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Sodium Hexametaphosphate | SHMP 68915-31-1

Sodium Hexametaphosphate | SHMP 68915-31-1,Sodium Hexametaphosphate is a compound that often goes unnoticed despite its widespread use in various industries. From water treatment to industrial manufacturing, Sodium Hexametaphosphate helps to enhance product quality, improving efficiency, and ensuring optimal performance. This article will further discuss the preparation, chemical characteristics, physical characteristics and many more to know and have an in-depth understanding of sodium Hexametaphosphate.

Sodium Hexametaphosphate | SHMP 68915-31-1

Organophilic Clay For Oil Drilling Mud

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Organoclay For Solvent Based Paint

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Organoclay For Water Based Paint

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Organo Bentonite For Grease

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Organoclay For Cosmetics

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Organoclay For Inks

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Wax Emulsion for Drilling Fluid

Wax emulsion can not only be used in drilling mud, but also widely used in the fields of coatings and inks, paper and packaging, and plastics.

In the textile and leather industries, it is used as a wear-resistant agent, lubricant, and matting agent, while the use of wax emulsion in leather can give it a better feel and can prevent stains and protect it.

It can be said that the application of wax emulsion is extremely wide.

In addition to the applications we mentioned above, it can also be applied to the ceramic industry, concrete maintenance and sealing industry, as well as adhesives, sealants, and cosmetics.

Wax Emulsion for Drilling Mud

Wax Emulsion

Wax emulsion is used in drilling mud. The first role it plays is to protect the stability of the well wall, and to play a role in lubrication and reducing resistance. At the same time, it can effectively reduce its filtration loss and protect the reservoir.

The reduction of filtration loss is mainly because drilling fluid is more likely to lose drilling fluid, which affects the stability of the well body.

Therefore, we use wax emulsion to seal the gaps in the formation and form a more resilient membrane, so that the pressure membrane of the well wall is not easy to be broken.

Sodium Hexametaphosphate

ORGANOCLAY:

Our Five-Star Treatment Media

Your first choice for removing organic contaminants from water or sediment, the ORGANOCLAY product range provides formulations to meet almost any adsorption application.

Used and trusted worldwide, it’s proven to work efficiently and effectively.

A little goes a long wayand reduces costs

ORGANOCLAY’s substantial adsorption capacity not only reduces necessary cap thickness compared to a conventional sand cap but can also extend cap life—in some circumstances, for years—and reduce overall costs.

Because ORGANOCLAY can be used as a pre-treatment to Granular Activated Carbon (GAC), ORGANOCLAY can increase overall efficiency by preventing surface pores in GAC from blinding.

The ORGANOCLAY Product Range

Powerfully adsorbant ORGANOCLAY is available in multiple formulations to best mitigate water and sediment contamination in a variety of specific conditions:

ORGANOCLAY: Our coarsest grain media, ORGANOCLAY is a larger and denser version of ORGANOCLAY CP-200 to aid in settling through the water column. When used for sediment capping, ORGANOCLAY can be placed hydraulically or mechanically.

Applications:

Sediment Capping

Organoclay_Sample_Shot

ORGANOCLAY : A proprietary granular filtration media that reliably adsorbs oils and similar organics from water. It is a brown and black mixture of 30% active ORGANOCLAY and 70% anthracite filter media, which allows for maximum utilization of the large sorption capacity of ORGANOCLAY without excessive pressure build-up in the column. When used as an in-series filtration media prior to an activated carbon vessel, ORGANOCLAY extends the life and adsorbency of the activated carbon by removing larger molecular organics before they reach it. It also lowers the overall operating cost relative to using activated carbon alone. ORGANOCLAY can also be used in standalone mode to treat oil-contaminated water and stream condensates.

Applications:

Groundwater Pump-and-Treat

Sediment Dewatering Treatment

Organoclay

ORGANOCLAY: In addition to adsorbing non-aqueous phase liquids and dissolved low-solubility organics, specially-formulated, sulfur-impregnated ORGANOCLAY sequesters mercury (Hg0, Hg+1 and Hg+2) and arsenic (As+5) from water. Ideal for groundwater pump-and-treat or sediment dewatering treatment, ORGANOCLAY can also be used in soil or sediment solidification/stabilization or as an additive to Portland Cement.

Applications:

Groundwater pump-and-treat

Sediment dewatering treatment

Solidification/stabilization

ORGANOCLAY CP-199: Our second finest grain media, ORGANOCLAY CP-199 features high adsorption capacity of oils, greases, and other NAPL. When used as an in-series filtration media prior to an activated carbon vessel, ORGANOCLAY CP-199 extends the life and adsorbency of the activated carbon by removing larger molecular organics that can cause fouling. ORGANOCLAY CP-199 also works as a standalone treatment media to treat oil-contaminated water and stream condensates.

Applications:

Organophilic Filtration Media

Bulk Sediment Capping

Solidification/Stabilization additive

Organoclay_Sample_Shot

ORGANOCLAY CP-200: Our second coarsest grain media, ORGANOCLAY CP-200’s particle size aids in settling through the water column when placing a bulk active in-situ sediment cap. ORGANOCLAY CP-200 is also your best match for intermixing with coarse inert soil for use of a Permeable Reactive Barrier (PRB).

Applications:

Bulk Sediment Capping

Permeable Reactive Barrier (PRB)

Organoclay_Sample_Shot

ORGANOCLAY 199: Our finest-grain media, ORGANOCLAY 199 features medium adsorption of oils, greases, and helps stabilize organics for increased solidification of treated soils and sediment. ORGANOCLAY 199 is for use in soil or sediment solidification/stabilization or as an additive to Portland Cement.

Applications:

In Situ Solidification

How it does it

The ORGANOCLAY product line is a range of proprietary adsorption media that is highly effective in removing oils, greases and other high molecular weight, low solubility organic compounds from aqueous streams. ORGANOCLAY products are specialty sorbents, altered to an organophilic state making them attractive to organic molecules.

Camp ShinningPioneer and leader in environmental remediation

Camp Shinning is the leader and pioneer in cutting-edge environmental remediation solutions. Around the globe, our innovative teams of clay mineralogists, chemists, and polymer scientists transform ordinary minerals into extraordinary technology to solve day-to-day problems worldwide.

Organoclay is an organically modified phyllosilicate, derived from a naturally occurring clay mineral. By exchanging the original interlayer cations for organocations (typically quaternary alkylammonium ions) an organophilic surface is generated, consisting of covalently linked organic moieties. The lamellar structure remains analogous to the parent phyllosilicate.

Separation of the layers due to ion exchange, from the initial interlayer spacing of as little as 3 Å in the case of Na+ cations to the distances in the range of 10–40 Å as well as the change of chemical character of the clay surface, allows the in-situ polymerization or mixing with certain polymers to obtain what is known as nanocomposite. When ordered aluminosilicate sheets are lying parallel to each other, separated with polymer chains of certain type, the system is classified as intercalated nanocomposite. If separation of the layers is so significant, that they are no longer lying opposite to one another, but randomly ordered, then one get the exfoliated nanocomposite.

Applications

Owing to its large surface area together with hydrophobic chains emerging from the clay surface, organoclay can be used to remove oil from water. It is also applied as a component in paint formulations or as a viscosifier for oil-based drilling fluids.

It can be used in polymer chemistry as a nucleating agent.

What is Organoclay?

How Organoclay is Used and the Benefits

Organoclay is a naturally occurring material that is commonly used in water treatment. Organoclays are well known for their high removal rate of oils and other hydrophobic compounds in water. The media is a naturally occurring mineral (commonly zeolite, bentonite clay, or a smectite mineral) which is chemically alternated to create a unique surface on the mineral. Camp Shinning’s organoclay is a zeolite based organoclay which has does not swell upon exposure to water.

How does Organoclay Work?

Camp Shinning alters zeolite with a surfactant bilayer that enhances the media’s ability to remove pollutants. The surfactant bilayer is created when a quaternary amine or surfactants is added to the mineral to modify the surface commonly referred to as surface-modified-zeolites (SMZ). By modifying the surface, we create a strong affinity with either cations (positively charged ions, i.e. dissolved metals) or anions (negatively charged ions, i.e. phosphate, nitrate). The bilayer that contains hydrophobic chains will capture non-polar organics such as benzene.

Illustration of How Organoclay Works

How is Organoclay Used?

Organoclays are used in various industries including remediation, water treatment, soil treatment, in polymer chemistry, in paints as a thickening agent, grease, inks, oil drilling fluids, rheological products, cosmetics, and many more commercial and industrial applications.

What are the Benefits of Using Organoclay?

Versatile installation — Load the media in standalone units, post-treatment, or pre-treatment units. To learn more about these systems on our Water Filtration Systems Page.

Cost Savings — Organoclay is an economical alternative to other treatment technologies such as resins or Granular Activated Carbon (GAC).

Increase Efficiency — Organoclays will decrease the loading on other treatment systems and increase the life of capital equipment.

Storage — Organoclays have a long shelf life and require dry ambient environments.

Handling — Organoclays are safe and easy to use.

How is Organoclay Used in Water Treatment?

CP-200 Liquid Phase, Pure Organoclay

Organoclays are used in industrial and commercial water treatment such as:

Condensate Treatment Systems: Condensate treatment is part of every power plant, refinery, chemical manufacturer, and any facility that uses stream. Typically, the condensate is recycled back into the boiler feed water where it is routed through boiler tubes for continued boiler use.

Recycling condensate is a common practice which decreases the amount of water disposal but can be costly if not designed correctly. By not treating the condensate that goes back into your boiler feed water you are introducing high concentrations of pollutants that came off leaking pumps, valves, and piping to your boiler tubes. When these pollutants (hydrocarbons and minerals) are introduced to the boiler tubes they will deposit on the surface which will reduce the heat transfer and overall reducing the boiler efficiency.

Camp Shinning’s works with condensate treatment manufacturers and users on providing a specialty blend of filter material for treating the pollutants that are commonly found in condensate. The condensate treatment blend of filter media uses organoclay and activated carbon to trap the contaminates in its’ pore structure.

Process Water Reuse Systems: Leaking pipes, valves, vessels, or inefficient processes can leave process water tainted with low concentrations of pollutants. These pollutants over time can lead to hazardous water that needs to be hauled off site for treatment. A common use of organoclay is to treat process water onsite in a vessel to reuse the water instead of discharge it or accumulate it and haul it off-site as hazardous waste. Tainted water can lead to downtime of capital equipment and hefty bills for hazardous waste disposal. Examples of process water treatment systems might include the wash water that is used in a metal plating facility, or batch water that has low concentrations of acrylic paint thinner. Simply installing a vessel of organoclay in a process water loop can significantly reduce planned and unplanned downtime.

Organoclays are used in remediation projects such as:

Groundwater Treatment: Pump-and-Treat Systems are typically implemented when groundwater is contaminated. For pump-and-treat systems, the water is typically pumped out of the ground into a large vessel. The large vessel or series of vessels is filled with a filter media (i.e. granular activated carbon, organoclay, resin) that removes any pollutants of concern such as heavy metals or oil. The water is then put back into the ground. Pump-and-treat are cost-effective designs for treating water if you select the most appropriate filter media to target your pollutants.

Sediment Capping: Capping, also known as permeable reactive barrier , is an in-situ remediation technology that typically follows dredging operations. Organoclay is used in sediment capping due to its’ ability to isolate contaminated sediment from a surrounding aquafer or aquatic system. It is a cost-effective material for capping as it has strong affinity for removing high molecular weight polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs), and heavy metals.

Stormwater Treatment: Organoclay is used to improve water quality in stormwater runoff. Typically, pollutants found in stormwater are monitored by state regulators to ensure we have clean lakes, rivers, oceans and wetlands

Learn more about how Organoclay is used in water treatment.

Rheological Additive for Solvent Base System

CP-200 is an organic derivative of bentonite clay act as Rheological additive in low to high polarity systems. Such as Ketones, Glycol, Alcohol, Esters and Ethers, includes Polar System with some Aromatic Solvents.

Properties & Markets

Paints & Coatings : A small addition of ORGANOCLAY can greatly enhance the rheological properties of the paint system. These properties prevent pigment settling and sagging on vertical surface to ensure the proper thickness of the coating is applied. They also ensure good leveling for the removal of brush marks.

Storage stability is guaranteed even with high temperatures. ORGANOCLAY confer water resistance and structure reinforcement with no adverse effect on adhesion and solvent relese. Gloss is minimally affected due to the low levels of addition. ALL ORGANOCLAY are used widely in a vast range of solvent based paint systems

Architectural Paints : Undercoats, Primers, Semi-Gloss, Gloss and Wood Stains

Industrial Coatings : Air Drying, Stoving Enamels, Epoxies, Esters, Urethanes, Vinyls, Acrylics, Anti-Corrosive, Automotive, Bitumionous, Coil, Road Marking, Underbody Car Coatings, Nitro Cellulose and Chlorinated Rubber.

Printing Inks : With the correct ORGANOCLAY, is possible to adjust the consistency of printing inks to the desired values, avoiding pigment sedimentation, providing good color distribution obtaining desired film thickness, reduction in misting, control of track, water pick up and dot gain control. ORGANOCLAY are used in much letterpress, lithographic and offset ink.

Lubricating Greases : Thickening lubricating oils with ORGANOCLAY can produce specialty high temperature resistant lubricating greases. ORGANOCLAY also gives good working stability and water resistance to the greases. Such greases are typically used for lubrication in foundries, mills and on high speed conveyors. Other greases can be manufactured for other industries such as agriculture, aviation, automotive and mining.

Cosmetics : The performance of cosmetics is enhanced by the use of ORGANOCLAY and they allow good colour retention and coverage for nail lacquers, lipsticks and eye shadows. They have been tested to be non-irritant for both skin and eye contact.

Food Contact Applications : ORGANOCLAY are used as thixotropic agents in coatings that come into contact with food. They are also used as fillers in plastic food containers. They are acceptable under current EEC legislation on food contact additives.

Drilling Fluids : ORGANOCLAY are used extensively in drilling fluids throughout the world. They are used to suspend the heavy sealing agents, normally barytes and carry the cuttings back to the surface. They also play an important part in lubricating the drill. ORGANOCLAY can also be used as fracfluids, where the gelling ability of them is used to seal rock fractures in the bore hole.

Nanofiller for Plastic : Highly purified organoclays because of their particle size and chemical structure have the unique ability to be able to function in a wide range of monomers and polymers. The resulting properties of polymers, compounded with these unique organoclays include :

  1. Increased Modular Strength without Sacrificing Impact Resistance
  2. Improved Gas Barrier Properties
  3. Increased Solvent and Heat Resistance
  4. Improved Fire Retarding Properties

The combination of these improved properties, convenient processing and relative low costs, makes nano composites a tremendous commercial opportunity as they are superior alternatives to the current fillers used in polymer systems.

Hectorite and Bentonite based organoclay grades

Optimum activation of organoclays by ideal organoclay for highest effectivity

Correct activation for highest efficiency

❖ Optimum shear applied for proper delamination

❖ Correct use of polar activator for conventional grades

❖ Right order of addition for best processing result

organoclays can be optimized by improved process parameters including a review of the process temperature.

However, temperature control during organoclay dispersion in solvent based systems is not as important as with e.g.

organic thixotropes.

Various methods used in manufacturing formulations and procedures sometimes suffer in efficiency when order of addition and mixing conditions are less than optimum.Further, the effects of solvent resin temperature on process development and final results will be discussed.

organoclay materials are based on either

bentonite or Hectorite, both minerals from the smectite group. They consist of microfine platelet stacks that, due to their mineralogical structure, expand in water in their natural form. In order to make them compatible with non-aqueous media such as organic solvents, however, it is necessary to modify the surface of their silicate plates with quaternary ammonium compounds.

The choice of this modification and processing conditions also plays an important role in the practical applicability and performance capabilities of the finished end systems. The resulting organoclay will be dried and milled to achieve a powdered material.

To be most rheologically effective, the size of the individual platelets and the total combined edge length following their successful activation is decisive.

the Hectorite platelets are significantly smaller than the bentonite ones, the resulting edge length per gram of silicate in the Hectorite is much larger.

This makes Hectorite additives able to build up a much denser and more rheologically effective network. In order to be activated, organoclays must first be exposed to high shear forces over a defined swelling period.

What is organophilic clay?

Organophilic clay is a type of clay that has been chemically modified to be compatible with organic solvents and non-aqueous systems. It’s a viscosifier and gelling agent used in various applications, including drilling fluids, paints, and cosmetics.

[Drilling Fluids]

Clay minerals whose surfaces have been coated with a chemical to make them oil-dispersible. Bentonite and hectorite (plate-like clays) and attapulgite and sepiolite (rod-shaped clays) are treated with oil-wetting agents during manufacturing and are used as oil-mud additives. Quaternary fatty-acid amine is applied to the clay. Amine may be applied to dry clay during grinding or it can be applied to clay dispersed in water. The latter process is much more expensive, requiring filtering, drying and other manufacturing steps. Organophilic bentonite and hectorite, “bentones,” are used in oil muds to build rheology for cuttings lifting and solids suspension. They also contribute to low-permeability filter cake. Organophilic attapulgite and sepiolite are used in oil muds strictly to build gel structure, which may not be long lasting due to shear degradation as the mud is pumped through the bit.

CP-2 organophilic clay is a viscosifier and gelling agent used in VERSA oil-based and NOVA synthetic-based systems. This amine-treated bentonite is used to increase carrying capacity and suspension properties, providing support for weighting agents and improved cuttings removal. CP-2 viscosifier also aids in filtercake formation and filtration control.

Applications

CP-2 viscosifier is proven effective in drilling, coring, workover and completion fluids. The product is also effective in specialty applications such as casing packs, packer fluids and spotting fluids. Good agitation and sufficient shear are required to develop viscosity when using CP-2 viscosifier to build fresh mud.

Typical concentrations range from 2 to 10 lbm/bbl [5.7 to 28.5 kg/m3] for most drilling fluid applications, depending on the base fluid and system requirements. Mineral oils generally require higher concentrations than diesel oils. CP-2 viscosifier will not fully yield by the shear and temperature exposure in a mixing plant or mud pit. Care should be taken not to overtreat with CP-2 viscosifier until the fluid has actually circulated through the well. For system maintenance, CP-2 viscosifier should be added as needed to maintain the flow properties and gel strengths in the desired ranges. Specialty applications such as packer fluids and casing packs typically use concentrations in the 10 to 15 lbm/ bbl [28.5 to 43 kg/m3] range.

Advantages

Provides gel structure and viscosity for the suspension of weight materials

Increases viscosity for improved hole-cleaning capacity

Improves filter-cake quality and filtration characteristics

Effective gelling agent in casing packs and packer fluids

Toxicity and handling

Bioassay information is available upon request. Handle as an industrial chemical, wearing protective equipment and observing the precautions described in the safety data sheet.

Packaging and storage

CP-2 viscosifier is packaged in 50-lb [22.7-kg] multiwall paper sacks. Store in a dry, well-ventilated area. Keep container closed. Store away from incompatibles. Follow safe warehousing practices regarding palletizing, banding, shrink-wrapping, and stacking.

So far I’ve had no luck finding organophilic clays like CP series in China apart from one drilling company that wanted upwards of $200 for a 25Kg bag of oil drilling product. I did a trawl of online patents to see how hard the stuff is to make.

Both these chemicals are used in fabric softeners and are available as industrial chemicals. Buying the bentonite and the surfactants above might be a bit more common compared to bentone in countries that don’t drill for oil much.

Is it going to be easy to buy these industrial surfactants than Bentone?, probably is if you can find an industrial chemical supplier who’ll sell you less than a 200 litre drum.

Organophilic Clay

Organophilic clay is a wet process improved viscosifier and gelling additive, derived from a naturally occurring clay mineral.

Feature

Organophilic clay has good performance efficiency in diesel, mineral oil and synthetic Oil; It can effectively suspends weighting materials and other solids, maintains suspension over a wide temperature range.

Application

Organophilic clay is a self-activating gallant offering rapid yield development, high gel strengths, and increased efficiency.

Sodium Hexametaphosphate | SHMP 68915-31-1

 

What is Sodium Hexametaphosphate?

Sodium Hexametaphosphate is also known by its synonyms Graham’s salt Tech Grade. It is a chemical compound with the CAS number 10124-56-8. It is commonly a white powder or granules that dissolve easily in water. This is a compound made up of several phosphate groups that are connected together in a repeating pattern. Its molecular structure consists of a chain of six phosphate units. It is commonly mixed with organoclay as a dispersion agent. It prevents clay minerals to stick together.

Sodium Hexametaphosphate finds applications in various industrial processes, including paints and coatings production, and as a dispersing agent in oil well drilling. Its unique properties make it an indispensable ingredient in these industries. SHMP stands out as a compound with remarkable versatility and widespread usage.

History

Theodor Fleitmann, a German chemist, named hexametaphosphoric acid in 1849. It’s a type of polyphosphoric acid. Around 1956, researchers conducted additional studies and analyses on Graham’s salt, also referred to as sodium polyphosphate, during the mid-20th century. Graham’s salt is made up of several phosphate groups that are combined together. We found cyclic anions with more than four phosphate groups in the hydrolysates of Graham’s salt through chromatographic analysis.

This discovery gave us a better understanding of the makeup and arrangement of hexametaphosphoric acid. It is suggested that hexametaphosphoric acid is made up of cyclic anions that are formed by linking more than four phosphate groups. The unique properties and behavior of hexametaphosphoric acid are attributed to its cyclic structures.

What is the Preparation of Sodium Hexametaphosphate?

To make sodium hexametaphosphate, you need to heat up monosodium phosphate until it melts and forms a clear liquid. This transformation requires a temperature that is just a bit higher than 625°C. When synthesizing, the solid compound monosodium phosphate undergoes high temperatures.

When the temperature goes beyond 625°C, the monosodium phosphate changes from being solid to becoming molten. This melted form looks like a transparent liquid. Heating is very important to get the chemical change and make sodium hexametaphosphate.

 

Sodium Hexametaphosphate Structure

The molecular structure of Sodium Hexametaphosphate consists of a chain of phosphate units linked together. Each phosphate unit is composed of one phosphorus atom bonded to four oxygen atoms. The phosphate units are connected to each other through oxygen atoms, forming a linear chain.

The chemical formula for sodium hexametaphosphate of (NaPO3)n, where “n” is equal to 6, indicating that there are six phosphate units in the chain. The molecular structure of sodium hexametaphosphate can be visualized as a cyclic structure. It have an alternating phosphorus and oxygen atoms. The fourth oxygen atom forms a double bond with the phosphorus atom. The arrangement results in a negatively charged phosphate group within each unit.

The cyclic structure of Sodium Hexametaphosphate is formed by connecting the phosphate units end-to-end, with each phosphate unit sharing oxygen atoms with neighboring units. The sodium ions in Sodium Hexametaphosphate are attracted to the negatively charged phosphate groups, balancing the charge and providing stability to the compound.

 

Physical Properties of Sodium Hexametaphosphate

Sodium Hexametaphosphate appears as a white powder or particle. The sodium hexametaphosphate solubility in water is kept minimal, with a maximum value of 0.06%. The compound dissolves well in water.

It has a refractive index of 1.482. It usually appears transparent under the light because of this. The pH of sodium hexametaphosphate typically falls within the range of 5.8 to 7.3 which is considered optimal for many applications. Sodium hexametaphosphate powder is commonly odorless.

 

Chemical Properties of Sodium Hexametaphosphate

The amount of total phosphate content of sodium hexametaphosphate measured as P2O5 (phosphorus pentoxide), is at least 68.00%. It also contains non-active phosphate. The content of non-active phosphate is kept below or equal to 7.50%.

The presence of iron is limited. It has an iron content of no more than 0.005%. It has a density of 2.48grams per cubic meter. Its molecular we 611.77 grams per molecule, makes sodium hexametaphosphate dispersing agent perfect together with organoclay that is used in oil field drilling. Sodium hexametaphosphate also has a boiling point of 1500°C, and this characteristic also adds value in its use with organoclay. It has a melting point of 628°C.

 

Applications of Sodium Hexametaphosphate

Sodium Hexametaphosphate uses in paint and coating formulations for its sequestering, dispersing, and deflocculating properties. It helps to improve the stability of the paint by preventing the precipitation of pigments and fillers. It can act as a coating agent, forming a thin passivating film on metal surfaces, which provides protection against corrosion. It is widely employed in industrial water treatment processes as well. It acts as a powerful sequestering agent, effectively binding and inhibiting the formation of scale caused by metal ions such as calcium and magnesium.

It is used as an industrial cleaning agent to remove impurities and stains from textile materials and machinery. It can function as a dispersing agent in pigmenting and dyeing operations, ensuring even distribution and adherence of colorants onto fabrics.

Sodium Hexametaphosphate is also utilized in the oil and gas industry, particularly in oil well drilling operations. When mixed with organoclay or organophilic clays, it helps to prevent the clumping and aggregation of drilling mud components, aiding in the smooth flow of the mud and ensuring effective drilling performance.

 

How Does Sodium Hexametaphosphate Promote Dispersion of Clay Particle?

When Sodium Hexametaphosphate is added to the organoclay slurry, it interacts with the clay particles and modifies their surface properties. One of the key effects of SHMP is to increase the electronegativity of the clay particles. This increase in electronegativity creates a negative charge on the surface of the clay particles.

As a result, the negatively charged clay particles repel each other due to the mutual electrostatic repulsion. This repulsive force helps to overcome the attractive forces between the clay particles, which typically lead to their aggregation and poor dispersion.

The repulsive force generated by the electronegative clay particles promotes the dispersion of the clay particles throughout the slurry. It prevents them from clumping together and allows for a more uniform distribution within the medium.

The dispersion of clay particles is beneficial in various applications. For example, in drilling fluids, the effective dispersion of organoclay improves the rheological properties and suspension stability, leading to better performance in oil well drilling operations. In coatings and paints, the dispersion of clay particles enhances their overall performance and contributes to improved quality and stability.

Is Sodium Hexametaphosphate Covalent or Ionic?

Sodium hexametaphosphate is indeed an ionic compound. Ionic compounds are created when atoms transfer electrons. This leads to the creation of positively charged ions and negatively charged ions. When a sodium atom gives away one electron, it becomes positively charged and forms a sodium ion. This has a net positive charge, so it’s classified as a cation.

The hexametaphosphate ion is formed by a chain of six phosphate units linked together. Each phosphate unit carries a negative charge, resulting in a total charge of six negative charges for the hexametaphosphate ion. It is an anion because it has a net negative charge.

 

Is sodium hexametaphosphate a dispersing agent?

Yes, sodium hexametaphosphate can function as a dispersing agent in certain applications. When it is mixed into soil hydrometer solutions or used in the sedimentation process, SHMP helps prevent clay minerals from sticking together and forming clumps, such as bentonite organoclay.

The dispersing action of sodium hexametaphosphate occurs due to its ability to increase the electronegativity of the clay particles. This increase in electronegativity creates a repulsive force between the clay particles, preventing their agglomeration and facilitating their dispersion throughout the solution. By keeping the clay particles dispersed, SHMP helps maintain a more uniform suspension and prevents settling during sedimentation.

In the context of paints and coatings, sodium hexametaphosphate helps to disperse pigments and other solid particles uniformly throughout the liquid medium. It prevents the agglomeration or settling of particles, ensuring a stable and homogenous dispersion. It is also a dispersing agent aids in preventing flocculation or coagulation of particles during storage or application of the paint or coating to maintain the stability and shelf life of the formulation.

 

Sodium Hexametaphosphate | SHMP 68915-31-1

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