2006 November | CAI Water Softener Systems | Filters

With so many reverse osmosis drinking water systems available for the home, it can be challenging to select the right one. Here we review the reverse osmosis process and describe some of the available product types and features that can help you to select the correct system for your application.

Reverse Osmosis Function
First, a brief non-technical description of reverse osmosis function. In the home, reverse osmosis systems (sometimes referred to as RO), produce purified water used for drinking and cooking. Also called “point-of-use” systems, they are typically designed to be installed beneath the kitchen sink, and include a faucet for dispensing the purified water. In very general terms, this process involves a semipermeable membrane which will only allow relatively pure water to pass through it. On one side of this membrane, there is a high concentration of impurities (raw, unprocessed water). Pressure is applied on this unprocessed water to make it flow through the membrane, and out to the other (low pressure) side. Purified drinking water is collected on the low pressure side of the membrane. Impurities that were not able to pass through the reverse osmosis membrane are washed to drain. Purified water is either stored in a small reservoir tank, or dispensed directly to a faucet.

Types of Reverse Osmosis Membranes
While there are many different types of reverse osmosis membranes, generally only two types are used to prepare drinking water in the home. One system uses a cellulose triacetate membrane, commonly called a “CTA”. The other more common, and generally higher quality, system uses a thin film composite membrane called a “TFC”.

The CTA membrane is organic by nature, and requires disinfection to prevent the growth of bacteria. You most commonly see these systems in municipal (city) water applications, as it is important for the supply water to be chlorinated when using a CTA membrane. Reverse osmosis systems that use CTA membranes can be more affordable, but sometimes can produce a lower volume and quality of purified water. CTA based systems typically contain a sediment pre-filter, followed by the membrane, and a post filter (or filters) that contain carbon. Again, CTA membrane systems should only be used with a chlorinated water supply.

A more common RO system, used in both municipal and well water applications, is one that uses a TFC membrane. TFC membranes are inorganic, and therefore not susceptible to bacterial growth. These membranes also provide a high quality and quantity of purified water, however, TFC membranes are damaged when chlorine is present in the water. For this reason all TFC systems utilize a carbon pre-filter. Carbon easily absorbs chlorine, protecting the downstream membrane from attack, and eventual failure. In chlorinated water applications, it is important to replace the carbon pre-filter on a regular basis, to insure continued protection of the TFC membrane. In well water applications where chlorine is not present, a TFC system is always the preferred choice. TFC systems normally contain a combination sediment/carbon pre-filter, followed by the membrane, and additional carbon post filters.

Tank vs. Tankless
After purified RO water is produced, traditional RO drinking water systems use a small storage tank to hold the water until dispensed. These tanks are typically 4 gallons in size, with an internal plastic bladder. The bladder holds about 2 gallons of water, and the remaining tank volume contains pressurized air, that provides the force required to send the purified water to the dispensing faucet. If RO water remains in a storage tank for an extended period of time, it can develop a “flat” taste. Most better quality systems include an inline carbon filter that is located between the tank and the dispensing faucet. This filter “polishes” the RO water and provides a fresh taste.

The tankless RO system is a new design on the market. This design incorporates multiple TFC reverse osmosis membranes, and provides direct dispensing of purified water to the tap. Tankless systems do not require a water storage tank, are more compact than traditional systems, and occupy less cabinet space. A tankless RO can deliver a large volume of water quickly, and sometimes (depending on the model), to multiple dispensing locations throughout the home. Since the dispensed water is prepared on-demand, it can also have an improved taste. The disadvantage is that cost of these systems is usually higher than traditional RO, and there are also more membranes to replace. Tankless systems typically perform best at pressures above 40 psi, and lower pressure applications may require a pressure booster pump.

Efficiency & Quality
Reverse osmosis systems send water to drain during the water purification process. Measurement of the efficiency of this process system “recovery”. The amount of water consumed during reverse osmosis primarily has to do with water quality, pressure, and temperature. However, the design of the system also plays a large part. Better quality systems send 2 to 4 gallons of water to drain for every gallon of water produced (approximately 25-30% efficient). Lower cost systems usually have a reduced rate of recovery, and can send as much a 6 gallons or more to drain for every gallon of water prepared (less that 15% efficient).

When considering a traditional reverse osmosis system that utilizes a water storage tank, it’s is important to select one that that includes an automatic shut-off valve (also referred to as an ASO valve). This valve stops the water manufacturing process when the storage tank has reached it’s full capacity, and reduces the amount of water sent to drain.

Another important consideration when selecting an RO drinking water system is product certification. The National Sanitation Foundation (www.nsf.com) and the Water Quality Association (www.wqa.com) are two independent third party associations that certify reverse osmosis drinking water systems to a quality standard. A system that meets or exceeds NSF Standard 58 or WQA Gold Seal certification is a tested product, and is assured to provide high quality drinking water.

We hope that this information helped you to understand the reverse osmosis process and, to select the correct reverse osmosis system for your application. If you have any questions, or would like to know more about reverse osmosis, please visit our site at http://www.caitechnologies.com.

Purchasing water softeners can be a daunting task with so many different manufacturers and varieties to choose from. Here we will explain the water softening process, and describe the various types of water softeners available and their function.

UNDERSTANDING THE WATER SOFTENING PROCESS
Water hardness can be evident as white “chalky” deposits on hot and cold water fixtures, soap deposits (“soap scum”), and rings around the bathtub. Hard water can make laundering clothing more difficult, and requires the use of more soap when bathing and cleaning. Water softeners act to remove the hardness, and levels of iron and manganese, from your water. Water softeners contain a control valve, that directs water flow during the regeneration cycle, a resin tank that contains the cation exchange resin, and a brine (salt) tank that hold the salt used during regeneration. Sodium and potassium is found in salt, as sodium chloride (NaCl) or potassium chloride (KCl). Salt is commonly available at most supermarkets, home centers, or plumbing supply stores in 40 or 50 pound bags. The water softening process is accomplished by a chemical cation exchange that replaces the calcium and magnesium in your water with a equivalent number of sodium or potassium ions. During the softening process, your household water passes through the resin bed, and the magnesium and calcium are removed. A given sized resin bed has a fixed capacity to remove hardness before it needs to be regenerated to full capacity in order to continue provide softened water (for example, one cubic foot of resin has the ability to remove 32,000 grains of hardness from your water). When the resin bed is nearing exhaustion, the control valve washes the resin bed, and draws salt containing solution from the brine tank through the resin. As the salt contacts the resin bed, the process of ion exchange occurs, and the magnesium and calcium (hardness) that was collected in the bed during operation is washed to drain. After a final rinse to remove the excess salt, the resin bed is again ready to provide softened water.

CHOOSING A WATER SOFTENER
There are many different types of water softeners available to the consumer, and selecting the correct one can be confusing. We’ll try to shed light on some different systems that are available, and hopefully make your selection process a little easier.

Metered Based Water
Softeners Most metered water softeners have a single resin tank, and separate brine (salt) tank. Water softeners have a fixed capacity (based on size) to remove hardness from your water. When that capacity is exhausted, the softener needs to regenerate in order to again provide softened water to your home or business. Metered units (also called “On-Demand”) measure the amount of water consumption, and only regenerate when necessary. This saves both salt and water that is used during the softener regeneration process. While costing slightly more than timer (clock) based softeners, metered units will lead to savings over time. There are basically two type of metered water softeners:

Microprocessor Based Metered Water Softeners
These softeners measure water consumption using a turbine that turns as your water is used. An electronic sensor detects the rate of turbine spin and sends a signal to the on-board computer control. Using parameters that are pre-set by the user (capacity, water hardness, etc.), the computer determines when regeneration is required and initiates the regeneration process automatically.

Electro-Mechanical Metered Water Softeners Similar to the microprocessor based softeners described above, electro-mechanical metered water softeners measure water consumption with a turbine that turns as your water is used. The turbine is connected directly to a mechanical water meter by cable. When the user-set gallon capacity is reached, an electrical motor is activated by a micro-switch, and moves the water softener through the regeneration process. Time

Clock Based Water Softeners
Time clock water softeners are different from metered water softeners, as they regenerate on a calendar basis. They also generally have a single resin tank softener with separate brine tank – but do not measure water consumption, and only regenerate on the day-of-the-week as set by the user – you pick the day (or days) of regeneration. An electrical motor automatically initiates the regeneration process when the time setting is reached.

Twin Tank Water Softeners
Twin tank water softeners have two resin tanks and a separate salt/brine tank. Twin tank units are always metered (demand), using either an electro-mechanical metering system, or computer based microprocessor meter as described above. Twin tank systems always have a fully regenerated tank available on standby, and deliver uninterrupted 24 hour supply of softened water. During regeneration, water is first passed thru the online tank before entering the tank undergoing regeneration – regeneration using this pre-treated water helps clean the system and extends the water softener lifetime. These units are generally more expensive that the single tank units described above, as they are basically two complete water softener systems combined into one unit.

We hope that this information helped you to understand water softening, and to select the correct water softener for your application. If you have any questions, or would like to know more about water softeners, please visit our site at http://www.caitechnologies.com/.

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