Saturday, March 1, 2014

Water Treatment For Residential Areas

Most of the residences get heir supply of water from municipal systems of water. A few of the homes use private water sources for their water. If you are using a private well or other private source that is not a public water supply, you are responsible for maintaining clean and safe water for your family to use. These private water sources are not regulated by the state and local standards that are applied to the municipal water sources.

The problems that you can face as an owner of a private will can be very big. Most of the things that you will find in well water are natural for the water and do not usually because any health concerns. You can, however, find some toxins that have been introduced into the water supply that can be dangerous to drink and also for humans to use. To make sure that your family is safe from the contain microorganisms in the water you drink, you will need to provide them with a water treatment system for residential use.

What does a residential water treatment system do?

A water treatment system that is designed for residential use completes a process of ridding your water of contaminants that it may have in it and thereby making it safe for drinking by you and your family.

Each of the water treatment systems for use in residences vary greatly. Some only get rid of certain substances in the water. Other systems can only provide relief from problems like hard water and does nothing to get rid of the toxic contaminants in the water.

Installation of these residential water treatment systems are also each different than the other. When you are talking about the installation of these water treatment systems you are coming into two different categories. They are the point of entry and the point of use device. The two vary by the amount of protection they give each home from contaminants.

The point of entry device treats all the water that is coming into the home. This gives each faucet clean water that is ready to be used. The point of use device focuses on the water that is flowing from one faucet only.

How To Buy Residential Water Treatment Equipment

When you are in the market to purchase a residential water treatment system, you will need to find out exactly what is in your water so you will be able to find the right equipment to remove those things.

You may have a hard water problem. Your water is full of high amounts of minerals like magnesium and calcium. Hard water will make it very difficult to wash clothes. The chemicals also create deposits on your pipes that will cause the water flow to be reduced. You will need to provide your home with a water treatment system that will deal with this problem only.

Your private well might be close to a sewage or disposal area like a septic tank. You might be concerned that the contamination from this area may cause your water to be unhealthy. Some of the waste from this area could go into your drinking water. You will need to focus on the main issue and that is to rid the water of microbial contamination. You will want to purchase a water treatment system for residences that will remove bacteria, fungus, parasites, and viruses.

Thursday, February 27, 2014

Treatment Processes For Sewage Water

When you hear the word sewage, you think of the nasty and contaminated water that would not even be considered safe or clean for humans to drink or to use for anything. If the sewage water is not cleaned before it is gotten rid of, the environment could suffer from it. These are the reasons for sewage water treatment processes in the sewage systems.

What Is The Treatment For Sewage Water?

We all know that sewage water treatment is a process for cleaning the water but, we want to know about that process and the purpose behind it.

Treating sewage water is a method that is used to take the contaminants in the water out. The contaminants that are removed will be anything from human waste solids to chemicals and biological that is in the water.

When the water goes through the sewage treatment methods, the waste water is changed into two different types of waste that is much safer to get rid of and to recycle for the environment. Those two wastes are solid waste, known as sludge, or waste stream, known as treated effluent.

Where Does The Sewage Water Come From?

The water from the sewage is made from many things. Homes and commercial and industrial business contribute tot he sewage also. The best way for you to get an example of the sewage water is to think about your septic tank. Sewage water is also made from onsite package plants and water treatment systems that are constantly moving.

The fact of the matter is that the sewage water may contain very dangerous and toxic substances and it will need to be cleaned. This water that comes from industrial companies is especially susceptible to toxins. A system for treatment of the sewage water may be added close to the reason for the sewage water or can also be put in farther away and only travel through a maze of pipes or pumping stations to the plant for treatment.

Treating The Water from sewage

The average process for treating sewage water has three stages to it. They are the primary, secondary, and tertiary treatment stages. Listed below are each one and the information on how they help the process for treating sewage water.

The First Stage

The primary stage is the first of the three to be completed. It hands the solid waste and removing it from the water. Solid waste may be oil, grease, fat, sand, grit, and course solid material. The primary stage involves four other smaller stages. They are:

1. The removal of influx or influent

2. The removal of the sand and grit

3. The pumping out of the raw sewage

4. Sedimentation

The Second Phase

The secondary stage involves the part of the process for treating the sewage water that gets rid of any solid waste that may be smaller than what the first phase can handle. This phase also concentrates on the biologics found in the sewage water and having them to degrade. This biological would include waste from humans, waste from food, detergent and soap.

The Final Phase

The tertiary phase is the last stage in the sewage water treatment process. It is definitely harder to complete than the first two parts. It will involve the following methods:

1. Water filtration

2. Lagooning the water

3. Making or utilizing wetlands

4. Removing the nutrients

5. Removing the phosphorous

6. Water disinfection

Chlorine Dioxide for Water Treatment

Now nearing its 200th birthday, the use of chlorine dioxide has been developed and honed over the years and it's widespread in water treatment industry. In industrial water treatment, it's main use is as a primary or secondary biocide in drinking water treatment. Where a water supply contains traces of organic contaminants, ClO2's selective oxidation of organics (without chlorination) reduces the taste and smell problems caused by disinfecting the water. By comparison, conventional chlorine treatment creates that classical swimming pool odour when it reacts with organic contaminants. An indication of the many potential uses of this widely used gas is gained from the US EPA list of approved use applications:

  • Industrial Cooling Water Treatment, Heat Transfer Systems (Evaporative Condensers, Dairy Sweetwater Systems, Hydrostatic Sterilizers and Retorts, Coolers, Warmers and Bottling Plants), Service Water, and Auxiliary Water Systems: For control of bacterial slime and algae in industrial recirculating and one-pass cooling systems.
  • Food Plant Process Water Treatment: For odor and microbial control in typical food processing water systems such as flume transport, chill water systems, and hydrocoolers.
  • Controlling Microbial Population In Poultry Processing Plant Waters in Federally Inspected Plants:
  • Public Water Systems: As both an oxidant and a disinfectant in drinking water treatment under 40CFR141.
  • Aqueous Systems For CIP Cleaning: As an antimicrobial agent in the recirculating cleaning solution.
  • Bacterial Slime Control in Paper Mills: In controlling microbiological growth in white water paper mill systems. to maintain control.
  • Mollusk Control in Water Systems: For mollusk control in commercial and industrial recirculating and one-pass cooling water systems.
  • Wastewater Treatment: As an oxidant in wastewater treatment.

Chlorine dioxide is particularly effective in controlling legionella bacteria, the cause of Legionnaires Disease.

  • It controls biofilm which can harbour legionella and protect them from the effects of other biocides.
  • It has a broad spectrum of activity against a wide range of micro-organisms in water at a pH between 4 and 10, whereas traditional biocides like chlorine and bromine start to lose effectiveness at pH >7.5 and >8.5 respectively.
  • It controls amoebae which have been shown to be a source of legionella.

The use of chlorine dioxide in these industrial water applications has been inhibited by the need to produce it "on site". Chlorine dioxide generators are often unreliable and difficult to control in applications where small quantities of chlorine dioxide are required intermittently such as a cooling tower or domestic building H&C system or a food washing line.

Wednesday, February 26, 2014

The Best Water Treatment System

Water is undoubtedly the purest substance in the world capable of curing a host of illnesses. But because it is pure it can be contaminated very easily. This brings us to the point of a carefully designed water treatment system for your home or business premises. With the best system in place you can clean out harmful impurities with the potential to cause illness, and even death.

You can have two types of treatment systems installed, depending of course on what exactly you need purification for. Let us say you have a well you would like to protect from contamination. In this instance you ought to have a system that incorporates at least two different systems. The first entails having a kinetic degradation fluxion method of water filtration.

With this method you remove large sediments that are visible with the naked eye, as well as those that are microscopic. A combined process incorporating a combination f zinc and copper helps to remove dangerous electrons that may be trapped in water. In addition to eliminating these microbiological contaminants are also rendered harmless.

But this purification process is not going to be enough as it does not remove those other impurities that are not removed with the kinetic process mentioned above. Therefore the granular activated carbon filter will do you more good than you can imagine. Using a film of bituminous coal the microscopic impurities are filtered out of you drinking water, thereby eliminating heavy metal contaminants and pesticides.

When it comes to tap water an entirely different purification method is implemented. Without even investing a lot of money in an in-built filtration system you could boil the water before drinking it. Boiling has the benefit of killing bacteria and pathogens that can quit easily form a part of water. This is preferable for particular instances when you store water for drinking in the fridge.

So before placing your water in storage bottles just boil it in a kettle before hand. However, boiling water is not really good enough. It is for this reason that you should actually use the distilling method. When you distill water you actually make use of the water vapor that you get when boiling water. So once it has condensed it will be safe for drinking, a lot safer than just boiling it.

On top of this you can also use reverse osmosis, a process that involves passing water through a semi-permeable membrane. Such a membrane extracts the microscopic particles in water, but it is not always safe. With time the membrane can deteriorate in quality, resulting in harmful pathogens remaining in water.

Tuesday, February 25, 2014

Water Treatment Plant Design - Importance of Water Softening Plant

Water treatment plant design is directly synonymous with the method or step of treating or filtering water. This is mainly done to lessen the chances of contamination or reduce the scope of any germ build-up. There are certain vital steps that are taken to ensure the purity of it better known as mineral water. This water is again packed into bottles made of superior quality and high-grade reliable plastic variety. Water is packaged into the bottles only after making it suitable for drinking the various purification and filtration process that takes place in the water softening plant.

It is made such that there is no chance of germs or water-borne diseases inorder to ensure the safety of such drinking water form. This water should be made hygienic enough and appropriate for drinking containing all the beneficial minerals. Packaged drinking water also known as mineral water is now being considered a preferable choice among most buyers. This kind of water is best suited for those who are prone to diseases carried through water and provides much guarantee on the safety or purity

There are a lot of mineral water brands which manufacture such packaged drinking water in pet bottles. These bottles are further priced affordably and reasonably to cater to all sections of buyers. Water softening plant takes the help of various processes enabled in the Water treatment plant design to make it suitable for different kinds of industrial purpose. This kind of treatment will help in facilitating the varied processes for treating water and making it apt for drinking. It is later packaged by different manufacturing brands and labels after conforming to the stringent set standard norms or regulations. These pet bottles are sealed in tightly with a bottle cap to secure the safety of the present water inside the bottle.

These are manufactured in keeping with the client or consumer needs. It is best to avoid buying a bottle with an open seal because such seal is enough proof of the fact that the water inside the bottle has been tampered with or contaminated. It is also necessary for preventing any kind of damage or leak caused to the bottle. All kinds of water treatment process are used for distillation and filtration of impure water and those present in the natural environment or in the surrounding water bodies. This will further help in reducing the pollution levels and thereby maintain the ecological balance.

Some of these treatments are also used for distilling and filtering the water of polluted lakes, ponds, lagoons, sludge and thereby keeping intact the natural equilibrium. This water is purified such that it is free and devoid of any impurity, life risking chemicals or chemical substances. This is mainly done to remove the solid impurities or substances present in the water alongside bacteria, fungi, algae and fertilizers. This mineral water is later packaged and processed for the sale of such bottles.

Sunday, February 23, 2014

Why Home Water Treatment Systems Are Necessary

With the increasing levels of environmental pollution this planet is experiencing, people have started to take more seriously their habits in an attempt to minimize the risk of being dangerously affected by all the harmful elements that are present everywhere.

Pollution is all around and perhaps the most dangerous form of pollution is water contamination, for we may be constantly exposed to it without even knowing we are.

Water contamination is even worst than air contamination, because air eventually cleans itself thanks to the action of the trees, so reducing gas emissions to an acceptable level will eventually improve the quality of the air we breathe.

However, water pollution is a different thing: once water has been contaminated, the only way to clean it is to take active part in the process; there's no tree that can help us with water purification. This is where home water treatment systems come to play.

The goal of home water treatment systems is to remove all the toxins and other contaminants from water to ensure maximum purity, ideally preserving the benefits that are naturally present in water. There are many water treatment products that claim to be effective, however this degree of effectiveness is sometimes diffuse.

This is a major problem, because choosing the wrong home water treatment system is a sure way to be exposed to unwanted organic and/or inorganic poisons that can be very dangerous.

Luckily, there are many companies as well as concerned individuals that have realized the problems of choosing the wrong water treatment product, and have shared a lot of trustable information with the rest of us so we can be sure about what home water treatment system is best for us.

Basically, there are two main types of water contaminants: organic contaminants (those which come from something that is or was alive, like bacteria, fungus, microscopic plants, etc) and inorganic contaminants (minerals and chemicals, like heavy metals, chloride, etc). The effectiveness of a water treatment product is directly related to its ability to deal with these contaminants.

Most people agree that chemical water treatment products are not good for two main reasons: first, they only deal with living organic contaminants (i.e. 2 drops of bleach per litre of water acts as a disinfectant) without taking care of toxic chemicals and metals, and second, the use of such water treatment products actually increase the amount of toxicity in the water. So, a non-chemical home water treatment system is the best.

These systems are based on filtering, and there are mainly three types: steam filtering, reverse osmosis filtering, and activated carbon filtering. While steam filtering eliminates all the heavy metals and most the organic contaminants in water, there are some chemicals that are not separated from it even when it's in steam form, and subsequently they are not stopped by this type of filters.

Additionally, some living entities are capable of resisting high temperatures, so they are not eliminated. On the other hand, reverse osmosis effectively distillates water, which means it makes it extremely pure, but the process also eliminates good minerals that a healthy body needs, like calcium and potassium.

The best home water treatment systems use activated carbon filters, which have the unique property of retaining the harmful organic and inorganic contaminants, while letting the good minerals pass through. For this reason, most people around the world recommend activated carbon filters.

Home water treatment systems are necessary to protect your family and yourself from the perils of polluted water, and those systems using activated carbon filters are the best ones around. Don't wait until it's too late, choose and get a good home water treatment system now. Your family's health depends on you, don't turn them down.

You can read more about water filtration systems by visiting my website below.

The Public Water Treatment Process Can Be Improved With A Home Water Purifier

The public water treatment process is not perfect. When the processes used by the facilities are added to the steps available for use in the home, the result can be nearly perfect. 99% of most contaminants can effectively be removed.

It is possible to measure the effectiveness of filtration steps by adding a known amount of contaminant to a sample and then running it through the filter. The number of contaminants remaining in the filtered sample is again measured.

It is possible to remove 99% or more of contaminants like chlorine, lead, cysts, THMs, benzene and lindane. Independent laboratories like Underwriter's conduct that kind of testing at the request of companies that manufacture home filters. Not all companies request testing.

The first thing to consider when comparing the filters currently on the market is whether or not the claims have been certified. Manufacturers of home filters are not required to have their claims certified in most states. Only the better companies have testing done to certify their claims, because testing is expensive. So, buying a cheap filter is probably not your best choice.

The main reason the public water treatment process is imperfect has to do with size and output. The volume of water they need to treat is very large. The output or flow rate must be very high.

In the home, you are treating a small fraction of what your facility handles every day. You can handle a lower output even in the shower, if the pressure is high enough.

The flow rate must be reduced in order to ensure that each drop is cleaned. Dual filtration compartments are sometimes used by companies to make doubly sure that every drop is cleaned. The final compartment may include a carbon block with tiny holes less than one micron in size. That step is designed to remove the maximum amount of chemical contaminants and strain out cysts.

Your local water treatment process protects you from most bacteria, viruses and other pathogens except in the cause of flooding or a line break. In those emergencies, your facility will notify you. They might advise you to boil before drinking. One of the things that home filters cannot do is treat biological contaminants other than cysts, regardless of how much it costs or the steps included.

Some believe that the public water treatment process could be improved. With new innovations or technology that may be possible. But, right now, we need home filters in order to get the maximum protection.

Friday, February 21, 2014

Water Treatment - How To Go About It?

Do you know that about three-tenths of water present on earth is used by humans? However, it is unfortunate that millions of people on earth are spending several hours per day collecting water from distant and even polluted sources. We should stop wasting it so that there is enough supply of fresh water for those people too. One of the ways in which we could contribute to the noble cause is by treating dirty liquid from different sources and making it fit for human use.

These days there are various appliances and chemicals available in the market for water treatment. By using these equipment and chemicals, you can prevent its wastage. By installing conditioning devices you can turn waste water into more acceptable end-use. The main aim of all water treatment processes is to remove or reduce existing contaminants from the liquid.

How is it done?

There are various processes that can be applied here. The process that is involved in treating drinking water includes separation of solid debris by using physical processes like filtration and settling. There are various chemical processes too - like coagulation and disinfection. For these processes you might need different equipment and devices specially manufactured for the treatment. A few of the water treatment supplies that you can buy for conditioning the waste water in your house are given below:

1. Hydrogen Peroxide
2. Resin Bedding
3. Pro Rust Out
4.Rez Up Feeders
5. Iron Filter Base
6. Crystal
7. Potassium Promaginate
8. Resin Cleaners
9. Gravel base
10. Carbon Filter Base
11. Softeners and Salts
12. Iron curtain bedding

How does these help?

With the use of these devices and equipment water is made fit for consumption. The substances that are removed during the process of treatment includes - disease causing bacteria, fungi, harmful microorganisms, suspended solids, viruses and minerals - sulfur, manganese, and iron. The water conditioning supplies also effectively removes man-made chemicals and pollutants including fertilizers and pesticides from the liquid.

Which one works the best?

You should always remember that there is no unique solution or process for it; it is difficult to standardize a solution. It is therefore advised that you consult with a water conditioning and plumbing solution provider to know and install the right types of equipment and devices. Nevertheless, you can get feasible suggestions from an expert.

If you need devices, chemicals, equipment or any other services and supplies regarding water treatment, Kenosha, WI based The Water Store can provide you the best all-encompassing solution for all your related problems and queries.

Thursday, February 20, 2014

Advanced Oxidation For Water Treatment - Ozone Peroxide (Peroxone)

Advanced Oxidation Processes (AOP) are a class of processes that create the hydroxyl radical. In general these processes require combining at least two different chemicals or a chemical and UV to complete the reaction. Some of the common AOP are ozone/UV, peroxide/UV, Fe/peroxide and the subject of this article ozone/peroxide.

The hydroxyl radical, the neutral state of the OH- ion, is a short-lived compound with one of the highest electrochemical oxidation potentials. this makes it highly reactive to virtually all organic compounds except those that are highly chlorinated.

In water treatment the hydroxyl radical can be used to oxidize many organic compounds all the way to CO2. This can be useful for materials that can not be treated any other way. An example would be acetone, which is the oxidation product of isopropyl alcohol (IPA). This compound is not easily stripped or absorbed onto carbon, but it can be oxidized to CO2 using the hydroxyl radical. Unlike membrane processes which transfer contaminants from one stream to another, i.e. concentrate the contaminant, oxidation processes that completely remove the contaminant from water.

All advanced oxidation processes make hydroxyl radicals. The selection of the appropriate process is an engineering analysis to minimize the cost of formation with the most efficient use of the hydroxyl radicals produced. Ozone/UV AOP require that the water have a relatively high UV transmittance, i.e. that the UV light can readily pass through the liquid. In applications where this is not possible another oxidation process should be employed.

The ozone peroxide process combines ozone from an ozone generator that has been dissolved into water with hydrogen peroxide to form one hydroxyl radical. the combination of ozone and peroxide is sometimes call peroxone. The advantage of this process is that it is not dependent on the UV transmittance of the water and does not require the added capital cost associated with the UV reactor. After reaction nothing is added to the water except oxygen. So, the process is sustainable.

The ozone, a gas produced in an ozone generator, is often transferred to the water via fine bubble diffuser or venturi injector. Peroxide is added via metering pump. The venturi injector is becoming a more common option since i can provide excellent mixing of the ozone, water and peroxide due to the high shear forces inside the venturi. The injection can be done at a single point or multiple points. The latter may be necessary if the amount of ozone to be injected is large versus the volume of water.

The amount of peroxide required relative to the ozone is 0.5:1 to 1:1 on a weight basis. This ratio varies from application to application. The proper amount is determined from experimentation. It is important to note that both ozone and peroxide can react with organic matter in water directly, although not at the rate of the hydroxyl radical. Given the complexity of most applications careful laboratory and pilot studies are recommended.

It is also important to note that since hydroxyl radicals are not selective oxidants, they will react with any oxidizable species. Since the radicals are expensive to form, less expensive oxidants or methods should be used to deal with the easier to deal with materials that could waste the hydroxyl radicals. Examples would include iron, manganese, hydrogen sulfide, etc. The advanced oxidation process should be targeted at the higher value refractory materials in solution.

Ozone peroxide has been used in a number of applications commercially including the treatment of 1,4 Dioxane. A difficult to treat organic solvent found in contaminated groundwater. it has also been approved to treat municipal wastewater for reuse.

Given the simplicity and flexibility of the ozone peroxide process and the lack of any byproducts, it is a good option for wastewater treatment applications where refractory organics are present.

Tuesday, February 18, 2014

Whole House Water Treatment - Easy Steps to Cleaner Water

Everybody wants to drink good tasting water, but even more important, having pure water is vital to your health. That's why whole house water treatment is a hot topic. If you read the papers or surf the Internet you will easily learn how dangerous the water supply in many cities can be.

A way around this toxic water is to control the water filtration in your own home. As you may know, bottled water is also extremely inefficient, and can sometimes be of even lower quality than tap water. Still, tap water picks up contaminants on its way through the pipes to your house. But with proper water treatment equipment, municipal water can be made quite pure and safe.

First, you need to learn what THMs are and how they play a role in the filtration process. THMs are a byproduct of the chlorination process that most public drinking water systems use for disinfection. Chloroform is the primary THM that scientists are concerned about. Even the EPA does not allow public systems to have more than 100 parts per billion of THMs in treated water. However, some municipal systems have had difficulty in meeting this standard.

Second, make sure your system can filter water of the primary toxic culprits. Such bad boys of the water world includes: chlorine and chloramines, Volatile Organic Compounds (such as pesticides and herbicides), heavy metals like mercury, bacterial/viruses, and lastly fluoride.

Third, select a whole house water treatment system from a reliable manufacturer. When you're shopping around, ask the associate if the main filter unit can be easily replaced at least every three years. A dependable company will also offer you a complete guarantee and certification of their products.

Fourth, you need to know the details about installing water treatment equipment.

What many people do not realize is that most devices such as this need to be installed by a licensed plumber. Be sure and read the fine print when buying a system. They should come with all the installation instructions. But still many are hard to actually install and require assistance by a skilled professional.

After that, know what a system includes. The first important piece a system will include is the main filter unit. These will vary in size, but many companies are creating small to mid-sized units that are unobtrusive and still effective. The next items to look for are the pre-filter and installation kit. Also, make sure the pieces include a shut-off valve and the required hardware pieces.

Lastly, plan for the time it will take and the cost for the installation process. A whole house water treatment system normally takes 1.5 to 2.5 hours to install by a licensed plumber. Prices for plumbing services will vary from state to state but an average cost of $150 to $250 should be expected.

Monday, February 17, 2014

Books on Water Treatments and Water Engineering

I have compiled a list of book reviews on water treatments and water engineering technologies and procedures for students and professionals alike. Hope this will help for references and guidance in learning and solving problems.

Principles of Industrial Water Treatment - 1985 Drew

This book provides the reader with up to date information on various water treatment subjects. The authors from Drew Chemical Corporation managed to present the principles upon which various industrial water treatment practices are based, in an understandable fashion. With a broad coverage, this book addresses a wide spectrum of water treatment industrial practices.

Wastewater Engineering - treatment, disposal and reuse - Tchobanoglous and Burton

An extensive volume focusing more on wastewater and water recycling. A Good quality examples and solutions, discussion topics and problems it has more than thirteen thousand pages.

Basic Water Treatment - Thomas Telford Publishing - C. Binnie - M. Kimber - G. Smethurst

This book has been targeted for university students, and also for the practicing water treatment engineers, for whom it will be a useful reference book, and a mechanical engineers and chemists who need to put their specialized knowledge into a boarder framework. It provides essential background and is a useful first choice reference book for many aspects of water quality and water treatments.

Filters and Filtration Handbook - Christopher Dickinson

A book of practical guide for engineers, managers and specifiers, incorporating in volume essential and useful information on the physical water purification techniques filtration and separation.

Boiler Water Treatment FAQ - Praveen Verma

This book offers a fundamental understanding of boiler operations on a wide variety of boilers. It is geared towards the novice operator or for as a learning guide. Comes handy to solve any boiler problem quickly and easily.

Illustrating on the immense knowledge and experience of the most respected firms in the industry, this book is the first major reference on the science of water treatment in several decades. It covers both the practical and academic aspects of water quality analysis, treatment plant procedures.

Systems Analysis for Water Technology - By Gujer, Willi

This book deals in a to the point format the methods used to develop mathematical models for water and wastewater treatment. It provides a systematic approach to mass balances, transport and transformation processes, kinetics, stoichiometry, reactor hydraulics, residence time distribution, heterogeneous systems, and the dynamic behavior of reactors, error propagation, parameter identification, error analysis, process control, time series analysis, stochastic modeling and probabilistic design.

Written as a textbook it is mainly intended to support graduate and doctoral students in environmental engineering, but may also serve as a valuable resource for academics and practitioners similarly.

Procedures Water Treatment Plants Employ to Cleanse Waste Water

Have you ever thought about how much waste water, or water contaminated by elements such as human or industrial waste, we produce each day? Nobody managed to come up with a specific figure just yet, but observing water treatment plants should give you an idea. Several new methods of waste water treatment have sprung up over the years because of the amount of waste water treatment plants handle on a daily basis. The increase in human population over the past decade also increased the amount of contaminants in our water supply. Human waste like feces or urine is commonly associated with water contamination, but other substances like paint, rubber residue, and industrial waste contribute to it as well. The main purpose of waste water treatment is to purify contaminated water for reuse or release back into the environment. It's a necessary process, especially since we've been using up our environment's supply of clean water at an alarming rate. Here are a few of the processes treatment facilities use to purify water. Flocculation Flocculation is a process that involves adding a clarifying agent to waste water, which solidifies the contaminants and makes it easier to remove them. A clay flocculant can easily separate dye, heavy metals, latex, oil, phosphates, paint, adhesives, and ink from waste water. Filtration Filtration is one of the earliest methods of removing solid contaminants from waste water. Today's filtration processes involve the use of a chamber filter press, which processes the water in batches. The process begins with clamping a stack of filtration plates together, and running the contaminated water through the plates. As the process continues, the solid contaminant accumulates into a "filter cake" within the plates. This filter cake is removed before the next batch of water is processed. Dewatering Sludge Sludge is the semi-solid material left behind by industrial waste water treatments. In a way, dewatering is the opposite of filtration and flocculation. Instead of removing solids from water, dewatering removes water from solids. While the primary purpose of removing water from sludge is to process that water for reuse, it also serves another purpose. Sludge, like any other waste material, needs to be disposed. If you own a factory, you'll find dumping waste often requires a lot of work and funds, especially if it's something as heavy as sludge. Removing water from sludge makes it lighter and easier to dispose. Aeration Aeration focuses on treating contaminated bodies of water. It increases the oxygen levels of waste water, which promotes the expulsion of toxic gases and breaks down other contaminants. There are three types of aeration: - Subsurface aeration - This process infuses oxygen beneath the water's surface to improve its overall oxygen levels. - Surface aeration - This type of aeration promotes oxygen exchange at the surface of the water, and releases contaminants like methane or carbon dioxide. It involves the use of fountains, floating surface aerators, and paddlewheel aerators to agitate the water's surface. - Natural aeration - A combination of subsurface and surface aeration, natural aeration involves introducing plant life into the water. These plants restore oxygen to the water through the natural process of photosynthesis.

Domestic Waste Water Treatment Plant With Rotordisk System

There are several types of waste, municipal waste (household waste) that a fluid is one of the environmental problems that are very well interfere with the existing watercourse. It is because of some content in the waste, including chemical and biological rubbish. These residues can in principle be broken down by itself in nature, but it will take a long time for neutering. To accelerate the neutralization of the waste treatment system may need to decipher the biological and chemical substances in water that can be accepted by nature without harming fish or plants. Process that usually takes many years becomes nature, but with this system, it only takes 12 to 24 hours. Usually, the treatment plant consists of several processing units as follows: 1. First Phase of initial treatment Screen with a bar mounted in the tank that serves as the first filter processing solids settle or float and objects with a diameter that can be solved. The droppings of the cleaning process and the decision manually. 2. The first stage of processing Form of initial processing at the waste water treatment plant is the presence, acting as a floating bath oil or grease catcher. The bathtub is necessary because the waste can be processed waste is to be a servant in the kitchen. After passing through the flotation units then the units will be the primary clarifier tanks precipitated solid waste. 3. The second phase of treatment Basic process of waste is in this second phase of the experiment in the biological treatment process that the unit rotating biological contractor (RBC). The RBC is the degradation of pollutants, microorganisms that grow on the disk rotating disk (rotor disk) Microorganisms will grow and attach to form the rotor disk of biomass / biofilm. Gravity drainage of waste produced by the high water level in zone 4 below the water level in the 3, 2 and 1. Waste water will be treated by a biomass which grows on the band in each successive disc areas zone 1 to 4. Biomass grown in the rotor disk will have contact with oxygen in the air at the time was above the water resulting from the transfer of oxygen. The rapid growth of gangs in the biomass produced in the areas of disk and a progressive reduction in the next area. Physics of the biomass in Zone 1 will be more daring with the strands of a dark brown again. While the area is will thin with light brown or yellowish. Sewage in 4 is quite clear the contents of the BOD, and the suspension base material. In this area, most of the water is recycled back into the tank as soon as precipitation and partly transferred to a final resolution purpose. Recycling is to provide direct access to the water content of the BOD concentration of oxygen is low, but high enough so that it will help the weight of a new waste water treatment units. 4. The final processing stage The plant is the last unit of the final clarifier settling to reduce suspended solids and biomass pellets peeling. The water that comes out after going through the above steps, when it was discovered the body is clear and free of solids discharged into rivers on the right.

Water Treatment Plant Design - Importance of Water Softening Plant

Water treatment plant design is directly synonymous with the method or step of treating or filtering water. This is mainly done to lessen the chances of contamination or reduce the scope of any germ build-up. There are certain vital steps that are taken to ensure the purity of it better known as mineral water. This water is again packed into bottles made of superior quality and high-grade reliable plastic variety. Water is packaged into the bottles only after making it suitable for drinking the various purification and filtration process that takes place in the water softening plant. It is made such that there is no chance of germs or water-borne diseases inorder to ensure the safety of such drinking water form. This water should be made hygienic enough and appropriate for drinking containing all the beneficial minerals. Packaged drinking water also known as mineral water is now being considered a preferable choice among most buyers. This kind of water is best suited for those who are prone to diseases carried through water and provides much guarantee on the safety or purity There are a lot of mineral water brands which manufacture such packaged drinking water in pet bottles. These bottles are further priced affordably and reasonably to cater to all sections of buyers. Water softening plant takes the help of various processes enabled in the Water treatment plant design to make it suitable for different kinds of industrial purpose. This kind of treatment will help in facilitating the varied processes for treating water and making it apt for drinking. It is later packaged by different manufacturing brands and labels after conforming to the stringent set standard norms or regulations. These pet bottles are sealed in tightly with a bottle cap to secure the safety of the present water inside the bottle. These are manufactured in keeping with the client or consumer needs. It is best to avoid buying a bottle with an open seal because such seal is enough proof of the fact that the water inside the bottle has been tampered with or contaminated. It is also necessary for preventing any kind of damage or leak caused to the bottle. All kinds of water treatment process are used for distillation and filtration of impure water and those present in the natural environment or in the surrounding water bodies. This will further help in reducing the pollution levels and thereby maintain the ecological balance. Some of these treatments are also used for distilling and filtering the water of polluted lakes, ponds, lagoons, sludge and thereby keeping intact the natural equilibrium. This water is purified such that it is free and devoid of any impurity, life risking chemicals or chemical substances. This is mainly done to remove the solid impurities or substances present in the water alongside bacteria, fungi, algae and fertilizers. This mineral water is later packaged and processed for the sale of such bottles.

Significance and Types of Water Treatment Plants

Water, a natural and essential resource is undoubtedly the most indispensable part of our lives. Though it is pure by nature, the purity of water is diminished with the contamination of various sources such as chemicals, pollutants and several organic materials. It thus becomes unfit for drinking or other useful purposes. The use of water treatment plant is one among different methodologies invented by mankind to save this precious natural resource from being depleted. Water is treated to make it suitable for human consumption through various processes. The growing rate of population has led to the consequent reduction in the availability of this natural resource. Recycling is one of the best methods to meet the growing needs of the people. Water Treatment Plant- Types and Uses There are different types of water treatment plants which use various types of equipments to purify water from pollution, chemicals and so forth. Chlorination, coagulation, disinfection, sedimentation and filtration are some of the most common processes undergone in such purifying plants. Packaged water treatment plant: These plants are used to purify and reduce the COD levels in the water. Different processes are used in these plants which include precipitation, coagulation, ion exchange and reverse osmosis. These plants are widely used for separating suspended solids from river and lake water. Ozone based plants: One of the most widely used plants for treating pool water. The ozone based plants use ozone to disinfect the water and it requires no other variety of chemicals for purification. Waste water treatment plant: The waste water which is collected from industries, homes and other places are treated in the waste water plants for reuse. This is one of the most effective methods of reusing the natural resource. Various kinds of pollutants such as biological, physical and radioactive elements are removed from water to make it usable again. Bottle water treatment plant: The use of bottled water has increased manifold during the past several years. Today millions of people all over the world rely in the availability of pure drinking water which is packaged and bottled. This water is treated in specific plants before it is packed in bottles. Mobile plants: These treatment plants are ideal for treating water during certain calamities or emergencies. It can also be used as a mobile unit for the requirement of army regiment units. The mobile treatment plant is usually an extension of an existing plant in some area. It can be used for treating ground and surface water. Compact water treatment plant: Another most effective treatment plants for treating ground water is the compact plant. It is considered to be more economical and can be used to purify water on the spot. The compact plants can also filter even the smallest particles in water. The need and use of water treatment plant has been escalating ever since the growth of population and industries. Though our planet is surrounded by 70 percent of water, only one percent of water can be used for drinking purposes. It is important to conserve this natural resource from depletion.

Modern Industrial Water Treatment Plants

Water as we all know is a very precious natural resource. One can stay about a month without food, but it's hard to survive for a week without water. This invaluable liquid constitutes about 60% of our body mass, 70% of our brain, and 80% of our blood. Although it covers one-third portion of our planet, only 3% is fresh water, and out of that only 1% is readily accessible for human use. One can make out from these facts and figures, how critical resource this water is. In this context, water needs to be conserved and more significantly recycled or treated. It's not feasible to use less than usual quantity of water because it is required for both domestic and commercial or industrial activities. So, the practicable approach is to treat or purify it for reuse, and here comes the role of modern industrial water treatment plants. The contemporary and advanced water treatment plants that are available nowadays, thoroughly purifies the water by removing undesirable chemicals, materials, and biological contaminants from it. This water may come from sources like households, factories, business houses, etc. The modern water filtration plants are so designed that they purify the contaminants and retain the natural properties of water. A few out of these sophisticated water treatment equipment are as mentioned under: 1) Mobile Water Treatment System: This system is fitted on a mobile trailer with all the necessary water purification apparatus. Its benefit is that it can be taken to the application area with no delay. This system is appropriate for treating both surface and groundwater. It is a high performance and high efficiency equipment. Its primary types include mobile reverse osmosis system, mobile waste-water treatment system, and mobile drinking water treatment. 2) Surface Water Treatment System: This system or plant is used for filtering the downstream water, purification of water supply by municipal corporations, and so. This system is capable enough to free the water from any kind of suspended solid, colloidal matter, organics, iron manganese, etc. The primary components of this system include filters, chlorination equipment, and chemical feed system. 3) Bottled Water Treatment Plant: This plant is also known as drinking water treatment plant. It is one of the most significant types of plants as the water purified by it is directly used for drinking purpose. This plant not only filters the water, but also provides the facility of packing it in plastic bottles for selling purpose. 4) Swimming Pool Water Treating Plant: As the name suggests this plant is meant for decontaminating the water of swimming pool. Due to regular presence of human beings in the pool, microorganisms develop in them. This contaminates the water of the swimming pool and may cause several diseases. But, the swimming pool water treating plant eradicates all types of impurities. 5) Seawater Desalination Plants: Seawater desalination plant is designed to desalinate or remove salt from the sea water. As was said in the aforementioned sentence, there is abundant of water on the earth, but only a scarce amount is fresh or drinking water. This plant plays a vital role by transforming the raw and salty sea-water into treated and pure drinking water. This system primarily makes use of two methods for purifying the sea water, i.e., distillation and electro-dialysis (ion exchange).

Different Applications of Water Treatment Plant

A water treatment plant is a facility where water is treated to make it acceptable for the designated end-user. Various processes involved in this exercise, such facilities include sedimentation, filtration, chlorination, disinfection, coagulation and so on. Water purification equipments used at these plants are water filters, ozone generator, oil water separators, screening equipments, sludge treatment equipment and many more. Treatment of water is done for different purposes and there are water treatment plants serving different applications. Here is a brief discussion. Wastewater Treatment The most common application of a water treatment plant is to treat the waste water collected from homes, industries and many other sources. In order to make the waste water reusable, it is treated to remove physical, radioactive, chemical and biological pollutants. Sewage treatment and sludge treatment are the two most popular sub-types of wastewater purification plants. A decentralized wastewater plant is another common facility in this category. The water treated at this facility is reused for landscape irrigation and toilet flush supply. Surface Water Treatment A surface water treatment process is used to make surface water fit for municipal applications. Suspended impurities, colloidal matter and organic components are removed through processes like sedimentation, aeration, screening, disinfection and sand filtration. Containerized Water Treatment Plant To make pollutant-free water available in remote areas, the containerized treatment plant for water is considered as a suitable option. A single unit arrangement is used in this category of treatment equipments. Such plants can also be installed near military and mining camps. Environmental emergencies too ca be met with the help of such facilities. Ozone Based Water Plant These plants use ozone for water purification and useful to treat pool water or water present in the cooling towers. Ozone is an excellent disinfectant for variety of microorganisms, including Cryptosporidium and protozoan parasites. The main advantage of this type of plant is that it doesn't require adding any chemical to the water. Seawater Treatment Plant Seawater is treated to remove dissolved minerals and salts at a seawater treatment plant. Desalination, membrane separation, vacuum freezing and many such processes are employed at these plants. Saudi Arabia and the USA are the two countries with most number of seawater desalination plants. Package Wastewater Plant Treating wastewater using the process of aeration is done at a package wastewater treatment facility. These plants are available in different sizes and are used for applications in small and medium urban areas, remote mining areas, construction sites, recreational sites, educational sites and at various other sites. Bottled Water Treatment The popularity of bottled drinking water is increasing with passing time. The water is collected at the source, treated and packed in bottles that are supplied to the market. A bottled water plant is installed near the source to make water treating easy and economical. Mobile Water Treatment This is another popular facility designed by water treatment plant manufacturers. Reverse osmosis and mobile wastewater treatment are the methods used to treat water at these facilities. This plant is installed over a big trailer and moved to different sites.

Comparing the Application of Biological and Chemical Water Treatment Plants

Developing a method to meet local wastewater disposal guidelines poses a unique set of challenges to each industry. Adequate treatment is necessary to prevent contamination of receiving waters but overtreatment is prohibitively expensive. It is important to note that when industries disposal of wastewater, the goal is not to create drinkable water but rather water that will not damage the surrounding environment. Depending upon the industry, biological, chemical, or combination water treatment plants may be the most effective option. Chemical treatment plants are primarily used by the steel and metal industry, electronics industry, and other industries which have to deal with inorganic chemicals. The target pollutants of a chemical plant are metallic matter and other objects which alter the pH level of the wastewater. Depending upon the chemicals used in the treatment efficiency can have a large range. Since the target is metallic matter, the treatment efficiency is typically around 90 percent to 95 percent. The benefit of using a chemical water plant is it requires much less space than a biological plant. Additionally, the initial installation and operation of the plant is relatively easy. As a result, it doesn't need to be professionally managed by a third party. The chemicals typically used in a water treatment plant include sodium hydroxide, aluminum sulfate, polymer coagulant, and sulfuric acid. Biological water plants are primarily used by processing related industries. This includes the dying/textile industry, for/leather industry, food processing, paper industry, and domestic wastewater municipalities. The target pollutants biological water plants address are high polluted organic matters. This includes organics, inorganic matter, suspended solids, total nitrogen, and total phosphorus. There are several benefits of operating a biological water plant. The most notable benefit is the high treatment efficiency. Compared to chemical water plants, biological treatment is much more effective across the board. Additionally, chemical treatment phases can be added, altered, or eliminated depending on the type and property of the wastewater. This level of flexibility makes it easy for local municipalities and corporations to modify their water plants to generate the cleanest wastewater possible. Regardless of the type of wastewater treatment process utilize, there are normally 4 to 6 stages of treatment the water will go through before it is released. While these stages will vary based upon the type of plant and the treatment effectiveness goals, each stage offers a unique capability which is essential to the overall treatment process.

Water Treatment Chemicals - For the Regular Maintenance of Cooling Towers

Cooling towers require water for their continuous and uninterrupted operation. The water required for such a process can be to the tune of thousands of gallons per day. Therefore, the water used for the operation of these towers needs to be maintained at appropriate standards of hygiene. The health of the tower depends upon how well the water is maintained.

Generally, the water used in these towers can deteriorate because of environmental conditions. Some of the conditions that may take place at a cooling water plant are stagnation of water, growth of bacteria, formation of algae and others. Using untreated water in these towers may also cause legionnaire's disease, which can be life threatening in its most severe form.

The best way forward is to use specialty water treatment chemicals that will prevent the deterioration of water due to environmental conditions. Further, using water treatment chemicals will lead to better management of the tower installation and help deal with a range of related problems such as scale, corrosion, suspended particles, solids, and even bio-fouling. The range of these treatment chemicals is vast, which includes bio-dispersants, biocides, antifoams, scale and corrosion inhibitors and other multi-capable products.

Preserving cooling water quality is an important aspect of the overall safety process. Therefore, keeping the water safe and free from contaminants is an integral part of the daily maintenance routine at the cooling tower. Besides this process, it is important that workers exposed to the maintenance process wear proper clothing along with gloves and other protective equipment.

It is not necessary for the water to look unclean. Even clean looking water can in fact be unhygienic and can harbor bacteria. Therefore, along with using water treatment chemicals, it is necessary to test the water regularly for bacteria and other impurities. Therefore using water treatment chemicals is an important part of managing and maintaining the cooling tower.

Companies that do not take water treatment seriously risk the health and productivity of their own employees. Additionally, any outbreak of disease in the company could affect the morale of the workers. Such incidents could also attract bad press coverage, thereby reducing the trust that shareholders and the general public reposes in the company. Such incidents could also lead to litigation, making the company incur heavy costs.

Thus, treatment of cooling water should be taken as a priority activity. Water treatment chemicals are an important aspect of this management, and care should be taken that the water in these towers is tested and maintained regularly.

Sunday, February 16, 2014

Drinking Water Treatment Systems - Consume Only the Best

Drinking water treatment systems have become quite popular after studies and the media have revealed the various contaminants that still exist even after plants have treated water. The EPA standards may not be enough to verify safe and healthy water which is why methods are used in homes to fully remove threats while keeping the good natural minerals.

Knowing the System

Water purification is the main goal of drinking water treatment systems which involves the removal of contaminants, harmful microorganisms and chemicals from a raw water source. Most water is purified for direct human consumption although there is also water produced for specific purposes with corresponding treatment profiles. Some of the methods include filtration, water softening, reverse osmosis, ultrafiltration, deionization, ultraviolet light and powdered activated carbon treatment.

Drinking water purification system can remove suspended particles of organic material, parasites, viruses, bacteria, algae, fungi, toxic metals like lead and copper and particulate sand. Some processes like reverse osmosis also take away beneficial minerals like magnesium and calcium. Elective purification is also available such as taste in mineral extraction, appearance in iron encapsulation and smell in hydrogen sulphide remediation. Simple procedures like activated carbon filters and boiling may not be sufficient to remove other potentially harmful materials.

Treat the Source

Systems should incorporate processes relative to the source of your water. Ground water is described as water coming from deep ground which may have fallen as rain several years ago. Soil and rock layers filter the ground water naturally before it is pumped to treatment plants. This source has high bacteriological quality and rich in dissolved solids like magnesium, carbonates and calcium. Iron and manganese may have to be reduced to improve the taste and quality.

Upland lakes and reservoirs are found in the headwaters of river systems usually above human habitation and protected by a surrounding zone. Bacteria, protozoa and algae is usually present and the water has low pH. Drinking water treatment systems should focus on adjusting these properties. Rivers, low land reservoirs and canals usually have plenty of bacteria, algae and suspended soils.

About Pre-Treatment

To better understand the right type of drinking water purification system that suits your needs, know how water is treated in purification plants. The pre-treatment process starts with pumping and containment wherein most of the water is pumped from its source or driven into holding tanks and pipes. The materials used for tanks, pumps and pipes should be selected well to prevent contamination. Next is the screening which removes large debris like trash, leaves, etc. Some sources like groundwater may skip this process.

Storage and Conditioning

After screening, the water may be stored in bankside reservoirs for a few days or several months allowing natural biological purification to occur. Storage reservoirs are also advantageous during drought and transitory pollution incidents. Pre-conditioning involves treatment of soda-ash or sodium carbonate to precipitate calcium carbonate for water rich in hardness salts. Pre-chlorination is done to prevent foul organisms from growing.

Other techniques may also be incorporated to take out fine solids, microorganisms, organic materials and inorganic substances. The method selected will depend on the type and quality of water, the costs of treatment as well as the quality standards expected. Ask for a water quality report in your area to assess which properties still need fixing then choose the right drinking water treatment systems that will improve the condition and state.

Friday, February 14, 2014

How to Compare Water Treatment Systems to Find the Very Best Ones

You have made an important decision about your family's health. You are investing in a water treatment system for your home. So, which system is right for your needs? To be sure that you get the best quality product at the best price, you need to compare water treatment systems.

There are a lot of systems on the market these days that still use outdated technology, such as reverse osmosis and distillation processes. Those systems cost just as much as modern multi stage carbon filters, yet they do not deliver the high quality tap water that you and your family require for good health? Use the information that I've compiled on system types to compare for yourself. After reading the differences, I am sure you will be confident in choosing the best filtration system for your needs.

First, look at reverse osmosis systems. Reverse osmosis (RO) forces water through a porous membrane. The membrane filters out inorganic compounds that are harmful to the human body; however, it also filters out the trace minerals like calcium and magnesium that give water its good natural taste. The major problem with RO is that many pesticides and herbicides have a very small molecular size, so they pass through the filtration membrane. Thus, they remain in the water you drink. RO systems require a secondary carbon filter unit, high pressure and high maintenance to be effective. Even then, the process is only one half to one third as effective as a modern multi stage carbon filtration system.

Second, consider distillation systems. Distillation vaporizes tap water along with inorganic chemicals like lead, calcium and magnesium. The vapor rises into a cooling unit where it condenses back into liquid form. The problem here is that the lead remains. The human body is designed to run on calcium and magnesium, but not excess lead. A benefit of distillation is that the process kills bacteria. Then again, the system requires a secondary carbon filter unit to be effective against lead and high levels of other inorganic chemicals.

Tap water distillation treats water slowly, which results in a production cost that is even higher than that of a reverse osmosis system. In short, neither RO nor distillation systems produce healthy, safe, and cost effective water filtration that you need in your home for your family.

Compare water treatment systems, based on their effectiveness. Quality and cost efficiency rely on a product working optimally. To make sure you purchase the system that works best for your specific needs, buy a multi stage carbon filtration system. These systems produce the healthiest alternative at the best value for use in your home. Multi stage carbon systems use carbon filtration, ion exchange, and sub micron filtration. They filter out the most harmful contaminants.

When you compare water treatment systems, remember that multi stage carbon filtration systems treat water better than reverse osmosis or distillation systems do. They take out of tap water what the human body does not need. At the same time, they leave behind trace minerals such as calcium and magnesium that the body does need. Now that you have viewed the information, your conclusion is easy.

Water Treatment on Steroids

Water quality is becoming an increasingly important issue in the US and around the world. Pollution of both ground water and surface water has resulted from the disposal of pharmaceuticals, personal care products and industrial wastes into our water supplies. Often the contaminants are found in low concentrations and are very difficult to remove by conventional means. Even when conventional methods do work, for example with activated carbon treatment, we are simply moving the pollutant from the water to the carbon which must be disposed of in a safe manner. In recent years, advanced oxidation processes (AOP) have been developed that can treat these pollutants without further disposal issues.

So what are advanced oxidation processes or AOP? The most familiar oxidation process is fire. Oxygen combines with carbon based materials to form carbon dioxide, CO2. Advanced oxidation processes work in a similar fashion, but in the water. Organic compounds are oxidized, you could say burned, to CO2. This eliminates the toxicity of the pollutants and makes the water safe for drinking or other uses.

An AOP combines multiple oxidants like ozone and hydrogen peroxide to form a much stronger oxidant known as the hydroxyl radical. This compound is capable of oxidizing virtually any organic compound. There are a variety of advanced oxidation processes such as UV and ozone, UV and peroxide, peroxide and ozone, peroxide with various catalysts, etc. UV with ozone is an intriguing combination since the ozone can be made from air and the entire process does not require any purchase or storage of chemicals. The oxidants are produced on site and with proper design produce no byprodusts.

Advanced oxidation processes can be used to solve a number of difficult environmental problems not readily solved by any other method. One such problem is 1,4 Dioxane. This industrial solvent was widely used in industry and has ended up in groundwater. Ozone/peroxide based AOP have been successfully applied to treat the groundwater to safe levels permitting it to be used for applications like drinking water. Another example is MTBE, a gasoline additive. Leaks of gasoline have contaminated ground water with MTBE around the US. While the compound can be treated with simple oxidants like ozone alone, the byproducts can be more toxic than the MTBE. AOP can be used to break down the MTBE to safe compounds that require no further treatment. Advanced oxidation processes have also been used to treat byproducts of pharmaceutical and personal care products, algal toxins such as microcystin, pesticides and herbicides, and chlorinated hydrocarbons such as TCE and PCE.

While treatment with an AOP is not inexpensive, it is a relatively simple process. For a UV Ozone process, ozone is made in an ozone generator and mixed with water. Ozonation of water is a process that is used routinely in drinking water treatment. In fact, about 30% of all public drinking water is treated at some point with ozone. The ozonated water then passes through a chamber with UV lamps. The UV light reacts with the ozone to form the hydroxyl radicals which convert the pollutants to carbon dioxide and other minerals. Other than the pumps, there are usually no moving parts in the system. The treated water can be returned to the ground or whatever source it came from or immediately put to use.

The continued development and deployment of advanced oxidation processes will allow industry and communities to recover contaminated ground water or reuse water that was once discarded. With high quality water resources in decline in the US and elsewhere, AOP can improve both the quality and availability of water. The costs are certainly reasonable at around $0.10/1,000 gallons treated.

So, we have the technology to recover contaminated water and reuse water that normally would be discarded. All that is really required is the will to do so.

Wednesday, February 12, 2014

Domestic Waste Water Treatment Plant With Rotordisk System

There are several types of waste, municipal waste (household waste) that a fluid is one of the environmental problems that are very well interfere with the existing watercourse. It is because of some content in the waste, including chemical and biological rubbish.

These residues can in principle be broken down by itself in nature, but it will take a long time for neutering.

To accelerate the neutralization of the waste treatment system may need to decipher the biological and chemical substances in water that can be accepted by nature without harming fish or plants. Process that usually takes many years becomes nature, but with this system, it only takes 12 to 24 hours.

Usually, the treatment plant consists of several processing units as follows:

1. First Phase of initial treatment

Screen with a bar mounted in the tank that serves as the first filter processing solids settle or float and objects with a diameter that can be solved. The droppings of the cleaning process and the decision manually.

2. The first stage of processing

Form of initial processing at the waste water treatment plant is the presence, acting as a floating bath oil or grease catcher. The bathtub is necessary because the waste can be processed waste is to be a servant in the kitchen. After passing through the flotation units then the units will be the primary clarifier tanks precipitated solid waste.

3. The second phase of treatment

Basic process of waste is in this second phase of the experiment in the biological treatment process that the unit rotating biological contractor (RBC). The RBC is the degradation of pollutants, microorganisms that grow on the disk rotating disk (rotor disk) Microorganisms will grow and attach to form the rotor disk of biomass / biofilm.

Gravity drainage of waste produced by the high water level in zone 4 below the water level in the 3, 2 and 1. Waste water will be treated by a biomass which grows on the band in each successive disc areas zone 1 to 4. Biomass grown in the rotor disk will have contact with oxygen in the air at the time was above the water resulting from the transfer of oxygen. The rapid growth of gangs in the biomass produced in the areas of disk and a progressive reduction in the next area. Physics of the biomass in Zone 1 will be more daring with the strands of a dark brown again. While the area is will thin with light brown or yellowish.

Sewage in 4 is quite clear the contents of the BOD, and the suspension base material. In this area, most of the water is recycled back into the tank as soon as precipitation and partly transferred to a final resolution purpose.

Recycling is to provide direct access to the water content of the BOD concentration of oxygen is low, but high enough so that it will help the weight of a new waste water treatment units.

4. The final processing stage

The plant is the last unit of the final clarifier settling to reduce suspended solids and biomass pellets peeling.

The water that comes out after going through the above steps, when it was discovered the body is clear and free of solids discharged into rivers on the right.

Tuesday, February 11, 2014

Mineral Water Treatment Benefits

"Water is life". Today, one can easily alter this sentence as "Healthy water is life". It is said that water is the much popular a beverage with each and every people across the globe unless it is good with health benefits. It is with such perfection, the water treatment plant projects manufacture treated water products which are approved with health essential minerals, and never possible with any of the harsh effects of chemicals.

Water treatment process used by these water treatment plants are advanced in their techniques to certify the best quality of water reaching to people in its bottled avatars. Mineral water treatment process benefits are very much real and it makes us healthier when we drink these mineral water products regularly. Let this article make you understand why it is good enough to have mineral water every day to restrict the recurring stomach problems from your life.

There are several such benefits in having mineral water every day:

1) Magnesium: To reduce body stress and in making the immune system much more stronger,projects are best enough. Magnesium is the essential mineral which is present in these mineral water bottled products.

Magnesium is also important with the options of energy production, muscle contraction, nucleic acid & protein metabolism, neuromuscular excitability, blood coagulation, muscle contraction, etc. it is also beneficial enough in revitalizing as well as reducing the stress from our body.

2) Chloride: It helps in the digestion process by regulating and maintaining such acids in stomach & intestines.

3) Sulfate: It is another such life giving minerals which is found in good mineral water products. Basically, it strengthens teeth and bones.

4) Calcium: Several mineral water products contain calcium and we all know that how much significant it is in strengthening our teeth as well as bones.

5) Iron: It is another one which is necessary a mineral in packaged mineral water products. Iron helps to transport the oxygen around our body. Whereas, it also controls the amount of these mineral necessary in drinking water and this makes the water much more special to drink with several of the healthy benefits.

6) Apart from all these, these process projects highly restricts the indulgence of harmful chemicals just by treating the same from its natural resources. It also makes water free from the arsenic compounds which is high with serious effects over our body.

It is with such perfection, the process plants are getting much importance over several parts of our globe, with the greatest increase of drinking healthy water every day.

How these water process plants work:

Processes are mandatorily undergone by project professionals using latest scientific techniques that make water free from any of the essential impurities. There are several such water treatment procedures which include:

a) Disinfection: For killing the presence of bacteria in water.
b) Aeration: Used in removal of dissolved iron or manganese.
c) Sedimentation: It is used in separation of solids, by removing the suspended solids that are trapped in the flocculation procedure.
d) Filtration: Removing the dust particles from water.
e) Desalination: It is the procedure which removes the excessive salt contents from water.

Drinking Water Treatment - Avoiding the Risks

Around 1.8 million people die each year due to water-borne diseases spurring authorities and companies to work together and develop safer and more effective means of distribution. Drinking water treatment can be done in various ways but it is equally important to maintain ecological cleanliness for long term benefits. Here are the different approaches of treatment.

Introduction to Water Treatment

The process used to make water acceptable and safe for consumption is referred to as drinking water treatment. The uses may vary aside from drinking such as medical purposes, industrial processes and the like. The main goal of treatment is to eliminate or remove all present contaminants in the water and continually improve it for future use. Treated water can also be safely discharged into the natural environment without any negative ecological effects through processes like coagulation, settling or slow sand filtration.

The need for clean water continues to rise especially among developing countries. High standards are vital for drinking purposes while factories have lower purification requirements. Household connection and community water point sources may not be very safe for human consumption. Surface waters and open-wells almost always need drinking water treatment.

The Standards

Drinking water treatment requires the right technologies and applications that include both household-scale point-of-use or POU and community-scale designs. There are several approaches to destroy microbial pathogenic agents such as filtration, boiling, chemical disinfection and UV or ultraviolet radiation exposure. Field-based studies have been conducted to determine how POU approaches reduce the possibility of waterborne diseases. POU capabilities regarding disease control depends on the potential to eliminate pathogens as well as social factors like proper usage and cultural application.

The priority of POU proponents is to provide clean and safe drinking water treatment to low-income households on a regular and sustainable basis. Drinking water parameters are generally categorized into chemical or physical and microbiological. Chemical or physical include trace organics, heavy metals, turbidity and TSS or total suspended solids. Microbiological include E. Coli, protozoans, bacteria and viruses. These can affect water properties such as taste, odor and appearance.

What's in Your Water?

Water coming from surface waters such as rivers or lakes is exposed to different external conditions and elements such as acid rain, pesticide runoff, storm water runoff, industrial waste and mud. A number of natural processes can improve and cleanse the water at an extent such as aeration, presence of beneficial microorganisms and minerals and exposure to sunlight. Groundwater such as those in private wells and a number of public water supplies may take longer to contaminate. The natural cleansing processes also take longer. Drinking water contamination can include disease-causing pathogens, agricultural chemicals and hazardous household products.

Contaminants are supposed to be regulated when present in drinking water supplies and pose a risk to public health. The EPA established safety levels and margins that may be adequate for the majority but become dangerous to selected individuals and groups. Scientists use "acceptable daily intake" to assess the risk of non-cancer-causing toxic materials.

Drinking Water Contaminants

Drinking water contamination can stem from four sources namely microbial pathogens, organics, inorganics and radioactive elements. Pathogens are the most common stemming from sewage and animal waste that lead to health problems like hepatitis, salmonella infection and dysentery. Organics include pesticides and volatile organic chemicals which can lead to cancer, birth defects and system damage and disorders. Inorganics include toxic metals and nitrate that can cause poisoning and cancer. Radioactive elements include radon stemming from decayed uranium rock and soil. It can lead to lung cancer.

Saturday, February 8, 2014

Compare Water Treatment Systems - Water Treatment Systems Explained

Types:

If you are looking to compare water treatment systems, each type's positives and negatives need to be taken into account. I'll outline the types of water treatment systems which are suitable for home use only.

Firstly, there is the stand alone filter that sits on a bench. These stone, steel or plastic vessels are filled by hand from water from the tap or tank. The water is filtered as it passes through ceramic and/or carbon filters via gravity. Just the thing for your daily drinking water. They can be quite attractive but you do need a 'spot' on your bench for them and the better ones aren't very cheap.

Distillation filters:

For home use, distillation is limited to drinking water only. Water is heated and the resulting steam is collected in a vessel. Unfortunately, not all of the water's chemicals are removed as those with a lower boiling point than water, pass into the collection chamber. Again, taste suffers because of the removal of those essential trace elements. Best left to industry, and for filling your car battery, where demineralized water is needed.

Next, are the types of filters that are attached to the mains water supply. These can be installed on the sink, under the sink, in the shower, or at the point of entry to the house.

Most people would only consider water treatment systems that purified drinking water only. Because of the nature of contaminants found in water, in particular chlorine, a shower filter and/or even a whole-house may be considered necessary for your needs. Chlorine gets into your skin through open pores while showering. The fumes from the shower and appliances such as the washing machine and dish washer, when using untreated water, can cause real problems, especially for asthmatics.

The pressure of the water mains forces water through the filtration system. These are the most commonly used because of their cost and convenience. To compare water treatment systems which use your mains water supply, we need to look at how they operate and the effectiveness of each.

Reverse Osmosis:

Water is forced through or a semi permeable membrane, removing many toxins in the process. They are quite expensive to operate (filter replacement) and slow the water flow down considerably, but their biggest negative is that, along with impurities, they also take out beneficial minerals such as calcium and magnesium which are very important to proper body functioning and for better tasting water.

UV Filters:

Water passes through or around an Ultra Violet tube, effectively killing bacteria and viruses. If your only concern is the bugs in the water, these are an excellent choice. They should be combined with other types of filters, if the other contaminants found in water are to be handled.

Ionizers:

An electric current is passed through water to raise its PH, ie increase its alkalinity. Some swear by them, others say they can't work in a water environment and are an expensive substitute for a diet containing calcium. I'm staying out of the argument for the moment.

Carbon filters:

These have been tried and tested over many many years. When water is forced through a carbon material, such as charcoal or coconut shell, chemicals and most other toxins collect on its surface--called adsorption. The combination of chemical bonding and mechanical straining makes a carbon filter, especially if it is a multi-stage process, the best of the water treatment systems. Also, they allow essential minerals like calcium and magnesium to pass.

Because they can be produced inexpensively and their replacement filters are reasonably priced, to compare water treatment systems without them having a carbon filter as part of their construction doesn't make a lot of sense. See below for excellent quality water filters selling at a discount.

Friday, February 7, 2014

Determining Amount of Ozone Required For Ozone Water Treatment

Ozone (O3) provides multiple benefits for water treatment including remove of organic compounds, certain inorganic compounds (Fe, Mn, H2S), color, odor and taste. It also acts as a micro flocculent which aids in removal of suspended solids. In addition it is an excellent disinfecting agent capable of killing a wide spectrum of micro organisms. As a result it is being increasing considered for a wide variety of water treatment applications.  

A key question in designing an O3 water treatment system is how much ozone is required to achieve the treatment objective. Removing of organic/inorganic compounds and disinfection are the two most common applications for ozone treatment, so these will be the focus of the article. 

In removing contaminants from water using ozone, it is important to understand that O3 acts by the chemical process of oxidation. A chemical substance is oxidized when it loses electrons. These reactions can occur with and without the presence of oxygen, but in the present case we are referring to reactions where oxygen in the form of O3 is involved. 

The amount of oxidizable material in the water is referred to as the ozone demand. 

Inorganic Compounds

The simplest reactions are where O3 reacts with inorganic compounds such as Fe, Mn and H2S. In the case of Fe and Mn the metals are oxidized to insoluble compounds the precipitate from solution. In water treatment removal of these compounds is important since the Fe and Mn can discolor water and deposit on piping systems and materials immersed in the water. So O3 is added to make the metal insoluble and they are subsequently filtered out of the water as a solid. The amount of O3 required is 0.44 mg ozone/mg Fe and 0.88 mg O3/mg Mn. 

Hydrogen Sulfide (H2S) creates an unpleasant odor in water (rotten eggs). In drinking water applications the H2S is often removed to make the water more palatable. The theoretical amount of ozone required to remove H2S is 3 mg O3/mg H2S, but in practice and excess of ozone is used (4 mg O3/mg H2S). The H2S is oxidized to sulfate, a soluble salt. 

Organic Compounds

It is more difficult to predict the amount of O3 required to remove organic matter from water. First, some organic compounds do not react with O3, even though it is a powerful oxidant. These compounds are typically carboxylic acids, ketones and aldehydes. Even with compounds that do react with O3, some of which will oxidize to smaller compounds that don't react. As a result it is difficult to predict the amount of O3 required without a detailed knowledge of the chemicals involved or conducting laboratory or pilot studies.  

One way to measure the amount of organic in water is to measure the Chemical Oxygen Demand (COD). This test essentially determines the amount of oxygen to convert all of the organic carbon in the sample to CO2. The test uses a powerful oxidant at elevated temperature to oxidize the organic compounds. A color change, which measures the amount of oxidant used, indicates the amount of COD.  

A change in COD is often used as an objective in water treatment. In laboratory tests the initial amount of COD is noted and O3 is applied to the contaminated solution. A correlation is developed between the O3 applied and the COD level. This is the most direct way to determine the amount of ozone needed. For organic compounds that are treatable with O3, a rule of thumb can be applied for an initial estimate of ozone demand. It says that you need 2.5 mg O3/mg of COD where the COD is composed of organic compounds that can be oxidized by O3.  

Another method of measure organic concentration in water is Total Organic Carbon (TOC). This test measures the total carbon (TC) in water by first removing the inorganic carbon (IC), e.g. carbonates, from the water. By measuring the TC and subtracting the IC remainder is TOC. While ozone can oxidize organic compounds, including some to CO2, many of the compounds will remain in the water in an oxidized state, so the change in TOC might not be great. Generally, to remove TOC requires the use of advanced oxidation processes which can involve the use of O3 as a component.  

Disinfection 

In order to inactivate micro organisms, it is necessary to expose them to ozone for a certain period of time. A measure of this is referred to as Ct, which is the average concentration of ozone multiplied by the average time of exposure. If one plotted O3 concentration versus time, the area under the curve would be Ct. Different organisms require different Ct at a given temperature for inactivation. Ct values for a variety of organism have been developed.

In order to build a concentration of O3 in water, the demand for ozone in solution must first be satisfied. This means that the organic and inorganic compounds that can be oxidized by O3 must be first removed before the concentration can build up to establish a Ct value.  

For disinfection the amount of O3 required would equal: 

Ozone Demand from Oxidizable Species (mg/l) + (Ct ÷ contact time) 

Ozone Decomposition 

O# in aqueous solution has a self decomposition reaction. In pure water O3, without any oxidizable species, will decompose back to oxygen. The decomposition reaction is a function of temperature. For example, at 25 degrees C (77 degrees F) and a pH of 7 the half life of ozone is 15 minutes.

So in addition to the O3 demand from oxidizable inorganic or organic compounds, one has to account for self decomposition. 

In developing the Ct value, the change in O3 concentration as a function of the contact time would be measured to determine the C vs t curve so that the area under the curve can be defined. 

Ozone Transfer Efficiency 

In order to act as an oxidant in aqueous systems, O3 must be transferred from the gas to liquid phase where it acts in solution as a dissolved species. The percentage of the O3 produced in the gas phase (the applied O3 dose) that ends up in solution (the transferred O3 dose) is referred to as the O3 transfer efficiency. 

The transfer efficiency is mainly affected by the following factors: 

  1. The ratio of gas volume to liquid volume (G/L ratio), lower ratio increases efficiency
  2. Bubble size, smaller bubbles increase efficiency
  3. Ozone demand of the water, higher demand increases efficiency
  4. Ozone concentration, higher concentration increases efficiency
  5. Pressure, higher pressure increases efficiency
  6. Detention time, longer detention time increases efficiency
  7. Temperature, lower temperature increases efficiency

 Required Ozone Production

O3 generators are normally rated in pounds per day (lbs/day) or grams per hour (g/h). The required O3 production rate is sometimes referred to the Applied Ozone Dose (AOD). We would also need to know the flow rate since most O3 demand requirements are computed in grams or milligrams per liter. So, the amount of water treated over a period of time is necessary.

In the case of organic/inorganic removal

AOD (g/h) = (O3 Demand (g/l) ÷ O3 Transfer Efficiency (%)) X Flow Rate (l/h)

 n the case of disinfection

OD (g/h) = (O3 Demand + (Ct ÷contact time) (g/l)) X Flow Rate (l/h) ÷ O3 Transfer Efficiency (%)

The only way to accurately know the proper amount of O3 required is to conduct pilot trials with O3 transfer equipment similar to that which will be used in full scale. Nonetheless the methodology discussed in this article along with the rules of thumb mentioned can be useful in generating rough estimates to see if O3 might be a candidate for further consideration in a water treatment application.

Thursday, February 6, 2014

Why a Reverse Osmosis Water Treatment System May Not Be What You Need

While talking to my friend, Diane, the other day our conversation turned to water purification systems. I asked her which one she used in her house, and she told me a reverse osmosis water treatment system. She said she rents it from a company, which I won't mention here by name.

I told her reverse osmosis water treatment systems alone will not remove all the dangerous chemicals from her water, such as chlorine, pharmaceutical drugs, pesticides and others.

I then told her our water company already used reverse osmosis on our water before piping it to us, so why would she want to spend her money on duplicating the process. She didn't know that little tidbit of information, so she said she'd have to go home and ask her husband why he chose that particular water purification method.

I'm sure she is not the only person who is not aware that a reverse osmosis water treatment system does not remove the harmful chemicals in our water supply. In order to remove these contaminates you need to use a granular activated carbon filter, a multi block media filter, and sub micron filter.

These three filters together with an ion exchange to remove the heavy metals from the water will provide you with the best water purification unit on the market today. Using these in combination will give you the protection you need from all the harmful contaminates lurking in our water supply.

Reverse osmosis water treatment systems were developed for use in the photo industry, because photo processing requires mineral free water to get a satisfactory end product. R.O. is a good choice if you are a photo processor, but for a home purification unit there are much better products that will give you pure, safe water to drink.

You will find some reverse osmosis systems that also use the granular carbon and sub micron filters along with reverse osmosis. These systems will do the job, but you will be paying more money than you need to if what you are trying to do is provide yourself and your family with clean healthy drinking water.

Not only will the initial cost of the units be more, but also the ongoing cost of electricity and water usage to run the system will cost more. If you are like my friend, Diane, who uses one of the many reverse osmosis water treatment systems on the market today, you might want to check out how many contaminates you are actually removing.

Hopefully you are like her and you are only renting a unit and you haven't spent the money on purchasing one. Check out other water purification units available. You can find them for under $100 for a counter top model that will provide you with fresh healthy water all day long.

Wednesday, February 5, 2014

Learn About Whole-House Water Treatment Systems

Whole-house water treatment systems may be the right option for your family. It really depends on which home water treatment system, you choose. Some, of course, are better than others.

For many years the reverse osmosis whole-house water treatment systems came highly recommended. But, the popularity of the filtration device has waned, as the types of contaminants we are faced with have changed.

There are over 2000 different toxic chemicals in surface and groundwater. Many of them are known to cause cancer. Some are just suspected to. Others are merely a contributing factor. A reverse osmosis home water treatment system will remove exactly NONE of them.

Whole-house water treatment systems were designed to remove minerals and organic compounds such as arsenic that are naturally occurring in water supplies. They were designed long before anyone realized that traces of chemicals that we use everyday would eventually end up in the water and become a health problem.

It was not initially designed as a home water treatment system, but for use by industries and large scale treatment facilities, as a purification step to be combined with granulated carbon and disinfection. You see, it is only one step in a complete purification process and if you are serviced by a public facility, that step has probably already been performed.

One of the primary targets for a home water treatment system is chlorine and the gases created by it when it is used to kill algae and bacteria. Nearly every facility in the world uses chlorine at some point in its purification process, even though there are known health risks associated with its use.

When consumed, it kills the "flora" that inhabits the stomach and bowels, causing digestive disorders. If you shower in it, your skin will be dry and your hair will be dull and brittle.

In a hot shower, it becomes airborne and triggers asthma attacks. It also irritates other respiratory conditions. Its initial use was as a poisonous gas in early chemical warfare. A soldier discovered that it could be used to "clean" water.

In order for whole-house water treatment systems to remove chlorine, they must contain carbon granules. They should also have a pre-filter to remove tiny sediments. They don't have to be expensive or large and bulky. They barely affect your water pressure, but they can help protect your family's health and safety.

The best home water treatment system costs less than a thousand dollars and pennies a day to operate. It does not require electricity or back flushing, because no wastewater is created. The main filter lasts for three years and the sediment filters for three months.

If you don't want to worry about when it's time to replace the filters, there is one company that will sign you up for an automatic shipment plan. So, the filters arrive at your door just in time to replace them.

Often it is more economical to purchase whole-house water treatment systems than it is to buy different units for the various faucets and showers in your home. Hopefully, this info will help you find the right solution for your family.