Applications: Drying

Spray Drying of Magnesium phosphate

Spray drying is a process used to transform a liquid into a dry powder form. Magnesium phosphate is a naturally occurring mineral that has many applications in the food and pharmaceutical industries. Spray drying of magnesium phosphate has been studied as a means of producing a fine powder with unique properties.

The process of spray drying involves atomizing a solution of magnesium phosphate into a stream of hot gas, which evaporates the solvent and leaves behind a fine powder. The resulting magnesium phosphate powder has a controlled particle size distribution, good flowability, and high reactivity.

Spray drying of magnesium phosphate has been used in a variety of applications, including the production of dietary supplements, pharmaceuticals, and food additives. The process can be used to modify the properties of magnesium phosphate, such as improving its bioavailability and solubility.

In summary, spray drying of magnesium phosphate is a promising technology that has the potential to improve the performance and versatility of this widely used mineral. Its applications extend to many different areas of the food and pharmaceutical industries, including the production of dietary supplements, pharmaceuticals, and food additives.

Please see the application note No. 566 for starting parameters, formulations and some results.

Spray Drying of Orange juice concentrate

Spray drying is a popular technique used in the food industry to convert liquid or paste foods into powder form. Orange juice concentrate is one of the products that can be obtained by spray drying. The process involves the removal of water from the orange juice concentrate through the use of hot air, resulting in a powdered product that can be easily stored and transported. The powder can be reconstituted with water to create a juice drink.

Spray drying of orange juice concentrate offers several advantages, such as prolonged shelf life, improved storage stability, reduced transportation costs, and easy handling. The powdered product is also used in the production of other orange-flavored products such as soft drinks, baked goods, and confectionery.

The process of spray drying orange juice concentrate can have a significant impact on the quality of the final product. The drying conditions and equipment used can affect the flavor, color, and texture of the powder. Therefore, optimizing the process parameters is crucial to produce high-quality orange juice concentrate powder.

Please see the application note No. 594 for starting parameters and some results.

Spray Drying of Phospholipides

Spray drying has been used as a method for producing powdered phospholipids. Phospholipids are a class of lipids that are essential components of cell membranes in all living organisms. They have numerous industrial applications such as emulsifiers, stabilizers, and encapsulating agents in the food, pharmaceutical, and cosmetic industries.

Spray drying of phospholipids has been used to produce powders with improved stability, increased solubility, and controlled release properties. The process involves atomizing a solution or suspension of phospholipids into a stream of hot gas, which evaporates the solvent and forms dry particles that are collected in a cyclone or filter.

In the food industry, spray-dried phospholipids have been used as emulsifiers in dairy products, bakery items, and infant formula. In the pharmaceutical industry, they are used as excipients in drug delivery systems and for the encapsulation of bioactive compounds. In the cosmetic industry, they are used in the production of lotions and creams, as they provide moisturizing properties and improve the skin barrier function.

Please see the application note No. 608 for starting parameters and some results.

Spray Drying of Phenolic resin TE 40-42

Phenolic resins are synthetic polymers that are widely used in the production of adhesives, coatings, and molded products due to their excellent mechanical, electrical, and thermal properties. The spray drying process can be used to produce phenolic resin powders with a narrow particle size distribution and controlled morphology, which can improve their processability and performance in various applications.

The spray drying of phenolic resin TE 40-42 involves the atomization of a phenolic resin solution or dispersion into a hot drying gas, typically nitrogen, in a spray dryer. The hot gas evaporates the solvent and heats the droplets, leading to the formation of solid particles that are collected at the bottom of the spray dryer.

The resulting phenolic resin powders can be used in a range of applications such as friction materials, laminates, coatings, and composites. The spray-dried phenolic resin powders offer advantages such as increased reactivity, improved dispersion, and better processability compared to other forms of the resin. Additionally, they can improve the durability, strength, and resistance of final products, making them suitable for use in harsh environments.

Please see the application note No. 607 for starting parameters and some results.

Spray Drying of Potassium hydrogencitrate

Potassium hydrogencitrate (KHC6H5O7) is a potassium salt of citric acid used for various pharmaceutical and food applications. Spray drying has been used as an effective technique for producing powdered forms of KHC6H5O7.

Spray drying of KHC6H5O7 allows for the production of powders with controlled particle size and morphology, which can be tailored to specific applications. The resulting powders have improved solubility, making them suitable for various processing and manufacturing applications.

Applications of KHC6H5O7 powders produced by spray drying include the development of pharmaceutical formulations such as effervescent tablets and oral solutions. In the food industry, the powders are used as a food additive, particularly in beverages, to provide a sour taste.

Overall, spray drying of KHC6H5O7 offers numerous benefits and has a wide range of potential applications in various industries, including pharmaceuticals and food production. Its versatility and adaptability make it a valuable tool for the development of new and innovative products.

Please see the application note No. 626 for starting parameters and some results.

Spray Drying of Poly-hydroxyl-ethylmetacrylat

Poly-hydroxyl-ethylmetacrylate (PHEMA) is a hydrogel polymer that is commonly used in biomedical applications such as tissue engineering, drug delivery, and wound healing. Spray drying has been used to produce PHEMA particles in various forms, such as microspheres and microparticles, with controlled size, shape, and porosity.

The spray drying process involves atomizing a PHEMA solution or suspension into a hot gas stream, which rapidly evaporates the solvent, leaving behind a dry powder or particles containing PHEMA. The size, shape, and properties of the particles can be controlled by adjusting the spray drying conditions, such as the feed rate, drying temperature, and gas flow rate.

Applications of spray-dried PHEMA particles include drug delivery, wound healing, and tissue engineering. The PHEMA particles can be functionalized with various bioactive molecules, such as growth factors or enzymes, to enhance their properties and performance.

Overall, spray drying of PHEMA particles offers numerous benefits and has a wide range of potential applications in the biomedical field. Its versatility and adaptability make it a valuable tool for the development of new and innovative materials with improved properties and performance.

Please see the application note No. 621 for starting parameters and some results.

Spray Drying of Paclitaxel

Spray drying is a process used to transform a liquid into a dry powder form. Paclitaxel is a potent chemotherapeutic drug used to treat a variety of cancers, including breast, lung, and ovarian cancer. Spray drying of paclitaxel has been extensively studied in recent years as a means of improving the drug's solubility and bioavailability.

The process of spray drying involves atomizing a solution of paclitaxel into a stream of hot gas, which evaporates the solvent and leaves behind a fine powder. The resulting paclitaxel powder is highly dispersible and can be easily reconstituted into a solution for intravenous administration.

Spray drying of paclitaxel has been used in a variety of applications, including the production of dry powder inhalers for lung cancer treatment, the formulation of oral solid dosage forms, and the creation of targeted drug delivery systems. The process has also been used to improve the stability of paclitaxel and to reduce the drug's toxicity.

In summary, spray drying of paclitaxel is a promising technology that has the potential to improve the efficacy and safety of this important chemotherapeutic agent, and its applications extend to many different areas of cancer treatment.

Please see the application note No. 599 for starting parameters, formulations and some results.

Nano-precipited calcium carbonate (NPCC)

Sample concentration: 8.5 %Solvent: Water

Spray Drying of Morphine

Spray drying is a process used to transform a liquid into a dry powder form. Morphine is a potent analgesic drug used to manage severe pain. Spray drying of morphine has been studied as a means of improving the drug's solubility, bioavailability, and stability.

The process of spray drying involves atomizing a solution of morphine into a stream of hot gas, which evaporates the solvent and leaves behind a fine powder. The resulting morphine powder is highly dispersible and can be easily formulated into various dosage forms such as tablets or capsules.

Spray drying of morphine has been used in a variety of applications, including the production of sustained-release formulations, fast-dissolving tablets, and oral transmucosal systems. The process has also been used to improve the stability of morphine and to reduce the drug's gastrointestinal side effects.

In summary, spray drying of morphine is a promising technology that has the potential to improve the efficacy, safety, and convenience of this potent analgesic drug. Its applications extend to many different areas of drug delivery, including sustained-release formulations and fast-dissolving dosage forms.

Please see the application note No. 583 for starting parameters, formulations and some results.

Spray Drying of Oil in Gelatin Microparticles

Spray drying is a common technique used to produce oil-encapsulated particles. Oil in gelatin microparticles can be produced using this technique. The process involves the formation of an emulsion containing oil, a gelatin solution, and a surfactant. The emulsion is then spray-dried, resulting in small, dry particles that can be used in a variety of applications. The use of gelatin as a matrix for encapsulation allows for the release of the oil in a controlled manner, making it a desirable ingredient in food and cosmetic products.

Oil in gelatin microparticles have numerous applications in the food, cosmetic, and pharmaceutical industries. They can be used as a source of nutrients or flavor in food products, as well as in the formulation of cosmetic products such as lotions and creams. Additionally, they can be used in the pharmaceutical industry as drug delivery systems, allowing for the controlled release of drugs in the body. The spray-drying process can be customized to achieve specific particle sizes and oil loadings, allowing for the production of particles with tailored properties to meet the needs of different applications.

Please see the application note No. 590 for starting parameters and some results.

Spray Drying of Nylon 6 (polyamide)

Spray drying is a process used to transform a liquid into a dry powder form. Nylon 6 (polyamide) is a widely used polymer with applications in many different industries, including textiles, automotive, and packaging. Spray drying of nylon 6 has been studied as a means of producing fine powders with unique properties.

The process of spray drying involves atomizing a solution of nylon 6 into a stream of hot gas, which evaporates the solvent and leaves behind a fine powder. The resulting nylon 6 powder has a controlled particle size distribution, high surface area, and unique morphology.

Spray drying of nylon 6 has been used in a variety of applications, including the production of high-performance fibers, films, and coatings. The process can be used to modify the properties of nylon 6, such as increasing its thermal stability, improving its processability, and enhancing its mechanical properties.

In summary, spray drying of nylon 6 is a promising technology that has the potential to improve the performance and versatility of this widely used polymer. Its applications extend to many different areas of industry, including textiles, automotive, and packaging.

Please see the application note No. 589 for starting parameters, formulations and some results.

Spray Drying of Orange flavour

Spray drying is a common technique used in the food industry to produce powders from liquid concentrates. Orange flavour is one such concentrate that can be spray dried to produce a powdered form. The process involves atomizing the liquid concentrate into small droplets which are then exposed to hot air, resulting in the evaporation of the water content and formation of a dry powder. Spray drying of orange flavour offers several benefits such as improved shelf life, enhanced stability, and ease of handling and storage.

Spray dried orange flavour powder finds wide application in the food industry as a flavoring agent in various products such as baked goods, confectioneries, beverages, and dairy products. It can also be used in the pharmaceutical industry to impart orange flavor to medicinal products. The powder form provides better uniformity of flavor, easy dosing, and faster solubility in water-based products. Spray dried orange flavour is also popularly used in the cosmetic industry for the formulation of perfumes, body sprays, and other personal care products.

Please see the application note No. 593 for starting parameters and some results.

Spray Drying of Oxytocyn acetate

Spray drying of oxytocin acetate is a process of converting liquid oxytocin acetate into dry powder form using a spray dryer. Oxytocin acetate is a synthetic hormone used to induce labor, prevent or control bleeding after childbirth, and in the treatment of breast pain or discomfort. Spray drying is a commonly used technique to produce stable and easily transportable formulations of oxytocin acetate that can be used in various pharmaceutical products.

The spray drying process of oxytocin acetate involves atomizing the liquid into a fine mist and then exposing it to hot air. The liquid droplets quickly evaporate, leaving behind dry powder particles. The resulting powder has a longer shelf life, better stability, and improved solubility in water.

The use of spray drying for oxytocin acetate has been crucial in the development of safe and effective pharmaceutical products for maternal health. This process has allowed for the easy storage and transportation of oxytocin acetate, making it more accessible to people in remote areas where refrigeration may not be readily available. It has also helped in the development of new formulations of oxytocin acetate that can be administered through different routes of administration, such as oral or nasal sprays, for improved patient convenience and compliance.

Please see the application note No. 597 for starting parameters, formulations and some results.

Spray Drying of Olive leaf extract

Spray drying of olive leaf extract involves the conversion of liquid extracts into dry powder form by evaporating the solvent under controlled temperature and pressure. Olive leaf extract is rich in phenolic compounds such as oleuropein, hydroxytyrosol, and tyrosol, which are known for their potent antioxidant and anti-inflammatory properties. The spray-drying technique helps to preserve these bioactive compounds and extend the shelf life of the extract.

Olive leaf extract is used in various industries, including food, nutraceutical, and pharmaceuticals. It is commonly used as a dietary supplement due to its beneficial effects on cardiovascular health, immune system function, and blood sugar regulation. It is also added to various food products, such as dressings, marinades, and sauces, to enhance their nutritional value and antioxidant activity. In the pharmaceutical industry, olive leaf extract is used as an active ingredient in topical and oral formulations for the treatment of various skin conditions and infections.

Overall, spray drying of olive leaf extract has numerous applications and provides a convenient and effective way to obtain a stable and bioactive powder for various industries.

Please see the application note No. 591 for starting parameters and some results.

Spray Drying of P 6 (Sexual attractant)

Spray drying has been used to create a more stable formulation of Pheromone P6, a sexual attractant compound used for pest management in agriculture. Spray drying has the advantage of producing dry and free-flowing powders, which are easy to handle and store. This technique can also be used to modify the release properties of the compound, leading to better pest management strategies. The spray-dried P6 formulation can be incorporated into dispensers, which release the pheromone over a specific period, mimicking the natural release of the compound by the insects. The use of spray-dried P6 formulations has shown promising results in controlling the population of certain pests, such as fruit flies and moths, which can cause significant damage to crops. Overall, spray drying is a valuable tool in the formulation and delivery of pheromones, aiding in the development of effective and sustainable pest management strategies in agriculture.

Please see the application note No. 598 for starting parameters, formulations and some results.

Spray Drying of Phosphonium Bentonite

Spray drying is a widely used technique to produce powders from liquid feedstocks, and it can be employed to produce phosphonium bentonite powders. Phosphonium bentonite is a type of organophilic clay that has been modified with phosphonium compounds to increase its solubility in organic solvents, and it has several applications in the oil and gas industry. The production of phosphonium bentonite powders through spray drying offers several advantages over traditional methods, including higher yields, improved product consistency, and better control over particle size and morphology.

The powders produced through spray drying of phosphonium bentonite can be used as thickeners and viscosifiers in oil and gas drilling fluids, as well as in other industrial applications such as coatings, adhesives, and plastics. In the oil and gas industry, phosphonium bentonite powders can improve the rheological properties of drilling fluids, increase their carrying capacity, and reduce the risk of wellbore instability. Additionally, these powders can help to minimize the environmental impact of drilling operations by reducing the amount of waste generated and improving the disposal of drilling fluids.

Please see the application note No. 609 for starting parameters and some results.

Spray Drying of Polycarbonate

Polycarbonate (PC) is a versatile and widely used thermoplastic material with a broad range of applications in various industries such as automotive, electronics, and construction. Spray drying is a technique that has been applied to the production of PC powders, offering several advantages in terms of product quality, performance, and process efficiency.

Spray drying of PC allows for the production of powders with controlled particle size and morphology, which can be tailored to specific applications. The resulting powders have high purity, low dust content, and improved solubility, making them suitable for a wide range of processing and manufacturing applications.

Applications of PC powders produced by spray drying include the manufacture of coatings, films, and other high-performance materials. The process can also be used to produce PC powders with enhanced mechanical properties, such as increased toughness and resistance to impact and abrasion.

Overall, spray drying of PC offers numerous benefits and has a wide range of potential applications in various industries, including engineering, manufacturing, and materials science. Its versatility and adaptability make it a valuable tool for the development of new and innovative products.

Please see the application note for starting parameters and some results.

Spray Drying of PFA

Spray drying is a commonly used method for producing dry powders from liquid solutions, suspensions, or emulsions. One such application is in the production of PFA (perfluoroalkoxy) powder. PFA is a thermoplastic resin that is commonly used in the manufacture of pipes, tubes, coatings, and other industrial applications. PFA has a unique set of properties that make it highly resistant to chemicals, high temperatures, and other extreme conditions.

Spray drying of PFA involves atomizing a liquid PFA solution into a spray of fine droplets using a spray nozzle. The droplets are then rapidly dried in a stream of hot gas, resulting in the formation of a dry powder. The powder can be further processed and used in a variety of industrial applications, including coatings, linings, and electrical insulation.

Spray drying of PFA offers several advantages over other drying methods, including the ability to produce a uniform powder with controlled particle size and morphology. It also allows for the production of powders with specific properties such as increased surface area or improved flowability, making it a valuable technique for industrial applications.

Please see the application note No. 606 for starting parameters and some results.

Spray Drying of Oxyhemoglobin

Spray drying has been used to prepare Oxyhemoglobin (OxyHb) nanoparticles, which are useful in drug delivery applications. The process involves the formation of OxyHb nanoparticles by spray drying a solution containing OxyHb and a biodegradable polymer such as poly(lactide-co-glycolide) (PLGA). Spray drying leads to the formation of a dry powder, which can be easily stored and transported.

OxyHb nanoparticles are being investigated for their use in targeted drug delivery systems, as they can be used to deliver drugs to specific tissues in the body. They can also be used to enhance the therapeutic efficacy of drugs, reduce their side effects and improve their bioavailability.

OxyHb nanoparticles have also been studied for their use in oxygen carriers for blood substitutes. Spray drying has been used to prepare OxyHb nanoparticles coated with a biocompatible polymer, which can be used as oxygen carriers in the treatment of anemia and other blood-related disorders.

Please see the application note No. 596 for starting parameters and some results.

Spray Drying of Passion flower

Passion flower (Passiflora incarnata) is a plant known for its sedative and anxiolytic properties, making it useful in the treatment of anxiety and sleep disorders. Spray drying has been used to produce passion flower extract powders, which can be used to make supplements, herbal remedies, and functional foods.

The spray drying process involves atomizing a solution or suspension of passion flower extract into a hot gas stream, which rapidly evaporates the solvent, leaving behind a dry powder containing the passion flower extract.

Spray-dried passion flower extract powders have been shown to have improved stability, longer shelf life, and enhanced bioavailability compared to traditional liquid extracts. They can be used in a range of applications, including the development of dietary supplements, herbal remedies, and functional foods.

Overall, spray drying of passion flower extract offers numerous benefits and has a wide range of potential applications in the herbal and dietary supplement industries. Its versatility and adaptability make it a valuable tool for the development of new and innovative products with improved properties and health benefits.

Please see the application note No. 601 for starting parameters and some results.