Farris Enterprises Inc. Blog

On April 10, Judge Janis L. Sammartino granted the Metropolitan Water District of Southern California’s motion to dismiss a lawsuit seeking to stop it from adding hydrofluosilicic acid to public drinking water for the purpose of fluoridation.

The attorneys at Blumenthal, Nordrehaug & Bhowmik filed a brief opposing the water district’s motion to dismiss the lawsuit, arguing that it should be stopped from distributing hydrofluosilicic acid through the public water systems because it has not been approved by the FDA to fluoridate public drinking water to fight tooth decay. According to the opposition filed by the attorneys, “This action is brought to seek redress for the unlawful and unconstitutional medication of Plaintiffs by Defendant Metropolitan Water District of Southern California using an unapproved drug.”

Specifically, the lawsuit sought to stop the water district’s alleged practice of “injecting hydrofluosilicic acid into the water supply for the purpose of treating disease and dental cavities” given that “hydrofluosilicic acid has never been approved by the United States Food and Drug Administration for the treatment of disease or dental cavities.”

The judge disagreed, ruling that the FDCA does not give rise to a private right of action and on this basis dismissed the lawsuit against the water district.

When asked about the court’s ruling, Norm Blumenthal, managing partner of Blumenthal, Nordrehaug & Bhowmik, said, “We plan on appealing the court’s decision to dismiss this case against the water district.” He added, “The action of the Metropolitan Water District of adding a drug to our drinking water for medical purposes without first obtaining FDA approval of this drug for such purposes is illegal and needs to be stopped.”

On April 6, the California Department of Public Health (CDPH) announced that it would be abandoning the drinking water unit certification program after Dec. 31 of this year.

The decision came after lengthy discussions with the Water Quality Assn. (WQA) and after the association introduced legislation to turn over certification responsibilities to American National Standards Institute (ANSI)-accredited third-party certifiers such as NSF Intl. and WQA.

WQA has been working with CDPH officials as well as legal and legislative council since November 2011 to streamline the product registration process after application reviews were halted by the agency due to budgetary problems. WQA submitted proposed legislation to spur streamlining the process and the agency submitted its own legislative language. WQA was told that the governor has already signed off on the budget trailer bill language and that the chairman of the legislative committee is also on board.

Accordin to WQA, the agency’s April notification letter left many questions unanswered. For this reason, WQA representatives met with CDPH officials on April 16 to discuss the pending hearing for the legislative bill and to clarify details for the program elimination. CDPH provided the budgetary language, which clearly indicated that the program will be eliminated in its entirety, including fees, applications and any other requirements of the program.

For companies selling products in California that make health claims, the products will require the approval of an ANSI-accredited certification body after passage of the 2012–2013 Budget Act. Enforcement will be conducted by any local health officer in the state of California.

If your company relies on the CDPH certification of products being sold in California rather than a third-party certification body, currently valid certificates issued by the Department of Public Health on or before Dec. 31, 2012, will remain in effect until five years following the date of initial issuance, not including any annual renewals. After that time, product approval by an ANSI-accredited certification body will be required.

Question:  Why isn’t my softener drawing brine?

Answer:  Assuming your softener is regenerating and going through all the cycles but still not pulling the brine solution up from the brink tank, here are the most common causes:

1. Drain line flow control (DLFC) is plugged.  Check the drain line and the retainer fitting on the back of the control valve.
2. Injector or injector screen may be plugged.  Check and clean if necessary.
3. Line pressure too low.  Feed pressure must be at least 20 PSI.
4. Internal control leak.  Check condition of seals/spacers, piston and replace if necessary

Question:  Help, my brine tank is overflowing!

Answer:  Again assuming your softener if able to regenerate and move through all the cycles on it’s own but still overflow the brine tank, below are a few things to check:

1. Plugged DLFC.  Check that drain line and drain fitting/retainer on back of control valve for debris
2. Plugged injector system.  Clean the injector and screen.
3. Damaged or blocked brine valve.  Inspect the brine valve and replace if necessary.
4. Foreign material in brine line flow control (BLFC).  Take apart the BLFC and look for debris and clean.

Question:  Why isn’t my water soft?

Answer:  If you’re not getting soft water out of your water softener here are the first things to check for:

1. Make sure the bypass valve is set to service and not bypassing the softener.
2. Make sure there is salt in the brine tank and the control valve is getting constant electricity
3. Inspect and clean BLFC to ensure sufficient water flow to brine tank
4. Inspect distributor tube and baskets and replace if necessary
5. Check seals and spacers and piston assembly for damage or wear.  Replace as necessary.
6. Check viewing window on timer motor to ensure the motor hasn’t burnt out

More softener troubleshooting questions and answers here!

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Health problems associated with iron and manganese are not significant. But, issues with these contaminants can become an extreme hassle.

Iron and manganese are metallic elements found in rock. They are commonly found in groundwater and less common in surface water.

The secondary drinking water standards, or maximum contaminant levels (MCLs), for iron have been set at 0.3 ppm and manganese at 0.05 ppm, but the EPA has yet to set any limit to enforce.

Health problems associated with iron and manganese are not significant. But, issues with these contaminants can become an extreme hassle. Most problems occur in pipelines, meaning repairs are going to take time and money.

Iron and manganese are capable of plugging or fouling pipelines, pressure tanks, water heaters as well as softeners. This can cut down the consumer’s water supply or softening equipment.

“Most water treatment professionals would agree that softening using ion exchange for iron and manganese removal can be efficacious (if the elements are in the dissolved state),” said Greg Gilles, vice president and principal of AdEdge Technologies Inc. “Other factors, such as water hardness, salt demand and eventual fouling of the cation resins, over time [should] be considered in the selection. This method is commonly used for residential treatment when hardness reduction is also a goal.”

Water softeners can be a good way to reduce iron and manganese, but there are other methods that may be suitable for your situation. You have to explore those options to find out which is the best.

Many water treatment professionals turn to chemicals in order to remove or suspend ferrous iron in their method of water treatment. Clear water iron must be transformed into a filterable ferric iron in order to remove this nuisance contaminant, or it must be suspended with chemicals to keep it from staining.

Softeners can be used and ion exchange will work for low levels of iron, but there are applications where ion exchange is not possible or practical. Let’s take a look at a filter media that works very well at removing iron without chemicals or regeneration.

Filter Media

Basic iron removal media (BIRM) is effective in removing low levels of iron. There are some parameters and specifications that must be met in order for this very dense oxygen catalyst to work properly and successfully.

• The iron levels should not exceed 10 parts per million (ppm);
• The dissolved oxygen has to be 15% of iron present;
• The flow rates have to be matched with no more than 3.5 to 5 gal per minute per sq ft (gpm/sq ft); and
• A good water pressure must be used to lift and backwash this dense media.

There are some other specifica- tions that have to be met in order to achieve optimum results and successful iron removal.

The proper testing of the water cannot be stressed enough when employing this type of media for water treatment because there are other contaminants that can cause failure or premature reduction of this media’s activity. Chlorine and ozone are not very compatible, oil and hydrogen sulfide hinder performance, and polyphosphates can coat the outside of the BIRM, thus reducing the catalyst capabilities. Matching the correct media and proper flow rate with each application in water treatment determines the success of the water treatment professional. Understanding what contaminants need to be removed in order to achieve the best effluent water is the most important thing to remember when designing a system.

BIRM is very low maintenance. It requires backwashing only. No chemicals are needed for regeneration and if backwashed often and properly, the life of the BIRM is exceptional. We applied this media to an irrigation system that also was used as a pre-filter for a softener. The softener worked very well and the system also removed the iron and prevented staining in the irrigation process. This same system was used to fill a small pond, swimming pool and hot tub, but after about five years the media became fouled and was replaced. The oxygen levels were low and the tannin levels of the influent water was very high, so in theory the expected life of the media exceeded the expectations of the system designers. The filter was overrun many times and after constant bleed-through, it was determined that the time had come to re-bed the filter.

Mixing Media

With the performance of BIRM, the system designers also mixed in some Filox-R in the re-bed mixture. This media is a higher concentration of manganese dioxide than BIRM, but also increases cost. There was a tradeoff because less BIRM was used, and, with using the Filox-R, the designers hoped for a longer run and better filtration performance. The specifications for the Filox-R are much different, however, from the BIRM; therefore, the manufacturer should be contacted before implementing any application. Again, proper water testing cannot be stressed enough when designing a system that will deliver desirable results.

The iron filter that was used consisted of a 21-by-69-in. vessel and the distributor had laterals to help in backwashing the media thoroughly. The control head used was a Fleck 2850 flat cap, time clock, backwash valve. The unit used 6 cu ft of BIRM, but we found with use that 9 gpm was the best flow rate with no bleed-through. According to specifications, the unit should have been good for a higher flow rate, but that was not feasible or practical. The shortfalls of the filter were explained in detail to the customer before installation, so any failure to reach desired results did not present any dissatisfaction.

The irrigation system was designed to keep each zone at a lower flow rate and more zones were implemented. It was very crucial that the flow levels were not exceeded and also that the amount of water on each run was not overextended. Constant overruns and high flow rates will cause premature fouling of the filter because of iron buildup and not backwashing contaminants thoroughly from the unit. The whole system worked remarkably well for many years. In the long run, the unit was cost-effective and provided iron-free water. The treated water was brown when coming out of the faucet and exceeded the specifications set forth by the manufacturer. The iron level was 3.5 ppm, tannins were high, manganese was 0.5 ppm, hardness was 22 grains and there were high sulfates. We had to chlorinate the water at least once per year to help control iron bacteria.

Effective Application

A good water treatment professional can be successful if he or she tests the influent water properly and applies the effluent water correctly. Water treatment professionals must also explain the system sufficiently to the user so that if there is dissatisfaction, the user does not feel cheated or ripped off. Sometimes a trial and error method needs to be used to test a system design. But if there is enough time for understanding the application and doing the math, a water treatment system can be implemented without problems, and customers are very pleased with performance.

Always refer to the manufacturer’s specifications and supplier’s engineers for help in the design process. This is just one method of dealing with iron removal and not a cure-all. It is environmentally friendly so you can think green while removing the brown.

Author’s note: Manufacturer’s specifications can be found at www.clackcorp.com for BIRM and www.watts.com for Filox-R.

Jeff Roseman, CWS-VI, is a consultant and freelance writer in the water industry. Roseman is a member of the WQP Editorial Advisory Board. 

Source: Water Quality Products   February 2010