Industrial Chemicals

Product Details:

Aluminium chloride is an inorganic compound with the chemical formula AlCl3. It is a white, crystalline solid that is highly soluble in water. Aluminium chloride is a versatile chemical with various industrial applications due to its unique properties and reactivity.

The production of aluminium chloride typically involves the reaction of aluminium metal with hydrogen chloride gas. The resulting compound is a volatile solid that sublimes at high temperatures. Aluminium chloride can also be synthesized by treating aluminium hydroxide or aluminium oxide with hydrochloric acid.

One of the primary applications of aluminium chloride is as a catalyst in organic synthesis. It is widely used in the chemical industry for various reactions, including Friedel-Crafts acylation and alkylation reactions. Aluminium chloride acts as a Lewis acid, which can accept electron pairs from other molecules, facilitating chemical reactions and promoting the formation of new compounds. It is particularly useful in the production of fragrances, dyes, pharmaceuticals, and polymers.

In addition to its catalytic properties, aluminium chloride is used as an additive in the production of polymeric materials. It is employed as a polymerization initiator and a modifier in the synthesis of various polymers, including polyethene and polypropylene. Aluminium chloride can alter the molecular weight, structure, and properties of polymers, leading to desired characteristics such as increased strength, flexibility, and heat resistance.

Furthermore, aluminium chloride is utilized in the production of certain pharmaceuticals and drugs. It serves as a starting material or intermediate in the synthesis of various medications, including antiperspirants, antacids, antihistamines, and anti-cancer drugs. Aluminium chloride is also used in the formulation of vaccines and other medical products.

In conclusion, aluminium chloride is a versatile chemical with numerous industrial applications. Its role as a catalyst in organic synthesis, its usage in the petroleum industry, and its contributions to polymer production highlight its importance in various sectors.

Product Details:

Caustic soda prills, also known as sodium hydroxide prills or pellets, are solid, white, and spherical particles of sodium hydroxide. Sodium hydroxide is a strong alkaline compound with the chemical formula NaOH.

Caustic soda prills are produced through the process of crystallization, where a concentrated solution of sodium hydroxide is evaporated under controlled conditions. The resulting solid particles are then formed into prills or pellets for ease of handling, storage, and transport. The prills are uniform in size and have a smooth surface, allowing for efficient dissolution and reaction in various applications.

Caustic soda prills have a wide range of industrial applications due to their strong alkaline properties. One of the primary uses of caustic soda is in the production of chemicals and chemical intermediates. It is a key raw material in the manufacturing of detergents, soaps, and cleaning agents. Sodium hydroxide reacts with fatty acids to form soap molecules, enabling the removal of dirt, oils, and greases from surfaces.

In addition to the detergent industry, caustic soda prills are utilized in the production of various organic and inorganic chemicals. It is commonly employed in the synthesis of dyes, pigments, pharmaceuticals, and explosives. Sodium hydroxide acts as a catalyst or reagent in many chemical reactions, facilitating the formation of desired products.

The textile industry relies on caustic soda prills for various purposes. It is utilized in the mercerization process of cotton, where the fabric is treated with sodium hydroxide to improve its strength, lustre, and dye affinity. Caustic soda is also used in the dyeing and finishing of textiles, as well as in the synthesis of synthetic fibres such as rayon and nylon.

Protective equipment, such as gloves, goggles, and a lab coat, should be worn when working with this chemical. It is essential to avoid contact with the skin, eyes, and clothing and to use proper ventilation to prevent inhalation of caustic fumes. Storage should be in a cool, dry place, away from incompatible substances.

In conclusion, caustic soda prills are an important industrial chemical with a wide range of applications. Their strong alkaline properties make them valuable in the production of detergents, chemicals, pulp and paper, water treatment, and textiles

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• Packaging Details: 50 Kg Bag

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Caustic soda flakes, also known as sodium hydroxide flakes, are solid, white, and crystalline particles of sodium hydroxide. Sodium hydroxide is a strong alkaline compound with the chemical formula NaOH.

Caustic soda flakes are produced through the process of evaporation, where a concentrated solution of sodium hydroxide is heated under controlled conditions. The water content of the solution is gradually removed, resulting in the formation of solid flakes.

Caustic soda flakes are different from caustic soda pearls in terms of their physical appearance, but both are used for similar purposes. Caustic soda flakes are produced through the electrolysis of brine, which is a solution of sodium chloride in water.

The process involves passing an electric current through the brine, which causes the sodium and chloride ions to separate. The sodium ions then react with water to form sodium hydroxide, which is collected as flakes.

Caustic soda flakes have a wide range of industrial applications due to their strong alkaline properties. One of the primary uses of caustic soda is in the production of chemicals and chemical intermediates. It is a key raw material in the manufacturing of detergents, soaps, and cleaning agents.

It is commonly employed in the synthesis of dyes, pigments, pharmaceuticals, and explosives. Sodium hydroxide acts as a catalyst or reagent in many chemical reactions, facilitating the formation of desired products.

Additional Information:

• Packaging Details: 50 Kg Bag

Product Details:

Founded in 1966, Prakash Chemicals is a Global Market Leader in chemical distribution with a product portfolio of over 250 products and a highly diverse supplier base. Embracing a culture of innovation, we have delivered specialized solutions to more than 4,000 customers across various industries. Our commitment to safety and sustainability has helped us set new benchmarks for entrepreneurial integrity and futuristic thinking.

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Propylene glycol is a colourless, odourless, and viscous chemical compound with the chemical formula C3H8O2. The production of propylene glycol typically involves the hydrolysis of propylene oxide, which is derived from propylene, a petrochemical feedstock. The resulting propylene glycol is then purified and processed into a liquid form. Propylene glycol is highly soluble in water and has low volatility, making it easy to handle and incorporate into various applications.

Propylene glycol's solubility properties make it an effective vehicle for delivering drugs and active ingredients to the target site. Propylene glycol is widely used as a humectant in the food and beverage industry. It helps retain moisture and prevent the drying out of food products, maintaining their texture and freshness.

 

In the automotive industry, propylene glycol is used as an antifreeze agent in cooling systems. It helps prevent the freezing and boiling of engine coolant, ensuring optimal engine performance. Propylene glycol-based antifreeze solutions also offer corrosion protection to the cooling system components, extending their lifespan.

Another significant application of propylene glycol is in the production of polyester resins. It serves as a reactant and plasticizer in the polymerization process, contributing to the formation of strong and flexible polymers. Polyester resins find applications in various industries, including construction, automotive, and electronics, for manufacturing fibreglass-reinforced plastics, coatings, and adhesives.

Propylene glycol is utilized in the production of polyurethane foams and elastomers. It acts as a chain extender and cross-linking agent in the polymerization reaction, enhancing the physical properties of the resulting polyurethane materials. Polyurethane foams and elastomers are widely used in the construction, automotive, and furniture industries due to their insulation, cushioning, and structural properties.

Propylene glycol is also employed as a preservative in certain food products, cosmetics, and personal care items. It helps inhibit the growth of microorganisms, extending the shelf life of these products. Additionally, propylene glycol has applications in the e-cigarette industry, where it is used as a solvent and diluent in the formulation of e-liquids.

In conclusion, propylene glycol is a versatile chemical compound with diverse applications in various industries. Its roles as a solvent, humectant, antifreeze agent, reactant, and preservative highlight its importance in pharmaceuticals, cosmetics, food and beverages, automotive, and polymer industries. 

Product Details:

Aluminium chloride is an inorganic compound with the chemical formula AlCl3. It is a white, crystalline solid that is highly soluble in water. Aluminium chloride is a versatile chemical with various industrial applications due to its unique properties and reactivity.

The production of aluminium chloride typically involves the reaction of aluminium metal with hydrogen chloride gas. The resulting compound is a volatile solid that sublimes at high temperatures. Aluminium chloride can also be synthesized by treating aluminium hydroxide or aluminium oxide with hydrochloric acid.

One of the primary applications of aluminium chloride is as a catalyst in organic synthesis. It is widely used in the chemical industry for various reactions, including Friedel-Crafts acylation and alkylation reactions. Aluminium chloride acts as a Lewis acid, which can accept electron pairs from other molecules, facilitating chemical reactions and promoting the formation of new compounds. It is particularly useful in the production of fragrances, dyes, pharmaceuticals, and polymers.

In addition to its catalytic properties, aluminium chloride is used as an additive in the production of polymeric materials. It is employed as a polymerization initiator and a modifier in the synthesis of various polymers, including polyethene and polypropylene. Aluminium chloride can alter the molecular weight, structure, and properties of polymers, leading to desired characteristics such as increased strength, flexibility, and heat resistance.

Furthermore, aluminium chloride is utilized in the production of certain pharmaceuticals and drugs. It serves as a starting material or intermediate in the synthesis of various medications, including antiperspirants, antacids, antihistamines, and anti-cancer drugs. Aluminium chloride is also used in the formulation of vaccines and other medical products.

In conclusion, aluminium chloride is a versatile chemical with numerous industrial applications. Its role as a catalyst in organic synthesis, its usage in the petroleum industry, and its contributions to polymer production highlight its importance in various sectors.

Additional Information:

• Packaging Details: 50 Kg Bag

Product Details:

Imported Technical Grade Urea refers to a specific type of urea fertilizer that is sourced from international suppliers or manufacturers. Urea is a nitrogenous compound with the chemical formula CO(NH2)2 and is one of the most commonly used nitrogen fertilizers in agriculture.

One of the key uses of Imported Technical Grade Urea is in the production of urea-based fertilizers. It serves as a fundamental component in the formulation of various nitrogen fertilizers, such as granular urea, prilled urea, or blended fertilizers. These fertilizers provide crops with a readily available source of nitrogen, which is essential for their growth, development, and overall productivity.

Imported Technical Grade Urea can also be utilized in the manufacturing of other urea-based products. For example, it serves as a precursor for the production of urea-formaldehyde resins, which are widely used in the production of adhesives, laminates, and moulded products. Urea-formaldehyde resins offer excellent bonding properties, high strength, and resistance to moisture and heat.

In addition, Imported Technical Grade Urea finds applications in various industrial processes. It can be used in the synthesis of certain plastics, fibres, and pharmaceutical compounds. Urea is also employed in the production of animal feed supplements, where it provides a concentrated source of nitrogen for livestock and helps promote healthy growth.

In summary, Imported Technical Grade Urea serves as a versatile base material for the production of urea-based fertilizers and value-added urea products. Its applications extend beyond agriculture to various industrial sectors, including adhesives, plastics, and pharmaceuticals.

Additional Information:

• Production Capacity: 50000 Kg
• Delivery Time: 2 days
• Packaging Details: 50 kg bag

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Benzyl alcohol is an organic compound with the chemical formula C₆H₅CH₂OH. It is a clear, colourless liquid with a mild, pleasant aroma. Benzyl alcohol finds applications in various industries, including pharmaceuticals, cosmetics, and personal care products, as well as as a solvent and a precursor in chemical synthesis.

The structure of benzyl alcohol consists of a benzene ring attached to a hydroxyl group (-OH) via a methylene (CH₂) bridge. This structure gives benzyl alcohol both aromatic and alcohol characteristics. It can be derived from the hydrolysis of benzyl chloride or by the reduction of benzaldehyde.

Benzyl alcohol is primarily known for its versatile applications as a solvent. It has excellent solubility in both polar and nonpolar solvents, making it useful for dissolving and diluting various substances. Benzyl alcohol is commonly employed in the formulation of inks, paints, coatings, and lacquers. It serves as a medium for dispersing pigments, resins, and other additives, aiding in their application and ensuring proper film formation.

In the pharmaceutical industry, benzyl alcohol plays a crucial role as a preservative and a solvent. It is used in injectable formulations to prevent the growth of microorganisms and maintain the stability of medications. Benzyl alcohol acts as a bacteriostatic agent, inhibiting the growth of bacteria, fungi, and yeast. It is commonly found in multi-dose vials, topical creams, and ointments.

In addition to its solvent and fragrance properties, benzyl alcohol has antimicrobial activity. It can be employed as an active ingredient in topical antiseptic solutions and disinfectants. Benzyl alcohol acts by disrupting the cell membranes of microorganisms, leading to their destruction or inhibition of growth. Its broad-spectrum antimicrobial activity makes it effective against bacteria, fungi, and some viruses.

Benzyl alcohol also finds applications in the field of chemistry and chemical synthesis. It serves as a versatile reagent and a precursor for the synthesis of various compounds. Benzyl alcohol can undergo numerous chemical transformations, including oxidation, esterification, and ether formation. These reactions allow for the introduction of functional groups and the synthesis of complex molecules.

Product Details:

Technical grade urea is a chemical compound with the formula CO(NH2)2. It is a solid, crystalline substance that is widely used in various industries for its unique properties and applications. Technical grade urea is primarily distinguished from agricultural or fertilizer-grade urea by its purity and specific manufacturing standards.

The production of technical-grade urea involves the synthesis of urea from ammonia and carbon dioxide in a high-pressure and high-temperature process known as the Haber-Bosch process. This results in the formation of pure urea crystals, which are then further processed to meet the required specifications for technical applications.

One of the main applications of technical grade urea is as a raw material in the production of resins, plastics, and adhesives. Urea-formaldehyde resins, for example, are widely used in the manufacturing of plywood, particleboards, laminates, and moulded products. These resins offer excellent bonding properties, high strength, and water resistance, making them suitable for various industrial and construction applications.

Technical grade urea is also utilized in the production of melamine, which is an important component in the manufacturing of laminates, coatings, and flame-retardant materials. Melamine-formaldehyde resins are known for their high heat resistance, hardness, and durability. They find applications in the automotive, electrical, and construction industries.

Another significant application of technical grade urea is in the production of nitrogen-based fertilizers. Urea fertilizer is widely used in agriculture for its high nitrogen content, which is essential for plant growth and development. It provides a readily available source of nitrogen that can be easily absorbed by plants. Urea is often combined with other nutrients and micronutrients to create balanced fertilizer formulations suitable for various crops and soil conditions.

In addition to its applications in resins, plastics, adhesives, and fertilizers, technical-grade urea finds use in the pharmaceutical industry. It serves as a starting material or intermediate in the synthesis of certain pharmaceutical compounds. Urea has also been used in dermatological treatments for its moisturizing and exfoliating properties.

In conclusion, technical grade urea is a versatile chemical compound with a wide range of applications in various industries. Its role in the production of resins, plastics, adhesives, fertilizers, and livestock feed supplements highlights its importance in manufacturing and agriculture.

Product Details:

Caustic soda lye is produced through the electrolysis of salt solutions, such as brine. The electrolysis process involves passing an electric current through a brine solution, leading to the decomposition of sodium chloride (NaCl) into sodium hydroxide, chlorine gas (Cl2), and hydrogen gas (H2). The resulting sodium hydroxide solution is then further purified and concentrated to obtain caustic soda lye.

One of the primary applications of caustic soda lye is in the chemical industry. It serves as a strong base and is utilized in various chemical reactions. Caustic soda lye is commonly used in the production of detergents, soaps, and cleaning agents. It helps in the saponification process, where fats and oils are converted into soap. It is also used in the manufacturing of various chemicals, including dyes, pigments, pharmaceuticals, and polymers.

Furthermore, caustic soda lye is utilized in the textile industry. It is used in the mercerization process of cotton, which improves its strength, lustre, and dye absorption properties. Caustic soda lye also finds applications in the production of synthetic fibres such as rayon and nylon.

Caustic soda lye plays a crucial role in water treatment processes. It is used as a pH adjuster and neutralizer to control acidity and alkalinity in water. Additionally, it is employed in the treatment of wastewater and effluents to remove impurities and neutralize acidic or alkaline substances.

In the metallurgical industry, caustic soda lye is used for various purposes. It is involved in the extraction of alumina from bauxite ore in the production of aluminium. Caustic soda lye helps dissolve alumina, allowing it to be separated from other impurities. It is also used in the refining of metals, such as the removal of unwanted impurities from steel and aluminium alloys.

Caustic soda lye has applications in the food industry as well. It is used in food processing for various purposes, including pH adjustment, neutralization, and as a cleaning agent. Caustic soda lye is employed in the production of certain food additives, such as caramel colour and cocoa processing.

In conclusion, caustic soda lye is a versatile chemical compound with numerous industrial applications. Its role as a strong base, pH adjuster, and neutralizer makes it valuable in the chemical, pulp and paper, textile, water treatment, metallurgical, and food industries. 

Product Details:

Acesulfame K, also known as acesulfame potassium, is a high-intensity artificial sweetener that is widely used as a sugar substitute in food and beverage products. It is a white, crystalline powder with a sweet taste but without the calories associated with sugar consumption. A

One of the primary reasons for the popularity of acesulfame K as a sweetener is its intense sweetness. It is approximately 200 times sweeter than sucrose (table sugar), allowing for a significant reduction in the amount of sweetener needed to achieve the desired sweetness level in food and beverages. This property makes it a cost-effective option for manufacturers looking to reduce sugar content in their products while maintaining a sweet taste.

Acesulfame K is stable under high temperatures, making it suitable for use in a wide range of food and beverage applications. It can withstand baking, cooking, and pasteurization processes without losing its sweetness or breaking down into harmful substances.

Another advantage of acesulfame K is its compatibility with other sweeteners. It can be used in combination with other artificial sweeteners, such as aspartame or sucralose, to create sugar-free or low-calorie products that closely mimic the taste of sugar. By blending sweeteners, manufacturers can achieve a more balanced flavour profile and improve the overall sensory experience of their products.

Acesulfame K is not metabolized by the body and has no caloric value, making it an attractive option for individuals looking to reduce calorie intake or manage conditions like diabetes. It does not contribute to tooth decay, as it is not fermented by oral bacteria like sugar. As a result, it can be used in oral care products, including toothpaste and mouthwash, to provide a sweet taste without promoting dental cavities.

The safety of acesulfame K has been extensively evaluated by regulatory authorities worldwide, including the U.S. Food and Drug Administration (FDA) and the European Food Safety Authority (EFSA). Based on the available scientific data, acesulfame K is considered safe for consumption at the approved levels. However, it is important to note that some individuals may have sensitivities or allergies to acesulfame K, and excessive consumption should be avoided.

In conclusion, acesulfame K is a high-intensity artificial sweetener used as a sugar substitute in various food and beverage products. Its intense sweetness, stability under high temperatures, and compatibility with other sweeteners make it a popular choice for manufacturers. It provides a sweet taste without the calories of sugar and is considered safe for consumption when used within regulatory limits.

Additional Information:

• Production Capacity: 5000000 Kg

Product Details:

Founded in 1966, Prakash Chemicals is a Global Market Leader in chemical distribution with a product portfolio of over 250 products and a highly diverse supplier base. Embracing a culture of innovation, we have delivered specialized solutions to more than 4,000 customers across various industries. Our commitment to safety and sustainability has helped us set new benchmarks for entrepreneurial integrity and futuristic thinking.

Product Details:

Monosodium Glutamate (MSG) is a flavour enhancer and food additive that is widely used in the food industry. It is the sodium salt of glutamic acid, a naturally occurring amino acid that is found in various foods. MSG is known for its ability to enhance the savoury taste, known as umami, in foods. MSG is a white crystalline powder that is highly soluble in water.

The primary function of MSG is to enhance the natural flavours of food. It does not have a distinct taste of its own but rather acts as a flavour amplifier, making the existing flavours in food more pronounced and satisfying. The umami taste that MSG enhances is often described as a savoury, meaty, or brothy flavour that adds depth and richness to dishes.

MSG is commonly used in savoury foods such as soups, sauces, snacks, processed meats, and ready-to-eat meals. It is also found in certain condiments, seasonings, and salad dressings. Its widespread use is attributed to its ability to improve taste and increase the overall palatability of foods.

In summary, Monosodium Glutamate (MSG) is a flavour enhancer used in the food industry to amplify the umami taste and improve the overall palatability of savoury foods.

Product Details:

Technical grade urea is a chemical compound with the formula CO(NH2)2. It is a solid, crystalline substance that is widely used in various industries for its unique properties and applications. Technical grade urea is primarily distinguished from agricultural or fertilizer-grade urea by its purity and specific manufacturing standards.

The production of technical-grade urea involves the synthesis of urea from ammonia and carbon dioxide in a high-pressure and high-temperature process known as the Haber-Bosch process. This results in the formation of pure urea crystals, which are then further processed to meet the required specifications for technical applications.

One of the main applications of technical grade urea is as a raw material in the production of resins, plastics, and adhesives. Urea-formaldehyde resins, for example, are widely used in the manufacturing of plywood, particleboards, laminates, and moulded products. These resins offer excellent bonding properties, high strength, and water resistance, making them suitable for various industrial and construction applications.

Technical grade urea is also utilized in the production of melamine, which is an important component in the manufacturing of laminates, coatings, and flame-retardant materials. Melamine-formaldehyde resins are known for their high heat resistance, hardness, and durability. They find applications in the automotive, electrical, and construction industries.

Another significant application of technical grade urea is in the production of nitrogen-based fertilizers. Urea fertilizer is widely used in agriculture for its high nitrogen content, which is essential for plant growth and development. It provides a readily available source of nitrogen that can be easily absorbed by plants. Urea is often combined with other nutrients and micronutrients to create balanced fertilizer formulations suitable for various crops and soil conditions.

In addition to its applications in resins, plastics, adhesives, and fertilizers, technical-grade urea finds use in the pharmaceutical industry. It serves as a starting material or intermediate in the synthesis of certain pharmaceutical compounds. Urea has also been used in dermatological treatments for its moisturizing and exfoliating properties.

In conclusion, technical grade urea is a versatile chemical compound with a wide range of applications in various industries. Its role in the production of resins, plastics, adhesives, fertilizers, and livestock feed supplements highlights its importance in manufacturing and agriculture.

Product Details:

Technical grade urea is a chemical compound with the formula CO(NH2)2. It is a solid, crystalline substance that is widely used in various industries for its unique properties and applications. Technical grade urea is primarily distinguished from agricultural or fertilizer-grade urea by its purity and specific manufacturing standards.

The production of technical-grade urea involves the synthesis of urea from ammonia and carbon dioxide in a high-pressure and high-temperature process known as the Haber-Bosch process. This results in the formation of pure urea crystals, which are then further processed to meet the required specifications for technical applications.

One of the main applications of technical grade urea is as a raw material in the production of resins, plastics, and adhesives. Urea-formaldehyde resins, for example, are widely used in the manufacturing of plywood, particleboards, laminates, and moulded products. These resins offer excellent bonding properties, high strength, and water resistance, making them suitable for various industrial and construction applications.

Technical grade urea is also utilized in the production of melamine, which is an important component in the manufacturing of laminates, coatings, and flame-retardant materials. Melamine-formaldehyde resins are known for their high heat resistance, hardness, and durability. They find applications in the automotive, electrical, and construction industries.

Another significant application of technical grade urea is in the production of nitrogen-based fertilizers. Urea fertilizer is widely used in agriculture for its high nitrogen content, which is essential for plant growth and development. It provides a readily available source of nitrogen that can be easily absorbed by plants. Urea is often combined with other nutrients and micronutrients to create balanced fertilizer formulations suitable for various crops and soil conditions.

In addition to its applications in resins, plastics, adhesives, and fertilizers, technical-grade urea finds use in the pharmaceutical industry. It serves as a starting material or intermediate in the synthesis of certain pharmaceutical compounds. Urea has also been used in dermatological treatments for its moisturizing and exfoliating properties.

In conclusion, technical grade urea is a versatile chemical compound with a wide range of applications in various industries. Its role in the production of resins, plastics, adhesives, fertilizers, and livestock feed supplements highlights its importance in manufacturing and agriculture.

Product Details:

Xanthan Gum Powder is a versatile food additive and thickening agent that is widely used in the food, pharmaceutical, and cosmetic industries. It is a high-molecular-weight polysaccharide produced by the fermentation of carbohydrates with the bacterium Xanthomonas campestris.

Xanthan Gum Powder has excellent thickening and stabilizing properties, making it valuable in a wide range of applications. In the food industry, it is commonly used as a thickener, emulsifier, and stabilizer in various products. Xanthan Gum Powder can enhance the texture, consistency, and mouthfeel of food and beverage formulations.

One of the primary applications of Xanthan Gum Powder is in the production of sauces, dressings, and gravies. It provides a smooth and uniform texture, prevents ingredient separation, and improves the overall stability of the product. Xanthan Gum Powder is also used in dairy products, bakery items, and gluten-free formulations to improve texture and provide a desirable mouthfeel.

In the pharmaceutical industry, Xanthan Gum Powder is used as a suspending agent in liquid medications. It helps to maintain the uniform distribution of active ingredients and prevents sedimentation. Xanthan Gum Powder also serves as a binder in tablet formulations, improving the tablet's integrity and disintegration properties.

Cosmetic and personal care products also benefit from the properties of Xanthan Gum Powder. It is used as a thickener and stabilizer in lotions, creams, and gels. Xanthan Gum Powder helps to create a smooth and consistent product texture and improves the spreadability and shelf life of cosmetic formulations.

Furthermore, Xanthan Gum Powder is utilized in various industrial applications. It is employed as a drilling fluid additive in the oil and gas industry, providing viscosity and suspension properties. Xanthan Gum Powder is also used in the textile industry as a thickener for printing and dyeing processes.

One of the notable advantages of Xanthan Gum Powder is its ability to provide stability and viscosity over a wide range of pH levels and temperatures. It is resistant to enzymatic degradation and can withstand both acidic and alkaline conditions, making it suitable for a variety of applications.

When using Xanthan Gum Powder, it is important to disperse it in water or another liquid before adding it to the formulation to prevent clumping. It is recommended to use a low-shear mixing process to achieve proper hydration and dispersion.

In summary, Xanthan Gum Powder is a versatile food additive and thickening agent with a wide range of applications. It is used as a thickener, emulsifier, and stabilizer in food, pharmaceutical, and cosmetic products. Xanthan Gum Powder provides texture, consistency, and stability to various formulations. It is also employed in industrial applications. 

Product Details:

Potassium carbonate powder is a white, odourless, and crystalline substance with the chemical formula K2CO3. The production of potassium carbonate typically involves the reaction of potassium hydroxide with carbon dioxide gas. The resulting solution is then evaporated to yield potassium carbonate crystals, which are subsequently ground into a fine powder form.

Potassium carbonate powder possesses several important properties that make it valuable in industrial applications. Firstly, it is a strong alkaline compound, similar to caustic soda, with a high pH value. It readily reacts with acids, forming salts and water, making it useful as a neutralizing agent or pH adjuster in various chemical reactions and processes.

One of the primary applications of potassium carbonate powder is in the production of glass. It is a key ingredient in the glass manufacturing process, serving as a flux agent that reduces the melting temperature of the glass batch. Potassium carbonate also improves the chemical durability and optical properties of the glass, making it suitable for applications such as flat glass, bottles, and optical lenses.

Potassium carbonate is widely used in the production of various chemicals and chemical intermediates. It serves as a precursor for the synthesis of potassium salts, including potassium bicarbonate, potassium permanganate, and potassium phosphate. These compounds find applications in agriculture, pharmaceuticals, food additives, and water treatment.

In the agricultural sector, potassium carbonate powder is utilized as a fertilizer. Potassium is an essential nutrient for plant growth and is required for various physiological processes. Adding potassium carbonate to the soil helps replenish potassium levels and promotes healthy plant development, improving crop yield and quality

Potassium carbonate is also used in the manufacturing of soaps and detergents. It acts as a water softener, preventing the formation of soap scum and enhancing the cleaning efficiency of these products. Additionally, it contributes to the stabilization and thickening of certain liquid detergent formulations.

 

Another significant application of potassium carbonate powder is in the production of fire extinguishing powders. It is a key ingredient in dry chemical fire extinguishers, where it functions as an effective fire suppressant by inhibiting the chemical reactions involved in the combustion process. Potassium carbonate-based fire extinguishers are commonly used in industrial settings and for specific types of fires, such as those involving flammable liquids.

Potassium carbonate powder is also employed in the food industry as a food additive. It is utilized as a buffering agent, pH regulator, and leavening agent in various food and beverage products. Additionally, it contributes to the preservation and flavour enhancement of certain food items.

In conclusion, its alkaline properties, solubility, and reactivity make it valuable in the production of glass, chemicals, fertilizers, soaps, fire extinguishers, and food additives. 

Additional Information:

• Packaging Details: 25 Kg Bag

Product Details:

Aspartame Sweetener Powder is a low-calorie artificial sweetener that is widely used as a sugar substitute in various food and beverage products. It is a white, crystalline powder that is highly sweet, approximately 200 times sweeter than sugar. Aspartame is made up of two amino acids, phenylalanine and aspartic acid, which are found naturally in many foods.

One of the primary benefits of Aspartame Sweetener Powder is its ability to provide sweetness without adding significant calories. It is commonly used in diet sodas, sugar-free beverages, and low-calorie food products to offer a sweet taste while reducing the overall calorie content. Aspartame can be part of a balanced diet for individuals looking to manage their calorie intake or reduce their sugar consumption.

Aspartame Sweetener Powder is heat-stable, making it suitable for use in both hot and cold beverages, as well as in cooking and baking. Unlike some other sweeteners, it retains its sweetness even at high temperatures, allowing for its incorporation into a wide range of recipes and food applications.

It is worth mentioning that aspartame's sweetness may diminish over time, especially when exposed to prolonged storage or high temperatures. Therefore, it is recommended to store products containing aspartame in cool, dry conditions and adhere to the expiration dates provided.

While aspartame is a widely used and accepted artificial sweetener, some individuals may have concerns or experience sensitivities or adverse reactions. In such cases, it is advisable to consult with a healthcare professional or consider alternative sweeteners.

In summary, Aspartame Sweetener Powder is a low-calorie artificial sweetener that provides sweetness without adding significant calories. It is widely used in a variety of food and beverage products as a sugar substitute. Aspartame is heat-stable, tooth-friendly, and approved for consumption by regulatory authorities.

Product Details:

Methylene Chloride, also known as dichloromethane (DCM), is a versatile and widely used organic solvent with various industrial applications. It is a colourless liquid with a sweet odour, and its chemical formula is CH2Cl2.

One of the significant applications of Methylene Chloride is as a solvent in various industries. It has excellent solvency power and is commonly used for paint stripping, degreasing metal surfaces, and cleaning electronic components. Methylene Chloride is also utilized in the production of adhesives, pharmaceuticals, and pesticides.

In the paint and coating industry, Methylene Chloride is employed as a paint remover or stripper. It effectively dissolves and removes paint from different surfaces, including wood, metal, and plastics. Its low boiling point and high volatility make it an efficient solvent for this application.

Methylene Chloride is also used in the pharmaceutical industry. It is a valuable solvent for the extraction of active compounds from natural products and the purification of pharmaceutical intermediates. It is widely used in the production of medications, such as cough syrups and over-the-counter topical formulations.

Another important application of Methylene Chloride is in the production of polyurethane foams. It is used as a blowing agent, which helps expand and create the cellular structure of the foam. Methylene Chloride provides efficient and controlled foaming properties in the manufacturing of insulation materials and flexible foams.

In addition to its solvent properties, Methylene Chloride is utilized as a propellant in aerosol products. It allows for the efficient dispersion of products, such as paints, cleaners, and personal care items. The low boiling point and vapour pressure of Methylene Chloride make it suitable for this application.

In summary, Methylene Chloride is a versatile organic solvent with various industrial applications. It is used as a solvent in paint stripping, metal degreasing, and electronic cleaning. It finds applications in pharmaceuticals, polyurethane foam production, and aerosol propellants.

Product Details:

Sodium benzoate is a common food preservative and additive that is widely used in the food and beverage industry. It is the sodium salt of benzoic acid and is known for its ability to inhibit the growth of bacteria, yeast, and mould. Sodium benzoate helps to extend the shelf life of various products and maintain their quality and safety.

One of the primary functions of sodium benzoate is its antimicrobial property. It effectively inhibits the growth of microorganisms by disrupting their metabolic processes. This property makes it a valuable ingredient in a wide range of food and beverage products, including fruit juices, carbonated drinks, pickles, sauces, jams, and dressings. By preventing the growth of spoilage-causing microorganisms, sodium benzoate helps to preserve the freshness and quality of these products.

Sodium benzoate is also used as a pH adjuster and flavour enhancer in certain food and beverage formulations. It can act as a buffering agent, helping to stabilize acidity and maintain the desired pH levels in acidic foods and drinks. Additionally, sodium benzoate can enhance the taste and flavour of certain products by suppressing off-flavours and odours that may develop during storage.

While sodium benzoate is considered safe for consumption, there have been concerns about its potential interaction with certain ingredients, particularly when combined with ascorbic acid (vitamin C). When exposed to heat or acidic conditions, sodium benzoate can form benzene, a compound that is a known carcinogen. However, the formation of benzene is dependent on several factors, including temperature, pH, and the presence of other substances. The use of sodium benzoate in combination with ascorbic acid is regulated to minimize the risk of benzene formation.

In summary, sodium benzoate is a widely used food preservative that helps inhibit the growth of microorganisms and extend the shelf life of various food and beverage products. It serves as an effective antimicrobial agent, pH adjuster, and flavour enhancer.

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Maleic anhydride is a white crystalline powder with a distinct pungent odour. It is an organic compound and is classified as an unsaturated dicarboxylic acid anhydride. With the chemical formula C4H2O3, maleic anhydride is derived from maleic acid and is widely used in various industrial applications.

The production of maleic anhydride typically involves the catalytic oxidation of benzene or butane. The process involves the use of metal oxide catalysts such as vanadium pentoxide or molybdenum trioxide. Maleic anhydride is obtained as a volatile vapour that is subsequently condensed and solidified into a powdered form.

One of the primary applications of maleic anhydride powder is in the production of unsaturated polyester resins. These resins are widely used in the manufacture of fibreglass-reinforced plastics, coatings, adhesives, and composite materials. Maleic anhydride reacts with polyols to form polyester chains, providing the resins with excellent mechanical strength, chemical resistance, and heat stability.

Maleic anhydride is also used as a raw material in the production of other important chemicals. It serves as a precursor for the synthesis of 1,4-butanediol, which is utilized in the production of polyurethanes, plastics, and solvents. Additionally, maleic anhydride can be converted to maleic acid, fumaric acid, and other derivatives that find applications in the pharmaceutical, agricultural, and food industries.

The reactivity of maleic anhydride extends beyond the field of polymer chemistry. It is commonly employed as a chemical intermediate in the synthesis of various speciality chemicals, including lubricant additives, agricultural chemicals, surfactants, and dyes. Its ability to undergo addition reactions with nucleophiles allows for the introduction of functional groups, enabling the customization of chemical structures to suit specific applications.

In conclusion, maleic anhydride powder is a versatile and reactive compound with diverse applications in the chemical industry. Its ability to form polyester resins, serve as a precursor for other chemicals, and participate in various chemical reactions makes it an essential component in the production of a wide range of products. Despite its reactivity, with proper handling and safety precautions, maleic anhydride contributes significantly to the advancement of numerous industrial processes. 

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Dicyandiamide (DCD) powder is a white crystalline substance with the chemical formula C2H4N4. It is also known by other names such as cyanoguanidine or DCD powder. The production of dicyandiamide powder typically involves the reaction of cyanamide with ammonia. The resulting solution is then evaporated, leading to the formation of solid dicyandiamide crystals.

Firstly, it is a versatile compound that can undergo various chemical reactions, making it a valuable building block for the synthesis of numerous organic compounds. It serves as a precursor for the production of melamine, guanamines, resins, and other speciality chemicals.

One of the primary applications of dicyandiamide powder is as a curing agent in the epoxy resin industry. It acts as a hardener for epoxy resins, providing excellent mechanical strength, adhesion, and chemical resistance to the cured product. Dicyandiamide-based epoxy systems are widely used in coatings, adhesives, composite materials, and electrical insulation applications.

Dicyandiamide powder is also utilized as a slow-release nitrogen fertilizer in the agricultural sector. It breaks down gradually in the soil, releasing nitrogen over an extended period. This controlled release of nitrogen ensures a sustained nutrient supply to plants, reducing the risk of nutrient leaching and optimizing crop growth and yield. Dicyandiamide is particularly beneficial for crops with high nitrogen requirements, such as corn, wheat, and rice.

Another significant application of dicyandiamide is in the production of guanidine derivatives. These derivatives find applications in the pharmaceutical and chemical industries. They are used as intermediates in the synthesis of pharmaceutical drugs, pesticides, and organic compounds with diverse functionalities.

Dicyandiamide powder is employed in the textile industry as a textile auxiliary agent. It acts as a dye-fixing agent, improving the colour fastness of dyed fabrics. Dicyandiamide forms complexes with reactive dyes, enhancing their affinity for fibres and reducing dye bleeding during washing or exposure to light.

In conclusion, dicyandiamide powder is a versatile organic compound with diverse industrial applications. Its utilization as a curing agent in the epoxy resin industry, slow-release nitrogen fertilizer in agriculture, and as a textile auxiliary agent showcases its versatility.

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Dimethylformamide (DMF) is an organic compound with the chemical formula (CH₃)₂NC(O)H. It is a colourless, polar liquid with a faint, amine-like odour. The structure of dimethylformamide consists of a formamide group (-C(O)NH₂) attached to two methyls (CH₃) groups. DMF is classified as a polar aprotic solvent due to its ability to dissolve both polar and nonpolar substances.

One of the primary applications of DMF is as a solvent in the pharmaceutical industry. It is widely used for the synthesis and purification of active pharmaceutical ingredients (APIs) and drug intermediates. DMF's exceptional solvency properties allow for the dissolution of a wide range of organic and inorganic compounds, facilitating various reactions and processes. Additionally, DMF is utilized as a carrier solvent for drug delivery systems and as a solubilizer in liquid formulations.

In the field of polymer chemistry, DMF plays a crucial role as a solvent and a reaction medium. It is commonly employed in the synthesis and processing of various polymers, including polyurethanes, polyamides, and polyacrylonitrile. DMF's high solvency power and ability to dissolve both polar and nonpolar polymers make it an excellent choice for polymerization, polymer modification, and polymer blending processes.

Moreover, DMF is utilized as a spinning solvent in the production of synthetic fibres. It is particularly suitable for the wet spinning of fibres such as acrylic, aramid, and polyurethane. DMF's high boiling point and low surface tension facilitate the fibre formation process, resulting in fibres with desirable properties such as high strength, durability, and chemical resistance.

Furthermore, DMF is employed as a reagent in various organic transformations and chemical reactions. It can act as a reactant, a catalyst, or a complexing agent in a wide range of synthetic procedures. DMF is particularly useful in amidation reactions, N-alkylation, and as a source of formyl groups in the synthesis of aldehydes. Its versatile reactivity and compatibility with many functional groups make it a valuable tool in organic synthesis.

In conclusion, dimethylformamide (DMF) is a versatile chemical with widespread applications in pharmaceuticals, polymers, and electronics. Its solvency power, reactivity, and compatibility with various compounds make it valuable in synthesis, purification, and processing applications. However, proper handling and adherence to safety regulations are necessary to ensure the safe use of DMF.

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The sorbic acid powder is a white, crystalline substance with the chemical formula C6H8O2. It is a naturally occurring organic compound and is widely used as a food preservative due to its antimicrobial properties. Sorbic acid is a member of the unsaturated fatty acid family and is found naturally in various fruits, such as berries.

The production of sorbic acid powder usually involves the condensation of crotonaldehyde and ketene. The resulting compound is then converted into sorbic acid through a series of chemical reactions. The final product is obtained as a fine powder, which is easily soluble in water and other solvents.

One of the significant advantages of sorbic acid as a food preservative is its ability to inhibit the growth of spoilage-causing microorganisms while being relatively safe for human consumption. It has a low toxicity profile and is considered a generally recognized safe (GRAS) substance by regulatory authorities. Sorbic acid is commonly used in the preservation of various food products, including baked goods, dairy products, beverages, processed meats, and condiments.

In addition to its antimicrobial properties, sorbic acid also acts as an antioxidant, helping to prevent the oxidation of fats and oils in food products. By inhibiting the formation of free radicals, sorbic acid helps maintain the sensory attributes and nutritional quality of food items.

Furthermore, sorbic acid has applications in the pharmaceutical industry. It is used as a preservative in certain pharmaceutical formulations to prevent microbial contamination. Sorbic acid helps maintain the efficacy and stability of pharmaceutical products, ensuring their safety and effectiveness throughout their shelf life.

In conclusion, sorbic acid powder is a widely used food preservative with antimicrobial and antioxidant properties. Its effectiveness against microorganisms and its relatively low toxicity makes it a popular choice in the food and beverage industry.

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• Packaging Details: 25 Kg Bag

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Acrylamide powder is a white, odourless, and crystalline substance with the chemical formula C3H5NO. It is an organic compound that is widely used in various industrial applications. Acrylamide is a versatile chemical that can undergo polymerization to form polyacrylamide, a polymer with numerous uses.

The production of acrylamide powder typically involves the reaction between acrylonitrile and water in the presence of a catalyst. The resulting acrylamide monomer is then purified and processed into a fine powder form. Acrylamide powder is soluble in water, making it easy to incorporate into various processes and applications.

One of the primary applications of acrylamide powder is in the production of polyacrylamide (PAM). Polyacrylamide is a water-soluble polymer that possesses a wide range of properties depending on its molecular weight and structure. It is extensively used as a flocculant, coagulant, and rheology modifier in various industries.

Acrylamide-based polyacrylamide is commonly used in wastewater treatment plants to remove suspended solids and contaminants from water. It acts as a flocculant, facilitating the aggregation of fine particles into larger, settleable flocs, which can be easily separated from the water. Polyacrylamide also finds applications in the mining industry, where it is used to clarify and dewater mineral slurries.

In the oil and gas industry, acrylamide powder is used in enhanced oil recovery (EOR) processes. Polyacrylamide is injected into oil reservoirs to increase the viscosity of the injected water, improving its sweep efficiency and enabling the recovery of more oil. Acrylamide-based polymers also find applications in drilling fluids, where they enhance the stability and lubricity of the fluid, reducing friction and improving drilling operations.

Another significant application of acrylamide is in the production of polyacrylamide gels for gel electrophoresis. Gel electrophoresis is a widely used technique in molecular biology and biochemistry for separating and analyzing proteins, DNA, and other biomolecules based on their size and charge. Acrylamide powder is polymerized to form a gel matrix that provides the necessary separation medium for electrophoretic analysis.

In conclusion, acrylamide powder is a versatile chemical with various industrial applications. Its polymerization into polyacrylamide provides a wide range of functionalities, including water treatment, oil and gas recovery, paper manufacturing, and gel electrophoresis.

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Monosodium phosphate, also known as sodium dihydrogen phosphate or monobasic sodium phosphate, is a chemical compound with the formula NaH2PO4. It is an inorganic salt that consists of sodium cations (Na+) and dihydrogen phosphate anions (H2PO4-).

In terms of its physical characteristics, monosodium phosphate typically appears as a white, crystalline powder or granules. It is highly soluble in water, which makes it convenient to use in aqueous solutions and as a buffering agent. The compound has a molecular weight of approximately 119.98 g/mol.

Monosodium phosphate finds extensive use in the food industry as a food additive. It serves as an acidity regulator, pH control agent, and emulsifier. It is commonly added to processed foods, beverages, and dairy products to enhance flavour, improve texture, and extend shelf life.

In the field of pharmaceuticals, monosodium phosphate is used as a pH adjuster and a buffering agent in the formulation of various medications. It helps maintain the optimal pH range for drug stability and efficacy. Moreover, it is utilized in the preparation of intravenous (IV) solutions to regulate pH levels and prevent pH-related complications during administration.

Monosodium phosphate also finds applications in the water treatment industry. It is employed as a corrosion inhibitor and a scale remover in water systems. Its ability to sequester calcium and magnesium ions helps prevent the formation of scale deposits and reduces the risk of equipment damage and clogging. Furthermore, it is used in detergents and cleaning agents for its ability to soften water and enhance cleaning efficiency.

In addition to its industrial uses, monosodium phosphate has agricultural applications. It is utilized as a fertilizer and a nutrient source for plants. The phosphate ions released from monosodium phosphate contribute to the growth and development of crops, especially during the early stages. It is particularly beneficial in soils with low phosphate levels, helping improve crop yields.

Monosodium Phosphate is also employed in laboratory settings. It serves as a buffer in various biochemical and molecular biology experiments. Its pH-regulating properties make it valuable for maintaining a stable environment for enzymatic reactions, DNA amplification, and protein assays.

In summary, monosodium phosphate is a versatile compound used in the food industry as an additive, in pharmaceuticals as a pH adjuster, in water treatment as a corrosion inhibitor, in agriculture as a fertilizer, and in laboratories as a buffer. Its properties and applications make it a valuable chemical in numerous industries, contributing to the development of a wide range of products and processes.

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Monosodium hydrogen phosphate, also known as sodium dihydrogen phosphate or monobasic sodium phosphate, is an inorganic compound with the chemical formula NaH2PO4. It is a white, crystalline powder that is highly soluble in water. Monosodium hydrogen phosphate has various applications in industries such as food, agriculture, and pharmaceuticals.

One of the primary uses of monosodium hydrogen phosphate is as a food additive. It serves as a pH regulator, buffering agent, and emulsifier in a wide range of food and beverage products. It helps maintain the pH stability of processed foods and enhances their texture and shelf life. Monosodium hydrogen phosphate is commonly found in dairy products, processed meats, bakery goods, and beverages.

In the agricultural sector, monosodium hydrogen phosphate is used as a source of phosphorus and as a fertilizer. Phosphorus is an essential nutrient for plant growth and development, and monosodium hydrogen phosphate provides an easily absorbable form of phosphorus to crops. It is particularly useful in areas where the soil is deficient in phosphorus, helping to improve crop yield and quality.

Monosodium hydrogen phosphate also finds applications in the pharmaceutical industry. It is used as a buffering agent in various medications to maintain the optimal pH for stability and effectiveness. Additionally, it can act as a disintegrant in tablet formulations, helping to facilitate the breakdown and dissolution of tablets in the digestive system.

Furthermore, monosodium hydrogen phosphate is utilized in laboratory settings as a reagent in chemical reactions. It can serve as a source of phosphorus in the synthesis of organic compounds, including pharmaceutical intermediates, flame retardants, and surfactants. Monosodium hydrogen phosphate also finds use in analytical chemistry as a pH buffer in laboratory experiments and assays.

In summary, monosodium hydrogen phosphate is a versatile compound with diverse applications in the food, agricultural, pharmaceutical, and chemical industries. Its roles as a pH regulator, fertilizer, buffer, and reagent make it valuable in various products and processes.

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GACL Phosphoric Acid is a chemical compound with the formula H3PO4. It is a colourless and odourless liquid that is widely used in various industries for its diverse applications. Phosphoric Acid is a strong acid and is commonly used in the production of fertilizers, food and beverages, detergents, and other chemical processes.

One of the major applications of GACL Phosphoric Acid is in the agricultural industry for the production of fertilizers. Phosphoric Acid is an essential component in the manufacturing of phosphate-based fertilizers, which are widely used to provide necessary nutrients to plants. These fertilizers help promote healthy growth and improve crop yields.

In the food and beverage industry, GACL Phosphoric Acid plays a crucial role as an acidulant and pH regulator. It is commonly used in the production of carbonated beverages, where it helps provide tartness and effervescence. Phosphoric Acid is also utilized in the manufacturing of jams, jellies, and other food products to enhance flavour, act as a preservative, and adjust pH levels.

Phosphoric Acid is an important ingredient in the production of detergents and cleaning agents. It is used as a pH adjuster and chelating agent, helping to remove mineral deposits and improve the cleaning efficiency of various products. Phosphoric Acid is also utilized in water treatment processes to control pH levels and prevent the formation of scale and corrosion.

In addition to its applications in agriculture, food and beverages, and cleaning products, GACL Phosphoric Acid is used in various chemical processes. It is employed as a catalyst in certain chemical reactions and as a raw material for the production of phosphates, phosphorous compounds, and flame retardants. Phosphoric Acid also finds applications in the pharmaceutical industry, where it is used in the synthesis of certain drugs and medications.

In summary, GACL Phosphoric Acid is a versatile chemical compound with a wide range of applications. It is used in agriculture for fertilizer production, in the food and beverage industry as an acidulant, in detergents and cleaning agents, and in various chemical processes. 

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Founded in 1966, Prakash Chemicals is a Global Market Leader in chemical distribution with a product portfolio of over 250 products and a highly diverse supplier base. Embracing a culture of innovation, we have delivered specialized solutions to more than 4,000 customers across various industries. Our commitment to safety and sustainability has helped us set new benchmarks for entrepreneurial integrity and futuristic thinking.

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Tert-Butylhydroquinone (TBHQ) is a synthetic organic compound with the chemical formula C10H14O2. It is a white, crystalline powder that is commonly used as a food preservative and antioxidant. TBHQ is derived from hydroquinone and is widely recognized for its ability to extend the shelf life of various food products.

One of the primary functions of TBHQ is its role as an antioxidant. It effectively inhibits the oxidation of fats and oils, which helps to prevent rancidity and prolong the freshness of food products. By scavenging free radicals and interfering with the oxidation process, TBHQ helps maintain the quality and stability of fats and oils, particularly in products such as snacks, baked goods, and fried foods.

TBHQ is commonly used in the food industry to prevent the spoilage of products that contain fats or oils. It is often added to processed foods, including cereals, crackers, chips, margarine, and cooking oils. By inhibiting the development of off-flavours and off-odours caused by lipid oxidation, TBHQ helps to preserve the sensory attributes of food and enhance its shelf life.

Another important characteristic of TBHQ is its ability to protect against colour changes in food. It helps prevent the discolouration of fruits, vegetables, and processed products caused by enzymatic or oxidative reactions. By maintaining the natural colour of food items, TBHQ enhances their visual appeal and consumer acceptance.

In addition to its application as a food preservative, TBHQ is also used in other industries. It can be found in cosmetics, pharmaceuticals, and various industrial products where its antioxidant properties are beneficial.

In summary, Tert-Butylhydroquinone (TBHQ) is a food preservative and antioxidant widely used in the food industry. It helps to prevent lipid oxidation, maintain the freshness and quality of food products, and protect against colour changes. TBHQ is commonly added to a variety of processed foods that contain fats or oils.

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Glacial acetic acid, also known as concentrated acetic acid, is a clear, colourless liquid with a strong pungent odour. It is an organic compound with the chemical formula CH3COOH. Glacial acetic acid gets its name from its ability to solidify or "glaciate" at low temperatures, forming ice-like crystals.

Glacial acetic acid is produced through the oxidation of acetaldehyde or by the reaction of methanol with carbon monoxide. The resulting liquid is then purified and concentrated to obtain glacial acetic acid. It is highly corrosive and requires careful handling and storage.

One of the primary applications of glacial acetic acid is in the chemical industry. It is a versatile chemical that serves as an essential building block in the synthesis of numerous organic compounds. Glacial acetic acid is used as a solvent and reagent in various reactions, including esterification, acetylation, and condensation reactions. It is particularly important in the production of vinyl acetate, which is a precursor to polyvinyl acetate and other vinyl-based polymers.

In the food industry, glacial acetic acid is used as a food additive and preservative. It serves as a flavouring agent and contributes to the characteristic tangy taste in various food products. Glacial acetic acid is a component of vinegar, which is commonly used in cooking, pickling, and salad dressings. It also acts as a preservative, inhibiting the growth of bacteria and extending the shelf life of certain food items.

Another significant application of glacial acetic acid is in the production of pharmaceuticals and chemicals. It is used in the synthesis of acetate esters, which are widely employed as solvents, plasticizers, and flavouring agents. Glacial acetic acid is also a component in the formulation of various medications, including analgesics, antipyretics, and antibiotics. It helps in the production of drugs such as aspirin, acetaminophen, and acetylsalicylic acid.

In addition, glacial acetic acid has applications in the rubber and plastics industry. It is used as a co-monomer in the production of vinyl acetate-ethylene (VAE) copolymers, which are utilized in adhesives, paints, and coatings. Glacial acetic acid also acts as a cross-linking agent in the vulcanization of rubber, enhancing its strength and durability.

In conclusion, glacial acetic acid is a versatile chemical with diverse applications in various industries. Its role as a solvent, reagent, and preservative makes it indispensable in the chemical, textile, food, pharmaceutical, and rubber industries.

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Anhydrous aluminium chloride is an inorganic compound with the chemical formula AlCl3. It is a white, crystalline solid that is highly soluble in organic solvents. Anhydrous aluminium chloride is primarily distinguished from its hydrated counterpart by its low moisture content, making it suitable for specific applications where water content needs to be minimized.

The production of anhydrous aluminium chloride involves the removal of water from hydrated aluminium chloride. This can be achieved through processes such as heating or drying under controlled conditions. The resulting product is a dry and anhydrous form of aluminium chloride with significantly lower moisture content.

 

One of the primary applications of anhydrous aluminium chloride is as a catalyst in various chemical reactions. It acts as a Lewis acid, capable of accepting electron pairs from other molecules, thereby facilitating chemical transformations. Anhydrous aluminium chloride is widely used in the chemical industry for reactions such as Friedel-Crafts acylation and alkylation, which are essential in the synthesis of fragrances, dyes, pharmaceuticals, and polymers.

Anhydrous aluminium chloride also finds applications in the petroleum and petrochemical industries. It is used as a catalyst in the production of gasoline and other hydrocarbon fuels through processes like cracking and isomerization. Anhydrous aluminium chloride helps increase the efficiency and selectivity of these reactions, resulting in improved fuel quality and higher yields.

 

In addition to its catalytic properties, anhydrous aluminium chloride is utilized in the production of speciality materials and compounds. It is used as a precursor in the synthesis of aluminium-based pigments, such as aluminium flake or aluminium powder, which find applications in paints, coatings, and printing inks. Anhydrous aluminium chloride is also employed in the production of high-performance polymers, such as polyolefins and polyesters, where it acts as a catalyst during polymerization processes.

Anhydrous aluminium chloride is a vital component in the electrolytic production of aluminium metal. It is used in the Hall-Héroult process, which involves the electrolysis of alumina (aluminium oxide) to extract pure aluminium. Anhydrous aluminium chloride is employed as a flux to lower the melting point of the alumina, thereby reducing energy requirements during the smelting process.

In conclusion, anhydrous aluminium chloride is a versatile chemical compound with various industrial applications. Its role as a catalyst in chemical reactions, its contributions to the petroleum and petrochemical industries, and its usage in the production of speciality materials and aluminium extraction highlight its significance.

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Chlorinated paraffin wax (CPW) is a group of synthetic compounds that are produced by the chlorination of paraffin wax, which is derived from petroleum. CPW is characterized by its high chlorine content, typically ranging from 30% to 70%, depending on the grade. It is available in various forms, such as liquid, solid, or powder, and it finds applications in a wide range of industries due to its unique properties.

One of the primary uses of chlorinated paraffin wax is as a flame retardant. The high chlorine content in CPW imparts excellent flame-retardant properties to materials. It is added to polymers, plastics, and rubber products to enhance their fire resistance and reduce the risk of ignition and spread of flames. CPW acts by releasing chlorine radicals when exposed to heat, which inhibits the combustion process and suppresses the formation of flammable gases.

CPW is also utilized as a plasticizer in the production of flexible PVC (polyvinyl chloride) products. It improves the flexibility, durability, and processing characteristics of PVC by reducing its rigidity and enhancing its flow properties. CPW acts as a lubricant and dispersing agent, facilitating the blending and dispersion of PVC resin with other additives during the manufacturing process. Additionally, CPW imparts resistance to chemicals, heat, and weathering to PVC products, making them suitable for a wide range of applications, including wires and cables, vinyl flooring, and automotive components.

Furthermore, chlorinated paraffin wax is employed as an additive in metalworking fluids and lubricants. It acts as an extreme pressure additive, providing lubrication and reducing friction between metal surfaces during machining operations. CPW forms a thin film on the metal surfaces, preventing direct contact and reducing wear and tear. It also improves the cooling properties of metalworking fluids, helping to dissipate heat generated during cutting and machining processes.

CPW finds applications in the textile industry as a fabric treatment agent. It is used as a sizing agent and lubricant in textile processing to improve the weaving and handling characteristics of fibres and yarns. CPW enhances the smoothness, stiffness, and resistance to abrasion of fabrics, making them suitable for various applications, including home textiles, apparel, and industrial fabrics.

Additionally, CPW is utilized in the formulation of paints, coatings, and sealants. It acts as a plasticizer and binder, enhancing the adhesion, flexibility, and durability of these products. CPW improves the water and chemical resistance of coatings and sealants, making them suitable for outdoor and harsh environments. It also helps in the dispersion of pigments and fillers, contributing to the overall performance and appearance of the finished coatings.

In conclusion, chlorinated paraffin wax (CPW) is a versatile compound with flame-retardant properties and serves as a plasticizer, lubricant, additive, and fabric treatment agent in various industries. Its unique characteristics make it valuable in the production of flame-retardant materials, flexible PVC products, metalworking fluids, textiles, paints, coatings, and sealants.

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Sodium nitrite powder is a chemical compound with the molecular formula NaNO2. It is a crystalline, odourless, and white to slightly yellow powder that is highly soluble in water.

One of the primary uses of sodium nitrite is as a food preservative. It is commonly added to processed meats, such as bacon, ham, sausages, and hot dogs, to inhibit the growth of bacteria, particularly Clostridium botulinum, which can cause botulism.

Sodium nitrite also finds application in the manufacturing of dyes and pigments. It is used as a precursor in the synthesis of various organic compounds and colourants. Sodium nitrite can react with aromatic compounds to form azo dyes, which are widely used in the textile, printing, and dyeing industries. These dyes provide vibrant and long-lasting colours to fabrics, plastics, and other materials.

Moreover, sodium nitrite is utilized in water treatment processes. It is an effective corrosion inhibitor that helps prevent the degradation of metal pipes and equipment in water distribution systems. Sodium nitrite forms a protective film on metal surfaces, reducing the risk of corrosion and extending the lifespan of infrastructure. It is particularly used in closed-loop cooling systems and conjunction with other chemicals for effective corrosion control.

Sodium nitrite is also employed in the production of pharmaceuticals and medical applications. It can be used as a precursor in the synthesis of various drugs, such as nitric oxide donors, which have vasodilatory properties and find use in the treatment of cardiovascular conditions. Additionally, sodium nitrite is utilized in certain medical procedures, such as the treatment of cyanide poisoning. It acts as an antidote by reacting with cyanide to form less toxic compounds.

In the chemical industry, sodium nitrite serves as a versatile reagent. It participates in various chemical reactions, including oxidation and reduction processes. Sodium nitrite can be used as an oxidizing agent, facilitating the conversion of certain compounds into their corresponding oxides or nitro compounds. It can also act as a reducing agent, donating electrons to other substances in redox reactions. These properties make sodium nitrite valuable in organic synthesis and the production of speciality chemicals.

In conclusion, sodium nitrite powder is a versatile chemical compound with applications in food preservation, dye production, water treatment, pharmaceuticals, and the chemical industry. Its antimicrobial properties make it valuable in preserving processed meats, while its reactivity makes it useful in various chemical reactions.

Additional Information:

• Production Capacity: 5000000 Kg

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Chlorinated paraffin wax (CPW) is a group of synthetic compounds that are produced by the chlorination of paraffin wax, which is derived from petroleum. CPW is characterized by its high chlorine content, typically ranging from 30% to 70%, depending on the grade. It is available in various forms, such as liquid, solid, or powder, and it finds applications in a wide range of industries due to its unique properties.

One of the primary uses of chlorinated paraffin wax is as a flame retardant. The high chlorine content in CPW imparts excellent flame-retardant properties to materials. It is added to polymers, plastics, and rubber products to enhance their fire resistance and reduce the risk of ignition and spread of flames. CPW acts by releasing chlorine radicals when exposed to heat, which inhibits the combustion process and suppresses the formation of flammable gases.

CPW is also utilized as a plasticizer in the production of flexible PVC (polyvinyl chloride) products. It improves the flexibility, durability, and processing characteristics of PVC by reducing its rigidity and enhancing its flow properties. CPW acts as a lubricant and dispersing agent, facilitating the blending and dispersion of PVC resin with other additives during the manufacturing process. Additionally, CPW imparts resistance to chemicals, heat, and weathering to PVC products, making them suitable for a wide range of applications, including wires and cables, vinyl flooring, and automotive components.

Furthermore, chlorinated paraffin wax is employed as an additive in metalworking fluids and lubricants. It acts as an extreme pressure additive, providing lubrication and reducing friction between metal surfaces during machining operations. CPW forms a thin film on the metal surfaces, preventing direct contact and reducing wear and tear. It also improves the cooling properties of metalworking fluids, helping to dissipate heat generated during cutting and machining processes.

CPW finds applications in the textile industry as a fabric treatment agent. It is used as a sizing agent and lubricant in textile processing to improve the weaving and handling characteristics of fibres and yarns. CPW enhances the smoothness, stiffness, and resistance to abrasion of fabrics, making them suitable for various applications, including home textiles, apparel, and industrial fabrics.

Additionally, CPW is utilized in the formulation of paints, coatings, and sealants. It acts as a plasticizer and binder, enhancing the adhesion, flexibility, and durability of these products. CPW improves the water and chemical resistance of coatings and sealants, making them suitable for outdoor and harsh environments. It also helps in the dispersion of pigments and fillers, contributing to the overall performance and appearance of the finished coatings.

In conclusion, chlorinated paraffin wax (CPW) is a versatile compound with flame-retardant properties and serves as a plasticizer, lubricant, additive, and fabric treatment agent in various industries. Its unique characteristics make it valuable in the production of flame-retardant materials, flexible PVC products, metalworking fluids, textiles, paints, coatings, and sealants.

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Benzyl chloride, also known as alpha-chlorotoluene, is an organic compound with the chemical formula C6H5CH2Cl. It is a colourless to pale yellow liquid with a strong, pungent odour.

One of the primary uses of benzyl chloride is as an intermediate in the synthesis of pharmaceutical compounds. It serves as a key starting material in the production of drugs, such as antihistamines, antibiotics, antiseptics, and cardiovascular medications. Benzyl chloride is often used in the pharmaceutical industry to introduce the benzyl group into organic molecules, enhancing their pharmacological properties.

In the chemical industry, benzyl chloride is utilized as a versatile building block for the synthesis of numerous compounds. It is commonly employed in the production of benzyl alcohol, benzyl cyanide, benzylamine, and benzyl acetate, among others. These derivatives of benzyl chloride have applications as solvents, flavouring agents, fragrance ingredients, and chemical intermediates.

Benzyl chloride is also utilized as a reagent in organic chemistry reactions. It undergoes various chemical transformations, such as nucleophilic substitution and addition reactions, to form a wide range of products. These reactions enable the synthesis of diverse compounds with different functional groups, making benzyl chloride a valuable tool for organic chemists.

In the agricultural sector, benzyl chloride is used in the production of crop protection agents. It is an essential ingredient in the synthesis of herbicides, fungicides, and insecticides. These agricultural chemicals help protect crops from weeds, fungal infections, and pest infestations, contributing to improved crop yield and quality.

In summary, benzyl chloride is a versatile compound with applications in the pharmaceutical, chemical, and agricultural industries. Its role as an intermediate in drug synthesis, a building block for various compounds, and a reagent in organic chemistry reactions makes it a valuable tool for researchers and manufacturers.

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Founded in 1966, Prakash Chemicals is a Global Market Leader in chemical distribution with a product portfolio of over 250 products and a highly diverse supplier base. Embracing a culture of innovation, we have delivered specialized solutions to more than 4,000 customers across various industries. Our commitment to safety and sustainability has helped us set new benchmarks for entrepreneurial integrity and futuristic thinking.

Product Details:

Chlorinated paraffin wax (CPW) is a group of synthetic compounds that are produced by the chlorination of paraffin wax, which is derived from petroleum. CPW is characterized by its high chlorine content, typically ranging from 30% to 70%, depending on the grade. It is available in various forms, such as liquid, solid, or powder, and it finds applications in a wide range of industries due to its unique properties.

One of the primary uses of chlorinated paraffin wax is as a flame retardant. The high chlorine content in CPW imparts excellent flame-retardant properties to materials. It is added to polymers, plastics, and rubber products to enhance their fire resistance and reduce the risk of ignition and spread of flames. CPW acts by releasing chlorine radicals when exposed to heat, which inhibits the combustion process and suppresses the formation of flammable gases.

CPW is also utilized as a plasticizer in the production of flexible PVC (polyvinyl chloride) products. It improves the flexibility, durability, and processing characteristics of PVC by reducing its rigidity and enhancing its flow properties. CPW acts as a lubricant and dispersing agent, facilitating the blending and dispersion of PVC resin with other additives during the manufacturing process. Additionally, CPW imparts resistance to chemicals, heat, and weathering to PVC products, making them suitable for a wide range of applications, including wires and cables, vinyl flooring, and automotive components.

Furthermore, chlorinated paraffin wax is employed as an additive in metalworking fluids and lubricants. It acts as an extreme pressure additive, providing lubrication and reducing friction between metal surfaces during machining operations. CPW forms a thin film on the metal surfaces, preventing direct contact and reducing wear and tear. It also improves the cooling properties of metalworking fluids, helping to dissipate heat generated during cutting and machining processes.

CPW finds applications in the textile industry as a fabric treatment agent. It is used as a sizing agent and lubricant in textile processing to improve the weaving and handling characteristics of fibres and yarns. CPW enhances the smoothness, stiffness, and resistance to abrasion of fabrics, making them suitable for various applications, including home textiles, apparel, and industrial fabrics.

Additionally, CPW is utilized in the formulation of paints, coatings, and sealants. It acts as a plasticizer and binder, enhancing the adhesion, flexibility, and durability of these products. CPW improves the water and chemical resistance of coatings and sealants, making them suitable for outdoor and harsh environments. It also helps in the dispersion of pigments and fillers, contributing to the overall performance and appearance of the finished coatings.

In conclusion, chlorinated paraffin wax (CPW) is a versatile compound with flame-retardant properties and serves as a plasticizer, lubricant, additive, and fabric treatment agent in various industries. Its unique characteristics make it valuable in the production of flame-retardant materials, flexible PVC products, metalworking fluids, textiles, paints, coatings, and sealants.

Product Details:

The sorbic acid powder is a white, crystalline substance with the chemical formula C6H8O2. It is a naturally occurring organic compound and is widely used as a food preservative due to its antimicrobial properties. Sorbic acid is a member of the unsaturated fatty acid family and is found naturally in various fruits, such as berries.

The production of sorbic acid powder usually involves the condensation of crotonaldehyde and ketene. The resulting compound is then converted into sorbic acid through a series of chemical reactions. The final product is obtained as a fine powder, which is easily soluble in water and other solvents.

One of the significant advantages of sorbic acid as a food preservative is its ability to inhibit the growth of spoilage-causing microorganisms while being relatively safe for human consumption. It has a low toxicity profile and is considered a generally recognized safe (GRAS) substance by regulatory authorities. Sorbic acid is commonly used in the preservation of various food products, including baked goods, dairy products, beverages, processed meats, and condiments.

In addition to its antimicrobial properties, sorbic acid also acts as an antioxidant, helping to prevent the oxidation of fats and oils in food products. By inhibiting the formation of free radicals, sorbic acid helps maintain the sensory attributes and nutritional quality of food items.

Furthermore, sorbic acid has applications in the pharmaceutical industry. It is used as a preservative in certain pharmaceutical formulations to prevent microbial contamination. Sorbic acid helps maintain the efficacy and stability of pharmaceutical products, ensuring their safety and effectiveness throughout their shelf life.

In conclusion, sorbic acid powder is a widely used food preservative with antimicrobial and antioxidant properties. Its effectiveness against microorganisms and its relatively low toxicity makes it a popular choice in the food and beverage industry.

Product Details:

Potassium permanganate, a potent and versatile chemical compound, is a remarkable creation of Star Oxavhem, a renowned chemical manufacturer and innovator. This compound, with the chemical formula KMnO4, exhibits a striking deep purple hue, instantly distinguishing it from other chemicals. The production of potassium permanganate involves the skillful combination of potassium hydroxide and manganese dioxide, a process that Star Oxavhem has mastered to perfection.

One of the most remarkable attributes of potassium permanganate lies in its powerful oxidizing properties. When dissolved in water, it readily releases manganese ions, which trigger a cascade of oxidation reactions. This capability makes it an invaluable agent in various fields, ranging from medicine to water treatment and even pyrotechnics.

In the medical domain, potassium permanganate has found its way into wound care and dermatology. Its antiseptic properties make it effective in disinfecting wounds, preventing infections, and promoting healing. Additionally, it has been used to treat various skin conditions like eczema, dermatitis, and fungal infections, providing relief to countless individuals.

The water treatment industry has greatly benefited from the contributions of potassium permanganate. Its potent oxidizing nature enables it to remove impurities, organic matter, and harmful microorganisms from water sources. Star Oxavhem's potassium permanganate has played a pivotal role in transforming contaminated water into a safe and potable resource, benefiting communities and safeguarding public health.

Furthermore, potassium permanganate has proven to be indispensable in laboratory settings. Chemists and researchers harness its oxidizing abilities to conduct experiments, synthesize compounds, and analyze complex mixtures. Its distinct color change during reduction reactions aids in detecting the endpoint of certain chemical reactions, ensuring accuracy and reproducibility in scientific studies.

In agriculture, potassium permanganate finds application in both plant protection and soil remediation. It can help control fungal and bacterial infections in crops, enhancing yields and overall agricultural productivity. Additionally, it can be used to neutralize certain soil contaminants, reducing environmental pollution and promoting sustainable land management practices.

The versatility of Star Oxavhem's potassium permanganate is further demonstrated in the realm of pyrotechnics. Its ability to release oxygen upon decomposition fuels vibrant and mesmerizing fireworks displays, captivating audiences and adding an element of magic to celebratory events.

However, it is important to note that while potassium permanganate offers numerous benefits, it demands careful handling and responsible usage. Its strong oxidizing potential can be hazardous if mishandled, causing skin and eye irritation. Proper safety measures, such as the use of protective equipment and adherence to handling guidelines, are essential when working with this chemical.

Star Oxavhem, with its unwavering commitment to quality and safety, ensures that its potassium permanganate adheres to the highest industry standards. Rigorous quality control measures are implemented throughout the manufacturing process, guaranteeing a product that is both effective and safe for its intended applications.