DELOACH BLOG

Topics: water treatment issues, water quality, water treatment, advanced treatment solutions, FDA, Safe drinking water, wastewater, Global, RO system, DeLoach Industries, Inc., Drinking Water, PFA's, DeLoach Industries, Cosmetics, make-up, water process system, removing PFAS & PFOS, pfas exposure, health effects of pfas, nonstick cookware, wastewater treatment system, water treatment standards, PFOS, safe drinking water act, pfoa regulations, the environmental protection agency, drinking water standards, adverse health effects, water resistant clothing, environmental safety

If you’ve been following the news, you know a growing problem with PFAS (per- and poly-fluoroalkyl substances) exists.

PFAS, a group of synthetic chemicals in a wide range of products, is causing a growing concern. Despite their widespread use, some PFAS compounds have been found to degrade into potentially harmful byproducts like PFAS-methyl tetrahydrofuran. What's more alarming is that these chemicals have infiltrated our drinking water sources, even in areas with high water tables. This is why it's crucial to understand effective methods for removing PFAS from water.  What should you do if you suspect that there’s a problem with your water? Check the source of the water, test it, and treat it if necessary.

Follow these steps to remove PFAS from drinking water.

Test Your Water

Although knowing how to remove contaminants is essential, it’s even more important to understand how to test your water for contamination. A water test kit can help you determine whether there are contaminants in your water and whether they are at a dangerous level. You can purchase water test kits at grocery stores, hardware stores, and online retailers. Generally, these kits come with the standard set of tests for a home water filtration system, but they also often include tests for specific contaminants. Use these tests to determine whether your water is safe to drink. If your water contains contaminants, remove them from your water source. This can be done by digging a more bottomless well, installing a water filtration system, or getting a water purification system. If your water does not contain contaminants, you don’t need to do anything except continue drinking your water.

Check the Source

Understanding the source of your water is a crucial step in addressing contamination. Whether you have a well or a water treatment system, knowing where your water comes from can provide valuable insights. By tracing the water's journey from the source, you can determine if contamination occurs upstream. This knowledge is essential for well owners, who might overlook the significance of understanding their water source. If you find contamination at the source, you can address it immediately, such as reducing the distance between the source and your dwelling or seeking alternative, uncontaminated sources.

Topics: water treatment issues, water quality, odor control, water treatment, advanced treatment solutions, Chemical Odor, Safe drinking water, RO system, filters, Filter Media, residential well water systems, DeLoach Industries, Inc., backwash, Carbon Filter, Micron Filter, Drinking Water, Clean Water, Contaminated Water, Water Source, Sediment Filter, PFA's, Water Test, Water Test Kit

Topics: water quality, water treatment, advanced treatment solutions, Safe drinking water, municipal water systems, DeLoach Industries, Inc., Drinking Water, DeLoach Industries, carbon filters, removing PFAS & PFOS, pfas exposure, health effects of pfas, exposure to pfas, water treatment standards, PFOS, drinking water standards, forever chemicals, water purification systems, carbon absorption

In recent years, PFOA and PFOS, commonly known as "forever chemicals," have raised concerns among municipalities, food and beverage industries, and commercial facilities in the USA and around the globe. These synthetic chemicals, which never break down and pose significant health risks, have been detected in water, food supplies, and even bottled purified water. As new EPA regulations take effect in 2024, industries are searching for effective and cost-efficient methods to remove these hazardous substances from their water supply. Fortunately, advanced water purification technologies such as microfiltration, ultrafiltration, and reverse osmosis can address these challenges.

Topics: water quality, advanced treatment solutions, Safe drinking water, RO system, municipal water systems, DeLoach Industries, Inc., Drinking Water, DeLoach Industries, reverse osmosis, water process system, removing PFAS & PFOS, pfas exposure, health effects of pfas, exposure to pfas, water treatment standards, PFOS, safe drinking water act, the environmental protection agency, drinking water standards, forever chemicals, water purification systems, microfiltration and ultrafiltration, potable water, membrane technology, types of membranes, flat sheet, spirally wound

PFOA and PFOS are man-made chemicals used in various products to simplify life. 

Forever chemicals, also known as synthetic chemicals called PFAS, have gained recognition. Scientists created these chemicals to make products resistant to water, stains, and sticking. The United States initially utilized them in the 1950s.

DuPont introduced Teflon in the 1950s to help Americans have nonstick cookware and make their lives easier. Americans and people from other countries liked this new improvement and soon used these substances in many different products.

These chemicals are resistant to water and lipids, so they don't break down and last a long time in the environment.

Over time, companies have used these chemicals in manufacturing various products, such as firefighting foam, food packaging, and cosmetics. As a result, these chemicals have entered the air, water, soil, and food production. They discontinued the use of PFAS and their other compounds in the mid-1970s.

People believe that contamination has affected more than 7000 metric tons of Fluorochemicals. PFOAs and PFOS, which can cause various health problems, have exposed many Americans and people in the USA.

PFOA chemicals contaminated 1% of public drinking water supply systems in 2016. The EPA did not regulate safe levels of PFOA and PFOS in drinking water systems for many years.

Topics: water quality, advanced treatment solutions, pH levels, Safe drinking water, RO system, particulate matter, Filter Media, municipal water systems, DeLoach Industries, Inc., Drinking Water, Clean Water, PFA's, DeLoach Industries, nylon, Cosmetics, reverse osmosis, water process system, removing PFAS & PFOS, pfas exposure, health effects of pfas, exposure to pfas, nonstick cookware, food packaging, water treatment standards, PFOS, safe drinking water act, pfoa regulations, the environmental protection agency, drinking water standards, water resistant clothing, environmental safety, forever chemicals

In modern industrial water treatment, advancements in technology and processes have revolutionized the way contaminants are removed from water.

This blog explores the integration of NSF/ANSI 61 certified systems, artificial intelligence in water treatment, and cutting-edge processes such as decarbonation and degasification. We'll also discuss the key differences between forced draft and induced draft degasification towers, helping you make informed decisions while designing your Industrial Water Treatment System.

1. NSF/ANSI 61-Certified Water Treatment Systems: To ensure the safety and quality of water treatment equipment, NSF/ANSI 61 certification has become a crucial standard. This certification verifies that materials and components used in water treatment systems comply with health and safety requirements. When selecting a water treatment solution, opting for NSF/ANSI 61 certified systems guarantees peace of mind and adherence to the highest industry standards.

2. Harnessing Artificial Intelligence in Water Treatment: Artificial intelligence (AI) has penetrated various industries, and water treatment is no exception. Integrating AI into water treatment processes allows for more efficient and optimized operations. AI-driven systems can monitor water quality in real-time, predict system failures, optimize chemical dosing, and reduce energy consumption. By leveraging AI technologies, water treatment facilities can enhance their overall performance and streamline resource utilization.

3. Decarbonation and Degasification Systems: Decarbonation and degasification are essential processes in industrial water treatment, particularly in pH levels in water and the ability to control removing the contaminants. These processes target the removal of carbon dioxide (CO2) and other dissolved gases from water to improve its quality. Two key systems used for this purpose are the decarbonator and aeration system.

Topics: degasification, advanced treatment solutions, biological scrubber, NSF/ANSI 61, Chemical Odor, Decarbonation, Safe drinking water, De-Aeration, decarbonator, degasifier, degassed water, ansi61, nsf/ansi61, Deagasification, decarbonation of water, DeLoach Industries, Inc., Drinking Water, Industrial Odor Control, DeLoach Industries, contaminants, process system, safe drinking water act, drinking water standards, environmental safety, air emissions, Forced Draft, Induced Draft

Degasification and decarbonation are essential processes in water treatment that play a crucial role in improving water quality.

Topics: degasification, hydrogen sulfide (H2S), Decarbonation, dissolved gases, decarbonator, degasifier, gases, carbonic acid, H2S Degasifier, co2 dissolved in water, degassed water, decarbonation of water, DeLoach Industries, Inc., hydrogen sulfide molar mass, DeLoach Industries, carbon filters, removing hydrogen sulfide in water, hydrogen sulfide gas, dissolved oxygen

Requires an application commonly referred to as either “Degasification” or "Decarbonation" and it requires the use of a piece of water treatment equipment called either a “degasifier” or a “decarbonator”.

Both of these are similar in nature and are designed for Carbon Dioxide (CO₂) removal from the incoming water. A properly designed decarbonator can remove 99.99% of the free carbon dioxide gas that is present in the water stream. One of the primary reasons for utilizing a decarbonator or degasifier for the removal of carbon dioxide gas is the raise the pH of the water without the need to add caustic. resulting in high-purity water.

The other reason is the remove the CO₂ prior to treating the water with Ion Exchange which utilizes Anion or Cation resins to reduce the regeneration cycles for the resin beds. High concentrations of CO₂ consume the ion charge within the resins and require more frequent regeneration cycles. The difference between anion and cation resins is that one is positively charged (anion) and the other is negatively charged (cation), cation resins, attract positive ions with their negative charge.

The term decarbonation describes the process of the removal of suspended gas or the conversion of carbonic acids into free Carbon Dioxide. Carbonic Acid (H₂CO₃) is stable at normal ambient anhydrous conditions. However, Carbonic Acid decomposes when not stable and in the presence of any water molecules to form carbon dioxide (CO₂).  The Carbonic acid breaks down when present in water and it is converted to a gas based upon certain conditions. It is common to have CO₂ present in water requiring a decarbonation process when utilizing certain types of water filtration such as membrane filtration with reverse osmosis or it can be present when the need to adjust pH is required. When removing (CO₂) the process is often referred to as “Decarbonation”, when removing (H₂S) Hydrogen Sulfide the process is often referred to as “Degasification”. 

Topics: water treatment issues, degasification, pH levels of water, aeration, iron oxidation, water treatment, water plant, bicarbonate, hydrogen sulfide (H2S), pH levels, Decarbonation, ION Exchange Resin, dissolved gases, De-Aeration, wastewater, carbon dioxide, oxygen, decarbonator, degasifier, gases, carbonic acid, H2S Degasifier

The Basics of Water Decarbonation

and the removal of carbon dioxide (CO2). The need to remove (CO2) is essential in most Aquaculture, Municipal, Industrial, and Food & Beverage Processes To understand you must familiarize yourself with Henry’s Law.

Henry's Law defines the method and proportional relationship between the amount of a gas in a solution in relation to the gas's partial pressure in the atmosphere. Often you will see and hear various terms like degasification, decarbonation, aeration, and even air stripping when discussing the removal of dissolved gases and other convertible elements from water. Understanding the impacts that Carbon Dioxide (CO2) can have on both equipment and aquatic life provides the basic reasons why the need to decarbonate water, exists. Carbon Dioxide (CO2) can exist naturally in the raw water supply or be the result of ph control and balance. In either case, the process called Decarbonation or Degasification provides the most cost-effective and efficient manner to reduce or tally remove (CO2) from the water. In addition to Carbon Dioxide (CO2), water can contain a variety of other contaminants that may impact the removal efficiency of the Carbon Dioxide. A variety of elements as well as dissolved gases such as oxygen, nitrogen, and carbon dioxide (CO2). A full analytical review of the water chemistry is required to properly design and size the “Water Treatment” process.

Breaking the bonds in water releases a dissolved gas

such as carbon dioxide (CO2) you must change the conditions of the vapor pressure surrounding the gas and allow the gas to be removed.  There are many variables to consider when designing or calculating the “means and methods” of the removal of carbon dioxide (CO2). When I refer to the means and methods. I am referring to the design of a decarbonator and its components. The means equals the size and type (Hydraulic load) of the decarbonator and the “method” equals the additional variables such as the cubic foot of airflow (CFM) and “Ratio” of the air to water to accomplish the proportional condition needed to remove the carbon dioxide (CO2).

Topics: water treatment issues, degasification, pH levels of water, aeration, iron oxidation, water treatment, water plant, bicarbonate, hydrogen sulfide (H2S), pH levels, Decarbonation, ION Exchange Resin, dissolved gases, De-Aeration, wastewater, carbon dioxide, oxygen, degasifier, gases, carbonic acid, H2S Degasifier, removal of CO2 from water

One of the most pressing issues that we face today is the phenomenon of red tide.

Red tide is algae bloom that can cause serious harm to marine life and humans.

In this article, I will explore what red tide is, what causes it, and its impact on Florida. Most importantly, the role of wastewater treatment in helping to prevent it.

What is Red Tide?

Red tide is a natural phenomenon that occurs when certain species of algae grow out of control. These algae produce toxins that harm marine life and humans. The term "red tide" comes from the reddish-brown color that the water takes on when the algae bloom. The bloom can happen in any part of the world in warm, coastal waters.

What Causes Red Tide? 

Various factors cause these harmful algae to bloom.

• Changes in water temperature
• Nutrient pollution
• Ocean currents

The most common cause is nutrient pollution. Nutrient pollution occurs when excess nutrients like nitrogen and phosphorus enter the water. These nutrients can come from agricultural runoff, sewage from residential drain fields, inefficient wastewater treatment plants, septic tanks, and fertilizer.

Red Tide Blooms in Florida - History and Impact.

Florida has a long history of deadly algae blooms. The state experiences red tide almost every year, lasting for months.

It devastates the state's marine life, including fish, sea turtles, and dolphins. The algae produce toxins that can kill these animals. The dead fish can wash up on shore, causing beachgoers an unpleasant odor and an eyesore.

How Do These Microscopic Algae Affect Marine Life?

It affects marine life in a variety of ways. The algae's toxins can cause respiratory problems and neurological issues.

With most coastal outbreaks, the loss of marine life is significant. It produces toxins and decreases oxygen levels, another contributing factor to marine animal fatalities. Red tide disrupts the entire ecosystem and has been increasing in both frequencies of outbreaks as well as areas impacted.

How Does Red Tide Impact Humans?

Topics: water treatment issues, water treatment, wastewater, DeLoach Industries, water process system, red tide, wastewater treatment plants, red tide in florida, wastewater treatment system, cause of red tide, water temperature, marine life, wastewater treatment infrastructure, benefits of wastewater treatment, water treatment standards