CategoriesGeneral Awareness Industrial Water Treatment

Top 5 Latest Water Treatment in the World right now!

Water is very crucial in our every day’s activity. We need water for survival and that’s why it’s important for us to make sure that the water we consume is safe and clean. There are new methods which can be used in water purification. They are effective and affordable as well. These filtration techniques can easily help get clean water within no time.

1. The Use Of Nanotechnology

This term sounds scientific to most common people although it’s a very easy process. This technology uses titanium dioxide nanotechnology. Sounds technical, right? This process eliminates bacteria and other toxins in water. It also helps break down unrefined compounds with the help of ultra violet rays. The nanotechnology method does not however use the polymer-based water treatment membrane. This method is very affordable and easy to apply. It is also environmentally friendly because it helps reduce the buildup of microorganisms known to grow rapidly on drenched surfaces.

2. The RO Purification

RO purification which is commonly known as reverse osmosis is one of the most used method of water treatment. This process involves the use of membrane technology which allows it remove dissolved salts and other impurities in water. This membrane has extremely fine pores which allow only water to pass through. The water leaves behind all the poisonous substances in the water. You however have to purchase the right RO to help it maintain the vital minerals in water.

3. UV Purification

This is also known as the e-boiling method. This water purification method uses ultra-violet light to help kill bacteria and other harmful substances in the water. This is a very easy process. The purifier contains a minute mercury lamp which manufactures diminutive wave UV radiations. The radiations function by irradiating the water and piercing through the cells of the microorganisms and viruses. This in turn destroys their capability to reproduce. This method however requires other filtration processes because the dead germs remain in the water until a separate filter is introduced to help remove the dead germs physically.

4. Acoustic Nanotube Technology

This technology was developed by NASA’s Johnson Space Centre to help in water purification. The Acoustic Nanotube Technology gets rid of the contaminants in the water by using a sieve which is normally surrounded by tiny diameter nanotubes. They help push the water away from the contaminants hence allowing you collect purified water separately.

5. SunSpring System

This is a water purification system that helps distil up to 5,000 gallons of drinking water in a single day. It uses a battery that solely runs on renewable energy. It is environmentally friendly and also a cost efficient method.

Final Thoughts

These 5 modern technologies will help you treat water easily and more efficiently at the comfort of your own home. Furthermore, you don’t have to worry about using chemicals in the purification methods. The Acoustic Nanotube Technology can be however tricky to use at home.

CategoriesGeneral Awareness

Why water purifiers are so essential for homes now?

Most of the time, people don’t pay much attention to what purifier they’re getting. This kind of ignorance can lead to the purifier not doing much good and instead only causing a lot of water wastage. From our childhood days, we’ve studied that water forms 70% of our body, and it’s always advised that we drink enough water throughout the day to keep ourselves hydrated.

However, access to clean drinking water is a big challenge. Water scarcity has been an issue for a long time. Moreover, with the problem aggravating, finding clean drinking water free of contaminants, chemicals, and other harmful substances is very difficult. That’s a reason that most households have taken to water purification and have installed water purifier systems in their homes.

Most of the time, people don’t pay much attention to what purifier they’re getting. This kind of ignorance can lead to the purifier not doing much good and instead only causing a lot of water wastage. Yes! You read that right. Some water purifiers discard a lot of water, and that leads to wastage. So, you must choose the right water purifier for your home.

Let us elaborate this a little and help you understand the primary reasons why it’s important to choose the right water purifier for your home.

Importance of Choosing the Right Water Purifier System

Whenever you’re making a purchase, you want to ensure that you’re getting the right thing. So, why ignore this when getting a water purifier? Water is one of our basic needs, and we must drink clean, hygienic, and safe water. It’s possible only when you have the right water purifier system to treat the water at your home.

Here are all the reasons for you to dig more into the basics of water purification and make an effort into finding the right water purifier for your home.

Water Type

Water supplied to different places differs a lot in its type depending on where it comes from. If it comes from the underground water systems, tankers, or wells, it would be hard water, full of impurities, and a high level of total dissolved solids. However, if the water comes from more natural sources like lakes or rainwater harvesting systems, it’s soft water with lesser contaminants.

Now, the fact is that there are many water purifier systems with different technologies and methods for water purification. Not every kind of purifier is ideal for every type of water. So, you need to look into the water type to understand the level of contamination in the water and then choose which purifier will be the right choice.

Talking about the level of contamination, that’s another reason why choosing the right purifier is important. Let’s dig into this.

Level of Contamination in Water

Different water purifier technologies work on eliminating the different levels of contamination in water. So, it’s imperative to check that and find a purifier that would treat the water accordingly.

Soft water does not have many contaminants, and the TDS level is pretty low. As such, in some rare cases, you may not even need to purify this water, and just some ordinary filtration works. However, in the longer run, even soft water needs water purification. But even with that need, UF water purifiers are a good fit. If the level of biological contaminants in the water is higher, the most you would need is a purifier with both UF and UV technology.

But when you move on to hard water, it has very high levels of contaminants, TDS, and other harmful chemicals and substances. As such, this water needs purification at more advanced levels, and RO purifiers come as the right choice for them. Moreover, you may need a combination of RO, UV, and UF technology for extremely hard water.

So, basically, different water types and the contamination level remarkably alter the right choice of water purifiers at your home. Besides this, there are other factors, like the chlorine content in the water and the odor. Water with higher chlorine content does not taste very palatable. Also, you would definitely not like to drink water that has a foul odor.

Given all these factors, it’s clear that not every water purifier is suited for every home. If you want a purifier that treats your water right, it’s important that you choose a purifier that is right.

Conclusion

Water is a basic necessity, and for your better health, it’s important that you drink clean and hygienic water that’s free from all contaminants and has minimal to no levels of TDS. This is possible only with water purification. But not every water purifier is suited to eliminate the contaminants and TDS from every type of water. So, it becomes important that you choose the right water purifier for your home.

With a good water purifier buying guide, the selection and purchase become pretty easy. So, check out a guide, check your water type and quality, and after due consideration, choose the water purifier that’s right for your home.

CategoriesGeneral Awareness Videos

Niagara water means tasty and sweet

#NIAGRAWATERSOLUTIONS#Niagra#niagra 💧@👉🏼Subscribe @👉🏼Like @👉🏼BellIcon🔔 @👉🏼Share নায়াগ্রার 💧 জল মানেই টেষ্টি এন্ড মিষ্টি 👍 Niagara water means tasty and sweet 👌 #NiagraWaterSolutions#niagra

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CategoriesGeneral Awareness Videos

Proper watering increases life expectancy by 10-15 years

#NIAGRAWATERSOLUTIONS 💧@👉🏼Subscribe @👉🏼Like @👉🏼BellIcon🔔 @👉🏼Share সঠিক জলপানে ১০-১৫ বছর আয়ু বৃদ্ধি Proper watering increases life expectancy by 10-15 years #NiagraWaterSolutions

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CategoriesGeneral Awareness Industrial Water Treatment

How can your Industrial Facility reduce Wastewater Discharge Volume?

We all can see populations rise and continue to tax waterways alongside the effects of climate change. So, increasing water-access fees and ever-tightening effluent regulations can all seem to create a losing battle for industrial facilities that are looking to keep ahead of the water-shortage curve. However, your facility, with a few preparations now to reduce wastewater volume and mitigate these future burdens, chances are your business will be able to better adapt to a water-stressed world.

Even though wastewater reduction solutions and industrial water conservation methods largely vary from industry to industry, there are some things all industrial facilities can do to ensure conserving water and reducing discharge waste is part of their short- and long-term strategies.

In this article, we’ll be looking at how industrial facilities are curbing wastewater discharge costs by reducing the volume of wastewater they have to discard—and, in turn, saving on sewer connection and transport fees, which can be steep depending on the level of contaminants present in your waste.

Many of the solutions below are similar to some information we’ve shared in a previous industrial water conservation post. This article, however, will focus on what facilities can do to reduce the volume of wastewater specifically, not just water usage overall. Many of the methods are throughout the entire production and manufacturing process. Here are the ways your industrial facility can reduce its wastewater discharge volume.

Identify problematic runoff and connection issues

One of the many ways industrial facilities can reduce their wastewater volume is by identifying any point of the process were groundwater, rainwater, or fractured pipes might be leaking freshwater or untreated process waster into your effluent streams. What might seem an unlikely place to find and reduce excess wastewater, it’s fairly common for extra water from these sources to seep directly into your effluent stream.

It’s also common for facilities to find that process piping has been routed inefficiently or that valves and connections are fractured or poorly sealed, which can all pose an issue when a facility is looking to tighten up its wastewater volume. Complete a thorough water usage audit that takes into consideration how much water is used at various parts of your production process and continue to set goals to tighten them. Also, keep in mind that some of your processes and wastewater will evaporate. Each small fix can add up to big savings over time.

Modify equipment and install water-saving devices like meters

It’s important to understand your facility will be using water in more places than just in its production processes. In addition to these other water uses (think high-efficiency toilets, drinking water units, and sinks), ask yourself if it is possible to lessen the water flow, replace water-intensive equipment with other technologies, or use water from one part of the process in another. Sometimes there are portions of a production process that can use a lesser quality of water.

Also, metering devices can help to reduce wastewater volume by ensuring levels are continually audited. Some can be used as automated shutoff mechanisms or overuse alarms, and they can go a long way in helping assess needed makeup water for cooling towers and boilers. Track the usage and adjust based on the device’s findings.

Reuse and recycle water at various parts of your operation

Implementing water recycling and reuse as part of your process can greatly reduce the volume of effluent your plant will have to discard. This approach can come with a high investment up front, but the long-term savings are often worth the cost. This is becoming especially true, too, with the growing call for facilities to be more responsible with their water usage, which is, as mentioned earlier in the article, taking the form of costly fees and stringent regulations. For this reason, many facilities are setting goals to make sure they’re not taking more water than they can (cleanly) replace. A thorough analysis can help determine which recycling measures will pay off for you.

Shift to waterless processes when able

Countless technological advancements are replacing water-intensive processes with those that have little water or even no water at all. Look into some of these solutions for your facility.

When it comes to treating your process water and wastewater for specific instances where you can’t discharge water at all, your facility might benefit from zero liquid discharge, a range of technologies that work to recover all fluid waste, leaving the facility with a solid cake of waste that is easier to discard.

Incorporate biological wastewater treatment technology

If your industrial or municipal facility generates organic-laden wastes, biological wastewater treatment might be an appropriate choice for your facility. These systems can be efficient and economical technologies for breaking down and removing organic contaminants from wastes such as those produced in the food and beverage, chemical manufacturing, oil and gas, and municipal industries. Bonus for facilities able to use this method: it’s a natural process that produces useful biogas that can be used as energy for other parts of the facility’s process.

CategoriesGeneral Awareness

How to determine the best water purifier?

With a multitude of options available in the market, consumers are often confused when it comes to buying a water purifier for their homes. It is an important decision as it involves ensuring good health and well-being of our families. So how do you go about picking the best water purifier for your home? Let’s take you through 5 simple steps:

1. Water Quality-check

Find the source of your tap water and get it tested for hardness, salinity and TDS (Total Dissolved Solids) levels. If the TDS levels are under 500 ppm, the water is consumable; but if the level of dissolved solids is beyond 1000 ppm, the water is hazardous and unhealthy. Identifying the source of your tap water is the first step in choosing the best water purifier.

  • Municipality water TDS averages around 200ppm.
  • Groundwater TDS ranges between 200 to 500ppm.
  • Borewell water TDS is usually more than 500ppm.

2. Purification Technology

Depending on the quality and source of water, you can choose from a range of water purifiers. RO (Reverse Osmosis) purification technology works best for water with higher TDS levels of more than 500ppm. RO technology filters heavy metals, particulates, minerals through selectively permeable membranes and provides purified water. If TDS is less than 200ppm, you can choose UV (Ultra-Violet) filtration technology which can remove impurities while retaining key minerals. For a TDS level between 200-500ppm, we recommend using a Niagra’s Mineral RO + UV device, that can add the essential minerals such as Calcium and Magnesium back in the RO purified water. Explore the entire range of Niagra Water Treatment Solutions.

3. Storage Capacity

Analyze your family’s daily water consumption to understand the required capacity of your water purifier. In places where there are frequent electricity fluctuations, purifiers with high water storage work well.

  • For 2-4 members we recommend a storage capacity of 5-8 litres.
  • For 4-6 members we recommend a storage capacity of 8-10 litres.
  • For more than 6 members, a storage capacity of 10 litres is recommended.

4. Additional Safety Features

While selecting a water purifier, look for more evolved features and functionality. For instance, filters are an essential part of water purification, but we often overuse them and end up drinking impure water. Hence, it’s crucial to change them as and when they expire. Niagra’s water purifiers come with a Double purity lock that warns you 15 days before the filter expiry and the auto-shutoff feature cuts off the water supply if the filter is not changed despite the warning. This guarantees 100% pure water in every glass of water.

5. Service & Maintenance

Water is purified through various filters that need maintenance at regular intervals. While buying a water purifier you should always consider the promptness of service and overall maintenance cost. While most of the water purifiers have an AMC (Annual Maintenance Cost), Niagra’s maintenance cost directly depends on the consumption/usage of water and not on a fixed yearly cost. Hence, with Niagra’s water purifiers, you can save more on annual costs while enjoying hassle-free customer service with its huge service network.

The Conclusion

A proper research keeping in mind the above five steps will help you choose the best water purifier for your home to ensure the health and wellness of your family.

CategoriesCovid-19 General Awareness

The Water Cycle – What Treatment Professionals You Need to Know to prevent Covid-19?

As the global health community tracks the spread of this virus, it’s important for water and wastewater professionals to keep updated on potential impacts.

It’s hard to miss the headlines. The recent outbreak of novel coronavirus (2019-nCoV or COVID-19) has dominated news cycles in recent weeks. The World Health Organization (WHO) is calling it “public enemy number one.” But what information do we have that is related to coronaviruses in water and wastewater systems? And what can water- and wastewater-system operators do to protect public health?

Modern water and wastewater treatment systems play an important role in public health protection. With the potential for environmental transmission, water and wastewater operators need to know the potential for survival of this type of virus in water and wastewater treatment systems.

Coronaviruses, named for the crown-like spikes on their surface, were first identified in the mid-1960s. Currently, seven coronaviruses are known to infect people and make them ill. Three of these — MERS-CoV, SARS-CoV, and COVID-19 — emerged in the last 20 years and are examples of how some coronaviruses that infect animals can evolve to infect humans. COVID-19 is a new variety of coronavirus and is an enveloped, single-stranded (positive-sense) RNA virus.

So, what is the fate of coronavirus in sewage and wastewater treatment plants? Or in the aquatic environment? And should we be worried about the efficacy of water treatment filtration and disinfection processes for coronavirus removal and inactivation?

The short answer: No — if we take proper precautions and risk considerations.

The long answer: This is a new virus without an extensive body of literature on the effectiveness of water and wastewater treatment processes. And real-life experiences will vary due to water quality and treatment plant details.

According to a 2008 University of Arizona study, coronaviruses have not been found to be more resistant to water treatment than other microorganisms such as E. coli, phage, or poliovirus — which are commonly used as surrogates for treatment performance evaluations. Results from bench-scale studies suggest that the survival of coronaviruses is temperature dependent, with greater survival at lower temperatures. Therefore, coronavirus is expected to be reduced in raw wastewater and surface waters in warmer seasons.

How is it transmitted?

Human viruses do not replicate in the environment. For a coronavirus to be transferred via the water cycle, it must have the ability to survive in human waste, retain its infectivity, and come in contact with another person — most likely via aerosols. Findings suggest that COVID-19 can be transmitted through human waste.

Should a major virus pandemic occur, wastewater and drinking water treatment industries would face increased scrutiny. Utilities would need to respond rapidly to minimize occupational and public health risks based on the available evidence. Wastewater effluents would possibly impact recreation, irrigation, and drinking waters. While wastewater treatment does reduce virus levels, infective human viruses are often detected in wastewater treatment plant effluent.

Information for wastewater treatment plant operators

Typically, human waste entering a sewage system is carried through an underground pipe system to a municipal treatment plant. Wastewater treatment plants receiving sewage from hospitals and isolation centers treating coronavirus patients — and domestic sewage from areas of known large contamination — may have elevated concentrations of viruses. Wastewater is treated by a variety of processes to reduce the pollution impacts on nearby receiving waters (lakes, rivers) and disinfected.

Currently, major data gaps exist on the potential role of the water cycle in the spread of enveloped viruses. The lack of detection methods for these strains of viruses is a main reason this type of information is still relatively unknown. Most detection methods are designed and optimized for non-enveloped enteric viruses, and there just isn’t enough information available.

In general, secondary wastewater treatment is credited with removing 1-log (90 percent) of viruses, though broad studies suggest the level of virus removal is highly variable, ranging from insignificant to greater than 2-log removal (99 percent). Because of this variability, the primary process for the inactivation of viruses in wastewater treatment is chemical disinfection (e.g., chlorination) and/or by ultraviolet light.

Drinking water treatment is an effective barrier

Surface-water treatment plants with upstream wastewater impacts are the most susceptible to having coronavirus contamination in the raw water supply during, and after, an outbreak. Viruses are exposed to several potentially inactivating stresses in surface waters, including sunlight, oxidative chemicals, and predation by microorganisms. Generally, enveloped viruses are more susceptible to common drinking water disinfectants than non-enveloped viruses.

Based on published research, water treatment processes that meet virus removal/inactivation regulations are effective for coronavirus control.

For example, drinking water quality guidelines from Health Canada note conventional treatment with free available chlorine can achieve at least 8-log inactivation of viruses in general. Of course, disinfection performance must be continuously monitored (e.g., turbidity, disinfectant dose, residual, pH, temperature, and flow). Optimized conventional filtration can achieve 2-log (99 percent) virus removal and is just one of many processes water treatment facilities incorporate to make our water safe to drink.

Modern drinking water treatment plants are well equipped to remove and disinfect viruses through filtration and disinfection processes.

So now what?

By and large, these viruses are not considered a major threat for the wastewater and water industries due to their low concentrations in municipal wastewater and high susceptibilities to degradation in aqueous environments. According to new OHSA guidance, there is no evidence to suggest that additional, COVID-19-specific protections are needed for employees involved in wastewater treatment operations.

The WHO found that risk communication and community engagement (RCCE) has been integral to the success of response to health emergencies. Action items related to coronavirus include communicating about preparedness measures and establishing a system for listening to public perceptions to prevent misinformation.

CategoriesCovid-19 General Awareness

Can Ozone Therapy be an option to prevent Covid-19?

The rapid and pandemic outbreak of SARS-CoV-2 causing COVID-19 recognizes in the containment of the infection and in its therapeutic management the two most addressed and challenging topics. Recent guidelines suggest that person-to-person transmission (droplets and aerosol) are the main transmission routes and that, although less likely, also contact with surfaces and objects on which the virus is present can represent a risk. With regard to treatment, many clinical trials are ongoing worldwide, but no specific antiviral treatment is unanimously recognized leaving to supportive care and symptoms management the most recommended approach.

Ozone has extensively been studied in medicine and currently applied at different possible concentrations in various disciplines such as dentistry, dermatology, acute and chronic infectious diseases, and pneumology. Chemically it is formed by a triatomic dynamically unstable molecule of oxygen that in gaseous form has a half-life of about 1 h at room temperature, rapidly reverting to oxygen. Regarding ozone-related risks, as environmental pollutant it has been shown to reduce maximal transpulmonary pressure, increases respiratory rate and decreased tidal volume as well as significantly increases mean airway resistance and specific airway resistance possibly contributing to increased Influenza A infection. Furthermore, it has been shown that the lipid peroxidation operated by high concentration of ozone at the alveolar level can cause strong structural alterations of the surfactant, in a dose and time dependent manner. Strong fusion of lamellar bodies (LBs), associated to the appearance of increasing concentrations of densely coiled LB-like shapes in the alveolar lavage, are resulting ultrastructural changes in type II alveolocites. At the same time, it occurs also a strong reduction of organized tubular myelin structures. This is likely due to the fact that medium-high concentration of ozone induce alveolar lesions as consequence of phospholipid peroxidation, causing time-dependent alterations in the organization of stored, and secreted surfactant membranes; as a result, administration of gaseous ozone must be avoided.

For medical purposes, ozone can be administered parenterally with minimal side effects, beside the only exception of not being injected intravenously as a gas because of the risk of embolism. As a powerful oxidant, when ozone comes into contact with blood or other body fluids, it releases reactive oxygen species (ROS), and lipid oxidation products (LOPs) both of which are responsible for the biological results. The main form of ROS is hydrogen peroxide (H2O2) which is easily transferred from plasma into the cells. When H2O2 abruptly appears above the threshold medical concentration in the cytoplasm of cells it represents the triggering stimulus for the possibly simultaneous activation of different biochemical pathways in erythrocytes, leukocytes and platelets in addition to other numerous biological effects, such as antimicrobial, immunostimulant, and antioxidant ones. H2O2 is then suddenly inactivated into water by the high concentration of glutathione (GSH), catalase (CAT), and glutathione peroxidase (GSH-Px) enzymatic systems, reducing its harmful potential. Although the exact mechanism of action of ozone is far to be fully elucidated, it has been characterized to have different biological properties. For example, it has been showed to facilitate wound healing by promoting the release of oxygen, platelet-derived growth factor and transforming grow factor β. Ozone is also regarded as capable to activate the immune system increasing the production of interferon and interleukin-2 and decreasing tumor necrosis factor (TNF) levels. In addition to this, ozone stimulates both the red blood cell glycolysis rate leading to an increased amount of oxygen released to the tissues and the Krebs cycle resulting in an increased production of ATP. It also reduces significantly NADH concentration and helps to oxidize cytochrome C, thus stimulating oxygen metabolism, as well as it shows anti-inflammatory and possible cytoprotective action interacting with NF-KB and Nrf2 transcription agents. The paradox that ozone exerts an antioxidant response (known as oxidative preconditioning) capable of reversing a chronic oxidative stress is related to the stimulation of production free radical scavengers and cell-wall protectors such as glutathione peroxidase, catalase, and superoxide dismutase.

Through the oxidation of double bonds, ozone possesses the unique ability to inactivate biological contaminants, including viruses. Ozone disrupts the integrity of the bacterial cell walls causing their lysis and death, and is able to effectively control spore germination of various dermatophytes (14, 15). Data obtained throughout years of research suggest that ozone inactivation of viruses occurs primarily in by lipid and protein peroxidation. Lipid peroxidation is initiated by different ROS, including H2O2. Through oxidation of the unsaturation along the hydrocarbon chain of fatty acid component of phospholipid membrane it causes severe structural and functional damage to the lipid bilayer of the plasma membrane. On the other hand, protein peroxidation is due either to interaction of protein with ROS or by interaction with secondary byproducts of oxidative stress; both of them cause irreversible oxidative changes that inhibit normal cellular mechanisms. These include loss of aggregation and proteolysis control, changes in enzyme-substrate binding activities, and modifications in immunogenicity. Protein peroxidation particularly seems to play a key role in the inactivation of non-enveloped viruses, such as adenovirus, poliovirus and other enteroviruses. Murray and coworkers demonstrated few years ago the efficacy of ozone against a variety of simple and complex viruses, including enveloped, non-enveloped, DNA, and RNA ones. Vesicular stomatitis Indiana virus (VSIV), adenovirus type-2 (HAdV-2), and selected strains of herpes simplex virus type-1 (HHV-1), vaccinia virus (VACV), influenza A virus (FLUAV) pools were exposed in vitro to a minimal amount of ozone (from 800 to 1,500 parts per million by volume), and it was effective in inactivating all these viruses. More in detail, enveloped viruses such as VSIV, HHV-1, VACV, and FLUAV showed great sensitivity to ozone while the non-enveloped HAdV-2 was more but not completely resistant to ozone. The results of the study suggest a direct and irreversible damage and destruction of the lipid viral envelope and protein capsid confirming the ability of ozone as a tool for the control of some viruses. Ozone therapy has recently been suggested as a possible economic and easily available further option for Sars-CoV-2 thanks to its immunomodulatory, anti-inflammatory and biocide action and to the nitric oxide associated and dependent antiplatelet effect. About the relationship between ozone and Sars-CoV-2 is also worth noting the “triangle” existing among human angiotensin-converting enzyme 2 (ACE2), that both is a receptor facilitating virus entry and, as fundamental component of renin-angiotensin system, also protects from acute lung injury, and Nrf2 pathway modulation, influencing ACE2 activity and being in turn influenced by ozone. Interestingly, the virus has also been found in substrates other than respiratory secretions, such as fecal swabs and blood, suggesting a possible interaction with the virus in case ozone is in the blood. Recently, the Italian “Istituto Superiore di Sanità” (National Institute of Health) answering to Prof. Franzini, member of “Scientific Society of Oxygen Ozone Therapy” Directive Board, recognized that oxygen-ozone therapy, after Ethical Committee approval and under patient informed consent, could represent a possible option. Remarkably, in this regard, two recent reports of the “Scientific Society of Oxygen Ozone Therapy,” referring to patients affected by COVID-19 undergoing immediately after hospitalization, in addition to standard therapy, also to autohemotherapy with ozonated blood, furnished very encouraging results. Moreover, also other reports hypothesizing the use of ozone in COVID-19 are being progressively undertaken and published.

Gas concentration, route of administration, safety, stage of the disease in which administer it, patients’ selection, contraindications, concomitant administration of antioxidants, etc., are some of the aspects that need to be further addressed with regard to its eventual use in COVD-19 patients, but in the authors opinion ozone therapy is an option that could deserve to be explored while waiting for specific treatments and for a vaccine.

CategoriesGeneral Awareness Uncategorized

Why Water Treatment is necessary in today’s world?

Water treatment is an expansive term that covers a wide scope of methods and cycles that are applied to water sources. The meaning of water treatment is an interaction that makes the water more adequate for a particular end-use. That implies water treatment can cover a colossal scope of utilizations, including drinking water, water for modern use, (for example, in creating paper, synthetic substances, and vehicles), and super unadulterated water, which is utilized for semiconductor and drug purposes.

Yet, what happens when water isn’t dealt with as expected? With regards to homegrown use water (otherwise called consumable water), it can have deplorable outcomes if the water hasn’t been suitably treated at the plant. Numerous hazardous waterborne infections represent a genuine danger to human and creature wellbeing whenever ingested. In the Industrial Revolution, many significant urban communities like London, Paris, and Frankfurt started the development of huge scope public sewer attempts to help successfully eliminate wastewater and sewage, and treat it in a lot more secure path than had been endeavored already, following a few flare-ups of illness that got connected to tainted water.

Waterborne Diseases

Untreated water is a favorable place for a few perilous waterborne infections and was a genuine risk to general wellbeing for a long time. The modernization of sewer frameworks and appropriately treated drinking water have generally killed these in the past; however, they are as yet present and ought to not be disparaged for their seriousness. Waterborne sicknesses represent a genuine danger to wellbeing in immature nations were appropriately treated water may not be promptly accessible.

These sicknesses are completely brought about by inappropriate sterilization and perilous water being ingested by individuals, and were once basic throughout the planet:

Hepatitis A: Causes queasiness, spewing, jaundice, fever, loose bowels and can bring about intense liver disappointment.

Typhoid: Causes fever, stomach agony, rash, and migraines.

Looseness of the bowels: Causes extreme looseness of the bowels, fever, and stomach torment.

Cholera: Causes extreme the runs and parchedness, fever, stomach agony, and spewing.

Leptospirosis: Side effects incorporate fever, rash and body torments. Can transform into Weil’s Disease which brings about meningitis, kidney disappointment, and jaundice. Creatures are additionally helpless.

Legionnaire’s Disease: Legionnaire’s is a type of abnormal pneumonia. It causes hacking, windedness, fever, muscle torments, and cerebral pains.

Giardiasis: Causes shortcoming, stomach issues, spewing, and looseness of the bowels.

The Conclusion

As you can see, water is invaluable to us. So, it makes sense to consume fresh water each time 365 days a year. Luckily, Niagra is a company that deals with all sorts of water treatment solutions whether you need it in your home or your workplace. Contact us for a demo today!