil-filled bed. The
filter is now extremely effective in removing suspended soil
and the resultant water quality is optimum for many days.
.....Finally,
however, the cycle comes to an end. The loaded medium becomes
increasingly dense and, ultimately, resistant to water flow.
At some point adequate flow can no longer be sustained; the
filter must be cleaned. We know the time has come because the
pressure in ? influent ? goes up, pressure out ? effluent ?
goes down (up to 15 psi differential), and the reading on the
flow meter drops ten percent or more. The cleaning process,
called backwashing, is accomplished by re-directing the water
flow backwards through the filter, generally from the bottom
up, in order to expand and scrub the sand. The entrapped soil
is thus carried out to waste in no more than about three minutes
per tank.
Valves are switched back, and a new filter cycles begins all
over again.
Now let’s expose some FABLES:
Most any sand will work in a high-rate-sand filter.
.....No.
Sand grade and grain type are very important. Crushed, angular
silica sand works well while rounded beach sand (typical of
sandblasting material) is very poor for entrapment. The sharper
the sand the more likely particles will be held while allowing
the water to pass. Filter companies are particular about the
sand sources for their filters.
The size of the sand particles serving as the filter bed is
an important consideration too. If the sand is too course, the
voids between the particles are too large to efficiently stop
the passage of fine solids. If it’s too fine, the bed will be
too dense and very little space is left for dirt to accumulate
between the sand grains. The sand particle size best for pool
filters has been established in a range of 0.4 to 0.6 millimeters,
or, in grade, number 20. Number 30, a finer sand grade, is sometimes
recommended for indoor pools when the soil volume is inadequate
to effectively load the more common grade.
It is best to change the filter’s
sand every year.
.....No.
Well cared for sand never needs changing. Backwashing does not
“wear out” sand during the brief 100 to 300 minutes per year
that sand scrubbing occurs. After all, it took nature hundreds,
even thousands of years to create and round off that sand on
the beach. Calcified or oil-laden sand may have to be replaced,
but that’s your fault, not that of the filter or the media.
If the water gets cloudy, we need
to backwash.
.....No.
Cloudy water can occur for a variety of reasons, but it’s rare
that simple backwashing will improve things. Backwashing places
the sand filter, temporarily, in its least effective mode ?
hardly a help for your cloudy water. You need to do it, but
only when you need to do it. The dirtier the filter the better,
until the filter begins to stop water. Then and only then is
when you need to backwash. Early in the new cycle the filter’s
efficacy is not optimized; it takes from a few hours to a day
or more to establish that natural “floc” of gelatinous material
and fines in order to propagate the process. Those operators
who backwash by the calendar or clock rather than by the gauges
are guaranteeing that their filters run less efficiently than
they could. Frequent, unnecessary backwashings can make sand
filters run downright poorly! Don’t backwash your filters along
with the Saturday bath; they probably don’t need it as badly
as you might.
( With indoor pools and water features, “breakthrough” of fines
is possible, requiring what appears to be premature backwashing
? where the differential was never achieved. This is unusual
and often is the result of an improper sand choice.)
If we can’t backwash at design
flows, lower values for longer periods work just fine.
.....No.
Backwashing must be done at the design flow, usually 15 gallons-per-minute
for each square foot of filter surface area. A slower rate,
for inadequate sewer lines or whatever reason, is certain to
allow conglomerated sand to develop. Also, with hair or lint
often serving as a structure, balls of organic material ? “mudballs”
in pool terminology ? will form and become imbedded in the top
layer of sand. If the backwash velocities are insufficient to
break up and wash the clumps to waste, they will work their
way deeper into the filter bed, helping to create “channels”.
Ultimately such ant-nest-like passages will permit unfiltered
water to take the path of least resistance through the medium
? and our systems fail to function.
In poorly flushed sand, living organisms can propagate, too.
This colonization of pathogens can be dangerous. Fix the waste
line or install a holding tank for backwash water so the full,
backward flow can be used to keep your sand healthy.
Iron, manganese, copper, and calcium
can be removed by filters.
.....No.
Nothing but suspended solids is removed by filtration. Suspensions
and solutions are very different. Dissolved solids like salt
and intentional calcium hardness (remember TDS?) cannot be seen
by the filter media. Iron pipes, copper heater elements, calcium
plaster and grout, impeller metal or any other affected solids,
when dissolved or “in solution”, are solids no more; essentially,
they are part of the liquid and will fly right through our filters.
Ultra-fine suspension won’t stop on its way through either;
“colored” water, otherwise transparent, is an example.
If you raise the pH accidentally to well over 8.3, you may in
fact precipitate your formerly dissolved solids. Your whole
pool will be a mess, so this is to be avoided. For the most
part, dissolved solids are invisible and harmless to your system,
your patrons and your chlorine’s work potential. Don’t expect
your filter even to notice them.
Filters stop bacteria and sanitize
water.
.....No.
There are many who confuse the filtration function with the
disinfection function. Disinfection is the chemical process
of killing disease-causing bacteria and other micro-organisms,
accomplished in the body of pool water itself. Bacteria are
generally far too small to be noticed by your filter media.
Most pathogens sail right through the sand and back to the pool.
Remember it is chlorine (or equivalent) that has the job of
sanitizing; the filter’s assignment is to remove the “big pieces”,
mostly those inorganic suspended particles that the chlorine
can’t oxidize.
Filters do remove soils that, if not removed, might impede the
sanitation effort. Those who think of filtration as part of
the disinfection process, however, because a filter may be capable
of removing some pathogens, have been misled. This removal is
not particularly beneficial, and can be a problem if relied
upon.
Cryptosporidium, a large oocyst (six to eight microns in size),
can in fact be trapped in a well-loaded filter. Recently, a
focus on filtration for crypto removal has shown up in fecal-accident
recommendations. It is not reasonable to expect the filtration
system to remove all such infestation, even in three or four
cycles. Too much of the water never sees the filter in a day,
or even two. Chlorine’s still got the primary job. (Crypto is
another conversation for another time…)
And, finally, let’s imagine Filter FUTURES:
.....Automated
and sequential backwashing, remote management, sand alternatives,
new packaging and efficient configurations have been emerging
for a while. The next step may be the intelligent breaking of
a longstanding rule: Never floc a high-rate sand filter. While
old, two-dimensional sand filters benefited from this addition
of a coagulant or other filter aid, adding alum, polymer, PAC
or another flocking agent to the three-dimensional process in
an attempt to improve output has always “blinded” the bed. The
water often looked better, at least at the very beginning hours
of a filter cycle, but too much build-up created the need for
premature backwashing. No amount of care in the trickling in
of the micro-flock avoids this problem; eventually, either too
little is added to do any good or too much collects and filtration
grinds to a stop. In every case, we lose filter cycle time,
labor, energy and water; we simply come out short. Flocking
high-rate sand is a flop.
.....But
what if we could somehow control a filter’s output qualitatively?
That’s how our chemical controllers and our thermostats do it.
Choose a desired outcome, seek it by measuring results, then
stop the feed (in this case the polymer) before problems arise.
Let’s use a turbidimeter on the filter’s effluent and trickle
in a flocking agent while we watch results! If our output is,
say, 0.3 NTU (Nephelometric Turbidity Units) and we set the
instrument ? the controller ? to 0.1 NTU, the relay remains
closed and a tiny pump feeds well-chosen polymer until the improvement
in clarity is achieved (or no more improvement is observed by
the meter). Then the feeder is shut off. The “clarity controller”
patiently waits until the clarity degrades slightly ? to a point
pre-selected to trigger feed again.
.....All
successful automation uses qualitative management rather than
quantitative, blind feed. A controller of this type will avoid
high-rate sand’s only real drawback, the marginal quality during
the beginning of each filter cycle. Such a subtle, monitored
application of filter aids may in fact make high-rate-sand filtration
better than it’s ever been before. Look for this leap in filter
technology in our filters’ collective futures… Maybe there will
be a reason to brag about one category of filter after all.
~kw
