Water Quality InformationWritten By Actual Experts

RSS

Hartford, Connecticut Drinking Water

Analies Dyjak @ Tuesday, September 25, 2018 at 11:28 am -0400

Analies Dyjak  |  Policy Nerd

For Hydroviv’s city of Hartford, Connecticut's drinking water quality report, we collected water quality test data from Hartford's annual Consumer Confidence Report and the U.S. Environmental Protection Agency. We cross referenced water quality data with toxicity studies in scientific and medical literature. The water filters that we sell at Hydroviv are optimized to filter out contaminants that are found in Hartford's drinking water.

Where Does Hartford Source Its Drinking Water?

Hartford sources its drinking water from surface water reservoirs throughout the massive Farmington River Watershed. Because Hartford’s source water is entirely surface, pollution that’s discharged into the river or its tributaries has the potential to enter drinking water. Hartford, as well as the rest of the state of Connecticut, has a long industrial history. Hartford drinking water has contaminants associated with industrial activities such as Strontium, Barium, Vanadium and Chromium 6. Additionally, hormones caused by household waste were detected in the city of Hartford's most recent drinking water quality report. 

Lead In Hartford Drinking Water

Hartford is an older city, so it’s no surprise that lead contamination is a big problem. Lead enters tap water through old lead service pipes and lead-containing plumbing. 10% of sites tested for lead had concentrations over 4 parts per billion. But the highest level detected in Hartford drinking water was 148 parts per billion. Environmental Protection Agency, Center for Disease Control, and American Academy of Pediatrics all recognize that there is no safe level of lead for children. Additionally, municipalities are only required to test a handful of homes every few years, so the levels reported in Hartford’s annual water quality report might not reflect the lead levels in your tap water. Lead exposure can cause developmental issues, lowered IQ, and damages to the kidneys and brain.

Disinfection Byproducts In Hartford Drinking Water

Hartford also has a serious problem with disinfection byproducts or DBPs. DBPs are formed when chlorine-based disinfectants that are routinely added to the water supply to kill bacteria, react with organic matter. In this years report, concentrations of haloacetic acids ranged from 7.7 to 38.2 parts per billion and 15.3 to 72.8 parts per billion for trihalomethanes. For a bit of perspective, EPA’s maximum contaminant level for haloacetic acids is 60 parts per billion and 80 parts per billion for trihalomethanes. While Hartford's water quality is technically in compliance with EPA’s threshold, regulatory agencies have very little knowledge about the adverse health effects of DBPs, and their toxicity. EPA has stated that they have been linked to an increased risk of bladder cancer, as well as kidney, liver, and central nervous system problems.

Other Articles We Think You Might Enjoy
Lead In Drinking Water: What You Need To Know
What Are Disinfection Byproducts?
Breakdown of The Lead and Copper Rule

Jackson, Mississippi Drinking Water Quality

Analies Dyjak @ Tuesday, September 25, 2018 at 11:57 am -0400

Analies Dyjak  |  Policy Nerd
**Updated July 26, 2019 to include current data

For Hydroviv’s assessment of Jackson, Mississippi drinking water, we collected water quality test data from Jackson's annual Consumer Confidence Report and the U.S. Environmental Protection Agency. We cross referenced Jackson water quality data with toxicity studies in scientific and medical literature. The water filters that we sell at Hydroviv are optimized to filter out contaminants that are found in Jackson drinking water.

High Lead Levels in Jackson Drinking Water

Lead enters tap water through old lead service pipes and lead-containing plumbing. 10% (or the 90th percentile) of taps tested for lead contamination had concentrations over 8 parts per billion. However, last year the 90th percentile was 16 parts per billion. It's unusual to see a municipality improve lead levels this drastically in just one year. The federal action level for lead is 15 parts per billion, but agencies such as the Center for Disease Control and American Academy of Pediatrics recognize that there is no safe level of lead for children. Additionally, municipalities are only required to test a handful of homes every few years, so these super high levels reported in Jackson’s annual water quality report might not even reflect the lead levels coming from your faucet. Lead exposure can cause developmental issues, lowered IQ, and damages to the kidneys and brain. In August of 2018, the city of Jackson sent a notice to all residents acknowledging the lead violation. The notice gave standard recommendations for preventing lead exposure, such as allowing tap water to run for 2 minutes before use, avoiding hot water for drinking or cooking, eliminating tap water for baby formula, and getting your child’s lead levels checked by a doctor.

Disinfection Byproducts In Jackson Drinking Water

DBPs are formed when chlorine-based disinfectants that are routinely added to the water supply to kill bacteria, react with organic matter. According to the most recent report, concentrations of haloacetic acids averaged 54 parts per billion but reached levels as high as 45 parts per billion. Concentrations of trihalomethanes averaged 58 parts per billion but reached levels as high as 68 parts per billion. For a bit of perspective, EPA’s maximum contaminant level for haloacetic acids is 60 parts per billion and 80 parts per billion for trihalomethanes. Health and regulatory agencies have very little knowledge about the adverse health effects of DBPs, and their toxicity. EPA has stated that they have been linked to an increased risk of bladder cancer, as well as kidney, liver, and central nervous system problems.

Chromium 6 In Jackson Drinking Water

Chromium 6 is a highly toxic metal that is currently unregulated by the EPA. Chromium 6 pollution is associated with metal processing, tannery facilities, chromate production, stainless steel welding, and pigment production. Concentrations of Chromium 6 average 48.5 parts per trillion. This is double the concentration determined to have a negligible impact on cancer risk. EPA has acknowledged that Chromium 6 is a known human carcinogen through inhalation, but is still determining its cancer potential through ingestion of drinking water. Lung, nasal and sinus cancers are associated with Chromium 6 exposure. Ingestion of extremely high doses of chromium 6 compounds can cause acute respiratory disease, cardiovascular, gastrointestinal, hematological, hepatic, renal, and neurological distress which may result in death.

Other Articles We Think You Might Enjoy
Lead In Drinking Water: What You Need To Know
What Are Disinfection Byproducts?
Breakdown of The Lead and Copper Rule

How Do Municipalities Prevent Lead Entering Drinking Water?

Analies Dyjak @ Tuesday, October 9, 2018 at 3:36 pm -0400

Analies Dyjak  |  Policy Nerd

Flint, Pittsburgh, Providence, and Portland are just some of the major U.S. cities dealing with high levels of lead in drinking water. Since Pittsburgh just began adding Orthophosphate to its distribution system, we decided to put together an article explaining what exactly this treatment technique is, and other popular municipal treatment techniques used for lead mitigation.

Why Is Lead Such A Big Problem And What Are We Doing To Fix It?

The 2014 drinking water crisis in Flint, Michigan made municipalities around the country turn the mirror on their own problems with lead contamination. Lead remains a major issue for cities and towns throughout the entire country. It may feel like Americans have been talking about lead exposure for years, so why is it still such a big problem? The answer is pretty simple: Homes in the U.S. built before 1986 most likely contain lead pipes, plumbing, and solder. To make matters worse, water distribution lines also tend to adhere to this cutoff date. Lead is still a big part of infrastructure in the United States.

Since municipalities are tasked with mitigating lead exposure, we wanted to go over some popular treatment techniques that are being used throughout the United States, and their effectiveness at removing lead from drinking water.

Orthophosphate: Corrosion Inhibitor

Orthophosphate is a common system-wide corrosion inhibitor. It’s created by combining phosphoric acid with zinc phosphate and sodium phosphate. Together these chemicals create a mineral-like crust on the inside of lead service lines. If municipalities are willing to follow a strict dosing and monitoring schedule, orthophosphate can be extremely effective at reducing lead levels in drinking water.

Other larger cities around the country have also adopted Orthophosphate as a solution for lead-contaminated drinking water. In June of 2004, Washington, D.C. introduced orthophosphate to its distribution system, following major District-wide lead contamination.

According to EPA, the health effects of phosphates are not well known and FDA has stated that they’re “generally recognized as safe.” The Lead and Copper Rule requires the use of polyphosphate or orthophosphate whenever a municipality is in exceedance of lead standards set by EPA. Both have been cited as effective, but some municipalities disagree. According to city officials in Madison, Wisconsin, utility providers tried both of these additives and neither of them effectively reduced lead levels in drinking water. Because they were unable to find a corrosion inhibitor that worked, Madison officials decided to mandate the removal of all lead service lines.

It’s important to remember that orthophosphate isn’t a permanent fix, nor does it magically remove lead pipes. Orthophosphate has been cited by EPA as an “interim Optimal Corrosion Control Treatment (OCCT) modification.” It will also increase your water bill. In Washington, D.C., orthophosphate costs DC Water customers approximately $700,000 annually.

Problems With Partial Lead Service Line Replacements

Partial service line replacements are another mitigation tool used to reduce lead exposure. To put it candidly: it's extremely invasive. People are often surprised to learn that lead levels actually increase in the months following a partial service line replacement. Water that comes in contact with lead-laden debris or freshly uncovered piping can easily become contaminated. This type of disruption negates any sort of expensive treatment being used by a utility provider, like orthophosphate. If a municipality is in exceedance with the 15 part per billion Action Level, they are mandated (under the Lead and Copper Rule) to replace a certain percentage of lead service lines every year. If you’re curious municipal requirements under the Lead and Copper Rule, click here!

Who Pays For Lead Line Replacements?

Ratepayers are typically responsible for paying for public water line replacements. However, homeowners are responsible for covering the cost of replacing lead service lines that distribute water directly into their homes. According to EPA, a homeowner that elects to do so can expect to pay anywhere from $2,500 to $8,000 per line. This is not feasible for most households in the United States. Additionally, people are still at risk of lead exposure because lead pipes may still exist at various locations throughout a distribution system. Some municipalities offer subsidies or rebates on private lead service line replacements, but not all. In Madison, Wisconsin for example, homeowners who are eligible can apply for a rebate which covers up to $1,500 of the line replacement.

Can pH Reduce Lead In Drinking Water?

Many municipalities believe that adjusting the pH of drinking water is the best way to reduce lead exposure, and here’s why: Acidic water increase corrosivity, which causes lead pipes to leach into drinking water. The idea is that by making water more alkaline (opposite direction on the pH scale), the corrosivity will decrease. This may sound good in theory, but a municipality must still correct for chloride when doing so. According to the World Health Organization, chloride “increases the electrical conductivity of water and thus increases its corrosivity” and “increases the rate of pitting corrosion of metal pipes.” Similar to the other treatments mentioned in this article, changing the pH of drinking water does not get rid of lead service lines. Additionally, maintaining a balanced pH throughout an entire distribution system is not an easy task.

How Do You Know If Lead Treatment Works?

Lead is different from other contaminants because problems arise at the tap, rather than the source water. The only way to truly know if a corrosion control method is working is to test every single tap (which is completely unfeasible). Under the Lead and Copper Rule, most municipalities are only required to test 50-100 homes every 3 years or every monitoring period. This is not nearly enough data for a larger municipality like New York City. There’s just no way to know if a system-wide treatment technique is working to the best of its ability, so the burden and responsibility is on the consumer.

Other Articles We Think You Might Enjoy:
Lead: What You Need To Know
Orthophosphate and Lead Contamination
Why Are So Many Schools Testing Positive For Lead?

America's Water Infrastructure Act of 2018

Analies Dyjak @ Tuesday, October 16, 2018 at 2:21 pm -0400

Analies Dyjak  |  Policy Nerd

America’s Water Infrastructure Act (AWIA) of 2018 passed in the Senate on October 10th, 2018 in a 99-1 majority vote. The purpose of the bill is to update existing marine and freshwater infrastructure throughout the United States. Unfortunately, AWIA fails to address emerging contaminants that are currently impacting communities around the country. This article provides a brief overview of the bill, some of its major gaps, and what we think are priority drinking water issues.

What Does America’s Water Infrastructure Act of 2018 Include?

Flood Control Management:

Aside from the direct immediate threat from a storm surge, flooding can have serious impacts after the fact. An increased threat of biological contamination into a water supply, non-point source pollution, and damages to water distribution infrastructure are just some of the long term implications from flooding. AWIA plans to reauthorize and increase funding to reduce impacts from climate related events, as well as restoration projects. Projects impacted by this water legislation include dam restoration, funding for levee systems, and stormwater capture.

Reauthorization of the Water Infrastructure Finance and Innovation Act (WIFIA):

Under WIFIA, states that are eligible can apply for Clean Water State Revolving Funds and Drinking Water State Revolving Funds. WIFIA also includes development and implementation activities, such as lead service line replacements. AWIA plans to reauthorize funding for these programs.

Reauthorization of the Drinking Water State Revolving Fund (DWSRF):

Through the DWSRF, states can receive funding for various types of water-related projects. States are then required to prioritize projects that; address issues that pose a serious threat to human health, are necessary for a water system to reach compliance under the Safe Drinking Water Act, and assist high-risk water systems. AWIA plans to reauthorize funding for this program.

Our Take:

There’s no question that updating water infrastructure in the United States is completely necessary. However, the 2018 Water Infrastructure Act will not create meaningful changes to drinking water. A majority of the bill aims to reauthorize existing provisions, and make minor adjustments to certain acts. AWIA emphasizes the level at which policies address drinking water quality in this country: poorly. The bill reiterates the status quo, with zero attention to the new and emerging contaminants that are violently impacting communities around the country. Chromium 6, Per and Polyfluoroalkyl Substances (PFAS), and Perchlorate are all industrial contaminants that were not touched upon in this bill. AWIA is also far too broad in scope. The provisions combined marine with freshwater infrastructure, without strictly focusing attention on drinking water. 

Other Articles We Think You Might Enjoy:
Lead and Copper Rule: What You Need To Know
PFAS In Drinking Water
 What Does "Safe" Drinking Water Actually Mean?

Problems We Found In Boynton Beach, Florida Drinking Water Quality

Analies Dyjak @ Tuesday, September 25, 2018 at 12:43 pm -0400

Analies Dyjak  |  Policy Nerd

For Hydroviv’s assessment of the city of Boynton Beach, Florida's drinking water, we collected water quality test data from the annual Boynton Beach Consumer Confidence Report and the U.S. Environmental Protection Agency. We cross referenced Boynton Beach water quality data with toxicity studies in scientific and medical literature. The water filters that we sell at Hydroviv are optimized to filter out contaminants that are found in Boynton Beach drinking water.

Disinfection Byproducts In Boynton Beach Drinking Water

Let’s start with Disinfection Byproducts or DBPs. DBPs are formed when chlorine-based disinfectants that are routinely added to the water supply to kill bacteria, react with organic matter. Boynton Beach water quality has some pretty high levels of disinfection byproducts. According to the most recent report, concentrations of haloacetic acids averaged 26 parts per billion but reached levels as high as 33.7 parts per billion and concentrations of trihalomethanes averaged 74.8 parts per billion but reached levels as high as 149 parts per billion. For a bit of perspective, EPA’s maximum contaminant level for haloacetic acids is 60 parts per billion and 80 parts per billion for trihalomethanes. Health and regulatory agencies have very little knowledge about the adverse health effects of DBPs, and their toxicity. EPA has stated that they have been linked to an increased risk of bladder cancer, as well as kidney, liver, and central nervous system problems.

Chloramine In Boynton Beach Drinking Water

While most cities use chlorine, Boynton Beach uses chlorine and chloramine in the disinfection process. Chloramine is primarily responsible for what many customers report as the “bad taste” or “pool smell” of tap water. Concentrations of chloramine averaged 3.01 parts per billion but reached concentrations as high as 4.8 parts per billion. Again for a bit of perspective, the maximum contaminant level for chloramine is 4 parts per billion.

Other Articles We Think You Might Enjoy:
Disinfection Byproducts: What You Need To Know
What's The Difference Between Chlorine and Chloramine?
Problems We Found In Miami's Drinking Water