تصميم وتصنيع وتركيب وتوريد محطات معالجة الصرف الصناعى-لشركات انتاج الكيماويات والغازات الصناعية

Technical study

in

industrial waste water treatment

for

chemicals production lines

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Wastewater Treatment Methods& Disposal

Satisfactory disposal of wastewater, whether by surface, subsurface methods or dilution, is dependent on its treatment prior to disposal.

Adequate treatment is necessary to prevent contamination of receiving waters to a degree which might interfere with their best or intended use, whether it be for water supply, recreation, or any other required purpose.

Wastewater treatment consists of applying known technology to improve or upgrade the quality of a wastewater.

Usually wastewater treatment will involve collecting the wastewater in a central, segregated location (the Wastewater Treatment Plant) and subjecting the wastewater to various treatment processes.

Most often, since large volumes of wastewater are involved, treatment processes are carried out on continuously flowing wastewaters (continuous flow or "open" systems) rather than as "batch" or a series of periodic treatment processes in which treatment is carried out on parcels or "batches" of wastewaters.

While most wastewater treatment processes are continuous flow, certain operations, such as vacuum filtration, involving as it does, storage of sludge, the addition of chemicals, filtration and removal or disposal of the treated sludge, are routinely handled as periodic batch operations.

Wastewater treatment, however, can also be organized or categorized by the nature of the treatment process operation being used; for example, physical, chemical or biological.

Examples of these treatment steps are shown below.

A complete treatment system may consist of the application of a number of physical, chemical and biological processes to the wastewater.

Physical

Sedimentation (Clarification)

Screening

Aeration

Filtration

Flotation and Skimming

Degassification

Equalization

Chemical

Chlorination

Ozonation

Neutralization

Coagulation

Adsorption

Ion Exchange

Biological

Aerobic

Activated Sludge Treatment Methods

Trickling Filtration

Oxidation Ponds

Lagoons

Aerobic Digestion

Anaerobic

Anaerobic Digestion

Septic Tanks

Lagoons

Industrial Wastewater Treatment

Physical treatment methods

include processes where no gross chemical or biological changes are carried out and strictly physical phenomena are used to improve or treat the wastewater.

Examples would be coarse screening to remove larger entrained objects and sedimentation (or clarification).

In the process of sedimentation, physical phenomena relating to the settling of solids by gravity are allowed to operate.

Usually this consists of simply holding a wastewater for a short period of time in a tank under quiescent conditions, allowing the heavier solids to settle, and removing the "clarified" effluent.

Sedimentation

for solids separation is a very common process operation and is routinely employed at the beginning and end of wastewater treatment operations.

While sedimentation is one of the most common physical treatment processes that is used to achieve treatment, another physical treatment process consists of aeration -- that is, physically adding air, usually to provide oxygen to the wastewater. Still other physical phenomena used in treatment consists of filtration.

Here wastewater is passed through a filter medium to separate solids.

An example would be the use of sand filters to further remove entrained solids from a treated wastewater.

Certain phenomena will occur during the sedimentation process and can be advantageously used to further improve water quality.

Permitting greases or oils, for example, to float to the surface and skimming or physically removing them from the wastewaters is often carried out as part of the overall treatment process.

In certain industrial wastewater treatment processes strong or undesirable wastes are sometimes produced over short periods of time.

Since such "slugs" or periodic inputs of such wastes would damage a biological treatment process, these wastes are sometimes held, mixed with other wastewaters, and gradually released, thus eliminating "shocks" to the treatment plant.

This is call equalization.

Another type of "equalization" can be used to even out wide variations in flow rates.

For example, the wet well of a pump station can receive widely varying amounts of wastewater and, in turn, pump the wastes onward at more uniform rates.

Chemical treatment

consists of using some chemical reaction or reactions to improve the water quality.

Probably the most commonly used chemical process is chlorination.

Chlorine,

a strong oxidizing chemical, is used to kill bacteria and to slow down the rate of decomposition of the wastewater.

Bacterial kill is achieved when vital biological processes are affected by the chlorine. Another strong oxidizing agent that has also been used as an oxidizing disinfectant is ozone.

A chemical process commonly used in many industrial wastewater treatment operations is neutralization.

Neutralization consists of the addition of acid or base to adjust pH levels back to neutrality.

Since lime is a base it is sometimes used in the neutralization of acid wastes.

Coagulation

consists of the addition of a chemical that, through a chemical reaction, forms an insoluble end product that serves to remove substances from the wastewater.

Polyvalent metals

are commonly used as coagulating chemicals in wastewater treatment and typical coagulants would include lime (that can also be used in neutralization), certain iron containing compounds (such as ferric chloride or ferric sulfate) and alum (aluminum sulfate).

Certain processes may actually be physical and chemical in nature.

The use of activated carbon to "adsorb" or remove organics, for example, involves both chemical and physical processes.

Processes such as ion exchange, which involves exchanging certain ions for others, are not used to any great extent in wastewater treatment.

Biological treatment methods use microorganisms, mostly bacteria, in the biochemical decomposition of wastewaters to stable end products.

More microorganisms, or sludges, are formed and a portion of the waste is converted to carbon dioxide, water and other end products.

Generally, biological treatment methods can be divided into aerobic and anaerobic methods, based on availability of dissolved oxygen.

The purpose of wastewater treatment is generally to remove from the wastewater enough solids to permit the remainder to be discharged to a receiving water without interfering with its best or proper use.

The solids which are removed are primarily organic but may also include inorganic solids.

Treatment must also be provided for the solids and liquids which are removed as sludge.

Finally, treatment to control odors, to retard biological activity, or destroy pathogenic organisms may also be needed.

While the devices used in wastewater treatment are numerous and will probably combine physical, chemical and biological methods, they may all be generally grouped under six methods:

Preliminary Treatment

Primary Treatment

Secondary Treatment

Disinfection

Sludge Treatment

Tertiary Treatment

Degrees of treatment are sometimes indicated by use of the terms primary, secondary and tertiary treatment.

Tertiary treatment, properly, would be any treatment added onto or following secondary treatment.

Preliminary Treatment

At most plants preliminary treatment is used to protect pumping equipment and facilitate subsequent treatment processes.

Preliminary devices are designed to remove or cut up the larger suspended and floating solids, to remove the heavy inorganic solids, and to remove excessive amounts of oils or greases.

To effect the objectives of preliminary treatment, the following devices are commonly used:

Screens -- rack, bar or fine

Comminuting devices -- grinders, cutters, shredders

Grit chambers

Pre-aeration tanks

In addition to the above, chlorination may be used in preliminary treatment.

Since chlorination may be used at all stages in treatment, it is considered to be a method by itself.

Preliminary treatment devices require careful design and operation.

Primary Treatment

In this treatment, most of the settleable solids are separated or removed from the wastewater by the physical process of sedimentation.

When certain chemicals are used with primary sedimentation tanks, some of the colloidal solids are also removed.

Biological activity of the wastewater in primary treatment is of negligible importance.

The purpose of primary treatment is to reduce the velocity of the wastewater sufficiently to permit solids to settle and floatable material to surface.

Therefore, primary devices may consist of settling tanks, clarifiers or sedimentation tanks.

Because of variations in design, operation, and application, settling tanks can be divided into four general groups:

Septic tanks

Two story tanks -- Imhoff and several proprietary or patented units

Plain sedimentation tank with mechanical sludge removal

Upward flow clarifiers with mechanical sludge removal

When chemicals are used, other auxiliary units are employed.

These are:

Chemical feed units

Mixing devices

Flocculators

The results obtained by primary treatment, together with anaerobic sludge digestion as described later, are such that they can be compared with the zone of degradation in stream self-purification.

The use of chlorine with primary treatment is discussed under the section on

Preliminary Treatment.

Secondary Treatment

Secondary treatment depends primarily upon aerobic organisms which biochemically decompose the organic solids to inorganic or stable organic solids.

It is comparable to the zone of recovery in the self-purification of a stream.

The devices used in secondary treatment may be divided into four groups:

Trickling filters with secondary settling tanks

Activated sludge and modifications with final settling tanks

Intermittent sand filters

Stabilization ponds

The use of chlorine with secondary treatment is discussed under the section on Secondary Treatment

Chlorination

This is a method of treatment which has been employed for many purposes in all stages in wastewater treatment, and even prior to preliminary treatment.

It involves the application of chlorine to the wastewater for the following purposes:

Disinfection or destruction of pathogenic organisms

Prevention of wastewater decomposition --

(a) odor control, and

(b) protection of plant structures

Aid in plant operation --

(a) sedimentation,

(b) trickling filters,

(c) activated sludge bulking

Reduction or delay of biochemical oxygen demand (BOD)

While chlorination has been commonly used over the years, especially for disinfection, other methods to achieve disinfection as well as to achieve similar treatment ends are also used.

Among the most common is the use of ozone. In view of the toxicity of chlorine and chlorinated compounds for fish as well as other living forms, ozonation may be more commonly used in the future.

This process will be more fully discussed in the section on disinfection.

Sludge Treatment

The solids removed from wastewater in both primary and secondary treatment units, together with the water removed with them, constitute wastewater sludge.

It is generally necessary to subject sludge to some treatment to prepare or condition it for ultimate disposal.

Such treatment has two objectives -- the removal of part or all of the water in the sludge to reduce its volume, and the decomposition of the putrescible organic solids to mineral solids or to relatively stable organic solids.

This is accomplished by a combination of two or more of the following methods:

Thickening

Digestion with or without heat

Drying on sand bed -- open or covered

Conditioning with chemicals

Elutriation

Vacuum filtration

Heat drying

Incineration

Wet oxidation

Centrifuging

Package UnitsThe term "package units" is used in the field to describe equipment which has been put on the market by a number of manufacturers that is intended to provide wastewater treatment by the use of prefabricated or modular units.

Package units can also refer to a complete installation, including both mechanisms and prefabricated containers.

This term is also applied to installations where only the mechanisms are purchased and the containers constructed by the purchaser in accordance with plans and specifications prepared by the manufacturer.

Though specific limitations have not been established, individual package units have, in general, been small installations serving a limited population.

Package units have been adapted to practically all the treatment devices, either singly or in various combinations that have been mentioned.

Tertiary and Advanced Wastewater Treatment

The terms "primary" and "secondary" treatment have been used to generally describe a degree of treatment;

for example, settling and biological wastewater treatment. Since the early 1970's "tertiary" treatment has come into use to describe additional treatment following secondary treatment.

Quite often this merely indicates the use of intermittent sand filters for increased removal of suspended solids from the wastewater.

In other cases, tertiary treatment has been used to describe processes which remove plant nutrients, primarily nitrogen and phosphorous, from wastewater.

Improvement and upgrading of wastewater treatment units as well as the need to minimize environmental effects has led to the increased use of tertiary treatment.

A term that is also sometimes used to indicate treatment of a wastewater by methods other than primary or biological (secondary) treatment is advanced treatment.

This degree of treatment is usually achieved by chemical (for example coagulation) methods as well as physical methods (flocculation, settling and activated carbon adsorption) to produce a high quality effluent water.

chemical treatment methodes

Industrial wastewater treatment involves treating wastewater to make it acceptable for discharge into a river, stream, lake, ocean, etc.

The treatment of industrial wastewater involves the use of various processes and performance chemicals to remove impurities from the water by coagulation, precipitation, flotation, sedimentation, filtration, biological oxidation, chemical oxidation, etc.

The following lists impurities that can be removed and problems that can be solved by using one or a combination of specialty treatment products:

Total Suspended Solids (TSS) removal

Color removal

Fat, Oil and Grease removal

Heavy Metals removal

Chemical Oxygen Demand (COD) reduction

Total Organic Carbon (TOC) removal

Biological Oxygen Demand (BOD) reduction

Sludge Dewatering

Hydrogen Sulfide odor control

Improve operational consistency

1-Suspended Solids Removal

In both municipal and industrial wastewater treatment applications there are many types of materials that need to be removed.

They can be organic solids, inorganic solids, oils, fats, etc. To remove these solids generally requires a product that has both good coagulating and flocculating capabilities.

the Solution:

Each different solid present in wastewater has its unique characteristics.

it carries a line of specialty products specifically designed to remove wastewater solids.

The products that will best assist you in solids removal are:

Aluminum Chloride Solution

Aluminum Chlorohydrate Solution

Ferric Chloride Solution

Polyaluminum Chloride Solution

2-Color Removal

Color in water comes from natural sources resulting from the decaying of leaves or other vegetation.

Color can also come from chemicals in the water resulting from industrial wastewater or agriculture runoff.

Most of the color present in water is soluble and very difficult to remove.

One approach to remove color is to oxidize it with chlorine.

This may reduce the color but it may also generate other organic compounds that also have to be removed from the water.

the Solution:

it has several products that work well in removing color from water.

In one case they work by absorbing the color in a large voluminous floc.

In another the anionic charge of the color allows the material to be selectively precipitated with an inorganic aluminum polyelectrolyte.

The products that will best assist in TOC removal are:

Aluminum Chloride Solution

Ferric Chloride Solution

Polyaluminum Chloride Solution

3-Oil Removal

In industrial wastewater, oils and greases are often removed by flotation.

Sometimes these oils and greases are present in the form of an emulsion.

To separate this type of oil, the emulsion must be broken.

These emulsions are negatively charged and can be readily coagulated and removed by flotation with a strong inorganic coagulant.

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the Solution:

a several inorganic coagulants that are very effective in breaking emulsions and coagulating oils.

They are:

Aluminum Chloride Solution

Ferric Chloride Solution

Polyaluminum Chloride Solution

4-TOC, COD and BOD Removal

TOC is the measure of the Total Organic Carbon, COD is the measure of the Chemical Oxygen Demand and BOD is the measure of the Biological Oxygen Demand in wastewater.

These three parameters are used to characterize both municipal and industrial wastewater.

BOD tends to be used more frequently in municipal wastewater treatment, and COD is used more often in industrial wastewater treatment.

In both municipal and industrial wastewater treatment applications there are many types of materials that contribute to TOC, BOD and COD.

They can be organics, inorganics, oils, fats, etc. TOC, BOD and COD can be removed by coagulation and/or filtration when they are in the form of suspended solids.

If they are soluble, then adsorption, biological oxidation or chemical oxidation processes are needed to remove them.

To remove suspended TOC, BOD and COD generally requires product that has both good coagulating and flocculating capabilities.

the Solution:

Each different solid present in wastewater has its unique characteristics.

it carries a line of specialty products specifically designed to remove wastewater solids.

The products that will best assist you in solids removal are:

Aluminum Chloride Solution

Ferric Chloride Solution

Polyaluminum Chloride Solution

5-Sludge Dewatering

In all water/solids separation processes, the solids must be handled and disposed of.

The volume of solids is directly related to the ultimate cost of disposal, and disposal costs are rising as regulations tighten and land values rise.

In cases where dewatering equipment is used to increase the percentage of solids in the sludge, the choice of dewatering chemical will make a significant difference in the results obtained.

The cost of the chemical is small compared to the cost savings of producing smaller sludge volumes through eliminating excess water.

Inorganics like ferric chloride and lime were widely used in the past but lost ground as the technology of organic polyelectrolytes proliferated.

Today, many municipal and industrial accounts are using combinations of organics and inorganics to ensure the best all-around performance.

the Solution:

a several products that can be used alone, in combinations with lime or in combination with organic polyelectrolytes.

They are:

Ferric Chloride Solution

Organic Polyelectrolytes

6-Hydrogen Sulfide Odor Control

In both municipal and industrial wastewater distribution systems and treatment plants hydrogen sulfide gas can form.

This gas, above threshold levels, can cause severe odor problems.

Irons salts in solution will react with the hydrogen sulfide dissolved in water and precipitate a fine suspension of iron sulfide.

the Solutions:

a several iron salts that readily react with hydrogen sulfide to form iron sulfides.

They are:

Ferric Chloride Solution

Ferrous Chloride Solution

7-Improved Operational Consistency

When looking at the use of chemicals for treating water and wastewater one must look at the entire system.

This includes clarification, filtration, disinfection and sludge dewatering.

The products used in the coagulation process have an impact on the operating efficiency of subsequent treatment processes.

A product may work well in one process but cause major problems in another.

As an example you may find a product works well to clarify water but it generates a sludge that is very difficult to dewater.

the Solutions:

a range of polyaluminum chemicals that are strongly cationic and prehydrolyzed, making them more reactive at lower dosages than conventional coagulants.

Lower dosages generally mean less solids carryover and less sludge generated.

The solids generated when using these polyaluminum chemicals are less voluminous and easier to filter and dewater.

These product attributes translate into a more constant and uniform operation with all interrelated processes.

The products that will best assist you in filtration are:

Aluminum Chlorohydrate Solution

Polyaluminum Chloride Solution

Polyaluminum Chlorosulfate Solution

Coagulation and Flocculation

Objective

How do coagulation and flocculation fit into the water treatment process?

Which chemical principles influence coagulation and flocculation?

Which chemicals are used in coagulation?

What factors influence coagulation and flocculation?

Overview of the Process

After the source water has been screened and has passed through the optional steps of pre-chlorination and aeration, it is ready for coagulation and flocculation.

In theory and at the chemical level, coagulation and flocculation is a three step process, consisting of flash mixing, coagulation, and flocculation.

However, in practice in the treatment plant, there are only two steps in the coagulation/flocculation process - the water first flows into the flash mix chamber, and then enters the flocculation basin.

Purpose

The primary purpose of the coagulation/flocculation process is the removal of turbidity from the water.

Turbidity is a cloudy appearance of water caused by small particles suspended therein. Water with little or no turbidity will be clear.

Turbidity is not only an aesthetic problem in water. Water with a high turbidity can be very difficult or impossible to properly disinfect.

As a result, the maximum allowable level of turbidity in water is 0.5 NTU, while the recommended level is about 0.1 NTU. (NTU, or TU, stands for nephelometric turbidity units, a measurement of the turbidity of water.)

In addition to removing turbidity from the water, coagulation and flocculation is beneficial in other ways.

The process removes many bacteria which are suspended in the water and can be used to remove color from the water.

Turbidity and color are much more common in surface water than in groundwater.

As surface water flows over the ground to streams, through streams, and then through rivers, the water picks up a large quantity of particles.

As a result, while aeration is more commonly required for groundwater, treatment involving coagulation and flocculation is typical of surface water.

Three Steps

As I mentioned above, the chemistry of coagulation/flocculation consists of three processes - flash mix, coagulation, and flocculation.

Each of these processes is briefly explained below.

In the flash mixer, coagulant chemicals are added to the water and the water is mixed quickly and violently.

The purpose of this step is to evenly distribute the chemicals through the water.

Flash mixing typically lasts a minute or less. If the water is mixed for less than thirty seconds, then the chemicals will not be properly mixed into the water.

However, if the water is mixed for more than sixty seconds, then the mixer blades will shear the newly forming floc back into small particles.

After flash mixing, coagulation occurs. During coagulation, the coagulant chemicals neutralize the electrical charges of the fine particles in the water, allowing the particles to come closer together and form large clumps.

You may already be familiar with the process of coagulation from cooking.

You can see coagulation occurring when preparing gelatin (jello) or when cooking an egg white.

The final step is flocculation. During flocculation, a process of gentle mixing brings the fine particles formed by coagulation into contact with each other.

Flocculation typically lasts for about thirty to forty-five minutes.

The flocculation basin often has a number of compartments with decreasing mixing speeds as the water advances through the basin.

This compartmentalized chamber allows increasingly large floc to form without being broken apart by the mixing blades.

Floc

The end product of a well-regulated coagulation/flocculation process is water in which the majority of the turbidity has been collected into floc, clumps of bacteria and particulate impurities that have come together and formed a cluster.

The floc will then settle out in the sedimentation basin, with remaining floc being removed in the filter.

The best floc size is 0.1 to 3 mm. Larger floc does not settle as well and is more subject to breakup in the flocculation basin. Smaller floc also may not settle.

Part 2: Chemistry

Introduction

Why do we need such a complex process to remove particles from water?

Some particles would settle out of the water on their own, given enough time.

But other particles would resist settling for days or months due to small particle size and to electrical charges between the particles.

We will consider the chemical processes which prevent and aid settling below.

But first, we will list the three types of objects which can be found in water.

Particles in Water

There are three types of objects which can be found in water. In order from smallest to largest, these objects are chemicals in solution, colloidal solids, and suspended solids.

Coagulation/flocculation will remove colloidal and suspended solids from water.

Chemicals in solution have been completely dissolved in the water.

They are electrically charged and can interact with the water, so they are completely stable and will never settle out of the water.

Chemicals in solution are not visible, either using the naked eye or using a microscope, and are less than 1 Mu in size.

(A Mu, or millimicron, is equal to 0.000000039 inches.) An example of a chemical in solution is sugar in water.

Colloidal solids, also known as nonsettleable solids, do not dissolve in water although they are electrically charged.

Still, the particles are so small that they will not settle out of the water even after several years and they cannot be removed by filtration alone.

Colloidal solids range between 1 and 500 Mu in size and can be seen only with a high-powered microscope.

Examples include bacteria, fine clays, and silts. Colloidal solids often cause colored water, such as the "tea color" of swamp water.

Finally, suspended, or settleable, solids will settle out of water over time, though this may be so slow that it is impractical to merely allow the particles to settle out in a water treatment plant.

The particles are more than 1,000 Mu in size and can be seen with a microscope or, sometimes, with the naked eye. Examples of suspended solids include sand and heavy silts.

Electrical Charges

The chemistry of coagulation and flocculation is primarily based on electricity.

Electricity is the behavior of negative and positively charged particles due to their attraction and repulsion.

Like charges (two negatively charged particles or two positively charged particles) repel each other while opposite charges (a positively charged particle and a negatively charged particle) attract.

Negative charges make particles repel each other.

Negatively charged particles repel each other due to electricity.

Most particles dissolved in water have a negative charge, so they tend to repel each other.

As a result, they stay dispersed and dissolved or colloidal in the water, as shown above.

The purpose of most coagulant chemicals is to neutralize the negative charges on the turbidity particles to prevent those particles from repelling each other.

The amount of coagulant which should be added to the water will depend on the zeta potential, a measurement of the magnitude of electrical charge surrounding the colloidal particles.

You can think of the zeta potential as the amount of repulsive force which keeps the particles in the water.

If the zeta potential is large, then more coagulants will be needed.

Coagulants tend to be positively charged.

Due to their positive charge, they are attracted to the negative particles in the water, as shown below.

Coagulants attract to the particles in water.

Positively charged coagulants attract to negatively

charged particles due to electricity.

The combination of positive and negative charge results in a neutral, or lack, of charge. As a result, the particles no longer repel each other.

The next force which will affect the particles is known as van der Waal's forces. Van der Waal's forces refer to the tendency of particles in nature to attract each other weakly if they have no charge.

Van der Waal's forces cause the particles to drift together.

Neutrally charged particles attract due to van der Waal's forces.

Once the particles in water are not repelling each other, van der Waal's forces make the particles drift toward each other and join together into a group.

When enough particles have joined together, they become floc and will settle out of the water.

Particles join together into floc.

Particles and coagulants join together into floc.

Part3: Coagulant Chemicals

Types of Coagulants

Coagulant chemicals come in two main types - primary coagulants and coagulant aids.

Primary coagulants neutralize the electrical charges of particles in the water which causes the particles to clump together.

Coagulant aids add density to slow-settling flocs and add toughness to the flocs so that they will not break up during the mixing and settling processes.

Primary coagulants are always used in the coagulation/flocculation process. Coagulant aids, in contrast, are not always required and are generally used to reduce flocculation time.

Chemically, coagulant chemicals are either metallic salts (such as alum) or polymers.

Polymers are man-made organic compounds made up of a long chain of smaller molecules.

Polymers can be either cationic (positively charged), anionic (negatively charged), or nonionic (neutrally charged.)

The table below shows many of the common coagulant chemicals and lists whether they are used as primary coagulants or as coagulant aids.

Different sources of water need different coagulants, but the most commonly used are alum and ferric sulfate.

Alum

There are a variety of primary coagulants which can be used in a water treatment plant.

One of the earliest, and still the most extensively used, is aluminum sulfate, also known as alum.

Alum can be bought in liquid form with a concentration of 8.3%, or in dry form with a concentration of 17%. When alum is added to water, it reacts with the water and results in positively charged ions.

Coagulant Aids

Nearly all coagulant aids are very expensive, so care must be taken to use the proper amount of these chemicals.

In many cases, coagulant aids are not required during the normal operation of the treatment plant, but are used during emergency treatment of water which has not been adequately treated in the flocculation and sedimentation basin.

A couple of coagulant aids will be considered below.

Lime is a coagulant aid used to increase the alkalinity of the water.

The increase in alkalinity results in an increase in ions (electrically charged particles) in the water, some of which are positively charged.

These positively charged particles attract the colloidal particles in the water, forming floc.

Bentonite is a type of clay used as a weighting agent in water high in color and low in turbidity and mineral content.

This type of water usually would not form floc large enough to settle out of the water.

The bentonite joins with the small floc, making the floc heavier and thus making it settle more quickly.

Types of suggested chemical for waste water chemical treatment

Aluminum Chloride Solution

Description:

Aluminum Chloride Solution is a concentrated metal salt solution ranging from 15-28% aluminum chloride.

The aluminum concentration, expressed as Al2O3, is 10.5%.

Aluminum Chloride Solution is available in different product grades depending upon the application:

Flocculant Grade is used for wastewater treatment applications.

This product grade is less concentrated than other grades of Aluminum Chloride Solution and may contain minor amounts of impurities that can alter visual appearance and odor.

Technical Grade is a full strength product of very good quality.

It is suitable for almost all applications, except those where very low levels of iron are required.

Technical Grade Aluminum Chloride Solution is available with NSF approval for drinking water treatment.

Water white Grade is a full strength product, similar to tech grade except for very low levels of iron. The iron (Fe) content of Water white grade is < 1%

Typical Applications and Benefits:

Aluminum Chloride Solution is an excellent source of Al3+ ions where the application demands a strong inorganic cationic metal salt.

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Aluminum Chlorohydrate

Description:

Aluminum Chlorohydrate Solution (ACH) is a highly concentrated solution of polyaluminum hydroxychloride.

It is characterized by having the highest aluminum concentration (23% Al2O3) of any commercially available aluminum based solution.

The basicity of ACH at 83% is also the highest available for any polyaluminum based solution.

Basicity refers to the degree of acid neutralization and also represents a measure of how highly polymerized the aluminum in ACH is.

The highly polymerized aluminum species in ACH have much higher cationic charges than the aluminum in standard salts such as alum or aluminum chloride, and even other polyaluminum products.

Therefore, ACH can offer both a higher level of performance and lower overall dosages.

The high degree of acid neutralization (basicity) also means that the effect on pH when applying ACH will be negligible. ACH also effectively coagulates over a broader pH range (as high as 9.5) versus traditional metal salts and lower basicity Pacl.

Ferric Chloride Solution

Description:

Ferric Chloride Solution is a concentrated mineral acid solution ranging from 30-45%ferric chloride.

Typical Applications and Benefits:

Ferric Chloride Solution is an excellent source of Fe3+ ions where the application demands a strong inorganic cationic metal salt.

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Polyaluminum Chloride Solution

Description:

Polyaluminum Chloride Solution represents a series of products ranging in the degree of acid neutralization, polymerization and Al2O3 concentration.

As the acid is neutralized in the manufacturing process, the aluminum portion of the product becomes more polymerized, resulting in higher cationic charge and increased performance capabilities. The degree of acid neutralization is measured by basicity.

Basicity can range from 0% (aluminum chloride solution) to 83% (aluminum chlorohydrate solution).

Typically available Polyaluminum Chloride solution products have basicities ranging from 10-70%.

Typical Applications and Benefits:

The Polyaluminum Chloride Solution product line offers a broad range of formulations that have unique performance characteristics when compared to the more conventional products like alum, aluminum chloride, ferric chloride, ferric sulfate, etc.

Organic Polymers

General Description:

Organic Polymers are used in a wide variety of municipal and industrial applications. Organic Coagulants are used to enhance the coagulation, flocculation and removal of impurities in water, many of which require NSF certification for use in potable water systems.

Use and Benefits in Water Treatment

Water soluble polymers, polyquatenary amines, polydadmacs, etc. are supplied in easy to use solution forms.

They are highly efficient contributors of cationic charge and molecular weight when applied in specific applications.

The process of coagulation is made highly efficient by the proper application of chemistry and dosage.

Organic Coagulants are used most efficiently in combination with inorganic coagulants such as polyaluminum chloride and other aluminum and iron salts. Depending on the specific chemistry of the target water, polymer use can vary from as little as 5% of the total coagulant dosage (inorganic + organic) to as much as 100% in cases where total organic use is indicated.

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Ferrous Chloride Solution

Description:

Ferrous Chloride Solution is a concentrated mineral acid solution ranging from 22-30% ferrous chloride. The empirical formula is Fe2+ + 2Cl-.

Typical Applications and Benefits:

Ferrous Chloride Solution is an excellent source of Fe2+ ions where the application calls for an oxidizable inorganic metal salt.

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Polyaluminum Chlorosulfate Solution

Description:

Polyaluminum Chlorosulfate Solution is a polymerized aluminum compound containing both chloride (Cl-) and sulfate (SO42-). The basicity (degree of acid neutralization) is 50%, resulting in only minimal impact on the pH of the receiving water.

The chemistry of this solution is such that it produces a very rapid forming and settling floc. PAC works very well in extreme conditions such as low temperature, low alkalinity, and physically challenged plants, where only a minimal amount of mixing and/or settling time is possible.

Polyaluminum Chlorosulfate Solution Product Line is NSF approved and meets AWWA standards for municipal and industrial drinking water applications.

Typical Applications and Benefits:

The Polyaluminum Chlorosulfate Solution product line offers a broad range of products that have unique performance characteristics when compared to the more conventional coagulants like alum, aluminum chloride, ferric chloride, ferric sulfate, etc.

The applications where Polyaluminum Chlorosulfate Solution is often the product of choice are:

Municipal and Industrial Water Treatment

Polyaluminum Chlorosulfate Solution is often employed as the primary coagulant in potable water and industrial water treatment plants, replacing the need for other coagulants such as alum, and in many cases also eliminating or at least greatly reducing the need for pH adjustment chemicals, coagulant aids and filter aids.

The benefits of this Polyaluminum Chlorosulfate Solution Product Line are most apparent when used in difficult treatment conditions; low temperature, low raw turbidities and low alkalinity, but can be effective in all types of waters.

Factors Influencing Coagulation

Introduction

In a well-run water treatment plant, adjustments are often necessary in order to maximize the coagulation/flocculation process.

These adjustments are a reaction to changes in the raw water entering the plant.

Coagulation will be affected by changes in the water's pH, alkalinity, temperature, time, velocity and zeta potential.

The effectiveness of a coagulant is generally pH dependent. Water with a color will coagulate better at low pH (4.4-6) with alum.

Alkalinity is needed to provide anions, such as (OH) for forming insoluble compounds to precipitate them out.

It could be naturally present in the water or needed to be added as hydroxides, carbonates, or bicarbonates.

Generally 1 part alum uses 0.5 parts alkalinity for proper coagulation.

The higher the temperature, the faster the reaction, and the more effective is the coagulation.

Winter temperature will slow down the reaction rate, which can be helped by an extended detention time.

Mostly, it is naturally provided due to lower water demand in winter.

Time is an important factor as well. Proper mixing and detention times are very important to coagulation.

The higher velocity causes the shearing or breaking of floc particles, and lower velocity will let them settle in the flocculation basins.

Velocity around 1 ft/sec in the flocculation basins should be maintained.

Zeta potential is the charge at the boundary of the colloidal turbidity particle and the surrounding water.

The higher the charge the more is the repulsion between the turbidity particles, less the coagulation, and vice versa.

Higher zeta potential requires the higher coagulant dose. An effective coagulation is aimed at reducing zeta potential charge to almost 0.

Coagulant

The proper type and concentration of coagulant are essential to the coagulation process.

The coagulant choice will depend on the conditions at the plant.

The concentration of coagulant also depends on the water conditions, and a jar test can be used to determine the correct concentration to use at any given time.

Coagulants are usually fed into the water using a gravimetric feeder or a metering pump. A gravimetric feeder feeds dry chemicals into the water by weight. A metering pump feeds a wet solution (a liquid) into the water by pumping a volume of solution with each stroke or rotation.

Improper coagulation related to coagulant may result from:

Using old chemicals

Using the wrong coagulant

Using the wrong concentration of coagulant.

This may result from setting the wrong feed rate on the gravimetric feeder or metering pump or from a malfunction of the equipment.

The efficiency of the coagulation-flocculation process is dependent on many variables. For a particular water these may include:

§ Type of coagulant used

§ Coagulant dosage

§ Final pH

§ Coagulant feed concentration

§ Type and dosage of chemical additives other than primary coagulant (e.g. polymers)

§ Sequence of chemical addition and time lag between dosing points

§ Intensity and duration of mixing at rapid mix stage

§ Type of rapid mix device

§ Velocity gradients applied during flocculation stage

§ Flocculator retention time

§ Type of stirring device used

§ Flocculator geometry.

So from the above parameter,we suggested the waste treatment steps to be compatable with environmental rules as 44/2000 and to be ready to go a head into (RO-UNIT) to achiving your parameters required for your operations

*DESIGN*	*TREATMENT-TYPE*	*NO.*
open underground concrete Tank with capacity of 400 cubic meters dimensions (3mitr high / 10 meter length / 10 m width) and is divided from the inside to the ten-lane width of each lane 1 meter and a height of two meters and ends filter of stainless steel with openings girth half to five micrometer to removal material dissolved with large and medium-sized particals and provides the tank number 4 slots out residual waste through pipes and pumps to pull the sludge to collection area	*PRE-TREATMENT*	1
*A set of pumps to lift water from last collection point in the collection tank to tank of chemical treatment* *3pumps with the ability to withdraw the pump 60 cubic meters / hour to operate 1 basic and 2 as reserves run* The metallic chemical processing tank cylinder from the top and conical from the bottom of the Vee capacity of 60 cubic meters provider with mixer for mixing chemicals, sewage and bottom of the barrel connector exit to exit sludge through 4 inches pipes across screw suction pump with ability of 20 cubic meters / hour Preparation of treatment chemicals unit composed of a 3 tanks (2 tank of a polyethylene +1tank of stainless steel) capacity of reservoirs 2 cubic meter is mounted on each tank number 1 Mixer + pump injection Chemicals variable volume pump treatment chemicals (co-aggultant + flocullant + clarifiring) in the liquid state to chemical treatment tank Number 2 pump drawing water treatment chemical processing tank to tank of biological treatment tank with ability to withdraw 60 cubic meters / hour and one key basic and the other backup as reserves run	*CHEMICAL-TREATMENT*	2
Unit for biological treatment system, ventilation and flotation with dissolved air capacity of 60 cubic meters with 2 pumping air from the bottom to the highest with capacity of 60 bar with the addition of chemical active sludge media constituent of the 200 species of aerobic bacteria to get rid of groups of nitrate-sulfate-carbonate-phosphate-iron-manganese and ending parts of the pipe connected to Vee out sludge through pipes of 4-inch diameter connected to the suction screw pump with ability 20 meters/hour Preparation Unit for materials of biological treatment of the chemical active sludge media in tank with capacity of 2 cubic meter of polyethylene provider with mixer for flipping and chemical injection pump with flowmeter A number of 2 pumps draw water treatment from biological treatment tank to tank of physical treatment with ability to withdraw 60 cubic meters / hour wherever one key basic and the other backup as reserve run	*SECONDARY-BIOLOGICAL TREATMENT*	3
CPU physical depositional tank divided into two parts, the first system closets number 4 chambers flowing water where once from the top and once from the bottom to upset the water and then the second unit sedimentation 100 lamella plates oblique angle of 55-56 degrees and make the movement of water from 20-30 km / h and fitted from the bottom Vee parts connected to pipe out remnants of 4-inch diameter and pump suction ability residues 20 cubic meters / hour	*PHYSICAL-TREATMENT*	4
*Unit for final Filteration consisting of a 3 Filters* *first filter Sandstone / gravel dimensions diameter 110 cm and height of 300 cm and then---* *the second filter of active carbon to expel diameter 110 cm and height of 300 cm and then—* *the third filter of zeolite dimensions of 110 cm diameter and height of 300 cm* *equipped with automatic head unit with ability 50 cubic meters / hour for entry and exit of treated water and provide with unit for backwash the filters* *so the material for manufacturing the filters made of galvanized iron* *And provide with number of 4 pumps lifting capacity per 60 cubic meters / hour are placed as following* *the first between the physical treatment tank and sand filter* *the second between the sand filter and carbon filter* *the third between carbon filter to zeolite filter* *the fourth between zeolite filter to treated water tank*	*FILTERATION-TREATMENT*	5
*underground Concrete tank for collection treated filterated water suitable to enter the R.O-UNIT.* *concrete tank with ceramic have a volume of 200 cubic meters, 2 meters high dimensions / length of 10 meters / 10 meters width*	*TREATED WATER COLLECTING TANK*	6
concrete Tank with capacity of 100 cubic meters divided into 2 meter underground and 1 meter above the ground to collect the sludge from all the reservoirs (the assembly first / chemical / biological / natural / backwash of filters) and post these processors are residues in the case of 35%liquid	*SLUDGE COLLECTING TANK*	7

The schedual of equipments in the suggested plant

*TREATMENT PURPOSE*		*QUNT.*	*ITEM*	*NO.*
*PRETREATMENT,COLLECTIN FEED WATER TANK*		1	*CONCERETE TANK*	1
*TREATED WATER COLLECTION TANK*		1	*CONCERETE TANK*	2
*SLUDGE COLLECTION TANK*		1	*CONCERETE TANK*	3
*CHEMICAL TREATMENT TANK*		1	*STEEL TANK*	4
*BIOLOGICAL TREATMENT TANK*		1	*STEEL TANK*	5
*PHYSICAL TREATMENT TANK*		1	*STEEL TANK*	6
*CHEMICAL PREPERATION TANK FOR CHEMICAL TREATMENT*		2	*PLASTIC TANK*	7
*CHEMICAL PREPERATION TANK FOR BIOLOGICAL TREATMENT*		1	*PLASTIC TANK*	8
*CHEMICAL PREPERATION TANK FOR CHEMICAL TREATMENT*		1	*STAIN STEEL TANK*	9
*3 FROM COLLECTION TANK TO CHEMICAL TANK.* *2 FROM CHEMICAL TANK TO BIOLOGICAL TANK.* *2 FROM BIOLOGICAL TANK TO PHYSICAL TANK.* *1 FROM PHYSICAL TANK TO SAND FILTER.* *1 FROM SAND FILTER TO CARBON FILTER.* *1 FROM CARBON FILTER TO ZEOLITE FILTER.* *1 FROMZEOLITE FILTER TO TREATED WATER TANK.*		11	*RAISING PUMPS*	10
*2 FROM COLLECTION TANK* *1 FROM CHEMICAL TANK* *1 FROM PHYSICAL TANK* *1 FROM BIOLOGICAL TANK* *1 FROM SLUDGE TANK TO OUT OF PLANT*		6	*SUCTION SCREW PUMPS*	11
*3 FOR CHEMICAL PREPARATION* *1 FOR BIOLOGICAL MEDIA PREPARATION*		4	*CHEMICAL INJECTION PUMP*	12
*1 FOR CHEMICAL TREATMENT TANK* *3 FOR CHEMICAL PREPARATION TANKS* *1 FOR BIOLOGICAL MEDIA PREPARATION TANK*		5	*MIXERS*	13
*PHYSICAL TREATMMENT TANK*		*100 PLATES*	*LAMELLAPLATES SHEET*	14
*PRETREATMENT COLLECTION TANK*		10	*STAINSTEEL SCREEN FILTER PLATE*	15
*FINAL FILTERATION MEDIA*		3	*STEEL FILTER*	16
*FINAL FILTERATION MEDIA*		3	*AUTOMATIC HEAD FOR FILTER*	17
*FINAL FILTERATION MEDIA*		3	*BACH WASH UNIT*	18
*ALL LENGTH OF PLANT*		1	*STEEL BLADDER*	19
*SURROUNDING ALL OF PLANT*		1	*STEEL WALL*	20
*FOR ALL PLANT*		1	*AUTOMATIC ELECTRIC OPERATING UNIT*	21
	*1 FOR CHEMICAL PREPARATION* *2 FOR BIOLOGICAL TREATMENT*	3	*AIR PUMP*	22

THE TREATED WATER ANALYSIS ACCORDING TO SUGGESTED WASTE WATER TREATMENT UNIT AND EGYPTAIN ENVIROMENTAL RULES NO.44/2000

*NORMAL(MG/L)*	*ITEM*	*NO.*
*600*	*BOD*	1
*1100*	*COD*	2
*6-9*	PH	3
*100*	*OIL&GREASE*	4
*43 C*	*TEMP.*	5
*800*	*TSS*	6
*8-15CM³/L*	*SED.DS*	7
*9000*	*TDS*	8
-	*PO4*	9
25	*TOTAL.POSPH.*	10
-	*NH3*	11
-	*NH2*	12
-	F	13
10	*SO4*	14
*100*	*NO3*	15
-	*IRON*	17
1	NI	18
-	ZN	19
1	*SIO2*	20
5	*TURBIDITY*	21
6	CA	22
1	K	23
*150*	*CO3*	24
-	*HCO3*	25
-	MN	26
-	B	27
-	BA	28
*5000*	CL	29
*4000*	NA	30

Operating steps

Collect water inside the tank assembly first passage of water through the 10-lane gradual rises and traveling at 30 km / h on the degree 55-56 degree for pollutants large and medium-sized sedimentation and water remains inside the tank for 6 hours of deposition before moving to the next step

The pumps lift the water deposited from the top two thirds of the tank to pull part of 50 cubic meter to the chemical treatment tank

The mixer start to work at 400-600 rpm just the waste water inside the tank,so the first chemical (co aggultant=poly aluminum chloride) in liquid state is adding for 10 min at effective ph=4-5,so the ph will deacreasing from 12 to 4.5 to precipitate the large and medium moles directly to the bottom of tank.

So the second chemical ll adding which is (the floculltant=hydrated calcium hydroxide) in liquid phase is adding for 10 min too at effective ph=11,so the ph ll increasing from 4.5 to 11 to precipitate the small moles by collecting firstly at the surface of the water and at definite molecular weight ll precipitated to the bottom of the tank.

So the third chemical ll adding (the clarifiring=inionic polymer) in liquid phase for 10 min to moderate the ph =8.5-9 achieving the clear crystal for water and extra precipitation to the sludge in liquifing pase=35% as small cake

So we stop the mixer to achieving the high level of sedimentration to separating the clear water than the sludge cake

This small cake of sludge is sucking by sucking screw pump to the sludge collecting tank

So the third step ll start from raising the treated water from the chemical treatment tank to the biological tank to make the flotation by air in the presence of chemical active sludge media to breaking all of chemical group which remain without any reaction in the chemical treatment step,so that ll be taking 30 min.

After the end of aeration and flotation,the sludge ll sucking to the sludge collecting tank and the treated water ll raising to the forth step of treating=physical treatment step by movement the water with velocity-25-30 km/hrs through physical chamber one from the top and another time from the bottom,so go to the lamella plate sheet to decreasing velocity to 10-15km/hrs to make high precipitation to the water make our parameters at80-90% in low levels at normal

values we need

So the sludge is sucking to the sludge collecting tank

After complete clearfing of water in physical treatment step the water is raising to the final filteration step which consistes of (sand/gravel/active carbon/zeolite) to adapted the ph and temp.,and cod,bod,complete removal of heavy metals and oil,grease,colloidal dissolved solids,odour and colour that ll achieving by bed depth of each media and good specification to make an extra-filteration,absorption and adsorption at retention time for passing the water inside the medias

The treated water is collecting in the treated water tank ready to go inside the R.O UNIT

The sludge is ready to treated to sucking and dewatring out side the unit or reused by your team in work shope again

The retention time of treating through the suggested waste water treatment plant for every 50 cubic meter of waste water=3 hrs treated in 4 steps of treatment methods

The treated water ll be=25-40 cubic meter of every 50 cubic meter achieving the total treated water=600-1000 cubic meter/1200 cubic meter /day

The suggested sludge in 35% liquid phase=10-25 cubic meter/50 cubic meter/hrs=200-600 cubic meter/1200cubic meter /day

ECONIMICAL QUOTATION

The schedual of equipments in the suggested plant

*TREATMENT PURPOSE*	*QUNT.*	*ITEM/price*	*NO.*
*PRETREATMENT,COLLECTIN FEED WATER TANK*	1	*CONCERETE TANK* *600000 eg.p*	1
*TREATED WATER COLLECTION TANK*	1	*CONCERETE TANK* *300000 eg.p*	2
*SLUDGE COLLECTION TANK*	1	*CONCERETE TANK* *150000 eg.p*	3
*CHEMICAL TREATMENT TANK*	1	*STEEL TANK* *180000 eg.p*	4
*BIOLOGICAL TREATMENT TANK*	1	*STEEL TANK* *180000 eg.p*	5
*PHYSICAL TREATMENT TANK*	1	*STEEL TANK* *180000 eg.p*	6
*CHEMICAL PREPERATION TANK FOR CHEMICAL TREATMENT*	2	*PLASTIC TANK* *6000 eg.p*	7
*CHEMICAL PREPERATION TANK FOR BIOLOGICAL TREATMENT*	1	*PLASTIC TANK* *3000 eg.p*	8
*CHEMICAL PREPERATION TANK FOR CHEMICAL TREATMENT*	1	*STAIN STEEL TANK* *20000 eg.p*	9
*3 FROM COLLECTION TANK TO CHEMICAL TANK.* *2 FROM CHEMICAL TANK TO BIOLOGICAL TANK.* *2 FROM BIOLOGICAL TANK TO PHYSICAL TANK.* *1 FROM PHYSICAL TANK TO SAND FILTER.* *1 FROM SAND FILTER TO CARBON FILTER.* *1 FROM CARBON FILTER TO ZEOLITE FILTER.* *1 FROMZEOLITE FILTER TO TREATED WATER TANK.*	11	*RAISING PUMPS* *440000 eg.p*	10
*2 FROM COLLECTION TANK* *1 FROM CHEMICAL TANK* *1 FROM PHYSICAL TANK* *1 FROM BIOLOGICAL TANK* *1 FROM SLUDGE TANK TO OUT OF PLANT*	6	*SUCTION SCREW PUMPS* *360000 eg.p*	11
*3 FOR CHEMICAL PREPARATION* *1 FOR BIOLOGICAL MEDIA PREPARATION*	4	*CHEMICAL INJECTION PUMP* *48000 eg.p*	12
*1 FOR CHEMICAL TREATMENT TANK* *3 FOR CHEMICAL PREPARATION TANKS* *1 FOR BIOLOGICAL MEDIA PREPARATION TANK*	5	*MIXERS* *80000 eg.p*	13
*PHYSICAL TREATMMENT TANK*	*100 PLATES*	*LAMELLAPLATES SHEET* *150000 eg.p*	14
*PRETREATMENT COLLECTION TANK*	10	*STAINSTEEL SCREEN FILTER PLATE* *50000 eg.p*	15
*FINAL FILTERATION MEDIA*	3	*STEEL FILTER* *150000 eg.p*	16
*FINAL FILTERATION MEDIA*	3	*AUTOMATIC HEAD FOR FILTER* *150000 eg.p*	17
*FINAL FILTERATION MEDIA*	3	*BACH WASH UNIT* *45000 eg.p*	18
*ALL LENGTH OF PLANT*	1	*STEEL BLADDER* *60000 eg.p*	19
*SURROUNDING ALL OF PLANT*	1	*STEEL WALL* *90000 eg.p*	20
*FOR ALL PLANT*	1	*AUTOMATIC ELECTRIC OPERATING UNIT* *125000 eg.p*	21
*1 FOR CHEMICAL PREPARATION* *2 FOR BIOLOGICAL TREATMENT*	3	*AIR PUMP* *180000 EG.P*	22
*THE TOTAL COST*		*ELECTRO-MECHANIC* *2,347,000 EG.P* *STEEL-STRUCTURE* *150000 EG.P* *CIVIL-STRUCTURE* *1,050,000 EG.*P	23

THE PRICE UNINCLUDING SALES TAXES

ORIGIN OF ELECTROMECHANIC=EUROPIAN

PAYMENT-ORDER

50% ADVANCED AT CONTRACT SIGN

25% AT EQUIPMENT DELIVERY AT PROJECT LOCATION

25% AFTER DELIVERY,ERECTION,WORKING OF PLANT

VALIDITY

30 DAYS

THE TOTAL COST OF CHEMICALS/YEAR

253200 EG.P/YEAR

THE TYPES OF CHEMICALS FOR CHEMICAL&BIOLOGICAL TREATMENT

*PURPOSE*	*QTY.*	*ITEM*	*NO.*
*AGGULTANT*		*POLY ALUMIN.CLORIDE*	1
*FLOCULTANT*		*HYDRATED CALCIUM HYDROXIDE*	2
*CLAFIRING*		*ANIONIC POLY ACRYLAMIDE*	3
*BOILOGICAL ACTIVE MEDIA*		*ACTIVE SLUDGE MEDIA*	4

THE TOTAL COST OF MEDIA / 3 YEARS

EG.P/3YEARS

THE TYPES OF FILTER MEDIA

*BED DEPTH*	*QTY.*	*ITEM*	*NO.*
*200 CM*		*SAND FILTER*	1
*220 CM*		*ACTIVA CARBON FILTER*	2
*200 CM*		*ZEOLITE FILTER*	3

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