Plaster Pool Stains

Years after the start-up is finished, changing water conditions can still damage and stain plaster in some surprising ways.

Gary Gripp’s story begins like so many others.

“I’d been servicing pools in this area for over 15 years when it happened,” says the service manager at Anderson Poolworks in Portland, Ore. Gripp and his team had been hired to drain, clean and refill a gunite pool, and everything seemed to have gone right. “When we left the job site, that plaster was clean as new, and the water was sparkling clear,” he says.

But the next afternoon, the customer called again, complaining that the pool’s water was grayish.

Gripp was hurrying back to the job site when he answered another call from the same customer, the water had now turned a pale shade of lavender.

“And by the next day,” he says, “the water was this beautiful deep purple — like a jewel. I wouldn’t have even guessed water could turn that color.”

The culprit, Gripp discovered, was manganese, a metal known to lend a distinctive range of tints to water: Grayish at lower concentrations, up through brighter shades of purple at higher ones. The real question was, why had manganese suddenly become such a problem for this pool?

“When we tested the fill water, we found that the manganese levels coming out of the tap were just about off the scale,” Gripp says. Luckily, he’d managed to pinpoint the problem before the manganese stained the plaster, and was able to bring the water back into balance with a sequestering agent.

Still, Gripp says he learned something crucial from the experience. “No matter how long I’ve been working on a pool,” he says, “I don’t assume anything anymore. I test the fill water on every visit, sometimes even multiple times. Your chemistry could be perfect, but until you test your makeup water you never know what it could be depositing into the system.”

As builders and service technicians around the country have confirmed, balanced water chemistry is a science — and, in its own way, an art — that reaches well beyond the start-up. Even years down the road, calcium hardness, total alkalinity, pH and other factors can shift dramatically, sometimes in a single day.

Even so, a little preparation and a lot of thoroughness can help stop these problems before they damage the plaster.

Chemical crawl

 
 

Changing water chemistry can seem to sneak up on you. Its effects, however, are often — though not always — the results of conditions that have been building up for some time.

Take metals, for example: Their level in the water can gradually rise due to a variety of factors. In dry or windy areas, evaporation removes water but leaves dissolved solids (including metals) behind, significantly raising the water’s total dissolved solids over time. If someone’s been adding a copper algaecide without testing the level regularly, the water’s copper level can rise even more quickly.

Metal deposits inside pipes can be harder to detect, and they often accumulate for years before leading to a problem. “At every pool I’ve seen that’s been around for a few years,” Gripp says, “you can cut a pipe open — even a PVC pipe — and see a deposit of some kind in there. It may be clear and slick, but something always accumulates.”

Most pool water contains some amount of dissolved metals, but these are typically harmless, and invisible to the naked eye. Nevertheless, a variety of common chemical reactions — such as the breakdown of hypochlorous acid under UV radiation and the electrolysis of saltwater in a chlorine generator — increase the water’s concentration of “free” oxygen, the form necessary for oxidation to occur.

The more free oxygen that becomes available, the more metals in the water begin to oxidize — that is, they bond with the free oxygen, which converts them into oxides. Oxidization causes the metals to precipitate out (or fall out) of solution and become visible as a tint in the water. The longer this oxidation reaction is allowed to continue, the greater the risk that the metal oxide will stain the plaster — and eventually be absorbed by its surface.

This is most common with copper, particularly in areas that experience severe storms or droughts, like the Gulf states, says Jana Auringer, owner of The Pool Lady in Coppell, Texas. Auringer travels the Southwest as a consultant, tracking down the sources of plaster stains. She says copper’s telltale pale green tint often appears in pools that experienced no staining issues prior to a bout of harsh weather, and it’s usually traceable to a chemical change in the pool’s fill water.

“[After a storm or drought], we’re finding higher levels of copper in the source water when we test it,” she says. “A lot of times, though, the metal won’t show up on water tests, because it’s already precipitated out and stained the plaster.”

Sudden shifts

 

Stains and other plaster issues don’t always sneak up so gradually, though. As Gripp discovered with his purple pool, water’s composition can seem to change dramatically in just a few days. Sometimes, water whose chemistry has remained stable for years will suddenly display a sharp drop in calcium hardness or total alkalinity. In those cases, servicepeople say, it’s probably not the same water at all.

Across the country, builders and service pros confirm that municipal water circulation has become more complex over the past few years. These days, the water that flows from a tap is a mixture of water from wells, rivers, reservoirs and storage tanks, and the proportion of water drawn from each source may vary from day to day.

Lance Sada became so frustrated by the seemingly random water chemistry he encountered on his route that he performed his own chemical survey. Using a series of brand-new test kits, the owner of A Clear Choice Pool and Spa Service in Sun City, Calif., tested the water up and down residential blocks in his area. “I found that from one street to another, the water’s calcium hardness might be as low as 20 ppm, or as high as 200,” he says. “Sometimes, the hardness from a single tap varied by 100 ppm from one day to the next.”

In cases like these, the most effective way to prevent problems is to test the pool’s fill water on every visit, before adding any chemicals. But in other situations, the source water itself is less of a problem than what it dredges up.

“Some customers get an accumulation of metal deposits in the bottom of their well,” Gripp says. “When you kick that well on, an abundance of iron, copper, manganese — whatever accumulated in that well source — will come flying into the pool during the initial burst of water.”

Pools that sit idle for the winter tend to display similar symptoms when the weather heats up. “If you shut a pool down for a period of time and you don’t empty the chlorinator, or run the chlorine off beforehand,” Gripp says, “that chlorine’s chewing away at the copper or iron inside the pipes.” When you turn such a system on, it may kick a cloud of metal oxides into the water, and create stains on the plaster.

Perhaps strangest of all, some stains only appear after a plaster surface has been freshly cleaned. “A degraded surface sometimes doesn’t attract stains because it’s so heavily scaled, or has some type of mineral coating on it,” Gripp explains. “And when you resurface it, you might find that your water chemistry looks fine, but all of a sudden you get a stain around the return.” Those stains are most likely metal oxides, to which the plaster’s exposed surface is suddenly vulnerable.

Even if you’re anticipating unpleasant surprises like these, they can’t always be avoided. If you start investigating as soon as you notice discoloration, though, it’s often possible to prevent a metal oxide from becoming a permanent plaster stain.

Getting proactive

 
 

Diagnosing the source of a discoloration takes a lot more than educated guesswork. Each pool’s chemical conditions are unique. Manganese, for instance, can appear as a gray, black, lavender or purple stain, depending on the chemistry of the surrounding water. A high TDS reading may point to an excessive level of contaminants, or it might mean you’re adding too much of a particular chemical — or any number of other issues. That’s why it’s crucial to pinpoint the problem’s origin, then confirm it with multiple tests, before you start any treatment.

To become a master of plaster problem-solving, you’ll need to focus on two related skills: Investigating all factors that affect the system, and confirming test results before starting to treat the issue.

The first skill, though it might seem overwhelming at first, is mostly a matter of knowing what questions to ask the customer, and listening carefully to the answers.

“You’ll need to get some background on when the owner first started seeing the discoloration,” Auringer says. “Was it after a heavy rain? After shocking the pool? After a new type of algae treatment? Try to find some change in circumstances to tie the problem to.”

It may also be helpful to find out if any equipment has been replaced, and ask to see the house’s plumbing to check if water has been running through old copper or iron piping. It’s also important to understand the history of the pool’s maintenance regimen, who’s been working on the pool, and what’s been added to the water over time. This can often lead to surprising (and useful) answers.

“It might sound like a lot,” Gripp says, “but if you take every pool on a case-by-case basis, you can find out everything you need to know in a 10-minute conversation.”

The second skill is also somewhat of a matter of instinct, but it too can be boiled down to some basic principles. Techs agree that you’re doing yourself a favor by testing on every visit, in more than one spot in the pool, and by testing source water regularly.

“Always start with a clean slate, and test the tap water first,” Gripp says. In fact, the first time he visits a site, he runs through every single test in his kit. “We also use the separate tests for manganese, iron, copper, phosphates and — if it’s applicable — salinity,” he adds.

Testing the water at several spots around the pool, then averaging the results, can help prevent inaccurate readings due to dead spots or other circulation problems. “Every time I’ve tested multiple spots in a pool,” Gripp explains, “there are significant pH, alkalinity and chlorine differences between them.”

Garrett and Gripp both recommend holding onto your results from the source water, and comparing them against your test results from around the pool for confirmation. “When you go to the doctor,” Garrett says, “he’s always going to check your blood pressure, pulse, temperature and so on, because that gives him a baseline reading to know if there’s anything else wrong with you. It’s no different for pool chemistry: You need to establish a baseline before you know what you need to adjust.”

Finally, before acting on your test results, it’s important to confirm them with other testing methods. At the very least, your test kit should be calibrated against a set of chemical standards, which are usually sold by the kit’s manufacturer. You can also ensure the accuracy of your results by confirming them against another type of test, such as an electronic meter or test strip.

“And that makes you so much more confident when you speak to the homeowner,” Gripp says, “because you can show them the results of multiple tests that all confirm each other.”

Source: Ben Thomas- Pool and Spa News | 2.11.2011

Perfect Water Balance

To effectively preserve the pool’s plaster life, techs must recognize common mistakes in calculating balanced water.

Since   the 1960s, the pool industry has relied on the Langelier Saturation Index to   achieve balanced water. The traditional method has been to land right at 0.0   of an SI with an allowable variance in either direction. But the subtleties   of pool chemistry call for both a studied approach and a modified SI range.

Over   the years, experts have seen two things: mistakes in calculating SI and a   need for the Index itself to be adjusted. Here, we examine some common errors   techs make in calculating each component of the Index, as well as the   advantages of skewing SI balance toward a positive number.
Balanced water will go a long way in preserving the life of the plaster and   the clarity of the pool.

pH
Measuring pH is the least problematic portion of the SI. There are no   conversions necessary since the pH level is actually the number you’re using   to compute SI. Just be aware of anything introduced to the pool that may have   an affect on the pH.

The   most obvious pH changes will be the result of introducing sanitizers into the   pool. Acidic sanitizers like trichlor and dichlor will lower the pH. However,   you should be cognizant of CO2 loss, which can be especially dramatic in   spas.

“People   forget that when you turn the aerator on … immediately the pH goes up,” says   Joan Vienot, owner of Pool Pal Inc. in Freeport, Fla.

It’s   best to tabulate the water balance in a spa after the unit has already been   used in order to account for these changes, she adds.

Alkalinity
As most techs know, alkalinity refers to the pool’s ability to buffer the   water against pH change. When calculating the Saturation Index, however, we   are only interested in alkalinity’s ability to keep calcium carbonate in   solution.

To   calculate the correct SI factor, techs must isolate carbonate (or, in   actuality, bicarbonate) alkalinity from the pool’s total alkalinity.

Though   a host of buffers contribute to total alkalinity, carbonates and cyanurates   make up the majority of alkalinity in most pools. This is particularly true   in pools that are sanitized with dichlor or trichlor, which continually feed   cyanuric acid in the vessel.

In   order to isolate carbonate- from cyanurate alkalinity, experts generally   recommend taking a third of the cyanuric acid level from the total alkalinity   reading. For example, at a pH of 7.5, a pool with 90 ppm of CYA would have   approximately 30 ppm of cyanurate alkalinity, which you would have to   subtract from the total alkalinity reading to find the necessary SI factor.   Note that cyanurate levels at a higher pH will be more than a third of the   cyanuric acid level.

But   remember, isolating the carbonate alkalinity is not correcting any kind of   interference. The cyanurate is still buffering against pH bounce.

“There   are people applying that ‘correction’ to the alkalinity even when they’re   reporting total alkalinity,” says Que Hales, a manager for Pool Chlor   in Tucson, Ariz.

This   mistake is especially troublesome because every time cyanuric acid is added   to the pool — whether directly or through stabilized sanitizers — carbonate   alkalinity actually is being transformed into cyanurates. Even with the rapid   transformation of bicarbonates to cyanurates, the total alkalinity should   remain a relatively stable pH buffer.

TDS
—or in some cases 1,500 ppm — in the water. However, these tables were   largely put together before salt-chlorine pools became popular.

With   salt levels of 3,500 ppm, many pools with chlorine generators have from   4,000- to 5,000 of TDS in them. In these cases, even using the 12.2 number is   hardly being accurate. Your water is much more corrosive than you may think.

“If   everyone will use 12.4 for the TDS factor, then the corrosive effect of the   salinity will be accounted for,” Vienot says.

While   Vienot uses a standard value of 12.4, chemist John Wojtowicz published an   equation in 2001 to explain the changing SI values as the TDS rose over 2,000   and above. As demonstrated by the chart, a normal   salt pool will be improperly balanced if a tech uses a 12.1 or 12.2 constant.

Calcium hardness
The calcium component of saturation chemistry is often misunderstood. The   actual contributing factor to saturation issues is the amount of calcium in   the water. Calcium test kits give that value. However, some industry test   methods give total harness instead, which includes calcium but also other   components. To correctly calculate saturation values, use a calcium hardness   rather than a total hardness kit.

Although   the calcium hardness level is a direct indication of how much calcium is   available in the water to fall out of solution, it is not the primary   indicator of whether calcium actually will precipitate. pH is the primary   factor, with alkalinity in second place.

And   although lower calcium levels do limit the amount of precipitate that can be   formed, you can’t go overboard and maintain too little calcium.

“If   you don’t have calcium added to water, it’s going to leech the calcium out of   that system,” explains Greg Garrett, technical advisor for the National Plasterer’s Council in Port Charlotte, Fla.

This   is especially true of newly plastered pools that have not had adequate time   for internal cement compound transformation, he adds.

Temperature
Temperature is as straight-forward as pH, but perhaps because of its relative   simplicity, many techs don’t pay attention to the seasonal differences in   pool and spa maintenance.

Temperature   is key to the SI because as the water heats up, calcium becomes much less   soluble. This is why pools can deteriorate over the off-season and many spas   are ridden with scaling problems in the summer.

“A   perfectly balanced pool in the summer may be very corrosive in the winter,”   Vienot says. “In spas is probably where you get the most common water balance   problems. If you balance them for cold water and then heat them up 60 degrees,   you’ve got some real problems.”

Even   if all the other SI factors are within an accepted range, an unaccounted for   temperature can quickly tip the water’s balance.

Proof positive
The NPC’s new start-up guide is now recommending an ideal range of all   positive indices for maintaining pools and spas. This approach is to ensure   that the calcium in the pool plaster is not etched out into the water.

“Why   tolerate negative indices, which indicates the water is under saturated by   [at least] one parameter?” Garrett says.

Even   APSP’s recommendations call for an ideal range of 0.0 to +0.5, with an   allowable variance on the negative side.

Service   techs generally agree.

“With   most pools, we intentionally ride the Saturation Index a little bit toward the   positive side to where, if something goes wrong, we’re more likely to scale   it than we are to etch it,” Hales says.

However,   some pools — those with exposed aggregate, water features that continually   raise pH through aeration or sanitizers that require constant adjustment —   may need the full range of the “neutral zone” of -0.3 to +0.5, he adds.

Source: John Miles- Pool and Spa News | 2.13.2009

Media Matters

Selecting the right filter media for a particular pool can save time and maintenance headaches down the road.

 

Water   clarity is a crucial aspect of pool maintenance, whether a job site involves   a small family pool or a huge commercial vessel.

But experts agree that there’s no “magic bullet” when it comes to filter   media — each type has its ups and downs, and is ideally suited for some   situations while potentially disastrous in others.

Here, veteran service technicians and scientists share their perspectives on   selecting filter media, and walk through the process of assessing a pool’s   filtration needs.

Sand
As many service techs know, sand is the oldest type of filter media in the   pool industry — but what’s less well known is that it’s the oldest filter   media in human history, dating back to the baths of ancient Egypt.

Like many tried-and-true technologies, sand filtration works as well as ever   in a limited range of circumstances — but as today’s pool circulation systems   have grown more complex, and filtration expectations more stringent, it’s no   longer the most efficient option available.

Still, sand is widely used in commercial pool systems — particularly those   with relatively slow circulation rates. In the 1950s, when the pool industry   was still in its infancy, many public pools used rapid-rate sand filters,   which filtered water through a bed of sand with a gravel substrate. This   system was soon made obsolete by high-rate sand filtration, which uses much   smaller sand particles and no gravel. Thus, most of today’s “sand filters”   are more precisely termed “high-rate sand filters.”

These filters typically use sand particles between 0.018 in. and 0.022 in. In   size — often called “#20 standard silica sand” — though some operators   substitute other media such as zeolite, or a mixture of crushed glass and   gravel. Material at this level of fineness can usually entrap particles   between 20 and 100 microns in size.

This might sound tiny, but sand actually misses many particles that would be   caught by more modern filters.

Operators who choose sand filtration are often motivated by the desire to   keep costs down, or simply by the knowledge that the pool’s bather load isn’t   particularly high. In some cases, this is a sensible decision.
However, a sand filter can bring along other costs that might not be as   obvious. As the top bed becomes caked over with debris, its sand will   sometimes start to form vertical channels, experts explain. These channels   can reduce the area where optimal filtration is taking place because the   water is mostly flowing through the channels that have formed, instead of   diffusing evenly through the filtration media.

Another inconvenience of sand filters is that they must be backwashed   frequently — the exact timing varies according to factors such as bather load   and flow rate, but most systems require a backwash approximately once per   month. In addition, the effectiveness of a sand filter can drop drastically   if the sand isn’t replaced at least once every five years. This process can   get fairly involved — it entails scooping large amounts of sand out of the   filter, finding a place to dispose of the material, then refilling the filter   with an even layer of clean new sand.

In short, sand filters are best suited for applications where low cost is a   top consideration, bather loads are fairly limited, and yearly “refreshes”   are acceptable to both the site operator and the service tech.

 
A   traditional sand filter is composed of a large central chamber — filled with   sand and/or gravel — through which water is circulated. A diatomaceous earth   filter’s overall design is similar, but its central chamber is more cylindrical,   and is filled with grids specially designed to be coated with DE.

Diatomaceous Earth
A significant step up from sand in several ways, diatomaceous earth (DE) is   composed of the skeletons of microscopic prehistoric organisms. The complex   structure of these skeletons results in much finer filtration — down in the   range of 3 to 5 microns — than #20 sand can achieve. This fine texture,   combined with high permissible flow rates, has made DE the filter media of   choice for many of today’s service technicians.

This effectiveness comes with a price, though. First, DE is toxic to humans,   which means it’s crucial to wear facial protection to prevent anyone from   accidentally inhaling or swallowing the substance. Care must also be taken to   ensure that the powder doesn’t contaminate nearby chemicals or equipment,   where it can cause corrosion or other unwanted reactions.

Because of concerns like these, many cities and counties also have   regulations against disposing of used DE in the street, or even down public   wastewater lines.

These restrictions have led many techs to develop workarounds. Supporters of   DE recommend disposing of used media in the customer’s yard (after securing   permission, of course) where it acts as a fertilizer for plants. Another   option is to use catch basins, which allow water to drain away from the DE,   which can then be thrown into the trash.

Still, cleanup and disposal of DE can be nearly as messy as cleaning a sand   filter — or, in a way, even more so, given the media’s toxic nature. And DE   filter’s require more backwashing, experts say.

DE is ideally suited for pools with high bather loads where pristine water is   a major priority. Maintenance won’t be a cinch by any means, but proper care   will ensure effective filtration of most particles, even at high flow rates   and temperatures.

Cartridge
A major leap forward in filtration technology came with the development of   cartridge filters. Rather than using a chamber filled with loose filter   media, these filters strain water through a compact array of pleats that   catch particles down in the range of 5 to 10 microns in size — about a third   the width of a human hair.

Though they don’t catch particles quite as tiny as those caught by DE   filters, cartridge filters are more efficient, especially in pools with   relatively low bather loads and flow rates. In these conditions, a cartridge   filter with a footprint of a few square feet can filter a volume of water in   the range of 500 square feet; far more than a sand filter of the same size.

Techs also report that these filters tend to be resistant to breakdowns and   serious clogs, and are much easier to clean than sand filters.

And unlike sand and DE, cartridges don’t require backwashing or regular media   replacement. Instead, all a tech needs to do is remove the cartridge from the   filter tank and hose it off; or, in some cases, dip it in a mild muriatic   acid solution to remove particularly stubborn particles.

The downside is that if this cleaning isn’t performed regularly, cartridge   filters have a tendency to clog, especially in pools with high bather loads,   techs report.

Thus, cartridge filters are best suited for applications with low to moderate   bather loads and water volume, such as residential pools that see usage a few   times a week. If simplicity of maintenance is a high priority, a cartridge   system may be ideal.

Source: Ben Thomas- Pool and Spa News | 1.27.2012

 

How to Properly Test Pool Water

Developing some good habits will lead to much more effective and accurate water chemistry analysis.

 

Inaccurate test results are not always the fault of the water-testing equipment. Whether you use a test kit, test strip, portable meter or countertop lab, sloppy technique or poor housekeeping can interfere with results.

Fortunately, the situation can be rectified easily — and usually at no expense.

The first rule of thumb is to read the instructions every time when making a purchase. Even if it’s the same test equipment from the same manufacturer, something important in the procedure may have changed since you last bought the product. If a “simple” test strip has a required technique for successful use, you can bet the farm other testing supplies do, too.

Keep in mind that test results are not an end in themselves — they are used to make treatment decisions. If the sample employed for the test is not representative of conditions in the whole pool, the results will not be actionable.

First, use a clean sample container. And avoid sampling near return lines, chemical feeders and dead zones. Instead, try for the midpoint of the pool, as you want to take the sample at the specified depth.

In addition, when a treatment chemical has just been added, allow at least two filtration cycles to pass before retesting in order for the product to circulate.

Timing also is important. After taking a water sample, don’t let it sit for too long. The sanitizer residual is particularly apt to change, resulting in a false low because it tends to dissipate as the sample sits. If the instructions say to observe a wait time after adding reagent(s), do not omit this step. Copper, iron, manganese and nitrate tests often need extra time for proper color development. The cyanuric acid turbidity test is time-sensitive as well.

Using the wrong sample volume is another common mistake. In “teaspoon chemistry,” a little difference can have a major impact. Always have the bottom of the meniscus sitting on the fill line of the sample tube. If using a pipettor, remember to check for improper fills due to air bubbles. A volume-related mistake with liquid reagents commonly involves using the wrong drop size. In addition, the dropper bottles are meant to be held vertically when dispensing. If a technician holds the bottle at a slant, the amount of reagent released will be more than the test design calls for. Moreover, if static is allowed to build up at the tip, the drops dispensed will get progressively smaller, resulting in less reagent being added.

Another testing pitfall lies in incomplete mixing. Reagents in tablet or powder form must be completely incorporated into the sample water for the proper reaction to take place. In particular, if a test vial is square, make sure nothing is stuck in a corner.

The fixes here are easy: Hold the dropper bottle upright; discharge static by wiping the dropper tip with a clean, damp cloth; and swirl until any clumps of reagent dissolve.

It’s paying close attention to what’s happening during each and every test that’s the real challenge.

Ambient light is another important consideration in testing. Most manufacturers recommend conducting color-matching tests in natural light (but not looking into the sun). This is because artificial lighting skews color perception — as do sunglasses. If testing indoors, where finding natural light is inconvenient, buy an inexpensive illuminator, much like photographers use to simulate daylight, and perform color comparisons in front of it. Colorimeter users must be aware that stray light will interfere with a test — be sure to close the sample chamber lid/cap the chamber as directed.

Contamination also will foul up test results. Check to ensure there is no residue in your sample container or test cell left over from a previous test. Do not switch caps between reagent bottles, or let them become dirty when you remove them. For that matter, replace caps immediately after use so that air and humidity don’t get inside to spoil reagents or test strips. Never allow finger oils to come in contact with reagents — this means not using a finger as a cap for a test cell, and not touching the pads on a test strip.

Finally, all tests have range limits, and testing outside the limits will result in error. For example, phenol red indicator is widely used to determine pH. It works in the range of 6.8 to 8.4, which is where pH normally is for pools and spas. A pH below or above that range can result in a color reaction that does not match anything on the color chart, or a deceptive “match” to the first or last color standard.

(When in doubt, for an extreme low reading conduct a base demand test, or for an extreme high reading do an acid demand test, using the treated sample.) The remedy is to use another indicator, appropriate for that pH level; although most of us in this scenario would treat to raise/lower the existing pH into the desired range using the demand test results as a guide, and then retest with phenol red for confirmation.

If you see room for improvement in your testing technique, or in the way you care for your testing supplies, turn over a new leaf today. It’s just as easy to develop a good habit as a bad one. Your test results will reward you for it.

 

Source: Patricia Fitzgerald- Pool and Spa News | 8.12.2011

Energy-Conscious Cleaning

Take a look at this guide to energy-efficient pool cleaners.

 

Pool   pumps have been a focal point for energy efficiency in several states.   Automatic cleaners may be next.

This summer, Pacific Gas & Electric Co., a leading   California utility and advocate of energy-efficient pool systems, will   conduct a study on the energy efficiency of automatic cleaners. Depending on   the results, the company could create new rebate incentives for buying   certain cleaner types, in particular those of the robotic variety.

However, you must consider a number of factors to make sure cleaners realize   the greatest possible energy savings.

The Pump
Pool cleaners don’t work in a vacuum, no pun intended. The relationship   between the cleaner and the pump is critical when it comes to saving energy.

To that end, a number of states are embracing legislation that would   encourage pool owners to use two-, multi- and variable-speed technology.

Variable-speed technology creates significant energy savings not only for   pool filtration, but for cleaning as well.

“I’ve got 1 amp [from the pump] for filtration and 3 amps for running the   sweep for about three hours,” explains John Balistreri, owner of Balistreri   Pool & Spa Service in Petaluma, Calif. “One lady dropped her [utility]   bill from $400 to $100.”

But a number of green-minded technicians are less enthusiastic when it comes   to two-speed pumps because of the energy they waste on a high-speed setting.

“Usually the high speed is too high and the low speed is too low [to run a   cleaner],” Balistreri notes.

However, in some cases, techs can utilize two-speed motors on pool/spa   combinations, using the high speed for the spa and the low speed for both   filtration and a low-flow suction-side cleaner.

In addition, some aren’t convinced the difference between energy on an   intermediate speed (on a variable-speed) and high-speed (on a two-speed) is   universally significant. This is especially true in areas with low energy   costs.

“You go to Phoenix and it’s 9 cents a kilowatt hour,” says Marchal   DePasquale, director of marketing, automatic cleaners, at Hayward Pool Products in Elizabeth, N.J. “You’re not going   to move someone toward a $700 pump when they’re living [with those rates].”

Applications
While saving energy is important, picking the right cleaner for the job is   crucial.

Pressure-side cleaners are a popular option, but the additional energy   expended by the booster pump they frequently require has been drawing a lot   of attention.

“There is a big interest in cleaners. They’re kind of a low-hanging fruit   [because] booster-pump cleaners actually have to utilize two pumps to perform   their as-advertised operation,” DePasquale says.

Indeed, pressure-side cleaners that need a booster pump can be energy hogs,   as some booster pumps charge in excess of 7 amps. Though there have been   improvements in the efficiency of pump motors, running an extra pump can   still make a dent in anyone’s electrical bill.

Yet they are also vital to running many pressure-side cleaner models.   Boosters provide a much-needed pressure requirement — often above 30 psi —   that filtration pumps cannot create over such a long distance.

This energy need may drive some techs to other cleaner models that can   operate solely on the filtration pump (or on their own, in the case of   robotic cleaners).

Still, when coupled with variable-speed technology, booster pumps may not be   as wasteful as they appear.

“A lot of people look at the booster and [think] that it will cost a heck of   a lot more money to operate,” says Brian King, Pentair’s senior product manager for   automatic cleaners. “Sure, you’re spending a bit more on the booster pump,   but you can do it while the variable-speed is running at a very low rate.”

Additionally, the booster pump should only be running one or two hours a day,   and even less so in the wintertime.

Pressure-side cleaners are particularly popular in Northern California and   much of the Southeast. They’re known for being able to pick up large debris   such as leaves, twigs and acorns. However, because they do not take advantage   of the pool’s own filtration system, these cleaners are not ideal for   cleaning up smaller, dust-like debris.

“If you’re in a leafy environment with a lot of trees around the pool … you   really want a pressure-side cleaner,” King says.

And not all pressure-side cleaners require a booster pump.

“[For] new pools built today, unless they have a really deep deep-end and   [the cleaner] really needs to climb around the pool, I don’t put in a   booster,” says Dean Nesson, owner of All Clear Pool & Spa in Rancho   Cucamonga, Calif.

Instead, Nesson likes to use a low-volume pressure cleaner and a dedicated   line that’s fed from the pump before the filter to reduce the risk of filter   explosions.

The other standard cleaner type — suction-side — comes with its own set of   pump parameters.

When combined with a two-speed pump, many suction-side cleaners can work at a   low speed. The difference creates a 56 percent savings in energy consumption   between the two speeds, according to DePasquale.

“But there are some compromises that are made with the performance of the   cleaner when you run it at low speed,” he warns.

Certainly the cleaner must run longer on a low speed, but it also won’t   create the same agitation and circulation as it would on high speed. Also,   suction-side cleaners are less effective in sweeping larger debris than   pressure-side.

For its part, the robotic cleaner is purported to sweep large debris and   small dirt particles. And the devices are very energy-efficient.

“Our educated guess is that the robotic cleaners offer dramatic savings over   pressure-side with booster pumps, somewhere in the range of 800 watts per   hour,” says Joanne Panchana, manager of the pump and motor rebate program for   Pacific Gas & Electric Co. in San Francisco.

However, for some applications, its higher price point may counter balance   some of the product’s advantages. And some techs may hesitate to use robotic   cleaners because they don’t function with the pump.

“They don’t circulate the pool at the same time [they’re cleaning],” Nesson   says. “So if you don’t have a skimmer working in your pool … you’re not going   to get results.”

Picking a pool cleaner also may depend on maintenance, and therefore a   technician’s own preference. Service techs may gravitate to whatever cleaner   is associated with the repairs and replacement parts with which they’re most   familiar.

Source: John Miles – Pool and Spa News | 4.30.2009

Electronic Water Testing Devices

Electronic testing provides ease of use, but is it appropriate for you

Electronic testing devices for water analysis seem to be everywhere these days. But some service professionals are still hesitant to use them, perhaps because they don’t understand how these systems work.

Taking cost, ease-of use, precision and calibration into consideration, you can make a wise decision about the meter that best fits your testing needs. Regardless of the instrument you choose, the real benefit is that it can eliminate some of the “guesswork” that is typically required.

SENSORS/ELECTRODES
For some of the parameters regularly measured in pool and spa water, an analysis can be performed with the simple push of a button. For example, pH can be measured by a portable pH electrode that can be partially submerged into the pool or spa, and the appropriate button pushed to activate the reading. Unfortunately, this technology does not allow for testing of all important parameters. Typically, these sensors will only measure pH, total dissolved solids (TDS), salt, ORP and temperature.

The latest in sensor/electrode technology allows some or all of these parameters to be measured on one unit starting at around $350. Several manufacturers now offer systems that are capable of measuring pH, TDS, salt, ORP and temperature in seconds, all with the same instrument.

ORP and pH are measured by these types of systems in much the same way. Voltage is generated between a reference electrode and a measuring electrode with pool water in between. A change in the current equals a change in the measured value. Even though there are two electrodes, these are often contained inside a single unit, giving it the appearance that it is just one probe. It is important to point out that ORP does not replace regular monitoring of free available chlorine. Regulations require testing free chlorine even in systems fit with ORP monitoring ability.

Conductivity results are used to approximate TDS and salt. Conductivity is the measure of the water’s ability to conduct an electrical current. A reference solution with known concentrations is used as a calibration standard. The unit then assumes the water “make-up” is similar to that of the standard and measures its ability to conduct an electrical current, which is converted into a salt or TDS reading, depending on the setting and calibration. Unfortunately, this is really just an approximation, as conductivity is not a direct measurement of TDS or salts. However, it is a fast and easy method that can provide a close approximation.

Advantages. Electrode systems provide near instant results for the parameters they are capable of measuring. Often several parameters can be measured by the same unit simply by switching modes. No additional reagents are needed for regular testing. The results also can be highly accurate and precise depending on the instrument. These instruments are typically easy to use and operate with little or no training required. This technology is also suitable for continuous online monitoring.

Disadvantages. The electrodes require careful handling and cleaning/rinsing after each use with distilled or deionized water. It is important to carefully follow the manufacturer’s recommendation for storage of the electrodes. These systems also require periodic calibration, and it may be difficult to tell when they are not reading accurately.

COLORIMETRIC TESTS
This type of electronic instrument is often referred to as a photometer or colorimeter. Either way, the basic technology is the measurement of light intensity at defined wavelengths as it passes through a reacted sample. A calculation based on a set calibration curve allows the measured value to be converted to appropriate value of the measured parameter.

This technology continues to improve as reagent technology gets better. As great as these systems can be, they are reliant on the reagents (liquid, tablets or powder pillows) for getting accurate measurement. Therefore, as reagents are improved and use life is extended, colorimeters become more accurate and
reliable. Additionally, the cost of these systems has dropped some in recent months as low-cost optics and internal components become available. Some multi-parameter colorimeters go for less than $150.

Advantages. Most all significant pool and spa parameters can be measured with this technology, and several combine up to 25 tests on one unit. These instruments provide a high degree of accuracy and precision. They typically will meet all regulatory requirements for testing. Most parameters require only a single reagent for testing.

Disadvantages. Reagents are required for this testing. This adds cost and handling concerns. Additionally, these systems may take longer to complete tests due to the mixing and testing completion times.

REFLECTANCE METERS
Reflectance testing is the newest technology to enter the pool and spa market. This type of system utilizes test strips instead of reagents to measure the intended water parameters. A test strip is reacted and placed on the clear channel where light is reflected off the reacted test pads. The reflected value is then read by an optical reader that allows for a colorimetric measurement. This measurement is then converted by complex algorithm to calculate concentrations of the measured parameters. This type of technology has been used in the past in the medical industry for measuring blood glucose levels.

Advantages. A quick and easy test for a few critical parameters at a time. For example, a three-way test for free chlorine, pH and alkalinity can be completed in just 20 seconds. The cost of replacement reagents is very low, as test strips are generally inexpensive. The up-front cost of these systems is also very inexpensive compared to other electronic testing equipment.

Disadvantages. The technology is dependent on test strip results in order to calculate the water analysis. Test strips will yield slightly more variation, and therefore less precision than other comparable methods. Not all parameters are currently available.

There is much to consider when selecting your next electronic testing instrument. Now you are more knowledgeable about how to select an appropriate tester, as well as some of the advantages and disadvantages of the specific methods. Keep these in mind and you will find the unit that is right for you.

Source: Joe Sweazy- Pool and Spa News | 2.12.2010

Cleaning Your Filter

Cleaning   Your Filter

Keep your pool filters free and clear   with regular maintenance

Keeping   the pool clean is a dirty job, which is why to clear dirt and debris   effectively, pool filters need periodic cleanings themselves.

The   three most common types of swimming pool filters are diatomaceous earth (DE),   sand and cartridge filters. Understanding how these different pool filters   work and how to maintain them can make your job easier, keep your pools   looking good, and keep your customers happy.

Micron   ratings

The   filter’s job is to trap all of the fine dust, dirt and sand particles that   pass through the skimmer basket and the hair-and-lint pot. Filters can make   the pool water look beautifully blue and crystal clear, but the water is not   necessarily pure. The misconception that a filter can purify water leads too   many homeowners and pool techs to blame cloudy water on filters instead of   proper water balance and sanitation.

Filters   remove only solid particles from swimming pool water. They generally cannot   remove dissolved contaminants, such as oils, bacteria or disease-causing   pathogens.

A   swimming pool filter’s efficiency is measured by its micron rating, meaning   how many microns can pass through the filter. A micron is a unit of length   equal to one millionth of a meter (1/1,000,000 m), or 0.0000394 of an inch.

A   grain of ordinary table salt is about 100 microns, and the human eye can see   down to about 35 microns without the aid of magnification. The lower the   micron rating on a pool filter, the smaller the particles it can remove from   the water.

Diatomaceous   Earth filters

The   DE filter is a favorite of pool builders and service technicians because it   has the best micron rating. A DE filter can strain out particles as small as 1   to 3 microns.

Diatomaceous   earth is a white powder that is made of the tiny skeletal remains of sea   creatures, called diatoms, which died prehistorically. Inside the DE filter   tank are eight semi-circular grids. The DE coats the grids and forms a filter   cake, which acts as a micro-screen to strain out tiny pieces of debris.

Pure   DE will not compact, so the pool water can easily pass through it. The dirt   and debris that is trapped in the filter cake will cause the filter cake to   pack and restrict water flow.

The   DE filter may be partially cleaned by backwashing. All DE filters have a   valve that allows the pool water to run backwards through the filter. Pool   water enters the filter and rinses most of the filter cake, dirt and debris   away to the sewer drain.

The   filter grids must be re-coated with a new filter cake after each backwashing.   Because backwashing does not remove all of the dirt and debris from the   filter, it is necessary to periodically open the filter and clean each grid   individually.

Separation   tanks

The   separation tank, found on many systems, is used to backwash a DE filter. The   job of the separation tank is to separate the DE and filter dirt from the   water while it is being backwashed.

Many   cities have banned DE and filter dirt from being backwashed down the street   and into storm drains. Some cities also don’t want DE and filter dirt   entering the sewer system, lest it clog the pipes. Therefore, during   backwashing, the discharged water must pass through a separation tank.

The   separation tank contains a strainer bag, which traps the DE dirt and muck.   Depending on the city ordinance, the clean, DE-free pool water is either   returned to the pool or sent down the sewer drains.

The   separation tank should be cleaned every time the filter is cleaned, and its   contents must be disposed of in a proper trash receptacle. It is important to   clean the separation tank at regular intervals — i.e., every time you clean   the filter — because the more impacted it gets, the less effective it   becomes; the heavier the strainer bag gets, the harder it is to remove; and   the more oils it collects, the worse its odor will be.

Adding   DE

After   backwashing the filter, you will need to add more DE to it through the   skimmer. Some pool techs will put the DE into a bucket, add water, then pour   the whole mixture down the skimmer; others will scoop the DE into the skimmer   directly.

DE   is added at a rate of 1 pound per 10 square feet of filter (always round up).   For years, a 1-pound coffee can was used as a DE measure; a 1-pound coffee   can holds 1/2 pound of DE, so you would use two 16-ounce coffee cans per   pound of DE. But coffee cans now hold only between 10 and 13 ounces — not 16   — so they are not recommended anymore. A 1-pound scoop is available at any   supply house. A 44-ounce drink cup also holds a pound of DE.

Sand   filters

A   sand filter is the oldest and simplest filter in use: The water used in the   famous Roman baths was filtered by running it through sand. The sand inside   the filter is called the sand bed. As the pool water passes through tiny   openings in the sand bed, dirt particles and other debris are trapped.

Sand   filters are virtually maintenance-free. A good sand filter can go years and   years on backwashing alone, if the backwashing is done right. There are no   grids to clean and no DE or sand to add — just backwash and go.

The   edges of the sand particles create tiny crevices to filter the water and   catch the debris. As dirt passes through the filter, it becomes trapped in   these crevices while the clean water passes through.

Just   as you would with a DE filter, when you backwash a sand filter, you run the   water backwards through the system so that all the dirt in the crevices and   gaps rises to the top of the filter and goes down the backwash line.

Sand   filters have the highest micron rating. They start out at about 40 microns   and go down to 20 microns over time. “A sand filter starts to clean better   the dirtier it gets,” says John Ott, Western Regional Technical Training   Manager at Hayward Pool Products, Elizabeth,   N.J.

Because   of this high micron rating, the water in a sand-filtered pool could start to   look cloudy. When this happens, simply add a good clarifier. A clarifier will   gather all of the small pieces of debris that pass through the filter and   clump them together into a larger piece of debris that will become trapped in   the sand filter’s crevices.

Backwashing   a sand filter

The   only way to clean a sand filter is by backwashing it. And it’s important to   remember that this is a two-step process.

First,   backwash the filter for at least two minutes, or until the water runs clear.   In normal run position, the sand gets packed down. During backwashing, the   sand rises and separates, thus releasing the debris trapped inside and   allowing it to flow out of the filter.

Second,   allow the filter to sit for 15 to 30 seconds. This lets the sand inside   settle down again. Then, set the backwash valve to the rinse setting and   rinse the filter for 30 seconds, or until the water runs clear.

A   common complaint about sand filters is that a small amount of dirt will shoot   back into the pool after backwashing. This is often because the second   backwashing step — allowing the filter to sit for 15 to 30 seconds so the   sand can settle and re-trap the dirt, followed by rinsing the filter — was   not performed. Bypassing this step may cause some dirt to escape the filter   and re-enter the pool. With proper backwashing and rinsing, and the addition   of a clarifier, a sand-filtered pool should stay clean and blue.

Cartridge   filters

Developed   in the 1950s, cartridge types are the newest of the swimming pool filters.   They are also the simplest to maintain, which is why they are so popular   today.

The   cartridge of the filter closely resembles a car’s air filter, but much   taller. The cartridge material is made from a pleated polyester cloth. As   water passes through the pleated material, dirt particles and debris are   trapped within the pleats. A new cartridge filter can strain out particles at   about 20 microns, but will go down to as low as 5 microns. The micron rating   actually gets lower as the filter gets dirtier.

The   cartridge must be removed for cleaning, as the filter cannot be backwashed.   It’s a good idea to clean a filter every six months to a year, depending on   the bather load and the size of the cartridges. (See “The Pressure’s On” for   more information on when to clean a filter.)

To   clean the filter, remove the cartridge and simply hose it off.

After   hosing the filter clean, take a minute to inspect it. The pleats should be   straight, not buckled or crooked. Also, inspect the molding on the top and   bottom of the cartridge. Is it in good shape, or is it starting to tear away   from the pleats? Buckling and tearing are signs that the cartridge is getting   old and needs to be replaced.

Source: Robert Foutz Jr.- Pool and Spa News | 3.26.2010