Most of What You Need to Know About Chemicals for the Upcoming Season

1 I 121 Aq Feat

There are literally thousands of articles on pool and spa water chemistry available in print and online. You can read them all, or just take a few minutes to read this summary article which tells you nearly everything you need to know in order to take good care of your customers’ water this season.

Any discussion of leisure water care starts with sanitizer. There are many different sanitizer options for pools that include chlorine, bromine, salt chlorination and biguanide. While each of these sanitizers offers a different range of features and benefits, chlorine sanitization is the most common choice for pools and spas due to its ease of use and impact on water balance. Chlorine can be introduced to the water in many ways, including sticks, tablets, granules, liquid and chlorine generator systems. Regardless of which version is being used, each form leads to the formation of hypochlorous acid. Hypochlorous acid is the killing form of chlorine that does the work of preventing disease and maintaining a safe and clear environment in the pool or spa water.

Since all forms of chlorine lead to the same sanitizing compound, the features and benefits among different chlorine options are focused on the secondary impact of the chlorine type on overall water chemistry. Service professionals and homeowners make sanitizer choices based on many different factors. For example, trichlor comes in slow dissolving sticks or tablets, making it the perfect choice for feeding through a chlorinator and allowing for less trips poolside for application. It’s important to understand that trichlor also has a low pH and can impact total alkalinity as well as pH readings. Dichlor, on the other hand, is a quick-dissolving granule product that can be broadcast directly to the pool. Dichlor does not impact water balance, but it must be applied several times a week if it is being used as the primary sanitizer.

STABILIZED, AND UNSTABILIZED, CHLORINE

Trichlor and dichlor are both stabilized chlorine products. The primary difference between a stabilized and unstabilized chlorine product is the presence of cyanuric acid. Chlorine is not UV stable. This means that on its own, chlorine will degrade in the presence of sunlight rather quickly. Stabilizer protects chlorine from UV rays, and stabilized chlorine will last five to six times longer than unstabilized chlorine. Thus, bathers will be protected longer when stabilizer is present.

present. Sodium hypochlorite, or liquid chlorine, is inexpensive and easy to apply to the pool, but it has a very high pH that results in the need for routine application of a pH decreaser to maintain a balanced pH. Calcium hypochlorite comes in both tablet and granule form, giving a wide variety of application options. It’s important to know that the pH of calcium hypochlorite is high, and the granules often require pre-dissolving before product addition. Hypochlorite products do not contain stabilizer, so stabilizer must be added directly to the pool in order to provide protection from UV degradation when using these products.

Due to current industry conditions, the use of liquid chlorine will become more prevalent for the upcoming pool season. This may be a new approach to sanitizing for many pool care professionals, so it’s a good idea to review the features of liquid chlorine and how to maximize it as a sanitizer in a pool. Liquid chlorine, also known as sodium hypochlorite, is an unstabilized sanitizer with a pH of around 13. The benefits of liquid chlorine include its cost effectiveness, as well as the ease of application. You can simply pour it in the pool without concern that it will bleach the surface. Remember that liquid chlorine is unstabilized, so when using it as the primary sanitizer, check and balance cyanuric acid independently of your sanitizer addition. A residual of 30-50 ppm of stabilizer is ideal to maximize the life of liquid chlorine and to protect it from UV degradation once it is added to the pool. Even with adequate stabilizer levels, liquid chlorine must be added frequently to maintain the EPA required 1-4 ppm sanitizer residual needed to provide adequate sanitization for the pool.

In addition to stabilizer, there are other components and ancillary products to consider for maximizing the effectiveness of liquid chlorine. Water balance can play a big part. Remember, the pH of liquid chlorine is around 13. This will drive the pH of the pool water upward with each addition. At a high pH, chlorine is not as active as it should be, making it less effective at sanitizing the pool water. The industry recognized correction factor is 10-16 fluid ounces of muriatic acid for every gallon of liquid chlorine added to maintain a pH of 7.2-7.6 — the range of pH necessary to ensure chlorine is active and effective in the pool.

ALGAECIDES, ENZYMES AND PHOSPHATE REMOVERS

In addition to balancing the water, there are other products that can be added to a routine pool care program in order to maximize the impact of liquid chlorine. A preventative algaecide, which should be a part of any pool care maintenance program, is an important addition to the pool when trying to maintain an adequate chlorine residual with liquid chlorine. Adding an algaecide weekly allows chlorine to be used for killing bacteria, and not get used up killing algae. The less work chlorine needs to do in the pool, the longer it will last. For service professionals, choosing the right preventative algaecide is important. Certain algaecides could cause excessive foaming when water features or attached spas are present. Refer to label instructions for guidance.

The addition of an enzyme product on a weekly basis can enhance the efficiency of any chlorine-based pool maintenance program. Enzymes break down non-living waste that is typically oxidized by higher levels of chlorine or a non-chlorine oxidizer. By using enzymes to break down the non-living waste (things like sunscreens, hair products, body oils, pollen and more) that are present in pool or spa water, the demand on chlorine is reduced.

Another option for service professionals to improve water quality and ensure success with liquid chlorine is orthophosphate removal. When the phosphate level gets too high (roughly over 125 ppb), it can create dull, cloudy or hazy water conditions and, in combination with high pH and calcium hardness, contributes to the formation of calcium phosphate scale on surfaces and equipment. This is especially problematic for saltwater pools. Since phosphate is the last step in the oxidation process of phosphorus, chlorine and shocks don’t have an effect upon it; however, phosphate does contribute to the conditions that make it harder for chlorine and algaecide to do their jobs. Therefore, keeping a pool at a near-zero phosphate residual is the ideal goal. Testing for and removing phosphate proactively helps reduce recurring pool problems, simplifies pool maintenance needs, and improves both the look and feel of the water. Look for multifunctional weekly maintenance products that will add both enzymes and phosphate removers at the same time, maximizing the potential of liquid chlorine while minimizing the time poolside and the number of product additions needed.

PHYSICAL, NOT CHEMICAL, WATER CARE

Often the first tool a service professional reaches for poolside is a chemical. However, the value of improving or expanding routine physical maintenance is by far one of the most overlooked solutions by both service professionals and pool owners to maximize a pool care program. The benefits of properly circulating pool water, providing good filtration, and even getting in a light personal workout by brushing and vacuuming, is often understated.

If the sanitizer, or any other ancillary chemicals applied to the pool, can’t reach problem areas, they will be less effective — if the sanitizer can’t reach it, it can’t kill it. Traditionally, pool water needs to be circulated 10-12 hours a day, and turnover the volume of the water at least twice in a 24-hour period. However, with variable-speed pumps allowing consumers to run their pumps for longer periods of time without breaking the bank, the standard 10-12 hours is more complex and flow patterns become more important.

Most consider the positioning of returns as an afterthought and think the more churn and surface disruption the better. In many cases, this is not true. For instance, larger aboveground pools can struggle to maintain good circulation since the lack of a main drain and limited amount of surface skimmers makes it more difficult. Many also have returns improperly positioned to point up toward the surface of the pool to make water appear to be circulating vigorously. Despite looking great, the circulation is inadequate and leads to problems occurring faster at the bottom and center of the pool. These areas of reduced circulation become the landing spot for large amounts of debris, while the areas and seams where the pool floor meets the walls become a haven for the start of biofilm and algae growth. What collects in these dead spots consumes chlorinebased sanitizers that blindly attempt to react and breakdown nitrogen-rich pool contaminants.

With good circulation in place, a pool ecosystem relies on proper filtration to remove debris and other contaminants from the water. The physical and biological processes occurring inside the filter increase the demand on the pool sanitizer and make it less efficient by performing activities outside of sanitization. As the filter performs its primary job, the contaminants fill the empty space between media whether those spaces are pores in a cartridge or the space between granules of sand, glass, and diatomaceous earth. This increases the media’s ability to filter smaller and smaller particles which improves clarity; however, flow inside begins to decrease as pressure within the system increases. Over time, the efficiency of the media is reduced, increasing the opportunity for biofilm growth within the media. Certain microorganisms can produce byproducts that increase the demand on a chlorine-based sanitizer.

Routine filter maintenance, such as backwashing or rinsing cartridges, will remove loose accumulations. Periodic chemical filter cleaning during the season removes the more difficult greases, oils, and scale that reduce filter effectiveness. Be mindful that not all filter cleaners work for every type of accumulation. Read labels and directions carefully before using.

Another method to increase chemical efficiency by keeping a clean filter is to incorporate products into weekly service that can help reduce the filter load. Routine use of enzymebased products can be an effective tool to help break down non-living organic accumulations in the filter media and provide longer filter cycles between cleaning. Most enzyme-based products also contain surfactants that not only help keep a filter clean but help in other problematic areas of the pool as well.

WATER LINES

One of the more unsightly pool water problems, and a source of frustration for pool owners, is the formation of water lines along the pool surface. Oils, greases and other wastes enter the pool water from bathers and most float on the surface. These nuisance contaminants mix with other debris that float and begin to accumulate on the pool walls, creating an ugly waterline that can also collect bacteria and algae, leading to increased sanitizer usage. Brushing is the most effective way to break down these accumulations and get them back into the bulk solution of the pool before they cause a problem.

Other areas of the pool also provide favorable conditions for accumulations that can lead to larger issues. Dead spots are areas of the pool where circulation is poor due to pool shape and structure, pool features or other accessories in the pool. For vinyl pools, certain seam locations can also provide a favorable surface for accumulations to develop. These areas should be brushed at least once a week to keep surfaces clean. The use of water tension modifiers can help keep these areas clean as well. Certain algaecides and most enzymebased products contain surfactants that modify water tension, helping to pull debris off surfaces and back into the water where it can be removed by the filter or broken down further by treatment products.

Common areas to watch for buildup of debris, algae or biofilm growth:

  • Light niche
  • Behind drop-in steps
  • Behind ladders
  • Sharp corners
  • Underneath ladder treads
  • Fountain or spa spillovers

With the use of liquid chlorine likely being more common for the upcoming pool season due to increased demand for sanitizers and oxidizers — and the possibly limited availability of other sanitizers and oxidizers — certain modifications to routines and practices should be made to maximize the effectiveness of the product being used. This should be done safely with proper storage and handling of products.

One of the larger differences between sodium hypochlorite and other solid chlorinating compounds, such as calcium hypochlorite, trichlor and dichlor, is how storage conditions can impact product degradation. Bleach concentration and storage temperature play a large role in the loss of product strength. Generally, increased temperatures will accelerate the process for all strengths, and higher concentrations will degrade at a faster rate. It is recommended to store liquid bleach in tightly closed containers out of direct sunlight in a dark cool place. For warehouses, never store liquid bleach over solids. It is good practice to store inert materials, such as hoses or handhelds, in-between liquid bleach storage and other chemicals.

When applying liquid chlorine poolside, pour slowly to avoid splashing. It is strongly recommended to wear gloves and goggles when handling and applying product. Liquid chlorine is corrosive, so it may cause skin and eye irritation, and damage clothing. Before discarding used containers, it is a good practice to rinse bottles out before discarding in trash.

TRANSPORTING LIQUID CHLORINE

Transporting large quantities of liquid chlorine on service trucks also requires a modification to the normal routine. It should never be transported in the passenger compartment and to protect against incompatibilities, use of an approved secondary container is recommended to protect in the case of spills or leaks. It’s also important to note that sodium hypochlorite should never come into direct contact with acids or ammonia-containing compounds. Mixing could result in the formation of harmful gases, which could lead to breathing difficulties.

Transportation regulations may be different for each state, sometimes even for individual counties or municipalities as well as Federal DOT requirements. It is the responsibility of the driver of the vehicle to know and comply with all federal, state, county, city and local transportation regulations. Also of note are requirements for signage on service vehicles. Be sure to follow all pertinent DOT regulations for the placarding of hazardous materials for transport. There are placarding exceptions in some areas for service vehicles if carrying less than 1,001 lbs aggregate gross weight of 5.1 oxidizers or other hazardous materials such as corrosives, fl ammable or combustible materials.

General guidelines include:

1. Carry an SDS for all chemicals

2. Separate and secure all chemicals

  • Separate liquids from solids
  • Separate oxidizers (dichlor and trichlor from cal hypo, lithium hypo and bleach)
  • Separate muriatic acid from everything including salt

3. No hydrocarbons

  • Gasoline
  • Diesel
  • Brake fluid
  • Motor oil

4. Respond to pool chemical spills immediately

  • Never put spilled chemicals back in the original container because they might be contaminated with substances such as dirt or grease
  • Use separate, dedicated materials, including clean and dry brooms, shovels and containers, to clean up and appropriately dispose of each spilled chemical — refer to the SDS for appropriate absorbents for liquid spills
  • Do not pour spilled chemicals down the drain or sewer
  • Do not store chemicals on a service vehicle for long periods of time — unload and use them or store them in an appropriate storage area

From a chemical standpoint, liquid chlorine can be an effective element of the weekly pool care maintenance program and is a capable weekly sanitizer product. However, since it must be added frequently to maintain the proper chlorine residual, anything that can be done to extend the life or enhance the effectiveness of liquid chlorine is a valuable addition to the program.

Balanced water, preventative algaecides, enzymes and phosphate removers all contribute to creating the ideal environment for liquid chlorine to be successful. In addition, proper physical maintenance, as well as storage and handling, round out an all-inclusive pool maintenance program — the key to success in providing customers the safe, clean water for which they are paying.


This article first appeared in the February 2021 issue of AQUA Magazine — the top resource for retailers, builders and service pros in the pool and spa industry. Subscriptions to the print magazine are free to all industry professionals. Click here to subscribe.

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